Functional interaction of protein kinase Calpha with the tyrosine kinases Syk and Src in human platelets

There is a high degree of cross-talk between tyrosine phosphorylation and the serine/threonine phosphorylation signaling pathways. Here we show a physical and functional interaction between the classical protein kinase C isoform (cPKC), PKCalpha, and two major nonreceptor tyrosine kinases in platelets, Syk and Src. In the presence of the cPKC-selective inhibitor Go6976, platelet 5-hydroxytryptamine release was abolished in response to co-activation of glycoproteins VI and Ib-IX-V by the snake venom alboaggregin A, whereas platelet aggregation was substantially inhibited. Of the two platelet cPKCs, PKCalpha but not PKCbeta was activated, occurring in an Syk- and phospholipase C-dependent manner. Syk and PKCalpha associate in a stimulation-dependent manner, requiring Syk but not PKC activity. PKCalpha and Syk also co-translocate from the cytosol to the plasma membrane upon platelet activation, in a manner dependent upon the activities of both kinases. Although PKCalpha is phosphorylated on tyrosine downstream of Syk, we provide evidence against phosphorylation of Syk by PKCalpha, consistent with a lack of effect of PKCalpha inhibition on Syk activity. PKCalpha also associates with Src; although in contrast to interaction with Syk, PKCalpha activity is required for the association of these kinases but not the stimulation-induced translocation of Src to the cell membrane. Finally, the activity of Src is negatively regulated by PKC, as shown by potentiation of Src activity in the presence of the PKC inhibitors GF109203X or Go6976. Therefore, there is a complex interplay between PKCalpha, Syk, and Src involving physical interaction, phosphorylation, translocation within the cell, and functional activity regulation.     

Direct binding and activation of protein kinase C isoforms by aldosterone and 17beta-estradiol

Protein kinase C (PKC) is a signal transduction protein that has been proposed to mediate rapid responses to steroid hormones. Previously, we have shown aldosterone directly activates PKCalpha whereas 17beta-estradiol activates PKCalpha and PKCdelta; however, neither the binding to PKCs nor the mechanism of action has been established. To determine the domains of PKCalpha and PKCdelta involved in binding of aldosterone and 17beta-estradiol, glutathione S-transferase fusion recombinant PKCalpha and PKCdelta mutants were used to perform in vitro binding assays with [(3)H]aldosterone and [(3)H]17beta-estradiol. 17beta-Estradiol bound both PKCalpha and PKCdelta but failed to bind PKC mutants lacking a C2 domain. Similarly, aldosterone bound only PKCalpha and mutants containing C2 domains. Thus, the C2 domain is critical for binding of these hormones. Binding affinities for aldosterone and 17beta-estradiol were between 0.5-1.0 nM. Aldosterone and 17beta-estradiol competed for binding to PKCalpha, suggesting they share the same binding site. Phorbol 12,13-dybutyrate did not compete with hormone binding; furthermore, they have an additive effect on PKC activity. EC(50) for activation of PKCalpha and PKCdelta by aldosterone and 17beta-estradiol was approximately 0.5 nM. Immunoblot analysis using a phospho-PKC antibody revealed that upon binding, PKCalpha and PKCdelta undergo autophosphorylation with an EC(50) in the 0.5-1.0 nm range. 17beta-Estradiol activated PKCalpha and PKCdelta in estrogen receptor-positive and -negative breast cancer cells (MCF-7 and HCC-38, respectively), suggesting estrogen receptor expression is not required for 17beta-estradiol-induced PKC activation. The present results provide first evidence for direct binding and activation of PKCalpha and PKCdelta by steroid hormones and the molecular mechanisms involved.     

