The guidelines is given below, and there are three article about nutrition, you are required to use AMA style, follow the guidelines strictly, - Management
The guidelines is given below, and there are three article about nutrition, you are required to use AMA style, follow the guidelines strictly,
that's all, the requirements are in the guideline
plz read guideline and those three paper carefully, otherwise I will not give a credit to the paper
NitN: Sample Final Paper NUT11
Word count: 792
Anemic? An Iron Fish Might Be What All You Need
Approximately 30% of the world’s population suffers from anemia.1 Anemia is a condition
where the body does not have enough of the protein called hemoglobin,2 which is the part of red
blood cells that carries oxygen to the tissues in our body.1 As a result, individuals with anemia often
experience tiredness, headaches, decreased cognitive abilities, impaired immunity, and poor
pregnancy outcomes.2 Iron deficiency is the most common cause of anemia1—referred to as iron-
deficiency anemia (IDA)—and most commonly affects women and children.2 Typically anemia is
treated with iron tablets; however, getting tablets to poor and remote villages is difficult and costs
money. Furthermore, many women find that they feel nauseated when taking iron pills, which may
discourage them from taking the supplement.
Almost 50% of the women in rural Cambodian villages experience anemia, but treatment
with iron supplements was unsuccessful.1 In the 1980s, researchers showed that cooking in iron pots
would increase the amount of iron in the food that was consumed,2 which could help prevent IDA.
As reported in the news recently, a Canadian scientist had the idea to use a lump of iron in place of
iron cookware. After many iterations of the iron-ingot, scientists finally settled on the shape of a fish
because it is a symbol of luck in Cambodian culture, and the Lucky Iron Fish project was born.1
They claim that the Lucky Iron Fish can be used to treat anemia in these Cambodian villages. When
the ingot is boiled in water or soup for at least 10 minutes some iron leaches into the liquid. Then the
iron fish is removed and lemon juice is to the food to help the body absorb the iron when the food is
consumed. They claim that using the Lucky Iron Fish every day would provide enough iron to meet
75% of the iron that a woman should consume. The news reports that several hundred Cambodian
NitN: Sample Final Paper NUT11
women tested the ingot for a year, and at the end half of the women who used the ingot weren’t
anemic anymore. They further claim that the ingot is better than supplements.
In the original research that tested the effectiveness of the Lucky Iron Fish, the researchers
actually had three different groups for their year-long study: iron-ingot, iron-ingot with basic
nutrition education, or a control that received neither.2 Ultimately, the researchers grouped both of
the iron-ingot groups together because they found that the nutrition lessons didn’t have an effect,
likely because the women that received the nutrition education couldn’t afford to purchase the foods
that the lessons encouraged them to eat. One critical piece of information that the news failed to
mention is that the women needed to add an acidifier, such as a teaspoon of citrus juice, while
boiling the ingot in plain water in order for water to make the ingot leach iron. Many Cambodian
soups contain acidic fruits, so additional juice isn’t needed in this case. Even though the Lucky Iron
Fish was tested in a smaller group that the news article reported, it actually seems to work better than
the news suggested. In the control group, the prevalence of anemia and IDA, which was measured
using blood tests, remained similar from the start to the end of the study. In the groups that received
the iron-ingot, the prevalence of anemia dropped from 57% to 11% and the prevalence of IDA
dropped from 13% to 2%. The original study didn’t directly compare to supplements, so we don’t
know if the iron-ingot works better than supplements for alleviating deficiency. Nevertheless, the
researchers didn’t notice any negative side effects, which is a benefit over supplements.
The prevalence of anemia in women in developing nations ranges from 11% in Nicaragua to
50% in Côte d’Ivoire.3 However, anemia can also be caused by other micronutrient deficiencies,
such as vitamins A and B12 or folate, repeated infections, or malaria.1 Additionally, the
inflammation that results from infection inhibits the absorption of iron,3 which may increase iron
requirements of individuals living in regions with a high burden of infection. Thus, before deciding
NitN: Sample Final Paper NUT11
whether to use the Lucky Iron Fish, health officials need to consider both the amount of anemia that
can be attributed to iron deficiency and the level of exposure to inflammation in a given region. In
countries with a high prevalence of IDA and low to moderate infection rates, the Lucky Iron Fish
could be a cost effective and successful method of treating IDA. However, the Iron Fish may not be
as effective in countries with high infection rates or multiple micronutrient deficiencies. In my
opinion, the news reporter could have added a bit more about the limitations of the Lucky Iron Fish;
however, the rest of the information provided in the news article was accurate.
References
1. Roxby P. Why an iron fish can make you stronger. BBC News.
http://www.bbc.com/news/health-32749629. Published May 17, 2015. Accessed July 29,
2017.
2. Charles CV, Dewey CE, Hall A, Hak C, Channary S, Summerlee AJS. A Randomized
Control Trial Using a Fish-Shaped Iron Ingot for the Amelioration of Iron Deficiency
Anemia in Rural Cambodian Women. Tropical Medicine & Surgery. 2015; 3(3): 195. DOI:
10.4172/2329-9088.1000195.
3. Petry N, Olofin I, Hurrell RF, et al. The Proportion of Anemia Associated with Iron
Deficiency in Low, Medium, and High Human Development Index Countries: A Systematic
Analysis of National Surveys. Nutrients. 2016; 8: 693. DOI: 10.3390/nu8110693.
ARTICLE
Received 1 Dec 2015 | Accepted 13 May 2016 | Published 24 Jun 2016
A key genetic factor for fucosyllactose utilization
affects infant gut microbiota development
Takahiro Matsuki1,*, Kana Yahagi1,*, Hiroshi Mori2,*, Hoshitaka Matsumoto1,*, Taeko Hara1, Saya Tajima1,
Eishin Ogawa3, Hiroko Kodama3, Kazuya Yamamoto2, Takuji Yamada2, Satoshi Matsumoto1,**
& Ken Kurokawa2,4,5,**
Recent studies have demonstrated that gut microbiota development influences infants’ health
and subsequent host physiology. However, the factors shaping the development of the
microbiota remain poorly understood, and the mechanisms through which these factors
affect gut metabolite profiles have not been extensively investigated. Here we analyse gut
microbiota development of 27 infants during the first month of life. We find three distinct
clusters that transition towards Bifidobacteriaceae-dominant microbiota. We observe
considerable differences in human milk oligosaccharide utilization among infant bifido-
bacteria. Colonization of fucosyllactose (FL)-utilizing bifidobacteria is associated with altered
metabolite profiles and microbiota compositions, which have been previously shown to affect
infant health. Genome analysis of infants’ bifidobacteria reveals an ABC transporter as a key
genetic factor for FL utilization. Thus, the ability of bifidobacteria to utilize FL and the
presence of FL in breast milk may affect the development of the gut microbiota in infants, and
might ultimately have therapeutic implications.
DOI: 10.1038/ncomms11939 OPEN
1 Yakult Central Institute, 5-11 Izumi, Kunitachi-shi, Tokyo 186-8650, Japan. 2 Department of Biological Information, Tokyo Institute of Technology, 2-12-1
Ookayama, Meguro-ku, Tokyo 152-8550, Japan. 3 Teikyo University School of Medicine, 2-11-1 Kaga, Itabashi-Ku, Tokyo 117-8605, Japan. 4 Earth-Life Science
Institute, Tokyo Institute of Technology, 2-12-1 Ookayama, Meguro-ku, Tokyo 152-8550, Japan. 5 National Institute of Genetics, Center for Information Biology,
Yata 1111, Mishima, Shizuoka 411-8540, Japan. * These authors contributed equally to this work. ** These authors jointly supervised this work. Correspondence
and requests for materials should be addressed to T.M. (email: [email protected]).
NATURE COMMUNICATIONS | 7:11939 | DOI: 10.1038/ncomms11939 | www.nature.com/naturecommunications 1
mailto:[email protected]
http://www.nature.com/naturecommunications
I
t is becoming increasingly apparent that the bacterial
ecosystem in our gut has a profound influence on human
health and disease. The gut microbiota contributes to immune
system maturation, energy harvesting and sympathetic nervous
system development. In particular, the composition and meta-
bolite profiles of gut microbiota have been associated with
pathogen resistance1–3, inflammatory responses4 and adiposity5,6.
