HDAC4 mutations cause diabetes and induce ß-cell FoxO1 nuclear exclusion.

BACKGROUND: Studying patients with rare Mendelian diabetes has uncovered molecular mechanisms regulating ß-cell pathophysiology. Previous studies have shown that Class IIa histone deacetylases (HDAC4, 5, 7, and 9) modulate mammalian pancreatic endocrine cell function and glucose homeostasis. METHODS: We performed exome sequencing in one adolescent nonautoimmune diabetic patient and detected one de novo predicted disease-causing HDAC4 variant (p.His227Arg). We screened our pediatric diabetes cohort with unknown etiology using Sanger sequencing. In mouse pancreatic ß-cell lines (Min6 and SJ cells), we performed insulin secretion assay and quantitative RT-PCR to measure the ß-cell function transfected with the detected HDAC4 variants and wild type. We carried out immunostaining and Western blot to investigate if the detected HDAC4 variants affect the cellular translocation and acetylation status of Forkhead box protein O1 (FoxO1) in the pancreatic ß-cells. RESULTS: We discovered three HDAC4 mutations (p.His227Arg, p.Asp234Asn, and p.Glu374Lys) in unrelated individuals who had nonautoimmune diabetes with various degrees of ß-cell loss. In mouse pancreatic ß-cell lines, we found that these three HDAC4 mutations decrease insulin secretion, down-regulate ß-cell-specific transcriptional factors, and cause nuclear exclusion of acetylated FoxO1. CONCLUSION: Mutations in HDAC4 disrupt the deacetylation of FoxO1, subsequently decrease the ß-cell function including insulin secretion, resulting in diabetes.

Angiotensin II Induces Skeletal Muscle Atrophy by Activating TFEB-Mediated MuRF1 Expression.

RATIONALE: Skeletal muscle wasting with accompanying cachexia is a life threatening complication in congestive heart failure. The molecular mechanisms are imperfectly understood, although an activated renin-angiotensin aldosterone system has been implicated. Angiotensin (Ang) II induces skeletal muscle atrophy in part by increased muscle-enriched E3 ubiquitin ligase muscle RING-finger-1 (MuRF1) expression, which may involve protein kinase D1 (PKD1). OBJECTIVE: To elucidate the molecular mechanism of Ang II-induced skeletal muscle wasting. METHODS AND RESULTS: A cDNA expression screen identified the lysosomal hydrolase-coordinating transcription factor EB (TFEB) as novel regulator of the human MuRF1 promoter. TFEB played a key role in regulating Ang II-induced skeletal muscle atrophy by transcriptional control of MuRF1 via conserved E-box elements. Inhibiting TFEB with small interfering RNA prevented Ang II-induced MuRF1 expression and atrophy. The histone deacetylase-5 (HDAC5), which was directly bound to and colocalized with TFEB, inhibited TFEB-induced MuRF1 expression. The inhibition of TFEB by HDAC5 was reversed by PKD1, which was associated with HDAC5 and mediated its nuclear export. Mice lacking PKD1 in skeletal myocytes were resistant to Ang II-induced muscle wasting. CONCLUSION: We propose that elevated Ang II serum concentrations, as occur in patients with congestive heart failure, could activate the PKD1/HDAC5/TFEB/MuRF1 pathway to induce skeletal muscle wasting.