Phosphorylation Of Protein Kinase C Substrate Research Articles

Abstract 123: Protein Kinase C Theta (PKCθ) Signaling Associated With The Generation Of Procoagulant Platelets Revealed By Phosphoproteomics And Systems Analysis

Protein kinase C (PKC) family members integrate platelet activation programs to support hemostasis, and, also drive inflammatory and vascular diseases. While some PKC isoforms have established roles in platelets, roles for PKCθ are less specified. Here, we aim to determine how PKCθ signaling orchestrates platelet function. We prepared washed platelets from human donors for biochemical, physiological and omics studies. Platelet signaling and physiology were studied following stimulation with agonists, including the glycoprotein receptor GPVI agonist crosslinked collagen-related peptide (CRP-XL), and protease activated receptor PAR1 and PAR4 agonists, TRAP6 and AYPGKF-NH 2 . Platelets were treated with inhibitors of PKC family members to study PKC activation mechanisms by Western blot using antisera against specific phosphorylation sites on PKC isoforms and PKC substrates. Phosphoproteomics studies of GPVI and PAR agonist-stimulated platelets quantified significant, site-specific changes in the phosphorylation of PKC isoforms as well as PKC substrates. In addition to established phosphorylation events (e.g., PKCδ Tyr311), we noted a novel, prominent phosphorylation on the C-terminus PKCθ at Ser685. After generating and characterizing antisera specifically reactive to PKCθ phospho-Ser685, Western blot analysis determined that PKCθ Ser685 phosphorylation occurred later following GPVI platelet activation (>5 min) relative to PKCδ Tyr311 phosphorylation and PKC substrate phosphorylation driven by calcium-dependent PKCs. Treatment of platelets with specific PKC inhibitors revealed that PKCα/β, PKCθ, and, to a lesser extent, PKCδ activities all determine PKCθ Ser685 phosphorylation. In parallel, platelet function studies found that inhibition of PKCθ had only minor effects on platelet secretion and aggregation; however, PKCθ inhibition significantly reduced platelet phosphatidylserine exposure - a marker of procoagulant platelet activity - in response to GPVI and PAR agonists. Together, our results suggest that PKCδ and PKCα/β activities drive the phosphorylation of PKCθ Ser685 to support procoagulant platelet generation in a manner that may be blunted by therapeutically relevant small molecule kinase inhibitors.

PKC signal amplification suppresses non-small cell lung cancer growth by promoting p21 expression and phosphorylation

Protein kinase C (PKC) activation was previously associated with oncogenic features. However, small molecule inhibitors targeting PKC have so far proved ineffective in a number of clinical trials for cancer treatment. Recent progresses have revealed that most PKC mutations detected in diverse cancers actually lead to loss-of-function, thus suggesting the tumor-suppressive roles of PKC proteins. Unfortunately, the development of chemicals to enhance PKC activity is lagging behind relative to its small molecular inhibitors. Here, we report that a bisindolylmaleimide derivative (3,4-bis(1-(prop-2-ynyl)-1H-indol-3-yl)-1 H-pyrrole-2,5-dione, BD-15) significantly inhibited cell growth in non-small cell lung cancer (NSCLC). Mechanistically, BD-15 treatment resulted in markedly enhanced phosphorylation of PKC substrates and led to cell cycle arrest in G2/M. Further, BD-15 treatment upregulated p21 protein levels and enhanced p21 phosphorylation. BD-15 also promoted caspase3 cleavage and triggered cellular apoptosis. In xenograft mouse models, BD-15 exerted anti-tumor effects to suppress in vivo tumor formation. Collectively, our findings revealed the tumor-suppressive roles of BD-15 through enhancing PKC signaling and thus leading to upregulation of p21 expression and phosphorylation.

Targeted disruption of PKC from AKAP signaling complexes.

