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Vascular Dysfunction in Hyperglycemia Is Protein Kinase C the Culprit? David D. Gutterman D iabetes mellitus (DM) is the

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Vascular Dysfunction in Hyperglycemia Is Protein Kinase C the Culprit? David D. Gutterman

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iabetes mellitus (DM) is the seventh leading cause of death in the United States with accelerated cardiovascular disease accounting for most (⬎75%) of the mortality. Major complications include retinopathy, nephropathy, neuropathy, and vasculopathy. Each has been linked to the severity of hyperglycemia; thus, the mainstay of treatment has been to aggressively control serum glucose levels. This practice is supported by the large NIH-sponsored Diabetes Complications and Control Trial that linked control of glucose to delayed onset of complications.1 Other mechanisms may also contribute because restoration of euglycemia does not always abrogate progression of established disease.2 Thus, alternative therapeutic approaches based on an understanding of the mechanisms of glucose-induced end-organ damage are needed. In the current issue of Circulation Research, Beckman et al3 describe the reversal of hyperglycemia-induced endothelial dysfunction in subjects treated with a novel, selective blocker of protein kinase C (PKC) ␤. The role of PKC in the vascular complications of DM has been established in animals. This study represents an important translational extension into the clinical arena supporting the possibility of drug trials. However, to appreciate the role of PKC in diabetic vascular disease, the complexity of mechanisms by which elevated levels of glucose causes tissue damage must be recognized. Three major mechanisms have been proposed. First, glucose stimulates flux through the sorbitol pathway creating an intracellular reductive redox shift with accumulation of NADPH. This reduces cellular uptake of myoinositol and decreases sodium-potassium ATPase activity. Blocking the sorbitol pathway with aldose reductase inhibitors improves peripheral nerve conduction but has little effect on diabetic retinopathy, indicating that different mechanisms participate in the vasculopathy of DM.4 Second, glucose can nonenzymatically glycosylate cellular proteins over time, yielding advanced glycosylated end-products (AGEs). AGEs can directly alter protein function or activate specific receptors with resultant changes in gene expression. AGEs also stimulate production of reactive oxygen species (ROS), common culprits in vascular pathology. The opinions expressed in this editorial are not necessarily those of the editors or of the American Heart Association. From the Cardiovascular Research Center, Medical College of Wisconsin, Milwaukee, Wis. Correspondence to David D. Gutterman, MD, Professor and Associate Director, Cardiovascular Research Center, Medical College of Wisconsin, 8701 Watertown Plank Rd, Milwaukee, WI 53226. E-mail [email protected] (Circ Res. 2002;90:5-7.) © 2002 American Heart Association, Inc. Circulation Research is available at http://www.circresaha.org

Third, through formation of diacylglycerol (DAG) and AGEs, glucose can activate and upregulate PKC.5 PKC is a ubiquitous family of serine-threonine phosphorylating enzymes.6 The distribution of over 10 isoforms varies among cell types with PKC␣ and ␤ most prevalent in the vasculature1 where hyperglycemia predominately activates the ␤ isoform.7 The effects of PKC activation are protean, including alterations in cell signaling, production of vasoconstrictor substances, and conversion of smooth muscle and endothelial cells to a proliferative phenotype in the retinal microcirculation and peripheral conduit vasculatures. How does PKC produce such diverse abnormalities within the vascular bed? Several proposed mechanisms include PKC-stimulated expression of endothelial adhesion molecules,6 inhibition of vascular smooth muscle cell apoptosis that contributes to vascular remodeling in DM,8 and inhibition of gap junctions.9 The common denominator may be reactive oxygen species (ROS) that are key in the pathological changes of PKC activation (Figure). Although the ability of PKC to induce ROS is wellestablished,10 the source of ROS is not clear. In cultured cells, glucose stimulates NADPH oxidase,10 whereas in intact tissues, such as aorta, nitric oxide synthase is involved.11 The net result is that activation of PKC generates ROS with subsequent impairment of endothelial function12 (Figure). These actions are responsible for the early and diffuse atherosclerosis in DM. A positive feedback loop exists whereby ROS generated from PKC activate phospholipase D, which hydrolyzes phosphatidylcholine to produce DAG and PKC activation again.13 The specific PKC isoform activated by hyperglycemia varies across tissues and species.8,14 Thus, involvement of PKC in the vascular dysfunction of diabetes may depend on the bed studied. The importance of PKC in the development of complications of DM is evident from studies in which inhibitors (staurosporine, H7, chelerythrine, calphostin C) or activators (PMA, overexpression) of PKC have been used to abrogate or reproduce the pathological changes associated with DM, respectively. Most pharmacological studies are restricted to in vitro models because common inhibitors of PKC are nonspecific and are associated with unacceptable toxicity. Recently, a novel compound has been developed, LY333531, that is a highly specific inhibitor of PKC␤2 the predominant isoform activated by hyperglycemia in the retina, heart, and aorta of diabetic rats.1,7,15 LY333531 has much less toxicity than other PKC inhibitors and has facilitated in vivo studies showing that oral administration to diabetic rats for 2 weeks improves albumin excretion and glomerular filtration rate and retinal

