Multi-omics reveal the gut microbiota-mediated severe foraging environment adaption of small wild ruminants in the Three-River-Source National Park, China

Hongjin LIU; Xinquan ZHAO; Shixiao XU; Liang ZHAO; Xueping HAN; Xianli XU; Na ZHAO; Linyong HU; Chongliang LUO; Xungang WANG; Qian ZHANG; Tongqing GUO

doi:10.1111/1749-4877.12830

Integrative Zoology ›› 2025, Vol. 20 ›› Issue (5) : 916 -935. DOI: 10.1111/1749-4877.12830

ORIGINAL ARTICLE

Multi-omics reveal the gut microbiota-mediated severe foraging environment adaption of small wild ruminants in the Three-River-Source National Park, China

Hongjin LIU ¹^,²^,³
, Xinquan ZHAO ⁶
, Shixiao XU ¹^,²^,³
, Liang ZHAO ¹^,²^,³
, Xueping HAN ⁵
, Xianli XU ¹^,²^,³^,⁴
, Na ZHAO ¹^,²^,³
, Linyong HU ¹^,²^,³
, Chongliang LUO ¹^,²^,³
, Xungang WANG ¹^,²^,³
, Qian ZHANG ¹^,²^,³
, Tongqing GUO ¹^,²^,³^,⁴

Author information +

History +

PDF

Abstract

The Tibetan antelope (Pantholops hodgsonii), blue sheep (Pseudois nayaur), and Tibetan sheep (Ovis aries) are the dominant small ruminants in the Three-River-Source National Park (TRSNP). However, knowledge about the association between gut microbiota and host adaptability remains poorly understood. Herein, multi-omics sequencing approaches were employed to investigate the gut microbiota-mediated forage adaption in these ruminants. The results revealed that although wild ruminants (WR) of P. hodgsoni and P. nayaur were faced with severe foraging environments with significantly low vegetation coverage and nutrition, the apparent forage digestibility of dry matter, crude protein, and acid detergent fiber was significantly higher than that of O. aries. The 16s rRNA sequencing showed that the gut microbiota in WR underwent convergent evolution, and alpha diversity in these two groups was significantly higher than that in O. aries. Moreover, indicator species, including Bacteroidetes and Firmicutes, exhibited positive relationships with apparent forage digestibility, and their relative abundances were enriched in the gut of WR. Enterotype analysis further revealed that enterotype 1 belonged to WR, and the abundance of fatty acid synthesis metabolic pathway-related enzyme genes was significantly higher than enterotype 2, represented by O. aries. Besides, the metagenomic analysis identified 14 pathogenic bacterial species, among which 10 potentially pathogenic bacteria were significantly enriched in the gut microbiota of O. aries. Furthermore, the cellulolytic strains and genes encoding cellulase and hemicellulase were significantly enriched in WR. In conclusion, our results provide new evidence of gut microbiota to facilitate wildlife adaption in severe foraging environments of the TRSNP, China.

Keywords

adaptability / gut microbiota / multi-omics sequencing / small ruminants / Three-River-Source National Park

Cite this article

Download citation ▾

Hongjin LIU, Xinquan ZHAO, Shixiao XU, Liang ZHAO, Xueping HAN, Xianli XU, Na ZHAO, Linyong HU, Chongliang LUO, Xungang WANG, Qian ZHANG, Tongqing GUO. Multi-omics reveal the gut microbiota-mediated severe foraging environment adaption of small wild ruminants in the Three-River-Source National Park, China. Integrative Zoology, 2025, 20(5): 916-935 DOI:10.1111/1749-4877.12830

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Arumugam M, Raes J, Pelletier E et al. (2011). Enterotypes of the human gut microbiome. Nature 473, 174-180.

[2]	Bai X, Lu S, Yang J et al. (2018). Precise fecal microbiome of the herbivorous Tibetan antelope inhabiting high-altitude alpine plateau. Frontiers in Microbiology 9, 2321.