Protein Kinase C (PKC) is a member of the AGC subfamily of kinases and regulates a wide array of signaling pathways and physiological processes. Protein–protein interactions involving PKC and its scaffolding partners dictate the spatiotemporal dynamics of PKC activity, including its access to activating second messenger molecules and potential substrates. While the A Kinase Anchoring Protein (AKAP) family of scaffold proteins universally bind PKA, several were also found to scaffold PKC, thereby serving to tune its catalytic output. Targeting these scaffolding interactions can further shed light on the effect of subcellular compartmentalization on PKC signaling. Here we report the development of two hydrocarbon stapled peptides, CSTAD5 and CSTAD6, that are cell permeable and bind PKC to disrupt PKC–gravin complex formation in cells. Both constrained peptides downregulate PMA-induced cytoskeletal remodeling that is mediated by the PKC–gravin complex as measured by cell rounding. Further, these peptides downregulate PKC substrate phosphorylation and cell motility. To the best of our knowledge, no PKC-selective AKAP disruptors have previously been reported and thus CSTAD5 and CSTAD6 are novel disruptors of PKC scaffolding by AKAPs and may serve as powerful tools for dissecting AKAP-localized PKC signaling.

Amplified Protein Kinase C Signaling in Alzheimer's Disease

Protein kinase C (PKC) isozymes are tightly regulated kinases that transduce signals from receptor‐mediated hydrolysis of membrane phospholipids. Whereas loss‐of‐function mutations in PKC are associated with cancer, germline mutations that enhance the activity of one isozyme, PKCα, are associated with Alzheimer’s Disease (AD). Here we show that introducing a highly penetrant AD‐associated variant of PKCα (M489V; increases catalytic activity by 30%) into a mouse model accelerates brain pathogenesis and results in a cognitive defect compared to wild‐type mice. Specifically, behavioral studies reveal a cognitive impairment in mice harboring this mutation compared to WT mice at 12 months of age, as assessed by performance on a Barnes Maze test, which measures spatial learning and memory. Additionally, the presence of the PKCα mutation in an AD mouse model overexpressing the amyloid precursor protein with the Swedish mutation, significantly exacerbated the cognitive decline as early as 6 months of age. To better understand the molecular basis for the cognitive defect, we analyzed the phosphoproteome and synapse morphology of mice harboring the PKCα M489V mutation. Analysis of the brain phosphoproteome of PKCα M489V mice vs wild‐type mice identified a variety of substrates with altered phosphorylation including known substrates of PKC involved in synaptic depression. Phosphorylation of one such protein, MARCKS, was increased both in mice harboring the PKCα mutation as well as human brains from patients with AD. Analysis of spine density revealed a modest (approximately 10%) but highly significant reduction in the number of spines per micron in the homozygous M489V mice compared to the wild‐type mice. Reduced spine density is consistent with the enhanced phosphorylation of MARCKS observed in brains from the M489V mice. In summary, this work reveals that a single amino acid change in the catalytic domain of PKCα is sufficient to cause increased phosphorylation of PKC substrates, neurite degeneration, and cognitive decline. These data strongly support inhibition of PKCα as a potential therapeutic target in AD.Support or Funding InformationCure Alzheimer's Fund

Protein kinase C signaling dysfunction in von Willebrand disease (p.V1316M) type 2B platelets

Abstractvon Willebrand disease (VWD) type 2B is characterized by gain-of-function mutations in von Willebrand factor (VWF), enhancing its binding affinity for the platelet receptor glycoprotein (GP)Ibα. VWD type 2B patients display a bleeding tendency associated with loss of high-molecular-weight VWF multimers and variable thrombocytopenia. We recently demonstrated that a marked defect in agonist-induced activation of the small GTPase, Rap1, and integrin αIIbβ3 in VWD (p.V1316M) type 2B platelets also contributes to the bleeding tendency. Here, we investigated the molecular mechanisms underlying impaired platelet Rap1 signaling in this disease. Two distinct pathways contribute to Rap1 activation in platelets: rapid activation mediated by the calcium-sensing guanine nucleotide exchange factor CalDAG–GEF-I (CDGI) and sustained activation that is dependent on signaling by protein kinase C (PKC) and the adenosine 5′-diphosphate receptor P2Y12. To investigate which Rap1 signaling pathway is affected, we expressed VWF/p.V1316M by hydrodynamic gene transfer in wild-type and Caldaggef1−/− mice. Using αIIbβ3 integrin activation as a read-out, we demonstrate that platelet dysfunction in VWD (p.V1316M) type 2B affects PKC-mediated, but not CDGI-mediated, activation of Rap1. Consistently, we observed decreased PKC substrate phosphorylation and impaired granule release in stimulated VWD type 2B platelets. Interestingly, the defect in PKC signaling was caused by a significant increase in baseline PKC substrate phosphorylation in circulating VWD (p.V1316M) type 2B platelets, suggesting that the VWF–GPIbα interaction leads to preactivation and exhaustion of the PKC pathway. Consistent with PKC preactivation, VWD (p.V1316M) type 2B mice also exhibited marked shedding of platelet GPIbα. In summary, our studies identify altered PKC signaling as the underlying cause of platelet hypofunction in p.V1316M-associated VWD type 2B.

