PKC-
-dependent activation of oxidative stress in adipocytes of obese and insulin-resistant mice: role for NADPH oxidase
Ilana Talior,1
Tamar Tennenbaum,2
Toshio Kuroki,3 and
Hagit Eldar-Finkelman1
1Department of Human Genetics and Molecular Medicine, Sackler School of Medicine, Tel Aviv University, Tel Aviv; 2Faculty of Life Science, Bar-Ilan University, Ramat Gan, Israel; and 3Institute of Molecular Oncology, Showa University, Tokyo Japan
Submitted 16 August 2004
; accepted in final form 21 October 2004
 |
ABSTRACT
|
---|
Oxidative stress is thought to be one of the causative factors contributing to insulin resistance and type 2 diabetes. Previously, we showed that reactive oxygen species (ROS) production is significantly increased in adipocytes from high-fat diet-induced obese and insulin-resistant mice (HF). ROS production was also associated with the increased activity of PKC-
. In the present studies, we hypothesized that PKC-
contributes to ROS generation and determined their intracellular source. NADPH oxidase inhibitor diphenyleneiodonium chloride (DPI) reduced ROS levels by 50% in HF adipocytes, and inhibitors of NO synthase (L-NAME, 1 mM), xanthine oxidase (allopurinol, 100 µM), AGE formation (aminoguanidine, 10 µM), or the mitochondrial uncoupler (FCCP, 10 µM) had no effect. Rottlerin, a selective PKC-
inhibitor, suppressed ROS levels by
50%. However, neither GÖ-6976 nor LY-333531, effective inhibitors toward conventional PKC or PKC-
, respectively, significantly altered ROS levels in HF adipocytes. Subsequently, adenoviral-mediated expression of wild-type PKC-
or its dominant negative mutant (DN-PKC-
) in HF adipocytes resulted in either a twofold increase in ROS levels or their suppression by 20%, respectively. In addition, both ROS levels and PKC-
activity were sharply reduced by glucose depletion. Taken together, these results suggest that PKC-
is responsible for elevated intracellular ROS production in HF adipocytes, and this is mediated by high glucose and NADPH oxidase.
protein kinase C-
; insulin-resistant adipcoytes
OXIDATIVE STRESS IS THOUGHT to play a causative role in the pathogenesis of type 2 diabetes and its complications and has been shown to increase insulin resistance both in animal models and in human patients with type 2 diabetes (3, 13, 14, 29). Once generated, reactive oxygen species (ROS) can act as second messengers and can activate a number of serine/threonine and tyrosine protein kinases (13, 29, 32). In addition, ROS have detrimental effects on proteins, lipids, and DNA, and their prolonged existence promotes severe tissue damage and cell death. It has been well demonstrated that hyperglycemia is a major factor responsible for the activation of oxidative stress (7, 9, 33, 36); however, little is known about the precise cellular mechanisms responsible for ROS generation in the diabetic tissues (7, 33). Previously, it was postulated that high glucose may activate ROS via multiple processes, such as enhanced formation of advanced glycation end products (AGE), dysfunction of the mitochondrial electron transport chain, and activation of the plasma membrane NADPH oxidase (3, 7). Among these possibilities, recent attention has been focused on NADPH oxidase as a potential source of ROS production in diabetic/hyperglycemic conditions (20, 29). This enzyme, which has been found primarily in phagocytic cells (1), was recently shown to exist in nonphagocytic cells, such as endothelial cells, vascular smooth muscle cells, fibroblasts, and adipocytes (21, 23, 28, 31). The phagocytic NADPH oxidase is a multicomponent enzyme, consisting of cytosolic components p47phox, p67phox, and the small G protein rac, as well as plasma membrane oxidase subunits (reviewed in Ref. 1). Assembly of the enzyme's components in the membrane is required for its activation (1). Current evidence suggests that protein kinase C (PKC) may regulate the activation of NADPH oxidase (4, 18, 20, 29). PKCs are a family of serine/theronine protein kinases that are classified into conventional PKC (cPKC-
, -
, and -
), which are calcium and diacylglycerol (DAG) dependent; novel PKC (nPKC-
, -
, -
, and -
), which are DAG dependent but calcium independent; and atypical PKC (aPKC), which are insensitive to both calcium and DAG (34, 37). PKC has been implicated initially in NADPH oxidase-dependent activation of several responses in phagocytic cells, because PMA triggered the production of superoxides (1). Recent studies have implicated PKC in activation of NADPH oxidase and suggested that PKC may phosphorylate the cellular subunit p47phox that may induce its membranous translocation (4, 15, 38, 39, 46). PKC-
was shown to increase NADPH oxidase activity in diabetic glumeruli (24), neutrophils (12), and HL60 cells (26). Other studies have implicated PKC-
as another regulator of the oxidase (2) and reported PKC-
's requirement for complex assembly of the enzyme's components (6). Still, the role of PKC in the activation of NDPH oxidase in nonphagocytic cells has not been well established.
