Structural organization of the human S-antigen gene. cDNA, amino acid, intron, exon, promoter, in vitro transcription, retina, and pineal gland

S-Antigen (S-Ag) is a major soluble photoreceptor protein involved in the visual transduction cascade. Several S-Ag cDNAs and a gene coding for human S-Ag were isolated from cDNA and gene libraries. The gene sequences of the coding, noncoding, and 5'-flanking regions of the gene were determined. The S-Ag gene was approximately 50 kbp (kilobase pairs) in length and contained 16 exons and 15 introns. The length of most exons was less than 100 base pairs (bp) and the smallest one was only 10 bp. In contrast, the length of most introns was larger than 2 kbp, and the gene comprised 97% intron and 3% exon. The splice sites for donor and acceptor were in good agreement with the GT/AG rule. The S-Ag protein of 403 amino acid residues was translated from a mRNA of 1.9 kbp, and the mRNA was transcribed from a gene of 50 kbp. The 5'-flanking region of the gene, approximately 1.1 kbp long, had no known regulatory elements for transcription such as TATA, GC, and CCAAT boxes. Interestingly, the 5'-flanking region had promoter activity in an in vitro transcription assay using a nuclear extract of rat brain. A major transcription start site was found at 387 bp upstream from the translation start site ATG. Our results indicate that the sequence of S-Ag promoter differs from other known promoters and may, perhaps, be specific for photoreceptor rod cells and pinealocytes.

Characterization of the 5'-flanking region of the rat protein kinase C gamma gene

The 5'-flanking region of protein kinase C (PKC) gamma gene was identified from a rat liver genomic library in a bacteriophage lambda Charon 4A. A 3.6-kilobase (kb) genomic fragment containing the 5'-flanking region, first exon, and first intron was isolated and sequenced. The transcriptional initiation site, identified by S1 mapping and primer extension, was located 243 base pairs upstream from the translational initiation site. Promoter activity of a DNA segment spanning the 5'-flanking region was demonstrated by both in vitro transcription using HeLa cell nuclear extracts and chloramphenicol acetyltransferase assay by transfection of 293 cells with a PKC gamma-CAT fusion construct. Chloramphenicol acetyltransferase assay revealed that a fragment of about 0.16 kb from the transcriptional initiation site was sufficient for promoter activity in these cells, and the construct containing up to 1.6 kb from the cap site was expressed at a similar level. This promoter-active fragment contains several regions similar to defined transcriptional elements in other mammalian promoters, such as those for stimulatory protein 1 (Sp1), activator proteins 1 and 2 (AP1, AP2), c-myc, cAMP regulatory element-binding protein (CREB), and enhancer core (EnhC). Investigation of the genomic structure of PKC gamma gene may lead to the identification of cis-elements controlling tissue-specific and developmental stage-specific expression of PKC gamma.

Feedback regulation of phospholipase C-beta by protein kinase C

Treatment of a variety of cells and tissues with 12-O-tetradecanoylphorbol-13-acetate (TPA), an activator of protein kinase C (PKC) results in the inhibition of receptor-coupled inositol phospholipid-specific phospholipase C (PLC) activity. To determine whether or not the targets of TPA-activated PKC include one or more isozymes of PLC, studies were carried out with PC12, C6Bu1, and NIH 3T3 cells, which contain at least three PLC isozymes, PLC-beta, PLC-gamma, and PLC-delta. Treatment of the cells with TPA stimulated the phosphorylation of serine residues in PLC-beta, but the phosphorylation state of PLC-gamma and PLC-delta was not changed significantly. Phosphorylation of bovine brain PLC-beta by PKC in vitro resulted in a stoichiometric incorporation of phosphate at serine 887, without any concomitant effect on PLC-beta activity. We propose, therefore, that rather than having a direct effect on enzyme activity, the phosphorylation of PLC-beta by PKC may alter its interaction with a putative guanine nucleotide-binding regulatory protein and thereby prevent its activation.