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Circulation Research

January 11/25, 2002

Pathway of hyperglycemia-induced vascular dysfunction. Elevations in cellular glucose increase flux through the polyol pathway, forming sorbitol and NADH. Both glucose and NADH stimulate formation of DAG that activates PKC. AGEs produced by glycation of proteins can also stimulate PKC or cause ROS activation directly. ROS are a proposed final common pathway for the genesis of atherosclerosis. In addition to AGEs and endogenous DAG, PKC is activated by fatty acids and angiotensin II. Inhibition of membrane translocation and activation of PKC is conferred by vitamin E which accelerates breakdown of DAG, by ACE-I, which block DAG stimulation of PKC, and by direct inhibitors such as LY33351, a PKC␤ selective antagonist that blocks the prooxidant and vascular pathological effects of PKC. Arrows indicate stimulation; dotted lines, inhibition; ACE-I, angiotensin-converting enzyme inhibitor; AGE, advanced glycosylation end-products; PKC, protein kinase C; DAG, diacylglycerol; and ROS, reactive oxygen species.

blood flow.15 The observed benefits were independent of glycemic control. Five years later, in this issue of Circulation Research, Beckman et al3 provide evidence in human subjects that the vascular dysfunction associated with hyperglycemia can be ameliorated with the same inhibitor of PKC␤. In a placebo controlled randomized double-blind trial, they show that the hyperglycemia-induced reduction in endothelium-mediated vasodilation is improved by LY333531. The test compound had no effect on methacholine dilation in euglycemia but restored dilation during hyperglycemia. The endpoint of improved endothelial function is important given the critical role of the endothelium in preventing atherosclerosis.16,17 This study paves the way for future clinical investigation of a novel targeted pharmacological inhibitor in the treatment of diabetic complications. The present study examined peripheral microvascular function. Mortality in DM involves conduit vessel disease; thus, it will be important to determine whether treatment also preserves endothelial function in the aorta and coronary arteries. The impaired dilation imposed by hyperglycemia in this study was modest and may reflect the short duration of glucose stress. In most models, 6 hours of hyperglycemia is not sufficient to maximally stimulate ROS production or for generation of AGEs. It will be important to determine the effectiveness of PKC blockade in subjects with longer periods of poor glycemic control as occur in DM. Finally, it will be important to determine the mechanism of improvement by assessing endothelial-derived substances such including NO.