In recent years, it became evident that fat tissue has important and integral roles in the development of insulin resistance and type 2 diabetes (22, 43). However, little is known about the mechanisms governing endogenous oxidative stress in the fat tissue, particularly those related to diabetes. In previous studies, we showed that oxidative stress is increased in adipocytes isolated from obese, insulin-resistant C57BL/6J mice (45) [an inbred mice strain susceptible to diet-induced obesity and diabetes (44)] and demonstrated that PKC-
activity significantly increased in these cells compared with "normal" adipocytes (45). In the present study, we hypothesized that PKC-
contributes to the rise in ROS production seen in high-fat diet-induced obese and insulin-resistant mouse (HF) adipocytes and examined their cellular source. Here, we show that PKC-
is an important player affecting cellular ROS production in both normal and diabetic adipocytes and suggest that this process is mediated by high glucose and NADPH oxidase.
 |
MATERIALS AND METHODS
|
---|
Materials.
PKC-
antibodies (Sc-213) were from Santa Cruz Biotechnology (Santa Cruz, CA), PKC inhibitors Rottlerin and GÖ-6976 were purchased from Calbiochem (San Diego, CA), and LY-333531 was from Biomole (Plymouth Meeting, PA). Diphenyleneiodonium chloride (DPI), carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP), rotenone, allopurinol, N
-nitro-L-arginine methyl ester hydrochloride (L-NAME), aminoguanidine, and 2',7'-dichlorodihydrofluorescein (DCHF) were from Sigma (Rehovot, Israel).
Animal and diets.
Four-week-old mice were randomly assigned to receive either standard laboratory food or a high-fat diet containing 35% lard (Bioserve, Frenchtown, NJ), in which 55% of the calories came from fat. The animals were housed in individual cages with free access to water in a temperature-controlled facility with a 12:12-h light-dark cycle; the animals were weighed periodically. Animals were used for testing after 16 wk on their designated diets. Animals were starved for 3 h before experiments and then killed. Animal care was followed according to the Tel Aviv University Institutional Animal Care and Use Committee.
Preparation of adipocytes.
Adipocytes were isolated from the epididymal fat pad by digestion with 0.4 mg/ml collagenase (Worthington Biochemical, Freehold, NJ), as described previously (30, 45). Digested fat pads were passed through nylon mesh, and the cells were washed three times with Krebs-bicarbonate buffer (pH 7.4) containing 1% bovine serum albumin (BSA, fraction V; Boehringer Mannheim, Mannheim, Germany), 10 mM HEPES (pH 7.3), 5 mM glucose, and 200 nM adenosine. Cells were centrifuged and collected from the top layer. This process enables isolation of adipocytes from other cells, such as macrophages, that were recently shown to accumulate in adipose tissue of HF mice (47). Aliquots of cells were used to determine the cell concentrations, as described by Talior et al. (45).
Measurement of intracellular ROS generation.
The determination of ROS was based on the oxidation of the nonfluorescent DCHF into a fluorescent dye, 2',7'-dichlorofluorescein (DCF), by peroxide as previously described, with some modifications (45). In brief, adipocytes (106) were incubated with indicated reagents for 1 h followed by the addition of DCHF (30 µM) for an additional 40 min. Cells were washed, and the fluorescence was measured in triplicate samples, using a multiplate fluorometer (Fl-600, excitation at 488 nm and emission at 530 nm). Known concentrations of DCHF incubated with 20 mM NaOH were used as standards.
Tissue infections and tissue extraction.
The recombinant adenovirus vectors were constructed and used as previously described (42). Epidydimal fat tissues were removed from control or HF animals and incubated with the PKC-
recombinant adenoviruses or with a "control" virus encoding
-galactosidase (
-Gal) together with lipofectamine (10 µg/ml; Invitrogen Life Technologies Carlsbad, CA) in Dulbecco's Modified Eagle's Medium (DMEM), with low glucose (5 mM glucose), supplemented with 1% BSA for 18 h at 37°C. The tissues were then washed with Krebs-bicarbonate buffer, and adipocytes were isolated from the infected tissues as described in the previous section. Infection efficiency was monitored by X-Gal staining (of
-Gal-infected tissues), which showed an efficiency of >50% of cells. Tissues were homogenized with ice-cold buffer G (25 µg/ml each of 50 mM Tris, pH 7.5, 150 mM NaCl, 1 mM EDTA, 1 mM EGTA, 10 mM
-glycerphosphate, 50 mM NaF, 5% glycerol, 1% Triton X-100, leupeptin, aprotinin, and pepstatin A). Homogenates were centrifuged at 10,000 g, and supernatants were collected. PKC-
was immunoprecipitated from the supernatants with specific anti-PKC-
antibody subjected to gel electrophoresis and immunoblot analysis with indicated antibodies. In other sets of experiments, adipocytes were isolated from infected tissues, as described in the previous section, and incubated with indicated concentrations of glucose. ROS were measured as described earlier.
