In pancreatic  cells, elevated glucose concentrations stimulate mitochondrial oxidative metabolism to raise intracellular ATP/ADP levels, prompting insulin secretion. Unusually low levels of expression of genes encoding the plasma membrane monocarboxylate transporter, MCT1 (SLC16A1), as well as lactate dehydrogenase A (LDHA) ensure that glucose-derived pyruvate is efficiently metabolized by mitochondria, while exogenous lactate or pyruvate is unable to stimulate metabolism and hence insulin secretion inappropriately. We show here that whereas DNA methylation at the Mct1 promoter is unlikely to be involved in cell-type-specific transcriptional repression, three microRNAs (miRNAs), miR-29a, miR-29b, and miR-124, selectively target both human and mouse MCT1 3 untranslated regions. Mutation of the cognate miR-29 or miR-124 binding sites abolishes the effects of the corresponding miRNAs, demonstrating a direct action of these miRNAs on the MCT1 message. However, despite reports of its expression in the mouse -cell line MIN6, miR-124 was not detectably expressed in mature mouse islets. In contrast, the three isoforms of miR-29 are highly expressed and enriched in mouse islets. We show that inhibition of miR-29a in primary mouse islets increases Mct1 mRNA levels, demonstrating that miR-29 isoforms contribute to the -cell-specific silencing of the MCT1 transporter and may thus affect insulin release.Glucose metabolism in pancreatic  cells is specialized to efficiently couple glucose oxidation to an increase in ATP/ADP ratio, critical for stimulating insulin secretion (37). Alternative metabolic pathways that could interfere with glucose sensing are suppressed by specifically "disallowing" expression of certain genes in  cells. These disallowed genes include those encoding lactate dehydrogenase A (LDHA), which converts pyruvate to lactate (25,39,40), and MCT1 (SLC16A1) (14,15,17,40,45,46), a plasma membrane monocarboxylate transporter. Both of these genes are widely expressed in other tissues but display very low expression levels in  cells (32,40). This modification seems likely to serve a 2-fold role: first, to avoid inappropriate stimulation of oxidative metabolism, and hence insulin release, in response to circulating pyruvate or lactate; and second, to prevent the loss of glucose-derived pyruvate from  cells.The effects of inappropriate overexpression of MCT1 are observed in the rare genetic disorder physical exercise-induced hypoglycemia (32). In this condition, autosomal dominant mutations in the MCT1 (SLC16A1) promoter lead to increased transcription of the MCT1 gene sufficient to overcome the -cell-specific block on expression (31). During strenuous physical exercise, pyruvate and lactate produced by anaerobic metabolism in skeletal muscle are released into the bloodstream. The presence of MCT1 then appears to allow the circulating pyruvate/lactate to enter  cells, where it acts as a substrate for mitochondrial oxidation leading to an increased cytosolic ATP/ADP ratio. This triggers insulin release desp...