Use of PKC inhibitors in DM may confer broader benefit than described by Beckman et al. LY333531 prevents diabetic neuropathy in rats by preserving myoinositol levels in the tissue.18 VEGF mediates endothelial cell proliferation, angiogenesis, and increased permeability in retinal and peripheral tissues in diabetes. Each of these pathological changes is abrogated by LY333531.19 In humans, LY333531 treatment for 1 month normalized retinal blood flow.20 Thus, the nephropathy, retinopathy, and microvascular disease of DM may also be improved by PKC inhibition. It is important to consider possible detrimental effects of long-term treatment with PKC inhibitors. PKC␤ is highly expressed in the brain.21 Mice lacking this isoform show impaired ability to learn.22 Reduction in PKC␤ isoforms are present in mice with Huntington’s disease and in the caudateputamen of patients with this condition suggesting an etiological role.21 The duration of treatment in the present study was short, minimizing toxicity. Furthermore, the induced vascular abnormalities were of brief duration. Higher doses of the inhibitor and longer treatment regimens would likely be needed to improve vascular function in chronically diabetic subjects. Although LY333531 is effective at reducing PKC activity, the study by Beckman et al raises the possibility that other more widely established treatments may be effective through a similar mechanism (Figure). HMG CoA reductase inhibitors can reduce DAG-mediated activation of PKC and the resultant migration of human vascular smooth muscle cells.23 Vitamin E also ameliorates complications of DM by reducing PKC activity and by antioxidant properties.24 ␣-Tocopherol treatment reduced PKC␤ expression by over 50% and restored NO production in vascular smooth muscle cells grown in high glucose.24 Similar benefits were also observed in retina, aorta, and hearts of diabetic rats. Finally, ramipril, an angiotensin-converting enzyme inhibitor (ACE-I), prevented elevations in PKC in retina and mesenteric arteries from diabetic rats.25 The benefits of ACE-I in DM are already well-established.26 In summary, many of the vascular and other end-organ complications of diabetes can be ameliorated by inhibition of PKC. In vascular tissue, the PKC␤ isoform appears to be a prominent mediator of changes in cell proliferation, vascular endothelial function, microvascular permeability, and collagen formation. Thus, PKC is clearly situated as a key perpetrator of the vascular complications of diabetes. Availability of selective isoform antagonists (e.g. LY333531) may provide a novel mechanism for treating vascular and other complications of diabetes independent of glycemic control and insulin resistance.

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Gutterman 4. Nishikawa T, Edelstein D, Brownlee M. The missing link: a single unifying mechanism for diabetic complications. Kidney Int Suppl. 2000; 77:S26 –S30. 5. Scivittaro V, Ganz MB, Weiss MF. AGEs induce oxidative stress and activate protein kinase C-␤II in neonatal mesangial cells. Am J Physiol Renal Physiol. 2000;278:F676 –F683. 6. Koya D, King GL. Protein kinase C activation and the development of diabetic complications. Diabetes. 1998;47:859 – 866. 7. Inoguchi T, Battan R, Handler E, Sportsman JR, Heath W, King GL. Preferential elevation of protein kinase C isoform ␤ II and diacylglycerol levels in the aorta and heart of diabetic rats: differential reversibility to glycemic control by islet cell transplantation. Proc Natl Acad Sci U S A. 1992;89:11059 –11063. 8. Kang N, Alexander G, Park JK, Maasch C, Buchwalow I, Luft FC, Haller H. Differential expression of protein kinase C isoforms in streptozotocininduced diabetic rats. Kidney Int. 1999;56:1737–1750. 9. Haller H. Postprandial glucose and vascular disease. Diabet Med. 1997; 14(suppl 3):S50 –S56. 10. Inoguchi T, Li P, Umeda F, Yu HY, Kakimoto M, Imamura M, Aoki T, Etoh T, Hashimoto T, Naruse M, Sano H, Utsumi H, Nawata H. High glucose level and free fatty acid stimulate reactive oxygen species production through protein kinase C– dependent activation of NAD(P)H oxidase in cultured vascular cells. Diabetes. 2000;49:1939 –1945. 11. Hink U, Li H, Mollnau H, Oelze M, Matheis E, Hartmann M, Skatchkov M, Thaiss F, Stahl RA, Warnholtz A, Meinertz T, Griendling K, Harrison DG , Forstermann U, Munzel T. Mechanisms underlying endothelial dysfunction in diabetes mellitus. Circ Res. 2001;88:e14 – e22. 12. Tesfamarian B, Brown ML, Cohen RA. Elevated glucose impairs endothelium-dependent relaxation by activating protein kinase C. J Clin Invest. 1991;87:1643–1648. 13. Taher MM, Garcia JG, Natarajan V. Hydroperoxide-induced diacylglycerol formation and protein kinase C activation in vascular endothelial cells. Arch Biochem Biophys. 1993;303:260 –266. 14. Dessy C, Matsuda N, Hulvershorn J, Sougnez CL, Sellke FW, Morgan KG. Evidence for involvement of the PKC-␣ isoform in myogenic contractions of the coronary microcirculation. Am J Physiol Heart Circ Physiol. 2000;279:H916 –H923. 15. Ishii H, Jirousek MR, Koya D, Takagi C, Xia P, Clermont A, Bursell S-E, Kern TS, Ballas LM, Heath WF, Stramm LE, Feener EP, King GL. Amelioration of vascular dysfunctions in diabetic rats by an oral PKC ␤ inhibitor. Science. 1996;272:728 –731.

