Project description:Interpretation of gut microbiome composition in type 2 diabetic subjects of North China

Project description:soil fungal community in Stipa Baicalensis Steppe of northern China Metagenome

Project description:Soil bacterial and fungal community in the grassland of Northern China

Project description:Soil samples of a pesticide-contaminated site in northern China Raw sequence reads

Project description:Bacterioplankton of the seawater in the Northern South China Sea Raw sequence reads

Project description:Soil fungal community in the grassland of Northern China in 2018 Raw sequence reads

Project description:Soil bacterial community in the grassland of Northern China in 2018 Raw sequence reads

Project description:Soil fungal community in the grassland of Northern China in 2019 Raw sequence reads

Project description:Soil bacterial community in the grassland of Northern China in 2019

Project description:Type 2 diabetes is associated with defective insulin secretion and reduced β-cell mass. Available treatments provide a temporary reprieve, but secondary failure rates are high, making insulin supplementation necessary. Reversibility of b-cell failure is a key translational question. Here, we reverse-engineered and interrogated pancreatic islet-specific regulatory networks to discover T2D-specific subpopulations characterized by metabolic-inflexibility and endocrine-progenitor/stem cell features. Single-cell gain- and loss-of-function and glucose-induced Ca++ flux analyses of top candidate MR in islet cells validated transcription factor BACH2 and associated epigenetic effectors as a key driver of T2D cell states. BACH2 knockout in T2D islets reversed cellular features of the disease, restoring a non-diabetic phenotype. BACH2-immunoreactive islet cells increased ~4-fold in diabetic patients, confirming the algorithmic prediction of clinically relevant subpopulations. Treatment with a BACH inhibitor lowered glycemia and increased plasma insulin levels in diabetic mice, and restored insulin secretion in diabetic mice and human islets. The findings suggest that T2D-specific populations of failing b-cells can be reversed and indicate pathways for pharmacological intervention, including via BACH2 inhibition.