Interplay between calcium, diacylglycerol, and phosphorylation in the spatial and temporal regulation of PKCalpha-GFP

Crosstalk between diacylglycerol kinase and protein kinase A in the regulation of airway smooth muscle cell proliferation

BACKGROUND

Diacylglycerol kinase (DGK) regulates intracellular signaling and functions by converting diacylglycerol (DAG) into phosphatidic acid. We previously demonstrated that DGK inhibition attenuates airway smooth muscle (ASM) cell proliferation, however, the mechanisms mediating this effect are not well established. Given the capacity of protein kinase A (PKA) to effect inhibition of ASM cells growth in response to mitogens, we employed multiple molecular and pharmacological approaches to examine the putative role of PKA in the inhibition of mitogen-induced ASM cell proliferation by the small molecular DGK inhibitor I (DGK I).

METHODS

We assayed cell proliferation using CyQUANT™ NF assay, protein expression and phosphorylation using immunoblotting, and prostaglandin E2 (PGE2) secretion by ELISA. ASM cells stably expressing GFP or PKI-GFP (PKA inhibitory peptide-GFP chimera) were stimulated with platelet-derived growth factor (PDGF), or PDGF + DGK I, and cell proliferation was assessed.

RESULTS

DGK inhibition reduced ASM cell proliferation in cells expressing GFP, but not in cells expressing PKI-GFP. DGK inhibition increased cyclooxygenase II (COXII) expression and PGE2 secretion over time to promote PKA activation as demonstrated by increased phosphorylation of (PKA substrates) VASP and CREB. COXII expression and PKA activation were significantly decreased in cells pre-treated with pan-PKC (Bis I), MEK (U0126), or ERK2 (Vx11e) inhibitors suggesting a role for PKC and ERK in the COXII-PGE2-mediated activation of PKA signaling by DGK inhibition.

CONCLUSIONS

Our study provides insight into the molecular pathway (DAG-PKC/ERK-COXII-PGE2-PKA) regulated by DGK in ASM cells and identifies DGK as a potential therapeutic target for mitigating ASM cell proliferation that contributes to airway remodeling in asthma.

Unloading of intercellular tension induces the directional translocation of PKCα

The migration of endothelial cells (ECs) is closely associated with a Ca²⁺ -dependent protein, protein kinase Cα (PKCα). The disruption of intercellular adhesion by single-cell wounding has been shown to induce the directional translocation of PKCα. We hypothesized that this translocation of PKCα is induced by mechanical stress, such as unloading of intercellular tension, or by intercellular communication, such as gap junction-mediated and paracrine signaling. In the current study, we found that the disruption of intercellular adhesion induced the directional translocation of PKCα even when gap junction-mediated and paracrine signaling were inhibited. Conversely, it did not occur when the mechanosensitive channel was inhibited. In addition, the strain field of substrate attributable to the disruption of intercellular adhesion tended to be larger at the areas corresponding with PKCα translocation. Recently, we found that a direct mechanical stimulus induced the accumulation of PKCα at the stimulus area, involving Ca ²⁺ influx from extracellular space. These results indicated that the unloading of intercellular tension induced directional translocation of PKCα, which required Ca ²⁺ influx from extracellular space. The results of this study indicate the involvement of PKCα in the Ca ²⁺ signaling pathway in response to mechanical stress in ECs.

Mesenchymal chemotaxis requires selective inactivation of myosin II at the leading edge via a noncanonical PLCγ/PKCα pathway

Chemotaxis, migration toward soluble chemical cues, is critical for processes such as wound healing and immune surveillance and is exhibited by various cell types, from rapidly migrating leukocytes to slow-moving mesenchymal cells. To study mesenchymal chemotaxis, we observed cell migration in microfluidic chambers that generate stable gradients of platelet-derived growth factor (PDGF). Surprisingly, we found that pathways implicated in amoeboid chemotaxis, such as PI3K and mammalian target of rapamycin signaling, are dispensable for PDGF chemotaxis. Instead, we find that local inactivation of Myosin IIA, through a noncanonical Ser1/2 phosphorylation of the regulatory light chain, is essential. This site is phosphorylated by PKCα, which is activated by an intracellular gradient of diacylglycerol generated by PLCγ. Using a combination of live imaging and gradients of activators/inhibitors in the microfluidic chambers, we demonstrate that this signaling pathway and subsequent inhibition of Myosin II activity at the leading edge are required for mesenchymal chemotaxis.

