Comparative characterization of bacterial communities in geese consuming of different proportions of ryegrass

Authors: Baodi Guo ^aff001; Dianhui Li ^aff001; Beibei Zhou ^aff001; Yong Jiang ^aff001; Hao Bai ^aff002; Yang Zhang ^aff001; Qi Xu ^aff001; Wenming Zhao ^aff001; Guohong Chen ^aff001
Authors place of work: Laboratory of Animal Genetics and Rearing and Molecular Design of Jiangsu Province, Yangzhou University, Yangzhou, PR, China ^aff001; Joint International Research Laboratory of Agriculture and Agri-Product Safety, the Ministry of Education of China, Institutes of Agricultural Science and Technology Development, Yangzhou University, Jiangsu Yangzhou, China ^aff002
Published in the journal: PLoS ONE 14(10)
Category: Research Article
doi: https://doi.org/10.1371/journal.pone.0223445

Summary

Geese are extremely well-adapted to utilizing plant-derived roughage in their diet, so the grass must be added to commercial diets under intensive rearing systems. However, it is unclear whether the gut microbiota will change significantly when adding different proportions of ryegrass. In this study, 240 healthy male Yangzhou geese (28 days old) with similar body weights were randomly divided into four groups and fed different proportions grass (CK, whole commercial diets; EG1, ryegrass: commercial diets = 1.5:1; EG2, ryegrass: commercial diets = 2:1; EG3, ryegrass: commercial diets = 3:1) respectively. When the geese grew to 70 days old, their intestines were collected and high-throughput sequencing technology was performed to investigate the microbial diversity in the caecum of geese with different dietary supplements. There was no obvious change in the alpha diversity of gut microbiota of geese with ryegrass intake (P > 0.05) and the composition of dominant bacterium (including Bacteroidetes and Firmicutes) was also similar. However, the ratio between Firmicutes and Bacteroidetes was remarkably reduced with ryegrass intake (P < 0.05), and the relative abundance of 30 operational taxonomic units (OTUs) significantly differed. Additionally, the content of cellulose-degrading microbiota such as Ruminiclostridium and Ruminococcaceae UCG-010 were significantly increased in geese fed with increasing amounts of grass. Finally, the functional profiles of the goose gut microbiota were explored using the PICRUSt tool. Carbohydrate metabolism and amino acid metabolism were dominant metabolic pathways. Lipid metabolism was significantly increased in EG3 compared that in the CK group (P < 0.05). Interestingly, Turicibacter and Parasutterella may have affected abdominal fat deposition as grass intake increased. Taken together, although the diversity of bacterial communities was similar in geese fed with different proportions of ryegrass, cellulose-degrading microbiota (Ruminiclostridium and Ruminococcaceae UCG-010) were abundant and the lipid metabolic pathway was enriched, which may reduce abdominal fat accumulation in high-ryegrass fed geese.

Keywords:

Grasses – Bacteria – Diet – Fats – Microbiome – Gut bacteria – Ruminococcus – Ryegrass

Introduction

The gut microbiota colonizes the host intestine through a very complex process of interactions between the microbiota and their hosts [1]. Microbiota coevolve with the host and play a central role in multiple host functions such as metabolism, immunity, development, and behavior [2]. Most studies have evaluated the microbiota in humans and vertebrates, clearly demonstrating that the composition of gut microbiota is impacted by multiple environmental factors such as diet. This provides the opportunity to improve the physiological status of the host by regulating intestinal bacteria [3, 4]. In humans, diets enriched with fat and protein can increase the number of Firmicutes in gut microbiota compared to plant-based diets that are higher in fiber and increase the numbers of Bacteroidetes [4]. Lachnospira and Ruminococcus degrade pectin in humans and are vital for the colonic fermentation of dietary fibers [5]. Similarly, feeding of a high-fat diet increased the number of Firmicutes (Lactococcus), while the number of Bacteroidetes was decreased in mice fecal samples [6]. However, few studies have evaluated the intestinal microbiota in geese.