Protein kinase C activity is a protective modifier of Purkinje neuron degeneration in cerebellar ataxia.

Among the many types of neurons expressing protein kinase C (PKC) enzymes, cerebellar Purkinje neurons are particularly reliant on appropriate PKC activity for maintaining homeostasis. The importance of PKC enzymes in Purkinje neuron health is apparent as mutations in PRKCG (encoding PKCγ) cause cerebellar ataxia. PRKCG has also been identified as an important node in ataxia gene networks more broadly, but the functional role of PKC in other forms of ataxia remains unexplored, and the mechanisms by which PKC isozymes regulate Purkinje neuron health are not well understood. Here, we investigated how PKC activity influences neurodegeneration in inherited ataxia. Using mouse models of spinocerebellar ataxia type 1 (SCA1) and 2 (SCA2) we identify an increase in PKC-mediated substrate phosphorylation in two different forms of inherited cerebellar ataxia. Normalizing PKC substrate phosphorylation in SCA1 and SCA2 mice accelerates degeneration, suggesting that the increased activity observed in these models is neuroprotective. We also find that increased phosphorylation of PKC targets limits Purkinje neuron membrane excitability, suggesting that PKC activity may support Purkinje neuron health by moderating excitability. These data suggest a functional role for PKC enzymes in ataxia gene networks, and demonstrate that increased PKC activity is a protective modifier of degeneration in inherited cerebellar ataxia.

Calcium-Dependent Protein Kinase C Is Not Required for Post-Tetanic Potentiation at the Hippocampal CA3 to CA1 Synapse.

Post-tetanic potentiation (PTP) is a widespread form of short-term synaptic plasticity in which a period of elevated presynaptic activation leads to synaptic enhancement that lasts tens of seconds to minutes. A leading hypothesis for the mechanism of PTP is that tetanic stimulation elevates presynaptic calcium that in turn activates calcium-dependent protein kinase C (PKC) isoforms to phosphorylate targets and enhance neurotransmitter release. Previous pharmacological studies have implicated this mechanism in PTP at hippocampal synapses, but the results are controversial. Here we combine genetic and pharmacological approaches to determine the role of classic PKC isoforms in PTP. We find that PTP is unchanged in PKC triple knock-out (TKO) mice in which all calcium-dependent PKC isoforms have been eliminated (PKCα, PKCβ, and PKCγ). We confirm previous studies and find that in wild-type mice 10 μm of the PKC inhibitor GF109203 eliminates PTP and the PKC activator PDBu enhances neurotransmitter release and occludes PTP. However, we find that the same concentrations of GF109203 and PDBu have similar effects in TKO animals. We also show that 2 μm GF109203 does not abolish PTP even though it inhibits the PDBu-dependent phosphorylation of PKC substrates. We conclude that at the CA3 to CA1 synapse Ca(2+)-dependent PKC isoforms do not serve as calcium sensors to mediate PTP. Neurons dynamically regulate neurotransmitter release through many processes known collectively as synaptic plasticity. Post-tetanic potentiation (PTP) is a widespread form of synaptic plasticity that lasts for tens of seconds that may have important computational roles and contribute to short-term memory. According to a leading mechanism, presynaptic calcium activates protein kinase C (PKC) to increase neurotransmitter release. Pharmacological studies have also implicated this mechanism at hippocampal CA3 to CA1 synapses, but there are concerns about the specificity of PKC activators and inhibitors. We therefore used a molecular genetic approach and found that PTP was unaffected when all calcium-dependent PKC isozymes were eliminated. We conclude that PKC isozymes are not the calcium sensors that mediate PTP at the CA3 to CA1 synapse.

Zinc depletion activates porcine metaphase II oocytes independently of the protein kinase C pathway.

