Protein kinase C-mediated functional regulation of dopamine transporter is not achieved by direct phosphorylation of the dopamine transporter protein

Dopaminergic neurotransmission is terminated by the action of the presynaptic dopamine transporter (DAT). It mediates Na(+)/Cl(-) -dependent re-uptake of extracellular dopamine (DA) into the cell, and is regarded as a major regulatory mechanism for synaptic transmission. Previous works have documented that protein kinase C (PKC) activator or inhibitor alters DA uptake by DAT, suggesting that PKC phosphorylation plays an important regulatory mechanism in DAT function. Based on the existence of consensus amino acid sequences for PKC phosphorylation, it has been postulated that PKC regulation of DAT is mediated by the direct phosphorylation of DAT protein. In this study, we try to discover whether the functional regulation of DAT by PKC is due to direct phosphorylation of DAT. The PKC null mutant hDAT, where all putative PKC phosphorylation sites are eliminated, has been constructed by the replacement of serine/threonine residues with glycines. The mutation itself showed no effect on the functional activities of DAT. The DA uptake activity of PKC null mutant was equivalent to those of wild-type hDAT (80-110% of wild-type). Phorbol ester activation of PKC inhibited DA uptake of wild-type hDAT by 35%, and staurosphorine blocked the effect of phorbol ester on DA uptake. The same phenomena was observed in PKC null mutant DAT, although no significant phosphorylation was observed by PKC activation. Confocal microscopic analysis using EGFP-fused DAT revealed that the activation of PKC by phorbol ester elicited fluorescent DAT to be internalized into the intracellular space both in wild-type and PKC null mutant DAT in a similar way. These results suggest that PKC-mediated regulation of DAT function is achieved in an indirect manner, such as phosphorylation of a mediator protein or activation of a clathrin-mediated pathway.     

Regulation of T-cell-derived protein kinase C activity by vitamin A derivatives

Protein kinase C (PKC) is a ubiquitous enzyme linked to transmembrane signal transduction. It regulates agonist-mediated activation of intracellular events that result in growth and differentiation in a variety of cells and tissues. PKC is the cellular receptor for phorbol ester tumor promoters, such as 12-O-tetradecanoylphorbol-13-acetate (TPA), that bind to, and directly activate, this enzyme. Vitamin A analogs (retinoids) have been known to antagonize biologic effects of phorbol esters, e.g., promotion of skin tumor formation; however, the extract mechanism(s) of this action is not clear. To analyze the effects of retinoids on T-cell-derived PKC, we partially purified the enzyme from human leukemic T cells (Jurkat) and examined the effects of different vitamin A analogs on its activity. Furthermore, the regulatory effects of retinoids on PKC activity were compared with those of common membrane phospholipids. Retinal inhibited PKC activation induced by TPA, as well as by diacylglycerol, the physiologic activator of PKC. The observed inhibition resulted from competition with phospholipid (phosphatidylserine) and was selective for the phospholipid-dependent C kinase; cAMP-dependent protein kinase, which is phospholipid-independent, was not affected by retinal. The inhibitory effect of retinal on PKC activity was similar to that of phosphatidylcholine. Retinoic acid, in contrast to retinal, induced a Ca2+-dependent activation of PKC, thus substituting for phosphatidylserine. Furthermore, PKC activation by retinoic acid was similar to that by phosphatidylserine, the natural phospholipid cofactor, in that both could be inhibited by phosphatidylcholine and augmented by phosphatidylinositol. The inhibition or activation of PKC by retinal or retinoic acid, respectively, was independent of whether the terminal aldehyde (retinal) or carboxyl (retinoic acid) groups were in the trans or cis configuration. Other vitamin A analogs tested did not affect PKC activity. The results demonstrate that different retinoids and phospholipids may have positive or negative cooperativity in PKC activation, thereby regulating its enzymatic activity and affecting the resulting intracellular activation events. These findings suggest that at least part of the biologic effects of retinoids in general, and their modulation of T-cell function in particular, may be mediated via the influence of their intracellular metabolites on PKC, and that this mechanism may account for some of the antagonistic effects of retinoids on TPA-mediated responses in cells.     

