Protein kinase C-epsilon is a developmentally regulated, neuronal isoform in the chick embryo central nervous system

The G Protein-Coupled Serotonin 1A Receptor Augments Protein Kinase Cε-Mediated Neurogenesis in Neonatal Mouse Hippocampus-PKCε-Mediated Signaling in the Early Hippocampus

The neurotransmitter serotonin (5-HT) plays an important role in mood disorders. It has been demonstrated that 5-HT signaling through 5-HT1A receptors (5-HT1A-R) is crucial for early postnatal hippocampal development and later-life behavior. Although this suggests that 5-HT1A-R signaling regulates early brain development, the mechanistic underpinnings of this process have remained unclear. Here we show that stimulation of the 5-HT1A-R at postnatal day 6 (P6) by intrahippocampal infusion of the agonist 8-OH-DPAT (D) causes signaling through protein kinase Cε (PKCε) and extracellular receptor activated kinase ½ (ERK1/2) to boost neuroblast proliferation in the dentate gyrus (DG), as displayed by an increase in bromodeoxy-uridine (BrdU), doublecortin (DCX) double-positive cells. This boost in neuroproliferation was eliminated in mice treated with D in the presence of a 5-HT1A-R antagonist (WAY100635), a selective PKCε inhibitor, or an ERK1/2-kinase (MEK) inhibitor (U0126). It is believed that hippocampal neuro-progenitors undergoing neonatal proliferation subsequently become postmitotic and enter the synaptogenesis phase. Double-staining with antibodies against bromodeoxyuridine (BrdU) and neuronal nuclear protein (NeuN) confirmed that 5-HT1A-R → PKCε → ERK1/2-mediated boosted neuroproliferation at P6 also leads to an increase in BrdU-labeled granular neurons at P36. This 5-HT1A-R-mediated increase in mature neurons was unlikely due to suppressed apoptosis, because terminal deoxynucleotidyl transferase dUTP nick-end labeling analysis showed no difference in DNA terminal labeling between vehicle and 8-OH-DPAT-infused mice. Therefore, 5-HT1A-R signaling through PKCε may play an important role in micro-neurogenesis in the DG at P6, following which many of these new-born neuroprogenitors develop into mature neurons.

PKCε-dependent H-Ras activation encompasses the recruitment of the RasGEF SOS1 and of the RasGAP neurofibromin in the lipid rafts of embryonic neurons

The spatial organization of plasma membrane proteins is a key factor in the generation of distinct signal outputs, especially for PKC/Ras/ERK signalling. Regulation of activation of the membrane-bound Ras, critical for neuronal differentiation and highly specialized functions, is controlled by exchanges in nucleotides catalyzed by nucleotide exchange factors (GEFs) for GTP loading and Ras activation, and by Ras GTPase Activated Proteins (RasGAPs) that lead to activation of the intrinsic GTPase activity of Ras and thus its inactivation. PKCs are potent Ras activators yet the mechanistic details of these interactions, or the involvement of specific PKC isoforms are now beginning to be addressed. Even less known is the topology where RasGAPs terminate Ras activation. Towards this aim, we isolated lipid rafts from chick embryo neural tissue and primary neuronal cultures when PKCε is the prominent isoform and in combination with in vitro kinase assays, we now show that, in response the PKCε-specific activating peptide ψεRACK, an activated PKCε is recruited to lipid rafts; similar mobility was established when PKCε was physiologically activated with the Cannabinoid receptor 1 (CB1) agonist methanandamide. Activation of H-Ras for both agents was then established for the first time using in vivo RasGAP activity assays, which showed similar temporal profiles of activation and lateral mobility. Moreover, we found that the GEF SOS1, and the major neuronal RasGAP neurofibromin, a specific PKCε substrate, were both transiently significantly enriched in the rafts. Finally, our in silico analysis revealed a highly probable, conserved palmitoylation site adjacent to a CARC motif on neurofibromin, both of which are included only in the RasGAP related domain type I (GRDI) with the known high H-RasGAP activity. Taken together, these results suggest that PKCε activation regulates the spatial plasma membrane enrichments of both SOS1 and neurofibromin, thus controlling the output of activated H-Ras available for downstream signalling in neurons.

