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Hypoxia-Regulated Activity of PKC in the Lens

From the Department of Biochemistry, Kansas State University, Manhattan, Kansas.

	Abstract

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PURPOSE. To show that hypoxia is necessary to prevent opacification of the lens. Protein kinase C (PKC)- serves a role that is distinct from PKC- when both PKC isoforms are expressed in the lens. PKC serves a very important role in hypoxic conditions, helping to prevent opacification of the lens.

METHODS. Digital image analysis, confocal microscopy, dye transfer assay, coimmunoprecipitation, Western blot analysis, and enzyme activity assays were used, respectively, to study opacification of the lens, intercellular communications, cellular localization of connexin-43 (Cx43), and the interactions between PKC, PKC, and Cx43 in the lens epithelial cells.

RESULTS. Hypoxic conditions (1%–5% of oxygen) were very important in maintaining clarity of the lenses of wild-type (WT) mice. Normoxic conditions induced opacification of the WT lens. Lenses from the PKC-knockout mice underwent rapid opacification, even in hypoxic conditions. Hypoxia did not induce apoptosis in the lens epithelial cells, judging by the absence of active caspase-3, and it did not change intercellular communication and did not affect the number and localization of junctional Cx43 plaques in the lens epithelial cell culture. Hypoxia activated PKC, whereas phorbol ester (TPA), oxidation (H₂O₂), and insulin-like growth factor-1 (IGF-1) activated PKC and decreased the activity of PKC. Hypoxia did not induce the phosphorylation of the Cx43.

CONCLUSIONS. Hypoxia-induced activation of PKC is very important in surviving hypoxia and maintaining the clarity of the lens. However, PKC is utilized in the control of Cx43 gap junctions.

Unlike cardiac tissue, lens tissue is naturally hypoxic and contains two stress-sensing PKC isoforms: PKC and PKC.^{44 45} As for PKC, it is very well known that it controls gap junction Cx43 through phosphorylation in many cell types.^{46 47 48} Recently, we demonstrated that the specific ability of PKC to phosphorylate Cx43 allows PKC to block the propagation of apoptotic signals.^{45 49} The role of PKC in the lens is still unclear. Taking into account the role of PKC in the heart, we recently studied the ability of hypoxia to regulate the PKC in the lens. We found that in the lens, like in the heart, hypoxia activates PKC which is associated with CytCOxIV in the mitochondria.⁵⁰ We also demonstrated that hypoxia-induced activation of CytCOx in the lens is PKC dependent: Hypoxia not only activated PKC but also stimulated interaction with CytCOx, which was not observed in lenses from the PKC knockout mice (KO). However, it is not certain what role PKC plays in the control of lens homeostasis. This work was directed to identifying that role.

	Materials and Methods

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Dulbecco’s modified Eagle’s medium (DMEM; low glucose), trypsin-EDTA, gentamicin, and penicillin/streptomycin were purchased from Invitrogen Corp. (Carlsbad, CA). Dithiothreitol (DTT), sodium fluoride (NaF), and bovine serum albumin (BSA) were purchased from Fisher Scientific (Hampton, NH). Fetal bovine serum was purchased from Atlanta Biologicals (Norcross, GA). Human recombinant FGF-2 (bFGF; cat. no. F0291), IGF-1 (cat. no. I3769), H₂O₂ (cat. no. H1009), phenylmethylsulfonyl fluoride (PMSF), and protease inhibitor cocktail (cat. no. P8340) were from Sigma-Aldrich (St. Louis, MO). TPA (cat. no. 524400), 4-phorbol-12,13-didecanoate (PDD, cat. no. 524394), and phosphatase inhibitors cocktail set II (cat. no. 524625) were purchased from Calbiochem (La Jolla, CA). PKC activity nonradioactive assay kit (cat. no. EKS-420) was purchased from Stressgen (Ann Arbor, MI). Protein A/G plus agarose beads were purchased from Santa Cruz Biotechnology (Santa Cruz, CA). All electrophoresis reagents and protein molecular weight markers for electrophoresis and protein assay dye were purchased from Bio-Rad Laboratories (Hercules, CA). Chemiluminescence substrate (SuperSignal West Femto Substrate Kit) with secondary anti-mouse or anti-rabbit IgG conjugated with horseradish peroxidase (cat. no. 34095) was purchased from Pierce (Rockford, IL).

