MicroRNA-496 and Mechanistic Target of Rapamycin Expression are Associated with Type 2 Diabetes Mellitus and Obesity in Elderly People.

BACKGROUND: Mechanistic target of rapamycin (mTOR) regulates lipid and glucose metabolism thus playing a key role in metabolic diseases like type 2 diabetes mellitus (T2DM). Recently, we demonstrated a functional interaction of microRNA-496 (miR-496) with mTOR and its impact on the regulation of human ageing. OBJECTIVES: As T2DM is most prevalent in older adults, we hypothesized that miR-496 may also have an impact on mTOR regulation in T2DM. METHODS: Based on real-time PCR and enzyme-linked immunosorbent assay, mTOR gene and protein expression as well as miR-496 expression were monitored in peripheral blood mononuclear cells (PBMC) from T2DM patients (median age: 71) and healthy age- and BMI matched controls (median age: 69). -Results: We demonstrated significant upregulation of phospho-mTOR and P70S6 Kinase (P70S6K) levels and significant downregulation of miR-496 in PBMC from elderly T2DM patients in comparison to a BMI and age-matched control cohort. Moreover, significant upregulation of phospho-mTOR protein and significant downregulation of miR-496 were observed in advanced stages of obesity. CONCLUSIONS: BMI-dependent upregulation of mTOR and the inverse expression profile of miR-496 observed in elderly T2DM patients suggest a correlation with T2DM. Hence, our results indicate a potential association of miR-496 with mTOR expression in elderly T2DM patients and obesity. Since phosphorylation of P70S6K was also elevated in T2DM patients, we conclude that mTOR signaling through TORC1 may be affected in the regulation of T2DM.

microRNA-496 - A new, potentially aging-relevant regulator of mTOR.

Recent findings strongly support a role for small regulatory RNAs in the regulation of human lifespan yet little information exists about the precise underlying mechanisms. Although extensive studies on model organisms have indicated that reduced activity of the nutrient response pathway, for example as a result of dietary restriction, can extend lifespan through the suppression of the protein kinase mechanistic target of rapamycin (mTOR), it still is subject of debate whether this mechanism is operative in humans as well. Here, we present findings indicating that human microRNA (miR)-496 targets 2 sites within the human mTOR 3'UTR. Coexpression of miR-496 with different fusion transcripts, consisting of the luciferase transcript and either wild-type mTOR 3'UTR or mTOR 3'UTR transcript with the miR-496 binding sites singly or combined mutated, confirmed this prediction and revealed cooperativity between the 2 binding sites. miR-496 reduced the mTOR protein level in HeLa-K cells, and the levels of miR-496 and mTOR protein were inversely correlated in Peripheral Blood Mononuclear Cells (PBMC), with old individuals (n = 40) harbouring high levels of miR-496 relative to young individuals (n = 40). Together, these findings point to the possibility that miR-496 is involved in the regulation of human aging through the control of mTOR.