Protein kinase C effects on nerve function, perfusion, Na + ,K + -ATPase activity and glutathione content in diabetic rats

Cameron, Norman E.; Cotter, Mary A.; Jack, Alison Margaret; Basso, Michael; Hohman, Thomas C.

doi:10.1007/s001250051280

Cited by 123 publications

(99 citation statements)

References 54 publications

(27 reference statements)

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“…All three mechanisms contribute to enhanced oxidative and nitrosative stress (4,5,7,9 -11) resulting from imbalance between production and neutralization of reactive oxygen species. Enhanced oxidative stress has been documented in peripheral nerve (4,5,8,(12)(13)(14), dorsal root and sympathetic ganglia (15), and vasculature (16,17) of the peripheral nervous system and has been implicated in neurovascular dysfunction and motor and sensory nerve conduction velocity (MNCV and SNCV) deficits, impaired neurotrophic support, nerve metabolic and signal transduction changes, and morphologic abnormalities characteristic for diabetes (4,5,12,14,16 -20). Evidence for the pathophysiologic role of reactive nitrogen species in PDN is also emerging (16,21).…”

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confidence: 99%

“…Improved blood glucose control reduces the risk of peripheral diabetic neuropathy (PDN), thereby implicating hyperglycemia as a leading causative factor. Diabetic hyperglycemia causes PDN via several mechanisms, among which increased aldose reductase (AR) activity (2)(3)(4)(5), nonenzymatic glycation/glycoxidation (6,7), and activation of protein kinase C (2,8) are the best studied. All three mechanisms contribute to enhanced oxidative and nitrosative stress (4,5,7,9 -11) resulting from imbalance between production and neutralization of reactive oxygen species.…”

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confidence: 99%

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Role of Poly(ADP-Ribose) Polymerase Activation in Diabetic Neuropathy

et al. 2004

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Oxidative and nitrosative stress play a key role in the pathogenesis of diabetic neuropathy, but the mechanisms remain unidentified. Here we provide evidence that poly(ADP-ribose) polymerase (PARP) activation, a downstream effector of oxidant-induced DNA damage, is an obligatory step in functional and metabolic changes in the diabetic nerve. PARP-deficient (PARP ؊/؊ ) mice were protected from both diabetic and galactose-induced motor and sensory nerve conduction slowing and nerve energy failure that were clearly manifest in the wild-type (PARP ؉/؉ ) diabetic or galactose-fed mice. Two structurally unrelated PARP inhibitors, 3-aminobenzamide and 1,5-isoquinolinediol, reversed established nerve blood flow and conduction deficits and energy failure in streptozotocin-induced diabetic rats. Sciatic nerve immunohistochemistry revealed enhanced poly(ADP-ribosyl)ation in all experimental groups manifesting neuropathic changes. Poly(ADP-ribose) accumulation was localized in both endothelial and Schwann cells. Thus, the current work identifies PARP activation as an important mechanism in diabetic neuropathy and provides the first evidence for the potential therapeutic value of PARP inhibitors in this devastating complication of diabetes. Diabetes 53: 711-720, 2004 D iabetic distal symmetric sensorimotor polyneuropathy affects up to 60 -70% of diabetic patients and is the leading cause of foot ulceration and amputation (1). Improved blood glucose control reduces the risk of peripheral diabetic neuropathy (PDN), thereby implicating hyperglycemia as a leading causative factor. Diabetic hyperglycemia causes PDN via several mechanisms, among which increased aldose reductase (AR) activity (2-5), nonenzymatic glycation/glycoxidation (6,7), and activation of protein kinase C (2,8) are the best studied. All three mechanisms contribute to enhanced oxidative and nitrosative stress (4,5,7,9 -11) resulting from imbalance between production and neutralization of reactive oxygen species. Enhanced oxidative stress has been documented in peripheral nerve (4,5,8,(12)(13)(14), dorsal root and sympathetic ganglia (15), and vasculature (16,17) of the peripheral nervous system and has been implicated in neurovascular dysfunction and motor and sensory nerve conduction velocity (MNCV and SNCV) deficits, impaired neurotrophic support, nerve metabolic and signal transduction changes, and morphologic abnormalities characteristic for diabetes (4,5,12,14,16 -20). Evidence for the pathophysiologic role of reactive nitrogen species in PDN is also emerging (16,21).The question of how oxidative and nitrosative stress causes PDN remains open. We explored the role for poly(ADP-ribose) (PAR) polymerase (PARP-1; EC 2.4.2.30), a nuclear enzyme that is activated by oxidant-induced DNA single-strand breakage and transfers ADP-ribose residues from NAD ϩ to nuclear proteins (22-25). PARP-1 is present in both endothelial cells (22,23) and Schwann cells of the peripheral nerve (26). PARP-1 activation is clearly manifest in diabetes and contributes to diabetic end...

