Project description:<p>Background: Grazing yearly on pasture is a traditional practice for yaks, which cannot meet the requirements of yak products since the insufficient forage supplied in the cold season results in a long production cycle. An intensive feeding system increasing production efficiency has been selected for beef and dairy cattle. However, its impacts on yaks are less studied, and it is unclear how the rumen microbiome, rumen metabolites and the host metabolome respond to an intensive feeding system and contribute to yak growth. Here, multi-omics, including rumen metagenomics, rumen and plasma metabolomics, were performed to classify the effects and regulatory mechanisms of intensive feeding system.</p><p>Results: In our results, increased growth performance and rumen volatile fatty acid (VFA) concentration were observed in yaks under the intensive feeding system compared to yaks grazing on pastures. Metagenomics of the rumen microbiome revealed that species of Clostridium and Methanobrevibacter as well as Piromyces sp. E2 and Anaeromyces robustus were increased in the rumen of intensively fed yaks, interacting and contributing to amino acid and carbohydrate metabolism. The rumen of yaks grazing on pasture had more cellulolytic microbes, such as Bacteroides and Fibrobacter species. Moreover, yaks under the intensive feeding system had lower methanogen and increased methane degradation functions, suggesting that the methane emission of these yaks may be decreased. These abundant microbiomes were correlated with the pathways of “Alanine aspartate and glutamate metabolism” and “Pyruvate metabolism”. Similar with rumen VFA results, metabolomics found that intensively fed yaks had greater concentrations of metabolites related to carbohydrates. The methyl metabolites associated with methane production were greater in the rumen of yak grazing on pasture. Additionally, these changed rumen microbiomes and their metabolites resulted in changes in plasma metabolome, finally affecting yaks’ growth.</p><p>Conclusions: This study compressively classifies the mechanism that an intensive feeding system benefits yak production and reveals the importance of the rumen microbiome for host metabolism and performance. These findings evidence that an intensive feeding system could be used for the yak industry.</p>

Project description:This study provides a clear and accurate dynamic transcriptome profile of mRNAs in rumen, reticulum, omasum and abomasum of yaks. The results include high-quality genomic data and help to elucidate the important roles of these mRNAs in regulation of growth, development and metabolism in yaks, and to further understand the molecular mechanisms underlying metabolic regulation of yak stomach tissues. At the same time, it provided a theoretical basis for age-appropriate weaning and supplementary feeding in yaks.

Project description:This study identifies key microbiome and epithelial cell subtypes involved in grass digestion and VFA metabolism in the rumen. By integrating multi-omic data, we reveal novel links between microbial activity, epithelial cell function, and grassland foraging, providing critical insights into mechanisms underlying grass prevalence and their implications for optimizing ruminant health and productivity. This research enhances our understanding of the grass-microbiome- rumen axis and its role in sustainable grazing systems.

Project description:We aimed to elucidate the effects of feeding condition (indoor grain-feeding vs. grazing on pasture) on c-miRNAs in Japanese Black (JB) cattle (Wagyu). The cattle at 18 months old were divided into pasture feeding and conventional indoor grain feeding for 5 months. Microarray analysis of c-miRNAs from the plasma extracellular vesicles led to the detection of a total of 202 bovine miRNAs in the plasma, including 15 miRNAs that differed between the feeding conditions.

Project description:The yak (Bos grunniens) is a critical livestock breed in the plateau region, and changing the feeding system can significantly improve the growth performance of yaks. In this study, the effects of different feeding regimes on growth performance and the meat quality of yaks were comprehensively compared. The transcriptome and proteome of longissimus dorsi muscle were studied by RNA-seq and TMT techniques. Our study found that indoor feeding significantly improved the yak growth performance (such as the average daily gain and net meat) and meat quality level compared with traditional grazing feeding. In the grazing (Group G) vs. stabling groups (Group HF) yak comparison, 40 DEGs/DAPs showed the same mRNA and protein expression trends. These genes are associated with collagen binding, lipoxygenase pathway, and arachidonic acid metabolic process.PRM verified the reliability of the TMT results. Moreover, some pathways such as the "AMPK signaling pathway," "FoxO signaling pathway," "PPAR signaling pathway," and "Fatty acid metabolism" were significantly enriched in this study. These results expand our knowledge of meat quality in yak and provide practical information and more evidence for further insight into the biological mechanisms of meat quality traits.