The goose (Anas cygnoides) is an important herbivore that supplies nutritious meat to humans [7]. Traditionally, geese are fed with grazing grass or cradling grass on a small-scale [8]. Using the original mode of feeding in intensive rearing of geese is impractical because of the high labor costs and land resources use. Therefore, feeding geese with commercial diets supplementing with a certain amount of grass has become the main method of production in the goose industry.

Goose has a strong ability to use coarse fiber from the grass but do not contain cellulolytic enzymes and hemi-cellulolytic enzymes, which are mainly secreted by microorganisms in the digestive tract. Therefore, it is important to study the diversity of gut microbes and microbiota composition. Xu et al. demonstrated that Bacteroidaceae and Lachnospiraceae are central cellulose-degrading microbiota [9]. By adding forage to the diet, the number of microorganisms that can degrade cellulose increased, such as Selenomonadales order, Negativicutes class, and Oscillospir and Megamonas genera [10]. However, the effects of different proportions of grass on the microbiota remain unclear.

Further, adding green grass to the diet influences the deposition of abdominal fat in geese [11]. Some microbiota can modulate obesity, such as the obesity-associated bacterial genus Turicibacter in rats [12] and Mucispirillum schaedleri and Methanobrevibacter, which are significantly correlated with fat deposition in chicken [13]. The microbiota associated with fat deposition in geese are not well-understood.

In this study, we performed 16S rRNA gene sequencing of geese consuming of different proportions of ryegrass, and the bacterial communities were characterized. Besides, the cellulose-degrading microbiota were identified abundantly in high-ryegrass fed geese, and the lipid metabolic pathway was enriched based on differentially represented OTUs. These data revealed the effect of the ryegrass addition on gut microbiota in geese.

Materials and methods

Ethics statement

All experimental protocols involving animals were approved by the Institutional Animal Care and Use Committee of Yangzhou University (approval number:151–2014). Procedures were performed in accordance with the Regulations for the Administration of Affairs Concerning Experimental Animals (Yangzhou University, China, 2012) and Standards for the Administration of Experimental Practices (Jiangsu, China, 2008).

Sample collection

A total of 240 healthy male Yangzhou geese (28 days old) with similar body weights were randomly divided into four groups (CK, whole commercial diets; EG1, ryegrass: commercial diets = 1.5:1; EG2, ryegrass: commercial diets = 2:1; EG3, ryegrass: commercial diets = 3:1), and fed with different proportions of grass from 29 to 70 days of age (Table 1). The ingredient and nutrient levels of the commercial diets are shown in Table 2. After 12 h of starvation at 70 days old, all geese were weighed individually, and five geese per group (with body weight closest to the mean per group weight) were selected and sacrificed. Birds were slaughtered by manual exsanguination immediately by anesthetizing them with sodium pentobarbital. The contents of the caecum were aseptically removed, placed in a sterile tube, and immediately stored at -80°C until further analyses.

**Tab. 1. Geese fed with different ratio of ryegrass addition to commercial diets.**

**Tab. 2. Ingredient and nutrient levels of the commercial diets in geese (29–70 days).**

DNA extraction and 16S rRNA gene sequencing

Microbiota genomic DNA was extracted from the samples using a Stool DNA Kit (OMEGA Bio-Tek, Norcross, GA, USA) according to the manufacturer’s instructions. The V4-V5 regions of the bacterial 16S rRNA gene were amplified by PCR (initial denaturation step at 98°C for 30 s, amplification at 98°C for 15 s, annealing at 50°C for 30 s, and extension at 72°C for 30 s, with an extra extension step at 72°C for 10 min) using the primers 515F: (5′-GTGCCAGCMGCCGCGG-3′) and 907R (5′-CCGTCAATTCMTTTRAGTTT-3′). PCR was performed in a 20-μL reaction volume containing 0.8 μL of each primer, 4 μL 5×FastPfu buffer, 2 μL 2.5mM dNTPs, 10 ng template DNA, and 0.4 μL FastPfu polymerase. Amplicons were extracted from 2% agarose gels and purified using an AxyPrep DNA Gel Extraction Kit (Axygen Biosciences, Union City, CA, USA) according to the manufacturer’s instructions and quantified using QuantiFluor^™ -ST (Promega, USA). Next-generation sequencing was performed with an Illumina Miseq 2500 PE250 (San Diego, CA, USA) according to standard protocols provided by Biozeron, Inc. (Shanghai, China).