Phosphorylation of magainin-2 by protein kinase C and inhibition of protein kinase C isozymes by a synthetic analogue of magainin-2-amide

Magainins are a family of antimicrobial peptides present in the skin extracts of Xenopus laevis. Both magainin-1 and -2 do not have any significant effect on the activity of protein kinase C (PKC). Magainin-2 was found to be readily phosphorylated by PKC to 0.5 mol 32P/mol of peptide. Neither magainin-1, which has a sequence of S8AGK and not S8AKK as in the case of magainin-2, nor the magainin-2 analogue with substitution of Ala for Ser8 was phosphorylated by the kinase, suggesting that Ser8 is the phosphorylation site of magainin-2. One synthetic analogue of magainin, designated magainin B, which has a greater tendency for alpha-helix formation in non-aqueous environment than the parent peptide resulting from substitution of Ser8, Gly13, and Gly18 with Ala in magainin-2-amide, is a potent inhibitor of PKC. This peptide inhibits all three PKC isozymes with IC50 less than 20 microM. Magainin B also inhibits the binding of [3H]phorbol 12,13-dibutyrate to the kinase. These results suggest that magainin-2 may be modified by PKC through phosphorylation and that certain synthetic analogues of magainins may be used as inhibitors of PKC.

Role of protein kinase C in cellular regulation

Protein kinase C (PKC) consists of a family of closely related enzymes ubiquitously present in animal tissues. These enzymes respond to second messengers, Ca2+, diacylglycerol and arachidonic acid, to express their activities at membrane locations. Numerous hormones, neurotransmitters, growth factors and antigens are believed to transmit their signals by activation of a variety of phospholipases to generate these messengers. The various PKC isozymes, which exhibit distinct biochemical characteristics and unique cellular and subcellular localizations, may be differentially stimulated depending on the duration and strength of these messengers. Activation of PKC has been linked to the regulation of cell surface receptors, ion channels, secretion, gene expression, and neuronal plasticity and toxicity. The mechanisms of action of PKC in the regulation of these cellular functions are not entirely clear. Further study to identify the target substrates relevant to the various cellular functions is essential to define the functional diversity of this enzyme family.

Effects of suramin, an anti-human immunodeficiency virus reverse transcriptase agent, on protein kinase C. Differential activation and inhibition of protein kinase C isozymes

Suramin inhibited protein kinase C (PKC) type I-III activity in a concentration-dependent manner. Similar inhibitory effects were observed with M-kinase, the constitutively active catalytic fragment of PKC, and autophosphorylation of PKC types I-III. Kinetic experiments indicated that suramin competitively inhibits activity with respect to ATP (Ki = 17, 27, and 31 microM, respectively) and that it can also inhibit by interaction with the substrate histone III-S. With protamine as the Pi acceptor, suramin inhibition was dependent on lipid, being approximately 4-fold less sensitive to inhibition in the absence of phosphatidylserine and diacylglycerol than in their presence. Suramin at low concentrations (10-40 microM), in the presence of Ca2+ and absence of lipid, was able to stimulate kinase activity (approximately 200-400%) in a type-dependent manner and at higher concentrations inhibited activity with histone III-S as substrate. These results indicate that suramin, a hexa-anionic hydrophobic compound, can act as a negatively charged phospholipid analog in activating PKC in the presence of Ca2+ and absence of lipid and can inhibit Ca2+/phosphatidylserine/diacylglycerol-stimulated kinase activity at higher concentrations by competing with ATP or by interaction with the exogenous substrate. Suramin inhibited cAMP-dependent protein kinase much less potently (IC50 = 656 microM) than PKC. The ability of suramin to inhibit PKC-mediated processes in intact cells was tested using the phorbol ester-stimulated respiratory burst of neutrophils as a model system. The respiratory burst of human neutrophils, when preincubated with suramin and then stimulated with phorbol ester, was inhibited in a concentration-dependent manner, suggesting that suramin may also be able to inhibit PKC-mediated processes in intact cells.

