Dynamics of Gut Microbiota Diversity During the Early Development of an Avian Host: Evidence From a Cross-Foster Experiment

Teyssier, Aimeric; Lens, Luc; Matthysen, Erik; White, Joël

doi:10.3389/fmicb.2018.01524

Cited by 91 publications

(145 citation statements)

References 79 publications

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“…Reaction conditions were as follows: 94 • C for 5 min, 94 • C for 45 s × 35 cycles, 55 • C for 45 s, 45 s at 72 • C, and 10 min final extension at 72 • C. PCRs were performed in triplicate on two independent occasions. Negative and positive controls were assessed to ensure accuracy [6]. Mis-tagging was controlled using blank tag combinations [24].…”

Section: Amplicon Librariesmentioning

confidence: 99%

“…Gut bacterial taxa play an important role in organismal health, including regulating digestion [1], nutrient uptake [2], fat metabolism [3], and vitamin synthesis [4]. A range of factors influence gut bacterial community composition and diversity, including diet [5], environment [6,7], and seasons [8]. However, the unique life cycle of birds, especially migratory birds, makes it interesting to study their gut bacterial community [9].…”

Section: Introductionmentioning

confidence: 99%

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Significant Differences in the Gut Bacterial Communities of Hooded Crane (Grus monacha) in Different Seasons at a Stopover Site on the Flyway

Zhang

Xiang

Dong

et al. 2020

Animals

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Intestinal bacterial communities form an integral component of the organism. Many factors influence gut bacterial community composition and diversity, including diet, environment and seasonality. During seasonal migration, birds use many habitats and food resources, which may influence their intestinal bacterial community structure. Hooded crane (Grus monacha) is a migrant waterbird that traverses long distances and occupies varied habitats. In this study, we investigated the diversity and differences in intestinal bacterial communities of hooded cranes over the migratory seasons. Fecal samples from hooded cranes were collected at a stopover site in two seasons (spring and fall) in Lindian, China, and at a wintering ground in Shengjin Lake, China. We analyzed bacterial communities from the fecal samples using high throughput sequencing (Illumina Mi-seq). Firmicutes, Proteobacteria, Tenericutes, Cyanobacteria, and Actinobacteria were the dominant phyla across all samples. The intestinal bacterial alpha-diversity of hooded cranes in winter was significantly higher than in fall and spring. The bacterial community composition significantly differed across the three seasons (ANOSIM, P = 0.001), suggesting that seasonal fluctuations may regulate the gut bacterial community composition of migratory birds. This study provides baseline information on the seasonal dynamics of intestinal bacterial community structure in migratory hooded cranes.

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Section: Amplicon Librariesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Significant Differences in the Gut Bacterial Communities of Hooded Crane (Grus monacha) in Different Seasons at a Stopover Site on the Flyway

Zhang

Xiang

Dong

et al. 2020

Animals

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“…Unsurprisingly, they also exhibit diversity in their microbiomes. Bird microbiomes appear to be dominated by a small number of bacterial phyla, namely Proteobacteria, Firmicutes, and Bacteroidetes (Grond, Sandercock, Jumpponen, & Zeglin, ; Hird et al, ; Waite & Taylor, ) and are influenced by environment (Wienemann et al, ), geographic location (Hird, Carstens, Cardiff, Dittmann, & Brumfield, ), diet (Rubio et al, ), age (Grond, Lanctot, Jumpponen, & Sandercock, ; Teyssier et al, ; Van Dongen et al, ), and host genetics (Kropáčková et al, ). Despite this, little is known about the role of the microbiome in avian evolution.…”

Section: Introductionmentioning

confidence: 99%

“…The nest, eggs, nestlings and parents form a complex and unique microbial network: nest building influences parental feather microbiome (Kilgas, Saag, Mägi, Tilgar, & Mänd, 2012) and nest materials influence eggshell microbiomes and nestling development (Jacob et al, 2015). Cross-fostering experiments show that the nest can significantly affect nestling microbiome (Teyssier, Lens, Matthysen, & White, 2018). Parental care by birds also regulates microbes: egg incubation influences bacterial pathogen load on eggs (Brandl et al, 2014); nestling faecal sacs are coated in a mucus that allows parents to easily remove nestling faeces and prevents contamination of the nest with harmful bacteria (Ibáñez-Álamo, Ruiz-Rodríguez, & Soler, 2014) and parental saliva (during feeding) can vertically transmit essential microbes to offspring (Kyle & Kyle, 2004).…”

mentioning

confidence: 99%

Evolutionary signal in the gut microbiomes of 74 bird species from Equatorial Guinea