Competitive binding of protein kinase Calpha to membranes and Rho GTPases

Previously, we have shown that protein kinase C (PKC) forms a direct high-affinity, isozyme-specific and membrane lipid-independent interaction with Rho GTPases [Slater, S. J., Seiz, J. L., Stagliano, B. A., and Stubbs, C. D. (2001) Biochemistry 40, 4437-4445]. Since the cellular activation of PKCalpha involves an initial translocation from cytosolic to membrane compartments, the present study investigates the interdependence between the direct protein-protein interaction of PKCalpha with the Rho GTPase, Cdc42, and the protein-lipid interactions of PKCalpha with membranes. It was hypothesized that the interaction of PKCalpha with membrane-bound Cdc42 would contribute to the overall membrane-binding affinity of the kinase by providing an additional anchor. However, it was found that the incorporation of isoprenylated Cdc42 into membranes resulted in an apparent decrease in the membrane-binding affinity of PKCalpha, whereas the association of PKCbetaI, PKCdelta, PKCepsilon, and PKCzeta was each unaffected. The presence of membrane-bound Cdc42 resulted in a rightward shift in both the PS- and Ca2+-concentration response curves for PKCalpha membrane association and for the ensuing activation, whereas the maximal levels of binding and activation attained at saturating PS and Ca2+ concentrations were in each case unaffected. Overall, these findings suggest that PKCalpha undergoes a isozyme-specific interaction with membrane-bound Cdc42 to form a PKCalpha-Cdc42 complex, which possesses a membrane-binding affinity that is reduced relative to that of the individual components due to competition between Cdc42 and PS/Ca2+ for binding to PKCalpha. Consistent with this, it was found that the interaction of PKCalpha with membrane-bound Cdc42 was accompanied by the physical dissociation of the PKCalpha-Cdc42 complex from membranes. Thus, the study provides a novel mechanism by which the membrane association and activation of PKCalpha and Cdc42 may be regulated by competing protein-protein and protein-lipid interactions.     

Autophosphorylation suppresses whereas kinase inhibition augments the translocation of protein kinase Calpha in response to diacylglycerol

We have seen that protein kinase Calpha (PKCalpha) is transiently translocated to the plasma membrane by carbachol stimulation of neuroblastoma cells. This is induced by the Ca2+ increase, and PKCalpha does not respond to diacylglycerol (DAG). The unresponsiveness is dependent on structures in the catalytic domain of PKCalpha. This study was designed to investigate if and how the kinase activity and autophosphorylation are involved in regulating the translocation. PKCalpha enhanced green fluorescent protein translocation was studied in living neuroblastoma cells by confocal microscopy. Carbachol stimulation induced a transient translocation of PKCalpha to the plasma membrane and a sustained translocation of kinase-dead PKCalpha. In cells treated with the PKC inhibitor GF109203X, wild-type PKCalpha also showed a sustained translocation. The same effects were seen with PKCbetaI, PKCbetaII, and PKCdelta. Only kinase-dead and not wild-type PKCalpha translocated in response to 1,2-dioctanoylglycerol. To examine whether autophosphorylation regulates relocation to the cytosol, the autophosphorylation sites in PKCalpha were mutated to glutamate, to mimic phosphorylation, or alanine, to mimic the non-phosphorylated protein. After stimulation with carbachol, glutamate mutants behaved like wild-type PKCalpha, whereas alanine mutants behaved like kinase-dead PKCalpha. When the alanine mutants were treated with 1,2-dioctanoylglycerol, all cells showed a sustained translocation of the protein. However, neither carbachol nor GF109203X had any major effects on the level of autophosphorylation, and GF109203X potentiated the translocation of the glutamate mutants. We, therefore, hypothesize that 1) autophosphorylation of PKCalpha limits its sensitivity to DAG and 2) that kinase inhibitors augment the DAG sensitivity of PKCalpha, perhaps by destabilizing the closed conformation.     

Inducible and myocyte-specific inhibition of PKCalpha enhances cardiac contractility and protects against infarction-induced heart failure

Mice null for the gene encoding protein kinase Calpha (Prkca), or mice treated with pharmacologic inhibitors of the PKCalpha/beta/gamma isoforms, show an augmentation in cardiac contractility that appears to be cardioprotective. However, it remains uncertain if PKCalpha itself functions in a myocyte autonomous manner to affect cardioprotection in vivo. Here we generated cardiac myocyte-specific transgenic mice using a tetracycline-inducible system to permit controlled expression of dominant negative PKCalpha in the heart. Consistent with the proposed function of PKCalpha, induction of dominant negative PKCalpha expression in the adult heart enhanced baseline cardiac contractility. This increase in cardiac contractility was associated with a partial protection from long-term decompensation and secondary dilated cardiomyopathy after myocardial infarction injury. Similarly, Prkca null mice were also partially protected from infarction-induced heart failure, although the area of infarction injury was identical to controls. Thus, myocyte autonomous inhibition of PKCalpha protects the adult heart from decompensation and dilated cardiomyopathy after infarction injury in association with a primary enhancement in contractility.     