Zinc is an important trace element that regulates several biological functions. This study investigated the role of zinc in the metaphase (M) II arrest of porcine oocytes. N, N, N', N'-tetrakis(2-pyridylmethyl)ethylenediamine (TPEN), a Zn(2+) chelator, was used to deplete free zinc from porcine MII stage oocytes. TPEN treatment significantly (P < 0.01) reduced the zinc content in the cytoplasm. The percentages of oocytes in which second polar body emission and pronuclear formation occurred increased as the concentration of TPEN increased (P < 0.01), and reached 93.64 ± 5.53% and 90.61 ± 9.10%, respectively, following treatment with 10 μM TPEN. Zinc depletion also resulted in cortical granule release and spindle depolarization. Maturation-promoting factor activity, as assessed by examining p34(cdc2) activity, decreased (P < 0.05) following zinc depletion. Following TPEN treatment, embryos developed to the 4-cell stage but failed to reach the blastocyst stage. Zinc release is a common event in protein kinase C (PKC) activation. Therefore, we examined the impact of zinc depletion on phosphorylation of PKC substrates. Phosphorylation of PKC substrates was reduced (P < 0.05) in zinc-depleted oocytes, and this was rescued by phorbol 12-myristate 13-acetate (PMA) treatment. However, treatment of oocytes with both PMA and TPEN did not affect pronuclear formation or second polar body emission. These data are inconsistent with the hypothesis that oocyte activation caused by zinc depletion is mediated by the PKC pathway. This study shows that zinc has a novel role in maintaining MII arrest in porcine oocytes, but this is not mediated by the PKC pathway.

Gravin‐mediated PKC signaling in heart (LB571)

Gravin is an A‐Kinase Anchoring Protein (AKAP) that scaffolds protein kinase A (PKA), protein kinase C (PKC), phosphatase 2B, β2‐adrenergic receptors to specific subcellular compartments. Studies show that scaffolding of PKC by gravin decreases PKC activity due to sequestration. Also, PKC is involved in the translocation and distribution of gravin. Our goal is to study the role of gravin in PKC signaling in the heart. Basal PKC activity in the cytosolic fractions of the homogenized hearts was found to be greater in gravin truncated (t/t) mice as compared to wild type (WT). This correlation was preserved following stimulation of the samples with a PKC activator, PMA (Phorbol 12‐myristate 13‐acetate). However, no change was observed in the extent of PKC substrate phosphorylation between these groups. It supports previous studies that PKC scaffolding by gravin decreases PKC activity. The next step is to study the effect of PKC on gravin translocation in cardiomyocytes using PKC activator PMA and inhibitor chelerythrine. We expect to see increased translocation of gravin to cytosol after PKC activation. These studies will help us better understand the functional significance of the role of gravin in PKC signaling.Grant Funding Source: R01HL085487

Protein kinase C (PKC) participates in acetaminophen hepatotoxicity through c-jun-N-terminal kinase (JNK)-dependent and -independent signaling pathways

This study examines the role of protein kinase C (PKC) and AMP-activated kinase (AMPK) in acetaminophen (APAP) hepatotoxicity. Treatment of primary mouse hepatocytes with broad-spectrum PKC inhibitors (Ro-31-8245, Go6983), protected against APAP cytotoxicity despite sustained c-jun-N-terminal kinase (JNK) activation. Broad-spectrum PKC inhibitor treatment enhanced p-AMPK levels and AMPK regulated survival-energy pathways including autophagy. AMPK inhibition by compound C or activation using an AMPK activator oppositely modulated APAP cytotoxicity, suggesting that p-AMPK and AMPK regulated energy survival pathways, particularly autophagy, play a critical role in APAP cytotoxicity. Ro-31-8245 treatment in mice up-regulated p-AMPK levels, increased autophagy (i.e., increased LC3-II formation, p62 degradation), and protected against APAP-induced liver injury, even in the presence of sustained JNK activation and translocation to mitochondria. In contrast, treatment of hepatocytes with a classical PKC inhibitor (Go6976) protected against APAP by inhibiting JNK activation. Knockdown of PKC-α using antisense (ASO) in mice also protected against APAP-induced liver injury by inhibiting JNK activation. APAP treatment resulted in PKC-α translocation to mitochondria and phosphorylation of mitochondrial PKC substrates. JNK 1 and 2 silencing in vivo decreased APAP-induced PKC-α translocation to mitochondria, suggesting PKC-α and JNK interplay in a feed-forward mechanism to mediate APAP-induced liver injury. Conclusion: PKC-α and other PKC(s) regulate death (JNK) and survival (AMPK) proteins, to modulate APAP-induced liver injury. (Hepatology 2014;59:1543-1554)