Library construction and sequencing

Purified PCR products were quantified with a Qubit®3.0 (Life Invitrogen) and every 24 amplicons whose barcodes differed were mixed equally. The pooled DNA product was used to construct an Illumina Pair-End library following Illumina’s genomic DNA library preparation procedure. The amplicon library was paired-end sequenced (2 × 250) on an Illumina MiSeq platform according to standard protocols. The raw reads were deposited into the NCBI Sequence Read Archive database (Accession Number: PRJNA553112).

Processing of sequencing data

Raw fastq files were demultiplexed, quality-filtered using QIIME (version 1.17) with the following criteria: (i) The 300-base pair (bp) reads were truncated at any site with an average quality score <20 over a 50-bp sliding window, discarding the truncated reads shorter than 10 bp. (ii) Exact barcode matching, 2 nucleotide mismatch in primer matching, and reads containing ambiguous characters were removed. (iii) Only sequences with overlaps longer than 10 bp were assembled according to their overlap sequence. Reads which could not be assembled were discarded.

OTUs were clustered with 97% similarity cutoff using UPARSE (version 7.1 http://drive5.com/uparse/) and chimeric sequences were identified and removed using UCHIME. The phylogenetic affiliation of each 16S rRNA gene sequence was analyzed by RDP Classifier (http://rdp.cme.msu.edu/) against the silva (SSU123) 16S rRNA database using confidence threshold of 70%.

Bioinformatics and statistical analysis

Heatmaps were generated using R (http://www.r-project.org/) for the four groups. The functional profiles of the microbiota were predicted using PICRUSt. Species richness and alpha diversity were determined by Kruskal-Wallis analysis. Abdominal fat deposition percentage was analyzed by one-way analysis of variance. The Kruskal-Wallis and analysis of variance tests were performed using SPSS 17.0 software (SPSS, Inc., Chicago, IL, USA). P < 0.05 was considered statistically significant.

Results

Richness and diversity in caecal microbiota of geese fed with different proportions of ryegrass addition

A total of 1,053,761 qualified sequences were obtained from 20 samples. Data analysis revealed that each sample contained an average of 2,158 OTUs. We then compared microbial diversity, assessed diversity by the Simpson and Shannon indices, and estimated richness by determining the Chao index in the four groups. Although we found no significant differences in richness and diversity (P > 0.05), the Chao index increased with ryegrass intake in the diet (S1 Table). The coverage index was greater than 0.99 in each group.

Dominance of Bacteroidetes and Firmicutes in geese fed with different propotion of ryegrass addition

Five major bacteria phyla were detected, Bacteroidetes, Firmicutes, Deferribacteres, Proteobacteria, and Cyanobacteria, among which Bacteroidetes and Firmicutes were dominant in each group (S1 Fig). Relevant differences were observed in the two predominant phyla: Bacteroidetes was less abundant in the CK group (60.27%) than in the EG1 (64.61%), EG2 (66.82%), and EG3 (65.71%) groups, whereas the relative abundance of Firmicutes was higher in the CK group (30.45%) than in the EG1 (27.83%), EG2 (26.19%), and EG3 (26.35%) groups (S2 Table). Statistical analysis by the Kruskal-Wallis test indicated that the Firmicutes to Bacteroidetes ratio was higher in the CK group and dramatically different from in the EG3 group (P < 0.05). Notably, the genera Bacteroides, Prevotellaceae Ga6A1 group, Muribaculaceae_norank (Bacteroidetes), Faecalibacterium, Megamonas, and Ruminococcaceae_uncultured (Firmicutes) were dominant in the four groups (S2 Fig).

