Expression of protein kinase C subspecies in rat retina

Distinct expression and localization of diacylglycerol kinase isozymes in rat retina

Recent studies have revealed that phosphoinositide (PI) signaling molecules are expressed in mammalian retinas, suggesting their importance in its signal transduction. We previously showed that diacylglycerol kinase (DGK) isozymes are expressed in distinct patterns in rat retina at the mRNA level. However, little is known about the nature and morphological aspects of DGKs in the retina. For this study, we performed immunohistochemical analyses to investigate in the retina the expression and localization of DGK isozymes at the protein level. Here, we show that both DGKβ and DGKι localize in the outer plexiform layer, within which photoreceptor cells make contact with bipolar and horizontal cells. These isozymes exhibit distinct subcellular localization patterns: DGKι localizes to the synaptic area of bipolar cells in a punctate manner, whereas DGKβ distributes diffusely in the subsynaptic and dendritic regions of bipolar and horizontal cells. However, punctate labeling for DGKε is evident in the outer limiting membrane. DGKζ and DGKα localize predominantly to the nucleus of ganglion cells. These findings show distinct expression and localization of DGK isozymes in the retina, suggesting a different role of each isozyme.

Loss of protein kinase Cgamma in knockout mice and increased retinal sensitivity to hyperbaric oxygen

OBJECTIVE

To determine if loss of protein kinase Cgamma (PKCgamma) results in increased structural damage to the retina by hyperbaric oxygen (HBO), a treatment used for several ocular disorders.

METHODS

Six-week-old mice were exposed in vivo to 100% HBO 3 times a week for 8 weeks. Eyes were dissected, fixed, embedded in Epon, sectioned, stained with toluidine blue O, and examined by light microscopy.

RESULTS

The thicknesses of the inner nuclear and ganglion cell layers were increased. Destruction of the outer plexiform layer was observed in the retinas of the PKCgamma-knockout mice relative to control mice. Exposure to HBO caused significant degradation of the retina in knockout mice compared with control mice. Damage to the outer segments of the photoreceptor layer and ganglion cell layer was apparent in central retinas of HBO-treated knockout mice.

CONCLUSIONS

Protein kinase Cgamma-knockout mice had increased retinal sensitivity to HBO. Results demonstrate that PKCgamma protects retinas from HBO damage.

CLINICAL RELEVANCE

Care should be taken in treating patients with HBO, particularly if they have a genetic disease, such as spinocerebellar ataxia type 14, a condition in which the PKCgamma is mutated and nonfunctional.

Protein kinase C subtypes and retinal ischemic preconditioning

The purpose of our study was to determine the specific subtypes of protein kinase C involved in the neuroprotection afforded by retinal ischemic preconditioning (IPC), their relationship to the opening of mitochondrial KATP (mKATP) channels, and their role in apoptosis after preconditioning and ischemia. Rats were subjected to retinal ischemia after IPC, or retinas were rendered ischemic after pharmacological opening of mKATP channels. Using immunohistochemistry and image analysis, we determined cellular localization of PKC subtypes. We blocked PKC-delta and -epsilon to study the effect on protection with IPC or with IPC-mimicking by the opening of mKATP channels. PKC subtypes were inhibited pharmacologically or with interfering RNA. Electroretinography assessed functional recovery after ischemia. IPC was effectively mimicked by injection of diazoxide to open the mKATP channel. IPC and/or its mimicking were attenuated by the PKC-delta inhibitor rottlerin and by interfering RNA targeting PKC-delta or -epsilon. Using TUNEL staining and Western blotting for caspase-3 and fodrin breakdown we assessed apoptosis. The injection of interfering RNA to PKC-delta and -epsilon before preconditioning significantly enhanced TUNEL staining as well as the cleavage of caspase-3 and fodrin after ischemia. In summary, our experiments have shown that both PKC-delta and -epsilon subtypes are involved in the cellular signaling that results in neuroprotection from IPC and that both are downstream of the opening of mKATP channels.