Protein kinase C and chemical-induced abnormal palate development

The protein kinase C (PKC) family of proteins mediates the action of growth factors and other ligands by activating a network of transcription factors that bind to TRE sequences in the promoters of many genes that regulate cell proliferation, differentiation, extracellular matrix synthesis, apoptosis and others in a cell type-, isozymeand context-specific manner. The critical role of PKC in embryonic development is indicated by early death of embryos in which one or more of these isozymes are inactivated. Our studies together with others show that palatal PKC signalling is functional and may be essential for normal palate development. Although single gene knockouts have failed to exhibit the cleft palate (CP) phenotype, owing to compensation by other kinases, many chemicals including the mycotoxin, secalonic acid D, disrupt palatal PKC signalling leading to altered palatal mesenchymal gene expression. The potential relevance of such effects to chemical-induced CP is discussed.

PKC-epsilon activation is required for recognition memory in the rat

Activation of PKCɛ, an abundant and developmentally regulated PKC isoform in the brain, has been implicated in memory throughout life and across species. Yet, direct evidence for a mechanistic role for PKCɛ in memory is still lacking. Hence, we sought to evaluate this in rats, using short-term treatments with two PKCɛ-selective peptides, the inhibitory ɛV1-2 and the activating ψɛRACK, and the novel object recognition task (NORT). Our results show that the PKCɛ-selective activator ψɛRACK, did not have a significant effect on recognition memory. In the short time frames used, however, inhibition of PKCɛ activation with the peptide inhibitor ɛV1-2 significantly impaired recognition memory. Moreover, when we addressed at the molecular level the immediate proximal signalling events of PKCɛ activation in acutely dissected rat hippocampi, we found that ψɛRACK increased in a time-dependent manner phosphorylation of MARCKS and activation of Src, Raf, and finally ERK1/2, whereas ɛV1-2 inhibited all basal activity of this pathway. Taken together, these findings present the first direct evidence that PKCɛ activation is an essential molecular component of recognition memory and point toward the use of systemically administered PKCɛ-regulating peptides as memory study tools and putative therapeutic agents.

Plasticity of 5‐HT1Areceptor‐mediated signaling during early postnatal brain development

The presence of serotonin 1A receptor (5-HT(1A)-R) in the hippocampus, amygdala, and most regions of the frontal cortex is essential between postnatal day-5-21 (P5-21) for the expression of normal anxiety levels in adult mice. Thus, the 5-HT(1A)-R plays a crucial role in this time window of brain development. We show that the 5-HT(1A)-R-mediated stimulation of extracellular signal-regulated kinases 1 and 2 (Erk1/2) in the hippocampus undergoes a transition between P6 and P15. At P6, a protein kinase C (PKC) isozyme is required for the 5-HT(1A)-R -->Erk1/2 cascade, which causes increased cell division in the dentate gyrus. By contrast, at P15, PKC alpha participates downstream of Erk1/2 to augment synaptic transmission through the Schaffer Collateral pathway but does not cause increased cell division. Our data demonstrate that the 5-HT(1A)-R -->Erk1/2 cascade uses PKC isozymes differentially, first boosting the cell division to form new hippocampal neurons at P6 and then undergoing a plastic change in mechanism to strengthen synaptic connections in the hippocampus at P15.

Glutamate-dependent transcriptional regulation of GLAST: role of PKC

The Na+-dependent glutamate/aspartate transporter GLAST plays a major role in the removal of glutamate from the synaptic cleft. Short-term, as well as long-term changes in transporter activity are triggered by glutamate. An important locus of regulation is the density of transporter molecules present at the plasma membrane. A substrate-dependent change in the translocation rate of the transporter molecules accounts for the short-term effect, whereas the long-term modulation apparently involves transcriptional regulation. Using cultured chick cerebellar Bergmann glial cells, we report here that glutamate receptors activation mediate a substantial reduction in the transcriptional activity of the chglast promoter through the Ca2+/diacylglicerol-dependent protein kinase (PKC) signaling cascade. Overexpression of constitutive active PKC isoforms of mimic the glutamate effect. Accordingly, increased levels of c-Jun or c-Fos, but not Jun-B, Jun-D or Fos-B, lower the chglast promoter activity. Serial deletions and electrophorectic mobility shift assays were used to define a specific region within the 5' proximal region of the chglast promoter, associated with transcriptional repression. A putative glutamate response element could be defined in the proximal promoter stretch more likely between nts -40 and -78. These results demonstrate that GLAST is under glutamate-dependent transcriptional control through PKC, and support the notion of a pivotal role of this neurotransmitter in the regulation of its own removal from the synaptic cleft, thereby modulating, mainly in the long term, glutamatergic transmission.