Animals
All animal procedures were approved by the Kansas State University Institutional Animal Care and Use Committee. Mice, including control and PKC knockout (KO) mice, were obtained from Jackson Laboratories (Bar Harbor, ME) and maintained as colonies in the Animal Research Facility at the College of Veterinary Medicine. PKC KO mice were obtained by breeding heterozygous individuals and the genotyping of the offspring was performed by PCR of tail snips. Yield was 10% homozygous for the PKC KO. The control mice were B6.129S4-Prkce/tm1/Msg/J and the PKC heterozygous mice (with or without PKC) were Prcke/tm1/Msg-2-3. Only homozygous KO-PKC mice were used from cross-breeding of heterozygous pairs. All mice were used at 6 weeks of age. The failure of the PKC^–/– mice to produce PKC protein was further verified by Western blot analysis with PKC antisera. The mice were killed by CO₂ followed by cervical dislocation. All experiments conformed to the ARVO Statement for Use of Animals in Ophthalmic and Vision Research.

Lens Culture
The eyeballs were surgically removed immediately after death and placed on ice. Immediately after eye surgery they were dissected in the microscope, and the lenses were placed in DMEM (with 10% serum) without phenol red, previously equilibrated with 1% O₂ and 5% CO₂ (hypoxic DMEM) for 12 hours and then washed twice with the same media to remove vitreous and pigmented tissue. Average time required for dissection during which lenses were exposed to air was 15 seconds. Twelve lenses were used for every experimental data point regardless of left or right eye, color of the eyeballs, size of the lens, or the sex of the mice. All lenses for every experimental data point were collected after dissection into one Petri dish and were washed together, and then 12 randomly chosen clear lenses were transferred into a new Petri dish (50 mm) covered with 2 mL of hypoxic DMEM and placed in the hypoxic chamber. Lenses with visible damage were discarded.

Analyses of Opacification
After an appropriate incubation time, the Petri dishes with the 12 lenses were taken out of the chamber and lens opacification was assessed by photographing the lenses with a digital camera according to Behndig et al.⁵¹ Briefly, to assess opacification, the 256-level gray-scale photographs of the steel grid (8 lines/mm) were taken through the lens by using retroillumination. Every picture taken for the analyses contained clear grid, background, and lens. The analyses of opacification were conducted with digital image-analysis software (ImageJ, a public domain, Java-based image processing program developed in the National Institutes of Health, Bethesda, MD; available at http://rsb.info.nih.gov/ij/index.html.) by marking a circular area of 0.8 mm² (1 mm in diameter) of the grid, background, and lens on the photograph and calculating a histogram of the distribution of gray values. The theoretical zero opacity, which is equal to the maximum transparency, was determined from the image of the grid alone, without the lens. Most of the pixels of the grid image are black and white, which renders a very broad histogram with a standard deviation (SD_zero) of 50.00 (Fig. 1A) . This value of SD_grid was calculated for every image separately and used as the theoretical zero opacity. The image of the background that gives uniform gray pixels values with a very small SD (SD_bkg 1.0) and a sharp histogram (Fig. 1B) gives a value of theoretical maximum opacity. The experimental opacity of the lens was achieved by calculating a histogram and SD (SD_exp) of the distribution of gray values of the grid visible through the lens (Fig. 1C) . After that, the opacity of the lens was expressed as a percentage of the theoretical zero opacity: 100 x SD_exp/SD_zero. To minimize the difference between photographs, we placed all lenses from one experimental set simultaneously on the grid, and several pictures were immediately taken. To minimize the difference between control and KO lenses, we photographed control and KO lenses together on the same grid. Freshly isolated lenses from control and KO mice are always clear; however, since murine lenses have a distinct biconvexity it was not possible to get a perfectly focused image of the grid for the central and periphery (close to equatorial region) parts of the lens at the same time. An unfocused image of the grid contains significantly more gray pixels and therefore significantly smaller SD_exp. To minimize the contribution of the unfocused peripheral parts of the lens on the final histogram and SD_exp, we used five different circular focus areas of 0.8 mm² (1 mm in diameter): central, left, right, top, and bottom. Five photographs with five different focuses on the central, top, bottom, and left–right areas were made and used for histogram calculations.