Phosphorylation of the Ca2+-binding protein CaBP4 by protein kinase C zeta in photoreceptors

CaBP4 is a calmodulin-like neuronal calcium-binding protein that is crucial for the development and/or maintenance of the cone and rod photoreceptor synapse. Previously, we showed that CaBP4 directly regulates Ca(v)1 L-type Ca2+ channels, which are essential for normal photoreceptor synaptic transmission. Here, we show that the function of CaBP4 is regulated by phosphorylation. CaBP4 is phosphorylated by protein kinase C zeta (PKCzeta) at serine 37 both in vitro and in the retina and colocalizes with PKCzeta in photoreceptors. CaBP4 phosphorylation is greater in light-adapted than dark-adapted mouse retinas. In electrophysiological recordings of cells transfected with Ca(v)1.3 and CaBP4, mutation of the serine 37 to alanine abolished the effect of CaBP4 in prolonging the Ca2+ current through Ca(v)1.3 channel, whereas inactivating mutations in the CaBP4 Ca2+-binding sites strengthened Ca(v)1.3 modulation. These findings demonstrate how light-stimulated changes in CaBP4 phosphorylation and Ca2+ binding may regulate presynaptic Ca2+ signals in photoreceptors.

An immunohistochemical study of protein kinase C in the bovine retina

The expression of protein kinase C (PKC) was studied in the bovine retina by immunohistochemical analysis. Western blot analysis showed that PKC isoforms, including alpha, betaI, delta and theta, were detected in the bovine retina. By immunohistochemistry, both PKC alpha and betaI were expressed in all retinal layers, with an intense localization of both PKC alpha and betaI detected in bipolar cells in the inner nuclear cell layer and in some glial cells in ganglion cell layers. The immunoreactivity of both PKC delta and theta was quite weak in the retinal layers, compared with that of PKC alpha and betaI. These findings suggest that both conventional and novel PKCs are differentially expressed in the bovine retina.

R659S mutation of gammaPKC is susceptible to cell death: implication of this mutation/polymorphism in the pathogenesis of retinitis pigmentosa

It has been reported that mutations of gammaPKC cause hereditary spinocerebellar atrophy type 14 (SCA14). Our recent study has revealed that the SCA14 mutant gammaPKC is susceptible to aggregation and causes cell death. Among mutations/polymorphisms of gammaPKC, the R659S mutation was firstly segregated from families with hereditary retinitis pigmentosa type 11 (RP11). Although more reliable etiological mutations of RP11 were subsequently discovered in a human homologue of yeast pre-mRNA splicing gene (PRP31), the role of this R659S missense change in the pathogenicity of RP11 is still controversial. In this study, we overexpressed R659S gammaPKC in CHO cells and characterized the properties of this mutant protein. We found that R659S gammaPKC more prominently induced cell death than did wild-type. This mutant gammaPKC had higher basal activity than wild-type, however, no difference was found in the extent of aggregation and insolubility to detergent between R659S mutant and wild-type. These results suggest that the R659S mutation is susceptible to neuronal death and is involved in the pathogenesis of neurodegenerative diseases, including RP11.

High glucose-induced membrane translocation of PKC betaI is associated with Arf6 in glomerular mesangial cells

Protein kinase C (PKC)-induced changes in glomerular mesangial cell (MC) phenotypic behavior has been implicated in diabetes. The activity of diacylglycerol-sensitive PKC isoforms in MCs is altered by ambient changes in glucose, but the regulation of PKC activity and subsequent intracellular signaling events are not yet clearly defined. Small GTP-binding proteins of the ADP-ribosylation factor (Arfs) family, may regulate protein kinase membrane recruitment and hence its activity in signaling events of non-polarized cells. Members of the ARF family may coordinate membrane dynamics and other cellular functions through their interaction with PKC. We studied the activation of Arf, PKC betaI and phospholipase D (PLD) in MCs cultured under normal or high glucose conditions. MCs cultured in high glucose medium exhibited predominantly cytosolic localization of PKC betaI, Arf3 and Arf6. However, phorbol ester (PMA) stimulation of cells cultured in high glucose significantly enhanced membrane association of PKC betaI and Arf6, but not Arf3. Using [3H]choline chloride to prelabel MCs and measuring [3H]choline-containing metabolite release as PLD activity, PMA stimulated a significant increase of PLD activity under high glucose condition. Our data suggest that Arf6 plays a specific role in activation of PKC betaI and PLD under high glucose condition, and may be a significant intracellular event in the change of the mesangial cell phenotype associated with diabetic nephropathy.