In vitro kinase activity.
PKC-
activity was assayed as previously described (45). In brief, adipocytes were lysed with buffer H (25 µg/ml each of 20 mM Tris, pH 7.5, 50 mM
-glycerophosphate, 1 mM EDTA, 1 mM EGTA, 1 mM DTT, 10 mM NaF, 5% glycerol, 1% Triton X-100, leupeptin, aprotinin, and pepstatin A). The lysates were centrifuged, and equal protein aliquots were used for PKC-
assays. The enzyme was immunoprecipitated for 2 h with anti-PKC-
antibody bound to protein A-Sepharose. The immunocomplexes were washed extensively, and the kinase reaction was performed at 30°C in 20 mM Tris·HCl, pH 7.3, with 10 mM MgCl2, 100 µM [
-32P]ATP, phosphatidylserine (PS, 40 µM), and 3 µg of histone H1 (per reaction). Reactions were terminated after 20 min by the addition of SDS-PAGE load buffer and were analyzed in 15% SDS-PAGE. In some experiments, Rottlerin was added to the immunoprecipitates to measure Rottlerin's inhibitory properties toward PKC-
.
Graphics and statistical analyses were performed by Origin 6.0 Professional software. A difference was considered to be statistically significant when P < 0.05. Quantitation of gel bands was performed by densitometry analysis.
 |
RESULTS
|
---|
To determine the source of intracellular ROS production, HF and control adipocytes (i.e., isolated from diabetic or healthy animals) were incubated with increasing concentrations of the NADPH oxidase inhibitor DPI (31). The results presented in Fig. 1A indicated that DPI decreased ROS levels in both control and HF adipocytes (by
50%). Notably, ROS levels were higher in HF adipocytes compared with control adipocytes. Nevertheless, treatment with DPI reduced ROS levels to the "normal" levels seen in control adipocytes (Fig. 1A). In contrast, inhibition of other flavoproteins that may be sensitive to DPI, such as xanthine oxidase or nitric oxide synthase (NOS), with allupurinol (10100 µM) or L-NAME (0.11 mM), respectively, had no effect on ROS levels (Fig. 1B). Finally, inhibition of AGE formation by aminoguanidine [10 µM (35)] or treatment with the mitochondrial uncoupler FCCP had no effect on ROS levels in HF adipocytes (Fig. 1B). Taken together, these results suggest that increased ROS production in HF adipocytes most likely originates from NADPH oxidase.

View larger version (18K):
[in this window]
[in a new window]
|
Fig. 1. Effect of diphenyleneiodonium chloride (DPI) on reactive oxygen species (ROS) levels in control and high-fat diet-induced obese and insulin-resistant mouse (HF) adipocytes. A: HF or control adipocytes were incubated with indicated concentrations of DPI for 1 h, followed by addition of 2',7'-dichlorodihydrofluorescein (DCHF) for another 40 min. Fluorescence of 2',7'-dichlorofluorescein (DCF) was measured in a triplicate sample, as described in MATERIALS AND METHODS. Results represent means ± SE of 5 independent experiments, presented as fold inhibition of ROS levels determined in control adipocytes. B: HF adipocytes were treated with allopurinol (100 µM), N -nitro-L-arginine methyl ester (L-NAME, 1 mM), aminoguanidine (AMG, 10 µM), and FCCP (10 µM) for 1 h before addition of DCHF. Fluorescence of DCF was measured in triplicate, as described in MATERIALS AND METHODS. Results represent means ± SE of 3 independent experiments, presented as fold inhibition of ROS levels determined in untreated HF adipocytes. *P < 0.05 treatment with DPI vs. no treatment.
|
|
We next examined whether PKC-
might affect ROS production. HF adipocytes were incubated with the selective PKC-
inhibitor Rottlerin (17) 1 h before incubation with DCFH. Indeed, increasing concentrations of Rottlerin decreased ROS levels by
50% (10 µM Rottlerin; Fig. 2A). Similar results were obtained with control adipocytes treated with Rottlerin. Interestingly, Rottlerin suppressed ROS to a greater extent in control cells than in HF adipocytes (68 ± 17 and 48 ± 6.5% control vs. HF at 10 µM Rottlerin; Fig. 2A).