Initial gut microbe colonization begins immediately after birth,
and bacterial ecosystems develop within the first few days.
Previous studies have reported that the composition of the infant
gut microbiota differs from that of adults7–9, that substantial
variation occurs between individuals6,10,11 and that bifidobacteria
predominate in most infants11–13. Recent studies also demon-
strated that environmental factors including the mode of delivery
and feeding affect the gut microbiota assemblage and that the
process is not random6,13,14. Furthermore, it has been indicated
that the gut microbiota development during infancy can have
long-lasting effects on the individual’s future health15–18.
However, little is known about their pattern of progression,
factors that drive the assembly of infant gut microbiota and how
these factors affect metabolite profiles.
Here we investigated gut microbiota compositions and
metabolic profiles for 217 stool samples obtained from 27 infants
during their first month of life (202 samples from 12 infants were
analysed longitudinally and 15 samples from 15 infants were
studied in follow-up). The dynamics and equilibria of the
developing microbiota were investigated, and their associations
with metabolites were evaluated. We subsequently analysed
phenotypes and genotypes of isolated bifidobacteria, and found
a key genetic factor affecting infant gut microbiota composition
and metabolite profile.
Results
Early development of gut microbiota. To investigate the
dynamics of gut microbiota immediately after birth, we analysed
the sequences of the V1–V2 region of the 16S rRNA genes
obtained from 12 infants born by normal delivery
(Supplementary Table 1) using the 454 GS Junior platform. We
obtained stool samples every day during the first week after birth
and every other day thereafter until 1 month of age (B17 stool
samples per infant; 202 samples in total). A total of 588,293
pyrosequencing reads (average 2,912±1,397 reads per sample;
Supplementary Table 2 and Supplementary Fig. 1) were analysed
using an open-source Quantitative Insights Into Microbial
Ecology (QIIME) software pipeline19 (Supplementary Table 3).
Figure 1a shows an age-dependent, gut microbiota composition
heatmap for each subject at the bacterial family level. The analysis
demonstrated that there are major variations in both the
composition and dynamic progression among individuals. Over-
all, the composition of the infant’s microbiota was relatively
simple, being composed of only a few dominant bacterial families.
The displacement of predominant bacteria occurred within only a
few days. We observed an increased average abundance of
Bifidobacteriaceae, a-diversities and total bacterial cell counts, as
well as decreased average abundances of Enterobacteriaceae and
Staphylococcaceae (Supplementary Fig. 2).
Characteristics of the taxonomic composition observed among
the samples were clearly distinguished by principal coordinate
analysis (PCoA) and partitioning around medoids (PAM)20 on
the basis of bacterial family composition data (Fig. 1b and
Supplementary Data 1). Values of the Calinski-Harabasz (CH)
index with PAM clustering suggest that the infant microbiota
could be divided into three clusters (Supplementary Fig. 3),
which were characterized by the predominance of Bifido-
bacteriaceae, Enterobacteriaceae or Staphylococcaceae (Fig. 1c).
We subsequently observed sequential transitions occurring
from Staphylococcaceae- to Enterobacteriaceae- and/or Entero-
bacteriaceae- to Bifidobacteriaceae-dominated microbiota, with
considerable individual variation in the day of the transition
(Fig. 1d). Transitions in the opposite direction were rarely
observed. The results suggest that the best-adapted bacterial
family in the infant gut may be Bifidobacteriaceae, followed by
Enterobacteriaceae and Staphylococcaceae.
Microbiota in 1-month-old infants. Subsequently, we performed
16S rRNA gene-library analysis using additional faecal samples;
in addition to the faecal samples from 12 infants (subjects A–L,
shown in Fig. 1 on day 29), we obtained faecal samples from their
parents (n¼22) and another 15 breast-fed infants at approxi-
mately 1 month after birth (Supplementary Tables 4 and 5). A
total of 147,010 high-quality reads (average 3,058±1,232 reads
per sample; Supplementary Data 2) were analysed, and the
resulting family composition heatmap is shown in Fig. 2a.
The results of PCoA and PAM clustering based on bacterial
family compositions suggest that the microbiota of 1-month-old
infants stratified into two clusters that were distinct from the
adult cluster (Fig. 2b and Supplementary Fig. 4). The majority of
infants (n¼18, designated as cluster B) were characterized as
having a significantly high abundance of Bifidobacteriaceae,
and the minor cluster (n¼9, designated as cluster E) had a
significantly high abundance of facultative anaerobes such as
Enterobacteriaceae, Enterococcaceae and Staphylococcaceae
(Fig. 2c and Supplementary Figs 5 and 6). The 22 adult samples
formed a single cluster (designated cluster AD), showing
significantly higher abundances of Lachnospiraceae, ‘Clostridiales
incertae sedis XIV’, Bacteroidaceae, Ruminococcaceae and
Peptostreptococcaceae, as well as higher a-diversity compared
with the two infant microbiota clusters (Fig. 2c and
Supplementary Figs 5–7).
The correlation coefficients observed between bacterial family
abundances in infant and adult microbiota are illustrated in
network diagrams (Fig. 2d and Supplementary Figs 8 and 9).
Analysis of the infant stool samples indicated that the abundance
of predominant Bifidobacteriaceae negatively correlated with
those of Enterobacteriaceae, Enterococcaceae, Clostridiaceae and
Staphylococcaceae. Furthermore, the network diagram for adults
indicated that bacterial family compositions and their associa-
tions were different from those of infants.
Bacterial lineages and gut environments. To understand how
gut microbiota affect the host’s physiology, it is important to
understand the entire gut ecosystem, not only in terms of
microbiota compositions but also in terms of the metabolites
produced by the bacteria. Therefore, we investigated the pH and
organic acid concentrations of each infant’s stool (Supplementary
Data 3) and assessed the correlation between these parameters
and bacterial family abundances (Fig. 3a and Supplementary
Fig. 10). We found that increased Bifidobacteriaceae abundance
positively correlated with organic acid concentrations and total
bacterial counts but negatively correlated with pH. In contrast,
the abundance of facultative anaerobes such as Enterobacter-
iaceae and Staphylococcaceae correlated with decreased organic
acid concentrations, decreased total bacterial counts and
increased pH (Fig. 3a), as well as decreased Bifidobacteriaceae
abundance (Fig. 2d).
Previous studies have reported that bifidobacteria produce
acetate and lactate as their metabolites1,21, and that some of these
strains (for example, Bifidobacterium longum ss. infantis ATCC
15697) can efficiently utilize some human milk oligosaccharide
(HMO) components22–25. Therefore, we hypothesized that
ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms11939
2 NATURE COMMUNICATIONS | 7:11939 | DOI: 10.1038/ncomms11939 | www.nature.com/naturecommunications
http://www.nature.com/naturecommunications
bifidobacteria consume the remaining oligosaccharides in the
infant gut, causing elevated acetate and lactate concentrations and
decreased pH. Furthermore, we examined the concentrations of
major residual HMO components in infant stools by high-
performance liquid chromatography (HPLC; Supplementary Data
3 and Supplementary Figs 11 and 12)26. As expected, HMO
consumption in the gut was associated with increased abundances
of Bifidobacteriaceae (Fig. 3a), increased organic acid
concentrations and decreased pH values (Fig. 3b). However,
some infants showed high faecal oligosaccharide concentrations
despite the presence of Bifidobacteriaceae (Fig. 3c). Therefore, we
examined the species composition of bifidobacteria in these
infants (Fig. 3c). We also analysed the oligosaccharide profiles of
breast milk provided by their mothers, and found that three
infants (subjects I29, TB16 and TB19) received breast milk from
non-secretor mothers (lacking 2’-fucosyllactose (2’-FL) and 2’,
3-difucosyllactose (DFL), Supplementary Table 6). However, we
found it difficult to explain these discordant results.
