Please prepare an extended outlines for Bioinformatic class project. . guidelines are attached below. - Biology
I am attaching here a guideline in a word file, this guideline in the word file is from my professors, which also talks about the presentation, please disregard the presentation part, this time I am only supposed to make a 2-page outline (not more than 2 pages). And the topic I have picked is Gut Microbiota and Bioinformatics. I have also attached 4 primary papers for your convenience but if you like you can pick another primary paper on the same topic. But make sure the papers you have picked be Primary research papers only and on same topic. Also, eventhough these papers talk more about Gut microbiota, you have to make these project outline by keping bioinformatics and its tools in mind, since this project is for Bioinformatics class. Note: This topic mainly focuses on bioinformatics tools and the biological topic/field will be Gut Microbiota.  Thanks BI OINFORMATICS – Outline for the end of the semester project Each individual will find 2 or 3 papers in the literature (Primary research papers only) that A) represent an area of biology that you are interested in; and B) represent work in the area of bioinformatics. Once you have honed in on these papers, read them with an eye toward understanding: What is the biological problem that the authors are trying to address, and what was their motivation? What previous work has been done in the area, and what tools were used in address this problem? What are the specifics about the bioinformatics approaches (e.g., particular programs, methods, programming language, databases, etc.) used? Did the authors evaluate whether the approaches used provided biologically meaningful results? You will prepare a 15 (+/- 2) minute presentation that includes some discussion of the biology/problem/background, but that focus most of the attention on the bioinformatics aspects. You will discuss methods/approaches, software used, etc., and present some results that you have obtained using e.g., a bioinformatics approach outlined in the papers. Remember that this will be due at the END of the semester; however, at this point I would like you to prepare a short outline that cites the papers you have chosen, briefly reports on the area of biology/problem/background related to the topic you have chosen. Next include a brief synopsis of the bioinformatics tools used, and a hint at some of the results obtained. Finally, include a list of names (if any) of individuals that you are considering working with as a group. This outline is not a complete report, and should be one or two outlining pages and nothing longer. The point here is that I would like to A) check that you have selected and read some papers; B) to have an idea about the bioinformatics work you will be presenting on. RESEARCH Open Access Associations between gut microbiota and Alzheimer’s disease, major depressive disorder, and schizophrenia Zhenhuang Zhuang1, Ruotong Yang1, Wenxiu Wang1, Lu Qi2,3* and Tao Huang1,4,5,6* Abstract Background: Growing evidence has shown that alterations in the gut microbiota composition were associated with a variety of neuropsychiatric conditions. However, whether such associations reflect causality remains unknown. We aimed to reveal the causal relationships among gut microbiota, metabolites, and neuropsychiatric disorders including Alzheimer’s disease (AD), major depressive disorder (MDD), and schizophrenia (SCZ). Methods: A two-sample bi-directional Mendelian randomization analysis was performed by using genetic variants from genome-wide association studies as instrumental variables for gut microbiota, metabolites, AD, MDD, and SCZ, respectively. Results: We found suggestive associations of host-genetic-driven increase in Blautia (OR, 0.88; 95\%CI, 0.79–0.99; P = 0.028) and elevated γ-aminobutyric acid (GABA) (0.96; 0.92–1.00; P = 0.034), a downstream product of Blautia-dependent arginine metabolism, with a lower risk of AD. Genetically increased Enterobacteriaceae family and Enterobacteriales order were potentially associated with a higher risk of SCZ (1.09; 1.00–1.18; P = 0.048), while Gammaproteobacteria class (0.90; 0.83–0.98; P = 0.011) was related to a lower risk for SCZ. Gut production of serotonin was potentially associated with an increased risk of SCZ (1.07; 1.00–1.15; P = 0.047). Furthermore, genetically increased Bacilli class was related to a higher risk of MDD (1.07; 1.02–1.12; P = 0.010). In the other direction, neuropsychiatric disorders altered gut microbiota composition. Conclusions: These data for the first time provide evidence of potential causal links between gut microbiome and AD, MDD, and SCZ. GABA and serotonin may play an important role in gut microbiota-host crosstalk in AD and SCZ, respectively. Further investigations in understanding the underlying mechanisms of associations between gut microbiota and AD, MDD, and SCZ are required. Keywords: Gut microbiota, Neuropsychiatric disorder, Mendelian randomization, Genetic association, Causality Background The human intestine comprises a very complex group of gut microbiota, which influence the risk of neuropsychiatric disorders [1, 2]. Accumulating evidence has suggested that microbiota metabolites such as neurotransmitters and short-chain fatty acids (SCFAs) may play a central role in microbiota-host crosstalk that regulates the brain function and behavior [3, 4]. Therefore, to understand the mechan- ism of the gut-brain axis in neuropsychiatric disorders may have clinical benefits. Observational studies, most of case-control designs, have shown differences in the composition of the gut microbiota between healthy individuals and patients with neuropsychi- atric disorders such as Alzheimer’s disease (AD), major depression disorder (MDD), and schizophrenia (SCZ); © The Author(s). 2020 Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the articles Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the articles Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data. * Correspondence: [email protected]; [email protected] 2Department of Epidemiology, School of Public Health and Tropical Medicine, Tulane University, New Orleans, LA, USA 1Department of Epidemiology & Biostatistics, School of Public Health, Peking University, 38 Xueyuan Road, Beijing 100191, China Full list of author information is available at the end of the article Zhuang et al. Journal of Neuroinflammation (2020) 17:288 https://doi.org/10.1186/s12974-020-01961-8 http://crossmark.crossref.org/dialog/?doi=10.1186/s12974-020-01961-8&domain=pdf http://orcid.org/0000-0002-0328-1368 http://creativecommons.org/licenses/by/4.0/ http://creativecommons.org/publicdomain/zero/1.0/ mailto:[email protected] mailto:[email protected] however, such associations substantially differed across studies [5–7]. Noteworthy, genome-based metabolic mod- eling of the human gut microbiota revealed that several genera have predictive capability to produce or consume neurotransmitters (called microbial neurotransmitters) such as γ-aminobutyric acid (GABA) and serotonin [8, 9], which have been consistently shown to played a key role in the regulation of brain function [10, 11]. A meta-analysis of 35 observational studies reported that increased GABA levels were associated with a lower risk of AD [12]. In addition, a previous study (n = 40) reported that plasma serotonin was lower and platelet serotonin was higher in SCZ patients compared with controls [13], while another study showed that lower platelet serotonin concentrations were associated with depressive symptoms of SCZ (n = 364) [14]. There is no doubt that these small observational studies were sus- ceptible to confounding bias and reverse causation. It is crucial to elucidate whether such associations reflect causal relations or spurious correlations due to bias. Mendelian randomization (MR), which overcomes the bias due to confounding and reverse causation above- mentioned, has been widely used to assess causal rela- tionships by exploiting genetic variants as instrumental variables of the exposure [15]. Recent genetic studies have demonstrated that the host genetic variants influ- ence the gut microbiota composition [16–18]. Thus, such findings allowed us to deploy an MR approach to infer the mutually causal relations of gut microbiota and metabolites with neuropsychiatric disorders. Therefore, we for the first time applied a two-sample bi-directional MR approach to detect causal relation- ships among gut microbiota, metabolites, and diverse forms of neuropsychiatric disorders including AD, SCZ, and MDD. Methods Study design overview We employed a two-sample bi-directional MR approach to investigate the causal relationships among gut micro- biota, metabolites, and AD, MDD, or SCZ using summary-level data from large genome-wide association studies (GWASs) for gut microbiota and AD, MDD, or SCZ. Ethical approval for each study included in the MR analysis can be found in the original articles [19–23]. Data sources and instruments Gut microbiota We leveraged summary statistics from a GWAS of gut microbiota conducted among two independent but geo- graphically matched cohorts of European ancestry (n = 1812) using 16S rRNA gene sequencing (Table 1) [19], which yielded a total of 38 and 374 identified phyla and genera respectively. The GWAS defined a “core measur- able microbiota” after removing rare bacteria and investigating associations between host genetic variants and specific bacterial traits, including 40 operational taxonomic units (OTUs) and 58 taxa ranging from the genus to the phylum level. Accordingly, the GWAS fur- ther identified 54 genome-wide significant associations involving 40 loci and 22 bacterial traits (meta-analysis P < 5 × 10−8). We selected single nucleotide polymor- phisms (SNPs) at thresholds for genome-wide signifi- cance (P < 5 × 10−8) from this GWASs as genetic instruments (Table S1). Gut microbial metabolites Considering the important roles of gut microbiota- derived metabolites in microbiota-host crosstalk in the brain function and behavior, we further chose key me- tabolites with available GWAS, including propionic acid, β-hydroxybutyric acid (BHB), serotonin, GABA, tri- methylamine N-oxide (TMAO), betaine, choline, and carnitine. These gut microbial metabolites play crucial roles in maintaining a healthy neuropsychiatric function, and if dysregulated, potentially causally linked to neuro- psychiatric disorders according to previous studies [3, 24, 25]. We searched PubMed for GWASs of the gut metabolites and leveraged summary-level data from a re- cent GWAS of the human metabolome conducted among 2076 participants of the Framingham Heart Study (Table 1) [20]. Since few loci identified by gut me- tabolite GWAS have reached the level of genome-wide significance, we only selected SNPs at thresholds for suggestive genome-wide significance (P < 1 × 10−5) from the GWAS for each metabolite (Table S2). Neuropsychiatric disorders We searched PubMed for GWASs of the neuropsychi- atric disorders and identified SNPs with genome-wide significant (P < 5 × 10−8) associations for AD [21], MDD [22], and SCZ [23], respectively (Table 1, Table S3). Summarized data for AD were obtained from the Inter- national Genomics of Alzheimer’s Project (IGAP), in- cluding 25,580 AD cases and 48,466 controls, and the analysis was adjusted for age, sex, and principal compo- nents when necessary [21]. Genetic associations for MDD were obtained from Psychiatric Genomics Consor- tium 29 (PGC29) including135,458 MDD cases and 344, 901 controls, using sex and age as covariates [22]. Gen- etic associations for SCZ were obtained from a meta- analysis of Sweden and PGC including 13,833 SCZ cases and 18,310 controls [23]. Detailed information on diag- nostic criteria for AD, MDD, and SCZ are provided in Table S4. These GWASs identified 19 SNPs for AD, 44 SNPs for MDD, and 24 SNPs for SCZ (P < 5 × 10−8), re- spectively (Table S3). Zhuang et al. Journal of Neuroinflammation (2020) 17:288 Page 2 of 9 Statistical analysis For instrumental variables, we only selected independent genetic variants which are not in linkage disequilibrium (LD) (defined as r2 < 0.1) with other genetic variants based on European ancestry reference data from the 1000 Genomes Project. We chose the variant with the lowest P value for association with the exposure when genetic variants were in LD. Moreover, for SNPs that were not available in GWASs of the outcome, we used the LD proxy search on the online platform (https:// snipa.helmholtz-muenchen.de/snipa3/index.php/) to re- place them with the proxy SNPs identified in high-LD (r2 > 0.8) or discard them if the proxies were not avail- able. Power calculations for the MR study were con- ducted based on the website: mRnd (http://cnsgenomics. com/shiny/mRnd/). We combined MR estimates by using inverse variance weighting (IVW) as primary method. Weighted mode, weighted median, and MR-Egger methods were used as sensitivity analyses. Detailed information about the MR methods mentioned above has been explained previously [26, 27]. The MR-Egger method examined for unknown horizontal pleiotropy as indicated by a non-zero inter- cept value. We also applied leave-one-SNP-out approach assessing the effects of removing these SNPs from the MR analysis to rule out potential pleiotropic effects. Ef- fect estimates are reported in beta values for the con- tinuous outcome and ORs (95\% CIs) for binary outcome. Bonferroni correction was used to adjust for multiple comparisons, giving a cutoff of P = 7.6 × 10−4 for the causal effect of gut microbiota on disorders and a cutoff of P = 1.7 × 10−4 for reverse causation. The MR analyses were conducted in the R version 3.5.1 computing environment (http://www.r-project.org) using the TwoSampleMR package (R project for Statis- tical Computing). This package harmonized effect of the exposure and outcome data sets including combined in- formation on SNPs, including phenotypes, effect alleles, effect allele frequencies, effect sizes, and standard errors for each SNP. In addition, we assumed that all alleles are presented on the forward strand in harmonization. In conclusion, the bi-directional MR results using the full set of selected SNPs. Results Associations of gut microbiota and metabolites with neuropsychiatric disorders We found suggestive evidence of a protective effect of the host-genetic-driven increase in Blautia on the risk of AD (per relative abundance: OR, 0.88; 95\% CI, 0.79– 0.99; P = 0.028) (Fig. 1, Figure S1). Importantly, we fur- ther observed suggestive evidence that genetically ele- vated gut metabolite GABA was associated with a lower risk of AD (per 10 units: 0.96; 0.92–1.00; P = 0.034) (Figs. 1 and 2). Furthermore, the host-genetic-driven increases in En- terobacteriaceae family and Enterobacteriales order were potentially related to a higher risk of SCZ (1.09; 1.00– 1.18; P = 0.048), while Gammaproteobacteria class was related to a lower risk of SCZ (0.90; 0.83–0.98; P = 0.011) (Fig. 1, Figure S1). Interestingly, gut production of serotonin was potentially associated with a higher risk of SCZ (1.07; 1.00–1.15; P = 0.047) (Figs. 1 and 3). In addition, we found suggestive association of the host- genetic-driven increase in Bacilli class with a higher risk of MDD (1.07; 1.02–1.12; P = 0.010) (Fig. 1, Figure S1). Sensitivity analysis yielded similar results for the causal effects of gut microbiota on neuropsychiatric disorders, and no horizontal pleiotropy or outliers were observed (Tables S5 and S6). No significant results were found for any of other selected gut microbiota or metabolites with neuro- psychiatric disorders (Table S7). MR power calculation showed strong power to detect significant (P < 7.6 × 10−4) causal effect (OR = 1.2) for most of gut microbiota with the risk of AD, MDD, and SCZ, respectively (Table S8). Associations of neuropsychiatric disorders with gut microbiota In the opposite direction, we applied the MR method to investigate the causal relationship of neuropsychiatric Table 1 Description of gut microbiota, metabolites, and neuropsychiatric disorders Traits Consortium or study Sample size Populations Journal Year Gut Gut microbiota PopGen/FoCus 1812 individuals European Nat Genet. 