1-Butanol interferes with phospholipase D1 and protein kinase Calpha association and inhibits phospholipase D1 basal activity

1-Butanol is commonly used as a substrate for phospholipase D (PLD) activity measurement. Surprisingly we found that, in the presence of 30 mM 1-butanol (standard PLD assay conditions), PLD1 activity in COS-7 cells was lost after incubation for 2 min. In contrast, in the presence of the protein kinase C (PKC) inhibitor staurosporine or dominant negative PKCalpha D481E, the activity was sustained for at least 30min. The binding between PLD1 and PKCalpha was also lost after 2 min incubation with 30 mM 1-butanol while staurosporine and D481E maintained the binding. 1-Butanol at 2 mM did not inhibit PLD1 basal activity or PLD1 binding to PKCalpha, and staurosporine and PKCalpha D481E produced a constant increase in PLD1 basal activity of 2-fold. These results indicate that 1-butanol is inhibitory to PLD1 activity by reducing its association with PKCalpha, and that the concentration of 1-butanol is an important consideration in assaying basal PLD1 activity.     

Design and characterization of a traceable protein kinase Calpha

Protein kinase Calpha (PKCalpha) is a critical component of pathways that govern cancer-related phenotypes such as invasion and proliferation. Proteins that serve as immediate substrates for PKCalpha offer potential targets for anticancer drug design. To identify specific substrates, a mutant of PKCalpha (M417A) was constructed at the ATP binding site such that it could bind a sterically large ATP analogue derivatized through the N6 amino group of adenosine ([gamma-32P]-N6-phenyl-ATP). Because this analogue could be utilized by the mutant kinase but not by wild-type PKCalpha (or presumably other protein kinase) to phosphorylate peptide or protein substrates, 32P-labeled products were the direct result of the mutant PKCalpha. Kinetic analysis with [gamma-32P]-N6-phenyl-ATP revealed that the mutant retained undiminished affinity for the peptide substrate (Km = 12.4 microM) and a Vmax value (10.3 pmol/min) that was only 3-fold lower than that exhibited by the wild-type enzyme with natural ATP. However, with [gamma-32P]ATP, the mutant had a somewhat lower affinity (Km = 82.8 microM) than the wild-type enzyme (Km = 9.3 microM) in vitro but was competent in causing aggressive motility in nonmotile MCF-10A human breast cells (with endogenous ATP), as previously described for wild-type PKCalpha. The FLAG-tagged PKCalpha mutant was expressed in MCF-10A cells and used to co-immunoprecipitate high-affinity substrates from lysates. Immunopellets were reacted with [gamma-32P]-N6-phenyl-ATP, and radiolabeled products were analyzed by SDS-PAGE and autoradiography. Mass spectrometry of selected bands identified several known substrates of PKC, thereby validating the methods used in these studies. These findings provide a foundation for future applications of this traceable PKCalpha mutant.     

Protein kinase C (PKC) delta regulates PKCalpha activity in a Syndecan-4-dependent manner

The phosphorylation state of Ser(183) in the cytoplasmic tail of syndecan-4 determines the binding affinity of the cytoplasmic tail to phosphatidylinositol 4,5-bisphosphate (PIP(2)), the capacity of the tail to multimerize, and its ability to activate protein kinase C (PKC) alpha. We sought to identify the kinase responsible for this phosphorylation and to determine its downstream effects on PKCalpha activity and on endothelial cell function. Among several PKC isoenzymes tested, only PKCalpha and -delta were able to specifically phosphorylate Ser(183) in vitro. However, studies in cultured endothelial cells showed that the phosphorylation level of syndecan-4 was significantly reduced in endothelial cells expressing a dominant negative (DN) PKCdelta but not a DN PKCalpha mutant. Syndecan-4/PIP(2)-dependent PKCalpha activity was significantly increased in PKCdelta DN cells, while PKCdelta overexpression was accompanied by decreased PKCalpha activity. PKCdelta-overexpressing cells exhibited a significantly lower proliferation rate and an impaired tube formation in response to FGF2, which were mirrored by similar observations in PKCalpha DN endothelial cells. These findings suggest that PKCdelta is the kinase responsible for syndecan-4 phosphorylation, which, in turn, attenuates the cellular response to FGF2 by reducing PKCalpha activity. The reduced PKCalpha activity then leads to impaired endothelial cell function. We conclude that PKCdelta regulates PKCalpha activity in a syndecan-4-dependent manner.     