Selective vulnerability of cerebellar granule neuroblasts and their progeny to drugs with abuse liability

Cerebellar development is shaped by the interplay of genetic and numerous environmental factors. Recent evidence suggests that cerebellar maturation is acutely sensitive to substances with abuse liability including alcohol, opioids, and nicotine. Assuming substance abuse disrupts cerebellar maturation, a central question is: what are the basic mechanisms underlying potential drug-induced developmental defects? Evidence reviewed herein suggests that the maturation of granule neurons and their progeny are intrinsically affected by several classes of substances with abuse liability. Although drug abuse is also likely to target directly other cerebellar neuron and glial types, such as Purkinje cells and Bergmann glia, findings in isolated granule neurons suggest that they are often the principle target for drug actions. Developmental events that are selectively disrupted by drug abuse in granule neurons and/or their neuroblast precursors include proliferation, migration, differentiation (including neurite elaboration and synapse formation), and programmed cell death. Moreover, different classes of drugs act through distinct molecular mechanisms thereby disrupting unique aspects of development. For example, drug-induced perturbations in: (i) neurotransmitter biogenesis; (ii) ligand and ion-gated receptor function and their coupling to intracellular effectors; (iii) neurotrophic factor biogenesis and signaling; and (iv) intercellular adhesion are all likely to have significant effects in shaping developmental outcome. In addition to identifying therapeutic strategies for drug abuse intervention, understanding the mechanisms by which drugs affect cellular maturation is likely to provide a better understanding of the neurochemical events that normally shape central nervous system development.

Differential localization of the neurofibromatosis 1 (NF1) gene product, neurofibromin, with the F-actin or microtubule cytoskeleton during differentiation of telencephalic neurons

The protein product of the neurofibromatosis 1 gene, neurofibromin, is abundantly expressed in the cerebral cortex during development, but its physiological role remains unknown. To gain insights into the functions of neurofibromin in neurons, we examined patterns of expression and subcellular localization of neurofibromin during neuronal differentiation. Western blot analysis of telencephali homogenates throughout chick embryogenesis revealed that neurofibromin expression increased during embryonic development. Further analysis showed that telencephalic neurons were also enriched in neurofibromin in culture and that a biphasic gain in expression correlated well with both phases of differentiation in culture, first with a massive outgrowth of processes and gains in neurotransmitter phenotype differentiation, and then with synapse formation. Compared to proteins associated with distinct cytoskeleton systems, the pattern of neurofibromin expression correlated closely with that of the cortical cytoskeleton protein paxillin. Moreover, analysis of immunofluorescence staining of neurofibromin showed that in the presence of a protein crosslinker which preserves both soluble and filamentous cytoskeleton proteins after extraction with Triton X-100, neurofibromin colocalized with F-actin only during the first differentiation phase. This colocalization persisted when the actin cytoskeleton was collapsed with cytochalasin D treatment. In contrast, during the second phase of differentiation neurofibromin colocalized with microtubules, but not F-actin, and the staining pattern was disrupted with nocodazole, but not cytochalasin. A constant finding under all conditions was the presence of neurofibromin in the nucleus, which supports the idea that the bipartite nuclear targeting sequence between residues 2555 and 2572 of neurofibromin may be functional. In summary, we have shown that telencephalic neurons and astroblasts are enriched in neurofibromin and that the subcellular targeting of neurofibromin toward the actin or the microtubule cytoskeleton is developmentally regulated.

Prolactin concurrently activates src-PLD and JAK/Stat signaling pathways to induce proliferation while promoting differentiation in embryonic astrocytes

