Fasudil, a Rho-kinase inhibitor, may improve insulin signaling. However, its long-term effect on metabolic abnormalities and its preventive effect on diabetic nephropathy are still unknown. We assessed these effects of fasudil in insulin-resistant diabetic rats, comparing them with those of an angiotensin II receptor blocker, olmesartan. Male Otsuka Long-Evans Tokushima fatty (OLETF) and Long-Evans Tokushima Otsuka, nondiabetic control, rats at 15 weeks of age were used. OLETF rats were randomized to receive a low or a high dose of fasudil or olmesartan for 25 weeks. To examine the therapeutic effects after the development of diabetes, OLETF rats at 30 weeks of age were given fasudil for 10 weeks. Administration of highdose fasudil completely suppressed the development of diabetes, obesity, and dyslipidemia and increased serum adiponectin levels in OLETF rats. High-dose olmesartan also decreased hemoglobin A1c and increased serum adiponectin. There was a significant correlation between hemoglobin A1c and serum adiponectin or free fatty acid levels. The treatment with high-dose fasudil ameliorated proteinuria, glomerulosclerosis, renal interstitial fibrosis, and macrophage infiltration in OLETF rats. Olmesartan, even at the low dose, suppressed renal complications. The treatment with fasudil after the development of diabetes improved the metabolic abnormalities in OLETF rats, but could not suppress the progression of nephropathy. We conclude that the long-term treatment with fasudil prevents the development of diabetes, at least in part, by improving adipocyte differentiation in insulin-resistant diabetic rats. Early use of fasudil may prevent diabetic nephropathy.
These findings suggest that galectin-3-positive cell infiltration may play an important role in the progression of DMN, and the degree of its expression may be predictive of poor prognosis of DMN.
Mizoribine inhibited renal macrophage accumulation and prevented the progression of glomerulosclerosis and interstitial fibrosis in non-insulin-dependent diabetic kidneys. In addition to standard treatments, anti-inflammatory agents may be useful for management of non-insulin-dependent diabetic nephropathy.
Background: Fractalkine is induced on activated endothelial cells and promotes strong adhesion of T cells and monocytes via its receptor CX3CR1. In kidney, fractalkine expression might be induced by high shear stress and play an important role in prolonged glomerular diseases. We examined whether fractalkine and CX3CR1 upregulation are found in streptozotocin-induced diabetic kidneys. Methods: Diabetic rats were randomized to receive an angiotensin-converting enzyme inhibitor (temocapril), aminoguanidine or no treatment. Reverse transcription-competitive polymerase chain reaction, Western blot analysis and immunohistochemistry were used. Results: At 4 weeks, fractalkine and CX3CR1 mRNA expression in diabetic kidneys increased compared with that in controls. Fractalkine staining in diabetic kidneys was clearly detected, along with glomerular capillary lumen and peritubular capillaries. A few CX3CR1 positive cell infiltration in diabetic glomeruli were found. Treatment with temocapril or aminoguanidine did not affect these changes. At 8 weeks, fractalkine and CX3CR1 mRNA expression in untreated diabetic kidneys markedly increased compared with that in controls. Membrane-anchored fractalkine protein expression in untreated diabetic rats also increased. The increased expression was suppressed by the treatment with temocapril and aminoguanidine. Increased CX3CR1-positive cell infiltration in diabetic glomeruli was also inhibited by both treatments. Some CX3CR1-positive cells were ED3 positive. Conclusions: Fractalkine and CX3CR1 upregulation were demonstrated in an early stage of diabetic kidney. These upregulation, as well as urinary albumin excretion, were suppressed by treatments with temocapril and aminoguanidine for 8 weeks. These findings suggest that fractalkine expression and CX3CR1-positive cell infiltration in diabetic kidneys might play an important role for progression of diabetic nephropathy.
The voltage-gated potassium channel Kv1.3 has been recently identified as a molecular target that allows the selective pharmacological suppression of effector memory T cells (T(EM)) without affecting the function of naïve T cells (T(N)) and central memory T cells (T(CM)). We found that Kv1.3 was expressed on glomeruli and some tubules in rats with anti-glomerular basement membrane glomerulonephritis (anti-GBM GN). A flow cytometry analysis using kidney cells revealed that most of the CD4(+) T cells and some of the CD8(+) T cells had the T(EM) phenotype (CD45RC(-)CD62L(-)). Double immunofluorescence staining using mononuclear cell suspensions isolated from anti-GBM GN kidney showed that Kv1.3 was expressed on T cells and some macrophages. We therefore investigated whether the Kv1.3 blocker Psora-4 can be used to treat anti-GBM GN. Rats that had been given an injection of rabbit anti-rat GBM antibody were also injected with Psora-4 or the vehicle intraperitoneally. Rats given Psora-4 showed less proteinuria and fewer crescentic glomeruli than rats given the vehicle. These results suggest that T(EM) and some macrophages expressing Kv1.3 channels play a critical role in the pathogenesis of crescentic GN and that Psora-4 will be useful for the treatment of rapidly progressive glomerulonephritis.
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