These observations prompted us to isolate bifidobacteria from
the infant faeces to assess their ability to utilize HMOs in vitro.
The 29 isolated strains were cultured in medium containing
HMOs as the carbon source and their growth was monitored
(Fig. 3d and Supplementary Figs 13 and 14). Interestingly, 14 of
the 29 strains exhibited remarkable growth in HMO medium
Subject ID
Days after birth
Enterobacteriaceae
Bifidobacteriaceae
Staphylococcaceae
Bacteroidaceae
Enterococcaceae
Porphyromonadaceae
Streptococcaceae
Clostridiaceae
Veillonellaceae
Pasteurellaceae
Lactobacillaceae
Micrococcaceae
Lachnospiraceae
Propionibacteriaceae
Peptostreptococcaceae
A B C D E F G H I J K L
2 → 29 1 → 29 1 → 29 1 → 29 1 → 29 2 → 29 5 → 29 2 → 29 3 → 29 3 → 292 → 29 2 → 29
0
10
50
100
Abundance (%)
a
EnterobacteriaceaeBifidobacteriaceaeBifidobacteriaceae-
predominant
Enterobacteriaceae-
predominant
Staphylococcaceae-
predominant
Staphylococcaceae
A
b
u
n
d
a
n
ce
(
%
)
100
50
0
100
50
0
100
50
0
a
a
c
a a
B E S
Cluster
B E S
Cluster
B E S
Cluster
b
b
b b
B
E
S
PC1(50%)
P
C
2
(1
8
%
)
Days after birthInfant
ID
J
E
F
G
I
D
L
A
H
B
C
K
– –
–
–
–
S
S S S S
S S S S S S
S
S
S S S S S
E E E E E
E E E E
E E E E E E E E E E
E E E E E E E E E E E E
E E E E E E E
E E EE E E E E E E
E E EEE E E E E E E E
E
E E EE E E
E E EE E
E E EE
E
E
E
E E E
E E E E
E E E
E E
NT NT
NT NT
NT
NT NT
NT
NT
1 2 3 4 5 6 7 9 11 13 15 17 19 21 23 25 27 29
B B B B B B B B B B B B B B B B B
B B B B B B B B B B B B B B B B B
B B B B B B B B B B B B B
B B B B B B B B B B B
B B B B B B B B B B
B B B B B B B
B B B B B
B B B B
B
B B
B B B B B B
b c
d
D19
Figure 1 | Infant gut microbiota community profiles during the first month of life. (a) Microbiota profiles in stool samples from 12 subjects (n¼202;
B17 sampling days per subject), temporally ordered from left to right. Each row represents taxonomic groups at the family level. The top 15 families are
displayed and sorted according to relative abundance. Abundances are represented using the colour scale. (b) Characteristics of infant gut microbiota,
illustrated by PCoA and PAM clustering analyses. Data from individuals (points) were clustered, and the centres of gravity (rectangles) were computed for
each class. The coloured ellipses encompass 67% of the samples in each cluster. (c) Box plots showing the relative abundances of the main contributors to
each cluster. Different letters (a–c) above the boxes indicate significant differences between clusters (Po0.05, Mann–Whitney U-test with Bonferroni’s
correction). (d) Temporal shift from Staphylococcaceae- or Enterobacteriaceae-dominant microbiota to Bifidobacteriaceae-dominant microbiota.
S, Staphylococcaceae-dominated (yellow); E, Enterobacteriaceae-dominated (blue); B, Bifidobacteriaceae-dominated (red); NT, not tested; —, sample not
provided.
NATURE COMMUNICATIONS | DOI: 10.1038/ncomms11939 ARTICLE
NATURE COMMUNICATIONS | 7:11939 | DOI: 10.1038/ncomms11939 | www.nature.com/naturecommunications 3
http://www.nature.com/naturecommunications
Taxon (family)
Enterobacteriaceae
Enterobacteriaceae
Enterobacteriaceae-
predominant
Bifidobacteriaceae
Bifidobacteriaceae
Bifidobacteriaceae-
predominant
Lachnospiraceae
Lachnospiraceae
Lachnospiraceae-, Bacteroidaceae-,
and Ruminococcaceae-predominant
Bacteroidaceae
Bacteroidaceae
Clostridiales (XIV)
Clostridiales (XIV)
Enterococcaceae
Enterococcaceae
Streptococcaceae
Veillonellaceae
Veillonellaceae
Staphylococcaceae
Staphylococcaceae
Porphyromonadaceae
Clostridiaceae
Propionibacteriaceae
Peptostreptococcaceae
Peptostreptococcaceae
Ruminococcaceae
Ruminococcaceae
Prevotellaceae
Sum of the others
Enterobacteriaceae
Enterobacteriaceae
Bifidobacteriaceae
Bifidobacteriaceae
Lachnospiraceae
Eubacteriaceae
ErysipelotrichaceaeBacteroidaceae
Bacteroidaceae
Coriobacteriaceae
Clostridiales XIV
Enterococcaceae
Streptococcaceae
Veillonellaceae
Staphylococcaceae
Porphyromonadaceae
Porphyromonadaceae
Clostridiaceae
Propionibacteriaceae
Peptostreptococcaceae
Ruminococcaceae
Prevotellaceae
Other(clostlidiales)
T
B
1
4
T
B
0
6
T
B
2
1
T
B
1
5
T
B
1
0
T
B
2
0
T
B
2
9
Jd
2
9
G
d
2
9
m
o
A
m
o
B
m
o
D
m
o
E
m
o
L
m
o
F
m
o
H
fa
G
fa
D
fa
F
fa
J
fa
B
fa
A
fa
H
fa
K
fa
C
m
o
l
m
o
K
fa
E
fa
l
fa
L
m
o
J
E
d
2
9
T
B
0
3
T
B
0
9
T
B
1
6
T
B
2
5
T
B
2
6
T
B
1
9
T
B
0
5
L
d
2
9
B
d
2
9
D
d
2
9
Id
2
9
F
d
2
9
C
d
2
9
K
d
2
9
A
d
2
9
H
d
2
9
T
B
0
7
0
10
50
100
Abundance (%)
A
b
u
n
d
a
n
ce
(
%
)
A
b
u
n
d
a
n
ce
(
%
)
A
b
u
n
d
a
n
ce
(
%
)
100
50
0
B E AD B E AD B E AD
B E ADB E ADB E AD
B E AD B E AD B E AD
80
40
0
70
35
0
40
20
0
60
40
20
0
30
20
10
0
40
20
0
20
10
0
10
5
0
a
b
c a
b
c a
b
c
a a
b
a a
b
a
a
b
a
a
b
a a
b
Cluster Cluster Cluster
E
AD
B
P
C
2
(2
7
%
)
PC1(43%)
Abundance (average)
>30% >10% >1%
Correlation
>0.6 < –0.6
< –0.5
< –0.4
< –0.3
>0.5
>0.4
>0.3
Infant
Adult
a
b
d
c
Figure 2 | Gut microbiota community profiles of 27 1-month-old infants and 22 adults. (a) Bacterial families representing more than 1% (on average) of
the microbiota in infants or adults are shown on the colour scale. Samples were hierarchically clustered by measuring Euclidean distances with complete-
linkage clustering, as shown in the upper tree. (b) Characteristics of infant and adult gut microbiota, as illustrated by PCoA and PAM clustering analyses.
Cluster B, Bifidobacteriaceae-predominant; cluster E, Enterobacteriaceae-predominant; cluster AD, adult-type microbiota. (c) Abundances of the main
contributors to each cluster. Different letters (a–c) indicate significant differences between clusters (Po0.05, Mann–Whitney U-test with Bonferroni’s
correction). Differences in other bacterial families are shown in Supplementary Fig. 7). (d) Network diagram showing co-occurrence relationships among
the main contributors in infants and adults. Node sizes indicate the abundances of each bacterial family, and the widths of the edges reflect the calculated
Spearman’s rank correlation coefficient.
ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms11939
4 NATURE COMMUNICATIONS | 7:11939 | DOI: 10.1038/ncomms11939 | www.nature.com/naturecommunications
http://www.nature.com/naturecommunications
Enterobacteriaceae
Enterobacteriaceae
Bifidobacteriaceae
Bifidobacteriaceae
Bacteroidaceae
Bacteroidaceae
Enterococcaceae
Streptococcaceae
Veillonellaceae
Staphylococcaceae
Porphyromonadaceae
Clostridiaceae
Correlation coefficient
–1.0 0 1.0
Propionibacteriaceae
Organic acids (mM) HMO (mM)
A
ve
ra
g
e
±
s
.d
.
54±39
21±24
5.1±15
4.4±9
4.2±7.6
2.6±8.5
2.4±4.3
2.4±5.3
1.1±2.4
1.1±2.6
A
ce
ta
te
(
3
0
.5
±
3
5
.3
)
L
a
ct
a
te
(
1
2
.9
±
3
1
)
F
L
(
2
8
.8
±
2
8
.2
)
L
N
T
+
L
N
n
T
(
3
.5
±
5
.2
)
L
N
F
P
+
L
N
D
F
H
(
2
4
.7
±
1
7
.5
)
S
u
cc
in
a
te
(
8
.9
±
1
2
)
T
o
ta
l a
ci
d
s
(5
4
.7
±
6
5
.1
)
T
o
ta
l H
M
O
(
5
7
±
4
1
.7
)
N
o
.
o
f
b
a
ct
e
ri
a
(
L
o
g
1
0
.2
±
0
.4
)
p
H
(
5
.9
±
0
.6
)
–0.53 0.47 0.67
0.61 0.54 0.57–0.67–0.49
–0.43
–0.49
–0.43
0.45
0.46
0.47
0.44 –0.42 0.48
0.46 0.51–0.49 –0.60 –0.47
–0.46 –0.58
–0.58
–0.390.59
–0.59 –0.48 –0.40 –0.56
0.50
0.39
0.33
0.36
0.35–0.32
–0.15 –0.34 0.35 0.33 0.20 0.34
–0.31
–0.040.160.00–0.08–0.230.320.210.120.32
–0.15–0.29–0.24–0.140.200.34–0.06
–0.13 0.02 0.20 0.11 0.39 0.32
0.29
0.38
0.31 –0.25 –0.15
–0.22 –0.13 –0.18 –0.21 0.13 0.22 0.29
0.380.31–0.03–0.03
–0.23
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0.400.250.10–0.25–0.330.25
0.09 0.26
180
120
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0 50 100 150 0 50 100 150
HMO (mM) HMO (mM)
7.5
6.5
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� = –0.77
P < 0.01
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1.2
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0 10 20 30 40
Incubation (h)
B. longum ss. infantis
B. longum ss. longum
B. longum
B. pseudocatenulatum
B. kashiwanohense
B. ps'catenulatum
B. breve
B. breve
B. dentium
B. bifidum
B. dentium
B. bifidum
O
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6
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a b
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Figure 3 | Relationships between bacterial family abundances and gut environments. (a) Spearman’s rank correlation coefficients between bacterial
family abundances and gut environmental factors such as pH, organic acid concentrations and faecal oligosaccharide concentrations are shown in
numerical and colour-scale formats. (b) Spearman’s rank correlations of oligosaccharide concentrations with pH values and acetate concentrations.
(c) Relationships between bacterial abundances, faecal oligosaccharide concentrations and the relative abundances of bifidobacterial species. The upper
tree shows hierarchical clustering on the basis of the bacterial family compositions. (d) Growth curves of 29 bifidobacterial strains in medium containing
HMOs (see Supplementary Fig. 14 for more details). (e) Glycoprofiles of bacterial supernatants after 40 h of cultivation. Samples are ordered based on
their OD600 values after 40 h of cultivation.
NATURE COMMUNICATIONS | DOI: 10.1038/ncomms11939 ARTICLE
NATURE COMMUNICATIONS | 7:11939 | DOI: 10.1038/ncomms11939 | www.nature.com/naturecommunications 5
http://www.nature.com/naturecommunications
(saturating OD60040.7), but 15 strains did not (saturating
OD600o0.3). Culture supernatants were collected to investigate
the remaining oligosaccharides. Although most bifidobacterial
strains utilized lacto-N-tetraose (LNT), there were considerable
differences in the utilization of fucosyllactose (sum of 20-FL,
3-fucosyllactose and DFL), which is the main component of
HMOs27,28 (Fig. 3e and Supplementary Fig. 15). These results
indicated that efficient FL utilization is not a universal property of
infant bifidobacteria and is instead strain-dependent.
Bifidobacterial genomes and FL utilization. To gain insight into
how the strains showed differences in FL utilization, we deter-
mined the draft genomes of all 29 strains (Table 1 and
Supplementary Table 7) and subsequently performed OrthoMCL
clustering analysis using bi-directional BLAST alignments
(Supplementary Fig. 16a). Initially, we investigated the presence
of fucosidase genes (glycoside hydrolase family classifications:
GH95 and GH29) and confirmed that all strains exhibiting robust
growth in an HMO-containing medium possessed at least one
fucosidase gene (Table 1 and Supplementary Fig. 16b). However,
we found that 6 out of 15 strains showing limited growth in the
HMO-containing medium possessed a fucosidase gene. We
analysed the phylogeny and subcellular localization of the fuco-
sidase genes. We found that most fucosidases, except for that of
B. bifidum BI-14, are intracellular enzymes, with only minor
sequence differences occurring between FL-utilizing and non-FL-
utilizing strains (Supplementary Fig. 17).
Subsequently, we searched for other genes responsible for FL
utilization and discovered that the presence of a homologous
group (HG_2571) corresponded with the FL-utilization pheno-
type in all strains, except for B. bifidum BI-14 (Table 1 and
Supplementary Fig. 16c). BLAST searches against the KEGG
database indicated that the homologous sequences were highly
similar to substrate-binding protein (SBP), which participates in
the multiple-sugar ABC transporter system (KEGG entry K02027;
Supplementary Fig. 16c). Furthermore, we found that two
permease genes of the multiple-sugar ABC transporter system
(K02025 and K02026) and the fucosidase gene (GH95) were
adjacent to the SBP gene in most strains (Fig. 4a). On the basis of
these findings, we hypothesized that the ABC transporter
mediates FL transportation into bacterial cells. This hypo-
thesis could explain the absence of the transporter in the
B. bifidum BI-14 strain, which utilizes FL because that strain
expresses extracellular membrane-bound fucosidases (Supple-
mentary Fig. 17).
To determine whether the putative ABC transporter SBP for FL
(denoted FL-SBP) mediates FL utilization, the gene was knocked
out in B. breve BR-A29 using homologous recombination
(Supplementary Fig. 18). After confirming that the FL-SBP gene
was knocked out, growth of the knockout strain was investigated
in the HMO medium. In contrast with the original BR-A29 strain,
the FL-SBP gene-knockout strain showed limited growth in the
HMO medium (Fig. 4b). Furthermore, we confirmed that FL was
not utilized by the FL-SBP gene-knockout strain (Fig. 4c),
demonstrating that the FL-SBP is responsible for FL utilization.
HMO-utilizing bifidobacteria affect gut ecosystems. Having
identified the differences in FL utilization among bifidobacteria,
we subdivided the Bifidobacteriaceae-dominated microbiota
(cluster B) into those colonized by FL-utilizing bifidobacteria
(designated cluster B1; n¼11) and those dominated with non-
FL-utilizing bifidobacteria (cluster B2; n¼7; Supplementary
Fig. 19). Furthermore, we compared the faecal organic acids,
pH, HMO and microbiota compositions of these two subgroups
with those of Enterobacteriaceae-dominated microbiota (cluster
E; n¼9). Compared with clusters B2 and E, cluster B1 showed
significantly higher acetate concentrations and lower pH and
residual oligosaccharide concentrations (Po0.05, Mann–
Whitney U-test with Bonferroni’s correction; Fig. 5 and
Supplementary Fig. 20). In addition, cluster B1 had significantly
higher Bifidobacteriaceae and lower Enterobacteriaceae abun-
dances. In contrast, there were no significant differences in faecal
acetate concentrations, pH or oligosaccharide concentrations
between clusters B2 and E.