2016 Gut metabolites FHS 2076 individuals European Cell Metab. 2013 Neuropsychiatric disorders Alzheimer’s disease IGAPa 25,580 cases and 48,466 controls European Nat Genet. 2013 Major depression disorder PGC29/deCODE/GenScotland/GERA/iPSYCH/UK Biobank/23andMeD 135,458 cases and 344,901 controls European Nat Genet. 2018 Schizophrenia Sweden/PGC 21,246 cases and 38,072 controls European Nat Genet. 2013 FoCus Food-Chain Plus, GERA Genetic Epidemiology Research on Adult Health and Aging, PGC Psychiatric Genomics Consortium a IGAP includes the Alzheimer’s Disease Genetics Consortium (ADGC), the Cohorts for Heart and Aging Research in Genomic Epidemiology consortium (CHARGE), the European Alzheimer’s disease Initiative (EADI), and the Genetic and Environmental Risk in Alzheimer’s disease consortium (GERAD) Zhuang et al. Journal of Neuroinflammation (2020) 17:288 Page 3 of 9 https://snipa.helmholtz-muenchen.de/snipa3/index.php https://snipa.helmholtz-muenchen.de/snipa3/index.php http://cnsgenomics.com/shiny/mRnd/ http://cnsgenomics.com/shiny/mRnd/ http://www.r-project.org disorders with gut microbiota. We found a suggestive as- sociation of AD with lower relative abundance of Erysi- pelotrichaceae family, Erysipelotrichales order, and Erysipelotrichia class (per 1-unit odds ratio: Beta±SE, − 0.274 ± 0.090; P = 0.003) and higher relative abundance of unclassified Porphyromonadaceae (0.351 ± 0.170; P = 0.040) (Fig. 1, Table S9). Additionally, MDD was associ- ated with higher relative abundance of unclassified Clos- tridiales (0.577 ± 0.241; P = 0.017), OTU16802 Bacteroides (0.842 ± 0.386; P = 0.029), and unclassified Prevotellaceae (0.978 ± 0.464; P = 0.035) (Fig. 1, Table S9). We further identified that SCZ was nominally re- lated to 2 genera, including higher relative abundance of OTU10589 unclassified Enterobacteriaceae (0.457 ± 0.220; P = 0.037) and lower relative abundance of un- classified Erysipelotrichaceae (− 0.248 ± -0.019; P = 0.045) (Fig. 1, Table S9). Associations were almost consistent in sensitivity ana- lyses using the weighted mode and weighted median methods. The MR-Egger method showed directional pleiotropy in the analysis of association between MDD and OTU16802 Bacteroides (P = 0.022) but not in any other potential significant associations (Table S9). How- ever, we had limited power (all less than 50\%) to test sig- nificant (P < 1.7 × 10−4) causal effect (Beta = 0.5) of the risk of AD, MDD, and SCZ on specific gut microbiota (data not shown), possibly due to small sample size of the gut microbiota GWAS. Discussion In this two-sample bi-directional MR study, we found suggestive evidence of causal relationships of Blautia with AD, of Enterobacteriaceae family, Enterobacteriales order, and Gammaproteobacteria class with SCZ, and of Bacilli class with MDD. More importantly, several neu- rotransmitters such as GABA and serotonin produced by gut microbiota were also potentially linked to the risks of neuropsychiatric disorders, implying their im- portant roles in microbiota-host crosstalk in the brain function and behavior. In the other direction, our results suggested that neuropsychiatric disorders, including AD, SCZ, and MDD might alter the composition of gut microbiota. Microbiota-gut-brain communication has been shown to play a key role in cognitive function [2]. However, animal studies regarding the effects of Blautia genus on AD have yielded conflicting results, but extrapolating these findings to human beings is challenging [28, 29]. A cohort study (n = 108) reported that decreased propor- tion of Blautia hansenii was associated with a higher risk of AD [30], while two case-control studies observed that Blautia were more abundant in AD patients [5, 31]. Fig. 1 Schematic representation of the present study, highlighting for each step of the study design and the significant results obtained. We aimed to estimate causal relationships between gut microbiota (98 individual bacterial traits) and neuropsychiatric disorders (Alzheimer’s disease, major depression disorder, and schizophrenia) using a bi-directional Mendelian randomization (MR) approach (step 1). Then, we performed a two- sample MR analysis to identify which microbiota metabolites associated with these disorders (step 2). Finally, we identified 14 individual bacterial traits and 2 gut metabolites to be associated with these disorders. GABA, γ-aminobutyric acid; SCFA, short-chain fatty acids Zhuang et al. Journal of Neuroinflammation (2020) 17:288 Page 4 of 9 Although the direction of associations between Blautia and the risk of AD substantially differed across studies, one consistent finding was that gut microbial neuro- transmitter GABA, a downstream product of Blautia- dependent arginine metabolism, was related to a reduced risk of AD. Notably, lower levels of gut product of GABA were observed in patients with AD in several case-control studies [32, 33]. In this bi-directional MR study, our results for the first time provide evidence of a causal relationship between relative abundance of Blau- tia and AD. More importantly, we demonstrated that el- evated GABA was potentially associated with a lower risk of AD. Our findings supported previous meta- analysis of 35 observational studies which suggested that GABA level in AD were significantly lower than that of controls [12]. Our findings suggest that GABA produced by gut microbiota may play an important role in microbiota-host crosstalk in the brain function and be- havior. Although not significant, our findings show very similar association directions for Blautia with MDD and SCZ. Our findings are in line with recent studies which indicated that decreased Blautia was associated with an increased risk of autistic spectrum disorder (ASD), sug- gesting a general change associated with psychiatric dis- orders [34]. There are many potential pathways linking specific gut microbiota to AD, among which metabolites produced by gut microbiota may play an important role. It is worth noting that GABA, as a primary inhibitory neuro- transmitter in the human central nervous system (CNS), has been shown to shape neurological processes and cognition [35]. Recent evidence has demonstrated that GABAergic functions could be an essential factor in the whole stage of AD pathogenesis which seemed to be more resistant to neurodegenerative changes in aged brain [36, 37]. Our MR results that increased GABA levels was potentially associated with a lower risk of AD lent further support to the hypotheses. The biological mechanisms of GABA production include degradation of putrescine, decarboxylation of glutamate, or from ar- ginine or ornithine [8]. Interestingly, the genus Blautia has shown a strong correlation with arginine metabolism [38], which may be involved in AD pathogenesis by regulating its downstream products such as GABA, sup- porting the potential pathway [39]. Since AD does not break out suddenly but develops through a long pro- dromal phase instead, it is plausible that our findings may be potentially effective in early interventions of such dis- order in the future by targeting the microbiota (e.g., gut microbiota transplantation, psychobiotics, or antibiotics). Fig. 2 Causal effect of GABA with the risk of AD. a Schematic representation of the MR analysis results: genetically determined higher GABA plasma levels were potentially associated with a lower risk of AD. b The odds ratios (95\% confidence interval) for AD per 10 units increase in GABA, as estimated in the inverse-variance weighted, weighted mode, weighted median, and MR-Egger MR analysis. The intercept of MR-Egger can be interpreted as a test of overall unbalanced horizontal pleiotropy. c The scatter plot represents instruments association including AD associations (y-axis) against instrument GABA associations (x-axis). The tunnel plot represents instrument precision (i.e., instrument AD regression coefficients divided by the correspondent instrument GABA SEs) (y-axis) against individual instrument ratio estimates in log odds ratio of AD (x- axis). βIV indicates odds ratio estimate per 1-ln 10 units increment in GABA levels. AD, Alzheimer’s disease; OR, odds ratio; CI, confidence interval; SNP, single-nucleotide polymorphism; SE, standard error; IVW, inverse variance weighted Zhuang et al. Journal of Neuroinflammation (2020) 17:288 Page 5 of 9 Recently, Enterobacteriales family and Gammaproteo- bacteria class have been identified to be important bio- markers of SCZ in recent cross-sectional studies, consistent with our findings [6, 40]. Furthermore, a case- control study (n = 364) identified a strong relationship of lower platelet serotonin concentrations with depres- sive symptoms of SCZ [14]. However, available evidence is still largely inadequate since observational studies mainly rely on self-reported information and are suscep- tible to confounding (e.g., diet and health status) and re- verse causation bias. Ertugrul et al. observed plasma serotonin increased while platelet serotonin decreased in SCZ patients after clinical treatments, which was incon- sistent with our findings [13]. In addition, our results support the finding that increased Bacilli is potentially associated with a higher risk of MDD, possibly involving dopamine metabolism which might play a role in the major symptoms of MDD [41, 42]. A meta-analysis of RCTs showed that probiotics, typically including Lacto- bacillus and Bifidobacterium, had some benefit for MDD, but we found no associations for these micro- biota, possibly due to the synergistic effect of gut micro- biome so that the influence of a particular taxon may be different from multiple taxa [43]. Furthermore, these clinical trials might draw biased conclusions because of small sample sizes (ranging from 17 to 110) or short- term effects (ranging from 3 to 24 weeks). Therefore, a large and long-term RCT in a well-characterized popula- tion using probiotic capsules containing specific micro- biota might provide further evidence for the gut-brain axis in these disorders. Importantly, epidemiological study indicated that elevated Enterobacteriales was also associated with a higher risk of ASD, suggesting that the same changes in intestinal microbiota composition might lead to different outcomes due to gene-gene inter- actions and gene-environment interactions [44]. Al- though our results showed no significant association for Gammaproteobacteria and MDD, animal models found increased levels of Gammaproteobacteria were also asso- ciated with higher MDD risk and fluoxetine treatment was effective, implying strong correlations between gut microbiota and anxiety- and depression-like behaviors [45]. The serotonin hypothesis of SCZ originated from earl- ier studies of interactions between the hallucinogenic drug D-lysergic acid diethylamide and serotonin in per- ipheral systems. However, direct evidence of serotoner- gic dysfunction in the pathogenesis of SCZ remains unclear [46]. According to the principle of brain plasti- city, glutamate signals are destroyed by serotonergic overdrive, leading to neuronal hypometabolism, synaptic atrophy, and gray matter loss in the end [47]. Our find- ings that genetically increased serotonin levels was po- tentially related to a high risk of SCZ using a MR Fig. 3 Causal effect of serotonin with the risk of SCZ. a Schematic representation of the MR analysis results: genetically determined higher serotonin plasma levels were potentially associated with a higher risk of SCZ. b The odds ratios (95\% confidence interval) for SCZ per 10 units increase in serotonin, as estimated in the inverse-variance weighted, weighted mode, weighted median, and MR-Egger MR analysis. The intercept of MR-Egger can be interpreted as a test of overall unbalanced horizontal pleiotropy. c The scatter plot represents instruments association including SCZ associations (y-axis) against instrument serotonin associations (x-axis). The tunnel plot represents instrument precision (i.e., instrument SCZ regression coefficients divided by the correspondent instrument serotonin SEs) (y-axis) against individual instrument ratio estimates in log odds ratio of SCZ (x-axis). βIV indicates odds ratio estimate per 1-ln 10 units increment in serotonin levels. SCZ, schizophrenia Zhuang et al. Journal of Neuroinflammation (2020) 17:288 Page 6 of 9 approach supported such hypothesis. Importantly, En- terobacteriaceae family and Enterobacteriales order can produce SCFAs (e.g., acetic acid and formic acid) in carbohydrate fermentation, thus inducing serotonin bio- synthesis by enterochromaffin cells which are the major producers of serotonin, and ultimately increasing the risk of SCZ [48, 49]. Our novel findings highlighted the potentially important role of gut microbiota-related neu- rotransmitters in effective and benign therapies of psy- chiatric disorders. Furthermore, we also found that neuropsychiatric disor- ders might alter the composition of gut microbiota. Our findings were consistent with a small case-control study (n = 50) suggesting that Erysipelotrichaceae family were all less abundant in patients with AD [5]. An observational study showed that Porphyromonadaceae were associated with poor cognitive performance, partly consistent with our results [50]. However, the results from animal studies are conflicting. Although several animal studies suggested that anti-AD microbes, such as Erysipelotrichiaceae, decreased in mouse models with AD, and Porphyromonadaceae in- creased in aged mice [28, 51], other