Reversible oxidative activation and inactivation of protein kinase C by the mitogen/tumor promoter periodate.

The oxidant mitogen/tumor promoter, periodate, was used to selectively modify either the regulatory domain or the catalytic domain of protein kinase C (PKC) to induce oxidative activation or inactivation of PKC, respectively. Periodate, at micromolar concentrations, modified the regulatory domain of PKC as determined by the loss of ability to stimulate kinase activity by Ca2+/phospholipid, and also by the loss of phorbol ester binding. This modification resulted in an increase in Ca2+/phospholipid-independent kinase activity (oxidative activation). However, at higher concentrations (greater than 100 microM) periodate also modified the catalytic domain, resulting in complete inactivation of PKC. The oxidative modification induced by low periodate concentrations (less than 0.5 mM) was completely reversed by a brief treatment with 2 mM dithiothreitol. In this aspect, the modification induced by periodate was different from that of the previously reported irreversible modification of PKC induced by H2O2. However, the inactivation of PKC induced by periodate at concentrations greater than 1 mM was not reversed by dithiothreitol. Among the phospholipids and ligands of the regulatory domain tested, only phosphatidylserine protected the regulatory domain from oxidative modification. In the presence of phosphatidylserine, the catalytic site was selectively modified by periodate, resulting in formation of a form of PKC that exhibited phorbol ester binding but not kinase activity. Both reversible and irreversible oxidative activation and inactivation of PKC also were observed in intact cells treated with periodate. Taken together these results suggest that periodate, by virtue of having a tetrahedral structure, binds to the phosphate-binding regions present within the phosphatidylserine-binding site of the regulatory domain and the ATP-binding site of the catalytic domain, and modifies the vicinal thiols present within these sites. This results in the formation of intramolecular disulfide bridge(s) within the regulatory domain or catalytic domain leading to either reversible activation or inactivation of PKC, respectively. Thus, oxidant mitogen/tumor promoters such as periodate may be able to bypass normal transmembrane signalling systems to directly activate pathways involved in cellular regulation.     

Monounsaturated fatty acids are required for membrane translocation of protein kinase C-theta induced by lipid overload in skeletal muscle

Abstract

Protein kinase C (PKC) activation induced by diacylglycerols (DAGs) is one of the sequels of the dysregulation of intramuscular lipid metabolism and is thought to play an important role in the development of insulin resistance (IR). We tested the hypothesis that DAGs with different acyl chains have different biological effects and that DAG species enriched in monounsaturated fatty acids (MUFA) act as better activators of PKC. The experiments were performed in vitro on C2C12 myotubes treated with palmitate (16:0), stearate (18:0) or oleate (18:1) and in vivo on the skeletal muscles of rats fed high-fat (HF), high-tristearin (TS) or high-triolein (TO) diets. To define the importance of endogenously synthesized MUFA on DAG-induced PKCθ activation, we performed experiments on stearoyl-CoA desaturase 1 knockout mice (SCD1-/-) as well. The results show that the content of total DAGs and the levels of saturated DAG species are significantly increased in both insulin-resistant (16:0, HF and TO) and highly insulin-sensitive (18:0 and TS) groups. An increase in MUFA-containing DAGs levels was most constantly related to increase in PKCθ membrane translocation and IR. In the muscles of MUFA-deficient SCD1-/- mice, the DAG content and the induction of PKCθ translocation by the HF diet were significantly reduced. Collectively, our data from both the cell and animal experiments show that DAGs composed of 16:1 and/or 18:1, rather than the levels of total or saturated DAGs, are related to PKCθ membrane translocation. Moreover, our results show that the availability of dietary MUFA and/or the activity of endogenous desaturases play an important role in muscle DAG accumulation.     