Rat liver nuclei protein kinase C is the isozyme type II

Rat liver nuclei protein kinase C is identified as type II isozyme employing monospecific antibodies obtained against each three types of rat brain protein kinase C isozymes. (Yoshida, Y., Huang, F. L., Nakabayashi, H., and Huang, K-P. (1988) J. Biol. Chem. 263, 9868-9873). A major immunoreactive protein band at 80 kDa was revealed by type II isozyme antibodies at each step of purification, nuclear extract included. The nuclear protein kinase C has been purified to apparent homogeneity as revealed by silver nitrate staining on sodium dodecyl sulfate-polyacrylamide gel electrophoresis showing a single 80 kDa protein band. It does seem that 66 kDa protein (Masmoudi, A., Labourdette, G., Mersel, M., Huang, F. L., Huang, K.-P., Vincendon, G., and Malviya, A. N. (1989) J. Biol. Chem. 264, 1172-1179) is a major contaminant devoid of any protein kinase activity. The ratio obtained between protein kinase C enzymatic activity over phorbol dibutyrate bound, at various purification steps, indicates that the nuclear enzyme is a phorbol ester receptor. When isolated nuclei were incubated with 12-O-tetradecanoyl phorbol-13-acetate, endogenous protein kinase C activity was elevated about 8-10-fold suggesting the existence of phorbol ester signaling pathway at the level of nucleus. The role of nuclear protein kinase C is delineated in the regulation of inducible gene transcription

Developmental expression of protein kinase C isozymes in rat cerebellum

Previously we showed that protein kinase C (PKC) isozymes (types I, II, and III) have distinctive neuronal localizations in cerebellum. In the present study, we followed the different appearances of these isozymes during the postnatal development of cerebellum. By immunoblot analysis, type I PKC was found to be low within 2 weeks after birth; an abrupt increase was observed between 2 and 3 weeks and leveled off afterwards. By immunofluorescent staining, the type I PKC-specific antibody recognized the cell bodies and dendrites of Purkinje cells. The increase of this isozyme between 2 and 3 weeks of age correlates with the spreading of Purkinje cell arborization, at which time bulk of synaptogenesis between dendritic spines and axons of granule cells occurs. Both type II and III PKCs were present in granule cells. At birth, the level of type II PKC was relatively high compared to that of type III PKC, and the type II PKC-specific antibody stained the granule cell precursors in the external layer more heavily than did the type III PKC-specific antibody. The level of type II PKC declined slightly after birth and increased again at one week and plateaued after three weeks, whereas that of type III PKC increased gradually until leveling off after three weeks. Throughout the development, the type III PKC-specific antibody also stained the cell bodies of Purkinje cells but not their dendrites. These results demonstrate that the developmental expression of PKC isozymes is under separate control, and their distinct cellular and subcellular localizations suggest their unique functions in the cerebellum.

Differential sensitivity of protein kinase C isozymes to phospholipid-induced inactivation

Interactions of types I, II, and III protein kinase C (PKC) with phospholipids were investigated by following the changes in protein kinase activity and phorbol ester binding. The acidic phospholipids such as phosphatidylserine (PS), phosphatidic acid, phosphatidyl-glycerol, and cardiolipin, which are activators of PKC in the assay of protein phosphorylation, could differentially inactivate PKC I, II, and III during preincubation in the absence of divalent cation. The phospholipid-induced inactivation of PKC was concentration and time dependent and only affected the kinase activity without influencing phorbol ester binding. PKC I was the most susceptible to the phospholipid-induced inactivation, and PKC III was the least. The IC50 values of PS for PKC I, II, and III were 5, 45, and greater than 120 microM, respectively. Addition of divalent cation such as Ca2+ or Mg2+ suppressed the phospholipid-induced inactivation of PKC. In the absence of divalent cation, PKC I, II, and III all formed complexes with PS vesicles, although to a slightly different degree, as analyzed by molecule sieve chromatography. [3H]Phorbol 12,13-dibutyrate binding for PKC I, II, and III was recovered after chromatography; however, the kinase activities of all these enzymes were greatly reduced. In the presence of Ca2+, all three PKCs formed complexes with PS vesicles, and both the kinase and phorbol ester-binding activities of PKC II and III were recovered following chromatography. Under the same conditions, the phorbol ester-binding activity of PKC I was also recovered, but the kinase activity was not. The phospholipid-induced inactivation of PKC apparently results from a direct interaction of phospholipid with the catalytic domain of PKC; this interaction can be suppressed by divalent cations. In the presence of divalent cations, PS interacted preferentially with the regulatory domain of PKC and resulted in the activation of the kinase.