Modulation of Ca(2+) release through ryanodine receptors in vascular smooth muscle by protein kinase Calpha

The role of protein kinase C (PKC) in Ca(2+) release through ryanodine receptors (RyRs) in the sarcoplasmic reticulum (SR) of vascular smooth muscle cells (SMCs) is not well understood. Caffeine was used to activate RyRs and the intracellular Ca(2+) concentration ([Ca(2+)](i)) was measured in both freshly isolated and cultured mouse aortic SMCs (ASMCs). Pre-activation of PKC with 1,2-dioctanoyl-sn-glycerol (DOG) prevented caffeine-induced [Ca(2+)](i) transients. Application of the PKC inhibitor calphostin C caused [Ca(2+)](i) transients which were not blocked by nifedipine or by removing extracellular Ca(2+) but were abolished after inhibition of the SR Ca(2+)-ATPase with thapsigargin or after inhibition of RyRs with ryanodine. In addition, chelerythrine and GF109203X also elevated resting [Ca(2+)](i) but no further [Ca(2+)](i) increase was seen with subsequent application of caffeine. Selective inhibition of PKCalpha with safingol blocked caffeine-induced [Ca(2+)](i) transients, but the PKCepsilon inhibitory peptide V1-2 did not. In cells expressing a EGFP-tagged PKCalpha, caffeine-induced [Ca(2+)](i) transients were associated with a rapid focal translocation near the cell periphery, while application of ionomycin and DOG caused translocation to the plasma membrane. Western blot showed that caffeine increased the relative amount of PKCalpha in the particulate fraction in a time-dependent manner. Co-immunoprecipitation of RyRs and PKCalpha indicated that they interact. In conclusion, our studies suggest that PKC activation can inhibit the gating activity of RyRs in the SR of ASMCs, and this regulation is most likely mediated by the Ca(2+)-dependent PKCalpha isoform.

Acadesine kills chronic myelogenous leukemia (CML) cells through PKC-dependent induction of autophagic cell death

CML is an hematopoietic stem cell disease characterized by the t(9;22) (q34;q11) translocation encoding the oncoprotein p210BCR-ABL. The effect of acadesine (AICAR, 5-Aminoimidazole-4-carboxamide-1-β-D-ribofuranoside) a compound with known antileukemic effect on B cell chronic lymphoblastic leukemia (B-CLL) was investigated in different CML cell lines. Acadesine triggered loss of cell metabolism in K562, LAMA-84 and JURL-MK1 and was also effective in killing imatinib-resistant K562 cells and Ba/F3 cells carrying the T315I-BCR-ABL mutation. The anti-leukemic effect of acadesine did not involve apoptosis but required rather induction of autophagic cell death. AMPK knock-down by Sh-RNA failed to prevent the effect of acadesine, indicating an AMPK-independent mechanism. The effect of acadesine was abrogated by GF109203X and Ro-32-0432, both inhibitor of classical and new PKCs and accordingly, acadesine triggered relocation and activation of several PKC isoforms in K562 cells. In addition, this compound exhibited a potent anti-leukemic effect in clonogenic assays of CML cells in methyl cellulose and in a xenograft model of K562 cells in nude mice. In conclusion, our work identifies an original and unexpected mechanism by which acadesine triggers autophagic cell death through PKC activation. Therefore, in addition to its promising effects in B-CLL, acadesine might also be beneficial for Imatinib-resistant CML patients.

Use of Fluorescence Resonance Energy Transfer-based Biosensors for the Quantitative Analysis of Inositol 1,4,5-Trisphosphate Dynamics in Calcium Oscillations

Inositol 1,4,5-trisphosphate (IP(3)) is an intracellular messenger that elicits a wide range of spatial and temporal Ca(2+) signals, and this signaling versatility is exploited to regulate diverse cellular responses. In this study, we have developed a series of IP(3) biosensors that exhibit strong pH stability and varying affinities for IP(3), as well as a method for the quantitative measurement of cytosolic concentrations of IP(3) ([IP(3)](i)) in single living cells. We applied this method to elucidate IP(3) dynamics during agonist-induced Ca(2+) oscillations, and we demonstrated cell type-dependent differences in IP(3) dynamics, a nonfluctuating rise in [IP(3)](i) and repetitive IP(3) spikes during Ca(2+) oscillations in COS-7 cells and HSY-EA1 cells, respectively. The size of the IP(3) spikes in HSY-EA1 cells varied from 10 to 100 nm, and the [IP(3)](i) spike peak was preceded by a Ca(2+) spike peak. These results suggest that repetitive IP(3) spikes in HSY-EA1 cells are passive reflections of Ca(2+) oscillations, and are unlikely to be essential for driving Ca(2+) oscillations. In addition, the interspike periods of Ca(2+) oscillations that occurred during the slow rise in [IP(3)](i) were not shortened by the rise in [IP(3)](i), indicating that IP(3)-dependent and -independent mechanisms may regulate the frequency of Ca(2+) oscillations. The novel method described herein as well as the quantitative information obtained by using this method should provide a valuable and sound basis for future studies on the spatial and temporal regulations of IP(3) and Ca(2+).