In normal development, embryonic astrocytes progress through their cell lineage by acquiring differentiation, by apoptosis, and by proliferation. In this study, we show that embryonic astrocytes may maintain and make gains in differentiation as they simultaneously progress through one cell cycle when induced by prolactin (PRL). Prolactin induced the majority of astrocytes to incorporate bromodeoxyuridine (BrdU) with a four-fold increase over controls after 18 h of exposure. Investigating possible mitogenic signaling pathways we show for the first time that prolactin is coupled to a sustained phospholipase D (PLD) activation, with an efficacy similar to the phorbol ester and astrocytic mitogen 12-tetradecanoylphorbol-13-acetate (TPA). Both cyclosporine and suramin abolished this activation. Staurosporine and calphostin C also inhibited the PRL effect by 50%, consistent with involvement of protein kinase C-(PKC)-alpha, the major PKC isoform in astrocytes. Genistein and PP1 blocked the activation indicating additional regulation by cytosolic tyrosine kinases. This profile of PLD activation was suggestive of a PLD I isoform and a mitogenic response. Upon completion of the cell cycle, analysis of glia fibrillary acidic protein (GFAP) and vimentin abundance, and glutamine synthetase (GS) activity showed that astrocytes had gained in expression of differentiation markers. Moreover, the intensity of GFAP immunofluorescence was greater per cell, as was the length of the cell processes. In exploring the signaling for prolactin-induced differentiation we found that prolactin activated the tyrosine kinase Janus kinase (JAK) 2 and significantly stimulated tyrosine, phosphorylation of the prolactin receptor. Stat 1 and 3 were also activated presumably downstream to JAK2 activation. A rapid translocation of the cytosolic Stats over the nucleus was seen in nearly every astrocyte corresponding well with the gains in GFAP per cell. The Stats translocation did not depend on MEK-ERK inhibition by PD98059, inhibition of p38 by 1 microm SB203580, or Src kinase family inhibition by PP1. Our results demonstrate the ability of PRL to concurrently induce activation of PLD, a mitogenic signaling pathway in astrocytes, and prolonged stimulation of Stat1, compatible with the increased GFAP upregulation and cell differentiation. Considered together this data may provide an explanation on the fast gain in both numbers and differentiation in the astrocytic population during development (HD 09402, CRF).

Transient suppression of cortactin ectopically induces large telencephalic neurons towards a GABAergic phenotype

Excitatory and inhibitory neuronal cell fates require specific expression of both neurotransmitter and morphological phenotypes. The role of the F-actin cytoskeleton in morphological phenotypes has been well documented, but its role in neurotransmitter phenotype expression remains unknown. Here we present evidence that the F-actin binding protein cortactin participates in determining both aspects of cell fate in large telencephalic neurons. We show that the expression of cortactin was upregulated early in development just prior to appearance of GABAergic neurons in the chick telencephalon at embryonic day 6. This program was faithfully maintained in primary neuronal cultures derived from E6 telencephalon, where immature neurons differentiate either to large pyramidal and large stellate excitatory neurons or to small inhibitory GABAergic neurons. Immunostaining revealed that cortactin was enriched in areas of membrane budding, growth cones, and in the cell cortex of immature neurons. With differentiation, intense punctate staining was also observed in an extraction-resistant cytosolic compartment of the soma and processes. More importantly, suppression of cortactin by inhibition of cortactin mRNA translation with antisense oligonucleotides caused permanent phenotypic changes. Specifically, a transient suppression of cortactin was achieved in immature neurons with a single exposure to antisense oligonucleotides. This inhibition first induced both the expression of mRNA and the enzymatic activity of GAD significantly earlier than in control neurons. Second, cortactin-suppressed large projectional neurons exhibited significantly shorter processes and growth cones with protrusive filopodia and an enlarged lamellipodia veil. Most importantly, this remodeling of neuritic outgrowth in projectional somata was accompanied by the ectopic induction of GABA (*-aminobutyric acid) expression. Considering this data altogether, it appears that cortactin may function to suppress concurrently several parameters of the GABAergic program in large developing neurons.

Ethanol-induced decrease of developmental PKC isoform expression in the embryonic chick brain

Prenatal ethanol exposure can cause a number of physiological deficits known as fetal alcohol syndrome (FAS). Because protein kinase C (PKC) regulates the cell cycle and has been linked to growth, we examined the effect of ethanol on PKC isoform expression in a developing chick brain. Ethanol exposure causes decreased head weight in chickens at day 5 in a dose-dependent manner and a decreased brain weight at days 7 and 10 at an ethanol concentration of 1.0 g/kg. Antibodies specific for PKC-alpha, beta, gamma, delta, epsilon, iota, lambda, mu and zeta were used to examine ethanol's effect on PKC expression in the growth-suppressed brain at days 5, 7 and 10 of development. Only four of the PKC isoforms tested are expressed in the chick brain prior to day 10: alpha, gamma, epsilon, and iota. PKC-alpha, gamma, and epsilon are developmentally increased during the time period studied. Ethanol causes a decreased expression of PKC-alpha on days 5, 7 and 10 and a decreased expression of PKC-gamma on days 7 and 10. Ethanol causes a decreased expression of PKC-epsilon only on day 7. PKC-iota expression is unchanged over the developmental times studied and ethanol exposure has no effect on PKC-iota expression. These data suggest that only specific PKC isoforms are developmentally expressed in the embryonic chick brain and that ethanol may inhibit the expression of those PKC isoforms that are developmentally regulated.