Protein kinase C signaling and oxidative stress

Oxidative stress is involved in the pathogenesis of various degenerative diseases including cancer. It is now recognized that low levels of oxidants can modify cell-signaling proteins and that these modifications have functional consequences. Identifying the target proteins for redox modification is key to understanding how oxidants mediate pathological processes such as tumor promotion. These proteins are also likely to be important targets for chemopreventive antioxidants, which are known to block signaling induced by oxidants and to induce their own actions. Various antioxidant preventive agents also inhibit PKC-dependent cellular responses. Therefore, PKC is a logical candidate for redox modification by oxidants and antioxidants that may in part determine their cancer-promoting and anticancer activities, respectively. PKCs contain unique structural features that are susceptible to oxidative modification. The N-terminal regulatory domain contains zinc-binding, cysteine-rich motifs that are readily oxidized by peroxide. When oxidized, the autoinhibitory function of the regulatory domain is compromised and, consequently, cellular PKC activity is stimulated. The C-terminal catalytic domain contains several reactive cysteines that are targets for various chemopreventive antioxidants such as selenocompounds, polyphenolic agents such as curcumin, and vitamin E analogues. Modification of these cysteines decreases cellular PKC activity. Thus the two domains of PKC respond differently to two different type of agents: oxidants selectively react with the regulatory domain, stimulate cellular PKC, and signal for tumor promotion and cell growth. In contrast, antioxidant chemopreventive agents react with the catalytic domain, inhibit cellular PKC activity, and thus interfere with the action of tumor promoters.     

Dissociation of protein kinase C activation and sn-1,2-diacylglycerol formation. Comparison of phosphatidylinositol- and phosphatidylcholine-derived diglycerides in alpha-thrombin-stimulated fibroblasts

Diacylglycerols (DAGs) derived from phosphatidylcholine (PC) hydrolysis have been shown to activate protein kinase C (PKC) in vitro, but it is not known whether this event occurs in response to DAGs generated via agonist-induced PC hydrolysis in intact cells. In this report we have addressed this question directly, using alpha-thrombin stimulation of IIC9 fibroblasts. PKC activation in intact cells was assessed in two ways, by measuring: 1) PKC membrane association as determined by kinase activity and Western blot analysis and 2) the phosphorylation of an endogenous PKC substrate, an 80-kDa protein. Treatment with 500 ng/ml alpha-thrombin has been shown to stimulate both phosphoinositide and PC hydrolysis, whereas treatment with 100 pg/ml alpha-thrombin stimulates only PC breakdown. Using these two conditions, we show that DAG produced from phosphoinositide, but not PC hydrolysis, is associated with the activation of PKC.     

Protein kinase Cβ is a modulator of the dopamine D2 autoreceptor‐activated trafficking of the dopamine transporter

The strength and duration of extracellular dopamine concentrations are regulated by the presynaptic dopamine transporter (DAT) and dopamine D2 autoreceptors (D2autoRs). There is a functional interaction between these two proteins. Activation of D2autoRs increases DAT trafficking to the surface whereas disruption of this interaction compromises activities of both proteins and alters dopaminergic transmission. Previously we reported that DAT expression and activity are subject to modulation by protein kinase Cβ (PKCβ). Here, we further demonstrate that PKCβ is integral for the interaction between DAT and D2autoR. Inhibition or absence of PKCβ abolished the communication between DAT and D2autoR. In mouse striatal synaptosomes and transfected N2A cells, the D2autoR‐stimulated membrane insertion of DAT was abolished by PKCβ inhibition. Moreover, D2autoR‐stimulated DAT trafficking is mediated by a PKCβ‐extracellular signal‐regulated kinase signaling cascade where PKCβ is upstream of extracellular signal‐regulated kinase. The increased surface DAT expression upon D2autoR activation resulted from enhanced DAT recycling as opposed to reduced internalization. Further, PKCβ promoted accelerated DAT recycling. Our study demonstrates that PKCβ critically regulates D2autoR‐activated DAT trafficking and dopaminergic signaling. PKCβ is a potential drug target for correcting abnormal extracellular dopamine levels in diseases such as drug addiction and schizophrenia.     

Syntaxin 1A and Receptor for Activated C Kinase Interact with the N-Terminal Region of Human Dopamine Transporter

The dopamine transporter (DAT) regulates the extent and duration of dopamine receptor activation through sodium-dependant reuptake of dopamine into presynaptic neurons, resulting in termination of dopaminergic neurotransmission. Using the yeast two-hybrid system, we have identified novel interactions between DAT, the SNARE protein syntaxin 1A, and the receptor for activated C kinases (RACK1). This association involves the intracellular N-terminal domain of human DAT (hDAT). Our data suggest that hDAT may exist as dimers or oligomers and that its protein-protein interactions with syntaxin 1A and RACK1 form functional regulatory complexes that may mediate DAT trafficking through modulation of hDAT phosphorylation by PKC.     