Sustained PKCβII activity confers oncogenic properties in a phospholipase D‐ and mTOR‐dependent manner

Protein kinase C (PKC) is a family of serine/threonine kinases implicated in a variety of physiological processes. We have shown previously that sustained activation of the classical PKCα and PKCβII induces their phospholipase D (PLD)-dependent internalization and translocation to a subset of the recycling endosomes defined by the presence of PKC and PLD (the pericentrion), which results in significant differences in phosphorylation of PKC substrates. Here, we have investigated the biological consequences of sustained PKC activity and the involvement of PLD in this process. We find that sustained activation of PKC results in activation of the mammalian target of rapamycin (mTOR)/S6 kinase pathway in a PLD- and endocytosis-dependent manner, with both pharmacologic inhibitors and siRNA implicating the PLD2 isoform. Notably, dysregulated overexpression of PKCβII in A549 lung cancer cells was necessary for the enhanced proliferation and migration of these cancer cells. Inhibition of PKCβII with enzastaurin reduced A549 cell proliferation by >60% (48 h) and migration by >50%. These biological effects also required both PLD activity and mTOR function, with both the PLD inhibitor FIPI and rapamycin reducing cell growth by >50%. Reciprocally, forced overexpression of wild-type PKCβII, but not an F666D mutant that cannot interact with PLD, was sufficient to enhance cell growth and increase migration of noncancerous HEK cells; indeed, both properties were almost doubled when compared to vector control and PKC-F666D-overexpressing cells. Notably, this condition was also dependent on both PLD and mTOR activity. In summary, these data define a PKC-driven oncogenic signaling pathway that requires both PLD and mTOR, and suggest that inhibitors of PLD or mTOR would be beneficial in cancers where PKC overexpression is a contributing or driving factor.

Targeting Sphingosine Kinase 1 in Carcinoma Cells Decreases Proliferation and Survival by Compromising PKC Activity and Cytokinesis

Sphingosine kinases (SK) catalyze the phosphorylation of proapoptotic sphingosine to the prosurvival factor sphingosine 1-phosphate (S1P), thereby promoting oncogenic processes. Breast (MDA-MB-231), lung (NCI-H358), and colon (HCT 116) carcinoma cells were transduced with shRNA to downregulate SK-1 expression or treated with a pharmacologic SK-1 inhibitor. The effects of SK-1 targeting were investigated by measuring the level of intracellular sphingosine, the activity of protein kinase C (PKC) and cell cycle regulators, and the mitotic index. Functional assays included measurement of cell proliferation, colony formation, apoptosis, and cell cycle analysis. Downregulation of SK-1 or its pharmacologic inhibition increased intracellular sphingosine and decreased PKC activity as shown by reduced phosphorylation of PKC substrates. In MDA-MB-231 cells this effect was most pronounced and reduced cell proliferation and colony formation, which could be mimicked using exogenous sphingosine or the PKC inhibitor RO 31-8220. SK-1 downregulation in MDA-MB-231 cells increased the number of cells with 4N and 8N DNA content, and similar effects were observed upon treatment with sphingosine or inhibitors of SK-1 or PKC. Examination of cell cycle regulators unveiled decreased cdc2 activity and expression of Chk1, which may compromise spindle checkpoint function and cytokinesis. Indeed, SK-1 kd cells entered mitosis but failed to divide, and in the presence of taxol also failed to sustain mitotic arrest, resulting in further increased endoreduplication and apoptosis. Our findings delineate an intriguing link between SK-1, PKC and components of the cell cycle machinery, which underlines the significance of SK-1 as a target for cancer therapy.

