Association of the beta isoform of protein kinase C with vimentin filaments.

Protein kinase C (PKC) isoforms are key mediators in hormone, growth factor, and neurotransmitter triggered pathways of cell activation (Nishizuka: Science 233:305-312, 1986; Nature 334:661-665, 1988). Stimulation of kinase activity by diacylglycerol and calcium often leads to translocation of PKC from the cytosol to a particulate fraction (Kraft and Anderson: Nature 301:621-623, 1983). The beta isoform of PKC is translocated and degraded much more rapidly than the alpha isoform in phorbolester-stimulated rat basophilic leukemia (RBL) cells (Huang et al.: J. Biol. Chem. 264:4238-4243, 1989). We report here immunofluorescence evidence that the distributions of PKC alpha and beta are strikingly different in antigen-activated RBL cells. PKC beta associates with perinuclear filaments and filaments that extend from the perinuclear area to the cell periphery whereas PKC alpha concentrates in regions of the cell periphery. This distribution of PKC beta is distinctly different from that of actin filaments and microtubules as determined by phalloidin staining and by anti-tubulin antibody labeling. In contrast, the staining patterns obtained with antibodies to PKC beta and to the intermediate filament protein vimentin are almost identical, indicating that PKC beta associates with vimentin filaments. These bundles of 100 A filaments may provide docking sites for interactions of PKC beta with its substrates and thus confer specificity to the actions of this isoform.     

Neuron-specific protein F1/GAP-43 shows substrate specificity for the beta subtype of protein kinase C

We determined whether the beta or gamma protein kinase C (PKC) subtypes implicated in long-term potentiation (LTP) selectively regulates protein F1 phosphorylation. Purified bovine PKC subtypes and recombinant PKC subtypes activated by phosphatidylserine (PS) and calcium were tested for their relative ability to phosphorylate purified rat protein F1 (a.k.a. GAP-43). After equalizing enzyme activity against histone, the recombinant beta II PKC phosphorylated protein F1 to a 6 fold greater extent than the recombinant gamma PKC. Bovine beta I PKC phosphorylated protein F1 to a 3 fold greater extent than bovine gamma PKC. Even when PS was replaced by lipoxin B4, which can selectively increase gamma PKC activity, beta I PKC was still superior to gamma PKC in phosphorylating protein F1. Taken together with previous cellular studies of brain showing parallel levels of expression of beta PKC mRNA and protein F1 mRNA, the present results make it attractive to propose that beta PKC regulates protein F1 phosphorylation during the development of synaptic plasticity.     

Purification and characterization of protein kinase C epsilon from rabbit brain.

Protein kinase C epsilon was chromatographically purified from rabbit brain to electrophoretic homogeneity. We identified the enzyme as the epsilon species of novel-type protein kinase C (nPKC epsilon), originally discovered and defined by cDNA cloning [Ohno, S., et al. (1988) Cell 53, 731-741], on the basis of the following observations: (i) the enzyme reacts specifically with an antipeptidic antiserum to nPKC epsilon but not with antisera to any of the other molecular species of PKC thus far known; (ii) it exhibits enzymatic behavior essentially identical to that of a recombinant nPKC epsilon purified from transfected COS cells [Konno, Y., et al. (1989) J. Biochem. 106, 673-678] and distinct from that of conventional PKC (alpha, beta I/II, and gamma) in its dependence on magnesium concentration and cofactors such as phospholipids, calcium, and phorbol ester; and (iii) it has an apparent molecular weight of 95.7K +/- 0.4K on SDS-PAGE, significantly greater than the other conventional and novel PKCs thus far identified. Notably, calcium exhibits a complex effect, both positive and negative, on the kinase activity of epsilon depending on the kind of substrate and the coexisting phospholipid, calling for a modification of the current notion that epsilon is a kinase unresponsive to calcium. The amount of epsilon species in the brain was estimated to be comparable to that of each conventional species, indicating that epsilon stands as one of the major PKC family members in brain. Furthermore, the enzyme shows a broader substrate spectrum than conventional PKC when examined with endogenous substrates, implying that it may cover a wider or different range of physiological functions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Selective post-transcriptional down-regulation of protein kinase C isoenzymes in leukemic T cells chronically treated with phorbol ester