The sustained second phase of hormone-stimulated diacylglycerol accumulation does not activate protein kinase C in GH3 cells

Numerous hormones activate cells through receptor-regulated hydrolysis of phosphoinositides resulting in elevated cellular diacylglycerol (DAG), an activator of protein kinase C (PKC). Our previous studies showed that thyrotropin-releasing hormone (TRH) treatment of GH3 cells stimulated a rapid (less than 10 s) but transient (less than 60 s) association of cytosolic PKC with the membrane. In this study, we investigated the roles of hormone-stimulated Ca2+ and DAG levels in initiating and terminating the membrane association of PKC. The initial effects of TRH were not mimicked by elevating CA2+ levels, however, inhibiting TRH-stimulated Ca2+ increases blocked hormone-stimulated PKC translocation. Hence, the TRH stimulation of both Ca2+ and DAG levels were essential for the initial PKC translocation. The termination of PKC membrane association could not be attributed to proteolysis of PKC nor to limiting Ca2+ levels. Treatment of cells with phorbol diesters potentiated and prolonged the effects of TRH on PKC translocation, suggesting that DAG levels limited the membrane association of PKC. Since TRH stimulated a sustained increase in DAG levels, DAG composition was analyzed. There was a marked shift in DAG from tetraenoic (at 15 s) to more saturated DAGs at longer times. In addition, increases in plasma membrane DAG in response to TRH were transient rather than sustained. We propose that the TRH stimulation of PKC translocation is short-lived due to the metabolism of plasma membrane DAGs which are effective in promoting PKC activation. In contrast, DAGs which accumulate in intracellular membranes during the sustained phase of TRH treatment appear to be ineffective as activators of PKC.     

Regulatory mechanism of histidine-tagged homocitrate synthase from Saccharomyces cerevisiae. II. Theory

In this study, rate equations that predict the regulatory kinetic behavior of homocitrate synthase were derived, and simulation of the predicted behavior was carried out over a range of values for the kinetic parameters. The data obtained allow application of the resulting expressions to enzyme systems that exhibit activation and inhibition as a result of the interaction of effectors at multiple sites in the free enzyme. Homocitrate synthase was used as an example in terms of its activation by Na+ binding to the active enzyme conformer at an allosteric site, inhibition by binding to the active site, and inhibition by lysine binding to the less active enzyme conformer.     

Effects of the methoxy group in the side chain of debromoaplysiatoxin on its tumor-promoting and anti-proliferative activities

Debromoaplysiatoxin (DAT) is a tumor promoter isolated from sea hare and exhibits anti-proliferative activity against several cancer cell lines. To clarify key residues that are responsible for its tumor-promoting activity, we focused on the chiral methoxy group in the side chain, whose role had not yet been discussed or examined before. Demethoxy-DAT (8) was derived from DAT and we evaluated its tumor-promoting activity, anti-proliferative activity, and ability to bind to protein kinase C (PKC) isozymes. Compound 8 showed somewhat weaker tumor-promoting activity than that of DAT both in vitro and in vivo, but showed higher anti-proliferative activity against several cancer cell lines. Although the affinity to novel PKC isozymes of 8 was comparable to that of DAT, the affinity to conventional PKC isozymes decreased slightly. These results suggest that the methoxy group of DAT is one of the key residues critical for tumor-promoting activity but not for anti-proliferative activity. Since the methoxy group has little influence on the molecular hydrophobicity, this is the first report showing that structural factors other than hydrophobicity in the side chain of DAT affected its biological activities.     