The secretion of soluble amyloid beta precursor protein (A beta PPs) by chick neurons in serum-free primary culture is not regulated by protein kinase C

The metabolism of amyloid precursor protein (A beta PP) in chick neurons cultured in serum-free medium is described. A beta PP immunoreactivity, detected with the 22C11 antibody, was seen at approximately 135 and approximately 120 kDa. A beta PPs (approximately 120 kDa) was released from the cells and could be detected in the culture medium without the need of a purification step. The content of A beta PPs increased with time after medium change, but was not affected by either carbachol (100 microM), glutamate (50 microM), veratrine (20 microM), oleic acid (200 microM), A23187 (5 microM), phorbol 12, 13-dibutyrate (PDBu, 1 microM), staurosporine (1 microM), Gö 6976 (1 microM) or okadaic acid (50 nM) although the combination of PDBu and okadaic acid reduced the secretion. Addition of the muscarinic receptor agonist carbachol to the neurons increased the rate of phosphoinositide breakdown. In Western blot experiments using antibodies to the alpha, beta II and epsilon isoforms of protein kinase C and conditions whereby robust signals could be seen with rat brain lysates, no immunoreactive bands that could be inhibited by appropriate positive control peptides were seen. It is concluded A beta PPs production by chick neurons in culture is mainly constitutive in nature.

mu-Opioids activate tyrosine kinase focal adhesion kinase and regulate cortical cytoskeleton proteins cortactin and vinculin in chick embryonic neurons

We have investigated the signal transduction pathway of the G-protein mu-opioid receptor upstream of phospholipase D (PLD) and protein kinase C-epsilon (PKC-epsilon) activation in postmitotic E6CH chick embryo cortical neurons. The mu-opioid receptor and PLD-PKC-epsilon functional coupling depends on upstream tyrosine kinase activation. We now report that the mu-opioid agonists specifically stimulated tyrosine phosphorylation and activation of the focal adhesion kinase (FAK) in a time-dependent manner. We also demonstrate that met-enkephalin, a mu-opioid agonist in E6CH cultures, significantly increases tyrosine phosphorylation of another Src kinase substrate, the cytoskeletal protein cortactin. Tyrosine phosphorylation of cortactin led to drastic changes in subcellular localization, an estimated 2-fold enrichment in the cytosol. Similarly, opioids stimulated a sustained tyrosine phosphorylation of vinculin, a protein enriched in focal adhesion sites. These data provide novel evidence that opioid receptor intracellular signaling engages the specific activation of tyrosine kinase FAK and regulates the neuronal cytoskeleton during central nervous system morphogenesis.

Selective activation by bryostatin-1 demonstrates unique roles for PKC epsilon in neurite extension and tau phosphorylation

Phorbol esters such as 12-O-tetradeonyl phorbol-13 acetate (TPA) induce a time-dependent biphasic effect on protein kinase C (PKC)-mediated events by fostering translocation of cytosolic (latent) PKC to the plasma membrane (where it is activated). Continued treatment, however, depletes the cell's entire PKC complement and induces a functional stake of PKC inhibition. Previous studies from several laboratories have demonstrated that long-term TPA treatment, like treatment with PKC inhibitors, induces neuronal differentiation. Bryostatin-1 also induces translocation and overall downregulation of PKC following long-term treatment, yet, unlike TPA or PKC inhibitors, does not induce neuronal differentiation, promoting controversy regarding the role of PKC inhibition in neuronal differentiation. We demonstrate herein that, despite overall downregulation in human neuroblastoma cells, membrane-associated levels of one PKC isoform (PKC epsilon) are actually increased following long-term bryostatin-1 treatment. Since previous studies have implicated this PKC isoform in phosphorylation of the microtubule-associated protein tau and in neuritogenesis, we examined the consequences of long-term bryostatin treatment on these phenomena. Treatment with 25 n-100 M bryostatin-1 for 72 h increased tau phosphorylation and inhibited neuritogenesis. By contrast, treatment with either TPA or the PKC inhibitor staurosporine did not induce tau phosphorylation and induced neurite elaboration. Bryostatin-1 antagonized neurite induction by staurosporine. These findings provide additional evidence for a unique role of PKC epsilon in the regulation of tau phosphorylation and neuronal differentiation, and demonstrate that bryostatin-1 can function under certain conditions as a selective PKC epsilon activator even following long-term treatment.