Project description:<p>This dataset comprises untargeted LC-MS metabolomics profiles of rumen samples from 8 sheep under moderate grazing with supplementary feeding and 8 sheep under intensive grazing with supplementary feeding. Samples were analyzed using Thermo Fisher Scientific mass spectrometers in positive/negative ionization modes. Data were processed with Progenesis QI and are intended for identifying differential metabolites in the rumen between the two grazing intensities with supplementation.</p>

Project description:yak rumen metagenome associated with feeding system Metagenome

Project description:Neotyphodium coenophialum is an endophytic fungus that infects most tall fescue (Festuca arundinacea) pastures that are commonly used in animal grazing systems in the United States. Beef cattle grazing such pastures are impaired in health and production performance, resulting in a large economic loss in US food-animal production systems. Based on clinical and biochemical blood analyte profiles, hepatic targeted gene and protein analyses, and hepatic transcriptomic profiling, microarray analysis using the WT Btau 4.0 Array (version 1.0, Affymetrix, Inc., Santa Clara, CA) was conducted to determine if grazing endophyte-infected tall fescue pastures affects pituitary gene expression profiles of growing beef steers. The specific overall hypothesis tested was that grazing high endophyte-infected pasture would alter the pituitary genomic expression profiles of the same growing steers, especially genes involved in production and secretion of prolactin, growth hormone, thyroid stimulating hormone, and adrenocorticotropic hormone. Sixteen steers were assigned to graze either a low toxic endophyte tall fescue-mixed grass (LE treatment, 5.7 ha, n = 8) or a high toxic endophyte infected tall fescue (HE treatment, 5.7 ha, n = 8) pasture located in the University of Kentucky Agricultural Research Center. All steers had ad libitum access to fresh water, an industry standard mineral-vitamin supplement, and grazed respective pastures for 89 to 105 days. Whole pituitaries were collected for RNA extraction and microarray analysis.

Project description:Neotyphodium coenophialum is an endophytic fungus that infects most tall fescue (Festuca arundinacea) pastures that are commonly used in animal grazing systems in the United States. Beef cattle grazing such pastures are impaired in health and production performance, resulting in a large economic loss in US food-animal production systems. Based on the clinical symptoms and laboratory analyses of blood, it was hypothesized that such affected cattle display liver-specific changes in the expression of gene transcripts that are associated with the metabolic enzymes and transporters critical for beef health and performance. Microarray analysis using the GeneChip Bovine Genome Array (Affymetrix, Inc., Santa Clara, CA) was conducted to determine if grazing endophyte-infected tall fescue pastures affects the liver gene expression profiles of growing beef steers. Nineteen steers were assigned to graze either a low toxic endophyte tall fescue-mixed grass (LE treatment, 5.7 ha, n = 9) or a high toxic endophyte infected tall fescue (HE treatment, 5.7 ha, n = 10) pasture located in the University of Kentucky Agricultural Research Center. All steers had ad libitum access to fresh water and an industry standard mineral-vitamin supplement. 88 days grazing on pasture. Approximately 2 g of tissue from the right lobe of the liver of each steer were collected for RNA extraction and microarray analysis.

Project description:Neotyphodium coenophialum is an endophytic fungus that infects most tall fescue (Festuca arundinacea) pastures that are commonly used in animal grazing systems in the United States. Beef cattle grazing such pastures are impaired in health and production performance, resulting in a large economic loss in US food-animal production systems. Based on clinical and biochemical blood analyte profiles, hepatic targeted gene and protein analyses, and hepatic transcriptomic profiling, microarray analysis using the BovGene-1_0-v1 array (Affymetrix) was conducted to determine if grazing endophyte-infected tall fescue pastures affects pituitary gene expression profiles of growing beef steers. The specific overall hypothesis tested was that grazing high endophyte-infected pasture would alter the pituitary genomic expression profiles of the same growing steers, especially genes involved in production and secretion of prolactin, growth hormone, thyroid stimulating hormone, and adrenocorticotropic hormone.