Identification of cellulose-degrading microbiota of geese fed with different proportion of ryegrass addition

Ryegrass contains a large amount of crude fiber as the main dietary source of non-digestible carbohydrates. To identify significantly different bacteria associated with cellulose-degrading microbiota, we compared the caecum microbiota in the CK, EG1, EG2, and EG3 groups by the Kruskal-Wallis test. At the genus level, the relative abundances of Prevotellaceae Ga6A1 group, Ruminiclostridium, Alistipes, and Ruminococcaceae UCG-010 were influenced by diet. Although the Prevotellaceae Ga6A1 group did not significantly differ between groups (P > 0.05), its relative abundance increased with increasing ryegrass intake (Fig 1A). Alistipes showed the lowest level in the EG1 group and highest level in the EG3 group (P < 0.05; Fig 1C). Ruminiclostridium and Ruminococcaceae UCG-010 were also underrepresented in the CK group compared to in the EG3 group (P < 0.05; Fig 1B and 1D).

**Fig. 1. Different bacteria associated with cellulose-degrading in genera of geese.**
A, Prevotellaceae Ga6A1 group; B, Ruminiclostridium; C, Alistipes; D, Ruminococcaceae UCG-010. * represent significantly different at P < 0.05.

We also identified significant differences using the Kruskal-Wallis test in the CK, EG1, EG2, and EG3 groups. Notably, 30 OTUs were significantly different between groups (P < 0.05; S3 Table). The heatmap showed that OTU 286, OTU 326, OTU363, and OTU 284 were enriched in the CK group, while OTU18, OTU196, OTU420, and OTU426 were important in the EG3 group, which belonged to the families Ruminococcaceae, Prevotellaceae, and Bacteriodaceae (Fig 2).

**Fig. 2. Heatmap of significant differences OUTs in geese fed with different propotion of ryegrass addition.**

Relationship between bacterial communities and abdominal fat percentage in geese

We found that the abdominal fat percentage decreased gradually with ryegrass intake and was highest in the CK group, showing significant differences from the EC1, EG2, and EG3 groups (P < 0.05); however, there was no significant differences among the EC1, EC2, and EC3 groups (P < 0.05; Fig 3). We also found that Barnesiella and Harryflintia were negatively correlated with abdominal fat percentage, while some microbiota showed positive correlations such as Turicibacter and Parasutterella (Table 3).

**Fig. 3. Abdominal fat percentage in geese fed with different proportions of ryegrass addition.**
* indicates significantly difference at P < 0.05.

**Tab. 3. Relationship between bacterial communities and abdominal fat percentage in geese.**

Function profiling of caecum microbiota in geese fed with different proportion of ryegrass addition

We used PICRUSt (Phylogenetic Investigation of Communities by Reconstruction of Unobserved States) as a tool for functional predictive exploration. The results showed that 40 of the 43 level II orthology groups (KOs in Kyoto Encyclopedia of Genes and Genomes) were detected in the Yangzhou goose caecum microbiome (S3 Fig). The dominant functions were carbohydrate metabolism, amino acid metabolism, replication and repair, membrane transport, and energy metabolism in the four groups. Lipid metabolism showed a high abundance suggesting a dramatic difference between the two groups (P < 0.05; Table 4).

**Tab. 4. Lipid metabolism abundance in geese fed with different proportion of ryegrass addition.**

Discussion

Geese, as herbivores, digest green forage to regulate their gut microbiota. Various factors may affect these bacteria, including genotypes, antibiotic factors, and environmental factors; particularly, the diet is a central factor influencing the gut microbiota [14, 15]. Fewer studies have evaluated the effect of adding different proportions of grass on the microorganisms in the goose gut. In this study, we characterized the gut microbiota in geese.

Exposure to the abundant bacteria associated with a high-fiber diet can enrich microbiome diversity [16]. High alpha diversity within the microbiota has been associated with good health, while low alpha diversity is related to poor health in humans [17]. In this study, we found that bacteria richness increased when ryegrass was added to the diet. Thus, ryegrass can be added during intensive goose rearing to improve goose health. The Shannon index was previously found to range from 4 to 5 among poultry [13] but varied from 7 to 9 in rabbit [18], goat [19], and swine [20]. In this study, the average Shannon index was approximately 5, which was similar to the value in chicken.

