PIMT Controls Insulin Synthesis and Secretion through PDX1.

Pancreatic beta cell function is an important component of glucose homeostasis. Here, we investigated the function of PIMT (PRIP-interacting protein with methyl transferase domain), a transcriptional co-activator binding protein, in the pancreatic beta cells. We observed that the protein levels of PIMT, along with key beta cell markers such as PDX1 (pancreatic and duodenal homeobox 1) and MafA (MAF bZIP transcription factor A), were reduced in the beta cells exposed to hyperglycemic and hyperlipidemic conditions. Consistently, PIMT levels were reduced in the pancreatic islets isolated from high fat diet (HFD)-fed mice. The RNA sequencing analysis of PIMT knockdown beta cells identified that the expression of key genes involved in insulin secretory pathway, Ins1 (insulin 1), Ins2 (insulin 2), Kcnj11 (potassium inwardly-rectifying channel, subfamily J, member 11), Kcnn1 (potassium calcium-activated channel subfamily N member 1), Rab3a (member RAS oncogene family), Gnas (GNAS complex locus), Syt13 (synaptotagmin 13), Pax6 (paired box 6), Klf11 (Kruppel-Like Factor 11), and Nr4a1 (nuclear receptor subfamily 4, group A, member 1) was attenuated due to PIMT depletion. PIMT ablation in the pancreatic beta cells and in the rat pancreatic islets led to decreased protein levels of PDX1 and MafA, resulting in the reduction in glucose-stimulated insulin secretion (GSIS). The results from the immunoprecipitation and ChIP experiments revealed the interaction of PIMT with PDX1 and MafA, and its recruitment to the insulin promoter, respectively. Importantly, PIMT ablation in beta cells resulted in the nuclear translocation of insulin. Surprisingly, forced expression of PIMT in beta cells abrogated GSIS, while Ins1 and Ins2 transcript levels were subtly enhanced. On the other hand, the expression of genes, PRIP/Asc2/Ncoa6 (nuclear receptor coactivator 6), Pax6, Kcnj11, Syt13, Stxbp1 (syntaxin binding protein 1), and Snap25 (synaptosome associated protein 25) associated with insulin secretion, was significantly reduced, providing an explanation for the decreased GSIS upon PIMT overexpression. Our findings highlight the importance of PIMT in the regulation of insulin synthesis and secretion in beta cells.

Methylation markers: a potential force driving cancer diagnostics forward.

Epigenetics, transcending genetics, genomics, and molecular biology, is now poised to be the avant-garde beacon of biological science. The rise of DNA methylation studies marks a new dawn in the field of epigenetics, which only a few decades ago was largely underestimated, but is now a dynamic area of research challenging and revising traditional paradigms of gene expression and behavior. Cancer research enjoys a major share of this attention to DNA methylation and it has been widely accepted for some time now that cancer is as much an epigenetic phenomenon as it is genetic. Epigenetic lesions and perturbations are acquired during the life of an individual and accumulate with aging and represent the flip side of the same coin that bears genetic mutations. Both events, either individually or in cooperation, result in the development and progression of cancer. Epigenetic research and the hunt for strong methylation markers has been ably mitigated by new and improved high throughput technology that has improved the efficacy and enabled the rapid progress of biomarker evaluation and validation. This review looks into some of the recent strides in biomarker research dealing exclusively with methylation markers and the potential key they may hold to the resilient door shut tight on cancer diagnostics and treatment.