View larger version (54K): [in this window] [in a new window]   FIGURE 1. (A) Theoretical zero-opacity histogram: the x-axis represents the gray-scale values and the y-axis shows the number of pixels found for each gray value. The theoretical zero opacity that is equal to the maximum transparency was determined from the image of the grid alone (inset), without lens. Circular area of 0.8 mm2 (1 mm in diameter) of the grid on the photograph was used for analyses. Most of the pixels are black and white, which renders a very broad histogram with SD 50.00. (B) The theoretical maximum (100%). Opacity was determined from the image of the background that gives uniform gray pixels values with a very small SDbkg 1.0 and a sharp histogram. (C) Experimental opacity of the lens: analysis of experimental opacification was performed by calculating a histogram of the distribution of gray values of the grid visible through the lens.

Tissue Culture
Rabbit lens epithelial cells (NN 1003A) or human lens epithelial cells were grown in DMEM with 10% fetal bovine serum (FBS) until 100% confluent in normoxic conditions unless otherwise specified (described later). The cells were used for experiments at 100% confluence on the third day after the last split. They were starved in DMEM without fetal bovine serum for 4 hours before treatment with growth factors, TPA, or H₂O₂. They were then treated at 37°C for 30 minutes with stress factors such as H₂O₂ (100 µM) and TPA (200 nM) and growth factors such as FGF-2 and IGF-1 (both at 25 ng/mL) by direct adding of the aforementioned substances to the medium. PDD was used as a negative control for TPA treatment.

Hypoxia
Normoxic conditions, or normoxia, were considered to be a state in which the partial pressure of oxygen in the gas is equal to that of air at sea level—approximately 21% oxygen or 150 mm Hg—plus 5% CO₂ at 37°C and 100% relative humidity in a cell culture incubator. Hypoxic conditions were created with the help of a hypoxic chamber (Proox C21; BioSpherix, NY) using nitrogen and CO₂ as displacement gases, set at 1%, 3%, 5%, and 10% O₂; 5% CO₂; 37°C; and 100% relative humidity. Petri dishes (100 mm) and 10 mL of DMEM (10% FBS) were used for cell culture, to ensure appropriate and fast ventilation of cultures in the chamber. No changes in the pH of the cell media were registered during hypoxia incubation for up to 4 days, as assessed by direct measurements of pH of the media in the dishes. Immediately after surgery, the mouse lenses were incubated in the DMEM (10% serum without phenol red) for 4, 8, or 12 hours in different oxygen concentrations (1%, 3%, 5%, 7%, or 10%, or 21% for normoxia), plus 5% CO₂ at 37°C and 100% relative humidity.

Whole-Cell or Lens Lysate Preparations
To reduce oxygen exposure during cell lysate preparations, after hypoxia experiments, phosphate-buffered saline (PBS) and cell lysis buffer were degassed for 30 minutes in a vacuum before experiments. Immediately after hypoxia treatment, cells were washed with 37°C PBS, collected from Petri dishes by scraping, sedimented, and washed two times in PBS. The cell pellets were lysed on ice with cell lysis buffer containing 20 mM Tris-HCl (pH 7.5), 0.5 mM EDTA, 0.5 mM EGTA, 1% Triton X-100, protease inhibitor cocktail (1:100), 2 mM PMSF, and phosphatase inhibitor cocktail (1:100). The lysates were sonicated for 20 seconds on ice. Protein concentration was equalized in all samples for future analyses.

