Multi-Omics Reveals the Impact of Exogenous Short-Chain Fatty Acid Infusion on Rumen Homeostasis: Insights into Crosstalk between the Microbiome and the Epithelium in a Goat Model

The consequences of massive exogenous supplementation of SCFAs on rumen microbial fermentation and rumen epithelium health remain an area that requires further exploration. In our study, we sought to investigate the specific impact of administering high doses of exogenous acetate, propionate, and butyrate on rumen homeostasis, with a particular focus on understanding the interaction between the rumen microbiome and epithelium. ABSTRACT Emerging data have underscored the significance of exogenous supplementation of butyrate in the regulation of rumen development and homeostasis. However, the effects of other short-chain fatty acids (SCFAs), such as acetate or propionate, has received comparatively less attention, and the consequences of extensive exogenous SCFA infusion remain largely unknown. In our study, we conducted a comprehensive investigation by infusion of three SCFAs to examine their respective roles in regulating the rumen microbiome, metabolism, and epithelium homeostasis. Data demonstrated that the infusion of sodium acetate (SA) increased rumen index while also promoting SCFA production and absorption through the upregulation of SCFA synthetic enzymes and the mRNA expression of SLC9A1 gene. Moreover, both SA and sodium propionate infusion resulted in an enhanced total antioxidant capacity, an increased concentration of occludin, and higher abundances of specific rumen bacteria, such as “Candidatus Saccharimonas,” Christensenellaceae R-7, Butyrivibrio, Rikenellaceae RC9 gut, and Alloprevotella. In addition, sodium butyrate (SB) infusion exhibited positive effects by increasing the width of rumen papilla and the thickness of the stratum basale. SB infusion further enhanced antioxidant capacity and barrier function facilitated by cross talk with Monoglobus and Incertae Sedis. Furthermore, metabolome and transcriptome data revealed distinct metabolic patterns in rumen contents and epithelium, with a particular impact on amino acid and fatty acid metabolism processes. In conclusion, our data provided novel insights into the regulator effects of extensive infusion of the three major SCFAs on rumen fermentation patterns, antioxidant capacity, rumen barrier function, and rumen papilla development, all achieved without inducing rumen epithelial inflammation. IMPORTANCE The consequences of massive exogenous supplementation of SCFAs on rumen microbial fermentation and rumen epithelium health remain an area that requires further exploration. In our study, we sought to investigate the specific impact of administering high doses of exogenous acetate, propionate, and butyrate on rumen homeostasis, with a particular focus on understanding the interaction between the rumen microbiome and epithelium. Importantly, our findings indicated that the massive infusion of these SCFAs did not induce rumen inflammation. Instead, we observed enhancements in antioxidant capacity, strengthening of rumen barrier function, and promotion of rumen papilla development, which were facilitated through interactions with specific rumen bacteria. By addressing existing knowledge gaps and offering critical insights into the regulation of rumen health through SCFA supplementation, our study holds significant implications for enhancing the well-being and productivity of ruminant animals.

[1]  Robert W. Li,et al.  Recent advances in developing butyrogenic functional foods to promote gut health , 2022, Critical reviews in food science and nutrition.

[2]  Zhuguo Li,et al.  Multi-omics reveals diet-induced metabolic disorders and liver inflammation via microbiota-gut-liver axis. , 2022, The Journal of nutritional biochemistry.

[3]  Shuangyan Han,et al.  Association of human gut microbiota composition and metabolic functions with Ficus hirta Vahl dietary supplementation , 2022, npj Science of Food.

[4]  T. Luo,et al.  Rumen and fecal microbiota profiles associated with immunity of young and adult goats , 2022, Frontiers in Immunology.

[5]  M. Hanigan,et al.  Effects of acetate, propionate, and pH on volatile fatty acid thermodynamics in continuous cultures of ruminal contents. , 2022, Journal of dairy science.

[6]  J. Loor,et al.  Impacts of Circadian Gene Period2 Knockout on Intestinal Metabolism and Hepatic Antioxidant and Inflammation State in Mice , 2022, Oxidative medicine and cellular longevity.

