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Aldose Reductase Regulates High Glucose-Induced Ectodomain Shedding of Tumor Necrosis Factor (TNF)- via Protein Kinase C- and TNF- Converting Enzyme in Vascular Smooth Muscle Cells

Department of Biochemistry and Molecular Biology (A.B.M.R., K.V.R., S.K.S.), University of Texas Medical Branch, Galveston, Texas 77555-0647; and Institute of Molecular Cardiology (S.S., A.B.), University of Louisville, Louisville, Kentucky 40202

Address all correspondence and requests for reprints to: Satish K. Srivastava, Department of Biochemistry and Molecular Biology, University of Texas Medical Branch, 301 University Boulevard, Galveston, Texas 77555-0647. E-mail: ssrivast{at}utmb.edu.

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
Chronic low-grade inflammation has emerged as a key contributor to the cardiovascular complications of diabetes, however, the mechanisms by which diabetes increases inflammation remain poorly understood. Here, we report that exposure to high glucose (HG) stimulates ectodomain shedding of TNF- from rat aortic smooth muscle cells in culture. Our results show that exposure to HG decreases membrane-associated TNF-. This decrease in unprocessed TNF- was prevented by the aldose reductase (AR) inhibitor sorbinil and AR small interference RNA. Treatment with HG, but not equimolar mannitol or 3-O-methyl glucose, resulted in phosphorylation and activation of TNF- converting enzyme (TACE) (ADAM17), which were attenuated by sorbinil or AR-specific small interference RNA. HG-induced TACE phosphorylation and TNF- processing were also prevented by TNF- protease inhibitor-1, an inhibitor of TACE. Inhibition of protein kinase C (PKC)- by rottlerin prevented HG-induced TACE activation and the accumulation of unprocessed TNF-. Treatment with sorbinil decreased elevated levels of circulating TNF- in streptozotocin-treated diabetic rats. Sorbinil treatment also decreased the expression of TNF-, matrix metalloproteinase-2, matrix metalloproteinase-9, and increased tissue inhibitor of metalloproteinase-3 in vascular smooth muscle cells treated with HG and in balloon-injured carotid arteries of diabetic rats. These results indicate that HG-induced TNF- shedding could be attributed to TACE activation, which is regulated, in part, by PKC- and AR. Therefore, inhibition of TACE by TNF- protease inhibitor-1, or pharmacological inhibition of PKC- or AR may represent useful strategies for treating vascular inflammation associated with diabetes.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
Diabetes is associated with the development of chronic low-grade inflammation (1, 2). Extensive clinical evidence demonstrates that both type 1 (3, 4) and type 2 diabetes (5, 6, 7, 8) are associated with an increase in circulating markers of inflammation, and that high levels of inflammation increase cardiovascular mortality risk in diabetics (9, 10, 11). An increase in inflammation has also been reported in tissues of animals with diabetes (12, 13). Extant data suggest that inflammation plays a circuitous role in diabetes. An increase in inflammation is a significant feature of the prediabetic states of obesity (1, 14), and metabolic syndrome (15), indicating that inflammation may have a causal role in the development of insulin resistance and early pathogenesis of diabetes (7, 16). In established diabetes, inflammation is associated with microcirculatory abnormalities (3), vascular dysfunction (5), and atherogenesis (17), suggesting that it is a symptom or a manifestation of diabetic tissue injury.

Mechanisms that link inflammation to the development of diabetes and diabetic complications are poorly understood. Although inflammatory cytokines such as TNF- have induced insulin resistance by stimulating serine phosphorylation of IRS-1 (18, 19), the processes by which diabetes induces and sustains inflammation are less clear. Previous studies show that hyperglycemia is an important contributor to inflammation. In cell culture experiments, high glucose (HG) stimulates inflammatory signaling that activates nuclear factor-B (NF-B) (20, 21, 22). In humans, an increase in plasma glucose leads to an acute increase in the levels of circulating cytokines, even in healthy nondiabetic individuals (23). Our studies show that vascular smooth muscle cells (VSMCs), when exposed to high levels of glucose, secrete TNF-, which then binds to the TNF- receptor, leading to stimulation of NF-B-mediated gene transcription (24). HG-induced release of preformed TNF- to TNF--mediated NF-B activation could be prevented by soluble TNF receptors, indicating the presence of an autocrine/paracrine loop linking TNF- release to subsequent NF-B activation. Nevertheless, the mechanisms by which HG stimulates TNF- release remain unknown.