Abstract 40: Protein Kinase C Regulation of 12-Lipoxygenase-Mediated Human Platelet Activation

Introduction: Platelet activation is important in the regulation of hemostasis and thrombosis. Uncontrolled activation of platelets may lead to arterial thrombosis which is a major cause of myocardial infarction and stroke. Following activation, metabolism of arachidonic acid (AA) by 12-lipoxygenase (12-LOX) may play a significant role in regulating the degree and stability of platelet activation as inhibition of 12-LOX significantly attenuates platelet aggregation in response to various agonists. Protein kinase C (PKC) activation is also known to be an important regulator of platelet activity. Objectives: Using a newly developed selective inhibitor for 12-LOX and a pan-PKC inhibitor, we investigated the role of PKC in 12-LOX-mediated regulation of agonist signaling in the platelet. Methods: To determine the role of PKC within the 12-LOX pathway, a number of biochemical endpoints were measured in human platelets including platelet aggregation, calcium mobilization, integrin activation, and phosphorylation of PKC substrates. Results: Inhibition of 12-LOX or PKC resulted in inhibition of dense granule secretion and attenuation of both aggregation and αIIbβ 3 activation. However, activation of PKC downstream of 12-LOX inhibition rescued agonist-induced aggregation and integrin activation. Additionally, direct PKC activation rescued deficits in phosphorylation of pleckstrin and other PKC substrates mediated by inhibition of 12-LOX. Finally, inhibition of 12-LOX had no effect on PKC-mediated aggregation indicating that 12-LOX is upstream of PKC. Conclusions: These studies support an essential role for PKC downstream of 12-LOX activation in human platelets and suggest 12-LOX as a possible target for anti-platelet therapy.

Peroxynitrite causes phosphorylation of vasodilator-stimulated phosphoprotein through a PKC dependent mechanism

Peroxynitrite is a potent nitrating and oxidizing agent that exerts differential effects on platelets. In the present study we investigated the influence of peroxynitrite on vasodilator-stimulated phosphoprotein (VASP), a protein that plays a key role in inhibition of platelet adhesion and spreading. In platelets, VASP is a substrate for protein kinase A (PKA), PKC and PKG and phosphorylation by these kinases is thought to block VASP-mediated actin cytoskeletal rearrangement. In the present study, we demonstrate that peroxynitrite phosphorylates VASP by a PKC-dependent mechanism. Peroxynitrite (0–100 µM) induced a concentration and time-dependent increase in phosphorylation of VASP at serine157 (Ser157) and Ser239. Inhibition of soluble guanylyl cyclase (sGC) did not significantly reduce peroxynitrite-mediated phosphorylation, indicating a cGMP-independent pathway for VASP phosphorylation. In contrast nitric oxide-mediated VASP phosphorylation was abolished under conditions of sGC inhibition. Further exploration of the mechanisms underlying VASP phosphorylation indicated a requirement for Ca2+ mobilization, but was independent of protein kinase A, Src kinases and protein nitration. Consistent with previous reports phorbol 12-myristate 13-acetate (PMA; 300 nM) induced phosphorylation of VASP at Ser157, but not Ser239, which was blocked by general protein kinase C (PKC) inhibitors, Ro31-8220 and Bisindolylmaleimide I (BIM-1), and Gö6976, an inhibitor of conventional PKC isoforms. Interestingly, treatment of platelets with these PKC inhibitors significantly reduced peroxynitrite-mediated phosphorylation of both sites, indicating that phosphorylation occurred through PKC-dependent mechanism. Consistent with these findings peroxynitrite caused a small increase in PKC activity as evidenced by increased phosphorylation of PKC substrates. Together these data indicate that peroxynitrite may inhibit platelet function by inducing the phosphorylation of VASP through a mechanism that requires the activation of PKC.

Electroconvulsive seizure increases phosphorylation of PKC substrates, including GAP-43, MARCKS, and neurogranin, in rat brain