[7]  M. Steele,et al.  Invited review: Effect of subacute ruminal acidosis on gut health of dairy cows. , 2022, Journal of dairy science.

[8]  J. Loor,et al.  The Short-Day Cycle Induces Intestinal Epithelial Purine Metabolism Imbalance and Hepatic Disfunctions in Antibiotic-Mediated Gut Microbiota Perturbation Mice , 2022, International journal of molecular sciences.

[9]  L. Guan,et al.  Understanding the role of rumen epithelial host-microbe interactions in cattle feed efficiency , 2022, Animal nutrition.

[10]  J. Loor,et al.  Normal Light-Dark and Short-Light Cycles Regulate Intestinal Inflammation, Circulating Short-chain Fatty Acids and Gut Microbiota in Period2 Gene Knockout Mice , 2022, Frontiers in Immunology.

[11]  Shengguo Zhao,et al.  Ruminal bacterial community is associated with the variations of total milk solid content in Holstein lactating cows , 2022, Animal nutrition.

[12]  Zehu Yuan,et al.  Sheep β-Defensin 2 Regulates Escherichia coli F17 Resistance via NF-κB and MAPK Signaling Pathways in Ovine Intestinal Epithelial Cells , 2021, Biology.

[13]  Bangmao Wang,et al.  Gut microbiota-derived short-chain fatty acids and colorectal cancer: Ready for clinical translation? , 2021, Cancer letters.

[14]  Naifeng Zhang,et al.  Solid diet manipulates rumen epithelial microbiota and its interactions with host transcriptomic in young ruminants , 2021, Environmental microbiology.

[15]  Qin Zhang,et al.  Melatonin alleviates titanium nanoparticles induced osteolysis via activation of butyrate/GPR109A signaling pathway , 2021, Journal of Nanobiotechnology.

[16]  Hao Zhang,et al.  Thiamine Alleviates High-Concentrate-Diet-Induced Oxidative Stress, Apoptosis, and Protects the Rumen Epithelial Barrier Function in Goats , 2021, Frontiers in Veterinary Science.

[17]  S. Maloney,et al.  Calm Hu ram lambs assigned by temperament classification are healthier and have better meat quality than nervous Hu ram lambs. , 2021, Meat science.

[18]  L. T. Kishi,et al.  Rumen bacterial diversity in relation to nitrogen retention in beef cattle. , 2020, Anaerobe.

[19]  Mengzhi Wang,et al.  Melatonin ameliorates ochratoxin A induced liver inflammation, oxidative stress and mitophagy in mice involving in intestinal microbiota and restoring the intestinal barrier function. , 2020, Journal of hazardous materials.

[20]  J. Loor,et al.  Ruminal epithelial cell proliferation and short-chain fatty acid transporters in vitro are associated with abundance of period circadian regulator 2 (PER2). , 2020, Journal of dairy science.

[21]  Junhu Yao,et al.  Rumen microbiome structure and metabolites activity in dairy cows with clinical and subclinical mastitis , 2020, Journal of animal science and biotechnology.

[22]  Gavin M Douglas,et al.  PICRUSt2 for prediction of metagenome functions , 2020, Nature Biotechnology.

[23]  X. Mao,et al.  Dietary protein levels and amino acid supplementation patterns alter the composition and functions of colonic microbiota in pigs , 2020, Animal nutrition.

[24]  J. Osorio,et al.  Thiamine ameliorates inflammation of the ruminal epithelium of Saanen goats suffering from subacute ruminal acidosis. , 2019, Journal of dairy science.

[25]  R. Ley,et al.  The human gut bacteria Christensenellaceae are widespread, heritable, and associated with health , 2019, BMC Biology.

[26]  A. Laarman,et al.  Effects of supplemental butyrate and weaning on rumen fermentation in Holstein calves. , 2019, Journal of dairy science.

[27]  Tianyu Yang,et al.  Short-Chain Fatty Acids Regulate the Immune Responses via G Protein-Coupled Receptor 41 in Bovine Rumen Epithelial Cells , 2019, Front. Immunol..

[28]  G. Liang,et al.  Regulation of rumen development in neonatal ruminants through microbial metagenomes and host transcriptomes , 2019, Genome Biology.