Western Blot and Coimmunoprecipitation Analyses
Western blot and immunoprecipitation analyses of cell lysates followed by Western blot analyses were performed as previously described.⁵² All cell lysates had the same total protein concentration (2 mg/mL) before immunoprecipitation. Anti-PKC, anti-PKC, and anti-Cx43-NT1 antibodies at 5 µg/mL were used for immunoprecipitation.

PKC Enzyme Activity Assays
PKC activity was determined by use of a PKC activity assay (Stressgen). Cell lysates from separate experiments were divided into three aliquots to run assays in triplicate for statistical purposes. Each was immunoprecipitated with anti-PKC or anti-PKC antibodies as described previously.⁵² The immunoprecipitate-agarose bead complexes were used directly to measure the activity of each PKC isoform according to the manufacturer’s manual. Three separate experiments were performed to obtain statistically relevant data. Purified recombinant active PKC supplied by the manufacturer was used as a positive control. Cell lysis buffer alone, supplemented with primary antibodies and agarose beads was used as a blank for the enzyme assay. Because of unavoidable variations in absolute values of PKC activity in separate experiments the final values of activities for all samples were normalized using the PKC control as a 100% for each experiment. Normalization of data to PKC control levels allowed the direct comparison of separate datasets regardless of the absolute values. Phosphatase inhibitors were present in all procedures, so that PKC and - autophosphorylation and the resulting activation could be maintained.

Confocal Scanning Fluorescent Microscopy
To visualize the specific location of Cx43 in the cells before and after the treatments, confocal scanning fluorescent microscopy was used, as previously described.⁵² Lens cells were grown on coverslips, treated as described earlier and then fixed in 4% paraformaldehyde, permeabilized, blocked, and treated with primary anti-Cx43-IF1 antibodies at 5 µg/mL concentration as previously described.⁵² Secondary fluorescent Alexa Fluor-488 antibodies at 10 µg/mL were used to visualize the specific location of the primary antibodies,.

Dye Transfer–Gap Junction Activity Assay
To study the gap junction activities in cell culture the scrape-loading/dye transfer (SL/DT) assay with lucifer yellow and rhodamine dextran was performed as described before.^{44 53 54} Gap junction activity was expressed as the number of cells transferring lucifer yellow minus cells with rhodamine dextran per total number of DAPI-stained cells. Three different areas along each scrape were analyzed with at least 1000 cells counted. The number of cells transferring lucifer yellow were expressed as the mean ± SD, with P < 0.05 considered significant.

Statistical Analyses
Commercial software (Origin; Microcal Software Inc., Northampton, MA) was used for statistical analyses. Results were expressed as the mean ± SD. Differences at P < 0.05 were considered to be statistically significant.