TNF- is initially produced as a membrane-bound precursor that is processed by TNF- converting enzyme (TACE), a recently identified type I membrane-bound metalloproteinase (ADAM-17) (25, 26). TACE is activated by phosphorylation, and activated phospho-TACE cleaves membrane-bound pro-TNF-, which has a molecular mass of 27 kDa, into an active, soluble form of 19 kDa (27, 28). Recent studies show that inhibition of TACE prevents several inflammatory conditions, including those that are associated with hyperglycemia (29, 30, 31). However, it is unclear whether TACE is expressed in vascular tissues and whether activation of TACE is an essential step in the processing of TNF- in these tissues when they encounter high levels of glucose. Therefore, the current study was designed to examine the effects of HG on TACE and the role of TACE in regulating TNF- release. Based on the results of our previous studies on VSMCs, which showed that HG-induced release of TNF- is prevented by inhibiting the aldose reductase (AR)-mediated activation of protein kinase C (PKC), we investigated the role of AR in regulating HG-induced TACE activation and TNF- processing. The results presented here suggest that AR is an obligatory mediator of HG-induced TACE activation, and point toward a new link between cardiovascular inflammation and activation of the rate-limiting enzyme of the polyol pathway.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Materials
PBS, trypsin, penicillin/streptomycin solution, fetal bovine serum (FBS), DMEM, and Opti-MEM were purchased from Life Technologies, Inc. (Gaithersburg, MD). Antibodies against rat TNF- were purchased from Calbiochem (San Diego, CA). Antibodies against TACE and tissue inhibitor of metalloproteinase (TIMP)-3 were purchased from Santa Cruz Biotechnology, Inc. (Santa Cruz, CA). Anti-matrix metalloproteinase (MMP)-2 and MMP-9 antibodies were obtained from Cell Signaling Technology, Inc. (Danvers, MA). The fluorescein isothiocyanate-TNF- and fluorescein isothiocyanate-IgG were purchased from eBioscience (San Diego, CA). The 7-amino-actinomycin D staining solution was purchased from BD PharMingen (San Diego, CA). Sorbinil was a gift from Pfizer Inc. (New York, NY). The TNF- protease inhibitor-1 (TAPI-1) and TACE-FRET substrate peptide were purchased from Peptides International Inc. (Louisville, KY). The PKC- inhibitor, Rottlerin, was purchased from EMD Biosciences, Inc. (Gibbstown, NJ). AR inhibitors (ARIs) sorbinil and zopolrestat were gifts from Pfizer, and tolrestat was obtained from American Home Products (Wyeth Pharmaceuticals Inc., Philadelphia, PA). All other reagents were of the highest purity available.

Cell culture
Rat VSMCs were isolated from adult rat aorta and characterized by smooth muscle cell-specific -actin expression. The VSMCs were maintained and grown in endotoxin-free DMEM supplemented with 10% FBS and 1% penicillin/streptomycin at 37 C in a humidified atmosphere of 5% CO₂ as described before (32). For glucose-stimulation experiments, the cells were serum starved in medium containing 0.1% serum and 5.5 mM glucose. After 24 h the medium was replaced with fresh medium containing 25 mM glucose (HG) or 5.5 mM glucose [normal glucose (NG)] with ARIs or vehicle (25% dimethylsulfoxide). The high-glucose medium was prepared fresh before use by adding 19.5 mM glucose to DMEM containing 5.5 mM glucose.

RNA interference ablation of AR
Small interference RNA (siRNA) specific to AR was designed, synthesized, and used to ablate AR in VSMCs as described by us earlier (24). Briefly, VSMCs grown in DMEM supplemented with 10% FBS were washed with Opti-MEM and incubated for 60 min with Opti-MEM media before transfection with siRNA oligonucleotides. The cells were incubated with 1 µM AR siRNA or scrambled control oligonucleotides using Lipofectamine Plus (15 µg/ml; Invitrogen Corp., Carlsbad, CA) as the transfection reagent. After 12 h the medium was replaced with fresh DMEM (containing 10% FBS), and the samples were incubated for another 12 h. Using this procedure a VSMC transfection efficacy of approximately 90% was obtained, and the levels of AR protein and activity were reduced by more than 95% (24).