Binding to, and activation of, protein kinase C (PKC) by phorbol ester (PE) tumor promoters may underlie their tumor-promoting activity. To study the effects of long-term PE treatment on regulation of cellular PKC, we adapted the human leukemic T cell line, Jurkat (JK), to continuous growth in the presence of PE. Such cells (JKPE) displayed loss of CD2 and CD3 cell surface molecules, known to play an important role in agonist-stimulated T cell activation, unresponsiveness to stimuli that induce interleukin 2 (IL2) receptor expression or IL2 production, change in the expression of several cell cycle-regulated genes, and a 6-fold reduction in cellular PKC enzymatic activity. This reduction was accompanied by the disappearance of a major approximately 82-kDa immunoreactive protein in JKPE cytosol when cell extracts were immunoblotted with a polyclonal anti-PKC peptide antibody cross-reactive with the PKC isoenzymes, alpha, beta, and gamma. Analysis with additional anti-peptide antibodies specific for alpha, beta, or gamma PKC indicated that all three types of PKC are expressed in JK cells; however, JKPE cells lost a major approximately 82 kDa immunoreactive cytosolic protein detectable with anti-PKC alpha antibody. In contrast, levels of expression and subcellular distribution of immunoreactive PKC beta and PKC gamma, as well as levels of mRNA specific for the three PKC isoenzymes, were not significantly affected by chronic PE treatment. These results indicate that PE-mediated reduction of PKC in JKPE cells is selective and occurs at the protein, not mRNA, level, and support the notion that distinct isoenzymes encoded by the PKC multigene family may be independently regulated. Moreover, the correlation between phenotypic and functional changes on one hand, and the selective reduction of PKC alpha on the other, raises the possibility that expression of CD2 and/or CD3 and functional activation in JKPE cells are preferentially regulated by PKC alpha.     

Purification and characterization of the zeta isoform of protein kinase C from bovine kidney.

The zeta isoform of protein kinase C (PKC zeta) was purified to near homogeneity from the cytosolic fraction of bovine kidney by successive chromatography on DEAE-Sephacel, heparin-Sepharose, phenyl-5PW, hydroxyapatite, and Mono Q. The purified enzyme had a molecular mass of 78 kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The protein was recognized by an antibody raised against a synthetic oligopeptide corresponding to the deduced amino acid sequence of rat PKC zeta. The enzymatic properties of PKC zeta were examined and compared with conventional protein kinase C purified from rat brain. The activity of PKC zeta was stimulated by phospholipid but was unaffected by phorbol ester, diacylglycerol, or Ca2+. PKC zeta did not bind phorbol ester, and autophosphorylation was not affected by phorbol ester. Unsaturated fatty acid activated PKC zeta, but this activation was neither additive nor synergistic with phospholipid. These results indicate that regulation of PKC zeta is distinct from that of other isoforms and suggest that hormone-stimulated increases in diacylglycerol and Ca2+ do not activate this isoform in cells. It is possible that PKC zeta belongs to another enzyme family, in which regulation is by a different mechanism from that for other isoforms of protein kinase C.     

Tissue and cellular distribution of the extended family of protein kinase C isoenzymes

Polyclonal isoenzyme-specific antisera were developed against four calcium-independent protein kinase C (PKC) isoenzymes (delta, epsilon, epsilon', and zeta) as well as the calcium-dependent isoforms (alpha, beta I, beta II, and gamma). These antisera showed high specificities, high titers, and high binding affinities (3-370 nM) for the peptide antigens to which they were raised. Each antiserum detected a species of the predicted molecular weight by Western blot that could be blocked with the immunizing peptide. PKC was sequentially purified from rat brain, and the calcium-dependent forms were finally resolved by hydroxyapatite chromatography. Peak I reacted exclusively with antisera to PKC gamma, peak II with PKC beta I and -beta II, and peak III with PKC alpha. These same fractions, however, were devoid of immunoreactivity for the calcium-independent isoenzymes. The PKC isoenzymes demonstrated a distinctive tissue distribution when evaluated by Western blot and immunocytochemistry. PCK delta was present in brain, heart, spleen, lung, liver, ovary, pancreas, and adrenal tissues. PKC epsilon was present in brain, kidney, and pancreas, whereas PKC epsilon' was present predominantly in brain. PKC zeta was present in most tissues, particularly the lung, brain, and liver. Both PKC delta and PKC zeta showed some heterogeneity of size among the different tissues. PKC alpha was present in all organs and tissues examined. PKC beta I and -beta II were present in greatest amount in brain and spleen. Although the brain contained the most PKC gamma immunoreactivity, some immunostaining was also seen in adrenal tissue. These studies provide the first evidence of selective organ and tissue distributions of the calcium-independent PKC isoenzymes.     