Identification of protein kinase C isozymes responsible for the phosphorylation of photoreceptor-specific RGS9-1 at Ser475

Inactivation of the visual G-protein transducin by GTP hydrolysis is regulated by the GTPase-accelerating protein (GAP) RGS9-1. Regulation of RGS9-1 itself is poorly understood, but we found previously that it is subject to a light- and Ca(2+)-sensitive phosphorylation on Ser(475). Because there are much higher RGS9-1 levels in cones than in rods, we investigated whether Ser(475) is phosphorylated in rods using Coneless mice and found that both the phosphorylation and its regulation by light occur in rods. Therefore, we used rod outer segments as the starting material for the purification of RGS9-1 kinase activity. Two major peaks of activity corresponded to protein kinase C (PKC) isozymes, PKCalpha and PKCtheta. A synthetic peptide corresponding to the Ser(475) RGS9-1 sequence and RGS9-1 were substrates for recombinant PKCalpha and PKCtheta. This phosphorylation was removed efficiently by protein phosphatase 2A, an endogenous phosphatase in rod outer segments, but not by PP1 or PP2B. Phosphorylation of RGS9-1 by PKC had little effect on its activity in solution but significantly decreased its affinity for its membrane anchor protein and GAP enhancer, RGS9-1 anchor protein (R9AP). PKCtheta immunostaining was at higher levels in cone outer segments than in rod outer segments, as was found for the components of the RGS9-1 GAP complex. Thus, PKC-mediated phosphorylation of RGS9-1 represents a potential mechanism for feedback control of the kinetics of photoresponse recovery in both rods and cones, with this mechanism probably especially important in cones.

Activation of PKC-beta(I) in glomerular mesangial cells is associated with specific NF-kappaB subunit translocation

Changes in expression and activity of protein kinase C (PKC) isoforms and early transcription factors may account for alterations in cell behavior seen in diabetes. We studied the expression of PKC-beta(I) in rat glomerular mesangial cells (MCs) cultured in normal or high glucose and compared it with the temporal and spatial expression of dimeric transcription factor (NF-kappaB) p50 and p65. The results show that in unstimulated cells PKC-beta(I) and NF-kappaB p50 are distributed in the cytosol and, on stimulation, their distribution is perinuclear and they are localized to the membrane. Serum-starved MCs cultured in high-glucose medium exhibit a predominantly cytosolic localization of PKC-beta(I) and both p50 and p65 NF-kappaB. However, phorbol 12-myristate 13-acetate (PMA) stimulation of cells grown in the presence of high glucose resulted in membrane translocation of PKC-beta(I) that was associated with nuclear translocation of NF-kappaB p65, but not NF-kappaB p50. Moreover, the translocation to the nucleus for NF-kappaB p65 was significantly higher in MCs exposed to high glucose compared with those exposed to normal glucose. These observations indicate that the NF-kappaB p65, but not NF-kappaB p50, expression and translocation pattern mirrors that of PKC-beta(I), which may be one important pathway by which signaling is enhanced in the high-glucose state.

Photoreceptor regulated expression of Ca(2+)/calmodulin-dependent protein kinase II in the mouse retina

The objective of this investigation is to determine mechanisms for regulation of retinal calmodulin kinase II (CaMKII). To this end, the expression and activity of CaMKII are examined in the retina of the rdta mouse, in which rod photoreceptors have been genetically ablated [47]. CaMKII levels are compared between rdta mice and the normal, littermate control mice. It is demonstrated that retinal CaMKII protein, enzyme activity and mRNA are significantly increased in response to the genetic ablation of rod photoreceptors. The data indicate that CaMKII expression/activity in amacrine and ganglion cells is negatively regulated by the rod photoreceptor-mediated visual input. The regulation appears to occur primarily at the transcriptional level. It is shown that the cytoplasmic polyadenylation element binding protein (CPEB), a regulatory factor for translation that is known to promote CaMKIIalpha translation in dendrites [83], is also present in the mouse retina. However, the polyadenylation-mediated translational control mechanism is not activated in this experimental paradigm.