[29]  M. Deyab Issue , 2019, Definitions.

[30]  William A. Walters,et al.  Reproducible, interactive, scalable and extensible microbiome data science using QIIME 2 , 2019, Nature Biotechnology.

[31]  Qiye Li,et al.  Large-scale ruminant genome sequencing provides insights into their evolution and distinct traits , 2019, Science.

[32]  M. Allen,et al.  Effects of rate and amount of propionic acid infused into the rumen on feeding behavior of Holstein cows in the postpartum period. , 2019, Journal of dairy science.

[33]  I. Mizrahi,et al.  The Road Not Taken: The Rumen Microbiome, Functional Groups, and Community States. , 2019, Trends in microbiology.

[34]  W. Ling,et al.  Supplementation with Sodium Butyrate Modulates the Composition of the Gut Microbiota and Ameliorates High-Fat Diet-Induced Obesity in Mice. , 2019, The Journal of nutrition.

[35]  B. Henrissat,et al.  Genomic insights from Monoglobus pectinilyticus: a pectin-degrading specialist bacterium in the human colon , 2019, The ISME Journal.

[36]  Q. Zebeli,et al.  Symposium review: The importance of the ruminal epithelial barrier for a healthy and productive cow. , 2019, Journal of dairy science.

[37]  Weiyun Zhu,et al.  Infusion of sodium butyrate promotes rumen papillae growth and enhances expression of genes related to rumen epithelial VFA uptake and metabolism in neonatal twin lambs. , 2018, Journal of animal science.

[38]  A. Ealy,et al.  Propionate Affects Insulin Signaling and Progesterone Profiles in Dairy Heifers , 2018, Scientific Reports.

[39]  D. Hoyt,et al.  Interspecies cross-feeding orchestrates carbon degradation in the rumen ecosystem , 2018, Nature Microbiology.

[40]  P. Boettcher,et al.  Review: Domestic herbivores and food security: current contribution, trends and challenges for a sustainable development. , 2018, Animal : an international journal of animal bioscience.

[41]  Lipeng Gao,et al.  Sodium Butyrate Improves High-Concentrate-Diet-Induced Impairment of Ruminal Epithelium Barrier Function in Goats. , 2018, Journal of agricultural and food chemistry.

[42]  A. Patra,et al.  Modulation of gastrointestinal barrier and nutrient transport function in farm animals by natural plant bioactive compounds – A comprehensive review , 2018, Critical reviews in food science and nutrition.

[43]  P. Guilloteau,et al.  Invited review: Use of butyrate to promote gastrointestinal tract development in calves. , 2018, Journal of dairy science.

[44]  Jia Gu,et al.  fastp: an ultra-fast all-in-one FASTQ preprocessor , 2018, bioRxiv.

[45]  M. Allen,et al.  Effects of acetic acid or sodium acetate infused into the rumen or abomasum on feeding behavior and metabolic response of cows in the postpartum period. , 2018, Journal of dairy science.

[46]  P. Gerber,et al.  Livestock: On our plates or eating at our table? A new analysis of the feed/food debate , 2017 .

[47]  K. Harvatine,et al.  Acetate Dose-Dependently Stimulates Milk Fat Synthesis in Lactating Dairy Cows. , 2017, The Journal of nutrition.

[48]  Steven G. Schroeder,et al.  Single-molecule sequencing and chromatin conformation capture enable de novo reference assembly of the domestic goat genome , 2017, Nature Genetics.

[49]  H. Dai,et al.  Sodium Butyrate Ameliorates High-Concentrate Diet-Induced Inflammation in the Rumen Epithelium of Dairy Goats. , 2017, Journal of agricultural and food chemistry.

[50]  Ben Nichols,et al.  VSEARCH: a versatile open source tool for metagenomics , 2016, PeerJ.

[51]  Jeffrey T Leek,et al.  Transcript-level expression analysis of RNA-seq experiments with HISAT, StringTie and Ballgown , 2016, Nature Protocols.

[52]  Paul J. McMurdie,et al.  DADA2: High resolution sample inference from Illumina amplicon data , 2016, Nature Methods.