Determination of TACE phosphorylation
Confluent (75–80%) VSMCs were serum starved overnight in DMEM containing 0.1% FBS. The medium was then replaced with fresh phosphate-free DMEM (Invitrogen) containing 0.1% FBS with or without ARIs and 0.5 mCi [³³P]orthophosphate (GE Healthcare Bio-Sciences Corp., Piscataway, NJ), and incubated for 30 min before treatment with HG. Cells were washed twice with ice-cold PBS, disrupted in cold Nonidet P-40 (NP-40) lysis buffer containing 50 mM Tris-HCl (pH 8.0), 150 mM NaCl, 1% NP-40, and 1x protease inhibitor cocktail (Sigma Chemical Co., St. Louis, MO). The lysates were cleared by centrifugation. TACE was immunoprecipitated using 50 µg cell lysate protein incubated overnight with 5 µg anti-TACE at 4 C, and the immune complexes were collected using an immunoprecipitation kit (Sigma Chemical). The immune complexes that were eluted were resolved on SDS-PAGE, followed by autoradiography and densitometric analysis.

Measurement of TACE activity
TACE activity in lysates of VSMCs was measured using a fluorescence-quenching substrate for ADAM17/TNF- (Peptide International) as described earlier (33). Briefly, VSMCs were treated with HG or HG plus ARI for 5 d, and the cells were collected in TACE-activity buffer containing 50 mM Tris-HCl (pH 7.4), 25 mM ZnCl₂, 4% glycerol, and 0.5% NP-40. The cells were lysed by freeze-thaw, and the supernatants were collected. Equal amounts of cell lysates were incubated with 5 µM TACE substrate for 30 min at 37 C, and changes in fluorescence were monitored at excitation wavelength (_ex) = 320 nm and emission wavelength (_em) = 420 nm using a fluorescence plate reader. Fluorescence quenching was used to calculate percent activity using appropriate control and blank values.

Western blot analysis
To examine the effect of AR inhibition on HG-induced expression of TIMP-3, TACE, MMP-2, MMP-9, and TNF-, growth-arrested VSMCs were treated with HG in the absence and presence of ARIs for indicated times. Extracts containing cytoplasmic and membrane-bound proteins were prepared as described earlier (34). Equal amounts of cytosolic or membrane-bound protein extracts were subjected to Western analyses using antibodies directed against TIMP-3, TACE, MMP-2, MMP-9, TNF-, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and actin. The antigen-antibody complexes were detected by enhanced chemiluminescence (Pierce, Rockford, IL). All blots were probed with either GAPDH or actin as a loading control, and densitometric analysis was performed using Kodak Image station 2000R (Eastman Kodak Co., Rochester, NY).

Balloon injury of carotid arteries
Sprague Dawley rats (250–300 g) were made diabetic by a single injection of streptozotocin (65 mg/kg ip) as described earlier (35). Blood glucose was monitored after 2 wk, and only the rats with blood glucose more than 16 mmol/liter entered the study. Control rats were treated with the vehicle only. Their blood glucose was less than 6 mmol/liter. Four weeks after streptozotocin injection, the carotid arteries were injured by a balloon as described before (21, 25). One day before injury and throughout the observation time, 10 rats in each group were gavage fed either tolrestat (15 mg/kg · d) or vehicle (2.5 mM sodium bicarbonate). The injured and uninjured arteries were perfusion fixed with 4% paraformaldehyde and stored in 70% ethanol. All animal protocols were approved by the Institutional Animal Care Committee.