An inhibitory fragment derived from protein kinase Cepsilon prevents enhancement of nerve growth factor responses by ethanol and phorbol esters

We have studied nerve growth factor (NGF)-induced differentiation of PC12 cells to identify PKC isozymes important for neuronal differentiation. Previous work showed that tumor-promoting phorbol esters and ethanol enhance NGF-induced mitogen-activated protein (MAP) kinase activation and neurite outgrowth by a PKC-dependent mechanism. Ethanol also increases expression of PKCdelta and PKCepsilon, suggesting that one these isozymes regulates responses to NGF. To examine this possibility, we established PC12 cell lines that express a fragment encoding the first variable domain of PKCepsilon (amino acids 2-144), which acts as an isozyme-specific inhibitor of PKCepsilon in cardiac myocytes. Phorbol ester-stimulated translocation of PKCepsilon was markedly reduced in these PC12 cell lines. In addition, phorbol ester and ethanol did not enhance NGF-induced MAP kinase activation or neurite outgrowth in these cells. In contrast, phorbol ester and ethanol increased neurite outgrowth and MAP kinase phosphorylation in cells expressing a fragment derived from the first variable domain of PKCdelta. These results demonstrate that PKCepsilon mediates enhancement of NGF-induced signaling and neurite outgrowth by phorbol esters and ethanol in PC12 cells.

Phosphorylation events mediated by protein kinase C alpha and epsilon participate in regulation of tau steady-state levels and generation of certain "Alzheimer-like" phospho-epitopes

Hyperactivation of protein kinase C (PKC) in intact neuroblastoma cells by several methods increases site-specific tau phosphorylation as shown by increases in paired helical filament-I (PHF-I) and ALZ-50 but not AT-8 immunoreactivity. In the present study, the influence of PKC on tau metabolism was further examined by isoform-specific antisense oligonucleotide-mediated PKC downregulation in human SH-SY-5Y neuroblastoma cells and by generation of stably-transfected subclones expressing isoform-specific anti-PKC mRNA sequences. Downregulation of PKC epsilon by both of these methods reduced PHF-I and ALZ-50 immunoreactivity, suggesting that this PKC isoform, perhaps via downstream kinase cascades, regulated tau phosphorylation events that normally generate these epitopes. By contrast, downregulation of either PKC epsilon or PKC alpha reduced immunoreactivity towards the phosphate-independent anti-tau antibodies 5E2 and JM, suggesting that both of these isoforms participated in regulation of tau steady-state levels. Downregulation of PKC beta did not affect any of the above changes. The above roles were apparently unique for PKC epsilon and PKC alpha, since activation of multiple PKC isoforms by phorbol ester treatment and/or other calcium-dependent kinase(s) by ionophore-mediated calcium influx could not compensate for downregulation of PKC alpha or PKC epsilon in maintaining tau steady-state levels or PHF-I/ALZ-50 immunoreactivity, respectively. These findings suggest that hyperactivation of signal transduction pathways, including those regulated by PKC, could evoke changes in neuronal cells reminiscent of those seen in affected neurons in Alzheimer's disease.

Protein kinase C and mouse sciatic nerve regeneration

We have studied the role of protein kinase C (PKC) in peripheral nerve regeneration by using the cultured adult mouse sciatic nerve, which displays regrowth of sensory axons under serum-free conditions. By the use of immunohistochemistry we show that one of the isoforms of PKC, PKC beta, is present in the nerve cell bodies of normal nerves and is upregulated after injury. In spite of this, the specific PKC inhibitor chelerythrine at 5 microM, a concentration well above its IC50 value for PKC, failed to reduce the outgrowth distance of new axons. This was not due to impermeability of the drug, since the same concentration caused a clear reduction of the injury-induced proliferation of Schwann cells in the crush region. Likewise, HA-1004, an inhibitor of cyclic nucleotide-dependent protein kinases, also lacked effect on outgrowth when used on its own, even at very high concentrations (100 microM). In contrast, outgrowth was significantly reduced when 5 microM chelerythrine and 5 microM HA-1004 were used in combination. In conclusion, the present results suggest that PKC-activity is important but not indispensable for the regeneration process. Successful completion of the latter could be achieved by several, perhaps redundant, phosphorylation systems.