animal studies showed that the relative abundance of Erysipelotrichiaceae was positively correlated with AD [52, 53]. Therefore, the asso- ciation of neuropsychiatric disorders with specific gut microbiota requires further study. It is universally accepted that the CNS modulates gut microbiota compositions mainly through hypothalamic-pituitary-adrenal (HPA) axis, or classical neurotransmitters liberated by neuronal efferent activation, which explains the microbiota-host crosstalk in neuropsychiatric disorders from another direction [54]. Additionally, it is plausible that alterations in gut microbiota and related metabolites would lead to a sys- temic change in inflammation that may contribute to the neuroinflammation in AD, MDD, and SCZ. Increas- ing evidence suggests that bacteria populating the gut microbiome may excrete large quantities of lipopolysac- charides and amyloids, resulting in the pathogenesis of AD during aging when the permeability of gastrointes- tinal tract epithelium or blood-brain barrier increases [55]. Recent research has indicated that gut inflamma- tion can induce activation of microglia and the kynure- nine pathway, which activate systemic inflammation- inducing depressive or schizophrenic symptoms [56, 57]. Therefore, more studies are required to explore the mechanisms underlying the relationships of inflamma- tion with the gut microbiota-brain axis and its relations with AD, MDD and SCZ. Strengths of the present study … www.aging-us.com 2764 AGING INTRODUCTION Major depressive disorder (MDD) is viewed as a major public health problem globally. MDD has a substantial impact on society and individuals, such as increasing economic burden and decreasing labor productivity [1–3]. At a global level, more than 300 million people are estimated to suffer from MDD, which is equivalent to 4.4\% of the world’s population [4]. However, the pathogenesis of MDD is still unclear. Some theories have been developed to explain the biological mechanisms of MDD, such as neurotrophic alterations www.aging-us.com AGING 2020, Vol. 12, No. 3 Research Paper Age-specific differential changes on gut microbiota composition in patients with major depressive disorder Jian-Jun Chen1,2,*,#, Sirong He3,*, Liang Fang2,4,*, Bin Wang1, Shun-Jie Bai5, Jing Xie6, Chan-Juan Zhou7, Wei Wang8, Peng Xie4,7,8,# 1Institute of Life Sciences, Chongqing Medical University, Chongqing 400016, China 2Chongqing Key Laboratory of Cerebral Vascular Disease Research, Chongqing Medical University, Chongqing 400016, China 3Department of Immunology, College of Basic Medicine, Chongqing Medical University, Chongqing 400016, China 4Department of Neurology, Yongchuan Hospital of Chongqing Medical University, Chongqing 402160, China 5Department of Laboratory, The First Affiliated Hospital of Chongqing Medical University, Chongqing 400016, China 6Department of Endocrinology and Nephrology, Chongqing University Central Hospital, Chongqing Emergency Medical Center, Chongqing 400014, China 7NHC Key Laboratory of Diagnosis and Treatment on Brain Functional Diseases, Chongqing Medical University, Chongqing 400016, China 8Department of Neurology, The First Affiliated Hospital of Chongqing Medical University, Chongqing 400016, China *Equal contribution #Co-senior authors Correspondence to: Peng Xie, Jian-Jun Chen; email: [email protected], [email protected] Keywords: major depressive disorder, gut microbiota, Firmicutes, Bacteroidetes, Actinobacteria Received: November 21, 2019 Accepted: January 12, 2020 Published: February 10, 2020 Copyright: Chen et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY 3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. ABSTRACT Emerging evidence has shown the age-related changes in gut microbiota, but few studies were conducted to explore the effects of age on the gut microbiota in patients with major depressive disorder (MDD). This study was performed to identify the age-specific differential gut microbiota in MDD patients. In total, 70 MDD patients and 71 healthy controls (HCs) were recruited and divided into two groups: young group (age 18-29 years) and middle-aged group (age 30-59 years). The 16S rRNA gene sequences were extracted from the collected fecal samples. Finally, we found that the relative abundances of Firmicutes and Bacteroidetes were significantly decreased and increased, respectively, in young MDD patients as compared with young HCs, and the relative abundances of Bacteroidetes and Actinobacteria were significantly decreased and increased, respectively, in middle-aged MDD patients as compared with middle-aged HCs. Meanwhile, six and 25 differentially abundant bacterial taxa responsible for the differences between MDD patients (young and middle-aged, respectively) and their respective HCs were identified. Our results demonstrated that there were age-specific differential changes on gut microbiota composition in patients with MDD. Our findings would provide a novel perspective to uncover the pathogenesis underlying MDD. mailto:[email protected] mailto:[email protected] www.aging-us.com 2765 AGING and neurotransmission deficiency [5, 6]. However, none of these theories has been universally accepted. Therefore, there is a pressing need to identify novel pathophysiologic mechanisms underlying this disease. In recent years, mounting evidence has shown that gut microbiota could play a vital role in every aspect of physiology [7]. It is the largest and most direct external environment of humans. Previous studies found that the disturbance of gut microbiota had a crucial role in the pathogenesis of many diseases [8–10]. Recent studies reported that gut microbiota could affect the host brain function and host behaviors through microbiota-gut- brain axis [11, 12]. Using germ-free mice, we found that gut microbiota could influence the gene levels in the hippocampus of mice and lipid metabolism in the prefrontal cortex of mice [13, 14]. Our clinical studies demonstrated that the disturbance of gut microbiota might be a contributory factor in the development of MDD [15, 16]. Nowadays, emerging evidence has shown the age- related changes in gut microbiota composition. For example, Firmicutes is the dominant taxa during the neonatal period, but Actinobacteria and Proteobacteria are about to increase in three to six months [17]. While in adults, Vemuri et al. reported that Bacteroidetes and Firmicutes were the dominant taxa [18]. Meanwhile, compared to younger individuals, the abundance of Bacteroidetes is significantly higher in frailer older individuals [19]. These results showed that there was a close relationship between age and gut microbiota composition. Ignoring this relationship would affect the robust of results when exploring the mechanism of action of gut microbiota in diseases. Therefore, to study the relationship between gut microbiota and MDD patients in different age groups, we recruited 52 young subjects aged from 18 to 29 years (27 healthy controls (HCs) and 25 MDD patients) and 89 middle-aged subjects aged from 30 to 59 years (44 HCs and 45 MDD patients). The main purpose of this study was to identify the age-specific differential changes on gut microbiota composition in MDD patients. Our results would display the different changes of gut microbiota composition along with age between HCs and MDD patients. RESULTS Differential gut microbiota composition As shown in Figure 1, the results of abundance-based coverage estimator (ACE) and Chao1 showed that there was no significant difference in OTU richness between MDD patients (young and middle-aged, respectively) and their respective HCs. However, the OPLS-DA model built with young HCs and young MDD patients showed an obvious difference in microbial abundances between these two groups (Figure 2A). The relative abundances of Firmicutes and Bacteroidetes were Figure 1. Comparison of alpha diversity between HCs and MDD patients. (A, B) ACE and Chao1 indexes showed no significant differences between young HCs (n=27) and young MDD patients (n=25); (C, D) ACE and Chao1 indexes showed no significant differences between middle-aged HCs (n=44) and middle-aged MDD patients (n=45). www.aging-us.com 2766 AGING significantly decreased and increased, respectively, in young MDD patients as compared with young HCs (Figure 2B). Meanwhile, the OPLS-DA model built with middle-aged HCs and middle-aged MDD patients showed an obvious difference in microbial abundances between these two groups (Figure 3A). The relative abundances of Bacteroidetes and Actinobacteria were significantly decreased and increased, respectively, in middle-aged MDD patients as compared with middle- aged HCs (Figure 3B). Key discriminatory OTUs In order to find out the gut microbiota primarily responsible for the separation between MDD patients (young and middle-aged, respectively) and their respective HCs, the Random Forests classifier was used. A total of 92 OTUs responsible for the separation between young MDD patients and young HCs were identified (Figure 4). These OTUs were mainly assigned to the Families of Bacteroidaceae, Clostridiaceae_1, Figure 2. 16S rRNA gene sequencing reveals changes to microbial abundances in young MDD patients. (A) OPLS-DA model showed an obvious difference in microbial abundances between the two groups (HCs, n=27; MDD, (n=25); (B) the relative abundances of Firmicutes and Bacteroidetes were significantly changed in young MDD patients (n=25) as compared with young HCs (n=27). Figure 3. 16S rRNA gene sequencing reveals changes to microbial abundances in middle-aged MDD patients. (A) OPLS-DA model showed an obvious difference in microbial abundances between the two groups (HCs, n=44; MDD, (n=45); (B) the relative abundances of Bacteroidetes and Actinobacteria were significantly changed in middle-aged MDD patients (n=45) as compared with middle-aged HCs (n=44). www.aging-us.com 2767 AGING Coriobacteriaceae, Erysipelotrichaceae, Lachnospiraceae, Peptostreptococcaceae and Ruminococcaceae. Meanwhile, a total of 122 OTUs responsible for the separation between middle-aged MDD patients and middle-aged HCs were identified (Figure 5). These OTUs were mainly assigned to the Families of Lachnospiraceae, Coriobacteriaceae, Streptococcaceae, Prevotellaceae, Bacteroidaceae, Eubacteriaceae, Actinomycetaceae, Sutterellaceae, Acidaminococcaceae, Erysipelotrichaceae, Ruminococcaceae, and Porphyromonadaceae. Figure 4. Heatmap of discriminative OTUs abundances between young HCs (n=27) and young MDD patients (n=25). Figure 5. Heatmap of discriminative OTUs abundances between middle-aged HCs (n=44) and middle-aged MDD patients (n=45). www.aging-us.com 2768 AGING Differentially abundant bacterial taxa Differentially abundant bacterial taxa responsible for the differences between MDD patients (young and middle-aged, respectively) and their respective HCs were identified by the metagenomic Linear Discriminant Analysis (LDA) Effect Size (LEfSe) approach (LDA score>2.0 and p-value<0.05). In total, six bacterial taxa with statistically significant and biologically consistent differences in young MDD patients were identified (Figure 6). Meanwhile, fifteen bacterial taxa with statistically significant and biologically consistent differences in middle-aged MDD patients were identified (Figure 7). In addition, using Figure 6. Differentially abundant features identified by LEfSe that characterize significant differences between young HCs (n=27) and young MDD patients (n=25). Figure 7. Differentially abundant features identified by LEfSe that characterize significant differences between middle-aged HCs (n=44) and middle-aged MDD patients (n=45). www.aging-us.com 2769 AGING the receiver operating characteristic (ROC) curve analysis, we found that Clostridium_sensu_stricto, Clostridium_XI and Clostridium_XVIII showed good diagnostic performance (area under the curve (AUC) >0.7) in diagnosing young MDD patients (Figure 8A– 8C). We also found that Anaerostipes, Streptococcus, Blautia, Faecalibacterium and Roseburia showed good diagnostic performance (AUC>0.7) in diagnosing middle-aged MDD patients (Figure 8D–8H). Effects of age on microbial abundances Using the LEfSe approach, we identified four differentially abundant bacterial taxa (the Family level) between young HCs and middle-aged HCs (Streptococcaceae, Coriobacteriaceae, Carnobacteriaceae and Clostridiales_Incertae_Sedis_XIII) (Figure 9A); we also identified six differentially abundant bacterial taxa (the Family level) between young MDD patients and middle-aged MDD patients (Prevotellaceae, Acidaminococcaceae, Veillonellaceae Peptostrep- tococcaceae, Lachnospiraceae and Ruminococcaceae) (Figure 9B). Meanwhile, using the LEfSe approach, we identified five differentially abundant bacterial taxa (the Genus level) between young HCs and middle-aged HCs (Streptococcus, Veillonella, Granulicatella, Collinsella and Megamonas) (Figure 10A). All these bacterial taxa were significantly decreased in middle-aged HCs; we also identified nine differentially abundant bacterial taxa (the Genus level) between young MDD patients and middle-aged MDD patients (Megamonas, Prevotella, Phascolarctobacterium, Anaerostipes, Clostridium_XVIII, Gordonibacter, Eggerthella, Clostridium_XI and Turicibacter) (Figure 10B). Effects of medication on microbial abundances To determinate the homogeneity of gut microbiota composition between medicated and non-medicated MDD patients, we firstly used the middle-aged HCs and non-medicated middle-aged MDD patients to built OPLS-DA model (Figure 11A). The results showed that 41 of the 44 middle-aged HCs and 30 of the 31 non- medicated middle-aged MDD patients were correctly diagnosed by the OPLS-DA model. Then, we used the built model to predict class membership of 14 medicated middle-aged MDD patients. The T-predicted scatter plot showed that 11 of the 14 medicated middle- aged MDD patients were correctly predicted (Figure 11B). These finding indicated that the gut microbiota composition of non-medicated middle-aged MDD patients were distinct from middle-aged HCs, but not from medicated middle-aged MDD patients. DISCUSSION Individuals in the different phases of life cycle (named children, young, middle-aged and elderly) present different biological characteristics and disease risks [20]. Understanding the different characteristics of patients in particular age phases could be facilitated to prevent and treat diseases. According to the World Health Organization reported, the prevalence rates of depression vary by age, peaking in older adulthood. It also occurs in children, but at a lower level compared with older age groups. Here, we conducted this work to investigate how the gut microbiota composition changed in different age phases of MDD patients, and found some age-specific differential gut microbiota in Figure 8. Differential taxa (at the genus level) with AUC>0.7 in diagnosing MDD patients from HCs. (A–C) the diagnostic performances of three taxa in diagnosing young MDD patients (n=25) from young HCs (n=27); (D–H) the diagnostic performances of five taxa in diagnosing middle-aged MDD patients (n=45) from middle-aged HCs (n=44). www.aging-us.com 2770 AGING Figure 9. 