蛋白激酶Cα在小鼠孤雌及四倍体胚胎早期发育过程中的分布和作用

为了观察蛋白激酶Cα(protein kinase Cα,PKCα在昆明白小鼠受精卵、孤雌激活和四倍体胚胎早期发育阶段的亚细胞定位和致密化进程中的表达变化,本实验利用免疫荧光化学染色与激光共聚焦显微镜观察相结合的方法,对受精卵、孤雌激活和四倍体胚胎早期发育阶段PKCα的表达进行了定位观察,并利用Western blot对三组胚胎致密化进程中PKCα的表达进行定量分析.结果显示,PKCα在上述三组胚胎发育的2-细胞期至囊胚期均有表达,虽然不同胚胎PKCα的分布在同一发育阶段存在差异,却表现出在各胚胎期主要分布于卵裂球核染色质内,以及在胚胎致密化开始,PKCα在卵裂球连接处发生重新分布的共同特点.此外,三组胚胎PKCα在致密化进程中的表达呈升高趋势,即致密化后的表达高于敛密化前.结果表明,PKCct对胚胎致密化的调节具有重要作用,其在8-细胞/4-细胞期的重新分布是胚胎进入桑椹胚期的必然事件,是胚胎致密化的前提,同时伴随蛋白表达增多.此外,PKCα在囊胚期发生了植入前的第二次重新分布.PKCα在三组胚胎各发育阶段表达情况各不相同,它对小鼠胚胎发育的影响体现在整个早期发育阶段.PKCα在小鼠受精卵早期发育阶段的两次重新分布可能与在致密化开始时启动的细胞黏附事件存在某种必然联系.     

Bile acids stimulate PKCalpha autophosphorylation and activation: role in the attenuation of prostaglandin E1-induced cAMP production in human dermal fibroblasts

The aim was to identify the specific PKC isoform(s) and their mechanism of activation responsible for the modulation of cAMP production by bile acids in human dermal fibroblasts. Stimulation of fibroblasts with 25-100 microM of chenodeoxycholic acid (CDCA) and ursodeoxycholic acid (UDCA) led to YFP-PKCalpha and YFP-PKCdelta translocation in 30-60 min followed by a transient 24- to 48-h downregulation of the total PKCalpha, PKCdelta, and PKCepsilon protein expression by 30-50%, without affecting that of PKCzeta. Increased plasma membrane translocation of PKCalpha was associated with an increased PKCalpha phosphorylation, whereas increased PKCdelta translocation to the perinuclear domain was associated with an increased accumulation of phospho-PKCdelta Thr505 and Tyr311 in the nucleus. The PKCalpha specificity on the attenuation of cAMP production by CDCA was demonstrated with PKC downregulation or inhibition, as well as PKC isoform dominant-negative mutants. Under these same conditions, neither phosphatidylinositol 3-kinase, p38 MAP kinase, p42/44 MAP kinase, nor PKA inhibitors had any significant effect on the CDCA-induced cAMP production attenuation. CDCA concentrations as low as 10 microM stimulated PKCalpha autophosphorylation in vitro. This bile acid effect required phosphatidylserine and was completely abolished by the presence of G?6976. CDCA at concentrations less than 50 microM enhanced the PKCalpha activation induced by PMA, whereas greater CDCA concentrations reduced the PMA-induced PKCalpha activation. CDCA alone did not affect PKCalpha activity in vitro. In conclusion, although CDCA and UDCA activate different PKC isoforms, PKCalpha plays a major role in the bile acid-induced inhibition of cAMP synthesis in fibroblasts. This study emphasizes potential consequences of increased systemic bile acid concentrations and cellular bile acid accumulation in extrahepatic tissues during cholestatic liver diseases.     

PKCa translocation from mitochondria to nucleus is closely related to induction of apoptosis in gastric cancer cells

PKCs have been implicated in the regulation of cellular differentiation, proliferation, apoptosis and signal transduction. It was demonstrated in this study that PKCα was located both at mitochondria and in cytosol in gastric cancer cell line BGC-823. Treatment of cells with 12-O-tetradecanoylphorbol-13-acetate (TPA) resulted in the translocation of PKCα from both mitochondria and cytosol to nucleus as clearly shown by laser-scanning-confocal microscopy, while the protein level of PKCα was not changed by TPA treatment as detected by Western blot. The results also revealed that TPA-induced translocation of PKCα was in close association with apoptosis induction, and such association was further affirmed by other experiments where various apoptotic stimuli and specific inhibitors of PKC were used. Taken together, these findings indicate that translocation of PKCα from both mitochondria and cytosol to nucleus in gastric cancer cell is accompanied by induction of apoptosis, and may imply a new mechanism of the potential linking between cell apoptosis and PKCα translocation.     