Visualizing the temporal effects of vasoconstrictors on PKC translocation and Ca2+ signaling in single resistance arterial smooth muscle cells

Arterial smooth muscle (ASM) contraction plays a critical role in regulating blood distribution and blood pressure. Vasoconstrictors activate cell surface receptors to initiate signaling cascades involving increased intracellular Ca(2+) concentration ([Ca(2+)](i)) and recruitment of protein kinase C (PKC), leading to ASM contraction, though the PKC isoenzymes involved vary between different vasoconstrictors and their actions. Here, we have used confocal microscopy of enhanced green fluorescence protein (eGFP)-labeled PKC isoenzymes to visualize PKC translocation in primary rat mesenteric ASM cells in response to physiological vasoconstrictors, with simultaneous imaging of Ca(2+) signaling. Endothelin-1, angiotensin II, and uridine triphosphate all caused translocation of each of the PKC isoenzymes alpha, delta, and epsilon; however, the kinetics of translocation varied between agonists and PKC isoenzymes. Translocation of eGFP-PKCalpha mirrored the rise in [Ca(2+)](i), while that of eGFP-PKCdelta or -epsilon occurred more slowly. Endothelin-induced translocation of eGFP-PKCepsilon was often sustained for several minutes, while responses to angiotensin II were always transient. In addition, preventing [Ca(2+)](i) increases using 1,2-bis-(o-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid tetra-(acetoxymethyl) ester prevented eGFP-PKCalpha translocation, while eGFP-PKCdelta translocated more rapidly. Our results suggest that PKC isoenzyme specificity of vasoconstrictor actions occurs downstream of PKC recruitment and demonstrate the varied kinetics and complex interplay between Ca(2+) and PKC responses to different vasoconstrictors in ASM.

Identification of acidic amino acid residues in the protein kinase C alpha V5 domain that contribute to its insensitivity to diacylglycerol

The protein kinase C (PKC) isoforms are maintained in an inactive and closed conformation by intramolecular interactions. Upon activation these are disrupted by activators, binding proteins and cellular membrane. We have seen that autophosphorylation of two sites in the C-terminal V5 domain is crucial to keep PKC alpha insensitive to the activator diacylglycerol, which presumably is caused by a masking of the diacylglycerol-binding C1a domain. Here we demonstrate that the diacylglycerol sensitivity of the PKC beta isoforms also is suppressed by autophosphorylation of the V5 sites. To analyze conformational differences, a fusion protein ECFP-PKC alpha-EYFP was expressed in cells and the FRET signal was analyzed. The analogous mutant with autophosphorylation sites exchanged for alanine gave rise to a substantially lower FRET signal than wild-type PKC alpha indicating a conformational difference elicited by the mutations. Expression of the isolated PKC alpha V5 domain led to increased diacylglycerol sensitivity of PKC alpha. We identified acidic residues in the V5 domain that, when mutated to alanines or lysines, rendered PKC alpha sensitive to diacylglycerol. Furthermore, mutation to glutamate of four lysines in a lysine-rich cluster in the C2 domain gave a similar effect. Simultaneous reversal of the charges of the acidic residues in the V5 and the lysines in the C2 domain gave rise to a PKC alpha that was insensitive to diacylglycerol. We propose that these structures participate in an intramolecular interaction that maintains PKC alpha in a closed conformation. The disruption of this interaction leads to an unmasking of the C1a domain and thereby increased diacylglycerol sensitivity of PKC alpha.

Mechanism of membrane redistribution of protein kinase C by its ATP-competitive inhibitors