16S rRNA gene sequencing reveals changes to microbial abundances at family level (Mean±SEM). (A) the abundances of four taxonomic levels were significantly changed between young HCs (n=27) and middle-aged HCs (n=44); (B) the abundances of six taxonomic levels were significantly changed between young MDD patients (n=25) and middle-aged MDD patients (n=45). Figure 10. 16S rRNA gene sequencing reveals changes to microbial abundances at genus level (Mean±SEM). (A) the abundances of five taxonomic levels were significantly changed between young HCs (n=27) and middle-aged HCs (n=44); (B) the abundances of nine taxonomic levels were significantly changed between young MDD patients (n=25) and middle-aged MDD patients (n=45). www.aging-us.com 2771 AGING MDD patients. Our results could provide a new perspective on exploring the pathogenesis of MDD. Many previous studies focused on the effects of gut microbiota on brain functions [21, 22]. However, few studies have taken the effects of age on gut microbiota into consideration when exploring the pathogenesis of MDD. Our previous study found that the relative abundances of Bacteroidetes and Actinobacteria were significantly decreased and increased, respectively, in MDD patients as compared with HCs [15]. But, in this study, we found that the relative abundances of Firmicutes and Bacteroidetes were significantly decreased and increased, respectively, in young MDD patients as compared with young HCs, and the relative abundances of Bacteroidetes and Actinobacteria were significantly decreased and increased, respectively, in middle-aged MDD patients as compared with middle- aged HCs. This disparity might be caused by the different age structures. Meanwhile, only 35 key discriminatory OTUs were significantly changed in both young (92 key discriminatory OTUs) and middle-aged (127 key discriminatory OTUs) MDD patients. Moreover, the differentially abundant bacterial taxa in young and middle-aged MDD patients were totally different at both Family level and Genus level. These results demonstrated that it was necessary to identify the age-specific differential gut microbiota in patients with MDD. As far as we known, gut microbiota composition and its function could be easily influenced by many factor, such as gender, age, life experiences, dietary habit and genetics. Mariat et al reported that the Firmicutes/Bacteroidetes ratio of the human microbiota could change with age [23]. Interestingly, here we found that the relative abundance of Firmicutes was significantly decreased in young MDD patients, but not in middle-aged MDD patients; the relative abundance of Bacteroidetes was significantly increased and decreased, respectively, in young and middle-aged MDD patients. In our previous studies, we did not analyze the potential effects of medication on gut microbiota composition in MDD patients [15, 16]. Here, due to the small samples of young group, we only used the middle-aged group to analyze the effects of Figure 11. Assessment of gut microbiota composition in non-medicated and medicated middle-aged MDD patients. (A) middle-aged HCs (n=44) and non-medicated middle-aged MDD patients (n=31) were effectively separated by the built OPLS-DA model; (B) 14 medicated middle-aged MDD patients were correctly predicted by the model. www.aging-us.com 2772 AGING medication on the gut microbiota composition. The results showed that the medication seemed to have little effects on gut microbiota composition in MDD patients. However, our findings had to be cautiously interpreted due to the relatively small samples using to analyze the effects of medication on gut microbiota composition. The relative abundance of genus Clostridium_XVIII was not found to be significantly different between MDD patients and HCs in our previous study [15]. However, in this study, we found that the relative abundance of genus Clostridium_XVIII was significantly decreased in young MDD patients compared with young HCs, while increased in middle- aged MDD patients compared with middle-aged HCs. The reason of this disparity might be that age could significantly affect the relative abundance of genus Clostridium_XVIII in MDD patients, but not HCs: i) compared to young MDD patients, the middle-aged MDD patients had a significantly higher relative abundance of genus Clostridium_XVIII; and ii) the relative abundance of genus Clostridium_XVIII was similar between young and middle-aged HCs. Meanwhile, we found that the relative abundance of genus Megamonas was significantly decreased in both middle-aged HCs and middle-aged MDD patients compared to their respective young populations. In addition, most of differential bacterial taxa were significantly decreased in middle-aged HCs compared with young HCs, but only about half of differential bacterial taxa were significantly decreased in middle- aged MDD patients compared with young MDD patients. Lozupone et al. reported that gut microbiota could not only simply determine the certain host characteristics, but also respond to signals from host via multiple feedback loops [24]. Therefore, our results suggested that age might have the different effects on the gut microbiota composition of HCs and MDD patients, and should always be considered in investigating the relationship between MDD and gut microbiota. Limitations should be mentioned here. Firstly, the number of HCs and MDD patients was relatively small, and future works were still needed to further study and support our results. Secondly, we only explored the age- specific differential changes on gut microbiota composition in patients with MDD; future studies should further investigate the functions of these identified differential gut microbiota using metagenomic technology. Thirdly, all included subjects were from the same site and ethnicity; thus, the potential site- and ethnic-specific biases in microbial phenotypes could not be ruled out, which might limit the applicability of our results [25–28]. Fourthly, only young and middle-aged groups were recruited, future studies should recruit old-aged group and children group to further identify the age-specific differential gut microbiota in the different phases of life cycle. Fifthly, we only investigated the differences in gut microbiota between HCs and MDD patients on phylum level, family level and genus level. Future studies were needed to further explore the differences on other levels, such as class level and species level. Sixthly, we did not collect information on smoking, a factor which could influence the gut microbiota composition. Future studies were needed to analyze how the smoking influenced the gut microbiota composition in the different phases of life cycle of subjects. Finally, we found that the medication status of subjects could not significantly affect our results. However, limited by the relatively small samples, this conclusion was needed future studies to further validate. In conclusion, in this study, we found that there were age-specific differential changes on gut microbiota composition in patients with MDD, and identified some age-specific differentially abundant bacterial taxa in MDD patients. Our findings would provide a novel perspective to uncover the pathogenesis underlying MDD, and potential gut-mediated therapies for MDD patients. Limited by the small number of subjects, the results of the present study were needed future studies to validate and support. MATERIALS AND METHODS Subject recruitment This study was approved by the Ethical Committee of Chongqing Medical University and conformed to the provisions of the Declaration of Helsinki. In total, there were 27 young HCs (aged 18-29 years) and 25 young MDD outpatients (aged 18-29 years) in the young group; there were 44 middle-aged HCs (aged 30-59 years) and 45 middle-aged MDD outpatients (aged 30- 59 years) in the middle-aged group. Most of MDD patients were first-episode drug-naïve depressed subjects. There were only seven young MDD patients and 14 middle-aged MDD patients receiving medications. The detailed information of these included subjects was described in Table 1. All HCs were recruited from the Medical Examination Center of Chongqing Medical University, and all MDD patients were recruited from the psychiatric center of Chongqing Medical University. MDD patients were screened in the baseline interview by two experienced psychiatrists using the DSM-IV (Diagnostic and Statistical Manual of Mental Disorders, 4th Edition)-based Composite International Diagnostic Interview (CIDI, version2.1). The Hamilton Depression Rating Scale (HDRS) was used to assess the depressive symptoms of each patient, www.aging-us.com 2773 AGING Table 1. Demographic and clinical characteristics of MDD patients and HCsa. Young group (18-29 years) Middle-aged group (30-59 years) HC MDD p-value HC MDD p-value Sample Size 27 25 – 44 45 – Age (years)c 24.96±2.31 24.0±3.74 0.26 47.16±8.07 44.96±7.76 0.19 Sex (female/male) 19/8 18/7 0.89 34/10 31/14 0.37 BMI 21.53±2.37 22.13±2.24 0.35 23.23±2.33 22.64±2.64 0.26 Medication (Y/N) 0/27 7/18 – 0/44 14/31 – HDRS scores 0.29±0.61 22.64±3.18 <0.00001 0.34±0.74 23.0±4.61 <0.00001 aAbbreviations: HDRS: Hamilton Depression Rating Scale; HCs: healthy controls; MDD: major depressive disorder; BMI: body mass index. and those patients with HDRS score >=17 were included. Meanwhile, MDD patients were excluded if they had other mental disorders, illicit drug use or substance abuse, and were pregnant or menstrual women. HCs were excluded if they were with mental disorders, illicit drug use or systemic medical illness. All the included subjects provided written informed consent before sample collection. 16s rRNA gene sequencing We used the standard PowerSoil kit protocol to extract the bacterial genomic DNA from the fecal samples. Briefly, we thawed the frozen fecal samples on ice and pulverized the samples with a pestle and mortar in liquid nitrogen. After adding MoBio lysis buffer into the samples and mixing them, the suspensions were centrifuged. The obtained supernatant was moved into the MoBio Garnet bead tubes containing MoBio buffer. Subsequently, we used the Roche 454 sequencing (454 Life Sciences Roche, Branford, PA, USA) to extract the bacterial genomic DNA. The extracted V3-V5 regions of 16S rRNA gene were polymerase chain reaction- amplified with bar-coded universal primers containing linker sequences for pyrosequencing [29]. The Mothur 1.31.2 (http://www.mothur.org/) was used to quality-filtered the obtained raw sequences to identify unique reads [30]. Raw sequences met any one of the following criteria were excluded: i) less than 200bp or greater than 1000bp; ii) contained any ambiguous bases, primer mismatches, or barcode mismatches; and iii) homopolymer runs exceeding six bases. The remaining sequences were assigned to operational taxonomic units (OTUs) with 97\% threshold, and then taxonomically classified according to Ribosomal Database Project (RDP) reference database [31]. We used these taxonomies to construct the summaries of the taxonomic distributions of OTUs, and then calculated the relative abundances of gut microbiota at different levels. The abovementioned procedure and most of data were from our previous studies [15, 16]. Statistical analysis Richness was one of the two most commonly used alpha diversity measurements. Here, we used two different parameters (Chao1 and ACE) to estimate the OTU richness [32, 33]. The orthogonal partial least squares discriminant analysis (OPLS-DA) was a multivariate method, which was used to remove extraneous variance (unrelated to the group) from the sequencing datasets. The LEfSe was a new analytical method for discovering the metagenomic biomarker by class comparison. The bacterial taxa with LDA score>2.0 were viewed as the differentially abundant bacterial taxa responsible for the differences between different groups. Here, both OPLS- DA [34, 35] and LEfSe were used to reduce the dimensionality of datasets and identify the differentially abundant bacterial taxa (the Family level and Genus level) that could be used to characterize the significant differences between HCs and MDD patients. Meanwhile, we used the Random Forest algorithm to identify the critical discriminatory OTUs. The ROC curve analysis was used to assess the diagnostic performance of these identified differential bacterial taxa. The AUC was the evaluation index. Finally, we used the LEfSe to reveal the changes of microbial abundances at Family level and Genus level in HCs and MDD patients, respectively. ACKNOWLEDGMENTS Our sincere gratitude is extended to Professors Delan Yang and Hua Hu from Psychiatric Center of the First Affiliated Hospital of Chongqing Medical University for their efforts in sample collection. CONFLICTS OF INTEREST The authors declare no financial or other conflicts of interest. http://www.mothur.org/ www.aging-us.com 2774 AGING FUNDING This work was supported by the National Key R&D Program of China (2017YFA0505700), the Non-profit Central Research Institute Fund of Chinese Academy of Medical Sciences (2019PT320002300), the Natural Science Foundation Project of China (81820108015, 81701360, 81601208, 81601207), the Chongqing Science and Technology Commission (cstc2017jcyjAX0377), the Chongqing Yuzhong District Science and Technology Commission (20190115), and supported by the fund from the Joint International Research Laboratory of Reproduction & Development, Institute of Life Sciences, Chongqing Medical University, Chongqing, China, and also supported by the Scientific Research and Innovation Experiment Project of Chongqing Medical University (CXSY201862, CXSY201863). REFERENCES 1. Yirmiya R, Rimmerman N, Reshef R. Depression as a microglial disease. Trends Neurosci. 2015; 38:637–58. https://doi.org/10.1016/j.tins.2015.08.001 PMID:26442697 2. Pan JX, Xia JJ, Deng FL, Liang WW, Wu J, Yin BM, Dong MX, Chen JJ, Ye F, Wang HY, Zheng P, Xie P. Diagnosis of major depressive disorder based on changes in multiple plasma neurotransmitters: a targeted metabolomics study. Transl Psychiatry. 2018; 8:130. https://doi.org/10.1038/s41398-018-0183-x PMID:29991685 3. Zhao H, Du H, Liu M, Gao S, Li N, Chao Y, Li R, Chen W, Lou Z, Dong X. Integrative proteomics–metabolomics strategy for pathological mechanism of vascular depression mouse model. J Proteome Res. 2018; 17:656–69. https://doi.org/10.1021/acs.jproteome.7b00724 PMID:29190102 4. Stringaris A. Editorial: what is depression? J Child Psychol Psychiatry. 