View larger version (34K):
[in this window]
[in a new window]
|
Fig. 2. Effect of PKC inhibitors on ROS levels in HF adipocytes. A: HF or control adipocytes were incubated with indicated concentrations of Rottlerin for 1 h, followed by addition of DCHF for another 40 min. Fluorescence of DCF was measured in triplicate, as described in MATERIALS AND METHODS. Results represent means ± SE of 3 independent experiments, presented as fold inhibition of ROS levels of untreated adipocytes. B: PKC- was immunoprecipitated from cell extracts prepared from HF adipocytes. In vitro PKC- activity was assayed in the presence of indicated concentrations of Rottlerin, as described in MATERIALS AND METHODS. Shown is phosphorylation of histone H1 (top). To asses specificity of assays, PKC- immunoprecipitates were incubated with or without phosphatidylserine (PS; middle). To show that the phosphorylated signal is above background, assays were performed on protein A-Sepharose beads only. Presence of PKC- antibody is indicated. C: HF adipocytes were incubated with Rottlerin (5 µM), GÖ-6976 (5 µM), or LY-333531 (10 µM) for 1 h, followed by addition of DCHF for another 40 min. Fluorescence of DCF was measured in triplicate, as described in MATERIALS AND METHODS, and presented as arbitrary units. Results represent means ± SE of 3 independent experiments, presented as fold inhibition of ROS levels determined in untreated adipocytes. *P < 0.05. D: same as C, except that HF adipocytes were incubated with a combination of Rottlerin and DPI, as indicated. Results represent means ± SE of 3 independent experiments, presented as fold inhibition of ROS levels determined in untreated adipocytes.
|
|
There is a debate about the ability of Rottlerin to inhibit PKC-
(10, 16, 17); therefore, we examined its in vitro effect on adipocyte PKC-
. The enzyme was immunoprecipitated from lysates prepared from HF adipocytes, and PKC-
activity was assayed in the immunoprecipitate complex with increasing concentrations of Rottlerin. The ability of PKC-
to phosphorylate the substrate histone H1 was significantly reduced by 5 and 10 µM Rottlerin (Fig. 2B, top), indicating that Rottlerin can inhibit PKC-
in vitro. To further confirm the specificity of the assay, we show that the kinase activity was dependent on the PKC lipid activator PS (Fig. 2B, middle). In addition, the assays were performed in protein A beads to show that the phopshorylated signal is above background (Fig. 2B, bottom). These studies suggested that PKC-
is involved in ROS production, and additional studies strengthen this point (Fig. 3).
We further examined whether other PKC isoforms affect ROS in HF adipocytes. Treatment with GÖ-6976, an effective inhibitor toward classical PKC isoforms [i.e.,
,
,
(11)], or the selective PKC-
inhibitor LY-333531 slightly reduced ROS levels (10 ± 1.5 and 22 ± 1.2%, respectively; Fig. 2C). These results suggested that conventional PKC isoforms are probably not involved in ROS production. They do not exclude, however, the possibility that novel or atypical PKC isoforms are involved. We next examined the effect of a combination treatment of Rottlerin with DPI on ROS levels. Apparently, administration of both Rottlerin and DPI into HF adipocytes or control adipocytes did not further enhance the reduction in ROS levels achieved by each reagent added separately (Fig. 2D). These results suggested that Rottlerin and DPI affect ROS via a common intracellular target, most likely NADPH oxidase.
