METTL13 Methylation of eEF1A Increases Translational Output to Promote Tumorigenesis.

Increased protein synthesis plays an etiologic role in diverse cancers. Here, we demonstrate that METTL13 (methyltransferase-like 13) dimethylation of eEF1A (eukaryotic elongation factor 1A) lysine 55 (eEF1AK55me2) is utilized by Ras-driven cancers to increase translational output and promote tumorigenesis in vivo. METTL13-catalyzed eEF1A methylation increases eEF1A's intrinsic GTPase activity in vitro and protein production in cells. METTL13 and eEF1AK55me2 levels are upregulated in cancer and negatively correlate with pancreatic and lung cancer patient survival. METTL13 deletion and eEF1AK55me2 loss dramatically reduce Ras-driven neoplastic growth in mouse models and in patient-derived xenografts (PDXs) from primary pancreatic and lung tumors. Finally, METTL13 depletion renders PDX tumors hypersensitive to drugs that target growth-signaling pathways. Together, our work uncovers a mechanism by which lethal cancers become dependent on the METTL13-eEF1AK55me2 axis to meet their elevated protein synthesis requirement and suggests that METTL13 inhibition may constitute a targetable vulnerability of tumors driven by aberrant Ras signaling.

The Rab-GTPase activating protein, TBC1D1, is critical for maintaining normal glucose homeostasis and ß-cell mass.

Tre-2/USP6, BUB2, cdc16 domain family, member 1 (TBC1D1), a Rab-GTPase activating protein, is a paralogue of AS160, and has been implicated in the canonical insulin-signaling cascade in peripheral tissues. More recently, TBC1D1 was identified in rat and human pancreatic islets; however, the islet function of TBC1D1 remains not fully understood. We examined the role of TBC1D1 in glucose homeostasis and insulin secretion utilizing a rat knockout (KO) model. Chow-fed TBC1D1 KO rats had improved insulin action but impaired glucose-tolerance tests (GTT) and a lower insulin response during an intraperitoneal GTT compared with wild-type (WT) rats. The in vivo data suggest there may be an islet defect. Glucose-stimulated insulin secretion was higher in isolated KO rat islets compared with WT animals, suggesting TBC1D1 is a negative regulator of insulin secretion. Moreover, KO rats displayed reduced ß-cell mass, which likely accounts for the impaired whole-body glucose homeostasis. This ß-cell mass reduction was associated with increased active caspase 3, and unaltered Ki67 or urocortin 3, suggesting the induction of apoptosis rather than decreased proliferation or dedifferentiation may account for the decline in islet mass. A similar phenotype was observed in TBC1D1 heterozygous animals, highlighting the sensitivity of the pancreas to subtle reductions in TBC1D1 protein. An 8-week pair-fed high-fat diet did not further alter ß-cell mass or apoptosis in KO rats, suggesting that dietary lipids per se, do not lead to a further impairment in glucose homeostasis. The present study establishes a fundamental role for TBC1D1 in maintaining in vivo ß-cell mass.

Role of prolyl hydroxylase domain proteins in the regulation of insulin secretion.

Type 2 diabetes is associated with impaired nutrient-regulated anaplerosis and insulin secretion in pancreatic ß-cells. One key anaplerotic substrate that may be involved in regulating insulin release is α-ketoglutarate (αKG). Since prolyl hydroxylase domain proteins (PHDs) can metabolize cytosolic αKG, we sought to explore the role of this enzyme in the regulation of ß-cell function. The oxygen-sensing PHDs regulate the stability of hypoxia-inducible factor 1α (HIF1α) as well as other proline-containing proteins by catalyzing the hydroxylation of proline residues. This reaction is dependent on sufficient levels of oxygen, iron, and αKG. In the present study, we utilized both pharmacological and genetic approaches to assess the impact of inhibiting PHD activity on ß-cell function. We demonstrate that ethyl-3,4-dihydroxybenzoate (EDHB), a PHD inhibitor, significantly blunted glucose-stimulated insulin secretion (GSIS) from 832/13 clonal cells, rat, and human islets. EDHB reduced glucose utilization, ATP/ADP ratio, and key TCA cycle intermediates such as pyruvate, citrate, fumarate, and malate. siRNA-mediated knockdown of PHD1 and PHD3 inhibited GSIS, whereas siRNA-mediated knockdown of PHD2 had no effect on GSIS. Taken together, the current results demonstrate an important role for PHDs as mediators of islet insulin secretion.

Deletion of ARNT/HIF1ß in pancreatic beta cells does not impair glucose homeostasis in mice, but is associated with defective glucose sensing ex vivo.