Protein kinase C (PKC) has been suggested as a molecular target related to the pathogenetic and therapeutic mechanisms of mood disorders in which electroconvulsive seizure (ECS) is effective. However, the reports concerning the effects of ECS on PKC are anecdotal and need further clarification. In this study, we examined the effects of ECS treatment on the phosphorylation of PKC substrates, including GAP-43, MARCKS, and neurogranin. Immunoblot using anti-p-PKC substrate antibodies revealed that a single ECS treatment induced temporal changes in the phosphorylation level of PKC substrates in rat brain, reflecting the effects on PKC activity. Phosphorylation of GAP-43 and MARCKS, representative PKC substrates related to synaptic remodeling, increased from 5 to 30 min, after a transient decrease at 0 min immediately after ECS, and returned to basal levels at 60 min in rat frontal cortex, hippocampus, and cerebellum. Phosphorylation of neurogranin, another PKC substrate, showed a similar pattern of temporal changes in the frontal cortex and hippocampus. Immunohistochemical analysis revealed that p-GAP-43 and p-MARCKS were densely stained throughout the neuronal cells of the prefrontal cortex and hippocampus, and the Purkinje cells of cerebellum, after ECS treatment. Brief and transient activation of PKC may be translated into long-term biochemical changes, resulting in synaptic plasticity. Taken together, the acute effects of ECS on PKC activity, which could be an underpinning of long-term biochemical changes induced by ECS, may contribute to understand the molecular mechanism of ECS.

Protein kinase C inhibitors alter neurotensin receptor binding and function in prostate cancer PC3 cells

Prostate cancer PC3 cells expressed constitutive protein kinase C (PKC) activity that under basal conditions suppressed neurotensin (NT) receptor function. The endogenous PKC activity, assessed using a cell-based PKC substrate phosphorylation assay, was diminished by PKC inhibitors and enhanced by phorbol myristic acid (PMA). Accordingly, PKC inhibitors (staurosporine, Go-6976, Go-6983, Ro-318220, BIS-1, chelerythrine, rottlerin, quercetin) enhanced NT receptor binding and NT-induced inositol phosphate (IP) formation. In contrast, PMA inhibited these functions. The cells expressed conventional PKCs (α, βI) and novel PKCs (δ, ε), and the effects of PKC inhibitors on NT binding were blocked by PKC downregulation. The inhibition of NT binding by PMA was enhanced by okadaic acid and blocked by PKC inhibitors. However, when some PKC inhibitors (rottlerin, BIS-1, Ro-318220, Go-69830, quercetin) were used at higher concentrations (>2 μM), they had a different effect characterized by a dramatic increase in NT binding and an inhibition of NT-induced IP formation. The specificity of the agents implicated novel PKCs in this response and indeed, the inhibition of NT-induced IP formation was reproduced by PKCδ or PKCε knockdown. The inhibition of IP formation appeared to be specific to NT since it was not observed in response to bombesin. Scatchard analyses indicated that the PKC-directed agents modulated NT receptor affinity, not receptor number or receptor internalization. These findings suggest that PKC participates in heterologous regulation of NT receptor function by two mechanisms: a) — conventional PKCs inhibit NT receptor binding and signaling; and b) — novel PKCs maintain the ability of NT to stimulate PLC. Since NT can activate PKC upon binding to its receptor, it is possible that NT receptor is also subject to homologous regulation by PKC.

Phosphorylation of Pleckstrin Increases Proinflammatory Cytokine Secretion by Mononuclear Phagocytes in Diabetes Mellitus

The protein kinase C (PKC) family of intracellular enzymes plays a crucial role in signal transduction for a variety of cellular responses of mononuclear phagocytes including phagocytosis, oxidative burst, and secretion. Alterations in the activation pathways of PKC in a variety of cell types have been implicated in the pathogenesis of the complications of diabetes. In this study, we investigated the consequences of PKC activation by evaluating endogenous phosphorylation of PKC substrates with a phosphospecific PKC substrate Ab (pPKC(s)). Phosphorylation of a 40-kDa protein was significantly increased in mononuclear phagocytes from diabetics. Phosphorylation of this protein is downstream of PKC activation and its phosphorylated form was found to be associated with the membrane. Mass spectrometry analysis, immunoprecipitation, and immunoblotting experiments revealed that this 40-kDa protein is pleckstrin. We then investigated the phosphorylation and translocation of pleckstrin in response to the activation of receptor for advanced glycation end products (RAGE). The results suggest that pleckstrin is involved in RAGE signaling and advanced glycation end product (AGE)-elicited mononuclear phagocyte dysfunction. Suppression of pleckstrin expression with RNA interference silencing revealed that phosphorylation of pleckstrin is an important intermediate in the secretion and activation pathways of proinflammatory cytokines (TNF-alpha and IL-1beta) induced by RAGE activation. In summary, this study demonstrates that phosphorylation of pleckstrin is up-regulated in diabetic mononuclear phagocytes. The phosphorylation is in part due to the activation of PKC through RAGE binding, and pleckstrin is a critical molecule for proinflammatory cytokine secretion in response to elevated AGE in diabetes.