To further assess the role of PKC-
in ROS production, PKC-
proteins were overexpressed in control and HF adipocytes by use of adenovirus-mediated gene delivery. An adenoviral vector encoding
-Gal was used as a control. Infection protocols were developed and optimized. Tissues infected with
-Gal construct were processed for X-Gal staining, and blue staining of the tissue shown in Fig. 3A confirmed the expression of
-Gal. In addition, adipocytes were isolated from
-Gal-infected tissues and processed for X-Gal staining as well. Blue staining of adipocytes confirmed the expression of
-Gal in adipocytes (
30% efficiency; Fig. 3B). Fat tissues were infected with either the recombinant adenovirus encoding wild-type (WT) PKC-
(WT-PKC-
) or its kinase dead (DN) mutant, DN-PKC-
. The degree of expression of PKC-
protein above endogenous levels was determined by Western blot analysis (Fig. 3C). Densitometry analysis of PKC-
bands indicated that overexpression of WT-PKC-
or DN-PKC-
was 5 ± 1.6-fold and 3 ± 1-fold, respectively, above endogenous PKC-
of
-Gal-infected adipocytes. ROS levels were determined in control or HF adipocytes that expressed the PKC-
proteins. Overexpression of WT-PKC-
resulted in a twofold increase in ROS levels in both control and HF adipocytes, compared with the
-Gal-infected cells (Fig. 3D). In contrast, expression of DN-PKC-
suppressed ROS levels by 28 ± 1.9 or 20 ± 1.5% in control or HF adipocytes, respectively (Fig. 3D). These results suggest that PKC-
contributes to ROS production in both normal and diabetic adipocytes. Notably, the effect of DN-PKC-
on ROS suppression was greater in control cells than in HF adipocytes. This was because PKC-
activity is higher in HF adipocytes (45), therefore "less" affected by inhibition.
We next examined whether ROS and PKC-
are regulated by glucose. This question was of particular importance because glucose uptake is dramatically increased in HF adipocytes (45). Incubation of HF adipocytes with decreased glucose concentrations gradually decreased ROS levels (Fig. 4A). Similarly, increased PKC-
activity correlated with increased glucose concentrations (Fig. 4B). Moreover, suppression of ROS in reduced glucose concentrations was stronger in DN-PKC-
-overexpressing cells than in control
-Gal-expressing cells (Fig. 4C). These results suggested a functional link between glucose, PKC-
activity and ROS production.
 |
DISCUSSION
|
---|
The present study demonstrates the novel findings that PKC-
enhances oxidative stress in insulin-resistant adipocytes and provides evidence that this process is most likely mediated by NADPH oxidase. This oxidase, which has been described mainly in phagocytic cells (1), was recently shown to exist in nonphagocytic cells (1, 31). However, the mode of activation of this oxidase in these cells is not known well. In 3T3-L1 adipocytes, it has been shown that ROS production was largely sensitive to the flavoprotein inhibitor DPI, a potential NADPH oxidase inhibitor (31). We report that DPI significantly decreased ROS in HF dipocytes. On the other hand, inhibitors for xanthine oxidase and NOS, and for AGE formation, or the mitochondrial uncoupler FCCP, had no effect on ROS, further suggesting that the major source for enhanced ROS production is NADPH oxidase. Our studies also suggest that PKC-
is an important regulator of ROS in HF adipocytes. Rottlerin, a selective PKC-
inhibitor, suppressed ROS levels, and adenoviral-mediated expression of PKC-
protein affected ROS: expression of the dominant negative mutant PKC-
reduced ROS levels by 30%, and overexpression of the wild-type PKC-
enhanced ROS levels twofold (Fig. 3D). It is noteworthy that PKC-
has been previously implicated in NADPH oxidase activation in various cells (2) and has been shown to be recruited to the complex assembly formation of the enzyme's components (6). The mechanisms by which PKC-
activates NADPH oxidase are not fully clear. It may be that PKC-
phosphorylates the cytoplasmic subunits of the oxidase, such as p47phox, and initiates its translocation of the membrane (15, 38). Future studies should further address this problem.
PKC-
regulates intracellular ROS production in normal adipocytes, which indicates that its role is not unique to HF adipocytes. Rather, abnormal regulation of PKC-
in HF adipocytes leads to sustained/enhanced activation of ROS production. These differences are crucial for the well-being of the cell. Although PKC-
and ROS are tightly regulated in normal adipocytes, their activity levels are increased in HF adipocytes, provoking/enhancing intracellular pathways, which leads to the detrimental effects associated with oxidative stress (3, 13, 14, 29).
How is PKC-
activated in HF adipocytes? Our studies suggest two alternative routes that can activate PKC-
, glucose, and oxidative stress. Hyperglycemia is a known factor activating PKCs, and it has been shown by numerous studies that, in cells chronically exposed to high glucose or in hypergluycemic animals, PKC is activated (20, 27, 29, 48). The fact that glucose suppressed PKC-
(Fig. 4B) suggested that high glucose influx into HF adipocytes (45) activates PKC-
. This, in turn, promotes the activation of NADPH oxidase. It is noteworthy that similar observations were recently reported in vascular cells, showing that high glucose activated NADPH oxidase in a PKC-dependent fashion, although the specific PKC isoform has not been determined (19, 20). An additional route for activation of PKC-
is oxidative stress. This has been initially shown in H2O2-treated COS-7 cells (25) and vascular muscle cells (41). In HF adipocytes, we previously showed that oxidative stress activates PKC-
(45). Thus it appears that a vicious cycle operates between ROS and PKC-
. Once activated by glucose, PKC-
enhances ROS production, which, in turn, feedback loops into the activation of PKC-
(Fig. 5). These consequential events amplify oxidative stress and may be attenuated by glucose depletion or inhibition of PKC-
.