AIMS/HYPOTHESIS: It has been suggested that the transcription factor ARNT/HIF1ß is critical for maintaining in vivo glucose homeostasis and pancreatic beta cell glucose-stimulated insulin secretion (GSIS). Our goal was to gain more insights into the metabolic defects seen after the loss of ARNT/HIF1ß in beta cells. METHODS: The in vivo and in vitro consequences of the loss of ARNT/HIF1ß were investigated in beta cell specific Arnt/Hif1ß knockout mice (ß-Arnt (fl/fl/Cre) mice). RESULTS: The only in vivo defects found in ß-Arnt (fl/fl/Cre) mice were significant increases in the respiratory exchange ratio and in vivo carbohydrate oxidation, and a decrease in lipid oxidation. The mitochondrial oxygen consumption rate was unaltered in mouse ß-Arnt (fl/fl/Cre) islets upon glucose stimulation. ß-Arnt (fl/fl/Cre) islets had an impairment in the glucose-stimulated increase in Ca(2+) signalling and a reduced insulin secretory response to glucose in the presence of KCl and diazoxide. The glucose-stimulated increase in the NADPH/NADP(+) ratio was reduced in ß-Arnt (fl/fl/Cre) islets. The reduced GSIS and NADPH/NADP(+) levels in ß-Arnt (fl/fl/Cre) islets could be rescued by treatment with membrane-permeable tricarboxylic acid intermediates. Small interfering (si)RNA mediated knockdown of ARNT/HIF1ß in human islets also inhibited GSIS. These results suggest that the regulation of GSIS by the KATP channel-dependent and -independent pathways is affected by the loss of ARNT/HIF1ß in islets. CONCLUSIONS/INTERPRETATION: This study provides three new insights into the role of ARNT/HIF1ß in beta cells: (1) ARNT/HIF1ß deletion in mice impairs GSIS ex vivo; (2) ß-Arnt (fl/fl/Cre) mice have an increased respiratory exchange ratio; and (3) ARNT/HIF1ß is required for GSIS in human islets.

Aryl hydrocarbon receptor nuclear translocator/hypoxia-inducible factor-1{beta} plays a critical role in maintaining glucose-stimulated anaplerosis and insulin release from pancreatic {beta}-cells.

The metabolic pathways that are involved in regulating insulin secretion from pancreatic ß-cells are still incompletely understood. One potential regulator of the metabolic phenotype of ß-cells is the transcription factor aryl hydrocarbon receptor nuclear translocator (ARNT)/hypoxia-inducible factor (HIF)-1ß. ARNT/HIF-1ß levels are profoundly reduced in islets obtained from type 2 diabetic patients. However, no study to date has investigated key pathways involved in regulating insulin release in ß-cells that lack ARNT/HIF-1ß. In this study, we confirm that siRNA-mediated knockdown of ARNT/HIF-1ß inhibits glucose-stimulated insulin secretion. We next investigated the metabolic consequence of the loss of ARNT/HIF-1ß knockdown. We demonstrate that ß-cells with reduced ARNT/HIF-1ß expression levels exhibit a 31% reduction in glycolytic flux without significant changes in glucose oxidation or the ATP:ADP ratio. Metabolic profiling of ß-cells treated with siRNAs against the ARNT/HIF-1ß gene revealed that glycolysis, anaplerosis, and glucose-induced fatty acid production were down-regulated, and all are key events involved in glucose-stimulated insulin secretion. In addition, both first and second phase insulin secretion in islets were significantly reduced after ARNT/HIF-1ß knockdown. Together, our data suggest an important role for ARNT/HIF-1ß in anaplerosis, and it may play a critical role in maintaining normal secretion competence of ß-cells.

Histone deacetylase 1 (HDAC-1) required for the normal formation of craniofacial cartilage and pectoral fins of the zebrafish.

Histone deacetylases interact with nucleosomes to facilitate the formation of transcriptionally repressed chromatin. In the present study, we show that histone deacetylase 1 (hdac-1) is expressed throughout embryonic development of the zebrafish. The expression of hdac-1 is ubiquitous in early embryos (2-16 hr postfertilization), but at later stages (36 and 48 hr postfertilization), it is primarily restricted to the branchial arches, fin bud mesenchyme, and hindbrain. We report the phenotypes of hdac-1 homozygous mutant embryos and embryos injected with an hdac-1 antisense morpholino. These embryos possess a complex phenotype affecting several embryonic structures. We observed developmental abnormalities in the heart and neural epithelial structures, including the retina and the loss of craniofacial cartilage and pectoral fins.