Decreased GLUT2 and glucose uptake contribute to insulin secretion defects in MODY3/HNF1A hiPSC-derived mutant β cells.
Blaise Su Jun LowChang Siang LimShirley Suet Lee DingYaw Sing TanNatasha Hui Jin NgVidhya Gomathi KrishnanSu Fen AngClaire Wen Ying NeoChandra S VermaShawn HoonSu Chi LimE Shyong TaiAdrian Kee Keong TeoPublished in: Nature communications (2021)
Heterozygous HNF1A gene mutations can cause maturity onset diabetes of the young 3 (MODY3), characterized by insulin secretion defects. However, specific mechanisms of MODY3 in humans remain unclear due to lack of access to diseased human pancreatic cells. Here, we utilize MODY3 patient-derived human induced pluripotent stem cells (hiPSCs) to study the effect(s) of a causal HNF1A+/H126D mutation on pancreatic function. Molecular dynamics simulations predict that the H126D mutation could compromise DNA binding and gene target transcription. Genome-wide RNA-Seq and ChIP-Seq analyses on MODY3 hiPSC-derived endocrine progenitors reveal numerous HNF1A gene targets affected by the mutation. We find decreased glucose transporter GLUT2 expression, which is associated with reduced glucose uptake and ATP production in the MODY3 hiPSC-derived β-like cells. Overall, our findings reveal the importance of HNF1A in regulating GLUT2 and several genes involved in insulin secretion that can account for the insulin secretory defect clinically observed in MODY3 patients.
Keyphrases
- genome wide
- induced pluripotent stem cells
- rna seq
- single cell
- molecular dynamics simulations
- dna methylation
- induced apoptosis
- nuclear factor
- dna binding
- type diabetes
- endothelial cells
- copy number
- cell cycle arrest
- transcription factor
- blood glucose
- glycemic control
- cardiovascular disease
- end stage renal disease
- newly diagnosed
- high throughput
- pluripotent stem cells
- metabolic syndrome
- molecular docking
- cell death
- blood pressure
- adipose tissue
- endoplasmic reticulum stress
- early onset
- prognostic factors
- inflammatory response
- skeletal muscle
- peritoneal dialysis
- binding protein