ATP-competitive inhibitors of PKC (protein kinase C) such as the bisindolylmaleimide GF 109203X, which interact with the ATP-binding site in the PKC molecule, have also been shown to affect several redistribution events of PKC. However, the reason why these inhibitors affect the redistribution is still controversial. In the present study, using immunoblot analysis and GFP (green fluorescent protein)-tagged PKC, we showed that, at commonly used concentrations, these ATP-competitive inhibitors alone induced redistribution of DAG (diacylglycerol)-sensitive PKCalpha, PKCbetaII, PKCdelta and PKCepsilon, but not atypical PKCzeta, to the endomembrane or the plasma membrane. Studies with deletion and point mutants showed that the DAG-sensitive C1 domain of PKC was required for membrane redistribution by these inhibitors. Furthermore, membrane redistribution was prevented by the aminosteroid PLC (phospholipase C) inhibitor U-73122, although an ATP-competitive inhibitor had no significant effect on acute DAG generation. Immunoblot analysis showed that an ATP-competitive inhibitor enhanced cell-permeable DAG analogue- or phorbol-ester-induced translocation of endogenous PKC. Furthermore, these inhibitors also enhanced [3H]phorbol 12,13-dibutyrate binding to the cytosolic fractions from PKCalpha-GFP-overexpressing cells. These results clearly demonstrate that ATP-competitive inhibitors cause redistribution of DAG-sensitive PKCs to membranes containing endogenous DAG by altering the DAG sensitivity of PKC and support the idea that the inhibitors destabilize the closed conformation of PKC and make the C1 domain accessible to DAG. Most importantly, our findings provide novel insights for the interpretation of studies using ATP-competitive inhibitors, and, especially, suggest caution about the interpretation of the relationship between the redistribution and kinase activity of PKC.

Protein kinase C alpha and epsilon differentially modulate hepatocyte growth factor-induced epithelial proliferation and migration

Protein kinase C (PKC) isoenzymes require membrane translocation for physiological activation. We have recently shown that the growth factors such as epidermal growth factor and hepatocyte growth factor (HGF), but not keratinocyte growth factor (KGF), regulate PKCalpha activation to promote epithelial wound healing [Sharma, G.D., Ottino, P., Bazan, H.E.P., 2005. Epidermal and hepatocyte growth factors, but not keratinocyte growth factor, modulate protein kinase C alpha translocation to the plasma membrane through 15(S)-hydroxyeicosatetraenoic acid synthesis. J. Biol. Chem. 280, 7917--924]. Protein kinase C alpha (PKCalpha) and protein kinase C epsilon (PKCvarepsilon) are two differentially regulated isoenzymes. While PKCalpha requires Ca(2+) for its activation, PKEvarepsilon is Ca(2+) independent. However, growth factor-induced activation of these enzymes and their specific regulation of epithelial migration and proliferation have not been explored. In the present study, we overexpressed PKCvarepsilon fused to green fluorescent protein to examine its translocation in real-time to the plasma membrane in living human corneal epithelial cells. Stimulation with HGF and KGF demonstrated translocation of PKCvarepsilon to the plasma membrane. Because HGF activates both PKCs, this growth factor was used to stimulate wound healing. PKCalpha or PKCvarepsilon-genes were knocked down individually without affecting the basal expression of the other PKC isoforms. Gene knockdown of PKCalpha significantly inhibited HGF-stimulated proliferation of human corneal epithelial cells. In contrast, PKCvarepsilon-gene-silencing severely impaired the HGF-stimulated migratory ability of human corneal epithelial cells. When migrating epithelial cells in the cornea wound bed after injury were transfected with specific PKCalpha- or PKCvarepsilon-siRNA, there was a significant delay in wound healing. Corneal wound healing stimulated with HGF in similar conditions was also inhibited. On the other hand, overexpression of PKCalpha or PKCvarepsilon-genes fused with green fluorescent protein in migrating corneal epithelium accelerated repair of the epithelial defect. Our findings demonstrate that PKCalpha and PKCvarepsilon modulate different stages of wound healing stimulated by HGF and contribute to epithelial repair by playing selective regulatory roles in epithelial proliferation and migration, both crucial to corneal wound healing.

Persistent activation of protein kinase Calpha is not necessary for expression of cerebellar long-term depression

Protein kinase Calpha (PKCalpha) plays a major role in the induction of long-term depression (LTD) in a cerebellar Purkinje cell (PC). The sequential activation model for classical PKC states that PKCalpha translocates to the plasma membrane by binding Ca(++) and then becomes fully activated by binding diacylglycerol (DAG), which enables estimation of the activity by monitoring its localization. Here, we performed simultaneous electrophysiological recording and fluorescence imaging in a cultured PC expressing GFP-tagged PKCalpha. When a PC was depolarized, PKCalpha transiently translocated to the plasma membrane in a Ca(++)-dependent manner. Application of membrane permeable DAG or the blocker of DAG lipase prolonged the translocation. These results suggest that the sequential activation model is applicable to PCs. Conjunctive applications of glutamate and depolarization pulse induced LTD, but did not prolong the translocation. Thus, our results imply that persistent activation of PKCalpha is not necessary for the expression of LTD.