2017; 58:1287–89. https://doi.org/10.1111/jcpp.12844 … ORIGINAL ARTICLE Gut microbiome remodeling induces depressive-like behaviors through a pathway mediated by the host’s metabolism P Zheng1,2,3,8, B Zeng4,8, C Zhou1,2,3,8, M Liu1,2,3, Z Fang1,2,3, X Xu1,2,3, L Zeng1,2,3, J Chen1,2,3, S Fan1,2,3, X Du1,2,3, X Zhang1,2,3, D Yang5, Y Yang1,2,3, H Meng6, W Li4, ND Melgiri1,2,3, J Licinio7,9, H Wei4,9 and P Xie1,2,3,9 Major depressive disorder (MDD) is the result of complex gene–environment interactions. According to the World Health Organization, MDD is the leading cause of disability worldwide, and it is a major contributor to the overall global burden of disease. However, the definitive environmental mechanisms underlying the pathophysiology of MDD remain elusive. The gut microbiome is an increasingly recognized environmental factor that can shape the brain through the microbiota-gut-brain axis. We show here that the absence of gut microbiota in germ-free (GF) mice resulted in decreased immobility time in the forced swimming test relative to conventionally raised healthy control mice. Moreover, from clinical sampling, the gut microbiotic compositions of MDD patients and healthy controls were significantly different with MDD patients characterized by significant changes in the relative abundance of Firmicutes, Actinobacteria and Bacteroidetes. Fecal microbiota transplantation of GF mice with ‘depression microbiota’ derived from MDD patients resulted in depression-like behaviors compared with colonization with ‘healthy microbiota’ derived from healthy control individuals. Mice harboring ‘depression microbiota’ primarily exhibited disturbances of microbial genes and host metabolites involved in carbohydrate and amino acid metabolism. This study demonstrates that dysbiosis of the gut microbiome may have a causal role in the development of depressive-like behaviors, in a pathway that is mediated through the host’s metabolism. Molecular Psychiatry (2016) 21, 786–796; doi:10.1038/mp.2016.44; published online 12 April 2016 INTRODUCTION Major depressive disorder (MDD) is a debilitating mental disorder affecting up to 15\% of general population and accounting for 12.3\% of the global burden of disease.1 MDD increases health- care expenditures and suicide rates.2 In recent decades, several theories have attempted to explain the pathogenesis of MDD, including neurotransmission deficiency,3 neurotrophic alterations,4 endocrine-immune system dysfunction5 and neuroanatomical abnormalities.6 As none of these theories has been universally accepted, a definitive pathogenesis of MDD remains largely elusive, and there is a pressing need to identify novel pathophy- siologic mechanisms underlying the disorder. Previously, we found that MDD was associated with obvious disturbances in peripheral and central metabolites.7–10 Interest- ingly, several altered metabolites in MDD subjects (such as hippurate, dimethylamine and dimethylglycine) are metabolic byproducts of gut microbiota.9 Moreover, previous clinical studies have reported disturbances in the gut microbiotic compositions in limited samples of heterogeneous depressed subjects with similar findings observed in animal models of depression.11–13 These preliminary studies highlight the potential association of gut microbiotic changes and the development of MDD. However, further investigation in larger, well-characterized MDD popula- tions is still required, as these previous studies have not addressed whether disturbances in gut microbiota have a causative role in the onset of MDD. In recent years, mounting evidence has demonstrated that gut microbiota can greatly influence all aspects of physiology.14 Variations in the composition of gut microbiota have been reported to have crucial roles in the pathogenesis of several enteric and metabolic diseases, such as irritable bowel syndrome, diabetes and obesity.15–19 Emerging evidence also suggests that gut microbiota can influence brain function and behavior through the ‘microbiota-gut-brain axis’.20–24 Germ-free (GF) mice, which are devoid of any bacterial contamination, have been widely used to investigate such phenomena.24 Recent studies have demon- strated that GF mice display reduced non-spatial memory, social motivation and anxiety compared with their conventionally raised specific pathogen-free (SPF) counterparts.21,23,25,26 Another recent study has described that targeted modifications in gut microbiota can correct autism spectrum disorder-related behavioral abnormalities.27 On the basis of these findings, we hypothesized that the dysbiosis of gut microbiota may be a contributory factor to the development of depression. 1Department of Neurology, The First Affiliated Hospital of Chongqing Medical University, Chongqing, China; 2Chongqing Key Laboratory of Neurobiology, Chongqing, China; 3Institute of Neuroscience and the Collaborative Innovation Center for Brain Science, Chongqing Medical University, Chongqing, China; 4Department of Laboratory Animal Science, College of Basic Medical Sciences, Third Military Medical University, Chongqing, China; 5Department of Neurology, Yongchuan Hospital, Chongqing Medical University, Chongqing, China; 6Department of Psychiatry, The First Affiliated Hospital of Chongqing Medical University, Chongqing, China and 7Mind & Brain Theme, South Australian Health and Medical Research Institute and Department of Psychiatry, School of Medicine, Flinders University, Adelaide, SA, Australia. Correspondence: Professor H Wei, Department of Laboratory Animal Science, College of Basic Medical Sciences, Third Military Medical University, Gaotanyan Street, Chongqing 400038, China or Professor P Xie, Department of Neurology, The First Affiliated Hospital of Chongqing Medical University, 1 Youyi Road, Yuzhong District, Chongqing 400016, China or Professor Julio Licinio, Mind & Brain Theme, South Australian Health and Medical Research Institute and Department of Psychiatry, School of Medicine, Flinders University, Adelaide, SA, Australia. E-mail: [email protected] or [email protected] or [email protected] 8These authors contributed equally to this work. 9These authors are co-senior authors. Received 8 June 2015; revised 15 February 2016; accepted 17 February 2016; published online 12 April 2016 Molecular Psychiatry (2016) 21, 786–796 © 2016 Macmillan Publishers Limited All rights reserved 1359-4184/16 www.nature.com/mp http://dx.doi.org/10.1038/mp.2016.44 mailto:[email protected] mailto:[email protected] mailto:[email protected] http://www.nature.com/mp In this study, we initially assessed how gut microbiota physiologically influence the psychobehavioral characteristics of GF and SPF mice. Then, using 16S rRNA gene sequencing, the gut microbial communities of 58 MDD patients and 63 healthy controls were compared to evaluate whether alterations in the gut microbiome are associated with MDD status. Furthermore, to assess whether alterations of gut microbiota have a causal role in depression-like behavior, gut microbiome remodeling was accom- plished through fecal microbiota transplantation (FMT) from either MDD patients or healthy individuals on GF mice followed by behavioral testing to assess depression-like behaviors. Finally, metagenomic and metabolomic analyses of samples from the mice harboring ‘depression microbiota’ were conducted to examine how the gut microbiome influences host metabolism. MATERIALS AND METHODS Behavioral testing The protocols of animal experimentation were reviewed and approved by the Ethical Committee of Chongqing Medical University (ECCMU, Chongqing, China) and the Third Military Medical University (Chongqing, China). Male GF Kunming mice and SPF Kunming mice were bred in the Experimental Animal Research Center at the Third Military Medical University. GF mice were kept in flexible film gnotobiotic isolators until the beginning of experiments. All animals were fed the same autoclaved chow and water ad libitum under a 12-h light-dark cycle (lights on at 0730) and a constant temperature of 21–22 °C and humidity of 55 ± 5\%. For each test, the mice were transferred to the experimental room for acclimation at least 1 h prior to behavioral testing. All tests described below were carried out by observers blind to the animal genotypes between 0800 and 1700. All behavioral tests were videotaped and quantified by a video-computerized tracking system (SMART, Panlab, Barcelona, Spain).28 Open-field test (OFT): All mice were individually tested in an open-field apparatus29 consisting of a black square base (45 × 45 cm2) with black walls (45 cm in height). A single mouse was gently placed in the corner of the chamber, and after 1 min of adaptation, all spontaneous activities were recorded for 5 min using the video-computerized tracking system. The total motion distance was used as an index of locomotor activity, while the proportion of distance spent in the center (inner 25\% of the surface area) was construed as an index of anxiety-like behavior. Y-maze: The Y-maze apparatus30 consisted of three dark gray arms (45 cm in length × 10 cm in width × 29 cm in height). Each mouse was placed at the end of one arm and allowed to freely explore the maze for 8 min. The sequence and total number of arms entered was recorded. Entry into an arm was considered valid only when all four paws of the mouse were inside that arm. The percentage of alternation was the number of triads containing entries into all three arms divided by the maximum possible number of alternations (the total number of arms entered minus 2)× 100\%. Tail suspension test (TST): Mice were individually suspended by their tails31 using adhesive tape (distance from tip of tail was 2 cm). Test sessions lasted for 6 min with the last 5 min scored for immobility. Mice that climbed on their tails were removed from further testing. Animals were considered to be immobile when they exhibited no body movement and hung passively. Forced swimming test (FST): The mice were placed individually in a Plexiglas cylinder (30 cm in height × 15 cm in diameter) filled with 15 cm water (24 ± 1 °C).32 Immobility was defined as the absence of all motion with the exception of movements required to keep the mouse’s head above water. Test sessions lasted for 6 min with the last 5 min scored for immobility. Subject recruitment and sample collection The protocols of clinical experimentation were reviewed and approved by ECCMU. Written informed consent was obtained from all recruited human subjects. Recruitment of MDD and healthy subjects was performed as previously described.7,9 Briefly, MDD diagnoses were carried out according to the Structured Psychiatric Interview using DSM-IV-TR criteria,33 and the 17-item Hamilton Depression Rating Scale was used to quantify the severity of MDD.34 MDD candidates were excluded on the basis of substance abuse in addition to pregnancy, nursing or current menstruation for female subjects. Healthy controls were excluded on the basis of a history of systemic medical illness or mental disorders or family history of any psychiatric disorder. A total of 58 MDD patients and 63 demographi- cally matched healthy controls were recruited from the psychiatric center and medical examination center of the First Affiliated Hospital at Chongqing Medical University, respectively. The majority of MDD subjects (n = 39) were drug-naive, while the remaining MDD subjects (n = 19) were being treated with various anti-depressants. All MDD subjects and healthy controls who were using antibiotics or prebiotics were excluded. The detailed characteristics of these recruited subjects are shown in Supplementary Table S1. Fecal sample collection and 16S rRNA gene sequencing Fecal samples were collected from the recruited subjects or FMT model, frozen immediately following collection and stored at − 80 °C prior to analyses. Fecal samples were pulverized with a mortar and pestle in liquid nitrogen, and bacterial genomic DNA was extracted by the standard Power Soil Kit protocol. Briefly, the fecal samples were thawed on ice. The MoBio lysis buffer was added to these fecal samples, which were further vortex mixed. Fecal suspensions were centrifuged and the supernatant placed into the MoBio Garnet bead tubes containing MoBio buffer. Roche 454 sequencing (454 Life Sciences Roche, Branford, PA, USA): The V3-V5 regions of the 16S rRNA gene extracted from the fecal samples of recruited subjects and cecum samples from recipient mice at 2 weeks post FMT were PCR-amplified with barcoded universal primers containing linker sequences for 454-pyrose-quencing.35 Illumina MiSeq sequencing (San Diego, CA, USA): The V4-V5 regions of the 16S rRNA gene extracted cecum samples from recipient mice at 1 week post FMT were PCR-amplified with primers containing linker sequences for Illumina MiSeq sequencing.36 16S rRNA gene sequencing analysis Raw sequences obtained from 454 sequencing were quality-filtered using Mothur (Version 1.31.2, http://www.mothur.org/) to obtain unique reads.37 Sequences of less than 200 bp and greater than 1000 bp as well as sequences containing any primer mismatches, barcode mismatches, ambiguous bases and homopolymer runs exceeding six bases were excluded. Raw sequences obtained from MiSeq sequencing were quality- filtered using QIIME (version 1.17) with the following criteria: (i) 300-bp reads were truncated at any site receiving an average quality score of less than 20 over a 50-bp sliding window and discarding the truncated reads that were shorter than 50 bp; (ii) exact barcode matching, two-nucleotide mismatch in primer matching and reads containing ambiguous characters were removed; and (iii) only sequences that overlapped longer than 10 bp were assembled according to their overlap sequence. All remaining sequences were assigned to operational taxonomic units (OTUs) with a 97\% threshold of pairwise identity and then classified taxonomically using the RDP reference database (http://www.mothur.org/ wiki/RDP_reference_files).38 These taxonomies were used to construct summaries of the taxonomic distributions of OTUs, which can then be applied to calculate the relative abundances of microbiota at different levels. Alpha diversity was calculated by four different parameters: (i) observed species; (ii) Shannon Index; (iii) phylogenetic diversity and (iv) Simpson.39,40 Distance matrices (Beta diversity) between samples were generated on the basis of weighted (Bray-Curtis similarity) and non- weighted (unweighted UniFrac) algorithms and reported according to principal coordinate analysis (PCoA).41 To perform the UniFrac analysis, representative sequences for each OTU were aligned using PyNAST, and a phylogenetic tree from this alignment was constructed with Fast Tree.42 Random Forest algorithm was carried out to identify the key discriminatory OTUs,43 which assigns an importance score to each OTU by estimating the increase in error caused by removing that OTU from the set of predictors. FMT Fecal samples from randomly chosen MDD patients (n = 5, male, age 27–61 years) and