VCAM-1 signals activate endothelial cell protein kinase Calpha via oxidation

Lymphocyte binding to VCAM-1 activates endothelial cell NADPH oxidase, resulting in the generation of 1 muM H(2)O(2). This is required for VCAM-1-dependent lymphocyte migration. In this study, we identified a role for protein kinase Calpha (PKCalpha) in VCAM-1 signal transduction in human and mouse endothelial cells. VCAM-1-dependent spleen cell migration under 2 dynes/cm(2) laminar flow was blocked by pretreatment of endothelial cells with dominant-negative PKCalpha or the PKCalpha inhibitors, R?-32-0432 or G?-6976. Phosphorylation of PKCalpha(Thr638), an autophosphorylation site indicating enzyme activity, was increased by Ab cross-linking of VCAM-1 on endothelial cells or by the exogenous addition of 1 muM H(2)O(2). The anti-VCAM-1-stimulated phosphorylation of PKCalpha(Thr638) was blocked by scavenging of H(2)O(2) and by inhibition of NADPH oxidase. Furthermore, anti-VCAM-1 signaling induced the oxidation of endothelial cell PKCalpha. Oxidized PKCalpha is a transiently active form of PKCalpha that is diacylglycerol independent. This oxidation was blocked by inhibition of NADPH oxidase. In summary, VCAM-1 activation of endothelial cell NADPH oxidase induces transient PKCalpha activation that is necessary for VCAM-1-dependent transendothelial cell migration.     

Protein kinase C-alpha regulates insulin action and degradation by interacting with insulin receptor substrate-1 and 14-3-3 epsilon

Protein kinase C (PKC)-alpha exerts a regulatory function on insulin action. We showed by overlay blot that PKCalpha directly binds a 180-kDa protein, corresponding to IRS-1, and a 30-kDa molecular species, identified as 14-3-3epsilon. In intact NIH-3T3 cells overexpressing insulin receptors (3T3-hIR), insulin selectively increased PKCalpha co-precipitation with IRS-1, but not with IRS-2, and with 14-3-3epsilon, but not with other 14-3-3 isoforms. Overexpression of 14-3-3epsilon in 3T3-hIR cells significantly reduced IRS-1-bound PKCalpha activity, without altering IRS-1/PKCalpha co-precipitation. 14-3-3epsilon overexpression also increased insulin-stimulated insulin receptor and IRS-1 tyrosine phosphorylation, followed by increased activation of Raf1, ERK1/2, and Akt/protein kinase B. Insulin-induced glycogen synthase activity and thymidine incorporation were also augmented. Consistently, selective depletion of 14-3-3epsilon by antisense oligonucleotides caused a 3-fold increase of IRS-1-bound PKCalpha activity and a similarly sized reduction of insulin receptor and IRS-1 tyrosine phosphorylation and signaling. In turn, selective inhibition of PKCalpha expression by antisense oligonucleotides reverted the negative effect of 14-3-3epsilon depletion on insulin signaling. Moreover, PKCalpha inhibition was accompanied by a >2-fold decrease of insulin degradation. Similar results were also obtained by overexpressing 14-3-3epsilon. Thus, in NIH-3T3 cells, insulin induces the formation of multimolecular complexes, including IRS-1, PKCalpha, and 14-3-3epsilon. The presence of 14-3-3epsilon in the complex is not necessary for IRS-1/PKCalpha interaction but modulates PKCalpha activity, thereby regulating insulin signaling and degradation.     

Peroxisome proliferator-activated receptor-beta/delta inhibits epidermal cell proliferation by down-regulation of kinase activity

Recent work has shown that peroxisome proliferator-activated receptor beta (PPARbeta) attenuates cell proliferation and skin carcinogenesis, and this is due in part to regulation of ubiquitin C expression. In these studies, the role of PPARbeta in modulating ubiquitin-dependent protein kinase Calpha (PKCalpha) levels and phosphorylation signaling pathways was evaluated. Intracellular phosphorylation analysis showed that phosphorylated PKCalpha and other kinases were lower in wild-type mouse skin treated with 12-O-tetradecanoylphorbol-13-acetate (TPA) as compared with PPARbeta-null mouse skin. No differences in expression levels of other PKC isoforms present in skin were observed. Lower ubiquitination of PKCalpha was found in TPA-treated PPARbeta-null skin as compared with wild-type, and inhibition of ubiquitin-dependent proteasome degradation prevented TPA-induced down-regulation of PKCalpha. The activity of PKCalpha and downstream signaling kinases is enhanced, and expression of cyclooxygenase-2 (COX-2) is significantly greater, in PPARbeta-null mouse skin in response to TPA compared with wild-type mouse skin. Inhibition of PKCalpha or COX-2 reduced cell proliferation in TPA-treated PPARbeta-null keratinocytes in a dose-dependent manner, whereas it only slightly influenced cell proliferation in wild-type keratinocytes. Combined, these studies provide strong evidence that PPARbeta attenuates cell proliferation by modulating PKCalpha/Raf1/MEK/ERK activity that may be due in part to reduced ubiquitin-dependent turnover of PKCalpha.     