Immunohistochemical studies
For analysis, paraffin sections of the arteries were warmed at 60 C for 1 h and then deparaffinized in xylene. The sections were then rehydrated by passing through 100, 95, 80, and 70% ethanol, and finally washed in deionized water. After blocking the peroxidase activity with 3% H₂O₂, the slides were rinsed in PBS twice and incubated overnight in the blocking solution (2% BSA, 0.1% Triton X-100, 2% normal rabbit IgG, and 2% normal goat serum) at 4 C. The slides were incubated with antibodies directed against TNF-, MMP-2, MMP-9, TIMP-3, and TACE for 1 h at room temperature. The slides were stained using universal LSAB+ System-horseradish peroxidase (DakoCytomation, Carpinteria, CA) and counter stained with hematoxylin. The sections were examined under bright-field light microscopy (EPI-800 microscope; Nikon Corp., Tokyo, Japan) and photographed with a Nikon camera fitted to the microscope.

Quantification of TNF- in rat serum
After indicated treatment, the rats were euthanized, and their blood was collected in heparin-coated Vacutainers (BD, Franklin Lakes, NJ) by heart puncture. The blood was incubated for 1 h at 37 C and centrifuged at 1000 rpm for 20 min. The supernatant (plasma) was collected. To measure TNF- levels in cultured cell supernatants, after the treatments, collected the cell culture medium and used directly for the assay. Levels of TNF- were measured according to the manufacturer’s instructions using a rat TNF- sandwich ELISA kit obtained from BD Biosciences (San Jose, CA). Known concentrations of rat TNF- were used to generate a standard curve. The assay was linear between 5 and 1000 pg/ml. This was well within the range of TNF- levels measured in the present study. The reaction was initiated by the addition of 0.1 ml of the serum and read at 450 nm on an ELISA plate reader. The results obtained are expressed as pg/ml plasma.

Statistical analysis
Data are presented as mean ± SEM, and the P values were determined using the one-way ANOVA and the unpaired Student’s t test.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
HG-induced TNF- shedding
To understand how HG causes TNF- release, we examined the mechanism of TNF- processing and shedding. As shown in Fig. 1A, addition of HG to the medium caused a time-dependent decrease in the level of unprocessed TNF- associated with the cell membrane. Time course studies showed a 30–40% decrease in membrane-associated TNF- within 20–30 min of HG exposure. However, when the duration of high-glucose exposure was more than 60 min, a partial recovery in the levels of membrane bound TNF- (mTNF-) was observed (Fig. 1A). These results indicate that HG rapidly stimulates the shedding of processed TNF- from the membrane and that this process results in the appearance of TNF- in the culture media.

View larger version (27K): [in this window] [in a new window]   FIG. 1. Role of AR in HG-induced shedding of mTNF- by VSMCs. Serum-starved VSMCs were either left untreated (A) or preincubated (B) with sorbinil (10 µM), and AR-siRNA and control siRNA transfected cells in 5.5 mM glucose (NG) medium were treated with 19.5 mM glucose (HG) for the indicated times (C). Time point 0 min represents NG. Cell extracts containing membranes were subjected to Western analysis as described in Materials and Methods. Western blots were developed using anti-TNF- and antiactin antibodies. Bars represent mean ± SEM; (n = 3) values of normalized intensity measured by densitometric scanning. *, P < 0.001 and **, P < 0.05 vs. 0 min HG; #, P < 0.001 vs. HG. D, Serum-starved VSMCs cultured in NG were treated with sorbinil, followed by incubation with HG for the indicated time points. Cells were fixed and stained with anti-TNF- antibodies, followed by counterstaining with nuclear stain and were photographed at the indicated times after exposure to HG.