healthy controls (n = 5, male, age 29–62 years) were used to colonize the guts of GF mice. The procedures of preparing the fecal samples for microbiota transplantation were as described in a previous study.16 Briefly, fecal samples were handled under anaerobic conditions. Each fecal sample (0.1 g) was suspended with 1.5 ml of reduced sterile phosphate-buffered saline, and pools were made from equal volumes of donor suspensions. Adult (6–8-week-old) male GF Kunming mice were colonized with pooled samples derived from either MDD patients or healthy controls. The ‘depression microbiota’ and the ‘healthy microbiota’ Altered gut microbiome induces depression P Zheng et al 787 © 2016 Macmillan Publishers Limited Molecular Psychiatry (2016), 786 – 796 http://www.mothur.org/ http://www.mothur.org/wiki/RDP_reference_files http://www.mothur.org/wiki/RDP_reference_files recipient mice were separately bred in different gnotobiotic isolators to prevent normalization of gut microbiota. Within each individual gnotobiotic isolator, either ‘depression microbiota’ or ‘healthy microbiota’ recipient mice were bred in different cages (five mice per cage). The weights of the mice were measured at the beginning of FMT experimentation and immediately prior to killing of the mice. The behavioral tests (including OFT, FST and TST) were performed on weeks 1 and 2 after microbiota transplantation. Cecal samples were collected at the time the mice were killed and immediately snap-frozen in liquid N2 and stored at − 80 °C. Comparisons of metabolite profiles from the FMT model On week 2 post FMT, the depressed and control mice were killed, and cecum, serum and hippocampus samples were obtained. These samples were subsequently extracted and analyzed by gas chromatography-mass spectrometry (Agilent 7890A/5975C (Agilent Technologies, Santa Clara, CA, USA)), liquid chromatography-mass spectrometry (Agilent 6538 UHD and Accurate-Mass Q-TOF/MS) and nuclear magnetic resonance (Bruker AVANCE II 600, Bruker Biospin, Rheinstetten, Germany), based metabolo- mics platforms. Gas chromatography-mass spectrometry metabolite profiles were processed according to our previously published work.44 The resulting three-dimensional matrix—including peak indices (RT-m/z pairs), sample names (observations) and normalized peak area percentages—were introduced into SIMCA-P 12.0 (Umetrics, Umeå, Sweden). Multivariate statistical methods, such as partial least squares discriminant analysis (PLS- DA), were used to identify differential metabolites between groups.45 The differential metabolites were identified using a statistically significant threshold of variable influence on projection values obtained from the PLS- DA model and a two-tailed Student’s t-test. Metabolites with variable influence on projection values of greater than 1.0 and P-values of less than 0.05 were deemed statistically significant.46 The Human Metabolome Database was used to comprehensively analyze the differential metabo- lites in terms of in vivo metabolic activity. Nuclear magnetic resonance-based metabolomics analysis of cecum samples: a 70-mg fecal sample was extracted with 700 μl of phosphate buffer solution (phosphate-buffered saline, 0.1 M, pH 7.4). Then, 400 μl samples of supernatant were mixed with 200 μl of phosphate-buffered saline. After centrifugation at 12 000 r.p.m. for 10 min, 500 μl samples of supernatant were transferred into 5-mm nuclear magnetic resonance tubes. The proton spectra were collected on a 600 Spectrometer operating at 599.925 MHz 1H frequency. A standard NOESYPR1D pulse sequence was used (recycle delay-90o-t1-90o-tm-90o-acquire free induction decay). PLS- DA was used to visualize discrimination between healthy controls and MDD subjects.45 The coefficient loading plots of the model were used to identify the spectral variables responsible for sample differentiation on the scores plot. A correlation coefficient (|r|) of greater than 0.500 was used as the cutoff value for statistical significance based on a P-value of 0.05. Liquid chromatography-mass spectrometry-based metabolomics analy- sis of cecum samples: an 80-μl aliquot of serum sample was mixed with 240 μl of methanol. Then, 0.01 g of hippocampal tissue was extracted with 1000 μl of buffer (chloroform/methanol = 2:1). The extracted supernatants of serum and hippocampus were subjected to Agilent 6538 UHD and Accurate-Mass Q-TOF/MS. Spectra were collected in both positive and negative ESI mode. PLS-DA were used to identify differential metabolites in GF mice relative to SPF mice.45 The differential metabolites were identified with variable influence on projection values of greater than 1.0 and P-values of less than 0.05. Shotgun metagenomic analysis of cecum samples Samples were sequenced by Illumina HiSeq2500. Raw datasets of PE read files were run through Trimmomatic (v0.32) to remove low-quality base pairs and sequence adapters using these parameters [SLIDINGWIN- DOW:4:15 MINLEN:36].47 Trimmed reads were filtered using the Fastq quality filter program (Fastx toolkit v0.0.13.2 ) with the parameters [-q 10 -p 10].48 MetaPhlAn v1.7.8 and Bowtie2 v2.2.1 were used for profiling the taxonomic clades in the high-quality metagenomic datasets.49,50 The paired-end and singleton reads were assembled using an IDBA-UD v1.1.1 assembler.51 The open reading frames of the assembled scaffold sequence were annotated using Prodigal v2.60 gene finder with the parameter [-p meta].52 Bowtie2 v2.2.1 aligner was used to map the reads to the assembled scaffold. The method for estimating the abundance of each predicted open reading frame from a sample has been previously described.53 KEGG Orthology was assigned through BLAST (BLASTP v2.2.29+) search against the KEGG GENES Database v58 and eggNOG v3.0 database with an E-value cutoff of 1e-5. Bitscore (greater than or equal to 60) and minimum alignment length (greater than or equal to 15 aa) were then used to filter the blast hits.54 Linear discriminant analysis was used to identify the differential KEGG pathway and KEGG enzyme commission number (E.C.s) representation between fecal microbiomes of the humanized depressed and healthy control mice.55 RESULTS Absence of gut microbiota produces decreased immobility time in the FST We initially assessed how the absence of gut microbiota physiologically influences psychobehavioral characteristics by comparing GF mice with SPF mice. From the OFT, representative motion tracks for a GF mouse and a SPF mouse are presented in Figures 1a and b. We found no difference in total motion distance between GF and SPF mice (Figure 1c). In contrast, the proportion of central motion distance was significantly increased in GF mice relative to SPF mice (Figure 1d), suggesting reduced anxiety-like behavior in GF mice. In the Y-maze spontaneous alternation test, the alternation percentage was significantly decreased in GF mice relative to SPF mice, indicating that GF mice displayed better memory performance compared with SPF mice (Figure 1e). In the FST, immobility time is widely used as an index of depression-like behavior. Here, we found that GF mice displayed decreased depression-like behavior as evidenced by a significantly decreased immobility time (Figure 1f). Expanding on previous studies that have observed altered anxiety and memory states from changes in gut microbiotic composition,56–58 we have for, we believe, the first time found that the absence of gut microbiota decreases immobility time in the FST, suggesting a potential link between the ‘microbiota-gut-brain axis’ and depression-like behavior. MDD patients exhibit significant alterations in their gut microbiomes Given clinical metabonomic observations of metabolic distur- bances generated from changes in gut microbiota in addition to murine studies showing that the absence of gut microbiota influences depression-like behavior, we next sought to determine whether MDD patients displayed disturbances in their gut microbiomes. The stool samples, as well as demographic and clinical data, from 58 MDD patients and 63 demographically matched healthy controls were collected. The detailed character- istics of these recruited subjects are shown in Supplementary Table S1. There were no significant differences in their key demographic characteristics (Supplementary Table S2). A culture-independent, 16S ribosomal RNA gene-sequence- based approach was used to compare the gut microbial commu- nities of MDD patients and healthy controls. DNA was extracted from their fecal samples. V3-V5 variable region of bacterial 16S rRNA genes was PCR-amplified. Samples were multiplexed and pyrose- quenced, followed by quality filtering and chimera checking. We obtained a total of 854 639 high-quality 16S rRNA gene sequences (7063± 2352 reads/fecal sample, Supplementary Table S3), which were subsequently clustered into OTUs at a 97\% similarity level. The majority of these OTUs belonged to only two phyla (Firmicutes and Bacteroidetes; 83.1 ± 11.9\%). Initially, the within-sample (α) phylogenetic diversity analysis showed that there were no significant difference between the two groups (Supplementary Figures S1a–d; Supplementary Table S4). In addition, the unweighted UniFrac analysis—which focuses on the degree of microbial phylogenetic similarity (β-diversity)—was used to determine the degree by which the gut microbiota within MDD subjects differed from those within healthy controls. The three-dimensional plots of unweighted UniFrac analysis showed an obvious difference in the gut microbial community Altered gut microbiome induces depression P Zheng et al 788 Molecular Psychiatry (2016), 786 – 796 © 2016 Macmillan Publishers Limited compositions between MDD patients and healthy controls (Figure 2a). A similar discrimination between MDD and healthy control group was also observed using weighted UniFrac analysis (Supplementary Figure S2). These differences in the gut microbiomes were not significantly related to any key categorical variables (that is, sex, smoking status and antidepres- sant use, Supplementary Figures S3a–e) nor to any key continuous variables (that is, age and body mass index, Supplementary Figures S4a and b). To identify the gut microbiota primarily responsible for discriminating MDD subjects from healthy controls, we applied a Random Forests classifier, which assigns an importance score to each OTU by estimating the increase in error caused by removing that OTU from the set of predictors. A total of 54 OTUs whose relative abundance reliably distinguished MDD and healthy control samples were identified (Figure 2b, Supplementary Table S5). Of these 54 differential OTUs, a total of 29 OTUs were overrepresented in MDD subjects and assigned to the families of Figure 1. Effect of gut microbiota on mood-related behavior. (a, b) Representative motion tracks for a germ-free (GF) mouse and a specific pathogen-free (SPF) mouse. (c) Open-field test (OFT): the total motion distance was measured to assess locomotor activity. There was no difference in total motion distance between GF and SPF mice (n = 22/GF group; n = 15/SPF group). (d) OFT: the proportion of central motion distance was quantified to assess anxiety-like behavior. GF mice displayed an increased proportion of central motion distance relative to SPF mice (n = 22/GF group; n = 15/SPF group). (e) Y-maze test: alternation rate of GF mice was significantly decreased compared with SPF mice (n = 17/GF group; n = 20/SPF group). (f) Forced swimming test (FST): GF mice displayed decreased depression-like behavior as evidenced by a significant decreased immobility time (n = 21/GF group; n = 15/SPF group). Data presented as means ± standard errors of the mean. **Po0.01, ***Po0.001 by t-test. Altered gut microbiome induces depression P Zheng et al 789 © 2016 Macmillan Publishers Limited Molecular Psychiatry (2016), 786 – 796 Actinomycineae, Coriobacterineae, Lactobacillaceae, Streptococ- caceae, Clostridiales incertae sedis XI (Parvimonas), Eubacteria- ceae, Lachnospiraceae (Anaerostipes, Blautia, Dorea, Lachnospiracea incertae sedis), Ruminococcaceae (Clostridium IV) and Erysipelotrichaceae incertae sedis, while a total of 25 OTUs were overrepresented in healthy control subjects and assigned to the families of Bacteroidaceae, Rikenellaceae (Alistipes), Lachnospiraceae (Coprococcus, Clostridium XlVa, Lachnospiracea incertae sedis, Roseburia and Faecalibacterium), Acidaminococcaceae (Phascolarctobacterium), Veillonellaceae (Megamonas) and Sutterellaceae. Those discriminative OTUs were mainly assigned to the phyla Firmicutes (45/56, 76.7\%), Actino- bacteria (5/56, 10.9\%) and Bacteroidetes (3/56, 5.3\%). Compared with healthy controls, the relative abundances of Actinobacteria were increased in MDD subjects, while those of Bacteroidetes were decreased (Figure 2c, Supplementary Figures S5a and b). Although there were no significant differences in the overall relative abundances of Firmicutes between MDD patients and healthy controls (Figure 2c, Supplementary Figure S5c), change of Firmicutes was still one of hallmark in MDD. This is because some members of the Firmicutes OTUs (24/56) were increased in MDD patients, while others were decreased (Supplementary Table S5). In sum, we observed that MDD was associated with a disturbance in the gut microbiome characterized by alterations in specific OTUs assigned to the phyla Firmicutes, Actinobacteria and Bacteroidetes. Transplantation of MDD patient microbiota induces depression- like behaviors in GF recipient mice To investigate whether changes in gut microbiome contribute to the pathogenesis of MDD, FMT experiments were performed.59 This approach has been successfully used to determine the causative role of gut microbiota in the onset of obesity, colitis and Figure 2. 16S rRNA gene sequencing reveals changes to microbial diversity in MDD. (a) Three-dimensional principal coordinate analysis (PCoA) of unweighted UniFrac distances showed an obvious difference in gut microbiotic composition between major depressive disorder (MDD) patients and healthy controls (n = 58/MDD, red plots; n = 63/HC, blue plots). The percentage of variation explained by principal coordinates is marked on the axes. (b) Heatmap of the 54 discriminative operational taxonomic units (OTUs) abundances between depressed subjects and healthy … © 2018 Chen et al. This work is published and licensed by Dove Medical Press Limited. 