Most studies have focused on the microbiota in humans and vertebrates [21]. Ley et al. showed that more than 94.2% of sequences in all Burkina Faso and European samples belonged to two major populated microbiota phyla: Actinobacteria and Bacteroidetes [21]. Velasco-Galilea et al. found that the predominant bacteria were Firmicutes (76.4%) and Tenericutes (7.8%) in the caecum of rabbit [22]. Firmicutes and Proteobacteria account for most of the bacteria in black bears [23]. However, in this study, Yangzhou geese were dominantly occupied by Bacteroidetes and Firmicutes. Bacteroidetes is associated with the degradation of cellulose [24]. We found that the relative abundance of Bacteroidetes increased with increasing ryegrass in the diets. Firmicutes, an important phylum, is involved in protein and fat metabolism [25]. A diet consisting of approximately 30% calories from protein and 70% from fat results in enrichment of Firmicutes in human [26]. Our results showed that Firmicutes, which was the second most abundant bacterium, was decreased (from 30.45% to 26.19%) with increasing ryegrass intake, likely because commercial diets contained more calories than ryegrass. Furthermore, the relative proportion of Bacteroidetes increases while Firmicutes decreases in humans with increased crude fiber intake in the diet [27]. Our results showed that the Firmicutes/Bacteroidetes ratio was decreased with increasing ryegrass intake.

Grass is a source of dietary fiber that must be fermented by microbiota in the caecum to produce energy. Prevotellaceae was reported as the most abundant microbiota in bovine and goats, both of which have a powerful ability to digest crude fibers [28]. Here, we found that the abundance of Prevotellaceae Ga6A1 group (family Prevotellaceae) was increased with increasing ryegrass in the diet. Ruminiclostridium can depolymerize cellulose and related plant cell wall polysaccharides [29]. The Ruminococcaceae family is important for degrading pectin and cellulose in the colonic fermentation of dietary fibers [30]. When humans switch from an animal to plant-based diet, the relative abundance of Alistipes was found to be increased [31]. In this study, Ruminiclostridium, Ruminococcaceae UCG-010 (family Ruminococcaceae), and Alistipes were increased, indicating their association with digestive fibers. Interestingly, OTU18, OTU196, OTU420, and OTU426 were major in the EG3 group and belong to the families Ruminococcaceae, Prevotellaceae, and Bacteriodaceae. Ruminococcaceae and Prevotellaceae are related to fiber digestion in the rumen [28, 32], which Bacteroidaceae is a central cellulose-degrading microbiota in geese [9]. Therefore, adding ryegrass to the diet can increase the relative abundance of cellulose-degrading bacteria.

Accumulating studies have demonstrated that obesity is associated with an imbalance in the normal bacteria composition [33]. Bacteria influence whole-body metabolism by impacting the energy balance associated with obesity [34]. Barnesiella is related to carbohydrate utilization [35] and Harryflintia belongs to the family Ruminococcaceae, which is associated with fiber digestion [30]. In this study, we found that Barnesiella and Harryflintia were negatively correlated with the abdominal fat percentage. The degradation process of ryegrass may require bacteria involved in cellulose and carbohydrate metabolism. Furthermore, high-grain feeding increases the abundance of Turicibacter in goats [19]. Parasutterella was elevated by sugar consumption in rat [36]. Our results demonstrate that Turicibacter and Parasutterella were positively correlated with the abdominal fat percentage. Because these bacteria break down higher-energy foods, they can increase abdominal fat deposition.

Furthermore, the caecum microbiota plays an important role in host metabolic pathways. Our results demonstrated that carbohydrate metabolism and amino acid metabolism were dominant functions in the four groups. Because the main ingredients in feed are carbohydrate and protein, the main metabolic pathways may be carbohydrate metabolism and amino acid metabolism in geese. Previous studies reported that carbohydrate metabolism and amino acid metabolism were the most abundant functional categories in geese [37]. We also found that enrichment of the lipid metabolic pathway decreased the accumulation of abdominal fat when grass was added to the diet. PICRUSt provided insight into the function of intestinal bacterial communities in geese. Additional histological methods (such as transcriptome and metabolomics) should be used to improve our understanding of bacterial function in the goose caecum.

