Bai Xue, Huang Zhiying, Tan Helin, Gu Yiren, Wang Xun, Jin Long, Shang Peng, Long Keren, Li Diyan, Li Mingzhou
College of Animal and Veterinary Sciences, Southwest Minzu University, Chengdu, China.
State Key Laboratory of Swine and Poultry Breeding Industry, College of Animal Science and Technology, Sichuan Agricultural University, Chengdu, China.
Front Vet Sci. 2025 Mar 26;12:1569196. doi: 10.3389/fvets.2025.1569196. eCollection 2025.
Tibetan pigs, native to the Qinghai-Tibet Plateau, have adapted over millennia to extreme conditions such as low oxygen, harsh cold, and high UV radiation, impacting their muscle characteristics and digestive tract microbiota. The quality of pork from Tibetan pigs (TP) and black pigs (BP) is influenced by various factors, including genetics, diet, and environmental adaptation. However, the specific influence of digestive tract microbiota metabolites on muscle traits remains poorly understood. Our goal was to correlate omic variations with meat quality traits and identify potential biomarkers predictive of superior meat quality, elucidate the regulatory effects of digestive tract microbial metabolites on Tibetan pig muscle characteristics, and reveal the genetic and nutritional mechanisms that promote adaptation to extreme environmental conditions.
This analysis encompassed metabolomic profiling of the entire digestive tract-including the stomach, jejunum, cecum, colon, and rectum-as well as histological, amino acid, fatty acid composition, and transcriptomic assessments of the longissimus dorsi muscle tissues to investigate how digestive tract microbial metabolites influence muscle adaptation to high altitudes.
Analyses revealed that Tibetan pig muscles contain smaller, more oxidative fibers enriched with flavor-enhancing amino acids. This was accompanied by a more favorable n-6/n-3 fatty acid ratio. Distinct patterns of microbial metabolites were observed in the digestive tract, influencing protein digestion and purine metabolism, and correlating with muscle glycine levels. Transcriptomic data showed varied gene expression in metabolic pathways related to salivary and pancreatic secretion, as well as carbohydrate and fatty acid metabolism. Integrated multi-omics approaches linked stomach metabolism, particularly through bile secretion pathways influenced by acetylcholine, to muscle functionality, highlighting the important role played by the ATP1B4 gene in enabling muscle physiology in Tibetan pigs.
This study highlights the importance of targeted dietary interventions in improving meat quality for specific pig breeds. It also provides a theoretical foundation for precision agriculture strategies aimed at enhancing the meat quality of both TP and BP pigs.
藏猪原产于青藏高原,历经数千年已适应了诸如低氧、严寒和高紫外线辐射等极端条件,这对它们的肌肉特性和消化道微生物群产生了影响。藏猪(TP)和黑猪(BP)猪肉的品质受多种因素影响,包括遗传、饮食和环境适应性。然而,消化道微生物群代谢产物对肌肉性状的具体影响仍知之甚少。我们的目标是将组学变化与肉质性状相关联,识别预测优质肉质的潜在生物标志物,阐明消化道微生物代谢产物对藏猪肌肉特性的调节作用,并揭示促进适应极端环境条件的遗传和营养机制。
本分析涵盖了整个消化道(包括胃、空肠、盲肠、结肠和直肠)的代谢组学分析,以及背最长肌组织的组织学、氨基酸、脂肪酸组成和转录组评估,以研究消化道微生物代谢产物如何影响肌肉对高海拔的适应性。
分析表明,藏猪肌肉含有更小、更具氧化性的纤维,富含增强风味的氨基酸。同时,n-6/n-3脂肪酸比例更优。在消化道中观察到不同的微生物代谢产物模式,影响蛋白质消化和嘌呤代谢,并与肌肉甘氨酸水平相关。转录组数据显示,与唾液和胰腺分泌以及碳水化合物和脂肪酸代谢相关的代谢途径中基因表达存在差异。综合多组学方法将胃代谢,特别是通过受乙酰胆碱影响的胆汁分泌途径,与肌肉功能联系起来,突出了ATP1B4基因在使藏猪肌肉具有生理功能方面所起的重要作用。
本研究强调了针对性饮食干预对改善特定猪种肉质的重要性。它还为旨在提高藏猪和黑猪猪肉品质的精准农业策略提供了理论基础。