Protein kinase C isoenzyme expression in retinal cells

Protein kinase C (PKC) is involved in both the physiological and pathophysiological processes in the retina and plays an important role in signal transduction. The aim of this study was to determine the PKC isoenzyme profile in three retinal cell types in culture, namely RPE cells, pericytes and retinal microvascular endothelial cells. Confluent cultures were lysed and isoenzyme expression detected by Western blotting. PKC isoenzymes alpha, beta(2) and delta were observed for all three cell types while beta(1) was specific for RPE cells. This study has characterised the PKC isoenzyme profile in three retinal cell types and suggests that defining the cell-specific isoenzyme pattern is an important step in understanding their precise physiological role and regulation in the retina.

Differential localization and expression of alpha and beta isoenzymes of protein kinase C in the rat retina

Expression and cellular localization of three isoenzymes of Ca2+-dependent protein kinase C (PKCalpha, PKCbeta, and PKCgamma) in the adult rat retina were revealed by immunohistochemistry and in situ hybridization histochemistry with isoenzyme-specific antibodies and cRNA probes. Immunoreactivities and mRNA signals for PKCalpha were conspicuous in rod bipolar cells. A subgroup of amacrine cells expressed PKCalpha. The cells in the ganglion cell layer also displayed PKCalpha gene products. Positive immunoreactivities for PKCbeta were localized as stripe patterns in the inner plexiform layer, corresponding to the stratification levels of axon terminals of cone bipolar cells. The somata of cone bipolar cells expressed PKCbeta. Amacrine cells and retinal ganglion cells also displayed PKCbeta gene products. The results obtained by immunohistochemistry were confirmed with colocalization of mRNA signals for PKCalpha and PKCbeta on the somata. The cell membranes showed stronger immunoreactivities than did the cytoplasms for both PKCalpha and PKCbeta. Neither immunoreactivities nor mRNA signals for PKCgamma were detected in all retinal regions. The differential roles of Ca2+-dependent PKC isoenzymes could be revealed in physiological defined retinal neurons.

Specific interaction of the PDZ domain protein PICK1 with the COOH terminus of protein kinase C-alpha

PICK1 is a protein kinase C (PKC) alpha-binding protein initially identified using the yeast two-hybrid system. Here we report that PICK1 contains a PDZ domain that interacts specifically with a previously unidentified PDZ-binding domain (QSAV) at the extreme COOH terminus of PKCalpha and that mutation of a putative carboxylate-binding loop within the PICK1 PDZ domain abolishes this interaction. The PDZ-binding domain in PKCalpha is absent from other PKC isoforms that do not interact with PICK1. We also demonstrate that PICK1 can homooligomerize through sequences that are distinct from the carboxylate-binding loop, suggesting that self-association and PKCalpha binding are not mutually exclusive. A Caenorhabditis elegans PICK1-like protein is also able to bind to PKCalpha, suggesting a conservation of function through evolution. Association of PKCalpha with PICK1 provides a potential mechanism for the selective targeting of PKCalpha to unique subcellular sites.