Conclusions

Our study revealed the overall composition of the microbiota in the caecum of geese that consumed different diets based on 16S rRNA gene sequencing. The diversity of bacterial communities was similar when geese were fed with different proportions of ryegrass, However, cellulose-degrading microbiota such as Ruminiclostridium and Ruminococcaceae UCG-010 were clearly observed in high-ryegrass fed geese. The lipid metabolic pathway was enriched based on differentially represented OTUs, which may reduce abdominal fat accumulation. These data revealed the effect of ryegrass addition on gut microbiota in geese, which providing a theoretical basis for adding an appropriate proportion of grass to the diet during intensive geese breeding.

Supporting information

S1 Table [chao]
Diversity estimation of the 16S rRNA gene libraries of the goose caecum from sequencing analysis.

S2 Table [docx]
Significantly different bacterial communities at phylum level in geese fed with different proportion of ryegrass addition.

S3 Table [docx]
Significant differences OTUs in geese fed with different proportion of ryegrass addition.

S1 Fig [tif]
Taxonomic profiles of the microbial communities at the phylum level of geese fed with different proportion of ryegrass addition.

S2 Fig [a]
Pie charts of median percent values of bacterial genera present in caecal samples of geese fed with different proportion of ryegrass addition (>3%).

S3 Fig [kos]
Functional predictions of all samples using PICRUSt.

Zdroje

1. Niu Q, Li P, Hao S, Zhang Y, Kim SW, Li H, et al. Dynamic distribution of the gut microbiota and the relationship with apparent crude fiber digestibility and growth stages in pigs. Scientific Reports. 2015;5(9938):9938.

2. Benson AK, Kelly SA, Legge R, Ma F, Low SJ, Kim J, et al. Individuality in gut microbiota composition is a complex polygenic trait shaped by multiple environmental and host genetic factors. Proceedings of the National Academy of Sciences of the United States of America. 2010;107(44):18933–8. doi: 10.1073/pnas.1007028107 WOS:000283749000038. 20937875

3. Everard A, Lazarevic V, Gaã¯A N, Johansson M, Stã¥Hlman M, Backhed F, et al. Microbiome of prebiotic-treated mice reveals novel targets involved in host response during obesity. Isme Journal. 2014;8(10):2116–30. doi: 10.1038/ismej.2014.45 24694712

4. Vangay P, Ward T, Gerber JS, Knights D. Antibiotics, pediatric dysbiosis, and disease. Cell Host & Microbe. 2015;17(5):553–64.

5. Xiaolei Z, Yonit BD, Laverde-Gomez JA, Bareket D, Sheridan PO, Duncan SH, et al. Unique Organization of Extracellular Amylases into Amylosomes in the Resistant Starch-Utilizing Human Colonic Firmicutes Bacterium Ruminococcus bromii. Mbio. 2015;6(5):e01058. doi: 10.1128/mBio.01058-15 26419877

6. Zhang CH, Zhang MH, Wang SY, Han RJ, Cao YF, Hua WY, et al. Interactions between gut microbiota, host genetics and diet relevant to development of metabolic syndromes in mice. Isme Journal. 2010;4(2):232–41. doi: 10.1038/ismej.2009.112 19865183

7. Schwartz S. A metagenomic study of diet-dependent interaction between gut microbiota and host in infants reveals differences in immune response. Genome Biology. 2012;13(4):r32. doi: 10.1186/gb-2012-13-4-r32 22546241

8. Wood KM, Salim H, Mcewen PL, Mandell IB, Miller SP, Swanson KC. The effect of corn or sorghum dried distillers grains plus solubles on growth performance and carcass characteristics of cross-bred beef steers. Animal Feed Science & Technology. 2011;165(1–2):23–30.