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Neuropsychiatric Disease and Treatment 2018:14 647–655 Neuropsychiatric Disease and Treatment Dovepress submit your manuscript | www.dovepress.com Dovepress 647 O r i g i N a l r e s e a r c h open access to scientific and medical research Open access Full Text article http://dx.doi.org/10.2147/NDT.S159322 sex differences in gut microbiota in patients with major depressive disorder Jian-jun chen1–4 Peng Zheng2,3 Yi-yun liu2,3 Xiao-gang Zhong2,3 hai-yang Wang2,3 Yu-jie guo2,3 Peng Xie2,3 1institute of life sciences, 2Department of Neurology, First affiliated hospital, 3institute of Neuroscience, 4Joint international research laboratory of reproduction and Development, chongqing Medical University, chongqing, china Objective: Our previous studies found that disturbances in gut microbiota might have a causative role in the onset of major depressive disorder (MDD). The aim of this study was to investigate whether there were sex differences in gut microbiota in patients with MDD. Patients and methods: First-episode drug-naïve MDD patients and healthy controls were included. 16S rRNA gene sequences extracted from the fecal samples of the included subjects were analyzed. Principal-coordinate analysis and partial least squares-discriminant analysis were used to assess whether there were sex-specific gut microbiota. A random forest algorithm was used to identify the differential operational taxonomic units. Linear discriminant-analysis effect size was further used to identify the dominant sex-specific phylotypes responsible for the differences between MDD patients and healthy controls. Results: In total, 57 and 74 differential operational taxonomic units responsible for separating female and male MDD patients from their healthy counterparts were identified. Compared with their healthy counterparts, increased Actinobacteria and decreased Bacteroidetes levels were found in female and male MDD patients, respectively. The most differentially abundant bacte- rial taxa in female and male MDD patients belonged to phyla Actinobacteria and Bacteroidia, respectively. Meanwhile, female and male MDD patients had different dominant phylotypes. Conclusion: These results demonstrated that there were sex differences in gut microbiota in patients with MDD. The suitability of Actinobacteria and Bacteroidia as the sex-specific biomarkers for diagnosing MDD should be further explored. Keywords: major depressive disorder, MDD, gut microbiota, biomarker Introduction Major depressive disorder (MDD) is a mental disorder characterized by loss of interest in normally enjoyable activities, low self-esteem, and low energy. This disease imposes a huge economic burden on the whole society. The pathogenesis of MDD is still unclear, and there are no objective diagnostic methods or 100\%-effective treatment methods.1,2 Many factors, such as genetics, biochemical or neurophysiological changes, and psychosocial variables, are associated with MDD.3,4 Recently, many researchers have attempted to explain its pathogenesis using neuroanatomical abnormalities, neurotransmission deficiency, and neurotrophic alterations.5 However, none of these theories has been universally accepted. Therefore, there is an urgent need to identify novel pathophysiologic mechanisms underlying MDD. A previous study reported that gut microbiota could influence all aspects of physi- ology.6 Many diseases have been found to be related to disturbed gut microbiota, such as obesity and diabetes.7,8 Researchers have also found that gut microbiota had an influence on brain function and behavior through the microbiota–gut–brain axis.9,10 Our previous study proved that gut microbiota could influence the expression levels of correspondence: Peng Xie Department of Neurology, First Affiliated hospital, chongqing Medical University, 1 Yixueyuan road, Yuzhong, chongqing 400016, china Tel +86 23 6848 5490 Fax +86 23 6848 5111 email [email protected] Journal name: Neuropsychiatric Disease and Treatment Article Designation: Original Research Year: 2018 Volume: 14 Running head verso: Chen et al Running head recto: Gut-microbiota sex differences in MDD DOI: 159322 http://www.dovepress.com/permissions.php https://www.dovepress.com/terms.php http://creativecommons.org/licenses/by-nc/3.0/ https://www.dovepress.com/terms.php www.dovepress.com www.dovepress.com www.dovepress.com http://dx.doi.org/10.2147/NDT.S159322 https://www.facebook.com/DoveMedicalPress/ https://www.linkedin.com/company/dove-medical-press https://twitter.com/dovepress https://www.youtube.com/user/dovepress mailto:[email protected] Neuropsychiatric Disease and Treatment 2018:14submit your manuscript | www.dovepress.com Dovepress Dovepress 648 chen et al genes in the hippocampi of mice.11 Meanwhile, our previous metabolomic studies showed an interesting phenomenon wherein several differential metabolites in MDD patients were the metabolic byproducts of gut microbiota.12,13 More- over, clinical studies have reported disturbed gut microbiota in limited samples of depressed patients.14,15 Based on these results, we conducted a further study, and found that the dysbiosis of gut microbiota might be a contributory factor in the development of MDD.16 Nowadays, the disproportionate prevalence of MDD in women might be the most consistent finding among studies on MDD. In our previous study, compared to healthy con- trols (HCs), the relative abundance of Bacteroidetes and Actinobacteria were found to be significantly changed in patients with MDD.16 However, possible sex differences in gut microbiota were not taken into consideration. Actu- ally, our previous metabolomic study found that there were divergent urinary metabolic phenotypes between males and females with MDD.17 Yurkovetskiy et al reported that hormonal regulation of microbe-controlling mechanisms could result in differences in microbial composition between males and females.18 Moreover, a recently published study reported that there were sex-specific transcriptional signa- tures in human depression.19 Therefore, we hypothesized that there were sex differences in gut microbiota in patients with MDD, and conducted this study to identify sex-specific gut microbiota. Patients and methods subject recruitment The protocol of this study was reviewed and approved by the ethical committee of Chongqing Medical University (Chongqing, China). The methods were carried out in accordance with approved guidelines and regulations. The 17-item Hamilton Depression Rating Scale (HDRS-17) was used to assess depression severity.20 Two experienced psychiatrists studying and treating depression for several years systematically used the HDRS-17 to diagnose each participant. MDD patients who met the following criteria were included: $18 years old, first-episode drug-naïve, and without obesity, diabetes, substance abuse, preexisting physical diseases, or other mental disorders. HCs did not have any previous lifetime history of Diagnostic and Statis- tical Manual of Mental Disorders IV axis I/II neurological diseases or systemic medical illness. MDD patients receiving nonpharmacologic treatments were also excluded. Subjects using antibiotics or probiotics were excluded. Pregnant, nursing, or currently menstruating candidates were excluded. All subjects recruited provided written informed consent. MDD patients and HCs were recruited from the psychiatric center and medical examination center, respectively. 16s rrNa gene sequencing Fecal samples were collected and stored at -80°C prior to analysis. The standard PowerSoil kit protocol was used to extract bacterial genomic DNA. Briefly, the frozen samples were thawed on ice and then pulverized with a pestle and mor- tar in liquid nitrogen, we added MoBio lysis buffer to these fecal samples and then mixed them, and after centrifuging, we placed the obtained supernatant into MoBio garnet-bead tubes containing MoBio buffer. Extracted V3–V5 regions of the 16S rRNA gene from these fecal samples were ampli- fied by polymerase chain reaction with bar-coded universal primers containing linker sequences for pyrosequencing.21 The 454 sequencing system (Hoffman-La Roche, Basel, Switzerland) was used. 16s rrNa gene-sequencing analysis In order to obtain unique reads, Mothur 1.31.2 was used to quality-filter the raw sequences obtained from 454 sequencing.22 Sequences meeting any one of the follow- ing criteria were excluded: ,200 bp or .1,000 bp, contained any bar-code mismatches, primer mismatches, or ambiguous bases, and contained homopolymer runs exceeding six bases. Finally, the remaining sequences were assigned to operational taxonomic units (OTUs) and then taxonomically classified using RDP reference database.23 To calculate the relative abundance of gut microbiota at different levels, summaries of taxonomic distributions of OTUs were constructed using these taxonomies. Four parameters (observed species, phylo- genetic diversity, Shannon index, Simpson index) were used to calculate α-diversity.24 β-Diversity was reported accord- ing to principal-coordinate analysis (PCoA).25 Meanwhile, both PCoA and partial least squares-discriminant analysis (PLS-DA) were used to find out whether MDD patients could be separated from HCs. A random forest algorithm was used to identify the differential OTUs responsible for sample differentiation. Cytoscape 3.2.1 software was used to analyze the potential relationship between demographic data and differential OTUs. Finally, the linear discriminant- analysis effect size (LEfSe) was further used to identify the dominant sex-specific phylotypes responsible for differences between MDD patients and HCs.26 Results Demographic data A total of 24 first-episode drug-naïve female MDD patients and 24 demographically matched female HCs were recruited. www.dovepress.com www.dovepress.com www.dovepress.com Neuropsychiatric Disease and Treatment 2018:14 submit your manuscript | www.dovepress.com Dovepress Dovepress 649 gut-microbiota sex differences in MDD The average ages of these MDD patients and HCs were 41.5±11.53 and 43.95±12.11 years (P=0.475), respec- tively. These MDD patients (22.01±2.17 kg/m2) and HCs (22.63±2.43 kg/m2) had similar average body-mass index (BMI; P=0.356). The average HDRS scores of these MDD patients were 23.04±4.93. Meanwhile, 20 first-episode drug-naïve male MDD patients and 20 demographically matched male HCs were recruited. The average ages of these MDD patients and HCs were 40.35±11.05 and 42.80±15.13 years (P=0.562), respectively. These MDD patients (22.22±2.18 kg/m2) and HCs (22.50±2.25 kg/m2) had similar average BMI (P=0.694). The average HDRS scores of these MDD patients were 23.9±3.68. Three female and two male MDD patients had coexisting anxiety disorders. Disturbed gut microbiota The majority of the obtained OTUs belonged to four phyla (female vs male): Firmicutes (73\% vs 75.2\%), Bacteroidetes (10\% vs 9.7\%), Actinobacteria (6.5\% vs 6.8\%), and Pro- teobacteria (4.8\% vs 5.3\%). The results of within-sample (α) phylogenetic diversity analysis showed no significant differences between MDD patients and HCs. The results of PCoA showed that gut microbial community composition was significantly different between female MDD patients and HCs (Figure 1A). The PLS-DA model showed similar results (Figure 1B). Meanwhile, the PCoA and PLS-DA models also showed significant differences in gut microbial community composition between male MDD patients and HCs (Figure 2). Differential gut microbiota A random forest classifier was used to identify the key dis- criminatory OTUs responsible for separating MDD patients from HCs. In total, 57 OTUs whose relative abundance could reliably distinguish female MDD patients from female HCs were identified. Of these differential OTUs, the 29 increased OTUs in female MDD patients were mainly assigned to the families of Coriobacteriaceae, Lachnospiraceae, and Ruminococcaceae, and the 28 decreased OTUs were mainly assigned to the families of Lachnospiraceae and Ruminococ- caceae (Figure 3). These differential OTUs were mainly assigned to the phyla Firmicutes (45 of 57, 78.9\%), Acti- nobacteria (six of 57, 10.5\%), and Bacteroidetes (three of 57, 5.3\%). Meanwhile, 74 OTUs whose relative abundance could reliably distinguish male MDD patients from HCs were identified. Of these differential OTUs, the 21 increased OTUs in male MDD patients were mainly assigned to the families of Lachnospiraceae and Erysipelotrichaceae, and the decreased 53 OTUs were mainly assigned to the families of Lachnospiraceae and Ruminococcaceae (Figure 4). The phyla these were mainly assigned to were Firmicutes (62 of 74, 83.8\%), Actinobacteria (three of 74, 4\%), and Bacteroidetes (six of 74, 8.1\%). Compared with female HCs, the relative abundance of Actinobacteria was increased in female MDD patients. Compared with male HCs, the relative abundance of Bacteroidetes was decreased in male MDD patients. Dominant phylotypes Dominant phylotypes responsible for the differences between MDD patients and HCs were identified by the metagenomic Figure 1 Obvious differences in gut microbial composition between female MDD patients and hcs. Notes: (A) Three-dimensional principal-coordinate analysis; (B) partial least squares-discriminant analysis. Abbreviations: MDD, major depressive disorder; hcs, healthy controls. www.dovepress.com www.dovepress.com www.dovepress.com Neuropsychiatric Disease and Treatment 2018:14submit your manuscript | www.dovepress.com Dovepress Dovepress 650 chen et al Figure 2 Obvious differences in gut microbial composition between male MDD patients and hcs. Notes: (A) Three-dimensional principal-coordinate analysis; (B) partial least squares-discriminant analysis. Abbreviations: MDD, major depressive disorder; hcs, healthy controls. Figure 3 heat map of differential operational taxonomic unit abundance between female MDD patients and hcs. Notes: assignment of each operational taxonomic unit provided at right. green and red indicate increase and decrease, respectively. Abbreviations: MDD, major depressive disorder; hcs, healthy controls. LEfSe approach. LEfSe is a new method for metagenomic biomarker discovery by way of class comparison. In total, 22 bacterial clades with statistically significant and biologically consistent differences in female MDD patients were identi- fied (Figure 5A). The most differentially abundant bacterial taxa in female MDD patients belonged to Actinobacteria. At the genus level, Actinomyces, Bifidobacterium, Asacchar- obacter, Atopobium, Eggerthella, Gordonibacter, Olsenella, Eubacterium, Anaerostipes, Blautia, Roseburia, Faecali- bacterium, and Desulfovibrio, which were most abundant in female MDD patients, and Howardella, Sutterella, and Pyramidobacter, which were most abundant in female HCs, were the key phylotypes that contributed to the different gut microbiota between female MDD patients and HCs (Figure 5B). Meanwhile, six bacterial clades with statistically significant and biologically consistent differences in male MDD patients were identified (Figure 6A). The most differentially abundant bacterial taxa in male MDD patients belonged to Bacteroidia (Bacteroidetes). At the genus level, Bacteroides, Erysip- elotrichaceae incertae sedis, Veillonella, and Atopobium, which were most abundant in male MDD patients, and www.dovepress.com www.dovepress.com www.dovepress.com Neuropsychiatric Disease