et al. 2020

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How the microbiome interacts with hosts across evolutionary time is poorly understood. Data sets including many host species are required to conduct comparative analyses. Here, we analyzed 142 intestinal microbiome samples from 92 birds belonging to 74 species from Equatorial Guinea, using the 16S rRNA gene. Using four definitions for microbial taxonomic units (97%OTU, 99%OTU, 99%OTU with singletons removed, ASV), we conducted alpha and beta diversity analyses. We found that raw abundances and diversity varied between the data sets but relative patterns were largely consistent across data sets. Host taxonomy, diet and locality were significantly associated with microbiomes, at generally similar levels using three distance metrics. Phylogenetic comparative methods assessed the evolutionary relationship between the microbiome as a trait of a host species and the underlying bird phylogeny. Using multiple ways of defining “microbiome traits”, we found that a neutral Brownian motion model did not explain variation in microbiomes. Instead, we found a White Noise model (indicating little phylogenetic signal), was most likely. There was some support for the Ornstein‐Uhlenbeck model (that invokes selection), but the level of support was similar to that of a White Noise simulation, further supporting the White Noise model as the best explanation for the evolution of the microbiome as a trait of avian hosts. Our study demonstrated that both environment and evolution play a role in the gut microbiome and the relationship does not follow a neutral model; these biological results are qualitatively robust to analytical choices.

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“…In birds, studies examining age-related changes in gut microbial diversity are limited and show conflicting results, potentially due to differences in parental and environmental transmission of microbes across species (Dewar et al, 2017;Godoy-Vitorino et al, 2010;Grond, Lanctot, Jumpponen, & Sandercock, 2017;van Dongen et al, 2013;Yin et al, 2010). For example, older nestlings of great tits (Parus major) had lower cloacal microbial diversity than younger nestlings (Teyssier, Lens, Matthysen, & White, 2018), while the opposite was found in tree swallows (Tachycineta bicolor; Mills, Lombardo, & Thorpe, 1999), and in house sparrows (Passer domesticus) age did not have any effect on microbial diversity or community structure (Kohl, Brun, Caviedes-Vidal, & Karasov, 2019). In turkeys (Meleagris gallopavo) it has been found that gut microbial diversity initially increases and then subsequently decreases during development (Danzeisen et al, 2015;Wilkinson et al, 2017), while in chickens (Gallus gallus) there is often a successional increase in diversity with age (Ballou et al, 2016;Lu et al, 2003;Oakley et al, 2014;van der Wielen, Keuzenkamp, Lipman, van Knapen, & Biesterveld, 2002).…”

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confidence: 99%

Major shifts in gut microbiota during development and its relationship to growth in ostriches

et al. 2019

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The development of gut microbiota during ontogeny is emerging as an important process influencing physiology, immunity and fitness in vertebrates. However, knowledge of how bacteria colonize the juvenile gut, how this is influenced by changes in the diversity of gut bacteria and to what extent this influences host fitness, particularly in nonmodel organisms, is lacking. Here we used 16S rRNA gene sequencing to describe the successional development of the faecal microbiome in ostriches (Struthio camelus, n = 66, repeatedly sampled) over the first 3 months of life and its relationship to growth. We found a gradual increase in microbial diversity with age that involved multiple colonization and extinction events and a major taxonomic shift in bacteria that coincided with the cessation of yolk absorption. Comparisons with the microbiota of adults (n = 5) revealed that the chicks became more similar in their microbial diversity and composition to adults as they aged. There was a five‐fold difference in juvenile growth during development, and growth during the first week of age was strongly positively correlated with the abundance of the genus Bacteroides and negatively correlated with Akkermansia. After the first week, the abundances of six phylogenetically diverse families (Peptococcaceae, S24‐7, Verrucomicrobiae, Anaeroplasmataceae, Streptococcaceae, Methanobacteriaceae) were associated with subsequent reductions in chick growth in an age‐specific and transient manner. These results have broad implications for our understanding of the development of gut microbiota and its associations with animal growth.

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Dynamics of Gut Microbiota Diversity During the Early Development of an Avian Host: Evidence From a Cross-Foster Experiment

Cited by 91 publications

References 79 publications

Significant Differences in the Gut Bacterial Communities of Hooded Crane (Grus monacha) in Different Seasons at a Stopover Site on the Flyway

Significant Differences in the Gut Bacterial Communities of Hooded Crane (Grus monacha) in Different Seasons at a Stopover Site on the Flyway

Evolutionary signal in the gut microbiomes of 74 bird species from Equatorial Guinea

Major shifts in gut microbiota during development and its relationship to growth in ostriches

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