9. Xu Q, Yuan X, Gu T, Li Y, Dai W, Shen X, et al. Comparative characterization of bacterial communities in geese fed all-grass or high-grain diets. Plos One. 2017;12(10):e0185590. doi: 10.1371/journal.pone.0185590 28972993

10. Chen X, Liu X, Du Y, Wang B, Zhao N, Geng Z. Green forage and fattening duration differentially modulate cecal microbiome of Wanxi white geese. Plos One. 2018;13(9). doi: 10.1371/journal.pone.0204210 WOS:000445639700034. 30252869

11. Wang HY, Liu Y, Gong SM, Chen YS, Da-Qian HE. Effects of ryegrass amount on the weight gain,feed utilization rate and slaughter performance of Zhedong white geese. Acta Agriculturae Shanghai. 2015.

12. Kim JY, Kwon YM, Kim IS, Kim JA, Yu DY, Adhikari B, et al. Effects of the Brown Seaweed Laminaria japonica Supplementation on Serum Concentrations of IgG, Triglycerides, and Cholesterol, and Intestinal Microbiota Composition in Rats. Front Nutr. 2018;5:23. doi: 10.3389/fnut.2018.00023 29707542

13. Wen C, Yan W, Sun C, Ji C, Zhou Q, Zhang D, et al. The gut microbiota is largely independent of host genetics in regulating fat deposition in chickens. The ISME journal. 2019. doi: 10.1038/s41396-019-0367-2 MEDLINE:30728470. 30728470

14. Paola MD, Filippo CD, Cavalieri D, Ramazzotti M, Poullet JB, Massart S, et al. PP90 IMPACT OF DIET IN SHAPING GUT MICROBIOTA REVEALED BY A COMPARATIVE STUDY IN CHILDREN FROM EUROPE AND RURAL AFRICA. Proceedings of the National Academy of Sciences of the United States of America. 2010.

15. Wu GD, Christian H, Kyle B, Ying-Yu C, Keilbaugh SA, Meenakshi B, et al. Linking long-term dietary patterns with gut microbial enterotypes. Science. 2011.

16. Carlotta DF, Duccio C, Monica DP, Matteo R, Jean Baptiste P, Sebastien M, et al. Impact of diet in shaping gut microbiota revealed by a comparative study in children from Europe and rural Africa. Proceedings of the National Academy of Sciences of the United States of America. 2010.

17. Emmanuelle LC, Trine N, Junjie Q, Edi P, Falk H, Gwen F, et al. Richness of human gut microbiome correlates with metabolic markers. Nature. 2013.

18. Zeng B, Han S, Wang P, Wen B, Jian W, Guo W, et al. The bacterial communities associated with fecal types and body weight of rex rabbits. Scientific Reports. 2015;5(9342):9342.

19. Junhua L, Tingting X, Weiyun Z, Shengyong M. High-grain feeding alters caecal bacterial microbiota composition and fermentation and results in caecal mucosal injury in goats. British Journal of Nutrition. 2014;112(3):416–27. doi: 10.1017/S0007114514000993 24846282

20. Hyeun Bum K, Klaudyna B, White BA, Singer RS, Srinand S, Jin TZ, et al. Microbial shifts in the swine distal gut in response to the treatment with antimicrobial growth promoter, tylosin. Proceedings of the National Academy of Sciences of the United States of America. 2012;109(38):15485. doi: 10.1073/pnas.1205147109 22955886

21. Ley RE, Lozupone CA, Hamady M, Knight R, Gordon, I. J. Worlds within worlds: Evolution of the vertebrate gut microbiota. Nature Reviews Microbiology. 2008;6(10):776–88. doi: 10.1038/nrmicro1978 18794915

22. Velasco-Galilea M, Piles M, Viñas M, Rafel O, González-Rodríguez O, Guivernau M, et al. Rabbit Microbiota Changes Throughout the Intestinal Tract. Frontiers in Microbiology.

23. Song C, Wang B, Tan J, Zhu L, Lou D, Cen X. Comparative analysis of the gut microbiota of black bears in China using high-throughput sequencing. Molecular Genetics & Genomics. 2017;292(2):407–14.