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confidence: 99%

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confidence: 99%

Role of Poly(ADP-Ribose) Polymerase Activation in Diabetic Neuropathy

et al. 2004

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“…These concentrations were not affected by PJ34 treatment in control or diabetic rats. [17] and PKC [22], with antioxidants [23] and with other agents, all indicating that consequences of diabetic hyperglycaemia such as increased sorbitol pathway activity, oxidative stress and PKC activation do not cause irreversible changes in the peripheral nervous system, at least in the early stage of PDN. More recently, it has been shown that intervention even further downstream than hyperglycaemia, at the level of oxidative-stress-initiated, mitogen-activated protein kinase signalling cascade, successfully restores normal nerve function [24].…”

Section: Resultsmentioning

confidence: 94%

“…In contrast, the effect of PARP inhibitor on nerve perfusion, manifested by a 17% increase in NBF and the absence of a significant increase in vascular conductance, was modest. While studies from several groups [17,22,23,27,28,36], including one from our laboratory [17], suggest that vascular factor plays an important role in MNCV and SNCV deficits in PDN, growing evidence indicates that the aetiology of diabetes-induced nerve dysfunction is far more complex, and involves both vascular and non-vascular mechanisms. In particular, in diabetic and galactosaemic transgenic mice overexpressing aldose reductase (AR) specifically in the Schwann cells of the peripheral nerve under the control of the rat myelin protein zero promoter, there was a significantly greater reduction in MNCV than in the corresponding groups of non-transgenic mice with normal AR content [37].…”

Section: Resultsmentioning

confidence: 94%

Evaluation of orally active poly(ADP-ribose) polymerase inhibitor in streptozotocin-diabetic rat model of early peripheral neuropathy

Szabó

Pacher

et al. 2004

Diabetologia

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Aims/hypothesis. Poly(ADP-ribose) polymerase activation depletes NAD + and high-energy phosphates, activates protein kinase C, and affects gene expression in various tissues. This study was designed to characterise the effects of the potent, orally active poly(ADP-ribose) polymerase inhibitor PJ34 in the Wistar rat model of early diabetic neuropathy. Methods. Control and streptozotocin-diabetic rats were maintained with or without PJ34 treatment (30 mg·kg −1 ·day −1 ) for two weeks, after two weeks without treatment. Endoneurial blood flow was assessed by hydrogen clearance; metabolites and highenergy phosphates were assayed by enzymatic spectrofluorometric methods; and poly(ADP-ribose) was detected by immunohistochemistry.Results. Blood glucose concentrations were increased to a similar extent in untreated and PJ34-treated diabetic rats compared with controls. Intense poly(ADPribose) immunostaining was observed in the sciatic nerve of diabetic rats, but not in other groups. Final sciatic motor nerve conduction velocity and digital sensory nerve conduction velocity were reduced by 24% and 22% respectively in diabetic rats compared with controls (p<0.01 for both), and both were 98% corrected by PJ34 (p<0.01 vs diabetic group for both).In contrast, with PJ34 treatment, nerve blood flow showed a modest (17%) increase, and vascular conductance showed a tendency to increase. Free mitochondrial and cytosolic NAD + :NADH ratios, assessed from the glutamate and lactate dehydrogenase systems, phosphocreatine concentrations, and phosphocreatine:creatine ratios were decreased in diabetic rats and essentially normalised by PJ34. In both untreated and PJ34-treated diabetic rats, nerve glucose, sorbitol and fructose were increased to a similar extent. PJ34 did not affect any variables in control rats. Conclusions/interpretation. Short-term poly(ADP-ribose) polymerase inhibitor treatment reverses functional and metabolic abnormalities of early diabetic neuropathy. Complete normalisation of nerve blood flow is not required for correction of motor or sensory nerve conduction velocities, provided that a therapeutic agent can restore nerve energy state via direct action on Schwann cells.Keywords Energy state · Motor and sensory nerve conduction · Nerve blood flow · Oxidative and nitrosative stress · Peripheral diabetic neuropathy · PJ34 · Poly(ADP-ribose) polymerase · Rat · Sorbitol pathway of glucose metabolism · Streptozotocindiabetes