In summary, we propose a new role for PKC-
in the activation of oxidative stress in HF adipocytes and suggest that its inhibition may be a way to prevent the deleterious effects of oxidative stress that develop in the diabetic fat tissue.
 |
GRANTS
|
---|
This work was supported by the Israeli Diabetes Foundation and by the Annual Award of the Hendrik and Irene Gutwirth Research Prize in Diabetes Mellitus, which was awarded to H. Eldar-Finkelman.
 |
FOOTNOTES
|
---|
Address for reprint requests and other correspondence: H. Eldar-Finkelman, Dept. of Human Genetics and Molecular Medicine, Sackler School of Medicine, Tel-Aviv University, Tel-Aviv 69978, Israel (E-mail: heldar{at}post.tau.ac.il)
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
 |
REFERENCES
|
---|
- Babior BM. NADPH oxidase: an update. Blood 93: 14641476, 1999.[Free Full Text]
- Bankers-Fulbright JL, Kita H, Gleich GJ, and O'Grady SM. Regulation of human eosinophil NADPH oxidase activity: a central role for PKCdelta. J Cell Physiol 189: 306315, 2001.[CrossRef][ISI][Medline]
- Baynes JW. Role of oxidative stress in development of complications in diabetes. Diabetes 40: 405412, 1991.[Abstract]
- Bouin AP, Grandvaux N, Vignais PV, and Fuchs A. p40(phox) Is phosphorylated on threonine 154 and serine 315 during activation of the phagocyte NADPH oxidase. Implication of a protein kinase c-type kinase in the phosphorylation process. J Biol Chem 273: 3009730103, 1998.[Abstract/Free Full Text]
- Braiman L, Alt A, Kuroki T, Ohba M, Bak A, Tennenbaum T, and Sampson SR. Protein kinase Cdelta mediates insulin-induced glucose transport in primary cultures of rat skeletal muscle. Mol Endocrinol 13: 20022012, 1999.[Abstract/Free Full Text]
- Brown GE, Stewart MQ, Liu H, Ha VL, and Yaffe MB. A novel assay system implicates PtdIns(3,4)P(2), PtdIns(3)P, and PKC delta in intracellular production of reactive oxygen species by the NADPH oxidase. Mol Cell 11: 3547, 2003.[ISI][Medline]
- Brownlee M. Biochemistry and molecular cell biology of diabetic complications. Nature 414: 813820, 2001.[CrossRef][ISI][Medline]
- Caruso M, Maitan MA, Bifulco G, Miele C, Vigliotta G, Oriente F, Formisano P, and Beguinot F. Activation and mitochondrial translocation of protein kinase Cdelta are necessary for insulin stimulation of pyruvate dehydrogenase complex activity in muscle and liver cells. J Biol Chem 276: 4508845097, 2001.[Abstract/Free Full Text]
- Ceriello A. Oxidative stress and glycemic regulation. Metabolism 49: 2729, 2000.[ISI][Medline]
- Davies SP, Reddy H, Caivano M, and Cohen P. Specificity and mechanism of action of some commonly used protein kinase inhibitors. Biochem J 351: 95105, 2000.[CrossRef][ISI][Medline]
- Davis PD, Elliott LH, Harris W, Hill CH, Hurst SA, Keech E, Kumar MK, Lawton G, Nixon JS, and Wilkinson SE. Inhibitors of protein kinase C. 2. Substituted bisindolylmaleimides with improved potency and selectivity. J Med Chem 35: 9941001, 1992.[ISI][Medline]
- Dekker LV, Leitges M, Altschuler G, Mistry N, McDermott A, Roes J, and Segal AW. Protein kinase C-beta contributes to NADPH oxidase activation in neutrophils. Biochem J 347: 285289, 2000.[CrossRef][ISI][Medline]
- Evans JL, Goldfine ID, Maddux BA, and Grodsky GM. Oxidative stress and stress-activated signaling pathways: a unifying hypothesis of type 2 diabetes. Endocr Rev 23: 599622, 2002.[Abstract/Free Full Text]
- Fiala E, Westendorf J, and West IC. Radicals and oxidative stress in diabetes. Toxicology 146: 8392, 2000.[CrossRef][ISI][Medline]
- Fontayne A, Dang PM, Gougerot-Pocidalo MA, and El-Benna J. Phosphorylation of p47phox sites by PKC alpha, beta II, delta, and zeta: effect on binding to p22phox and on NADPH oxidase activation. Biochemistry 41: 77437750, 2002.[CrossRef][ISI][Medline]
- Frank GD, Saito S, Motley ED, Sasaki T, Ohba M, Kuroki T, Inagami T, and Eguchi S. Requirement of Ca(2+) and PKCdelta for Janus kinase 2 activation by angiotensin II: involvement of PYK2. Mol Endocrinol 16: 367377, 2002.[Abstract/Free Full Text]
- Gschwendt M, Muller HJ, Kielbassa K, Zang R, Kittstein W, Rincke G, and Marks F. Rottlerin, a novel protein kinase inhibitor. Biochem Biophys Res Commun 1999: 9398, 1994.