Characterization of two forms of protein kinase C alpha, with different substrate specificities, from skeletal muscle

We have investigated protein kinase C (PKC) in skeletal muscle cytosol and demonstrated the presence of two major activities. These did not correspond to different PKC isoenzymes but seemed to represent two species of PKC alpha as deduced by: elution during hydroxyapatite chromatography at KH2PO4 concentrations expected of PKC alpha; detection of the two species by three specific but unrelated anti-(PKC alpha) antibodies; immunodepletion of both activities with anti-(PKC alpha) antibody; and demonstration of identical requirements of both Ca2+ ions and lipid for activation. These species, termed PKC alpha 1 and PKC alpha 2, phosphorylated the modified conventional PKC pseudosubstrate peptide (19-31, Ser-25) equally well. Importantly, however, the activities differed in that PKC alpha 1 phosphorylated histone IIIS, and also peptides derived from the EGF receptor and glycogen synthase, to a much greater extent than did PKC alpha 2. Similarly, incubation of crude muscle extracts with either PKC alpha 1 or alpha 2 gave rise to different protein phosphorylation patterns. The involvement of proteolysis, dephosphorylation or oxidative modification in the interconversion of PKC alpha 1 and PKC alpha 2 during preparation was ruled out. Although some PKC-binding proteins were detected in overlay assays, their presence did not explain the anomalous PKC alpha 2 activity. The results suggest that a modification of PKC alpha in situ limits its substrate specificity, and indicate an additional level of control of the kinase that may be a site for modulation of PKC-mediated signal transduction.

Deletion of specific protein kinase C subspecies in human melanoma cells

It has been shown that tumor-promoting phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA), stimulates the proliferation of normal human melanocytes, whereas it inhibits the growth of human melanoma cell lines. The expression of protein kinase C (PKC) subspecies, the major intracellular receptors for TPA, was examined in normal melanocytes and the four melanoma cell lines HM3KO, MeWo, HMV-1, and G361. PKC was partially purified and then separated into subspecies by column chromatography on Mono Q and hydroxyapatite successively, and finally subjected to immunoblot analysis using antibodies specific for the PKC subspecies. Of the PKC subspecies examined, delta-, epsilon-, and zeta-PKC were detected in both normal melanocytes and the four melanoma cell lines. In contrast, both alpha-PKC and beta-PKC were expressed in normal melanocytes, whereas either alpha-PKC or beta-PKC was detected in melanoma cells. Specifically, HM3KO, MeWo, and HMV-1 cells were shown to contain alpha-PKC but not beta-PKC, while G361 cells expressed beta-PKC but not alpha-PKC. The growth of these melanoma cells was suppressed by TPA treatment, and the growth of the G361 cells lacking alpha-PKC was inhibited more efficiently than the other melanoma cell lines which lacked beta-PKC. It was further shown that beta-PKC was not detected in freshly isolated human primary or metastatic melanoma tissues. These results suggest that the expression of alpha-PKC or beta-PKC may be altered during the malignant transformation of normal melanocytes and that loss of alpha-PKC or beta-PKC may be related to the inhibitory effect of TPA on the growth of melanoma cells.

Differential down-regulation of protein kinase C subspecies in normal human melanocytes: possible involvement of the zeta subspecies in growth regulation

Normal human melanocytes are often grown in vitro in the continuous presence of 12-O-tetradecanoylphorbol-13-acetate (TPA) for growth in vitro. The expression of protein kinase C (PKC) subspecies, which are the major cellular receptors for phorbol esters, was examined in melanocytes after long-term treatment with TPA to investigate the role of PKC subspecies in TPA-dependent cell growth. The PKC enzyme activity detected in quiescent melanocytes was almost completely depleted in cells after incubation with 85 nM TPA for 48 h. Immunoblot analysis indicated that, among the PKC subspecies alpha, beta, delta, epsilon, and zeta expressed in quiescent cells, alpha-, beta-, delta-, and epsilon-PKC were significantly down-regulated, whereas zeta-PKC remained at detectable levels in TPA-treated cells. TPA did not significantly affect the expression or subcellular distribution of zeta-PKC in melanocytes. Immunoprecipitation assay revealed that the enzyme activity of zeta-PKC was increased in both the cytosol and particulate cell fractions, but the increase was much greater in the latter. The activation of zeta-PKC lasted for 24 to 48 h after the addition of TPA; thereafter, zeta-PKC activity returned to basal levels. DNA synthesis was shown to change concomitantly with the activation of zeta-PKC in TPA-treated cells. These results indicate that TPA induces not only the down-regulation of alpha-, beta-, delta-, and epsilon-PKC, but also long-term activation of zeta-PKC in melanocytes, and that activation of zeta-PKC parallels the growth of normal human melanocytes.