[3]	Barbier FF, Chabikwa TG, Ahsan MU et al. (2019). A phenol/chloroform-free method to extract nucleic acids from recalcitrant, woody tropical species for gene expression and sequencing. Plant Methods 15, 62.

[4]	Batista-García RA, del Rayo Sánchez-Carbente M, Talia P et al. (2016). From lignocellulosic metagenomes to lignocellulolytic genes: Trends, challenges and future prospects. Biofuels, Bioproducts and Biorefining 10, 864-882.

[5]	Buffie CG, Pamer EG (2013). Microbiota-mediated colonization resistance against intestinal pathogens. Nature Reviews Immunology 13, 790-801.

[6]	Cabral L, Persinoti GF, Paixão DA et al. (2022). Gut microbiome of the largest living rodent harbors unprecedented enzymatic systems to degrade plant polysaccharides. Nature Communications 13, 629.

[7]	Cantarel BL, Coutinho PM, Rancurel C, Bernard T, Lombard V, Henrissat B (2009). The Carbohydrate-Active EnZymes database (CAZy): An expert resource for glycogenomics. Nucleic Acids Research 37, D233-D238.

[8]	Chi X, Gao H, Wu G et al. (2019). Comparison of gut microbiota diversity between wild and captive bharals (Pseudois nayaur). BMC Veterinary Research 15, 243.

[9]	Costea PI, Hildebrand F, Arumugam M et al. (2018). Enterotypes in the landscape of gut microbial community composition. Nature Microbiology 3, 8-16.

[10]	Drula E, Garron M-L, Dogan S, Lombard V, Henrissat B, Terrapon N (2022). The carbohydrate-active enzyme database: Functions and literature. Nucleic Acids Research 50, D571-D577.

[11]	Edgar RC (2010). Search and clustering orders of magnitude faster than BLAST. Bioinformatics 26, 2460-2461.

[12]	Fan C, Zhang L, Fu H et al. (2020). Enterotypes of the gut microbial community and their response to plant secondary compounds in plateau pikas. Microorganisms 8, 1311.

[13]	Faust K, Raes J (2012). Microbial interactions: From networks to models. Nature Reviews Microbiology 10, 538-550.

[14]	Feldsine P, Abeyta C, Andrews WH (2002). AOAC International methods committee guidelines for validation of qualitative and quantitative food microbiological official methods of analysis. Journal of AOAC International 85, 1187-1200.

[15]	Flint HJ, Bayer EA, Rincon MT, Lamed R, White BA (2008). Polysaccharide utilization by gut bacteria: Potential for new insights from genomic analysis. Nature Reviews Microbiology 6, 121-131.

[16]	Flint HJ, Scott KP, Duncan SH, Louis P, Forano E (2012). Microbial degradation of complex carbohydrates in the gut. Gut Microbes 3, 289-306.

[17]	Gao H, Jiang F, Zhang J et al. (2023). Effects of ex situ conservation on diversity and function of the gut microbiota of the Tibetan wild ass (Equus kiang). Integrative Zoology 18, 1089-1094.

[18]	Ge R-L, Cai Q, Shen Y-Y et al. (2013). Draft genome sequence of the Tibetan antelope. Nature Communications 4, 1858.

[19]	Gensollen T, Iyer SS, Kasper DL, Blumberg RS (2016). How colonization by microbiota in early life shapes the immune system. Science 352, 539-544.

[20]	Ghaisas S, Maher J, Kanthasamy A (2016). Gut microbiome in health and disease: Linking the microbiome-gut-brain axis and environmental factors in the pathogenesis of systemic and neurodegenerative diseases. Pharmacology & Therapeutics 158, 52-62.

[21]	Gharechahi J, Vahidi MF, Bahram M, Han J-L, Ding X-Z, Salekdeh GH (2021). Metagenomic analysis reveals a dynamic microbiome with diversified adaptive functions to utilize high lignocellulosic forages in the cattle rumen. The ISME Journal 15, 1108-1120.