Lack of constitutive activity of the free kinase domain of protein kinase C zeta. Dependence on transphosphorylation of the activation loop

Following the induction of apoptosis in mammalian cells, protein kinase C zeta (PKC zeta) is processed between the regulatory and catalytic domains by caspases, which increases its kinase activity. The catalytic domain fragments of PKC isoforms are considered to be constitutively active, because they lack the autoinhibitory amino-terminal regulatory domain, which includes a pseudosubstrate segment that plugs the active site. Phosphorylation of the activation loop at Thr(410) is known to be sufficient to activate the kinase function of full-length PKC zeta, apparently by inducing a conformational change, which displaces the amino-terminal pseudosubstrate segment from the active site. Amino acid substitutions for Thr(410) of the catalytic domain of PKC zeta (CAT zeta) essentially abolished the kinase function of ectopically expressed CAT zeta in mammalian cells. Similarly, substitution of Ala for a Phe of the docking motif for phosphoinositide-dependent kinase-1 prevented activation loop phosphorylation and abolished the kinase activity of CAT zeta. Treatment of purified CAT zeta with the catalytic subunit of protein phosphatase 1 decreased activation loop phosphorylation and kinase activity. Recombinant CAT zeta from bacteria lacked detectable kinase activity. Phosphoinositide-dependent kinase-1 phosphorylated the activation loop and activated recombinant CAT zeta from bacteria. Treatment of HeLa cells with fetal bovine serum markedly increased the phosphothreonine 410 content of CAT zeta and stimulated its kinase activity. These findings indicate that the catalytic domain of PKC zeta is intrinsically inactive and dependent on the transphosphorylation of the activation loop.     

Locally generated methylseleninic acid induces specific inactivation of protein kinase C isoenzymes: relevance to selenium-induced apoptosis in prostate cancer cells

In this study, we show that methylselenol, a selenometabolite implicated in cancer prevention, did not directly inactivate protein kinase C (PKC). Nonetheless, its oxidation product, methylseleninic acid (MSA), inactivated PKC at low micromolar concentrations through a redox modification of vicinal cysteine sulfhydryls in the catalytic domain of PKC. This modification of PKC that occurred in both isolated form and in intact cells was reversed by a reductase system involving thioredoxin reductase, a selenoprotein. PKC isoenzymes exhibited variable sensitivity to MSA with Ca(2+)-dependent PKC isoenzymes (alpha, beta, and gamma) being the most susceptible, followed by isoenzymes delta and epsilon. Other enzymes tested were inactivated only with severalfold higher concentrations of MSA than those required for PKC inactivation. This specificity for PKC was further enhanced when MSA was generated within close proximity to PKC through a reaction of methylselenol with PKC-bound lipid peroxides in the membrane. The MSA-methylselenol redox cycle resulted in the catalytic oxidation of sulfhydryls even with nanomolar concentrations of selenium. MSA inhibited cell growth and induced apoptosis in DU145 prostate cancer cells at a concentration that was higher than that needed to inhibit purified PKC alpha but in a range comparable with that required for the inhibition of PKC epsilon. This MSA-induced growth inhibition and apoptosis decreased with a conditional overexpression of PKC epsilon and increased with its knock-out by small interfering RNA. Conceivably, when MSA is generated within the vicinity of PKC, it specifically inactivates PKC isoenzymes, particularly the promitogenic and prosurvival epsilon isoenzyme, and this inactivation causes growth inhibition and apoptosis.     

The identification and purification of a mammalian-like protein kinase C in the yeast Saccharomyces cerevisiae.

We have purified a yeast protein kinase that is phospholipid-dependent and activated by Diacylglycerol (DAG) in the presence of Ca2+ or by the tumour-promoting agent tetradecanoyl-phorbol acetate (TPA). The properties of this enzyme are similar to those of the mammalian protein kinase C (PKC). The enzyme was purified using chromatography on DEAE-cellulose followed by hydroxylapatite. The latter chromatography separated the activity to three distinguishable sub-species, analogous to the mammalian PKC isoenzymes. The fractions enriched in PKC activity contain proteins that specifically bind TPA, are specifically phosphorylated in the presence of DAG and recognized by anti-mammalian PKC antibodies.     

