Institut National de La Santé et de la Recherche Médicale (INSERM), Toulouse, France.
Unité Mixte de Recherche (UMR) 1297, Institut Des Maladies Métaboliques Et Cardiovasculaires (I2MC), Team 2: 'Intestinal Risk Factors, Diabetes, Dyslipidemia', Université Paul Sabatier (UPS), 31432, Toulouse Cedex 4, France.
Acta Diabetol. 2021 Aug;58(8):1035-1049. doi: 10.1007/s00592-021-01682-1. Epub 2021 Mar 22.
The intestinal microbiota to immune system crosstalk is a major regulator of metabolism and hence metabolic diseases. An impairment of the chemokine receptor CX3CR1, as a key regulator shaping intestinal microbiota under normal chow feeding, could be one of the early events of dysglycemia.
We studied the gut microbiota ecology by sequencing the gut and tissue microbiota. We studied its role in energy metabolism in CX3CR1-deficent and control mice using various bioassays notably the glycemic regulation during fasting and the respiratory quotient as two highly sensitive physiological features. We used antibiotics and prebiotics treatments, and germ free mouse colonization.
We identify that CX3CR1 disruption impairs gut microbiota ecology and identified a specific signature associated to the genotype. The glycemic control during fasting and the respiratory quotient throughout the day are deeply impaired. A selected four-week prebiotic treatment modifies the dysbiotic microbiota and improves the fasting state glycemic control of the CX3CR1-deficent mice and following a glucose tolerance test. A 4 week antibiotic treatment also improves the glycemic control as well. Eventually, germ free mice colonized with the microbiota from CX3CR1-deficent mice developed glucose intolerance.
CX3CR1 is a molecular mechanism in the control of the gut microbiota ecology ensuring the maintenance of a steady glycemia and energy metabolism. Its impairment could be an early mechanism leading to gut microbiota dysbiosis and the onset of metabolic disease.
肠道微生物群与免疫系统的相互作用是代谢的主要调节剂,因此也是代谢疾病的主要调节剂。趋化因子受体 CX3CR1 的损伤,作为正常进食条件下塑造肠道微生物群的关键调节剂之一,可能是血糖失调的早期事件之一。
我们通过对肠道和组织微生物群进行测序来研究肠道微生物群生态。我们使用各种生物测定法研究了 CX3CR1 缺陷和对照小鼠的能量代谢中的作用,特别是空腹时的血糖调节和呼吸商作为两个高度敏感的生理特征。我们使用抗生素和益生元治疗以及无菌小鼠定植。
我们发现 CX3CR1 的破坏会损害肠道微生物群生态,并确定了与基因型相关的特定特征。空腹时的血糖控制以及全天的呼吸商受到严重损害。为期四周的特定益生元治疗可改变失调的微生物群,并改善 CX3CR1 缺陷小鼠的空腹状态血糖控制以及随后的葡萄糖耐量测试。为期四周的抗生素治疗也可改善血糖控制。最终,用来自 CX3CR1 缺陷小鼠的微生物群定植无菌小鼠会导致葡萄糖不耐受。
CX3CR1 是控制肠道微生物群生态的分子机制,可确保稳定的血糖和能量代谢。其损伤可能是导致肠道微生物群失调和代谢疾病发生的早期机制。