Peptides Derived from the C2 Domain of Protein Kinase Cϵ (ϵPKC) Modulate ϵPKC Activity and Identify Potential Protein-Protein Interaction Surfaces

Peptides Derived from the C2 Domain of Protein Kinase Cϵ (ϵPKC) Modulate ϵPKC Activity and Identify Potential Protein-Protein Interaction Surfaces

Nefiracetam Potentiates N-Methyl-d-aspartate (NMDA) Receptor Function via Protein Kinase C Activation and Reduces Magnesium Block of NMDA Receptor

Nicotinic acetylcholine receptors and N-methyl-D-aspartate (NMDA) receptors are known to be down-regulated in the brain of Alzheimer's disease patients. We have previously demonstrated that the nootropic drug nefiracetam potentiates the activity of both nicotinic acetylcholine and NMDA receptors and that nefiracetam modulates the glycine binding site of the NMDA receptor. Because the NMDA receptor is also modulated by Mg2+ and protein kinases, we studied their roles in nefiracetam action on the NMDA receptor by the whole-cell patch-clamp technique and immunoblotting analysis using rat cortical or hippocampal neurons in primary culture. The nefiracetam potentiation of NMDA currents was inhibited by the protein kinase C (PKC) inhibitor chelerythrine, but not by the protein kinase A (PKA) inhibitor N-[2-(4-bromocinnamylamino)ethyl]-5-isoquinoline (H89). In immunoblotting analysis, nefiracetam treatment increased the PKCalpha activity with a bell-shaped dose-response relationship peaking at 10 nM, thereby increasing phosphorylation of PKC substrate and NMDA receptor. Such an increase in PKCalpha-mediated phosphorylation was prevented by chelerythine. Nefiracetam treatment did not affect the PKA activity. Analysis of the current-voltage relationships revealed that nefiracetam at 10 nM largely eliminated voltage-dependent Mg2+ block and that this action of nefiracetam was sensitive to PKC inhibition. It was concluded that nefiracetam potentiated NMDA currents not by acting as a partial agonist but by interacting with PKC, allosterically enhancing glycine binding, and attenuating voltage-dependent Mg2+ block.

Epidermal Growth Factor Induces Fibroblast Contractility and Motility via a Protein Kinase C δ-dependent Pathway

Myosin-based cell contractile force is considered to be a critical process in cell motility. However, for epidermal growth factor (EGF)-induced fibroblast migration, molecular links between EGF receptor (EGFR) activation and force generation have not been clarified. Herein, we demonstrate that EGF stimulation increases myosin light chain (MLC) phosphorylation, a marker for contractile force, concomitant with protein kinase C (PKC) activity in mouse fibroblasts expressing human EGFR constructs. Interestingly, PKCdelta is the most strongly phosphorylated isoform, and the preferential PKCdelta inhibitor rottlerin largely prevented EGF-induced phosphorylation of PKC substrates and MARCKS. The pathway through which EGFR activates PKCdelta is suggested by the fact that the MEK-1 inhibitor U0126 and the phosphatidylinositol 3-kinase inhibitor LY294002 had no effect on PKCdelta activation, whereas lack of PLCgamma signaling resulted in delayed PKCdelta activation. EGF-enhanced MLC phosphorylation was prevented by a specific MLC kinase inhibitor ML-7 and the PKC inhibitors chelerythrine chloride and rottlerin. Further indicating that PKCdelta is required, a dominant-negative PKCdelta construct or RNAi-mediated PKCdelta depletion also prevented MLC phosphorylation. In the absence of PLC signaling, MLC phosphorylation and cell force generation were delayed similarly to PKCdelta activation. All of the interventions that blocked PKCdelta activation or MLC phosphorylation abrogated EGF-induced cell contractile force generation and motility. Our results suggest that PKCdelta activation is responsible for a major part of EGF-induced fibroblast contractile force generation. Hence, we identify here a new pathway helping to govern cell motility, with PLC signaling playing a role in activation of PKCdelta to promote the acute phase of EGF-induced MLC activation.