Inhibition of AR prevents HG-induced TACE phosphorylation
To elucidate further the mechanism of TNF- shedding, we next examined the role of TACE. TACE is a matrix metalloprotease, which has previously mediated the processing of membrane bound pro-TNF- to an active soluble form (27, 28). Based on our observation that inhibition of AR prevents HG-induced decrease in membrane-associated TNF-, we tested whether inhibition of AR would also affect phosphorylation and activation of TACE. As shown in Fig. 2A, treatment with HG led to a time-dependent increase in the abundance of phospho-TACE in the cells. A significant increase in TACE phosphorylation was observed within 20 min high-glucose exposure. Between 60 and 120 min exposure, a 5- to 6-fold increase in TACE phosphorylation was observed. These observations suggest that HG stimulates TACE phosphorylation, and that the resultant increase in TACE activity may be responsible for greater cleavage and release of TNF- from the membrane. To probe the role of AR in this process, the cells were treated with the sorbinil. As shown in Fig. 2A, treatment with sorbinil led to nearly complete inhibition of TACE phosphorylation, and no increase in phospho-TACE was observed for 120 min. Similar results were obtained from cells treated with AR siRNA (Fig. 2B). In these cells no significant increase in HG-induced TACE phosphorylation was observed at any time during observation, although the cells that were treated with control siRNA showed, as expected, a 5- to 6-fold increase in TACE phosphorylation. Under these conditions no changes in the levels of TACE protein were observed when the cells were treated either with HG alone or HG and sorbinil (Fig. 2C). These data indicate that within the observation time, the levels of TACE protein were unaffected by any of the treatment protocols. Furthermore, TACE phosphorylation was not affected by the addition of equimolar concentrations of either mannitol or a metabolically inactive analog of glucose [3-methyl glucose (3-MG)] to the medium (Fig. 2D). Together, these results indicate that inhibition of AR prevents HG-induced TACE phosphorylation and that this effect is not due to osmotic changes induced by the addition of HG to the medium.

View larger version (31K): [in this window] [in a new window]   FIG. 2. Inhibition of AR prevents HG-induced TACE phosphorylation. Serum-starved VSMCs in 5.5 mM glucose (NG) medium incubated with sorbinil (10 µM) (A) or AR-siRNA transfected cells (B) were treated with 0.5 mCi [33P]orthophosphate for 30 min, followed by stimulation with 19.5 mM glucose (total glucose 25 mM, HG) for the indicated times. Time point 0 min represents NG. The cells were immunoprecipitated with anti-TACE antibodies, and the eluted immune complexes were resolved on SDS-PAGE, followed by autoradiography. C, Growth-arrested VSMCs were treated with HG plus sorbinil for the indicated time periods, and total cell extracts were subjected to Western blot analysis using antibodies against total-TACE and GAPDH. D, Autoradiograph showing phospho-TACE 30 min after treatment in lanes 1, 4, and 7 with 5.5 mM, lanes 2, 5, and 8 with 15 mM, and lanes 3, 6, and 9 with 25 mM D-mannitol, 3-O-methyl glucose, and glucose, respectively. Bars represent values of mean ± SEM (n = 3) band intensity normalized to the intensity of the band in cells before the addition of HG. Average fold changes are listed for each treatment. *, P < 0.001 vs. 0 min HG; #, P < 0.001 vs. HG.

View larger version (10K): [in this window] [in a new window]   FIG. 3. Inhibition of AR prevents HG-induced TACE activity. A, VSMCs incubated with medium containing 5.5. 15, and 25 mM glucose, mannitol, and 3-MG were harvested, and TACE activity was determined by incubating equal amounts of cell extracts with 5 µM TACE substrate for 30 min at 37 C. Fluorescence quenching was monitored at excitation wavelength (ex) = 320 nm and emission wavelength (em) = 420 nm using a fluorescence plate reader. B, VSMCs incubated with NG (5.5 mM) and HG (25 mM) without or with ARIs, zopolrestat and sorbinil, were harvested and measured TACE activity as described in Materials and Methods. Bars represent mean ± SEM (n = 4). *, P < 0.001 vs. HG; #, P < 0.001 and ##, P < 0.01 vs. NG.

TAPI-1 inhibits HG-induced TNF- processing

View larger version (18K): [in this window] [in a new window]   FIG. 4. TAPI inhibits HG-induced TNF- shedding and TACE phosphorylation: Serum-starved VSMCs in 5.5 mM glucose (NG) medium incubated without or with TAPI-1 for 30 min, followed by stimulation with HG for the indicated time periods. The cells were treated with HG (A) or HG plus sorbinil (B) and harvested; cell membrane extracts were prepared, and an equal amount of membrane protein was subjected to Western analysis using anti-TNF- antibodies. C, The VSMCs were treated with 0.5 mCi [33P]orthophosphate for 30 min, followed by stimulation with HG for the indicated times. Time point 0 min represents NG. The cells were immunoprecipitated with anti-TACE antibodies, and the eluted immune complexes were resolved on SDS-PAGE, followed by autoradiography. Bars represent normalized values of mean ± SEM (n = 3) intensity measured by densitometric analysis. *, P < 0.001 and **, P < 0.05 vs. 0 min HG; #, P < 0.001 vs. HG.