	Results

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Lens Opacification Study
To investigate the effects of hypoxia on PKC, we had to establish the main physiological outcome/property that is relevant for the lens. This property is the transparency of the lens and its opposite characteristic, opacity of the lens. Wild-type lenses and lenses from PKC-KO mice were cultured together in the separate wells in hypoxic conditions at 1%, 3%, 5%, and 10% O₂ and in 21% O₂ (normoxia) for 4, 8, and 12 hours. Figure 2A shows representative images of the fresh wild-type (WT) and PKC-KO lenses before incubation. Freshly isolated lenses from control and KO mice have always been clear; however, since murine lenses have a distinct biconvexity, and experimental procedure obviously produced some optical defects, it was not possible to obtain opacification value equal to zero. Opacity of the fresh WT lens and fresh PKC-KO lens at the beginning of incubation was the same and did not exceed 5% (4.9 ± 1.1 for WT, and 5.1 ± 1.3 for KO, mean ± SD; Figs. 2B 2C ). Increased concentration of oxygen induced opacification (Figs. 2B 2C) . Wild-type lens became opaque at 21% oxygen, even after 4 hours of incubation (opacity, 68.16 ± 10.13) and stayed relatively transparent after 12 hours in 1% O₂ (opacity, 28.02 ± 15.61). Remarkably, that opacity of the WT lenses demonstrated gradual increasing from 1% to 10% oxygen, whereas PKC-KO lenses became opaque up to 78%, even after 4 hours, regardless of the concentration of the oxygen (Figs. 2B 2C) . It is worth noting that careful visual examination of every lens in the microscope in all experiments demonstrated that in all cases opacification started from the equatorial region of the lens. Even during preliminary experiments when the apical and posterior parts of the lens were intentionally tapped with forceps during transfer to the Petri dishes, opacification started from the equatorial region. We did not do more careful studies of the lens, but at the level of the visual examination in a microscope we can make a conclusion that opacification was cortical and spread from the equatorial to the apical and posterior regions which were the last parts where opacification occurred (as well as the nuclear part of the lens). Although we took care to prevent exposure of all lenses to O₂, obviously some handling (15 seconds) resulted in some exposure to oxygen. However, these results clearly demonstrated the following: hypoxia has a profound effect on the main physiological property (transparency) of the lens; hypoxia is the normal physiological state, and any condition close to normoxia promotes opacification; and PKC is necessary for the protection of the lens from opacity. Fresh lenses as well as lenses incubated in hypoxic conditions for 12 hours demonstrated the expression of HIF-1 (Fig. 2D) , and the level of HIF-1 normally seen in the hypoxic lens was decreased in normoxic conditions (Fig. 2E) . Our hypothesis is that the high level of opacification in the PKC-KO lens resulted, first, from the loss of PKC–dependent activation of the CytCOxIV when the lens had brief normoxia due to handling. Previously, we demonstrated that PKC is a prerequisite for hypoxia-induced activation of the CytCOxIV.⁵⁰ The second possibility may result from an effect of PKC on Cx43 which is absent in PKC-KO mice.

View larger version (69K): [in this window] [in a new window]   FIGURE 2. (A) Freshly isolated lenses from wild-type control and KO mice. (B) Images of the wild-type control and KO mice after 4, 8, and 12 hours of hypoxia in vitro. PKC KO lenses show abnormal opacification in hypoxic conditions in vitro. (C) Experimental opacity of the lens is expressed as a percentage of the theoretical zero opacity. Fresh wild-type and KO lenses are always clear; however, since murine lenses have a distinct biconvexity and the experimental procedure obviously produced some optical defects, it was not possible to obtain values of the experimental opacity of the lens equal to zero. Therefore, the mean value of the experimental opacity of freshly isolated wild-type control (CNT) lenses was 4.9 ± 1.7 and the that of freshly isolated KO lenses was 5.1 ± 1.9 (P > 0.05). Data are plotted as the mean ± SD. Significant differences: *P < 0.05); **P < 0.001 between data indicated by arrows. There is no significant difference between values of mean experimental opacity for 10% and 21% oxygen in the WT group and between 1%, 3%, and 21% oxygen in the KO group. (D, E) Western blot analyses of HIF-1 in lens homogenates of freshly isolated wild-type lens (CNT) and lenses after hypoxia treatment. Increased levels of oxygen (10%–21%) induced the disappearance of HIF-1. -Tubulin was used as the loading control. The average pixel values (E) for every HIF-1 band were calculated and then normalized and plotted as a percentage of the control (CNT) value obtained in freshly isolated lenses. (Un-Scan-It gel and graph digitizing software was used to digitize the bands; Silk Scientific, Orem, UT).

View larger version (56K): [in this window] [in a new window]   FIGURE 3. Scrape-loading/dye transfer analyses of the lens epithelial cells in (A) normoxic conditions and (B) after hypoxia (1% O2 for 24 hours). (C) Dye transfer was expressed in percentages as the number of cells transferring lucifer yellow minus cells with rhodamine dextran per total number of DAPI-stained cells. (D, E) Western blot analyses of HIF-1 in cell lysates in normoxic (CNT) conditions (20% O2, 5% CO2, 37°C) and during hypoxia (5% O2, 5% CO2, 37°C). Average pixel values were calculated for both bands of HIF-1. The second band of HIF-1 at 100 kDa represents post-translational modification of HIF-1 according to Reference 56 . (F, G) Western blot analyses of caspase-3 in cell lysates in normoxic (CNT) conditions (20% O2, 5% CO2, and 37°C) and during hypoxia (5% O2, 5% CO2, and 37°C). TPA treatment (200 nM, 30 minutes, 37°C) was used as a positive control for active caspase-3. -Tubulin was used as the loading control. Data are plotted as the mean percentage (±SD) of control (n = 4). Significant differences: *P < 0.05; **P < 0.001 between the indicated data and the control.