Effects of a fecapentaene on protein kinase C

Protein kinase C (PKC) is a Ca2(+)- and phospholipid-dependent serine and threonine protein kinase which binds and is activated by tumor promoters such as the phorbol ester 12-0-tetradecanoylphorbol-13-acetate (TPA). PKC can be activated in vitro by phosphatidylserine (PS) plus Ca2+. We report here that the compound fecapentaene-12 can replace the requirement for PS in the activation of PKC by Ca2+. In addition, at low concentrations fecapentaene-12 can enhance the activation of PKC by Ca2+ and PS. It can also either enhance or inhibit activation of PKC by the tumor promoter teleocidin, depending on the assay conditions. These results are of interest since fecapentaene is known to be a potent mutagen that is produced by Bacteroides species present in the lumen of the human colon. The present studies raise the possibility that this compound might also play a role in colon cancer by altering the activity of PKC.     

Teleocidin and phorbol ester tumor promoters exert similar mitogenic effects on human lymphocytes

The tumor promoter 12-0-tetradecanoyl-phorbol-13-acetate (TPA) affects a wide variety of cellular functions via its binding to protein kinase C (PKC). The TPA molecule contains a diacylglycerol (DAG)-like structure, which may explain its ability to mimic DAG in PKC activation. Teleocidin (TCD) is a different tumor promoter which can compete with TPA in binding to its cell surface receptors even though structurally unrelated to TPA or DAG. Since TCD may use an additional receptor system and/or be distinguished from TPA in its effect on cells, we compared the effects of TPA and TCD on human peripheral blood lymphocytes (PBL). Both tumor promoters preferentially enhanced cell proliferation of sheep erythrocyte-rosetted lymphocytes, which were enriched for T cells. Additionally, TPA and TCD both induced a high density of cell surface receptors for interleukin 2 (IL2) and transferrin, but not synthesis or production of IL2. However, either of the tumor promoters synergized with T cell mitogens to induce high level IL2 production by PBL. In dose response and kinetic studies, matching concentrations of TPA and TCD induced similar effects in PBL. The results thus demonstrate that TPA and TCD are alike in mitogenic capacity, and suggest that structural similarity between the tumor promoter and DAG, the physiological activator of PKC, is not an essential property for promoting tumors or affecting a wide variety of cellular functions.     

Three ubiquitin conjugation sites in the amino terminus of the dopamine transporter mediate protein kinase C-dependent endocytosis of the transporter

Dopamine levels in the brain are controlled by the plasma membrane dopamine transporter (DAT). The amount of DAT at the cell surface is determined by the relative rates of its internalization and recycling. Activation of protein kinase C (PKC) leads to acceleration of DAT endocytosis. We have recently demonstrated that PKC activation also results in ubiquitylation of DAT. To directly address the role of DAT ubiquitylation, lysine residues in DAT were mutated. Mutations of each lysine individually did not affect ubiquitylation and endocytosis of DAT. By contrast, ubiquitylation of mutants carrying multiple lysine substitutions was reduced in cells treated with phorbol ester to the levels detected in nonstimulated cells. Altogether, mutagenesis data suggested that Lys19, Lys27, and Lys35 clustered in the DAT amino-terminus are the major ubiquitin-conjugation sites. The data are consistent with the model whereby at any given time only one of the lysines in DAT is conjugated with a short ubiquitin chain. Importantly, cell surface biotinylation, immunofluorescence and down-regulation experiments revealed that PKC-dependent internalization of multilysine mutants was essentially abolished. These data provide the first evidence that the ubiquitin moieties conjugated to DAT may serve as a molecular interface of the transporter interaction with the endocytic machinery.     

Activation of cAMP-dependent protein kinase alters the chromatin structure of the urokinase-type plasminogen activator gene promoter.

In LLC-PK1 cells, the urokinase-type plasminogen activator (uPA) gene is induced by two of the major signal transduction pathways, the protein kinase C (PKC) and the cAMP-dependent protein kinase (PKA) pathways. We have analyzed the chromatin structure of 26 kb of the uPA gene locus and have shown that PKA activation but not PKC activation induce major chromatin structural alterations in the uPA gene promoter. In uninduced cells, several DNase I hypersensitive (HS) sites were detected in the 5' and 3' flanking regions but not in the transcribed region. Two of the sites correspond to previously characterized regulatory sites: a cAMP responsive site at nucleotide position -3500 with respect to the initiation site, and the PEA3/AP1 site at -2100 that mediates PKC activation. After the activation of PKA but not PKC, a strong HS site was induced at -2600. Functional analysis of this region revealed cAMP responsive activity. Chromatin structural alterations again brought about specifically by PKA but not by PKC were were also detected in the upstream of the promoter by topoisomerase I cleavage site analysis, with two prominent sites appearing at -2800 and -3300. These results suggest that the strong cAMP induction of the uPA gene requires structural alterations that permit cooperative interactions between the multiple cAMP responsive sites.     