HG-induced TACE activation is mediated by PKC-

View larger version (19K): [in this window] [in a new window]   FIG. 5. Inhibition of PKC- prevents HG-induced TACE phosphorylation: Serum-starved VSMCs in 5.5 mM glucose (NG) medium incubated without or with rottlerin (2 µM) for 30 min, followed by stimulation with HG for the indicated time. The cells were treated with HG (A) and HG plus rottlerin (B) and harvested; cell membrane extracts were prepared, and an equal amount of membrane protein was subjected to Western analysis using anti-TNF- antibodies. C, VSMCs were treated with 0.5 mCi [33P]orthophosphate for 30 min, followed by stimulation with HG for the indicated time. Time point 0 min represents NG. The cells were immunoprecipitated with anti-TACE antibodies, and the eluted immune complexes were resolved on SDS-PAGE, followed by autoradiography. Bars represent normalized values of mean ± SEM (n = 3) intensity measured by densitometry analysis. *, P < 0.001 and **, P < 0.05 vs. 0 min HG; #, P < 0.001 vs. HG.

View larger version (13K): [in this window] [in a new window]   FIG. 6. Inhibition of AR prevents HG-induced expression of matrix metalloproteases. Serum-starved VSMCs, in 5.5 mM glucose (NG) medium, incubated with sorbinil (10 µM) or AR-siRNA transfected cells were treated with HG for 24 h. The cells were then harvested, and whole cell extracts were prepared. Equal amounts of protein were subjected to Western analysis using antibodies directed against MMP-2, MMP-9, TIMP-3, and GAPDH. Bars represent normalized values of mean ± SEM (n = 3) intensity measured by densitometry analysis. *, P < 0.001 vs. NG; #, P < 0.001 vs. HG.

Inhibition of AR diminishes TNF- levels during diabetes

View larger version (7K): [in this window] [in a new window]   FIG. 7. Inhibition of AR prevents TNF- secretion in diabetic rats. Diabetes was induced in adult Sprague Dawley rats by injection with a single dose of streptozotocin (65 mg/kg body weight ip). After 4 wk diabetes, the mice were treated either with vehicle or the ARI sorbinil at a dose of 25 mg/kg/body weight · d ip for 4 wk. The levels of TNF- were measured in the serum by ELISA. Data represent mean ± SD (n = 4). *, P < 0.001 vs. nondiabetic and #, P < 0.001 vs. diabetic rats.

View larger version (98K): [in this window] [in a new window]   FIG. 8. Inhibition of AR prevents the expression of MMPs and TIMP-3 in balloon-injured rat carotid arteries. The carotid artery of nondiabetic and diabetic rats was injured by a balloon as described in Materials and Methods. A, Ten days after injury, the uninjured (control) and injured arteries were harvested, fixed by paraformaldehyde treatment, and stained with antibodies raised against TNF-, MMP-2, MMP-9, and TIMP-3 using the LSAB+ System-horseradish peroxidase. Photomicrographs of the stained sections were acquired using an EPI-800 microscope (bright-field) connected to a Nikon camera. Percent staining was determined by measuring positive immunoreactivity per unit area. Arrows represent the area for positive staining for an antigen. B, The intensity of antigen staining was quantified by digital image analysis. The bar graphs show means ± SD (n = 3). *, P < 0.01 vs. nondiabetic and #, P < 0.01 vs. diabetic rats.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