- Heitzer T, Wenzel U, Hink U, Krollner D, Skatchkov M, Stahl RA, MacHarzina R, Brasen JH, Meinertz T, and Munzel T. Increased NAD(P)H oxidase-mediated superoxide production in renovascular hypertension: evidence for an involvement of protein kinase C. Kidney Int 55: 252260, 1999.[CrossRef][ISI][Medline]
- Inoguchi T, Li P, Umeda F, Yu HY, Kakimoto M, Imamura M, Aoki T, Etoh T, Hashimoto T, Naruse M, Sano H, Utsumi H, and 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 49: 19391945, 2000.[Abstract]
- Inoguchi T, Sonta T, Tsubouchi H, Etoh T, Kakimoto M, Sonoda N, Sato N, Sekiguchi N, Kobayashi K, Sumimoto H, Utsumi H, and Nawata H. Protein kinase C-dependent increase in reactive oxygen species (ROS) production in vascular tissues of diabetes: role of vascular NAD(P)H oxidase. J Am Soc Nephrol 14: S227S232, 2003.[Abstract/Free Full Text]
- Jones SA, O'Donnell VB, Wood JD, Broughton JP, Hughes EJ, and Jones OT. Expression of phagocyte NADPH oxidase components in human endothelial cells. Am J Physiol Heart Circ Physiol 271: H1626H1634, 1996.[Abstract/Free Full Text]
- Kahn BB and Flier JS. Obesity and insulin resistance. J Clin Invest 106: 473481, 2000.[Free Full Text]
- Kashiwagi A, Shinozaki K, Nishio Y, Maegawa H, Maeno Y, Kanazawa A, Kojima H, Haneda M, Hidaka H, Yasuda H, and Kikkawa R. Endothelium-specific activation of NAD(P)H oxidase in aortas of exogenously hyperinsulinemic rats. Am J Physiol Endocrinol Metab 277: E976E983, 1999.[Abstract/Free Full Text]
- Kitada M, Koya D, Sugimoto T, Isono M, Araki S, Kashiwagi A, and Haneda M. Translocation of glomerular p47phox and p67phox by protein kinase C-beta activation is required for oxidative stress in diabetic nephropathy. Diabetes 52: 26032614, 2003.[Abstract/Free Full Text]
- Konishi H, Tanaka M, Takemura Y, Matsuzaki H, Ono Y, Kikkawa U, and Nishizuka Y. Activation of protein kinase C by tyrosine phosphorylation in response to H2O2. Proc Natl Acad Sci USA 94: 1123311237, 1997.[Abstract/Free Full Text]
- Korchak HM and Kilpatrick LE. Roles for beta II-protein kinase C and RACK1 in positive and negative signaling for superoxide anion generation in differentiated HL60 cells. J Biol Chem 276: 89108917, 2001.[Abstract/Free Full Text]
- Koya D and King GL. Protein kinase C activation and the development of diabetic complications. Diabetes 47: 859866, 1998.[Abstract]
- Krieger-Brauer HI, Medda PK, and Kather H. Insulin-induced activation of NADPH-dependent H2O2 generation in human adipocyte plasma membranes is mediated by Galphai2. J Biol Chem 272: 1013510143, 1997.[Abstract/Free Full Text]
- Kuroki T, Isshiki K, and King GL. Oxidative stress: the lead or supporting actor in the pathogenesis of diabetic complications. J Am Soc Nephrol 14: S216220, 2003.[Free Full Text]
- Lawrence JC Jr, Guinovart JJ, and Larner J. Activation of rat adipocyte glycogen synthase by insulins. J Biol Chem 252: 444450., 1977.[Abstract]
- Mahadev K, Wu X, Zilbering A, Zhu L, Lawrence JT, and Goldstein BJ. Hydrogen peroxide generated during cellular insulin stimulation is integral to activation of the distal insulin signaling cascade in 3T3-L1 adipocytes. J Biol Chem 276: 4866248669, 2001.[Abstract/Free Full Text]
- Mahadev K, Zilbering A, Zhu L, and Goldstein BJ. Insulin-stimulated hydrogen peroxide reversibly inhibits protein-tyrosine phosphatase 1b in vivo and enhances the early insulin action cascade. J Biol Chem 276: 2193821942, 2001.[Abstract/Free Full Text]
