Microbiome variations induced by delta9-tetrahydrocannabinol predict weight reduction in obese mice

A. Kaye, Matthew Rusling, Amey Dhopeshwarkar, Parhesh Kumar, Lauren Wagment-Points, Kenneth Mackie, Li-Lian Yuan
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Abstract

Obesity and high-fat diets induce consistent alterations in gut microbiota composition. Observations from epidemiological reviews and experiments also illustrate weight regulation effects of delta9-tetrahydrocannabinol (THC) with microbiome shifts. Therefore, we investigated the weight-loss potential of THC in obese mice models and to elucidate the contribution of specific gut microbiome changes in THC-induced weight loss.High-fat diet induced obese mice were treated with oral THC supplementation for two weeks and compared with controls. In addition to measuring weight, fecal samples were obtained at various timepoints, sequenced for bacterial 16s rRNA content and analyzed using QIIME2. Alpha and beta diversity were computed followed by linear mixed effects (LME) modeling of bacterial relative abundance relationship to THC treatment and weight change.In both male and female mice, the THC group had significantly greater average weight loss than controls (−17.8% vs. −0.22%, p<0.001 and −13.8% vs. +2.9%, p<0.001 respectively). Male mice had 8 bacterial taxonomic features that were both significantly different in relative abundance change over time with THC and correlated with weight change. An LME model using three bacterial features explained 76% of the variance in weight change with 24% of variation explained by fixed effects of feature relative abundance alone. The model also accurately predicted weight change in a second male mouse cohort (R=0.64, R2=0.41, p=<0.001). Female mice had fewer significant predictive features and were difficult to model, but the male-produced 3-feature model still accurately predicted weight change in the females (R=0.66, R2=0.44, p<0.001).Using a stepwise feature selection approach, our results indicate that sex-specific gut microbiome composition changes play some role in THC-induced weight loss. Additionally, we illustrated the concept of microbiome feature-based modeling to predict weight changes.
δ9-四氢大麻酚诱导的微生物组变化可预测肥胖小鼠体重的减轻
肥胖和高脂肪饮食会引起肠道微生物群组成的持续改变。流行病学评论和实验观察也表明,δ9-四氢大麻酚(THC)的体重调节作用与微生物群的变化有关。因此,我们研究了 THC 在肥胖小鼠模型中的减肥潜力,并阐明特定肠道微生物组变化在 THC 诱导的减肥中的贡献。除测量体重外,还在不同时间点采集粪便样本,进行细菌 16s rRNA 含量测序,并使用 QIIME2 进行分析。在雄性和雌性小鼠中,THC组的平均体重下降幅度明显大于对照组(分别为-17.8% vs. -0.22%,p<0.001和-13.8% vs. +2.9%,p<0.001)。雄性小鼠有 8 个细菌分类特征,这些特征与 THC 的相对丰度变化存在显著差异,并且与体重变化相关。使用三种细菌特征的 LME 模型解释了体重变化变异的 76%,而仅由特征相对丰度的固定效应解释的变异为 24%。该模型还能准确预测第二组雄性小鼠的体重变化(R=0.64,R2=0.41,p=<0.001)。使用逐步特征选择方法,我们的结果表明,性别特异性肠道微生物组组成的变化在四氢大麻酚诱导的体重减轻中发挥了一定作用。我们的结果表明,性别特异性肠道微生物组组成的变化在 THC 诱导的体重减轻中发挥了一定作用。此外,我们还阐述了基于微生物组特征的建模概念,以预测体重变化。
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