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“…Como o aumento da atividade da PKC nos vasa nervorum leva à maior resposta contrátil e redução da vasodilatação, foram realizados estudos utilizando inibidores da PKC, os quais demonstraram efeito positivo sobre a condução nervosa, o que se atribuiu à melhora do fluxo sangüíneo aos nervos (42,43).…”

Section: Fluxo Sangüíneo Vascularunclassified

O papel da proteína quinase C no desenvolvimento das complicações vasculares do diabetes mellitus

Schaan

2003

Arq Bras Endocrinol Metab

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Arq Bras Endocrinol Metab vol 47 nº 6 Dezembro 2003 654 RESUMOA mortalidade dos pacientes com diabetes (DM) é maior do que a da população em geral e decorre especialmente das doenças cardiovasculares. Os prováveis mecanismos da aterosclerose acelerada nestes pacientes são os efeitos tóxicos diretos da glicose sobre a vasculatura, a resistência à insulina e a associação do DM a outros fatores de risco para doença cardiovascular. O principal determinante do dano tecidual causado pelo DM é a hiperglicemia, resultando em aumento de glicose intra-celular, aumento de diacilglicerol (DAG) e ativação da proteína quinase C (PKC). Esta revisão tem por objetivo compilar os efeitos da hiperglicemia sobre a via DAG-PKC, a disfunção vascular relacionada a ela, e, finalmente, as novas perspectivas de tratamento das complicações crônicas vasculares do DM baseadas na inibição desta via. UMA EPIDEMIA DE DIABETES MELLITUS do tipo 2 (DM2) vem ocorrendo nos últimos anos, com tendência de crescimento na próxima déca-da (1-3). As complicações do DM2, tanto micro como macrovasculares, emergem como uma das maiores ameaças à saúde em todo o mundo, com imensos custos econômicos e sociais (4).A doença cardiovascular é responsável por até 80% das mortes em indivíduos com DM2. De fato, o risco relativo de morte por eventos cardiovasculares ajustado para a idade em diabéticos é 3 vezes maior do que o da população em geral (5). Estudo observacional recente demonstrou que o risco de morte por doença arterial coronariana em pacientes com

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Protein kinase C effects on nerve function, perfusion, Na + ,K + -ATPase activity and glutathione content in diabetic rats

Cited by 123 publications

References 54 publications

Role of Poly(ADP-Ribose) Polymerase Activation in Diabetic Neuropathy

Role of Poly(ADP-Ribose) Polymerase Activation in Diabetic Neuropathy

Evaluation of orally active poly(ADP-ribose) polymerase inhibitor in streptozotocin-diabetic rat model of early peripheral neuropathy

O papel da proteína quinase C no desenvolvimento das complicações vasculares do diabetes mellitus

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