and Treatment 2018:14 submit your manuscript | www.dovepress.com Dovepress Dovepress 651 gut-microbiota sex differences in MDD Anaerovorax, Gordonibacter, and Pyramidobacter, which were most abundant in male HCs, were the key phylotypes that contributed to the different gut microbiota between male MDD patients and HCs (Figure 6B). correlation analysis CoNet 1.1 (Cytoscape application) was used to evaluate correlations among the demographic data and relative abundance of bacterial genera (Figure 7). For female MDD patients, six genera (Asaccharobacter, Clostridium XIVa, Erysipelotrichaceae incertae sedis, Streptococcus, Faeca- libacterium, and Lachnospira incertae sedis) were nega- tively correlated with age, three genera (Clostridium XIVa, Erysipelotrichaceae incertae sedis, and Streptococcus) were negatively correlated with HDRS score, and one genus (Streptococcus) was negatively correlated with BMI. For male MDD patients, one genus (Erysipelotrichaceae incertae sedis) was negatively correlated with age, two genera (Veillonella and Collinsella) were negatively and positively, respectively, correlated with HDRS score, and Figure 4 heat map of differential operational taxonomic unit abundance between male MDD patients and hcs. Notes: assignment of each operational taxonomic unit provided at right. green and red indicate increase and decrease, respectively. Abbreviations: MDD, major depressive disorder; hcs, healthy controls. Figure 5 Taxonomic differences in gut microbiota in female subjects. Notes: (A) Bacterial clades (25) with statistically significant and biologically consistent differences in female MDD patients and HCs (LDA score .2); (B) MDD-enriched taxa indicated by positive lDa scores (green), and hc-enriched taxa indicated by negative scores (red). Abbreviations: MDD, major depressive disorder; hcs, healthy controls; lDa, linear discriminant analysis. www.dovepress.com www.dovepress.com www.dovepress.com Neuropsychiatric Disease and Treatment 2018:14submit your manuscript | www.dovepress.com Dovepress Dovepress 652 chen et al two genera (Dorea and Lachnospira incertae sedis) were positively correlated with BMI. These results showed that only three key phylotypes (Erysipelotrichaceae incertae sedis, Asaccharobacter, and Faecalibacterium) were negatively correlated with age and one key phylotype (Veillonella) was negatively correlated with HDRS, while other key phylotypes showed no correlation with demographic data. Discussion In total, 57 female-specific and 74 male-specific differential OTUs were identified. Among these OTUs, only 18 differential OTUs (mainly assigned to the phyla Firmicutes, 14 of 18, 77.8\%) were present in both female and male MDD patients. The relative abundance of Actinobacteria and Bacteroidetes was increased and decreased in female and male MDD patients compared to their healthy counterparts, respectively. Moreover, the most differentially abundant bacterial taxa belonged to Actinobacteria in female MDD patients and Bacteroidia (phyla Bacteroidetes) in male MDD patients. The dominant phylotypes in female and male MDD patients were also different. These results demonstrated that there were sex differences in gut microbiota in patients with MDD, Figure 7 associations among demographic data (age, BMi, and hDrs) and gut microbiota. Notes: (A) Female and (B) male MDD patients. red lines indicate positive relationships, green lines negative relationship, and circles: red, demographic data; green, Asaccharobacter; blue, Clostridium XiVa; orange, erysipelotrichaceae incertae sedis; dark orchid, Faecalibacterium; yellow, lachnospiraceae incertae sedis; deep sky blue, Streptococcus; crimson, Collinsella; light green, Dorea; pink, Veillonella; olive, others. Abbreviations: BMi, body-mass index; hDrs, hamilton Depression rating scale; MDD, major depressive disorder. Figure 6 Taxonomic differences in gut microbiota in male subjects. Notes: (A) Twelve bacterial clades with statistically significant and biologically consistent differences in male MDD patients and HCs (LDA score .2); (B) MDD-enriched taxa indicated by positive lDa scores (green), and hc-enriched taxa indicated by negative scores (red). Abbreviations: MDD, major depressive disorder; hcs, healthy controls; lDa, linear discriminant analysis. www.dovepress.com www.dovepress.com www.dovepress.com Neuropsychiatric Disease and Treatment 2018:14 submit your manuscript | www.dovepress.com Dovepress Dovepress 653 gut-microbiota sex differences in MDD and the suitability of Actinobacteria and Bacteroidia as the sex-specific biomarkers for diagnosing MDD should be further evaluated. Our previous study found that the relative abundance of Bacteroidetes and Actinobacteria was significantly decreased and increased, respectively, in MDD patients.16 The purpose of this previous study was to investigate whether the dysbiosis of the gut microbiome played a causal role in the development of depressive-like behaviors. Therefore, sex-based differ- ences were not taken into consideration. However, sex- based differences are prominent in affective disorders.27–29 Our previous metabolomic studies also found sex-specific differential metabolites in MDD and bipolar disorder.17,30 Therefore, when separately analyzing the differential gut microbiota in female and male MDD patients, we found that the Bacteroidetes level was only significantly decreased in male MDD patients and the Actinobacteria level only signifi- cantly increased in female MDD patients. Moreover, in order to rule out the potential influence of antidepressants on gut microbiota, only drug-naïve MDD patients were recruited, which might make our conclusion more robust in identifying sex-specific gut microbiota. A previous study reported a general underrepresentation of Bacteroidetes related with depression.14 However, Jiang et al found that Bacteroidetes levels were increased in MDD patients.15 In this study, decreased Bacteroidetes levels were found in male MDD patients. Meanwhile, Jiang et al also reported the decreased phyla Firmicutes level and increased phyla Actinobacteria level in MDD patients. However our results showed that increased Actinobacteria levels were only found in female MDD patients, and the overall rela- tive abundance of Firmicutes was not significantly changed in female or male MDD patients. This disparity might be caused by the sex factor. Additionally, the differences in demographic and clinical characteristics of the recruited MDD patients, sample sizes, and/or statistical methods used to identify MDD-associated gut microbiota might also have a role in this disparity. However, these results consistently showed that MDD was linked to distinct alterations in gut microbial compositions. In clinical practice, depression and metabolic-disease comorbidity, such as diabetes and obesity, is common.31 Previous studies have shown that low Bacteroidetes levels were associated with obesity.32,33 Stunkard et al reported a link between depression and obesity through low-grade inflam- mation.34 Meanwhile, Troseid et al established a correlation between low-grade inflammation and bacteria.35 Therefore, in order to rule out the potential influence of obesity and diabetes, we excluded subjects with either. Finally, the difference in BMI between MDD patients and HCs was almost negligible. Moreover, the correlation analysis also showed that there was no correlation between any key phy- lotypes and BMI. It is unlikely that obesity or diabetes could be a confounding factor in this study. Although no significant differences in the overall abun- dance of Firmicutes between HCs and MDD patients were identified in this study, some Firmicutes OTUs in both female and male MDD patients were increased, while others were decreased. Therefore, the disturbed Firmicutes could still be a hallmark in MDD.16 Moreover, the correlation analysis found that the relative abundance of seven genera (Clostridium XIVa, Erysipelotrichaceae incertae sedis, Streptococcus, Dorea, Faecalibacterium, Lachnospira incertae sedis, and Veillonella) belonging to Firmicutes showed correlations with age, HDRS score, and BMI. A previous study reported that there was a negative relationship between the sever- ity of depressive symptoms and the relative abundance of Faecalibacterium,15 but in this study only the negative relationship between the severity of depressive symptoms and the relative abundance of four other genera (Clostridium XIVa, Streptococcus, Erysipelotrichaceae incertae sedis, and Veillonella) was identified. These different results might also be caused by the sex factor. In addition, a positive relation- ship between the severity of depressive symptoms and the relative abundance of Collinsella in male MDD patients was found here. Schnorr and Bachner reported a reduction in Actinobacteria levels after intervention, mainly from the loss of Collinsella.36 As such, Collinsella might also be a useful index for the clinical management and treatment of MDD. The brain can alter gut function, and is widely acknowl- edged. However, it is less readily accepted that signals from the gut can influence brain function. Actually, gut microbiota could regulate the size and composition of bile-acid pool size, and in turn be an important regulator of the blood– brain barrier and hypothalamic–pituitary–adrenal axis.37 Meanwhile, metabolites from the gut microbiota have a significant effect on regulating the gut–brain axis and host immunity.38 Gut microbiota can also regulate brain func- tion by influencing tryptophan metabolism39 and influence the development and activity of brain tissue by regulating microglia homoeostasis.40 In addition, Sobko et al found that Lactobacillus could convert nitrate to nitric oxide, which is a potent regulator of the immune and nervous systems.41 Previous studies have reported that L. rhamnosus and L. acidophilus might have an analgesic action on the host by inhibiting the spinal neuron cellular memory of the distension.42,43 www.dovepress.com www.dovepress.com www.dovepress.com Neuropsychiatric Disease and Treatment 2018:14submit your manuscript | www.dovepress.com Dovepress Dovepress 654 chen et al Limitations Limitations should be noticed here. First, the number of recruited samples was relatively small, and the results of this exploratory research need future studies to verify and support them. Second, an animal experiment was not per- formed to determine whether Actinobacteria or Bacteroi- detes could be potential targets for MDD treatment. Third, a previous study reported that dietary habits could influence gut microbiota,44 but the relationship between dietary intake and gut microbial compositions could not be analyzed here, because of missing detailed dietary information. However, our findings were not likely to be significantly influenced by this potential confounding factor, because of the similar lifestyles and dietary habits of the recruited samples from Chongqing. Fourth, all recruited subjects were from the same place, and thus ethnic biases and site-specificity in microbial phenotypes could not be ruled out. Fifth, we did not measure estrogen levels in female patients, but Baker et al reported that gut microbiota could regulate estrogen levels through secretion of β-glucuronidase.45 Future studies should explore the potential relationship between estrogen levels and gut microbiota. Finally, we did not analyze depressive episode duration, although previous a study found that there was evidence for the interplay between immune and endocrine systems in drug-naïve MDD patients with short-illness- duration first affective episodes.46 Conclusion This study firstly determined that there were sex differences in gut microbiota in patients with MDD and identified gender- specific gut microbiota. The most differentially abundant bacterial taxa in female and male MDD patients belonged to Actinobacteria and Bacteroidia, respectively. These findings could provide new insights for uncovering the pathogenesis of MDD and studying potential gut-mediated therapies for MDD. However, due to the risk of overseeing effects in small cohorts, these findings must be verified and supported in the larger cohorts. Meanwhile, future studies are warranted to evaluate the suitability of Actinobacteria and Bacteroidia as sex-specific biomarkers for diagnosing MDD. Acknowledgments This work was supported by the Natural Science Founda- tion Project of China (81701360, 81601208, 81771490), Chongqing Science and Technology Commission (cstc2017j- cyjA0207, cstc2014kjrc-qnrc10004), Science and Technol- ogy Research Program of Chongqing Municipal Education Commission (grant KJ1702037), Special Project on Natural Chronic Noninfectious Diseases (2016YFC1307200), National Key Research and Development Program of China (2017YFA0505700), and National Basic Research Program of …
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Your assignment may be more than 5 paragraphs but not less. INSTRUCTIONS:  To access the FNU Online Library for journals and articles you can go the FNU library link here:  https://www.fnu.edu/library/ In order to n that draws upon the theoretical reading to explain and contextualize the design choices. Be sure to directly quote or paraphrase the reading ce to the vaccine. Your campaign must educate and inform the audience on the benefits but also create for safe and open dialogue. A key metric of your campaign will be the direct increase in numbers.  Key outcomes: The approach that you take must be clear Mechanical Engineering Organic chemistry Geometry nment Topic You will need to pick one topic for your project (5 pts) Literature search You will need to perform a literature search for your topic Geophysics you been involved with a company doing a redesign of business processes Communication on Customer Relations. 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Furman was caught i One major ethical conflict that may arise in my investigation is the Responsibility to Client in both Standard 3 and Standard 4 of the Ethical Standards for Human Service Professionals (2015).  Making sure we do not disclose information without consent ev 4. Identify two examples of real world problems that you have observed in your personal Summary & Evaluation: Reference & 188. Academic Search Ultimate Ethics We can mention at least one example of how the violation of ethical standards can be prevented. Many organizations promote ethical self-regulation by creating moral codes to help direct their business activities *DDB is used for the first three years For example The inbound logistics for William Instrument refer to purchase components from various electronic firms. During the purchase process William need to consider the quality and price of the components. In this case 4. A U.S. Supreme Court case known as Furman v. 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