Discussion
Gut microbiota development in healthy, full-term infants has
been investigated using culture-based enumeration29, molecular
analysis with 16S rRNA gene-targeting primers or probes10–12,30,
or, more recently, using metagenomic approaches8,9,13,31. These
intensive observational studies have demonstrated that the
modes of delivery10,13, feeding10,13,29 and use of antibiotics12
can influence the development of the infants’ microbiota. In
addition, recent investigations have suggested that maternal
HMO secretion type31, environmental exposures10,14 and
bacterial transmission and propagation30 can also alter the
Table 1 | Summary of the draft genomes of the 29 bifidobacterial strains.
Strains Genome size (Mbp) No. of CDSs Growth with
HMO (OD60040.7)
a-L-fucosidase HG_2571
GH29 GH95 SBP of ABC
transporter
B. breve BR-06, BR-10, BR-14, BR-15,
BR-20, BR-21, BR-A29, BR-I29 (eight strains)
2.2–2.7 1,928–2,368 þ � þ þ
B. breve BR-07, BR-19, BR-C29, BR-H29,
BR-L29 (five strains)
2.2–2.5 1,955–2,224 � � þ �
B. longum ss. infantis IN-07, IN-F29
(two strains)
2.6–2.7 2,356–2,441 þ þ þ þ
B. longum ss. longum LO-06, LO-10, LO-21,
LO-C29, LO-K29a, LO-K29b (six strains)
2.4–2.7 1,987–2,209 � � � �
B. pseudocatenulatum CA-C29, CA-K29a,
CA-K29b (three strain)
2.2–2.5 1,825–2,168 þ � þ þ
B. pseudocatenulatum CA-05, CA-B29,
CA-D29 (three strains)
2.2–2.3 1,896–1,904 � � � �
B. bifidum BI-14 2.2 1,779 þ þ þ �
B. dentium DE-29 2.6 2,127 � þ � �
HMO, human milk oligosaccharide; SBP, substrate-binding protein.
ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms11939
6 NATURE COMMUNICATIONS | 7:11939 | DOI: 10.1038/ncomms11939 | www.nature.com/naturecommunications
http://www.nature.com/naturecommunications
assemblage of infants’ microbiota. However, the overall
understanding of gut microbiota development is still limited
because of the small number of subjects studied9, the low
frequency of sample analysis8,13,31 and/or the limitations in the
enumeration methods used10–12. In addition, metabolite profiles,
bacterial strain isolation and related phenotype and genotype
Strain
FL
utilization
IN-F29
IN-07
CA-C29
CA-K29b
CA-K29a
…
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Date:
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Summary:
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Early diet of infants, not maternal obesity, influences
development of gut microbiome
February 11, 2016
American Society for Microbiology
After the age of nine months, the development of the infant gut microbiota is driven by the
transition to family foods, not maternal obesity, according to results from a new study. The
gut microbiota is a complex community of microorganisms that live in the digestive tract.
Children are essentially born without microbes in their gut, and they are immediately
colonized upon birth. The next several years are critical in establishing a person's
endogenous gut microbiota.
a b e g d
FULL STORY
After the age of nine months, the development of the infant gut microbiota is
driven by the transition to family foods, not maternal obesity, according to results
from a new study. The study was published online this week in mSphere, an
open-access journal of the American Society for Microbiology.
"Our results reveal that the transition from early infant feeding to family foods is a major determinant for
gut microbiota development," said senior author Tine Rask Licht, PhD, professor and head of the
Research Group for Microbiology and Immunology, National Food Institute, Technical University of
Denmark, Soborg, Denmark. "Maternal obesity did not influence microbial diversity or specific taxon
abundances during the complementary feeding period."
The gut microbiota is a complex community of microorganisms that live in the digestive tract. Children
are essentially born without microbes in their gut, and they are immediately colonized upon birth. The
next several years are critical in establishing a person's endogenous gut microbiota. Later in life, the gut
Cite This Page:
American Society for Microbiology. "Early diet of infants, not maternal obesity, influences development of
gut microbiome." ScienceDaily. ScienceDaily, 11 February 2016.
<www.sciencedaily.com/releases/2016/02/160211142225.htm>.
microbiota can change in response to factors such as diet, but only slightly. Each adult has a very
distinct gut microbiota. "When you look at an adult's gut microbiota, it is more or less like a fingerprint,"
explained Professor Licht.
The gut microbiota is strongly affected by diet and has been linked with obesity. Children of obese
parents have a higher risk of developing obesity, and this is only partially explained by genetic
predisposition. While many previous studies have focused on the impact of early infant diet, particularly
breastfeeding, few studies have addressed the influence of maternal obesity on the infant gut microbiota,
which can occur either through microbes transmitted during birth or through the dietary habits of the
family.
To shed light on the issue, Martin Laursen, a PhD student at Technical University of Denmark, and
colleagues compared the gut microbiotas of two cohorts of infants, one born from a random sample of
healthy mothers (n=114) and the other born from obese mothers (n =113). The researchers analyzed
stool samples from the children at nine months and 18 months. By nine months, most children have
transitioned, at least partially, to a complementary diet. Microbiota data were compared to breastfeeding
patterns and detailed individual dietary recordings.
The major determinants of gut microbiota development were breastfeeding duration and composition of
the complementary diet. In both cohorts, gut microbial composition were strongly affected by introduction
of family foods with high protein and fiber contents.
"We found that introduction of family foods is the main driver of development of the complex microbial
ecosystem in the gut at age 9 months. The food determines the diversity and the composition of the
microbiota, and this is very important," said Professor Licht. "It is well known that breast feeding has a
great impact on gut microbiota, but nobody has addressed the effect of diet at this age before."
Story Source:
Materials provided by American Society for Microbiology. Note: Content may be edited for style and
length.
Journal Reference:
1. Laursen, M.F. et al. Infant Gut Microbiota Development Is Driven by Transition to Family Foods
Independent of Maternal Obesity. mSphere, February 2016 DOI: 10.1128/mSphere.00069-15
MLA APA Chicago
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Infant Gut Microbiota Development Is
Driven by Transition to Family Foods
Independent of Maternal Obesity
Martin Frederik Laursen,a Louise B. B. Andersen,b Kim F. Michaelsen,b
Christian Mølgaard,b Ellen Trolle,a Martin Iain Bahl,a Tine Rask Lichta
National Food Institute, Technical University of Denmark, Søborg, Denmarka; Department of Nutrition, Exercise
and Sports, University of Copenhagen, Frederiksberg, Denmarkb
ABSTRACT The first years of life are paramount in establishing our endogenous
gut microbiota, which is strongly affected by diet and has repeatedly been linked
with obesity. However, very few studies have addressed the influence of maternal
obesity on infant gut microbiota, which may occur either through vertically transmit-
ted microbes or through the dietary habits of the family. Additionally, very little is
known about the effect of diet during the complementary feeding period, which is
potentially important for gut microbiota development. Here, the gut microbiotas of
two different cohorts of infants, born either of a random sample of healthy mothers
(n � 114), or of obese mothers (n � 113), were profiled by 16S rRNA amplicon se-
quencing. Gut microbiota data were compared to breastfeeding patterns and de-
tailed individual dietary recordings to assess effects of the complementary diet. We
found that maternal obesity did not influence microbial diversity or specific taxon
abundances during the complementary feeding period. Across cohorts, breastfeed-
ing duration and composition of the complementary diet were found to be the ma-
jor determinants of gut microbiota development. In both cohorts, gut microbial
composition and alpha diversity were thus strongly affected by introduction of fam-
ily foods with high protein and fiber contents. Specifically, intake of meats, cheeses,
and Danish rye bread, rich in protein and fiber, were associated with increased alpha
diversity. Our results reveal that the transition from early infant feeding to family
foods is a major determinant for gut microbiota development.