- Marfella R, Quagliaro L, Nappo F, Ceriello A, and Giugliano D. Acute hyperglycemia induces an oxidative stress in healthy subjects. J Clin Invest 108: 635636, 2001.[Free Full Text]
- Mellor H and Parker PJ. The extended protein kinase C superfamily. Biochem J 332: 281292, 1998.[ISI][Medline]
- Nilsson BO. Biological effects of aminoguanidine: an update. Inflamm Res 48: 509515, 1999.[CrossRef][ISI][Medline]
- Nishikawa T, Edelstein D, Du XL, Yamagishi S, Matsumura T, Kaneda Y, Yorek MA, Beebe D, Oates PJ, Hammes HP, Giardino I, and Brownlee M. Normalizing mitochondrial superoxide production blocks three pathways of hyperglycaemic damage. Nature 404: 787790, 2000.[CrossRef][ISI][Medline]
- Nishizuka Y. Protein kinase C and lipid signaling for sustained cellular responses. FASEB J 9: 484496, 1995.[Abstract/Free Full Text]
- Reeves EP, Dekker LV, Forbes LV, Wientjes FB, Grogan A, Pappin DJ, and Segal AW. Direct interaction between p47phox and protein kinase C: evidence for targeting of protein kinase C by p47phox in neutrophils. Biochem J 344 Pt 3: 859866, 1999.
- Regier DS, Waite KA, Wallin R, and McPhail LC. A phosphatidic acid-activated protein kinase and conventional protein kinase C isoforms phosphorylate p22(phox), an NADPH oxidase component. J Biol Chem 274: 3660136608, 1999.[Abstract/Free Full Text]
- Rosenzweig T, Aga-Mizrachi S, Bak A, and Sampson SR. Src tyrosine kinase regulates insulin-induced activation of protein kinase C (PKC) delta in skeletal muscle. Cell Signal 16: 12991308, 2004.[CrossRef][ISI][Medline]
- Saito S, Frank GD, Mifune M, Ohba M, Utsunomiya H, Motley ED, Inagami T, and Eguchi S. Ligand-independent trans-activation of the platelet-derived growth factor receptor by reactive oxygen species requires protein kinase C-delta and c-Src. J Biol Chem 277: 4469544700, 2002.[Abstract/Free Full Text]
- Shen S, Alt A, Wertheimer E, Gartsbein M, Kuroki T, Ohba M, Braiman L, Sampson SR, and Tennenbaum T. PKCdelta activation: a divergence point in the signaling of insulin and IGF-1-induced proliferation of skin keratinocytes. Diabetes 50: 255264, 2001.[Abstract/Free Full Text]
- Spiegelman BM and Flier JS. Adipogenesis and obesity: rounding out the big picture. Cell 87: 377389, 1996.[ISI][Medline]
- Surwit RS, Kuhn CM, Cochrane C, McCubbin JA, and Feinglos MN. Diet-induced type II diabetes in C57BL/6J mice. Diabetes 37: 11631167, 1988.[Abstract]
- Talior I, Yarkoni M, Bashan N, and Eldar-Finkelman H. Increased glucose uptake promotes oxidative stress and PKC-
activation in adipocytes of obese, insulin-resistant mice. Am J Physiol Endocrinol Metab 285: E295E302, 2003.[Abstract/Free Full Text]
- Venugopal SK, Devaraj S, Yang T, and Jialal I. Alpha-tocopherol decreases superoxide anion release in human monocytes under hyperglycemic conditions via inhibition of protein kinase C-alpha. Diabetes 51: 30493054, 2002.[Abstract/Free Full Text]
- Xu H, Barnes GT, Yang Q, Tan G, Yang D, Chou CJ, Sole J, Nichols A, Ross JS, Tartaglia LA, and Chen H. Chronic inflammation in fat plays a crucial role in the development of obesity-related insulin resistance. J Clin Invest 112: 18211830, 2003.[Abstract/Free Full Text]
- Zierath JR, Krook A, and Wallberg-Henriksson H. Insulin action and insulin resistance in human skeletal muscle. Diabetologia 43: 821835, 2000.[CrossRef][ISI][Medline]