Protein kinase Calpha is required for endothelin-1-induced proliferation of human myometrial cells.

The role of protein kinase C (PKC)-alpha in endothelin-1 (ET-1)-induced proliferation of human myometrial cells was investigated. Inhibition of conventional PKC with G? 6976 eliminated the proliferative effect of ET-1. Treatment of myometrial cells with an antisense oligonucleotide against PKCalpha efficiently reduced PKCalpha protein expression without effect on other PKC isoforms and resulted in the loss of ET-1-induced cell growth. Immunocytochemistry using an antibody against PKCalpha revealed that there was no PKCalpha immunoreactivity in the nuclei of quiescent nonconfluent untreated cells, whereas it is evenly distributed throughout the cytoplasm. Exposure of myometrial cells to ET-1 for 15 min caused the PKCalpha to shift towards the perinuclear area, and incubation for 60 min caused a shift towards the nucleus. These results reveal that PKCalpha is required for ET-1-induced human myometrial cell growth and suggest that targeting of PKCalpha by antisense nucleotides might be an important approach for the development of anticancer treatments.     

The PDZ domain of PICK1 differentially accepts protein kinase C-alpha and GluR2 as interacting ligands

The C terminus (ct) of protein kinase C-alpha (PKCalpha) has a type I PDZ binding motif, whereas GluR2 has a type II PDZ binding motif. Both motifs are recognized by the PDZ domain of protein interacting with protein kinase C (PICK1), and PICK1-PKCalpha-controlled phosphorylation regulates the synaptic expression and function of GluR2. Here, we show that a specific mutation within the carboxylate-binding loop of the PDZ domain of PICK1 (K27E; PICK1-KE) results in a loss of interaction with GluR2 but not with PKCalpha. In GST pull-down studies, PICK1-WT (wild type) but not PICK1-KE was retained by GST-ct-GluR2. Furthermore, PICK1-WT co-immunoprecipitated both PKCalpha and GluR2, whereas PICK1-KE only co-immunoprecipitated PKCalpha. In heterologous cells, PICK1-WT, but not PICK1-KE, clustered GluR2 and also clustered GluR1 in a GluR2-dependent manner. However, neither PICK1-WT nor PICK1-KE altered the distribution of PKCalpha, even after phorbol ester-induced redistribution of PKCalpha to the membrane. Finally, PICK1-KE showed no mislocalization when compared with PICK1-WT in neurons. Taken together, it appears that the PDZ domain of PICK1 is less sensitive to mutations for PKCalpha when compared with GluR2 binding. These results suggest that the PDZ domain of PICK1 has distinct PKCalpha and GluR2 binding subsite(s).     

Involvement of mu- and m-calpains and protein kinase C isoforms in L8 myoblast differentiation

The objectives were to investigate the roles of different calpains and protein kinase C (PKC) isoforms in muscle differentiation. Concentrations of mu- and m-calpain increased significantly whereas PKCalpha and delta declined significantly during L8 myoblast differentiation. Both mu-calpain and m-calpain antisense oligonucleotides inhibited myotube formation and creatine kinase activity during L8 myoblast differentiation. These results implied that both mu- and m-calpain were involved in L8 myoblast differentiation. To investigate the involvement of calpain in regulation of PKC concentrations, mu-calpain antisense oligonucleotides were added to L8 myoblasts. PKCalpha remained unchanged and PKCdelta declined. By adding m-calpain antisense oligonucleotides instead, PKCalpha level remained unchanged and PKCdelta concentrations increased significantly during differentiation. These results suggest that PKCalpha, but not PKCdelta, is the substrate for mu-calpain and PKCalpha and delta are the substrates for the m-calpain. In addition, more phosphorylated myogenin was found in day 2 antisense oligonucleotides treated L8 cells. It is concluded that the decline of PKCalpha mediated by m- and mu-calpain is essential for L8 myoblast differentiation. The decline of PKC during myoblast differentiation may cause hypo-phosphorylation of myogenin, which in turn activates muscle-specific genes during myogenesis.