Purification of the delta isoenzyme of protein kinase C from the hepatopancreas of the shrimp Penaeus monodon with phosphorylation on tyrosine residues

The delta isoenzyme of protein kinase C (PKC-delta), purified from the plasma membrane of the hepatopancreas of the shrimp Penaeus monodon is specifically phosphorylated at tyrosine residues, as demonstrated by specific dephosphorylation by phosphotyrosyl protein phosphatase from the hepatopancreas of the shrimp Penaeus monodon. The specific activity of purified PKC-delta was 200 units/mg of protein. The subunits of M(r) 66,000, 62,000, and 58,000 of PKC-delta were not autophosphorylated after the addition of phosphatidylserine and diolein. However, the purified PKC-delta was active and catalyzed the phosphorylation of myelin basic protein. The kinase activity of the purified PKC-delta could be decreased after treatment with phosphotyrosyl protein phosphatase.

Alpha-, beta II- and gamma-subspecies of protein kinase C localized in the monkey hippocampus: pre- and post-synaptic localization of gamma-subspecies

Protein kinase C (PKC) has attracted wide attention as a key enzyme for the expression of long-term potentiation in the hippocampus, a basic model for memory. It is of interest to study the detailed localization of PKC subspecies in the monkey hippocampus. We used immunocytochemistry to examine the localization of PKC subspecies in the hippocampus of the monkey, Macaca mulatta. Subspecies of PKC in the monkey could be separated by hydroxyapatite chromatography and the elution profile proved to be similar to that of the rat. Antibodies against each alpha, beta II and gamma-subspecies of the rat specifically reacted with the respective subspecies of monkey PKC. The alpha-, beta II- and gamma-subspecies were distinctly distributed in the hippocampus. The beta I-subspecies was not evident in the hippocampus. While both the alpha- and gamma-subspecies immunoreactive pyramidal cells were distributed throughout the hippocampus (CA1-CA3), the beta II-subspecies immunoreactive cells were scattered only in the CA1 region. The gamma-subspecies was found in granule cells and dendrites in the dentate gyrus, in mossy fibers and in their terminals in the CA3 region. The alpha-subspecies was also present in granule cells and in the dendrites but not in the mossy fibers. Glial cells did not stain with any of the antibodies used. Electron microscopy clearly showed that the gamma-subspecies was localized in both presynaptic terminals and post-synaptic dendrites. These observations suggest that subspecies of PKC in the monkey hippocampus may be involved in distinct functions and that the gamma-subspecies of PKC may act pre- and post-synaptically in pyramidal cells of the hippocampus.

Localization of protein kinase C subspecies in the rabbit retina

The localization of PKC subspecies alpha, beta, gamma, epsilon and zeta was studied immunocytochemically in the rabbit retina. Conventional, Ca(2+)-sensitive PKC subtypes alpha, beta, gamma were all localized in different neuronal populations. The zeta-subspecies, which does not require Ca2+ for activation, was colocalized with PKC-alpha. PKC-epsilon, which is independent of Ca2+ and DAG, was colocalized with PKC-beta. Some populations of neurons, including cone bipolar cells, contained none of the PKC-subspecies studied. These results imply a cellular segregation of different signaling pathways in mammalian retina.

Protein kinase C delta- and epsilon-subspecies in rat central nervous tissue; differential distribution and phorbol ester-induced redistribution in synaptosomes

Distribution of the delta- and epsilon-subspecies of protein kinase C (PKC) in rat central nervous tissues was semiquantitated by an immunoblot analysis. The epsilon-subspecies, which is expressed predominantly in the brain, was abundant in hippocampus and cerebral cortex among rat brain areas, whereas the delta-subspecies, which is expressed ubiquitously in many tissues, showed no significant difference among tissue areas tested. Unlike other subspecies, the delta-subspecies was primarily associated with particulate fractions. Subcellular fractionation analysis revealed that both the epsilon- and delta-subspecies were enriched in the synaptosomal P2 fraction. Treatment with 12-O-tetradecanoyl-phorbol 13-acetate (TPA) induced translocation of the epsilon-subspecies from cytosolic fraction to membrane fraction. In contrast, upon treatment with TPA, the delta-subspecies normally bound to membrane fraction was released into cytosol.