Down-regulation of protein kinase C in Swiss 3T3 fibroblasts is independent of its phosphorylating activity

The phorbol ester TPA induces down-regulation of protein kinase C (PKC) in Swiss-3T3 fibroblasts, as determined by the use of an alpha, beta, gamma PKC-specific antiserum. PKC is almost completely degraded 10 hours after TPA treatment of the cells and recovers within 72 hours. The staurosporine derivative K252a, known to inhibit PKC activity, causes strong suppression of TPA-induced (PKC-catalyzed) protein phosphorylation in Swiss-3T3 cells. Inhibition of protein phosphorylation by K252a is still effective when the process of down-regulation is completed. However, K252a does not influence TPA-induced down-regulation of PKC at all. Thus, down-regulation of PKC is not dependent on the enzyme's phosphorylating activity and, therefore, most likely not on its autophosphorylation as has been suggested by Ohno et al. [J. Biol. Chem. 265, 6296-6300 (1990)].     

Phosphorylation of membrane-bound acetylcholine receptor by protein kinase C: characterization and subunit specificity

Acetylcholine receptor (AChR) from Torpedo electric organ in its membrane-bound or solubilized form is phosphorylated by the Ca2+/phospholipid-dependent protein kinase (PKC). The subunit specificity for PKC is different from that observed for cAMP-dependent protein kinase (PKA). Whereas PKC phosphorylates predominantly the delta subunit and the phosphorylation of the gamma subunit by this enzyme is very low, PKA phosphorylates both subunits to a similar high extent. We have extended our phosphorylation studies to a synthetic peptide from the gamma subunit, corresponding to residues 346-359, which contains a consensus PKA phosphorylation site. This synthetic peptide is phosphorylated by both PKA and PKC, suggesting that in the intact receptor both kinases may phosphorylate the gamma subunit at a similar site, as has been previously demonstrated by us for the delta subunit [Safran, A., et al. (1987) J. Biol. Chem. 262, 10506-10510]. The diverse pattern of phosphorylation of AChR by PKA and PKC may play a role in the regulation of its function.     

Expression and activity of protein kinase C isoenzymes during normal and abnormal murine palate development

Protein kinase C (PKC) plays a critical role in signal transduction, mediating various cellular events critical for normal development, including that of the palate. In vivo and in vitro studies suggest the relevance of the inhibition of PKC by the mycotoxin, secalonic acid D (SAD), to its induction of cleft palate (CP) in mice. In the present study, temporal and spatial expression and the activity of various PKC isoenzymes were studied in the control and SAD-exposed murine embryonic palate during gestational days (GD) 12-14.5 by western blotting, immunohistochemistry, and phosphotransfer assay. The Ca2+-dependent isoenzymes, PKC alpha and PKC betaII, showed significant expression on GD 12.0, which gradually decreased through GD 14.5, whereas PKC betaI and PKC gamma were negligible throughout. All Ca2+-independent isoenzymes (epsilon, delta, and zeta) were expressed more abundantly and, in contrast to the Ca2+-dependent ones, progressively increased with age. SAD failed to alter this pattern of expression but enhanced the phosphorylation of PKC epsilon throughout development. Immunohistochemical analysis revealed an isoenzyme-specific distribution of PKC between the epithelium and mesenchyme. As expected, SAD significantly inhibited the total Ca2+-dependent PKC activity in palatal extracts. Although total Ca2+-independent PKC activity in palatal extracts was unaffected by SAD, individual pure isoenzymes were either selectively inhibited (PKC zeta), stimulated (PKC delta), or unaffected (PKC epsilon) by SAD. These results show that PKC isoenzymes exhibit dynamic temporal and spatial patterns of expression and activity in the developing palate and that the induction of CP by SAD is associated with an alteration in their activation and/or activity.     

Isoenzyme-specific translocation of protein kinase C (PKC)betaII and not PKCbetaI to a juxtanuclear subset of recycling endosomes: involvement of phospholipase D

Elucidation of isoenzyme-specific functions of individual protein kinase C (PKC) isoenzymes has emerged as an important goal in the study of this family of kinases, but this task has been complicated by modest substrate specificity and high homology among the individual members of each PKC subfamily. The classical PKCbetaI and PKCbetaII isoenzymes provide a unique opportunity because they are the alternatively spliced products of the beta gene and are 100% identical except for the last 50 of 52 amino acids. In this study, it is shown that green fluorescent protein-tagged PKCbetaII and not PKCbetaI translocates to a recently described juxtanuclear site of localization for PKCalpha and PKCbetaII isoenzymes that arises with sustained stimulation of PKC. Mechanistically, translocation of PKCbetaII to the juxtanuclear region required kinase activity. PKCbetaII, but not PKCbetaI, was found to activate phospholipase D within this time frame. Inhibitors of phospholipase D (1-butanol and a dominant negative construct) prevented the translocation of PKCbetaII to the juxtanuclear region but not to the plasma membrane, thus demonstrating a role for phospholipase D in the juxtanuclear translocation of PKCbetaII. Taken together, these results define specific biochemical and cellular actions of PKCbetaII when compared with PKCbetaI.     