Overexpression of epsilon-protein kinase C enhances nerve growth factor-induced phosphorylation of mitogen-activated protein kinases and neurite outgrowth

Protein kinase C (PKC) activation enhances neurite outgrowth in several cell lines and primary neurons. The PKC isozymes that mediate this response are unknown. One clue to their identity has come from studies using PC12 cells treated with ethanol. In these cells, ethanol increases levels of delta-PKC and epsilon-PKC and markedly enhances nerve growth factor (NGF)-induced neurite outgrowth and activation of mitogen-activated protein (MAP) kinases by a PKC-dependent mechanism. Since these findings suggest that delta-PKC or epsilon-PKC can promote neural differentiation, we studied neurite outgrowth in stably transfected PC12 cell lines that overexpress these isozymes. Overexpression of epsilon-PKC markedly increased NGF-induced neurite outgrowth. This effect was blocked by down-regulating PKC or by treating cells with the PKC inhibitor GF 109203X. In addition, overexpression of epsilon-PKC enhanced NGF-induced phosphorylation of MAP kinases. In contrast, overexpression of delta-PKC did not alter responses to NGF. These results demonstrate that epsilon-PKC promotes NGF-induced neurite outgrowth by enhancing NGF signal transduction. These findings suggest a role for epsilon-PKC in neural differentiation and plasticity.

Phorbol esters and PKC signaling regulate proliferation, vimentin cytoskeleton assembly and glutamine synthetase activity of chick embryo cerebrum astrocytes in culture

We have recently shown that expression of specific protein kinase C (PKC) isoforms correlates with cell fate in neural chicken embryo cells. Therefore we investigated the effects of PKC activation by phorbol esters on acquisition of the astrocytic phenotype, using cultured embryonic cortical astrocytes, derived from 15-day-old chick embryos (E15CH), as a model. Short term treatment with the phorbol ester 12-tetradecanoylphorbol-13-acetate (TPA), which activates PKC-alpha/beta in E15CH, caused association of PKC with the cytoskeleton. In vitro kinase assays of cytoskeleton-associated PKC demonstrated phosphorylation of many cytoskeletal proteins. Phosphorylation was blocked by protein kinase inhibitors (H8), and enhanced by phosphatase inhibitors (calyculin A). Among these PKC substrates, a most prominent 60-kDa protein was identified as vimentin. Assembly of vimentin into the cytoskeleton depends on cell type and state of differentiation. To establish that TPA (PKC) regulates assembly of vimentin into the cytoskeleton of astrocytes, we used pulse-chase (20/5 min) labeling with [35S]methionine, and immunoprecipitations with an anti-vimentin mAb from extractable and cytoskeletal fractions. These studies revealed that 20 min treatment with TPA leads to a 3-fold increase in the rate of newly synthesized full-length vimentin assembly (posttranslational assembly). Furthermore, TPA increased cotranslational assembly of vimentin. The protein kinase A activator forskolin, did not have such effects on vimentin assembly. Long-term TPA treatment, which correlates with a prolonged phospholipase D (PLD) activation, was mitogenic and caused dramatic changes in the morphology of astrocytes. In addition these fibrous, polarized astrocytes had decreased activity of the astrocyte specific enzyme, glutamine synthetase, but had increased abundance of vimentin protein. These studies provide biochemical evidence on acquisition of a different astrocytic phenotype after activation of the PKC/PLD pathway, in the chick embryo. Therefore PKC and PLD activation is pivotal for the acquisition and maintenance of phenotypes in chick embryonic astrocytes.