[22]	Guo N, Wu Q, Shi F et al. (2021). Seasonal dynamics of diet-gut microbiota interaction in adaptation of yaks to life at high altitude. npj Biofilms and Microbiomes 7, 38.

[23]	Hale VL, Tan CL, Niu K et al. (2018). Diet versus phylogeny: A comparison of gut microbiota in captive colobine monkey species. Microbial Ecology 75, 515-527.

[24]	Hastie PM, Mitchell K, Murray J-AM (2008). Semi-quantitative analysis of Ruminococcus flavefaciens, Fibrobacter succinogenes and Streptococcus bovis in the equine large intestine using real-time polymerase chain reaction. British Journal of Nutrition 100, 561-568.

[25]	Hoffmann C, Dollive S, Grunberg S et al. (2013). Archaea and fungi of the human gut microbiome: Correlations with diet and bacterial residents. PLoS ONE 8, e66019.

[26]	Islam M, Sahana M, Areendran G et al. (2023). Prediction of potential habitat suitability of snow leopard (Panthera uncia) and blue sheep (Pseudois nayaur) and niche overlap in the parts of western Himalayan region. Geo: Geography and Environment 10, e00121

[27]	Jiang F, Gao H, Qin W et al. (2021). Marked seasonal variation in structure and function of gut microbiota in forest and alpine musk deer. Frontiers in Microbiology 12, 699797.

[28]	Jiang F, Pengfei S, Zhang J et al. (2023). Comparative analysis of gut microbial composition and functions of forest musk deer in different breeding centres. Acta Theriologica Sinica 43, 129.

[29]	Kanehisa M, Furumichi M, Tanabe M, Sato Y, Morishima K (2017). KEGG: New perspectives on genomes, pathways, diseases and drugs. Nucleic Acids Research 45, D353-D361.

[30]	Karlsson FH, Fåk F, Nookaew I et al. (2012). Symptomatic atherosclerosis is associated with an altered gut metagenome. Nature Communications 3, 1245.

[31]	Krajmalnik-Brown R, Ilhan ZE, Kang DW, DiBaise JK (2012). Effects of gut microbes on nutrient absorption and energy regulation. Nutrition in Clinical Practice 27, 201-214.

[32]	Levin D, Raab N, Pinto Y et al. (2021). Diversity and functional landscapes in the microbiota of animals in the wild. Science 372, eabb5352.

[33]	Li H, Li T, Tu B, Kou Y, Li X (2017). Host species shapes the co-occurrence patterns rather than diversity of stomach bacterial communities in pikas. Applied Microbiology and Biotechnology 101, 5519-5529.

[34]	Li H, Zhou R, Zhu J, Huang X, Qu J (2019). Environmental filtering increases with elevation for the assembly of gut microbiota in wild pikas. Microbial Biotechnology 12, 976-992.

[35]	Li W, Godzik A (2006). Cd-hit: A fast program for clustering and comparing large sets of protein or nucleotide sequences. Bioinformatics 22, 1658-1659.

[36]	Lian X, Zhang T, Cao Y, Su J, Thirgood S (2007). Group size effects on foraging and vigilance in migratory Tibetan antelope. Behavioural Processes 76, 192-197.

[37]	Liu H, Han X, Zhao N et al. (2022). The gut microbiota determines the high-altitude adaptability of tibetan wild asses (Equus kiang) in Qinghai-Tibet Plateau. Frontiers in Microbiology 13, 949002.

[38]	Liu H, Hu L, Han X et al. (2020a). Tibetan sheep adapt to plant phenology in alpine meadows by changing rumen microbial community structure and function. Frontiers in Microbiology 11, 587558.

[39]	Liu H, Xu T, Xu S et al. (2019). Effect of dietary concentrate to forage ratio on growth performance, rumen fermentation and bacterial diversity of Tibetan sheep under barn feeding on the Qinghai-Tibetan plateau. PeerJ 7, e7462.