Vasopressin-induced translocation and proteolysis of protein kinase Cα in an amphibian brain: Modulation by corticosterone

In urodele amphibians, the hypothalamic neuropeptide arginine vasotocin and the adrenal steroid corticosterone interact to regulate reproductive behavior by actions in the brain. The present study investigated signal transduction pathways underlying acute effects of vasotocin and corticosterone, presumably mediated via "non-genomic" steroid action, in an amphibian brain. We used Western blot to examine the effects of corticosterone and the vasotocin receptor agonist arginine vasopressin, alone and in combination, on the subcellular localization and proteolytic processing of protein kinase C-alpha (PKCalpha) in tiger salamander brain tissue. Treatment of whole brain minces with vasopressin or vasotocin led to increases in PKCalpha in membrane fractions and concurrent decreases in PKCalpha in cytosolic fractions. Vasopressin or vasotocin treatment also induced the appearance in membrane and cytosolic fractions of a PKCalpha-immunoreactive band that corresponds to PKMalpha, the proteolytically generated, free catalytic subunit of PKCalpha. Treatment with corticosterone alone had no consistent effect on either PKCalpha or PKMalpha in either fraction. However, pretreatment with corticosterone reliably blocked vasopressin-induced increases in cytosolic PKMalpha. These data provide new information about the cellular mechanisms of action of vasopressin and corticosterone in the vertebrate brain and suggest a cellular mechanism by which the two hormones interact to regulate neuronal physiology and behavior.

A survey of the signaling pathways involved in megakaryocytic differentiation of the human K562 leukemia cell line by molecular and c-DNA array analysis

The K562 cell line serves as a model to study the molecular mechanisms associated with leukemia differentiation. We show here that cotreatment of K562 cells with PMA and low doses of SB202190 (SB), an inhibitor of the p38 MAPK pathway, induced a majority of cells to differentiate towards the megakaryocytic lineage. Electronic microscopy analysis showed that K562 cells treated with PMA+SB exhibited characteristic features of physiological megakaryocytic differentiation including the presence of vacuoles and demarcation membranes. Differentiation was also accompanied by a net increase in megakaryocytic markers and a reduction of erythroid markers, especially when both effectors were present. PMA effect was selectively mediated by new PKC isoforms. Differentiation of K562 cells by the combination of PMA and SB required Erk1/2 activation, a threshold of JNK activation and p38 MAPK inhibition. Interestingly, higher concentrations of SB, which drastically activated JNK, blocked megakaryocytic differentiation, and considerably increased cell death in the presence of PMA. c-DNA microarray membranes and PCR analysis allow us to identify a set of genes modulated during PMA-induced K562 cell differentiation. Several gene families identified in our screening, including ephrins receptors and some angiogenic factors, had never been reported so far to be regulated during megakaryocytic differentiation.

Defects in muscarinic receptor-coupled signal transduction in isolated parotid gland cells after in vivo irradiation: evidence for a non-DNA target of radiation

Radiation-induced dysfunction of normal tissue, an unwanted side effect of radiotherapeutic treatment of cancer, is usually considered to be caused by impaired loss of cell renewal due to sterilisation of stem cells. This implies that the onset of normal tissue damage is usually determined by tissue turnover rate. Salivary glands are a clear exception to this rule: they have slow turnover rates (>60 days), yet develop radiation-induced dysfunction within hours to days. We showed that this could not be explained by a hypersensitivity to radiation-induced apoptosis or necrosis of the differentiated cells. In fact, salivary cells are still capable of amylase secretion shortly after irradiation while at the same time water secretion seems specifically and severely impaired. Here, we demonstrate that salivary gland cells isolated after in vivo irradiation are impaired in their ability to mobilise calcium from intracellular stores (Ca2+ i), the driving force for water secretion, after exposure to muscarinic acetylcholine receptor agonists. Using radioligand-receptor-binding assays it is shown that radiation caused no changes in receptor density, receptor affinity nor in receptor-G-protein coupling. However, muscarinic acetylcholine agonist-induced activation of protein kinase C alpha (PKCalpha), measured as translocation to the plasma membrane, was severely affected in irradiated cells. Also, the phorbol ester PMA could no longer induce PKCalpha translocation in irradiated cells. Our data hence indicate that irradiation specifically interferes with PKCalpha association with membranes, leading to impairment of intracellular signalling. To the best of our knowledge, these data for the first time suggest that, the cells' capacity to respond to a receptor agonist is impaired after irradiation.