Effects of Hypoxia and PKC on Junctional Cx43

View larger version (23K): [in this window] [in a new window]   FIGURE 4. Confocal images of immunolabeled Cx43 in the human lens epithelial cells: (A) Control, normoxic conditions (21% O2, 5% CO2, 12 hours, and 37°C). (B) Hypoxic conditions (5% O2, 5% CO2, 12 hours, and 37°C). Lens epithelial cells were cultured and immunolabeled. (C) The number of junctional Cx43 plaques per cell in normoxic (CNT, control) and hypoxic (HPX) conditions. Data are plotted as the mean ± SD (n = 3). No significant difference between HPX and control was found.

View larger version (43K): [in this window] [in a new window]   FIGURE 5. (A–F) Confocal images of immunolabeled Cx43 (green). Lens epithelial cells were starved for 4 hours without serum then treated with TPA (200 nM, 30 minutes, and 37°C), H2O2 (100 µM, 30 minutes, and 37°C), FGF-2 or IGF-1 (25 ng/mL, 30 minutes, and 37°C) in normoxic conditions and immunolabeled. PDD (200 nM, 30 minutes, and 37°C) was used as a negative control for TPA treatment. White arrows: the junctional interface between two cells. Scale bar, 20 µm. (G) Quantitative analyses of Cx43 plaques per cell. Data are plotted as the mean ± SD (n = 4). Significant differences: *P < 0.05; **P < 0.001 between the indicated data and the control.

Effect of Hypoxia on PKC and PKC

View larger version (44K): [in this window] [in a new window]   FIGURE 6. (A) PKC- and - enzyme activities in the cell lysates in normoxic (CNT, 20% O2, 5% CO2, and 37°C) and hypoxic (HPX) conditions (5% O2, 5% CO2, 37°C, and 12 hours). Each PKC was immunoprecipitated from cell lysates, and enzyme activity was assayed. (B) Western blot analyses of Ser729-PKC in lens homogenates of freshly isolated wild-type lenses (CNT) and lenses after hypoxia treatment. Hypoxia (1%–3% of oxygen) does induce the phosphorylation of PKC on Ser729, an indication of PKC activation, to the level close to that in the control fresh lenses. -Tubulin was used as the loading control. (C) The average pixel values for every Ser729-PKC band were calculated and then normalized and plotted in percentage of control (CNT) value obtained for freshly isolated lenses (mean ± SD, n = 3). Significant differences: *P < 0.05; **P < 0.001 between the indicated data and the control.

Effects of TPA, IGF-1, and H₂O₂ on PKC and -

View larger version (33K): [in this window] [in a new window]   FIGURE 7. (A) PKC and (B) PKC enzyme activities in the cell lysates in normoxic conditions (21% O2, 5% CO2, and 37°C). Control (CNT) lens epithelial cells. Cells were starved for 4 hours without serum and then treated with PDD (200 nM), TPA (200 nM), FGF-2 (25 ng/mL), IGF-1 (25 ng/mL), or H2O2 (100 µM) for 30 minutes at 37°C in normoxic conditions. Each PKC was immunoprecipitated from cell lysates, and enzyme activity was assayed. PDD was used as a negative control for TPA treatment. Data are plotted as the percentage of control for each enzyme (mean ± SD, n = 3). Significant differences: *P < 0.01; **P < 0.001 between indicated data and the control.

Removal of PKC by TPA-Enhanced Interaction of PKC with Cx43

View larger version (30K): [in this window] [in a new window]   FIGURE 8. Western blot analyses of Cx43 (A, D), PKC (B, E), and PKC (C, F) in immunoprecipitates (IP) with anti-PKC or anti-PKC- antibodies in normoxic (21% O2, 5% CO2, and 37°C) conditions. Control (CNT); TPA treatment (+TPA; 200 nM, 30 minutes, and 37°C). Data are plotted as a percentage of the control (mean ± SD, n = 4). **P < 0.001; significant difference between the indicated data and the control.