IMPORTANCE The potential influence of maternal obesity on infant gut microbiota
may occur either through vertically transmitted microbes or through the dietary
habits of the family. Recent studies have suggested that the heritability of obesity
may partly be caused by the transmission of “obesogenic” gut microbes. However,
the findings presented here suggest that maternal obesity per se does not affect the
overall composition of the gut microbiota and its development after introduction of
complementary foods. Rather, progression in complementary feeding is found to be
the major determinant for gut microbiota establishment. Expanding our understand-
ing of the influence of complementary diet on the development and establishment
of the gut microbiota will provide us with the knowledge to tailor a beneficial pro-
gression of our intestinal microbial community.
KEYWORDS: 16S rRNA sequencing, breastfeeding, complementary diet, family foods,
infant gut microbiota, maternal obesity
Despite the temporal resilience and stability of the gut microbiota, long-term diet(1) and major diet shifts (2) are known to affect the human gut microbiota. Infancy
and early childhood constitute a period in life in which the microbiota is characterized
by relatively low stability and high responsiveness toward influencing factors. During
this period, dietary factors have major implications for the establishment of the gut
Received 25 November 2015 Accepted 6
January 2016 Published 10 February 2016
Citation Laursen MF, Andersen LBB,
Michaelsen KF, Mølgaard C, Trolle E, Bahl MI,
Licht TR. 2016. Infant gut microbiota
development is driven by transition to family
foods independent of maternal obesity.
mSphere 1(1):e00069-15. doi:10.1128/
mSphere.00069-15.
Editor Garret Suen, University of Wisconsin,
Madison
Copyright © 2016 Laursen et al. This is an
open-access article distributed under the terms
of the Creative Commons Attribution 4.0
International license.
Address correspondence to Tine Rask Licht,
[email protected]
Diet affects infant gut microbiota
RESEARCH ARTICLE
Host-Microbe Biology
crossmark
Volume 1 Issue 1 e00069-15 msphere.asm.org 1
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http://orcid.org/0000-0002-6399-9574
http://dx.doi.org/10.1128/mSphere.00069-15
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microbiota (3, 4). While many previous studies have focused on early infant diet (5, 6),
particularly breastfeeding and formula feeding, only a few have addressed the effects
of the complementary (solid-food) diet of infants in the period after 6 months of age
(7). As the gut microbial population is not fully established until the age of 3 to 5 years
(8, 9), it is important to understand how it is influenced by the transition from early
infant feeding to family foods during the complementary feeding period, which is
defined by the WHO as the period from 6 until 18 to 24 months of age (10). The
established adult gut microbiota has been linked with a range of metabolic, autoim-
mune, and allergic diseases (9). Specifically, the intestinal microbiome has repeatedly
been linked to obesity in animal models (11–15) as well as in human studies (16, 17).
By transplantation of fecal microbial communities from human twins discordant for
obesity into germfree mice, it has been shown that a greater increase in body mass and
adiposity occurs in mice transplanted with obese donor microbiota than with the
corresponding microbiota from the lean donor twin, suggesting the importance of gut
microbes over human genetics in the etiology of obesity (18). Indeed, children of obese
parents have a higher risk of developing obesity, and this is not explained solely by
human genetic predisposition. Since gut microbes can be transferred from mother to
infant during birth (19), an obesity-associated microbiota may be transferred from an
obese pregnant woman to her offspring. It is well documented that obese mothers on
average breastfeed for a shorter time than normal-weight mothers (20) and that
breastfeeding has a protective effect on obesity in offspring (21). Further, parental
obesity is associated with lower socio-economic status and specific dietary patterns (22)
that may affect the type of complementary diet introduced to the infant and thereby
the development of the gut microbiota (9), as well as contribute to future obesity risk
(23). Indeed, diet-microbiota interactions have been shown to be key players in the
development of obesity (18). Therefore, we compared the gut microbiota profiles of
two different cohorts of Danish infants at the ages of 9 and 18 months, designated
SKOT I (24) and SKOT II (25), respectively (SKOT is a Danish abbreviation for dietary
habits and well-being of young children). SKOT I includes infants from a random sample
of mothers (mean body mass index [BMI], 22.9 kg/m2), and SKOT II includes infants of
obese mothers (mean BMI, 35.1 kg/m2). To elucidate the impact of (i) maternal obesity
and (ii) dietary factors on infant gut microbiota development, associations between
specific features of the gut microbiota and dietary factors were investigated with a
focus on breastfeeding and complementary diet composition.
RESULTS
Gut microbiota development during the complementary feeding period is inde-
pendent of maternal obesity. To assess the impact of maternal obesity on gut
microbiota establishment in offspring, we sequenced the V3 region of 16S rRNA genes
from fecal samples of 227 individuals at both 9 and 18 months of age in the two SKOT
cohorts. These cohorts are different with respect to maternal obesity and generally
differ in terms of socio-economic status, C-section prevalence, and early infant feeding
but differ only slightly with respect to infant body composition measures (Table 1).
Between-sample diversity (beta diversity) of the gut microbiota in the two cohorts was
investigated by principal-coordinate analysis (PCoA) of the Bray-Curtis dissimilarity
indices and showed clustering according to age rather than cohort (Fig. 1A). Distances
to the group centroid for each point, as an estimate of beta diversity, illustrated no
differences between cohorts (Fig. 1A). However, greater beta diversity was observed at
9 months than at 18 months in both cohorts, in line with previous reports (26–28).
Levels of within-sample diversity (alpha diversity), as estimated by the Shannon index,
the number of observed genera, and Pielou’s evenness index of the communities, were
not significantly different between the two cohorts at either 9 months or 18 months of
age (Fig. 1B). However, there was a significant increase in these alpha diversity
measures from 9 to 18 months in both cohorts. On a compositional level, the gut
microbiotas across time and cohorts were dominated by four phyla, Firmicutes (64.2%),
Actinobacteria (23.4%), Bacteroidetes (7.7%), and Proteobacteria (4.3%), while less than
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0.5% belonged to other phyla or were unclassified. On average, 98.3% of the commu-
nities belonged to 24 bacterial families (Fig. 2). Despite large interindividual variation,
average bacterial communities assessed at the phylum level as well as at the family
level at 9 months and 18 months were highly similar between SKOT I and II (Fig. 2).