The mechanism of protein kinase C activation

Protein kinase C (PKC) consists of a family of closely related enzymes highly concentrated in the CNS. These enzymes respond to the second messengers calcium (Ca2+) and diacylglycerol (DAG), to express their activities at membrane locations. Each member of this enzyme family displays distinct biochemical characteristics and is enriched in different cellular and subcellular locations. Activation of PKC in the nervous system has been implicated in the regulation of neurotransmitter release, ion channels, growth and differentiation, and neural plasticity. It is believed that an increase in the intracellular concentration of Ca2+ triggers the association of a group of PKC isozymes with the membrane where DAG interacts with PKC to stimulate the enzyme activity. Stimulation of PKC at the cellular membrane is, therefore, dependent upon the duration and magnitude of the DAG signal. The association of PKC with the membrane may also lead to a conversion of the enzyme into an effector-independent form for a sustained activation after the Ca2+ and DAG signals dissipate. Activation of PKC results in the phosphorylation of cellular proteins; however, the physiological substrates of this enzyme in the nervous system are still poorly characterized.

Reduced protein kinase C immunoreactivity and altered protein phosphorylation in Alzheimer's disease fibroblasts

Abnormal protein kinase C levels and protein kinase C-dependent phosphorylation are biochemical alterations in brain tissue obtained from patients with Alzheimer's disease. Because many biochemical and biophysical abnormalities are found in peripheral tissues of patients with Alzheimer's disease, we studied protein kinase C levels and the in vitro phosphorylation of proteins under protein kinase C-activating conditions in fibroblasts derived from patients with Alzheimer's disease. The concentration of protein kinase C-like immunoreactivity was reduced in Alzheimer's disease samples, although the protein kinase C activity determined by the phosphorylation of exogenous histone was not. The degree of in vitro phosphorylation of an Mr 79,000 protein in the presence of protein kinase C activators was less in Alzheimer's disease than in control fibroblast cytosol, and a reduction was more prominent in cases of familial Alzheimer's disease than in sporadic Alzheimer's disease. Therefore, the aberrant phosphorylation mediated by protein kinase C is found not only in the brain but also in fibroblasts.

Studies of protein kinase C in the rat basophilic leukemia (RBL-2H3) cell reveal that antigen-induced signals are not mimicked by the actions of phorbol myristate acetate and Ca2+ ionophore

Exogenous activators of protein kinase C such as PMA in combination with a Ca2+ ionophore (A23187), cause secretion in rat basophilic (RBL-2H3) cells,but they do so through stimulatory signals that are not the same as those generated by Ag or oligomers of IgE. On the one hand, the synergy between PMA and A23187 and the suppression of Ag-mediated signals (hydrolysis of inositol phospholipids and rise in concentration of cytosolic Ca2+) by PMA were totally dependent on protein kinase C. The loss of synergistic and inhibitory actions of PMA, for example, correlated with the loss of protein kinase C (as determined by immunoblotting techniques) when cells were continuously exposed to PMA. Furthermore, the permeabilization of RBL-2H3 cells resulted in the loss of both protein kinase C and the inhibitory action of PMA, but both were retained if cells were exposed to PMA before permeabilization Ag-induced secretion, on the other hand, was not as dependent on the presence of protein kinase C. The potent inhibitor of this enzyme, staurosporine, which blocked completely the secretory response to the combination of PMA and A23187, did not inhibit Ag-induced secretion except at concentrations (greater than 10 nM) that inhibited Ag-stimulated hydrolysis of inositol phospholipids as well. Also RBL-2H3 cells still showed some secretory-response (approximately 25% of normal) to Ag when cells were depleted (greater than 98%) of protein kinase C by prolonged treatment with PMA. Previous studies have indicated that the secretory response to PMA and A23187 is much lower than that elicited by Ag when the concentrations of stimulants were matched to give the same increase in concentrations of cytosolic Ca2+.

Studies of protein kinase C in the rat basophilic leukemia (RBL-2H3) cell reveal that antigen-induced signals are not mimicked by the actions of phorbol myristate acetate and Ca2+ ionophore