[40]	Liu H, Zhao X, Han X et al. (2020b). Comparative study of gut microbiota in Tibetan wild asses (Equus kiang) and domestic donkeys (Equus asinus) on the Qinghai-Tibet plateau. PeerJ 8, e9032.

[41]	Liu Y, Zou X, Chen J, Pan T (2022). Impacts of protected areas establishment on pastoralists’ livelihoods in the Three-River-Source Region on the Qinghai-Tibetan Plateau. Land Use Policy 115, 106018.

[42]

Ludwig W, Euzéby J, Whitman WB (2010). Taxonomic outlines of the phyla Bacteroidetes, Spirochaetes, Tenericutes (Mollicutes), Acidobacteria, Fibrobacteres, Fusobacteria, Dictyoglomi, Gemmatimonadetes, Lentisphaerae, Verrucomicrobia, Chlamydiae, and Planctomycetes. In: Krieg NR, Staley JT, Brown DR et al., eds. Bergey's Manual® of Systematic Bacteriology, 2nd edn, vol. 4. Springer, Berlin, pp. 21-24.

[43]	Luo R, Liu B, Xie Y et al. (2012). SOAPdenovo2: An empirically improved memory-efficient short-read de novo assembler. Gigascience 1, 18. https://doi.org/10.1186/2047-217X-1-18

[44]	Martinson VG, Douglas AE, Jaenike J (2017). Community structure of the gut microbiota in sympatric species of wild Drosophila. Ecology Letters 20, 629-639.

[45]	Mukherjee A, Lordan C, Ross RP, Cotter PD (2020). Gut microbes from the phylogenetically diverse genus Eubacterium and their various contributions to gut health. Gut Microbes 12, 1802866.

[46]	Nicholson JK, Holmes E, Kinross J et al. (2012). Host-gut microbiota metabolic interactions. Science 336, 1262-1267.

[47]	Nielsen HB, Almeida M, Juncker AS et al. (2014). Identification and assembly of genomes and genetic elements in complex metagenomic samples without using reference genomes. Nature Biotechnology 32, 822-828.

[48]	Niu Q, Li P, Hao S et al. (2015). Dynamic distribution of the gut microbiota and the relationship with apparent crude fiber digestibility and growth stages in pigs. Scientific Reports 5, 9938.

[49]	O'Toole PW, Jeffery IB (2015). Gut microbiota and aging. Science 350, 1214-1215.

[50]	Peng X, Wilken SE, Lankiewicz TS et al. (2021). Genomic and functional analyses of fungal and bacterial consortia that enable lignocellulose breakdown in goat gut microbiomes. Nature Microbiology 6, 499-511.

[51]	Qin W, Song P, Lin G et al. (2020). Gut microbiota plasticity influences the adaptability of wild and domestic animals in co-inhabited areas. Frontiers in Microbiology 11, 125.

[52]	Rognes T, Flouri T, Nichols B, Quince C, Mahé F (2016). VSEARCH: A versatile open source tool for metagenomics. PeerJ 4, e2584.

[53]	Rong C, Yan M, Zhen-Zhong B et al. (2012). Cardiac adaptive mechanisms of Tibetan antelope (Pantholops hodgsonii) at high altitudes. American Journal of Veterinary Research 73, 809-813.

[54]	Shang Z, Tan Z, Kong Q et al. (2022). Characterization of fungal microbial diversity in Tibetan sheep, Tibetan gazelle and Tibetan antelope in the Qiangtang region of Tibet. Mycoscience 63, 156-164.

[55]	Shi Y, Miao Z-Y, Su J-P, Wasser SK (2021). Shift of maternal gut microbiota of Tibetan antelope (Pantholops hodgsonii) during the periparturition period. Current Microbiology 78, 727-738.

[56]	Su Y, Su J, Li F et al. (2022). Yak gut microbiota: A systematic review and meta-analysis. Frontiers in Veterinary Science 9, 889594.

[57]	Sullam KE, Essinger SD, Lozupone CA et al. (2012). Environmental and ecological factors that shape the gut bacterial communities of fish: A meta-analysis. Molecular Ecology 21, 3363-3378.