24. Berry D. The emerging view of Firmicutes as key fibre degraders in the human gut. Environmental Microbiology. 2016;18(7):2081–3. doi: 10.1111/1462-2920.13225 26842002

25. Okazaki Y, Sekita A, Chiji H, Kato N. Consumption of lily bulb modulates fecal ratios of firmicutes and bacteroidetes phyla in rats fed a high-fat diet. Food Science & Biotechnology. 2016;25(1 Supplement):153–6.

26. Kaoutari AE, Armougom F, Gordon JI, Raoult D, Henrissat B. The abundance and variety of carbohydrate-active enzymes in the human gut microbiota. Nature Reviews Microbiology. 2013;11(7):497–504. doi: 10.1038/nrmicro3050 23748339

27. Ley RE, Turnbaugh PJ, Samuel K, Gordon JI. Microbial ecology: human gut microbes associated with obesity. Nature. 2006;444(7122):1022–3. doi: 10.1038/4441022a 17183309

28. Elie J, Itzhak M. Composition and similarity of bovine rumen microbiota across individual animals. Plos One. 2012;7(3):e33306. doi: 10.1371/journal.pone.0033306 22432013

29. Ravachol J, Borne R, Meynial-Salles I, Soucaille P, Pagès S, Tardif C, et al. Combining free and aggregated cellulolytic systems in the cellulosome-producing bacterium Ruminiclostridium cellulolyticum. Biotechnology for Biofuels. 2015;8(1):114.

30. Gosalbes MJ, VÃ zquez-Castellanos JF, Angebault C, Woerther PL, Ruppã© E, Ferrãºs ML, et al. Carriage of Enterobacteria Producing Extended-Spectrum Î2-Lactamases and Composition of the Gut Microbiota in an Amerindian Community. Antimicrob Agents Chemother. 2015;60(1):507–14. doi: 10.1128/AAC.01528-15 26552974

31. David LA, Maurice CF, Carmody RN, Gootenberg DB, Button JE, Wolfe BE, et al. Diet rapidly and reproducibly alters the human gut microbiome. Nature. 2014;505(7484):559. doi: 10.1038/nature12820 24336217

32. Gagen EJ, Padmanabha J, Denman SE, Mcsweeney CS. Hydrogenotrophic culture enrichment reveals rumen Lachnospiraceae and Ruminococcaceae acetogens and hydrogen-responsive Bacteroidetes from pasture-fed cattle. Fems Microbiology Letters. 2015;362(14).

33. Etxeberria U, Arias N, Boqué N, Macarulla MT, Portillo MP, Martínez JA, et al. Reshaping faecal gut microbiota composition by the intake of trans-resveratrol and quercetin in high-fat sucrose diet-fed rats. Journal of Nutritional Biochemistry. 2015;26(6):651–60. doi: 10.1016/j.jnutbio.2015.01.002 25762527

34. Amandine E, Vladimir L, Nadia G, Maria J, Marcus S, Fredrik B, et al. Microbiome of prebiotic-treated mice reveals novel targets involved in host response during obesity. Isme Journal. 2014;8(10):2116–30. doi: 10.1038/ismej.2014.45 24694712

35. Li P, Yang C, Yue R, Zhen Y, Zhuo Q, Piao J, et al. Modulation of the Fecal Microbiota in Sprague-Dawley Rats Using Genetically Modified and Isogenic Corn Lines. J Agric Food Chem. 2018;66(2):551–61. doi: 10.1021/acs.jafc.7b05285 29264925

36. Noble EE, Hsu TM, Jones RB, Fodor AA, Goran MI, Kanoski SE. Early-Life Sugar Consumption Affects the Rat Microbiome Independently of Obesity. Journal of Nutrition. 2017;147(1):20–8. doi: 10.3945/jn.116.238816 27903830

37. Li M, Zhou H, Pan X, Xu T, Zhang Z, Zi X, et al. Cassava foliage affects the microbial diversity of Chinese indigenous geese caecum using 16S rRNA sequencing. Sci Rep. 2017;7:46837. doi: 10.1038/srep46837 28731455