Exogenous activators of protein kinase C such as PMA in combination with a Ca2+ ionophore (A23187), cause secretion in rat basophilic (RBL-2H3) cells,but they do so through stimulatory signals that are not the same as those generated by Ag or oligomers of IgE. On the one hand, the synergy between PMA and A23187 and the suppression of Ag-mediated signals (hydrolysis of inositol phospholipids and rise in concentration of cytosolic Ca2+) by PMA were totally dependent on protein kinase C. The loss of synergistic and inhibitory actions of PMA, for example, correlated with the loss of protein kinase C (as determined by immunoblotting techniques) when cells were continuously exposed to PMA. Furthermore, the permeabilization of RBL-2H3 cells resulted in the loss of both protein kinase C and the inhibitory action of PMA, but both were retained if cells were exposed to PMA before permeabilization Ag-induced secretion, on the other hand, was not as dependent on the presence of protein kinase C. The potent inhibitor of this enzyme, staurosporine, which blocked completely the secretory response to the combination of PMA and A23187, did not inhibit Ag-induced secretion except at concentrations (greater than 10 nM) that inhibited Ag-stimulated hydrolysis of inositol phospholipids as well. Also RBL-2H3 cells still showed some secretory-response (approximately 25% of normal) to Ag when cells were depleted (greater than 98%) of protein kinase C by prolonged treatment with PMA. Previous studies have indicated that the secretory response to PMA and A23187 is much lower than that elicited by Ag when the concentrations of stimulants were matched to give the same increase in concentrations of cytosolic Ca2+.

Expression and function of protein kinase C isozymes

Three protein kinase C (PKC) isozymes, type I, II, and III, have been identified as the major Ca2+/phospholipid-stimulated protein kinases in the various animal tissues. Based on the immunochemical analysis it was demonstrated that PKC I was encoded by gamma cDNA, PKC II by the alternatively spliced beta I and beta II cDNAs, and PKC III by alpha cDNA. The expression of these enzymes appears to be tissue-specific and developmentally regulated. The central nervous system expresses high level of all three isozymes and the peripheral tissues mainly PKC II and III. During brain development, the expression of PKC I appears to follow the progress of synaptogenesis, whereas PKC II and III increase progressively from fetus up to 2-3 weeks of age. The level of PKC I in adult brain is highest in the cerebellum, hippocampus, amygdala, and cerebral cortex especially in those cortical regions being important for visual information processing and storage. The role of PKC II and III in cellular regulation was investigated by treatment of rat basophilic leukemia cells with the phorbol ester, phorbol 12-myristate 13-acetate. This phorbol ester caused a faster degradation of PKC II than III, indicating a differential down-regulation of these two enzymes by this compound. The results presented in this study support the contention that each species of PKC has a distinct function in the regulation of a variety of cellular processes.

Phosphorylation of human interleukin-2 (IL-2)

Human interleukin-2 (IL-2) is a lymphokine which is capable of activating lymphocytes and supporting the long-term in vitro growth of activated T cell clones. Recombinant human IL-2, expressed in either E. coli or cos cells, was shown to be phosphorylated by protein kinase C. Phosphorylated IL-2 synthesized in E. coli was analyzed by SDS-PAGE, reverse phase HPLC, and tryptic peptide mapping. The phosphorylated tryptic peptide was identified as the N-terminal fragment containing a single phosphorylation site at the serine residue at position 7. There was no difference in biological activity between non-phosphorylated and phosphorylated IL-2, as determined by a T cell growth assay. Although the physiological role of phosphorylation of IL-2 is unclear, IL-2 can be labeled with [gamma-32P] ATP and protein kinase C to a high specific radioactivity, and the synthesis of biologically active 32p-labeled IL-2 may be useful for receptor-binding studies of the cells containing low level of phosphoprotein phosphotases.

Type I protein kinase C isozyme in the visual-information-processing pathway of monkey brain

Previously using PKC isozyme-specific antibodies for immunoblot analysis, we demonstrated the heterogeneous distribution of PKC isozymes in various regions of monkey and rat brains and that type I PKC was most abundant in cerebellum, hippocampus, amygdala, and cerebral cortex (Huang et al.: J Biol Chem 262:15714-15720, 1987). Using these antibodies, we have also demonstrated that type I, II, and III PKC are products of PKC genes gamma, beta, and alpha, respectively (Huang et al.: Biochem Biophys Res Commun 149:946-952, 1987). By immunocytochemical analysis, type I PKC-specific antibody showed strong reactivity in various types of neuron in hippocampal formation, amygdala, cerebellum, and neocortex. In hippocampal formation, granule cells of dentate gyrus and pyramidal cells of hippocampus were heavily stained. By immunoblot analysis, relative levels of PKC isozymes in several areas of monkey cerebral cortex involved in the visual information processing and storage were determined. Both type II and III PKCs appeared to be evenly distributed and at moderate levels, type I PKC formed a gradient of increasing concentration rostral along the cerebral cortex of occipital to temporal and then to the limbic areas. Neurobehavioral studies have demonstrated that the neocortical and limbic areas of the anterior and medial temporal regions participate more directly than the striate, prestriate, and posterior temporal regions in the storage of visual representations and that both hippocampus and amygdala are important in the memory formation. As type I PKC is present at high levels in hippocampus, amygdala, and anterior temporal lobe, we predict that the type I protein kinase C may participate in the plastic changes important for mnemonic function.