Indeed, according to PCA of family-level composition, samples clustered according to
age rather than cohort and showed the relative contributions of bacterial families to the
variation in the data set (Fig. 3A). After correction for multiple testing, we found no
significant differences between cohorts with respect to relative abundances of bacterial
phyla, families, or genera at either 9 or 18 months, and no differences in the changes
occurring from 9 to 18 months between the two cohorts were identified (Fig. 3B). In
contrast, over time, Lachnospiraceae, Ruminococcaceae, Eubacteriaceae, Rikenellaceae,
TABLE 1 Characteristics of the SKOT cohort subsets used in this studya
Parameter (unit of measure)
Value for SKOT I
(n � 114)
Value for SKOT II
(n � 113) P valueb
Mother
BMI at the infant age of 9 mo (mean kg/m2 � SD) 22.9 � 3.2 35.1 � 4.2 �0.0001 (MWT)
Work situation
Job (%) 80.7 76.1
Student (%) 14.9 8.0
No job (%) 4.4 15.9 0.007 (�2)
Education level
Basic (%) 12.3 32.7
Short (%) 11.4 12.4
Medium (%) 32.5 34.5
Long (%) 43.9 20.4 �0.0001 (�2)
Household income per yearc
�650,000 DKK (%) 44.7 49.0
�650,000 DKK (%) 55.3 51.0 0.587 (FET)
Infant
Birth
Wt for age at birth (mean Z score � SD) 0.35 � 0.84 0.81 � 1.04 0.0003 (tW)
Length for age at birth (mean Z score � SD) 1.20 � 0.96 1.65 � 1.11 0.013 (t)
BMI for age at birth (mean Z score � SD) �0.41 � 0.91 �0.08 � 1.13 0.015 (tW)
C-section prevalence (%) 13.3 33.7 0.0006 (FET)
Gestational age at birth (mean no. of wks � SD) 40.2 � 1.2 40.3 � 1.3 0.448 (t)
Sex
Male (%) 47.4 53.1
Female (%) 52.6 46.9 0.427 (FET)
Early infant feeding
Age at introduction to complementary feeding (mean no. of mos � SD) 4.4 � 0.7 4.2 � 0.6 0.0018 (MWT)
Duration of exclusive breastfeeding (mean no. of mos � SD) 3.6 � 1.8 2.6 � 2.0 0.0006 (MWT)
Total duration of breastfeeding (mean no. of mos � SD) 8.1 � 3.8 6.6 � 4.5 0.0068 (MWT)
Anthropometry
Wt for age at 9 mo (mean Z score � SD) 0.46 � 0.92 0.83 � 0.93 0.003 (t)
Length for age at 9 mo (mean Z score � SD) 0.23 � 0.90 0.88 � 0.97 �0.0001 (t)
BMI for age at 9 mo (mean Z score � SD) 0.45 � 1.03 0.46 � 0.95 0.939 (t)
Subscapularis skinfold thickness for age at 9 mo (mean Z score � SD) 0.19 � 1.24 0.39 � 0.99 0.184 (tW)
Waist circumference at 9 mo (mean cm � SD) 45.64 � 3.07 44.95 � 2.99 0.090 (t)
Wt for age at 18 mo (mean Z score � SD) 0.50 � 0.84 0.70 � 0.85 0.094 (t)
Length for age at 18 mo (mean Z score � SD) 0.07 � 0.92 0.42 � 0.97 0.006 (t)
BMI for age at 18 mo (mean Z score � SD) 0.64 � 0.97 0.63 � 0.87 0.945 (t)
Subscapularis skinfold thickness for age at 18 mo (mean Z score � SD) 0.59 � 1.11 0.82 � 1.20 0.141 (t)
Waist circumference at 18 mo (mean cm � SD) 46.83 � 2.88 46.61 � 2.52 0.550 (t)
aData are from reference 25.
bStatistical significance was evaluated by the Mann-Whitney test (MWT), the chi-square test (�2), Fischer’s exact test (FET), Student’s t test (t), and Student’s t test with
Welch’s correction (tW).
cDKK, Danish krone.
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and Sutterellaceae were significantly increased in both cohorts, and Bifidobacteriaceae,
Actinomycetaceae, Veillonellaceae, Enterobacteriaceae, Lactobacillaceae, Enterococ-
caceae, Clostridiales incertae sedis XI, Carnobacteriaceae, and Fusobacteriaceae were
significantly decreased in both cohorts (Fig. 3B; see Table S1 in the supplemental
material). This is in agreement with a previous study of the SKOT I cohort using
quantitative-PCR (qPCR)-based microbiota assessment (8) and with studies involving
other cohorts (27–30). These results suggest that maternal obesity per se does not
influence gut microbiota development during the complementary feeding period. The
high gut microbiota similarity between the two cohorts, independently sampled during
different time periods, allowed a high-powered characterization of infant gut microbi-
-0.5 -0.4 -0.3 -0.2 -0.1 0.0 0.1 0.2 0.3 0.4 0.5
-0.3
-0.2
-0.1
0.0
0.1
0.2
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SKOT I 9m
SKOT II 9m
SKOT I18m
SKOT II 18m
PC1 (11.0%)
P
C
2
(2
.3
%
)
S
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9 months 18 months
***
***
ns
ns
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9 months 18 months
ns
***
***
ns
S
ha
nn
on
in
de
x
S
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20
40
60
80
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ns
***
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ns
9 months 18 months
O
bs
er
ve
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ge
ne
ra
S
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9 months 18 months
ns
***
***
ns
P
ie
lo
u'
s
ev
en
ne
ss
in
de
x
Beta diversity
Alpha diversity
A
B
FIG 1 Gut microbial beta and alpha diversity is independent of maternal obesity but changes over time. (A) PCoA plot
based on Bray-Curtis dissimilarity, with the centroid for each group shown with a black boarder. The distance to the group
centroid for each point provides a measure of homogeneity of variance, used to estimate beta diversity. PC1 and PC2,
principal coordinates 1 and 2, respectively. (B) Alpha diversity measures as estimated by the Shannon index, observed
genera, and Pielou’s evenness index. Boxes indicate 25th to 75th percentiles, with mean values marked as a line and
whiskers indicating minimum and maximum values. ns, not significant; *, P < 0.05; **, P < 0.01; ***, P < 0.001 (according
to Tukey’s honestly significant difference test for beta diversity and paired [within cohorts, across time points] or unpaired
[across cohorts at the same time point] t tests for alpha diversity measures).
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ota development and identification of the main factors explaining variation in gut
microbiota.
Limited influence of C section, gestational age at birth, and prior use of
antibiotics. The mode of delivery (31), gestational age at birth (within a normal range
of full-term delivery) (32), and use of antibiotics (33) have all previously been shown to
impact the infant gut microbiota. In the SKOT cohorts, neither microbial community
compositions nor alpha diversity measures at 9 months were significantly different
between individuals born by C section and those born vaginally (see Table S2 in the
supplemental material). We did, however, note a decreased relative abundance of
Bacteroidaceae (P � 0.003, false-discovery-rate-corrected P values [q] � 0.072) in infants
born by C section in SKOT II (Table S2), in line with results of previous studies (27, 31,
34). Gestational age at birth was not associated with gut microbiota composition or
alpha diversity at 9 months (Table S3), and the use of antibiotics 2 weeks before the
sample was taken (current antibiotic use was an exclusion criterion) could not explain
the variation in gut microbial diversity at 9 or 18 months (Table S4). All infants in the
present study were delivered at full term (range, 37 to 42 weeks), C-section prevalence
was low in SKOT I (Table 1), and for only a few infants was the use of oral antibiotics
during the 2 weeks prior to sampling registered (10 individuals in total). Further, the
relative late sampling point (9 months of age) may explain discrepancies with prior
studies.
FIG 2 Composition of gut microbiota in SKOT I and SKOT II. Relative abundances of bacterial phyla (small panels) and families (large panels) in the SKOT
I cohort (n � 114) at the ages of 9 months (A) and 18 months (B) and in the SKOT II cohort (n � 113) at the ages of 9 months (C) and 18 months (D).
Boxes indicate 25th to 75th percentiles, with mean relative abundances marked as lines and whiskers indicating the range (minimum/maximum)
multiplied by the interquartile range (25th to 75th percentiles) from the boxes. Bacterial families are ranked by average relative abundances at the age
of 9 months. Detailed information can be found in Table S1 in the supplemental material.
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Duration of exclusive breastfeeding, rather than age at introduction of
complementary feeding, is reflected in late-infancy gut microbiota. Danish
mothers are advised to exclusively breastfeed their infants until the age of approxi-
mately 6 months and to continue partial breastfeeding until the infant is about 1 year
old. It is additionally recommended to introduce complementary foods (apart from
infant formula) at about the age of 6 months but not before the age of 4 months (35).