High levels of glucose induce a wide range of metabolic derangements that occur from several biochemical abnormalities. The major biochemical abnormalities induced by HG are thought to be due to: 1) excessive flux of glucose through the polyol pathway, which reduces glucose to sorbitol; 2) activation of PKC isoforms; and 3) increased accumulation of advanced glycosylation end products (50). Although multiple studies present convincing data showing that these pathways are activated in tissues exposed to HG (22, 24, 32, 50), the mechanisms by which they induce and increase inflammation remain unclear. Previous studies show that inhibition of advanced glycosylation end product formation decreases atherosclerotic lesion formation in diabetic mice, and that inhibition of PKC ameliorates diabetic nephropathy and neuropathy (51). Studies in our laboratory have shown that HG-induced activation of PKC and NF-B could be prevented by inhibiting AR (24, 32, 52, 53), indicating that HG-induced increase in inflammation is in part due to activation of the polyol pathway. In addition, we have found that when VSMCs are exposed to HG, they secrete TNF- into the media (24). This TNF- then acts in a paracrine/autocrine fashion to stimulate the activity of NF-B, which in turn increases the transcription of cytokine genes and stimulates cell growth (24, 50). Consistent with a central role of early release of TNF- in HG-induced inflammation, we have found that treatment with soluble TNF- receptors or anti-TNF- antibodies prevents HG-induced mitogenesis and NF-B activation (24). Our current data extend these observations and demonstrate that HG stimulates the processing of preformed TNF- by a mechanism that depends upon the activation of PKC and the polyol pathway.

TNF- is a central mediator of inflammatory responses. Its synthesis in most cells is stimulated by NF-B, which binds to the promoter of the TNF- gene (54). TNF- is synthesized in a pro-form, and has to be processed to an active form for secretion and binding to the TNF- receptor (55, 56). Processing mechanisms of TNF resemble those of other cytokines and growth factors such as TGF-β and epidermal growth factor (57). The protease responsible for TNF- cleavage has been identified to be TACE or ADAM17 (58). TACE is a zinc-dependent membrane-bound disintegrin metalloproteinase that is responsible for ectodomain shedding of cytokines and growth factors such as TNF- or TGF- (57, 58). In agreement with its role in TNF- processing, we found that an increase in TNF- shedding in cells exposed to HG (Fig. 1) was associated with a corresponding increase in TACE phosphorylation (Fig. 2). That TACE activation is essential for HG-induced TNF- ectodomain shedding is indicated by the observation that treatment with TAP1–1 prevented TACE phosphorylation and the release of TNF- from membrane-associated sites (Fig. 4).

Our results also indicate that the mechanisms that regulate HG-induced TNF shedding relate to the activation of the polyol pathway and PKC-. The central role of the polyol pathway in regulating TACE activation and TNF- shedding is consistent with several lines of evidence showing that inhibition of AR prevents: 1) TNF- shedding in VSMCs exposed to HG, 2) phosphorylation and activation of TACE in these cells, and 3) the increase in TNF- in the plasma and arterial lesion of diabetic animals. Collectively, these data suggest that AR is an obligatory mediator of HG-induced TNF-shedding because it is required for the activation and phosphorylation of TACE. Moreover, the observation that treatment with ARIs decreases TNF- levels in diabetic rats provides new and compelling evidence supporting a proinflammatory role of this enzyme in diabetes. Previous studies show that obesity and diabetes increase the expression of inflammatory cytokines such as TNF- in adipose tissue, liver, as well as skeletal muscle, and that these cytokines contribute to insulin resistance (1). However, in the context of hyperglycemia, the increase in intracellular glucose in tissues with insulin-insensitive glucose transport, such as endothelial, smooth muscle, or renal cells or neurons, are likely to be significant sources of inflammatory cytokines. This is consistent with our observation that inhibition of AR, which prevents HG-induced cytokine production, decreases circulating levels of cytokines in diabetic rats. Therefore, even though the tissue sources of cytokine generation during diabetes remain unclear, it is likely that inhibition of AR by preventing glucose-induced changes in noninsulin-dependent tissues could decrease the overall cytokine load during diabetes. Because cytokine production is regenerative, inhibition of these sources could also decrease inflammation in insulin-sensitive tissues such as heart and skeletal muscle, which become hypoglycemic, and those such as the liver that do not express much AR (59).

