Department of Biological Sciences, Auburn University, College of Science and Mathematics, Auburn, AL, United States.
Department of Animal Sciences, College of Agriculture, Auburn University, Auburn, AL, United States.
Front Cell Infect Microbiol. 2021 Oct 19;11:698657. doi: 10.3389/fcimb.2021.698657. eCollection 2021.
Due to its immunomodulatory potential, the intestinal microbiota has been implicated as a contributing factor in the development of the meta-inflammatory state that drives obesity-associated insulin resistance and type 2 diabetes. A better understanding of this link would facilitate the development of targeted treatments and therapies to treat the metabolic complications of obesity. To this end, we validated and utilized a novel swine model of obesity, the Mangalica pig, to characterize changes in the gut microbiota during the development of an obese phenotype, and in response to dietary differences. In the first study, we characterized the metabolic phenotype and gut microbiota in lean and obese adult Mangalica pigs. Obese or lean groups were created by allowing either (obese) or restricted (lean) access to a standard diet for 54 weeks. Mature obese pigs were significantly heavier and exhibited 170% greater subcutaneous adipose tissue mass, with no differences in muscle mass compared to their lean counterparts. Obese pigs displayed impaired glucose tolerance and hyperinsulinemia following oral glucose challenge, indicating that a metabolic phenotype also manifested with changes in body composition. Consistent with observations in human obesity, the gut microbiota of obese pigs displayed altered bacterial composition. In the second study, we characterized the longitudinal changes in the gut microbiota in response to diet and aging in growing Mangalica pigs that were either limit fed a standard diet, allowed access to a standard diet, or allowed access to a high fat-supplemented diet over an 18-week period. As expected, weight gain was highest in pigs fed the high fat diet compared to and limit fed groups. Furthermore, the and high fat groups displayed significantly greater adiposity consistent with the development of obesity relative to the limit fed pigs. The intestinal microbiota was generally resilient to differences in dietary intake (limit fed ), though changes in the microbiota of pigs fed the high fat diet mirrored changes observed in mature obese pigs during the first study. This is consistent with the link observed between the microbiota and adiposity. In contrast to intestinal bacterial populations, bacteriophage populations within the gut microbiota responded rapidly to differences in diet, with significant compositional changes in bacteriophage genera observed between the dietary treatment groups as pigs aged. These studies are the first to describe the development of the intestinal microbiota in the Mangalica pig, and are the first to provide evidence that changes in body composition and dietary conditions are associated with changes in the microbiome of this novel porcine model of obesity.
由于其免疫调节潜力,肠道微生物群已被认为是导致代谢炎症状态发展的一个促成因素,而代谢炎症状态会驱动肥胖相关的胰岛素抵抗和 2 型糖尿病。更好地了解这种联系将有助于开发针对肥胖代谢并发症的靶向治疗和疗法。为此,我们验证并利用了一种新的肥胖猪模型——曼加利察猪,以描述在肥胖表型发展过程中和对饮食差异的反应中肠道微生物群的变化。在第一项研究中,我们描述了瘦素和肥胖成年曼加利察猪的代谢表型和肠道微生物群。通过允许(肥胖)或限制(瘦素)获得标准饮食 54 周来创建肥胖或瘦素组。成熟肥胖猪明显更重,皮下脂肪组织质量增加 170%,而与瘦素猪相比肌肉质量没有差异。肥胖猪在口服葡萄糖挑战后表现出葡萄糖耐量受损和高胰岛素血症,表明代谢表型也表现出身体成分的变化。与人类肥胖的观察结果一致,肥胖猪的肠道微生物群显示出细菌组成的改变。在第二项研究中,我们描述了在生长的曼加利察猪中,肠道微生物群在饮食和衰老方面的纵向变化,这些猪在 18 周的时间内分别限制饲喂标准饮食、允许获得标准饮食或允许获得高脂肪补充饮食。正如预期的那样,高脂肪饮食组的猪体重增加最高,与限制饮食组和标准饮食组相比。此外,与限制饮食组的猪相比,和高脂肪组的猪表现出明显更高的肥胖程度,这与肥胖的发展一致。肠道微生物群通常对饮食摄入的差异具有弹性(限制饮食),尽管高脂肪饮食组猪的微生物群变化反映了在第一项研究中成熟肥胖猪观察到的变化。这与微生物群和肥胖之间的联系一致。与肠道细菌种群相反,肠道微生物群中的噬菌体种群对饮食差异迅速做出反应,随着猪龄的增长,在饮食处理组之间观察到噬菌体属的组成发生显著变化。这些研究首次描述了曼加利察猪肠道微生物群的发展,并且首次提供了证据表明身体成分和饮食条件的变化与这种新型肥胖猪模型的微生物组的变化有关。