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16. Celermajer DS. Endothelial dysfunction: does it matter? Is it reversible? J Am Coll Cardiol. 1997;30:325–333. 17. Luscher TF, Noll G. Endothelial function as an end-point in interventional trials: concepts, methods and current data. J Hypertens Suppl. 1996;14:S111–S119. 18. Nakamura J, Kato K, Hamada Y, Nakayama M , Chaya S, Nakashima E, Naruse K, Kasuya Y, Mizubayashi R, Miwa K, Yasuda Y, Kamiya H, Ienaga K, Sakakibara F, Koh N, Hotta N. A protein kinase C-␤–selective inhibitor ameliorates neural dysfunction in streptozotocin-induced diabetic rats. Diabetes. 1999;48:2090 –2095. 19. Xia P, Aiello LP, Ishii H, Jiang ZY, Park DJ, Robinson GS, Takagi H, Newsome WP, Jirousek MR, King GL. Characterization of vascular endothelial growth factor’s effect on the activation of protein kinase C, its isoforms, and endothelial cell growth. J Clin Invest. 1996;98:2018 –2026. 20. Bursell SE, King GL. Can protein kinase C inhibition and vitamin E prevent the development of diabetic vascular complications? Diabetes Res Clin Pract. 1999;45:169 –182. 21. Harris AS, Denovan-Wright EM, Hamilton LC, Robertson HA. Protein kinase C␤ II mRNA levels decrease in the striatum and cortex of transgenic Huntington’s disease mice. J Psychiatry Neurosci. 2001;26: 117–122. 22. Weeber EJ, Atkins CM, Selcher JC, Varga AW, Mirnikjoo B, Paylor R, Leitges M, Sweatt JD. A role for the ␤ isoform of protein kinase C in fear conditioning . J Neurosci. 2000;20:5906 –5914. 23. Yasunari K, Maeda K, Minami M, Yoshikawa J. HMG-CoA reductase inhibitors prevent migration of human coronary smooth muscle cells through suppression of increase in oxidative stress. Arterioscler Thromb Vasc Biol. 2001;21:937–942. 24. Ganz MB, Seftel A. Glucose-induced changes in protein kinase C and nitric oxide are prevented by vitamin E. Am J Physiol Endocrinol Metab. 2000;278:E146 –E152. 25. Osicka TM, Yu Y, Lee V, Panagiotopoulos S, Kemp BE, Jerums G. Aminoguanidine and ramipril prevent diabetes-induced increases in protein kinase C activity in glomeruli, retina and mesenteric artery. Clin Sci (Lond). 2001;100:249 –257. 26. Heart Outcomes Prevention Evaluation Study Investigators. Effects of ramipril on cardiovascular and microvascular outcomes in people with diabetes mellitus: results of the HOPE study and MICRO-HOPE substudy. Lancet. 2000;355:253–259. KEY WORDS: protein kinase C 䡲 humans

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Vascular Dysfunction in Hyperglycemia: Is Protein Kinase C the Culprit? David D. Gutterman Circ Res. 2002;90:5-7 Circulation Research is published by the American Heart Association, 7272 Greenville Avenue, Dallas, TX 75231 Copyright © 2002 American Heart Association, Inc. All rights reserved. Print ISSN: 0009-7330. Online ISSN: 1524-4571

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