A key role for interferon regulatory factors in mediating early-life metabolic defects in male offspring of maternal protein restricted rats.

An adverse intra-uterine environment, induced by maternal consumption of diets high in saturated fat or low in protein have been implicated as a potential trigger for development of metabolic disease in later life. However, the underlying mechanisms responsible for this programming of obesity have yet to be described. Recent studies have demonstrated that interferon regulatory factors 3 (IRF3) and 4 (IRF4) function to repress adipogenesis. We investigated whether impaired IRF3 and IRF4 function may predispose to development of metabolic disease in a model of programmed obesity. Changes in IRF3 and IRF4 levels, adipogenic gene expression, and adiponectin signalling were measured in white adipose tissue from programmed male offspring of rat dams fed a low-protein diet (MLP), which are predisposed to obesity. 3T3L1 adipocytes were used to determine novel regulatory mechanisms governing IRF expression. IRF3 and IRF4 levels were suppressed in MLP rats, together with raised lipogenic and adipogenic gene expression. Adiponectin and adiponectin receptor 1 and 2 mRNA levels were reduced in MLP rats, along with levels of PPARα and activity of AMP-activated protein kinase (AMPK), 2 downstream targets of adiponectin. Further studies determined that both IRF3 and IRF4 are induced by adiponectin, with adiponectin-AMPK and adiponectin-PPARα signalling regulating IRF3 and IRF4, respectively. We have demonstrated that impaired ability to repress adipogenesis and lipogenesis, through dysregulated adiponectin-PPARα-AMPK-IRF signalling, may play a causal role in predisposing MLP offspring to development of obesity and metabolic disease in later life.

The AMPK-SIRT signaling network regulates glucose tolerance under calorie restriction conditions.

AIMS: SIRT1 and AMP-activated protein kinase (AMPK) share common activators, actions and target molecules. Previous studies have suggested that a putative SIRT1-AMPK regulatory network could act as the prime initial sensor for calorie restriction-induced adaptations in skeletal muscle-the major site of insulin-stimulated glucose disposal. Our study aimed to investigate whether a feedback loop exists between AMPK and SIRT1 in skeletal muscle and how this may be involved glucose tolerance. MAIN METHODS: To investigate this, we used skeletal muscle-specific AMPKα1/2 knockout mice (AMPKα1/2(-/-)) fed ad libitum (AL) or a 30% calorie restricted (CR) diet and L6 rat myoblasts incubated with SIRT1 inhibitor (EX527). KEY FINDINGS: CR-AMPKα1/2(-/-) displayed impaired glucose tolerance (*p<0.05), in association with down-regulated SIRT1 and PGC-1α expression (<300% vs. CR-WT, (±±)p<0.01). Moreover, AMPK activity was decreased following SIRT1 inhibition in L6 cells (~0.5-fold vs. control, *p<0.05). SIGNIFICANCE: This study demonstrates that skeletal muscle-specific AMPK deficiency impairs the beneficial effects of CR on glucose tolerance and that these effects may be dependent on reduced SIRT1 levels.