Although the mechanisms by which inhibition of AR prevents inflammation and hyperglycemic injury remain unclear, our studies suggest that the beneficial effects of AR inhibition could be, in part, attributable to inhibition of PKC isoforms. Both cytokines and HG activate several PKC isoforms. In VSMCs, exposure to HG results in the activation of several PKC isoforms, including, PKCβ1, β2, , and (52). Simultaneous activation of several PKC isoforms is due to an increase in the synthesis of diacylglycerol (DAG), which is an essential cofactor and activator of classical as well as novel PKC isoforms (60, 61). Our studies show that inhibition of AR prevents DAG formation, and thereby simultaneously affects the activation of both classical and novel PKCs (52). The present study showing that treatment with the PKC- inhibitor rottlerin prevents TACE phosphorylation and TNF- shedding (Fig. 5) suggests that HG-induced TNF- shedding is mediated by PKC--dependent activation of TACE and that inhibition of AR diminishes TNF- shedding by preventing PKC- activation. Although several previous studies show that ectodomain shedding of growth factors and cytokines is regulated by PKC (62), to the best of our knowledge, the present study is the first to show that PKC- is required for TACE activation.

PKC- is strongly activated by HG and diabetes along with PKC-β1 and β2 (52, 63), and has been linked to endothelial cell apoptosis in HG (64), nonetheless, its role as a mediator of the cardiovascular complications of diabetes is unclear. Moreover, even though significant attention has been divested in studying and treating diabetic activation of PKC-β, and PKC-β inhibitors have been effective in attenuating diabetic retinopathy and nephropathy (65, 66), an essential role of PKC- in regulating TACE activation and TNF- shedding demonstrated here suggests that PKC- inhibitors could also be useful in preventing or treating diabetic complications. Alternatively, it may be even more beneficial to prevent the activation of all PKC isoforms simultaneously by preventing glucose-induced DAG accumulation. This could be accomplished by either increasing DAG kinase activity, e.g. by peroxisome proliferator activated receptor- activation (67), or by preventing DAG formation by inhibiting AR (52). In either case, it appears that interrupting signaling events upstream to DAG formation is likely to provide more extensive protection than inhibition of individual PKC isoforms.

Several studies show that PKC regulates TACE phosphorylation and activation. For example, TNF- release and TACE phosphorylation in ionomycin-stimulated RBL-2H3 cells have required PKC (68). Similarly, phorbol ester-activated TACE-induced release of meprin-β is prevented by PKC inhibition (69). Despite these observations, the molecular mechanisms by which PKC regulates TACE have not been fully elucidated. In human airway epithelial cells, TACE is activated by reactive oxygen species (ROS), and PKC inhibitors prevent TACE activation by preventing ROS generation (70), indicating that PKC is an indirect regulator of TACE and that this regulation is mediated by ROS. In contrast, PKC- has been shown to bind directly to ADAM (MDC9) to stimulate the shedding of heparin-binding epidermal growth factor-like growth factor (71). PKC- could also induce TACE phosphorylation by activating ERKs, which have phosphorylated Thr-735 of TACE (72). Clearly, additional studies are required to elucidate the specific mechanism by which PKC- regulates HG-induced TACE phosphorylation and activation. Finally, because TACE-mediated shedding is not limited to TNF-, and TACE has been involved in cleaving the membrane-anchored forms of several other proteins such as TGF- (73), L-selectin (74), TNF-receptor-II (75), and fractalkine (76), inhibition of TACE, by TACE-specific inhibitors, or by inhibiting PKC- or AR, could potentially, at the same time, prevent several aspects of HG-induced inflammation, cell adhesion, and abnormal cell growth.

	Footnotes

 
This work was supported by National Institutes of Health Grants DK36118 (to S.K.S.), ES11860, HL55477 (to A.B.), and GM71036 (to K.V.R.).

Disclosure Statement: The authors have nothing to disclose.

First Published Online September 4, 2008

Abbreviations: AR, Aldose reductase; ARI, aldose reductase inhibitor; DAG, diacylglycerol; FBS, fetal bovine serum; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; HG, high glucose (25 mM); MMP, matrix metalloproteinase; mTNF-, membrane bound TNF-; 3-MG, 3-methyl glucose; NF-B, nuclear factor-B; NG, normal glucose (5.5 mM); NP-40, Nonidet P-40; PKC, protein kinase C; ROS, reactive oxygen species; siRNA, small interference RNA; TACE, TNF- converting enzyme; TAPI-1, TNF- protease inhibitor-1; TIMP, tissue inhibitor of metalloproteinase; T1D, type 1 diabetes; VSMC, vascular smooth muscle cell.

Received May 8, 2008.

Accepted for publication August 25, 2008.

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