[53]  Weiyun Zhu,et al.  Microbiome-metabolome analysis reveals unhealthy alterations in the composition and metabolism of ruminal microbiota with increasing dietary grain in a goat model. , 2016, Environmental microbiology.

[54]  P. Gerber,et al.  Environmental impacts of beef production: Review of challenges and perspectives for durability. , 2015, Meat science.

[55]  Romà Tauler,et al.  Evaluation of changes induced in rice metabolome by Cd and Cu exposure using LC-MS with XCMS and MCR-ALS data analysis strategies , 2015, Analytical and Bioanalytical Chemistry.

[56]  Anders F. Andersson,et al.  Experimental insights into the importance of aquatic bacterial community composition to the degradation of dissolved organic matter , 2015, The ISME Journal.

[57]  Angela C. Poole,et al.  Human Genetics Shape the Gut Microbiome , 2014, Cell.

[58]  Fei Li,et al.  Subacute ruminal acidosis challenge changed in situ degradability of feedstuffs in dairy goats. , 2014, Journal of dairy science.

[59]  Z. Shen,et al.  Increased papillae growth and enhanced short-chain fatty acid absorption in the rumen of goats are associated with transient increases in cyclin D1 expression after ruminal butyrate infusion. , 2013, Journal of dairy science.

[60]  Q. Zebeli,et al.  Feeding barley grain-rich diets altered electrophysiological properties and permeability of the ruminal wall in a goat model. , 2013, Journal of dairy science.

[61]  Robert S Plumb,et al.  Global metabolic profiling of animal and human tissues via UPLC-MS , 2012, Nature Protocols.

[62]  Nicholas A. Bokulich,et al.  Quality-filtering vastly improves diversity estimates from Illumina amplicon sequencing , 2012, Nature Methods.

[63]  J. Liu,et al.  Insertion depth of oral stomach tubes may affect the fermentation parameters of ruminal fluid collected in dairy cows. , 2012, Journal of dairy science.

[64]  P. Guilloteau,et al.  Effect of method of delivery of sodium butyrate on rumen development in newborn calves. , 2011, Journal of dairy science.

[65]  C. Huttenhower,et al.  Metagenomic biomarker discovery and explanation , 2011, Genome Biology.

[66]  Masanori Arita,et al.  GC/MS based metabolomics: development of a data mining system for metabolite identification by using soft independent modeling of class analogy (SIMCA) , 2011, BMC Bioinformatics.

[67]  Jianguo Xia,et al.  Web-based inference of biological patterns, functions and pathways from metabolomic data using MetaboAnalyst , 2011, Nature Protocols.

[68]  F. Stumpff,et al.  Ruminant Nutrition Symposium: Role of fermentation acid absorption in the regulation of ruminal pH. , 2011, Journal of animal science.

[69]  M. Steele,et al.  Ruminant Nutrition Symposium: Molecular adaptation of ruminal epithelia to highly fermentable diets. , 2011, Journal of animal science.

[70]  Gonçalo R. Abecasis,et al.  The Sequence Alignment/Map format and SAMtools , 2009, Bioinform..

[71]  Joshua D. Knowles,et al.  Development of a robust and repeatable UPLC-MS method for the long-term metabolomic study of human serum. , 2009, Analytical chemistry.

[72]  R. Abagyan,et al.  XCMS: processing mass spectrometry data for metabolite profiling using nonlinear peak alignment, matching, and identification. , 2006, Analytical chemistry.

[73]  Thomas D. Schmittgen,et al.  Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. , 2001, Methods.

[74]  E. N. Bergman Energy contributions of volatile fatty acids from the gastrointestinal tract in various species. , 1990, Physiological reviews.

[75]  R. E. Brown,et al.  Pathways of fatty acid synthesis and reducing equivalent generation in mammary gland of rat, sow, and cow. , 1970, Archives of biochemistry and biophysics.

[76]  S. Salzberg,et al.  FLASH: fast length adjustment of short reads to improve genome assemblies , 2011, Bioinform..

[77]  Thomas D. Schmittgen,et al.  Analysis of Relative Gene Expression Data Using Real-Time Quantitative PCR and the 2 2 DD C T Method , 2022 .