溴化反刍球菌和普氏链球菌对啮齿动物模型自主运动行为的影响

Matthew Rusling, Anisha Karim, A. Kaye, C. Lee, Lauren Wegman−Points, Victoria Mathis, Thomas Lampeter, Li-Lian Yuan
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摘要

本研究调查了肠道微生物组与自愿运动之间的关系,重点是大鼠模型中的轮跑活动。肠道微生物组在宿主的生理、稳态和行为中发挥着至关重要的作用。肠道微生物组的变化与包括肥胖在内的各种病理状态和健康状况有关。鉴于缺乏运动与肥胖发展之间的密切联系,我们的研究旨在确定与自愿运动水平升高有关的微生物组因素。雄性 Sprague Dawley 大鼠被用于为期 4 周的运动范例中,在监测自愿轮跑行为的同时,每周从粪便颗粒中采集微生物组样本。在 4 周的时间过程中,我们发现跑步距离存在显著的正相关性,这表明跑步活动的等级在很大程度上得到了保留。此外,早期的跑步活动可能会对随后的跑步行为产生影响。对肠道微生物组的分析表明,α多样性与每天的跑步距离呈正相关,在高跑步组和低跑步组之间观察到β多样性的显著差异。分类学分析表明,跑步和久坐状态下的微生物丰度存在明显差异,尤其是反刍球菌科(Ruminococcaceae)和肽球菌科(Peptostreptococcaceae)。反刍球菌科,尤其是溴反刍球菌科,被认为是运动适应性的重要因素,而肽链球菌科与跑步表现以及α多样性成反比关系。这项研究强调了肠道微生物组作为运动行为调节器的潜力。未来的研究应重点关注微生物组变化与运动适应性之间的生物机制,其中溴化酵母菌(R. bromii)和链球菌(Peptostreptococcus)有望通过未来的干预研究影响运动行为。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Influences of Ruminococcus bromii and Peptostreptococcaceae on voluntary exercise behavior in a rodent model
This study investigates the relationship between the gut microbiome and voluntary exercise, focusing on wheel running activity in a rat model. The gut microbiome plays a crucial role in host physiology, homeostasis, and behavior. Alterations in the gut microbiome have been linked to various pathological states and health conditions, including obesity.Given the strong association between physical inactivity and obesity development, our study aimed to identify microbiome factors associated with elevated levels of voluntary exercise. Male Sprague Dawley rats were used in the 4-week exercise paradigm in which voluntary wheel running behavior was monitored alongside weekly microbiome sampling from fecal pellets.We observed individual differences in running activity among the cohort. Significant positive correlations in running distance were identified across the 4-week time course, suggesting that running activity ranking was largely preserved. Furthermore, earlier running activity emerged as a potential predictor for subsequent running behaviors. Analysis of gut microbiome revealed that alpha diversity was positively correlated with daily running distances, with significant differences in beta diversity observed between high and low running groups. Taxonomic analysis showed distinct abundance differences between running and sedentary conditions, particularly in the Ruminococcaceae and Peptostreptococcaceae families.Our results suggest that the microbiome composition changes significantly early in exercise exposure, potentially influencing exercise behavior. Ruminococcaceae, particularly R. bromii, was identified as a significant contributor to exercise adaptation, while Peptostreptococcaceae was inversely related to running performance as well as alpha diversity. This study underscores the potential of the gut microbiome as a modulator of exercise behavior. Future research should focus on the biological mechanisms linking microbiome changes to exercise adaptation, with R. bromii and Peptostreptococcus as promising candidates for influencing exercise behaviors through future interventional studies.
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