The cytoplasmic C-terminus of polycystin-1 increases cell proliferation in kidney epithelial cells through serum-activated and Ca(2+)-dependent pathway(s)

Polycystin-1 (PC1) is a large transmembrane protein important in renal differentiation and defective in most cases of autosomal dominant polycystic kidney disease (ADPKD), a common cause of renal failure in adults. Although the genetic basis of ADPKD has been elucidated, molecular and cellular mechanisms responsible for the dysregulation of epithelial cell growth in ADPKD cysts are still not well defined. We approached this issue by investigating the role of the carboxyl cytoplasmic domain of PC1 involved in signal transduction on the control of kidney cell proliferation. Therefore, we generated human HEK293 cells stably expressing the PC1 cytoplasmic tail as a membrane targeted TrkA-PC1 chimeric receptor protein (TrkPC1). We found that TrkPC1 increased cell proliferation through an increase in cytoplasmic Ca2+ levels and activation of PKC alpha, thereby upregulating D1 and D3 cyclin, downregulating p21waf1 and p27kip1 cyclin inhibitors, and thus inducing cell cycle progression from G0/G1 to the S phase. Interestingly, TrkPC1-dependent Ca2+ increase and PKC alpha activation are not constitutive, but require serum factor(s) as parallel component. In agreement with this observation, a significant increase in ERK1/2 phosphorylation was observed. Consistently, inhibitors specifically blocking either PKC alpha or ERK1/2 prevented the TrkPC1-dependent proliferation increase. NGF, the TrkA ligand, blocked this increase. We propose that in kidney epithelial cells the overexpression of PC1 C-terminus upregulates serum-evoked intracellular Ca2+ by counteracting the growth-suppression activity of endogenous PC1 and leading to an increase in cell proliferation.

Real-time analysis of phospholipase C activity during different patterns of receptor-induced Ca2+ responses in HEK293 cells

[Ca(2+)](i) oscillations can either depend on oscillatory inositol-1,4,5-trisphosphate (InsP(3)) formation by phospholipase C (PLC) or rely on local feedback mechanisms involving the InsP(3) receptor. To assess the PLC activity underlying carbachol-induced [Ca(2+)](i) oscillations in single HEK293 cells, we co-imaged [Ca(2+)](i) with fluorescent fusion proteins of protein kinase C (PKC) isotypes and the PH domain of PLC-delta 1 (PLC-delta 1(PH)). The translocation of PKC alpha-YFP in single cells followed two discrete patterns. Upon maximally effective agonist concentrations, a fast association and delayed dissociation (k(on)>k(off)) was the predominant pattern. The delayed dissociation has been linked to diacylglycerol formation. Upon stimulation with submaximally effective agonist concentrations as well as during regenerative [Ca(2+)](i) waves, we mainly observed short translocations with k(on) approximately equal to k(off). Translocation time courses and efficiencies of the diacylglycerol-sensing PKC epsilon-CFP and the InsP(3)/phosphatidylinositol-4,5-bisphosphate-sensing YFP-PLC-delta 1(PH) were closely correlated. Significant PLC activity was only detectable upon strong receptor stimulation, which typically failed to trigger [Ca(2+)](i) oscillations. During [Ca(2+)](i) oscillations induced by submaximal receptor stimulation, YFP-PLC-delta 1(PH) did not translocate, whereas a fluorescent PKC epsilon fusion protein has been reported to exhibit a slow, non-oscillatory accumulation at the plasma membrane. We conclude that carbachol-induced [Ca(2+)](i) oscillations in HEK293 cells develop at low levels of presumably non-oscillatory PLC activity.

Conventional PKCs regulate the temporal pattern of Ca2+ oscillations at fertilization in mouse eggs

In mammalian eggs, sperm-induced Ca²⁺ oscillations at fertilization are the primary trigger for egg activation and initiation of embryonic development. Identifying the downstream effectors that decode this unique Ca²⁺ signal is essential to understand how the transition from egg to embryo is coordinated. Here, we investigated whether conventional PKCs (cPKCs) can decode Ca²⁺ oscillations at fertilization. By monitoring the dynamics of GFP-labeled PKCα and PKCγ in living mouse eggs, we demonstrate that cPKCs translocate to the egg membrane at fertilization following a pattern that is shaped by the amplitude, duration, and frequency of the Ca²⁺ transients. In addition, we show that cPKC translocation is driven by the C2 domain when Ca²⁺ concentration reaches 1–3 μM. Finally, we present evidence that one physiological function of activated cPKCs in fertilized eggs is to sustain long-lasting Ca²⁺ oscillations, presumably via the regulation of store-operated Ca²⁺ entry.

Autophosphorylation Suppresses Whereas Kinase Inhibition Augments the Translocation of Protein Kinase Cα 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.