[58]	Sun G, Zhang H, Wei Q et al. (2019). Comparative analyses of fecal microbiota in European mouflon (Ovis orientalis musimon) and blue sheep (Pseudois nayaur) living at low or high altitudes. Frontiers in Microbiology 10, 1735.

[59]	Tap J, Furet JP, Bensaada M et al. (2015). Gut microbiota richness promotes its stability upon increased dietary fibre intake in healthy adults. Environmental Microbiology 17, 4954-4964.

[60]	Thomas F, Hehemann J-H, Rebuffet E, Czjzek M, Michel G (2011). Environmental and gut bacteroidetes: The food connection. Frontiers in Microbiology 2, 93.

[61]	Tickle T L, Segata N, Waldron L et al. (2013). Two-stage microbial community experimental design. The ISME Journal 7, 2330-2339.

[62]	Van Soest Pv, Robertson JB, Lewis BA (1991). Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of Dairy Science 74, 3583-3597.

[63]	Wang L, Hu L, Yan S et al. (2017). Effects of different oligosaccharides at various dosages on the composition of gut microbiota and short-chain fatty acids in mice with constipation. Food & Function 8, 1966-1978.

[64]	Wu GD, Chen J, Hoffmann C et al. (2011). Linking long-term dietary patterns with gut microbial enterotypes. Science 334, 105-108.

[65]	Yan M, Xin X, Jiakai F, Benyin Z (2022). Effect of altitude on the diversity of gut microbiota of yaks grazing on the Qinghai-Tibet Plateau. Microbiology China 49, 620-634.

[66]	Yifan C, Jianping S, Xinming L, Tongzuo Z, Qinghu C (2008). Food habits of Tibetan antelope (Pantholops hodgsoni) in the Kekexili Nature Reserve. Acta Theriologica Sinica 28, 14.

[67]	Yuan MM, Guo X, Wu L et al. (2021). Climate warming enhances microbial network complexity and stability. Nature Climate Change 11, 343-348.

[68]	Yun J-H, Roh SW, Whon TW et al. (2014). Insect gut bacterial diversity determined by environmental habitat, diet, developmental stage, and phylogeny of host. Applied and Environmental Microbiology 80, 5254-5264.

[69]	Zeng Y, Wang L-E, Zhong L (2022). Future risk of tourism pressures under climate change: A case study in the three-river-source national park. Remote Sensing 14, 3758.

[70]	Zhang J, Xu C, Huo D, Hu Q, Peng Q (2017). Comparative study of the gut microbiome potentially related to milk protein in Murrah buffaloes (Bubalus bubalis) and Chinese Holstein cattle. Scientific Reports 7, 42189.

[71]	Zhang T, Jiang F, Zhang J et al. (2023). A review of wildlife conservation and management strategies of Sanjiangyuan National Park. Acta Theriologica Sinica 43, 193.

[72]	Zhang Z, Xu D, Wang L et al. (2016). Convergent evolution of rumen microbiomes in high-altitude mammals. Current Biology 26, 1873-1879.

[73]	Zhao J, Yao Y, Li D et al. (2023). Metagenome and metabolome insights into the energy compensation and exogenous toxin degradation of gut microbiota in high-altitude rhesus macaques (Macaca mulatta). npj Biofilms and Microbiomes 9, 20.

[74]	Zhu B, Wang X, Li L (2010). Human gut microbiome: The second genome of human body. Protein & Cell 1, 718-725.

[75]	Zhu Z, Sun Y, Zhu F et al. (2020). Seasonal variation and sexual dimorphism of the microbiota in wild blue sheep (Pseudois nayaur). Frontiers in Microbiology 11, 1260.

RIGHTS & PERMISSIONS

2024 The Authors. Integrative Zoology published by International Society of Zoological Sciences, Institute of Zoology/Chinese Academy of Sciences and John Wiley & Sons Australia, Ltd.