The occurrence of three calcium-independent protein kinase C subspecies (delta, epsilon and zeta) in retina of different species

The localisation and immunochemical identification of three different forms of calcium-independent protein kinase C (PKC-epsilon, PKC-delta and PKC-zeta) in retinas of different species were analysed by immunohistochemistry and SDS-PAGE/Western blotting, respectively. More than one component of different molecular weights reacted with the polyclonal antibodies in all retinal samples though in all instances a component of molecular weight corresponding to the individual PKCs was recognised and could be eliminated or reduced by preincubating the primary antibodies with the peptides used to generate the antibodies. PKC-zeta immunoreactivity was exclusively associated with the inner segments of the photoreceptors in both mammalian (guinea-pig, rabbit, rat) and non-mammalian (goldfish, chick) retinas. PKC-epsilon immunoreactivity is present in bipolar cells, particularly in their terminals of mammalian and goldfish retinas. In the chick retina immunoreactivity for this enzyme and for PKC-delta was with the inner segments of the photoreceptors. The Müller cells in mammalian retinas and a sub-population of ganglion cells in the goldfish retina exhibited positive immunoreactivity for PKC-delta. The immunoreactivities for all the PKC isoenzymes were eliminated or drastically reduced when the primary antibodies were first preincubated with the peptides used to generate the antibodies.

Regulation of delta protein kinase C during rat ovarian differentiation

Studies were undertaken to classify protein kinase C (PKC) forms present in rat corpora lutea and to begin to evaluate their regulation during ovarian differentiation. Hydroxyapatite (HAP) column chromatography of rat luteal tissue revealed the presence of multiple forms of PKC (alpha, beta, delta, zeta). Identification of the PKC isoforms was based upon elution positions from HAP column chromatography and immunoreactivity. The delta PKC isoform was identified as the major Ca(2+)-independent form of PKC present in rat luteal tissue. The Ca(2+)-independent, lipid-dependent phosphorylation of the 80-kDa delta PKC was readily detectable in soluble luteal extracts and was shown to reflect autophosphorylation of delta PKC. To evaluate the regulation of PKC isoforms during ovarian differentiation, PKC protein levels were compared between preovulatory follicle-enriched ovaries and corpora lutea obtained on day 16 of pregnancy. Levels of delta PKC protein were greatly elevated in corpora lutea compared to levels in preovulatory follicles. In contrast, levels of alpha and beta PKC protein remained constant while levels of zeta PKC were slightly higher in the follicular than the luteal extract. Levels of delta PKC mRNA were also higher in corpora lutea than in preovulatory follicles. These results are the first to demonstrate the physiological regulation of delta PKC with follicular differentiation into corpora lutea and implicate a role for this prominent PKC form in the corpus luteum during pregnancy.

Protein kinase C in galactosemic and tolrestat-treated lens epithelial cells

Using isozyme-specific anti-peptide antisera against peptides from the alpha-, beta-, gamma-, delta-, epsilon-, and zeta-isoforms of brain protein kinase C (PKC), we have identified proteins in bovine lens epithelial cells, in culture, that were reactive with these antisera. Western blots of lens epithelial cell homogenates showed that PKC-alpha antisera reacted with a major protein, and PKC-gamma antisera reacted with a minor protein. When the lens epithelial cells were cultured in media supplemented with 40 mM galactose, to model the conditions of sugar cataracts, a decrease in PKC-gamma, but not in PKC-alpha was observed. These were normalized if the cells were cultured in 40 mM galactose media supplemented with an inhibitor of aldose reductase, Tolrestat (10 microM). These results suggest that changes in PKC isoforms occur in the galactosemic diabetic state.