Protein kinase Calpha translocates to the perinuclear region to activate phospholipase D1

The inhibition of phorbol ester activation of phospholipase D1 (PLD1) by protein kinase C (PKC) inhibitors has been considered proof of phosphorylation-dependent activation of PLD1 by PKCalpha. We studied the effect of the PKC inhibitors Ro-31-8220 and bisindolylmaleimide I on PLD1 activation and found that they inhibited the activation by interfering with PKCalpha binding to PLD1. Further studies showed that only unphosphorylated PKCalpha could bind to and activate PLD1 and that both inhibitors induced phosphorylation of PKCalpha. The phosphorylation status of either PLD1 or PKCalpha per se did not affect PLD1 activation in vitro. Immunofluorescence studies showed that PLD1 remained in the perinuclear region after phorbol ester treatment, whereas PKCalpha translocated from cytosol to both plasma membrane and perinuclear regions. Both Ro-31-8220 and bisindolylmaleimide I blocked the translocation of PKCalpha to the perinuclear region but not to the plasma membrane. Studies with okadaic acid suggested that phosphorylation regulated the relocation of PKCalpha from the plasma membrane to the perinuclear region. It is proposed that localization and interaction of PKCalpha with PLD1 in the perinuclear region is required for PLD1 activation and that PKC inhibitors inhibit this through phosphorylation of PKCalpha, which blocks its translocation.

Calcium signalling: the ups and downs of protein kinase C

Oscillations in intracellular calcium levels control a plethora of physiological processes, but how they are decoded by a cell remains unclear. In a recent study, advances in FRET technology have been used to describe how calcium oscillations are decoded through phase-locked oscillations in substrate phosphorylation catalysed by protein kinase C.

Induction of neurites by the regulatory domains of PKCdelta and epsilon is counteracted by PKC catalytic activity and by the RhoA pathway

We have shown that protein kinase C (PKC) epsilon, independently of its kinase activity, via its regulatory domain (RD), induces neurites in neuroblastoma cells. This study was designed to evaluate whether the same effect is obtained in nonmalignant neural cells and to dissect mechanisms mediating the effect. Overexpression of PKCepsilon resulted in neurite induction in two immortalised neural cell lines (HiB5 and RN33B). Phorbol ester potentiated neurite outgrowth from PKCepsilon-overexpressing cells and led to neurite induction in cells overexpressing PKCdelta. The effects were potentiated by blocking the PKC catalytic activity with GF109203X. Furthermore, kinase-inactive PKCdelta induced more neurites than the wild-type isoform. The isolated regulatory domains of novel PKC isoforms also induced neurites. Experiments with PKCdelta-overexpressing HiB5 cells demonstrated that phorbol ester, even in the presence of a PKC inhibitor, led to a decrease in stress fibres, indicating an inactivation of RhoA. Active RhoA blocked PKC-induced neurite outgrowth, and inhibition of the RhoA effector ROCK led to neurite outgrowth. This demonstrates that neurite induction by the regulatory domain of PKCdelta can be counteracted by PKCdelta kinase activity, that PKC-induced neurite outgrowth is accompanied by stress fibre dismantling indicating an inactivation of RhoA, and that the RhoA pathway suppresses PKC-mediated neurite outgrowth.

A genetically encoded fluorescent reporter reveals oscillatory phosphorylation by protein kinase C

Signals transduced by kinases depend on the extent and duration of substrate phosphorylation. We generated genetically encoded fluorescent reporters for PKC activity that reversibly respond to stimuli activating PKC. Specifically, phosphorylation of the reporter expressed in mammalian cells causes changes in fluorescence resonance energy transfer (FRET), allowing real time imaging of phosphorylation resulting from PKC activation. Targeting of the reporter to the plasma membrane, where PKC is activated, reveals oscillatory phosphorylation in HeLa cells in response to histamine. Each oscillation in substrate phosphorylation follows a calcium oscillation with a lag of approximately 10 s. Novel FRET-based reporters for PKC translocation, phosphoinositide bisphosphate conversion to IP3, and diacylglycerol show that in HeLa cells the oscillatory phosphorylations correlate with Ca2+-controlled translocation of conventional PKC to the membrane without oscillations of PLC activity or diacylglycerol. However, in MDCK cells stimulated with ATP, PLC and diacylglycerol fluctuate together with Ca2+ and phosphorylation. Thus, specificity of PKC signaling depends on the local second messenger-controlled equilibrium between kinase and phosphatase activities to result in strict calcium-controlled temporal regulation of substrate phosphorylation.