Signalling events mediating the activation of protein kinase C by interleukin-2 in cytotoxic T cells.

Interleukin-2 (IL-2) plays a vital role in the generation and regulation of the immune response, including important aspects of T cell survival. IL-2-mediated survival of T cells appears to be dependent on the activation of a pool of membrane-associated protein kinase C (PKC) that occurs in the absence of detectable translocation of the enzyme from the cytosol to membranes. In this report we investigate the mechanism(s) responsible for this PKC activation after IL-2 stimulation in the cytotoxic T cell line, CTLL-2. Tyrosine kinase activity, activated after IL-2 stimulation, was found not to be linked to the activation of PKC by the cytokine. On the other hand, a pertussis toxin (PTX)-sensitive G protein did appear coupled to PKC activation since PTX effectively blocked IL-2 stimulated PKC activity. Diacylglycerols (DAG), but not inositol 1,3,5-triphosphate (IP3) and intracellular Ca2+, increased after IL-2 stimulation suggesting that DAGs were generated via the phosphatidylcholine-phospholipase C (PC-PLC) or phosphatidylcholine-phospholipase D (PC-PLD) pathways. The increase in DAG by IL-2 was probably necessary for activation of membrane-resident PKC since exogenously applied DAG stimulated this PKC pool in both intact cells and in isolated membranes. IL-2 also increased arachidonic acid (AA) production in CTLL-2 cells, probably via phospholipase A2 (PLA2) since the PLA2 inhibitors oleoyloxyethyl phosphocholine and AACOCF3 (AACF) effectively blocked IL-2 stimulated PKC activation. Exogenous AA also increased PKC activity in intact cells and isolated membranes, suggesting that AA produced by IL-2 receptor stimulation was probably linked to PKC activation. These results suggest that the activation of membrane-resident PKC by IL-2 involves multiple second messengers, including G proteins, DAG and AA.     

Subcellular distribution of protein kinase C/phorbol ester receptors in differentiating mouse keratinocytes

The activation of protein kinase C (PKC) by diacylglycerol or tumor promoters plays a pivotal role in signal transduction and subsequent activation of cellular processes. Since the activity of this enzyme is dependent on its immediate lipid domain, its relative distribution within the cell may be an important regulatory mechanism. We report here a relative decrease in PKC/phorbol ester receptor associated with the particulate fraction of mouse keratinocytes induced to differentiate by two separate systems. First, proliferating keratinocytes maintained in low Ca2+ (0.09 mM) serum-free medium were induced to differentiate rapidly by the addition of Ca2+ (1.8 mM). A 1.4-fold decrease in the percent of total phorbol receptor binding activity present in the particulate fraction and concomitant increase in binding in the cytosol fraction was evident 20 min after the Ca2+ addition. Second, in keratinocytes that differentiate over a 6 day cultivation period in serum-containing medium with Ca2+ concentration of 1.8 mM, a significant decrease in the percent of the phorbol receptor binding activity present in the particulate fraction was observed as the culture begins to differentiate on days 3 and 4. Maximal phorbol ester binding in the particulate fraction corresponded to the proliferative phase of the culture (day 2), while lower levels of PKC/phorbol ester binding to particulate fractions were noted during the early differentiative phase (days 3 and 4). Addition of the synthetic diacylglycerols 1-oleoyl-2-acetylglycerol or L-alpha-1,2 dioctanyl glycerol at 30 micrograms/ml to proliferating keratinocyte cultures induced a modest increase in two markers of terminal differentiation: cornified envelope formation and transglutaminase levels. These findings, taken together, support the hypothesis that PKC activation plays a role in the initial signalling events for keratinocyte differentiation.