Effect of TPA, IGF-1, and H₂O₂, Activators of PKC, on Phosphorylation of S368 on Cx43

View larger version (46K): [in this window] [in a new window]   FIGURE 9. Western blot analyses of cell lysates in normoxic conditions. (A, D) Cx43, nonphosphorylated (NP) Cx43 isoform. P1 and P2, phosphoisoforms of Cx43. (D; open patterned bars) NP phosphoisoform; (gray bars) P2 phosphoisoform of Cx43. (B, E) Ser-368-phosphoisoform of Cx43. There was no shift in the relative molecular weight of the S368-Cx43. When compared with positions of the NP, P1, and P2 bands in (A), S368-Cx43 migrated at the position of the NP. Control (CNT). Cells were treated with PDD (200 nM), TPA (200 nM), FGF-2 (25 ng/mL), IGF-1 (25 ng/mL), or H2O2 (100 µM) for 30 minutes at 37°C in normoxic conditions. (C) β-Actin was used as the loading control. Data are plotted as percentage of control (mean ± SD, n = 4). Significant difference: *P < 0.01, **P < 0.001, between indicated data and control; only statistically relevant data were marked.

View larger version (74K): [in this window] [in a new window]   FIGURE 10. Western blot analyses of cell lysates in normoxic conditions (CNT, No TPA, + TPA) conditions and in hypoxia (5% O2, 5% CO2, and 37°C). (A, G) Ser-368-phosphoisoform of Cx43, (B, H) Cx43 probed by anti-C-terminal-Cx43 antiserum and (C, I) Cx43 probed by anti-N-terminal-Cx43 antiserum. Western blot analyses of PKC (D, J) and PKC (E, K). TPA treatment (200 nM, 30 minutes, and 37°C) was used as the positive control for phosphorylation of Cx43 on Ser-368 (A). (F, L) β-Actin was used as the loading control. Data are plotted as a percentage of control (mean ± SD, n = 4). Significant difference: *P < 0.01; **P < 0.001 between indicated data and control; only statistically relevant data are marked.

View larger version (50K): [in this window] [in a new window]   FIGURE 11. Western blot analyses of Cx43 probed by (A, E) anti-N-terminal-Cx43 antibodies, (B, F) anti-C-terminal-Cx43, (C, G) anti-Ser-368-Cx43 antibodies in cell lysates in normoxic (CNT, 21% O2, 5% CO2, and 37°C) conditions and in 12 hours of hypoxia (5% O2, 5% CO2, and 37°C). TPA treatment (200 nM, 30 minutes, and 37°C) was performed. In the case of hypoxia+TPA, 200 nM was added directly to the media after 12 hours of hypoxia and incubated for 30 minutes at 37°C in the same hypoxic conditions. (D, H) -Tubulin was used as the loading control. Data are plotted as a percentage of the control (mean ± SD, n = 4). **P < 0.001, difference between the indicated data and the control.