Differential down-regulation of protein kinase C isozymes

Types I, II, and III protein kinase C have been shown to be products of, respectively, gamma, beta, and alpha genes of this enzyme family (Huang, F. L., Yoshida, Y., Nakabayashi, H., Knopf, J. L., Young, W. S., III, and Huang, K.-P. (1987) Biochem. Biophys. Res. Commun. 149, 946-952). Incubation of the highly purified rat brain protein kinase C isozymes with trypsin (kinase/trypsin (w/w) = 100) under identical conditions results in a preferential degradation of types I and II enzymes, whereas the type III enzyme was relatively resistant to tryptic proteolysis. Degradation of the type III enzyme by trypsin could be facilitated with the addition of Ca2+, phosphatidylserine, and dioleoylglycerol; none of these components alone was effective. Limited proteolysis of the three protein kinase C isozymes generated distinctive fragments for each isozyme, indicating that each isozyme has different trypsin-sensitive sites. Tryptic digestion of the type III protein kinase C was used as a model to determine the effects of various modulators on protein kinase C degradation. While Ca2+ and phosphatidylserine together were sufficient to convert the type III protein kinase C from a trypsin-insensitive to a -sensitive form, addition of dioleoylglycerol greatly reduced the Ca2+ requirement for such a conversion. Among the various phospholipids tested, in the presence of either dioleoylglycerol or phorbol ester, phosphatidylserine, cardiolipin, and phosphatidic acid were the most effective, and phosphatidylcholine and phosphatidylethanolamine were the least effective in supporting the digestion of type III protein kinase. Other acidic phospholipids, such as lysophosphatidylserine and phosphatidylinositol, were also effective in supporting the degradation in the presence of phorbol ester but not in the presence of dioleoylglycerol. The relevance of these proteolytic reactions to physiological responses was assessed with phorbol ester on rat basophilic leukemia RBL-2H3 cells, which contained both types II and III protein kinase C. Immunoblot analysis with the isozyme-specific antibodies revealed that phorbol ester induced a faster degradation of type II than that of type III isozyme in these cells. The results demonstrate that the various protein kinase C isozymes have different susceptibilities to proteolysis in vitro, when tested with trypsin, as well as to endogenous proteases in intact cells.

Protein kinase C located in rat liver nuclei. Partial purification and biochemical and immunochemical characterization

In the rat liver homogenate, maximal protein kinase C activity was found at two calcium concentrations (1.75 and 3.5 mM). Subcellular fractionation of the liver homogenate revealed that the protein kinase C activity requiring 1.75 mM calcium was present only in the cytosolic and particulate subcellular fractions. The protein kinase C activity requiring 3.5 mM calcium concentration was mainly located in the rat liver nuclei preparation. About 19% of the liver homogenate protein kinase C activity requiring 3.5 mM calcium was present in the nuclei. Goat anti-rat brain protein kinase C antibodies revealed a single immunoreactive band at 80-82 kDa in the rat liver nuclear, particulate, or cytosolic fractions. Based on the ratio of plasma membrane marker enzyme activity determined in the nuclear preparation, the purity of the isolated nuclei was ascertained. Rat liver nuclear protein kinase C activity has been partially purified. The purification steps sequentially employed were Triton X-100 extraction of isolated nuclei, DEAE-cellulose chromatography, Phenyl-Superose, and Mono Q (fast protein liquid) chromatography. The final purification step revealed, by silver nitrate staining on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, two protein bands at 80 and 66 kDa, respectively. These findings provide definitive data regarding the nuclear location of protein kinase C. The nuclear location of protein kinase C may lead to an understanding of the molecular pathway involved in signal transduction from the plasma membrane to the nucleus.