Role of the Ca2+/phosphatidylserine binding region of the C2 domain in the translocation of protein kinase Calpha to the plasma membrane

Signal transduction via protein kinase C (PKC) is closely regulated by its subcellular localization. To map the molecular determinants mediating the C2 domain-dependent translocation of PKCalpha to the plasma membrane, full-length native protein and several point mutants in the Ca(2+)/phosphatidylserine-binding site were tagged with green fluorescent protein and transiently expressed in rat basophilic leukemia cells (RBL-2H3). Substitution of several aspartate residues by asparagine completely abolished Ca(2+)-dependent membrane targeting of PKCalpha. Strikingly, these mutations enabled the mutant proteins to translocate in a diacylglycerol-dependent manner, suggesting that neutralization of charges in the Ca(2+) binding region enables the C1 domain to bind diacylglycerol. In addition, it was demonstrated that the protein residues involved in direct interactions with acidic phospholipids play differential and pivotal roles in the membrane targeting of the enzyme. These findings provide new information on how the C2 domain-dependent membrane targeting of PKCalpha occurs in the presence of physiological stimuli.

The catalytic domain limits the translocation of protein kinase C alpha in response to increases in Ca2+ and diacylglycerol

Translocation of protein kinase C (PKC) alpha, beta II, delta and epsilon fused to enhanced green fluorescent protein (EGFP) was studied in living neuroblastoma cells by confocal microscopy. Exposure to carbachol elicited transient translocation of PKC alpha-EGFP and beta II-EGFP in most of the cells, PKC delta-EGFP in a few cells and induced sustained translocation of PKC epsilon-EGFP. To monitor levels of Ca(2+) and diacylglycerol and the translocation of PKC in the same cell, the Ca(2+)-sensitive C2 domain, diacylglycerol-sensitive C1 domains and full-length PKC were fused to red, cyan and yellow fluorescent proteins respectively. PKC alpha was translocated a few seconds after the C2 domain, which represents an increase in Ca(2+). This delay was insensitive to removal of the pseudosubstrate in PKC alpha, but the isolated regulatory domain translocated simultaneously with the C2 domain. Translocation of PKC epsilon coincided with the increase in diacylglycerol. Ionomycin induced translocation of PKC alpha and the C2 domain, whereas 1,2-dioctanoylglycerol caused translocation of the C1 domains and PKC epsilon, but not PKC alpha. Experiments with individual C1 domains showed that treatment with carbachol or phorbol 12,13-dibutyrate elicited translocation of PKC alpha C1a, PKC epsilon C1a and PKC epsilon C1b, whereas PKC alpha C1b was largely insensitive to these agents. In contrast with full-length PKC alpha, the regulatory domain of PKC alpha and pseudosubstrate-devoid PKC alpha responded to the carbachol-stimulated increase in diacylglycerol.

Protein kinase C isoform-specific differences in the spatial-temporal regulation and decoding of metabotropic glutamate receptor1a-stimulated second messenger responses

Metabotropic glutamate receptors (mGluRs) coupled via Gq to the hydrolysis of phosphoinositides stimulate Ca(2+) and PKCbetaII oscillations in both excitable and non-excitable cells. In the present study, we show that mGluR1a activation stimulates the repetitive plasma membrane translocation of each of the conventional and novel, but not atypical, PKC isozymes. However, despite similarities in sequence and cofactor regulation by diacyglycerol and Ca(2+), conventional PKCs exhibit isoform-specific oscillation patterns. PKCalpha and PKCbetaI display three distinct patterns of activity: (1) agonist-independent oscillations, (2) agonist-stimulated oscillations, and (3) persistent plasma membrane localization in response to mGluR1a activation. In contrast, only agonist-stimulated PKCbetaII translocation responses are observed in mGluR1a-expressing cells. PKCbetaI expression also promotes persistent increases in intracellular diacyglycerol concentrations in response to mGluR1a stimulation without affecting PKCbetaII oscillation patterns in the same cell. PKCbetaII isoform-specific translocation patterns are regulated by specific amino acid residues localized within the C-terminal PKC V5 domain. Specifically, Asn-625 and Lys-668 localized within the V5 domain of PKCbetaII cooperatively suppress PKCbetaI-like response patterns for PKCbetaII. Thus, redundancy in PKC isoform expression and differential decoding of second messenger response provides a novel mechanism for generating cell type-specific responses to the same signal.

Single-cell kinase assays: opening a window onto cell behavior

Recent advances in analytical techniques have made the performance of biochemical assays on individual mammalian cells possible. Of particular interest is the ability to measure the activation of kinases, enzymes with critical roles in virtually every aspect of cell physiology. Single-cell kinase assays promise to deliver a newfound understanding of the molecular mechanisms responsible for cellular control and behavior by revealing the dynamic nature of signal transduction networks in living cells. A recent exciting development is the potential to perform assays of multiple kinases simultaneously in a single cell.