	Discussion

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Does PKC participate in the regulation of Cx43 gap junctions in the lens epithelial cells as it does in the heart? In the heart, Cx43 complexes with PKC, but not with PKC, and plays an important role in the cardiac ischemic and pharmacologic preconditioning phenomena.¹² Connexin 43 is very important for normal electrophysiological properties of the heart^{64 65} which allows PKC to phosphorylate Cx43 and thus regulate the intercellular communications between cardiac myocytes. It has been found that hypoxia induces dephosphorylation of Cx43 at heart gap junctions; Cx43 has also been found to be downregulated and displaced from intercalated discs.^{14 16 21 66 67} These changes were directly associated with uncoupling of gap junctions and decreased electrophysiological properties of cardiomyocytes.⁶⁷ Detailed studies of phosphorylation of Cx43 during hypoxia have shown that Ser-297, -306, -330, and -368 at Cx43 are dephosphorylated.¹⁶ Other studies demonstrated that, during hypoxia and preconditioning, PKC controls the phosphorylation of multiple serines in the C terminus of Cx43 (Ser-365, -368, -369, -372, and -373).⁶⁸ In contrast to the cardiomyocytes, our experiments demonstrated a lack of some effects of PKC on Cx43. Hypoxia did not affect intercellular communication as measured by dye transfer. This opposite regulation has several implications. PKC would only regulate gap junctions in response to growth signals and oxidative stress. In normoxic conditions, when the activity of the PKC is decreased, PKC is still bound to Cx43, and PKC requires either an IGF-1 or oxidative signal to become activated and to interact with and phosphorylate Cx43. In hypoxic conditions, whereas PKC is activated, only PKC-activating signals can induce phosphorylation of Cx43. This activation of PKC then displaces PKC from Cx43 and the activated PKC phosphorylates Cx43, especially on Ser-368, regardless of oxygen concentration, causing plaque disassembly and inhibition of the dye transfer. The absence of changes in dye transfer, total amount of Cx43, absence of phosphorylation on Ser-368, the absence of P1 or P2 phosphoisoforms of Cx43 explain why hypoxia itself does not inhibit the intercellular communication and does not affect gap junctional plaques. Our data led us to the conclusion that, in the case of lens epithelial cells, PKC does not participate in the regulation of disassembling and degradation of Cx43 gap junction plaques. That role is a specific one for PKC. In contrast, degradation is accomplished in the heart by PKC.³⁵

But the question remains: What is the purpose of PKC if it does not participate in the regulation of gap junctions? In conditions of hypoxia which activates PKC in heart and in the lens, the PKC, in the heart, is translocated to plasma membranes^{27 69 70} and phosphorylates and inhibits Cx43 gap junctions,^{35 71} to prevent the propagation of apoptotic signal.³⁴ In lens, PKC, activated by hypoxia, translocates to the mitochondria, protects CytCOxIV and blocks apoptosis, by a mechanism which is likely similar to that in the heart.⁷² Both pathways, PKC-dependent and PKC-dependent, work in conjunction, preventing mitochondrial CytCOxIV from damage, and, keeping communication between adjacent epithelial cells open through junctional Cx43 (the bystander effect). This hypothesis is also supported by our recent data demonstrating that mutations in the Zn-finger of the C1B stress switch domain of PKC removes PKC from the regulation of Cx43 gap junctions, induces an increased amount of unregulated Cx43 plaques and promotes caspase-3-based apoptosis in the lens epithelial cells through open Cx43 channels.⁴⁹ In lens that expresses both isoforms, PKC appears to be the primary regulator of gap junctions in response to oxidative stress. PKC displaces PKC from gap junctions as a means of protection that is not required in the more resilient tissues such as heart. In the hypoxic lens, PKC would be primarily found in the mitochondria, to be used as an adaptive/protective response to natural hypoxia. Although knockout mouse models exist for both PKC and PKC, a double-knockout does not exist, and this would be an ideal model to determine the requirements for these two stress-sensing kinases.

	Footnotes

 
This is publication number 08-226-J from the Kansas Experimental Station.

Supported by National Eye Institute EY0R01-13421 (DJT); National Institutes of Health Grant P20 RR016475 from the INBRE (Institutional Development Award [IDeA] Network of Biomedical Research Excellence) Program of the National Center for Research Resources (LG, DJT); and a grant from the Kansas City Life Science Institute (DJT).

Submitted for publication July 22, 2008; revised October 17, 2008; accepted January 15, 2009.

Disclosure: V. Akoyev, None; S. Das, None; S. Jena, None; L. Grauer, None; D.J. Takemoto, None

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be marked "advertisement" in accordance with 18 U.S.C. 1734 solely to indicate this fact.

Corresponding author: Dolores J. Takemoto[b], Department of Biochemistry, 141 Chalmers Hall, Kansas State University, Manhattan, KS, 66506; dtak{at}ksu.edu.

	References

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