Distinct roles of arginases 1 and 2 in diabetic nephropathy.

Diabetes is the leading cause of end-stage renal disease, resulting in a significant health care burden and loss of economic productivity by affected individuals. Because current therapies for progression of diabetic nephropathy (DN) are only moderately successful, identification of underlying mechanisms of disease is essential to develop more effective therapies. We showed previously that inhibition of arginase using S-(2-boronoethyl)-l-cysteine (BEC) or genetic deficiency of the arginase-2 isozyme was protective against key features of nephropathy in diabetic mouse models. However, those studies did not determine whether all markers of DN were dependent only on arginase-2 expression. The objective of this study was to identify features of DN that are associated specifically with expression of arginase-1 or -2. Elevated urinary albumin excretion rate and plasma urea levels, increases in renal fibronectin mRNA levels, and decreased renal medullary blood flow were associated almost completely and specifically with arginase-2 expression, indicating that arginase-2 selectively mediates major aspects of diabetic renal injury. However, increases in renal macrophage infiltration and renal TNF-α mRNA levels occurred independent of arginase-2 expression but were almost entirely abolished by treatment with BEC, indicating a distinct role for arginase-1. We therefore generated mice with a macrophage-specific deletion of arginase-1 (CD11bCre /Arg1fl/fl ). CD11bCre /Arg1fl/fl mice had significantly reduced macrophage infiltration but had no effect on albuminuria compared with Arg1fl/fl mice after 12 wk of streptozotocin-induced diabetes. These results indicate that selective inhibition of arginase-2 would be effective in preventing or ameliorating major features of diabetic renal injury.

[1]  S. Morris,et al.  Arginase inhibition: a new treatment for preventing progression of established diabetic nephropathy. , 2015, American journal of physiology. Renal physiology.

[2]  J. Vacher,et al.  Macrophage-derived Tumor Necrosis Factor-α mediates diabetic renal injury , 2015, Kidney international.

[3]  S. Morris,et al.  Diabetic nephropathy is resistant to oral L-arginine or L-citrulline supplementation. , 2014, American journal of physiology. Renal physiology.

[4]  Xiaomei Meng,et al.  Resveratrol prevents hypoxia-induced arginase II expression and proliferation of human pulmonary artery smooth muscle cells via Akt-dependent signaling. , 2014, American journal of physiology. Lung cellular and molecular physiology.

[5]  L. Nelin,et al.  Asymmetric dimethylarginine does not inhibit arginase activity and is pro‐proliferative in pulmonary endothelial cells , 2014, Clinical and experimental pharmacology & physiology.

[6]  T. Cooper,et al.  Macrophages directly mediate diabetic renal injury. , 2013, American journal of physiology. Renal physiology.

[7]  A. Gvritishvili,et al.  Protective role of small pigment epithelium-derived factor (PEDF) peptide in diabetic renal injury. , 2013, American journal of physiology. Renal physiology.

[8]  S. Morris,et al.  Arginase inhibition mediates renal tissue protection in diabetic nephropathy by a nitric oxide synthase 3-dependent mechanism , 2013, Kidney international.

[9]  M. Mauer,et al.  Temporal Profile of Diabetic Nephropathy Pathologic Changes , 2013, Current Diabetes Reports.

[10]  E. Abdel-Rahman,et al.  Therapeutic Modalities in Diabetic Nephropathy: Standard and Emerging Approaches , 2012, Journal of General Internal Medicine.

[11]  M. Okusa,et al.  Monocyte/macrophage chemokine receptor CCR2 mediates diabetic renal injury. , 2011, American journal of physiology. Renal physiology.

[12]  S. Morris,et al.  Arginase-2 Mediates Diabetic Renal Injury , 2011, Diabetes.

[13]  G. Kaplan,et al.  Toll-like receptor–induced arginase 1 in macrophages thwarts effective immunity against intracellular pathogens , 2008, Nature Immunology.

[14]  A. Chait,et al.  Type 1 diabetes promotes disruption of advanced atherosclerotic lesions in LDL receptor-deficient mice , 2008, Proceedings of the National Academy of Sciences.

[15]  J. Ward,et al.  Immunohistochemical Markers for the Rodent Immune System , 2006, Toxicologic pathology.

[16]  F. Scaglia,et al.  Clinical, biochemical, and molecular spectrum of hyperargininemia due to arginase I deficiency , 2006, American journal of medical genetics. Part C, Seminars in medical genetics.

[17]  J. Vacher,et al.  Targeted expression of Cre recombinase in macrophages and osteoclasts in transgenic mice , 2005, Genesis.

[18]  R. Roeder,et al.  S Phase Activation of the Histone H2B Promoter by OCA-S, a Coactivator Complex that Contains GAPDH as a Key Component , 2003, Cell.

[19]  W. Grody,et al.  Mouse Model for Human Arginase Deficiency , 2002, Molecular and Cellular Biology.

[20]  Thomas D. Schmittgen,et al.  Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. , 2001, Methods.

[21]  H. Zoghbi,et al.  Generation of a Mouse Model for Arginase II Deficiency by Targeted Disruption of the Arginase II Gene , 2001, Molecular and Cellular Biology.

[22]  Guoyao Wu,et al.  Arginine metabolism: nitric oxide and beyond. , 1998, The Biochemical journal.

[23]  W. Grody,et al.  Comparative properties of arginases. , 1996, Comparative biochemistry and physiology. Part B, Biochemistry & molecular biology.

[24]  B. Bode,et al.  Efficacy, safety, and pump compatibility of insulin aspart used in continuous subcutaneous insulin infusion therapy in patients with type 1 diabetes. , 2001, Diabetes care.