Constitutive activation of the mTOR signaling pathway within the normal glomerulus

Fructose induces several kinds of human metabolic disorders; however, information regarding fructose-induced kidney injury is still limited. This study examined fructose-induced kidney injury in mice and clarified the differential susceptibility of three mouse strains: C57Bl/6J, CBA/JN and DBA/2N. In this study all mice were fed with an equal calorie count for sixteen weeks to remove the influence of total energy intake from metabolic effects by fructose-feeding. Only DBA/2N mice, but not C57Bl/6J and CBA/JN mice, fed with fructose displayed tubulointerstitial fibrosis localized on the outer cortex of the kidney together with the increase of mRNA expression of Kim1 and Ngal in the absence of distinct glomerular lesions and albuminuria - decidedly different from diabetic nephropathy. In time-course study of DBA/2N mice fed with fructose diet, the inflammation and fibrosis in the outer cortex of the kidney were enhancing after eight weeks, in parallel with the accumulation of oxidative stress. This progression of renal damage in DBA/2N mice was accompanied with increasing mRNA expression of GLUT5. These results suggest that the responsiveness of GLUT5 expression to fructose at the kidney is one of pivotal roles for the progression of fructose-induced kidney injury.     

Hepatic insulin signaling is required for obesity-dependent expression of SREBP-1c mRNA but not for feeding-dependent expression

Dissecting the role of insulin in the complex regulation of triglyceride metabolism is necessary for understanding dyslipidemia and steatosis. Liver insulin receptor knockout (LIRKO) mice show that in the physiological context of feeding, hepatic insulin signaling is not required for the induction of mTORC1, an upstream activator of the lipogenic regulator, SREBP-1c. Feeding induces SREBP-1c mRNA in LIRKO livers, though not to the extent observed in controls. A high fructose diet also partially induces SREBP-1c and lipogenic gene expression in LIRKO livers. Insulin signaling becomes more important in the pathological context of obesity, as knockdown of the insulin receptor in ob/ob mice, a model of Type 2 diabetes, using antisense oligonucleotides, abolishes the induction of SREBP-1c and its targets by obesity and ameliorates steatosis. Thus, insulin-independent signaling pathways can partially compensate for insulin in the induction of SREBP-1c by feeding but the further induction by obesity/Type 2 diabetes is entirely dependent upon insulin.     

SREBP-1c in nonalcoholic fatty liver disease induced by Western-type high-fat diet plus fructose in rats

This study concentrated on the initial events triggering the development of nonalcoholic fatty liver disease induced by a high-fat plus fructose (HF-F) diet and on the possibility of delaying nonalcoholic fatty liver disease progression by adding dehydroepiandrosterone (DHEA) to the diet. Sterol regulatory element binding protein-1c (SREBP-1c) activation plays a crucial role in the progression of nonalcoholic fatty liver disease induced by an HF-F diet. This study investigated the protective effects of DHEA, a compound of physiological origin with multitargeted antioxidant properties, against the induction of SREBP-1c and on liver insulin resistance in rats fed an HF-F diet, which mimics a typical unhealthy Western diet. An HF-F diet, fortified or not with DHEA (0.01%, w/w), was administered for 15 weeks to male Wistar rats. After HF-F the liver showed unbalanced oxidative status, fatty infiltration, hepatic insulin resistance, and inflammation. The addition of DHEA to the diet reduced both activation of oxidative-stress-dependent pathways and expression of SREBP-1c and partially restored the expression of liver X-activated receptor-α and insulin receptor substrate-2 genes. DHEA supplementation of the HF-F diet reduced de novo lipogenesis and delayed progression of nonalcoholic fatty liver disease, demonstrating a relationship between oxidative stress and nonalcoholic fatty liver disease via SREBP-1c.     

RBMX is a novel hepatic transcriptional regulator of SREBP-1c gene response to high-fructose diet

In rodents a high-fructose diet induces metabolic derangements similar to those in metabolic syndrome. Previously we suggested that in mouse liver an unidentified nuclear protein binding to the sterol regulatory element (SRE)-binding protein-1c (SREBP-1c) promoter region plays a key role for the response to high-fructose diet. Here, using MALDI-TOF MASS technique, we identified an X-chromosome-linked RNA binding motif protein (RBMX) as a new candidate molecule. In electrophoretic mobility shift assay, anti-RBMX antibody displaced the bands induced by fructose-feeding. Overexpression or suppression of RBMX on rat hepatoma cells regulated the SREBP-1c promoter activity. RBMX may control SREBP-1c expression in mouse liver in response to high-fructose diet.