As we have previously reported (25), infants in the SKOT I cohort were both exclusively
and partially breastfed significantly longer than infants in the SKOT II cohort. Addition-
ally, age at the introduction of complementary foods was significantly lower in SKOT II
than in SKOT I (Table 1). Despite the fact that no infants in either of the cohorts were
exclusively breastfed beyond the age of 6 months, the recorded duration of exclusive
breastfeeding was associated with the relative abundance of specific bacterial taxa at
the age of 9 months. This was most pronounced in SKOT I, possibly due to the longer
average duration of exclusive breastfeeding in this cohort (Fig. 4A and B). However,
differences in the effects of duration of exclusive breastfeeding on microbiota between
cohorts were modest and not large enough to evoke detectable significant differences
between the two cohorts at the age of 9 months (Fig. 1 to 3). In both cohorts, the
duration of exclusive breastfeeding was negatively correlated with Lachnospiraceae
(e.g., the genera Dorea, Coprococcus, Blautia, Pseudobutyrivibrio, and Roseburia) and
genera within Ruminococcaceae (e.g., Ruminococcus, Anaerotruncus, Oscillibacter, Clos-
tridium IV, and Butyricicoccus), encompassing species known to utilize plant-derived
complex carbohydrates and resistant starch introduced with solid foods (36). Also,
Erysipelotrichaceae, Peptostreptococcaceae, and Eubacteriaceae were negatively affected
BA
SKOT I
La
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no
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-6
-4
-2
0
2
4
6
***
***
ns
*** **
***
*
**
ns
ns
ns
ns
***
**
ns
***
ns
**
ns
***
*
***
*** ***
Lo
g
2(
Fo
ld
c
ha
ng
e)
SKOT II
La
ch
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ae
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-6
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***
***
ns
*** ***
***
ns ns ns
***
**
***
***
ns
***
**
***
*
***
ns
ns
*
**
*
Lo
g
2(
Fo
ld
c
ha
ng
e)
Firmicutes
Actinobacteria
Bacteroidetes
Proteobacteria
Fusobacteria
ns
Phylum
FIG 3 Gut microbiota composition is independent of maternal obesity but changes over time. (A) PCA biplot of the relative abundances of bacterial
families at 9 and 18 months of age in SKOT I and SKOT II. Ellipses indicate 95% confidence intervals for each group, while arrows show loadings. var.,
variance. (B) Log2-transformed fold changes of relative abundances of bacterial families between the ages of 9 and 18 months within SKOT I and SKOT
II. Error bars indicate the standard error of the mean. ns, not significant; *, q < 0.05; **, q < 0.01; ***, q < 0.001 (according to false-discovery-rate-corrected
[5%] paired Wilcoxon signed-rank tests of relative abundances at 9 months versus 18 months). No significant differences were found between the fold
changes of bacterial families occurring in the two cohorts after we performed false-discovery-rate-corrected (5%) Mann-Whitney tests.
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by the duration of exclusive breastfeeding (Fig. 4A). Positive correlations with exclusive
breastfeeding were observed in both cohorts for Bifidobacteriaceae (Bifidobacterium),
which are known to utilize the lactose and human milk oligosaccharides found in breast
milk (37), and Veillonellaceae (e.g., Veillonella and Megasphaera), known lactate utilizers
(38, 39). In addition, Pasteurellaceae (Haemophilus) abundances were positively corre-
lated with the duration of exclusive breastfeeding (Fig. 4A and B). Although not
significant in both cohorts, lactic acid bacteria (Lactobacillaceae, Enterococcaceae, Strep-
tococcaceae) and other bacteria known to be present in human milk, like Prevotella (40),
and on breast tissue, like Enterobacteriaceae (Escherichia and Klebsiella) (41), were
positively correlated with duration of exclusive breastfeeding (Fig. 4A and B). At the age
of 9 months, 97 infants (nSKOT I � 59, nSKOT II � 38) were still partially breastfed.
Additionally, the estimated average daily breast milk intake at the age of 9 months was
strongly correlated with gut microbiota composition and confirmed the associations
obtained for the duration of exclusive breastfeeding (see Table S5 in the supplemental
material). Consistently with our previous report (8), the effects of breastfeeding on
microbial composition were limited at 18 months (Table S6). Some infants are fed with
infant formula as a replacement or a supplement to breastfeeding for a period prior to
the introduction of complementary foods. However, age at the introduction of com-
plementary foods (range, 3 to 6 months) did not correlate with abundances of specific
bacterial families at 9 months (Table S7). Furthermore, alpha diversity measures at
9 months were negatively correlated with the duration of exclusive breastfeeding,
whereas age of introduction to complementary feeding was generally not correlated
with alpha diversity measures, although a weak negative association with observed
Family Genus
0 1 2 3 4 5 6
0.0
0.5
1.0
1.5
2.0
2.5
3.0 rho = -0.182
p = 0.008
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bre astfe e ding (months)
S
h
an
n
o
n
in
d
e
x
≤ 3 4 5 6
0.0
0.5
1.0
1.5
2.0
2.5
3.0 rho = -0.047
p = 0.490
Age at introduction to
comple me ntary fe e ding
(months)
S
h
an
n
o
n
in
d
e
x
0 1 2 3 4 5 6
0
10
20
30
40
50
60
70 rho = -0.236
p = 0.0005
Duration of e xclusiv e
bre astfe e ding (months)
O
b
se
rv
e
d
g
e
n
e
ra
≤ 3 4 5 6
0
10
20
30
40
50
60
70 rho = -0.139
p = 0.039
Age at introduction to
comple me ntary fe e ding
(months)
O
b
se
rv
e
d
g
e
n
e
ra
0 1 2 3 4 5 6
0.0
0.2
0.4
0.6
0.8
1.0
rho = -0.144
p = 0.035
Duration of e xclusiv e
bre astfe e ding (months)
P
ie
lo
u'
s
ev
en
ne
ss
≤ 3 4 5 6
0.0
0.2
0.4
0.6
0.8
1.0
rho = -0.027
p = 0.692
Age at introduction to
comple me ntary fe e ding
(months)
P
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lo
u'
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BA C
FIG 4 Duration of exclusive breastfeeding is reflected in late-infancy gut microbiota. Hierarchical clustering of Spearman’s rank correlations of duration
of exclusive breastfeeding with gut microbial composition at 9 months of age at the family (A) and genus (B) levels in SKOT I and II. *, P < 0.05; **, P <
0.01; ***, P < 0.001. (C) Spearman’s rank correlations of alpha diversity measures (Shannon index, observed genera, and Pielou’s evenness index) to
duration of exclusive breastfeeding (0 to 6 months) and age at introduction of complementary feeding (3 to 6 months) for compiled data from SKOT I
and II. Boxes indicate 25th to 75th percentiles, with mean values marked as a line and whiskers indicating minimum and maximum values.
Transition to Family Foods Affects Gut Microbiota
Volume 1 Issue 1 e00069-15 msphere.asm.org 7
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genera at 9 months was observed (Fig. 4C). These results suggest that breastfeeding
duration, rather than the timing of introduction of complementary foods, is reflected in
gut microbiota composition during late infancy, as recently proposed in a study of gut
microbiome data from Swedish infants (27).
Composition of complementary diet during late infancy affects gut micro-
biota composition. A validated 7-day food registration was performed by the parents
when the infants were 9 months old (42). On the macronutrient level, no significant
differences in fat or carbohydrate intake were observed between the two cohorts;
however, protein intake was significantly higher (P � 0.0001, Student’s t test) in SKOT
II, while SKOT I infants had a significantly higher (P � 0.016, Student’s t test) fiber intake
(Fig. 5A). To capture the complete picture of the complementary diet of the infants in
both cohorts at 9 months of age, we previously (25) divided the complete dietary
recordings into 23 food groups (defined in Table 2). By PCA of the compiled SKOT I and
II subsets of data included in this study (n � 217), the previously defined (25) principal
components named family foods (PC1) and health-conscious food (PC2) were gener-
ated (Fig. 5B). The family foods component describes the transition from early infant
foods (with low loadings of breast milk, formula, and porridge) to foods introduced
during late infancy (with high loadings of meat, milk, cheese, animal fat, and rye bread).
Macronutrients
0
10
20
30
40
50
60
70
80
90
100
Carbohydrate Prote in Fat
SKOT I
SKOT II
***
ns
ns
P
er
ce
nt
o
f t
ot
al
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rg
y
in
ta
ke
0
1
2
3
4 *
Fibre
Fi
br
e
in
ta
ke
(m
g/
kJ
)
Bifidobacteriaceae
-4 -2 0 2 4 6 8
0
20
40
60
80
100
rho = -0.241
q = 0.008
Fam ily food
PC1 (13.2%)
R
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ab
un
da
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of
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if
id
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(%
)
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-4 -2 0 2 4 6 8
-6
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Fam ily food
SKOT I
SKOT II
PC1 (13.2%)
P
C
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