Increased serum levels of resistin, a molecule secreted by fat cells, have been proposed as a possible mechanistic link between obesity and insulin resistance. To further investigate the effects of resistin on glucose metabolism, we derived a novel transgenic strain of spontaneously hypertensive rats expressing the mouse resistin gene under the control of the fat-specific aP2 promoter and also performed in vitro studies of the effects of recombinant resistin on glucose metabolism in isolated skeletal muscle. Expression of the resistin transgene was detected by Northern blot analysis in adipose tissue and by real-time PCR in skeletal muscle and was associated with increased serum fatty acids and muscle triglycerides, impaired skeletal muscle glucose metabolism, and glucose intolerance in the absence of any changes in serum resistin concentrations. In skeletal muscle isolated from non-transgenic spontaneously hypertensive rats, in vitro incubation with recombinant resistin significantly inhibited insulin-stimulated glycogenesis and reduced glucose oxidation. These findings raise the possibility that autocrine effects of resistin in adipocytes, leading to release of other prodiabetic effector molecules from fat and/or paracrine actions of resistin secreted by adipocytes embedded within skeletal muscle, may contribute to the pathogenesis of disordered skeletal muscle glucose metabolism and impaired glucose tolerance.
To identify renally expressed genes that influence risk for hypertension, we integrated expression quantitative trait locus (QTL) analysis of the kidney with genome-wide correlation analysis of renal expression profiles and blood pressure in recombinant inbred strains derived from the spontaneously hypertensive rat (SHR). This strategy, together with renal transplantation studies in SHR progenitor, transgenic and congenic strains, identified deficient renal expression of Cd36 encoding fatty acid translocase as a genetically determined risk factor for spontaneous hypertension.
Major controversy exists as to whether increased C-reactive protein (CRP) contributes to individual components of the metabolic syndrome or is just a secondary response to inflammatory disease processes. We measured blood pressure and metabolic phenotypes in spontaneously hypertensive rats (SHR) in which we transgenically expressed human CRP in liver under control of the apoE promoter. In SHR transgenic rats, serum levels of human CRP approximated the endogenous levels of CRP normally found in the rat. Systolic and diastolic blood pressures measured by telemetry were 10–15 mmHg greater in transgenic SHR expressing human CRP than in SHR controls (P<0.01). During oral glucose tolerance testing, transgenic SHR exhibited hyperinsulinemia compared to controls (insulin area under the curve 36±7 versus 8±2 nmol/L/2h, respectively, P<0.05). Transgenic SHR also exhibited resistance to insulin stimulated glycogenesis in skeletal muscle (174±18 versus 278±32 nmol glucose/g/2h, P<0.05), hypertriglyceridemia (0.84±0.05 versus 0.64±0.03 mmol/L, P<0.05), reduced serum adiponectin (2.4±0.3 versus 4.3±0.6 mmol/L, P<0.05), and microalbuminuria (200±35 versus 26±5 mg albumin/g creatinine, respectively, P<0.001). Transgenic SHR had evidence of inflammation and oxidative tissue damage with increased serum levels of interleukin 6 (IL6) (36.4±5.2 versus 18±1.7 pg/ml, P<0.005) and increased hepatic and renal TBARS (1.2±0.09 versus 0.8±0.07 and 1.5±0.1 versus 1.1±0.05 nM/mg protein, respectively, P<0.01), suggesting that oxidative stress may be mediating adverse effects of increased human CRP. These findings are consistent with the hypothesis that increased CRP is more than just a marker of inflammation and can directly promote multiple features of the metabolic syndrome.
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