Differential regulation of phospholipases C and D by phorbol esters and the physiological activators carbachol and glutamate in astrocytes from chicken embryo cerebrum and cerebellum

Primary astrocytic cultures derived from day-15 chick embryo (E15) cerebral hemispheres (CH) or cerebellum (CB) express a calcium/phospholipid-dependent isoform as the major protein kinase C (PKC-alpha/beta). PKC was activated (translocation of activity from cytosol to membrane) following stimulation with carbachol, so we tested for activation of phospholipase C (PLC) as the source of diacylglycerol released from polyphosphoinositide (PIP2) hydrolysis. Carbachol activated PLC (inositol phosphate release) 4-fold in a time- and dose-dependent manner in cortical (CH) astrocytes, but there was no activation of PLC in astrocytes from cerebellum (CB). Pirenzepine, but not gallamine, attenuated both carbachol-induced PKC translocation and PIP2 hydrolysis in E15CH astrocytes, arguing for contribution of M1 subtype. The phorbol ester TPA completely inhibited PIP2 hydrolysis, both basal and carbachol-stimulated, and elicited a stronger, but shorter (10 min) activation of PKC than that observed with carbachol. We investigated phospholipase D (PLD) activation as an alternate source of diacylglycerol in astrocytes, since the ratio of PLC to PKC activation by carbachol was lower in astrocytes than observed in neurons. We observed a dramatic (10-fold) time- and dose-dependent activation of PLD by TPA in CH and a 3-fold increase in CB. The duration of TPA-dependent PLD activation correlated well with increased cell proliferation and changes in astrocytic phenotype markers. Carbachol-stimulated PLD activation was observed in CH but not in CB astrocytes, being mostly dependent on the M3 receptor subtype in the former. In contrast, glutamate elicited a greater PLD activation in CB astrocytes, than in CH astrocytes. TPA activation of PLD was totally blocked by staurosporine (PKC inhibitor) and genistein (a tyrosine kinase inhibitor) in cerebellar (CB) astrocytes; however, total inhibition of TPA-dependent PLD activation was only achieved in cortical (CH) astrocytes after addition of EGTA. Thapsigargin activated PLD in both populations, further emphasizing the PLD activation dependency on [Ca2+]i. Taken together with our previous observations that TPA induces proliferation, cytoskeleton changes, and decreases of glutamine synthetase activity, these data suggest that phospholipase D is a differential but important participant in the regulation of the signalling of mitosis and differentiation in astrocytes during their development.

Atypical zeta-protein kinase c displays a unique developmental expression pattern in rat brain

The expression of atypical zeta-protein kinase C (PKC) was examined during prenatal and postnatal rat brain development. Immunoblot as well as transcript analysis revealed a dramatic increase in expression at 2-3 days post-birth, which declined thereafter and remained at levels observed in the adult brain. The expression of zeta-PKC precedes that of the other PKC isoforms in developing rat brain. Subcellular fractionation of pup and adult brain documented distribution between all three distinct fractions (A,B,C), including the low speed pellet composed of nuclei. In adult brain, the kinase was enriched in the A fraction of the sucrose gradient. Specific substrate proteins of zeta-PKC were characterized in each of the subcellular fractions from both pup and adult brain. Four predominant proteins pp76, pp60-doublet, pp54 and pp45 were identified as zeta-PKC endogenous substrates. All four proteins were phosphorylated on serine residues, while the pp60-doublet was also phosphorylated on tyrosine. The pp60-doublet was the most predominant substrate, specifically enriched in the A fraction of a sucrose gradient of adult brain and immunoprecipitated by monoclonal antibody to pp60c-src.

Degradation of protein kinase C alpha and its free catalytic subunit, protein kinase M, in intact human neuroblastoma cells and under cell-free conditions. Evidence that PKM is degraded by mM calpain-mediated proteolysis at a faster rate than PKC

Proteolytic cleavage of protein kinase C (PKC) under cell-free conditions generates a co-factor independent, free catalytic subunit (PKM). However, the difficulty in visualizing PKM in intact cells has generated controversy regarding its physiological relevance. In the present study, treatment of SH-SY-5Y cells with 2-O-tetradecanoylphorbol 13-acetate resulted in complete down-regulation of PKC within 24 h without detection of PKM. By contrast, low levels of PKM were transiently detected following ionophore-mediated calcium influx under conditions which induced no detectable PKC loss. PKM was not detected during rapid cell-free degradation of partially purified SH-SY-5Y PKC alpha by purified human brain mM calpain. However, when the kinetics of PKC degradation were slowed by lowering levels of calpain, PKM was transiently detected. PKM was also only transiently observed following calpain-mediated degradation of purified rat brain PKC alpha. Densitometric analyses indicated that, once formed, PKM was degraded approximately 10 times faster than PKC. These data provide an explanation as to why PKM is difficult to observe in situ, and indicate that PKM should not be considered as an 'unregulated' kinase, since its persistence is apparently strictly regulated by proteolysis.