蛋白激酶C同工酶分子结构及功能研究进展

蛋白激酶Ｃ（ＰＫＣ）是至少包括１１种亚型在内的丝／苏氨酸蛋白激酶家族,可分为传统型（ｃＰＫＣｓ）、新型（ｎＰＫＣｓ）、非典型（ａＰＫＣｓ）和ＰＫＣ－ｕ四大类。各ＰＫＣ亚型在ＡＴＰ结合位点、磷脂酰基转移位点、假性底物位点、佛波酯结合位点的氨基酸序列既高度保守又有变异。ＰＫＣ在机体内分布和作用十分广泛,本文主要介绍了ＰＫＣ在肿瘤形成、侵润和转移及肿瘤耐药性产生,调节造血干／祖细胞定向分化成熟,以及激素     

Intracellular redistribution of protein kinase D2 in response to G-protein-coupled receptor agonists

The protein kinase D (PKD) family consists of three serine/threonine protein kinases: PKC mu/PKD, PKD2, and PKC nu/PKD3. While PKD has been the focus of most studies to date, no information is available on the intracellular distribution of PKD2. Consequently, we examined the mechanism that regulates its intracellular distribution in human pancreatic carcinoma Panc-1 cells. Analysis of the intracellular steady-state distribution of fluorescent-tagged PKD2 in unstimulated cells indicated that this kinase is predominantly cytoplasmic. Cell stimulation with the G protein-coupled receptor agonist neurotensin induced a rapid and reversible plasma membrane translocation of PKD2 by a mechanism that requires PKC activity. In contrast to the other PKD isoenzymes, PKD2 activation did not induce its redistribution from the cytoplasm to the nucleus. Thus, this study demonstrates that the regulation of the distribution of PKD2 is distinct from other PKD isoenzymes, and suggests that the differential spatio-temporal localization of these signaling molecules regulates their specific signaling properties.     

Differential inhibition of protein kinase C subtypes

Catalytic properties of protein kinase C isoforms purified from rat brain and bovine adrenocortical tissues were examined. The results showed that known inhibitors of PKC activity such as gossypol and H-7 were active on all the three isolated enzyme isoforms with similar IC50 values. However, whereas the type III brain isozyme activity was not affected by a preincubation with phosphatidylserine (PS), the same treatment resulted in a virtually complete loss of the type I and II isoform activities within 4 min at 30 degrees. This kinase inactivation caused by PS preincubation was prevented in the presence of ATP-Mg2+ or its competitive inhibitor H-7. These findings indicate that the type III isoform can clearly be distinguished from the other members of the PKC family by this specific property. This approach was used to confirm the characterization of the single form of PKC detected in bovine adrenocortical tissue as a type III isotype. This specific behavior toward phosphatidylserine suggests that the molecular organization of the phospholipid sensitive, regulatory domain of the PKC isoform III with regard to its catalytic site and thus its mechanism of activation may differ from that of other PKC isotypes.     

Signalling by protein kinase C isoforms in the heart

Understanding transmembrane signalling process is one of the major challenge of the decade. In most tissues, since Fisher and Krebs's discovery in the 1950's, protein phosphorylation has been widely recognized as a key event of this cellular function. Indeed, binding of hormones or neurotransmitters to specific membrane receptors leads to the generation of cytosoluble second messengers which in turn activate a specific protein kinase. Numerous protein kinases have been so far identified and roughly classified into two groups, namely serine/threonine and tyrosine kinases on the basis of the target amino acid although some more recently discovered kinases like MEK (or MAP kinase kinase) phosphorylate both serine and tyrosine residues.Protein kinase C is a serine/threonine kinase that was first described by Takai et al. [1] as a Ca- and phospholipid-dependent protein kinase. Later on, Kuo et al. [2] found that PKC was expressed in most tissues including the heart. The field of investigation became more complicated when it was found that the kinase is not a single molecular entity and that several isoforms exist. At present, 12 PKC isoforms and other PKC-related kinases [3] were identified in mammalian tissues. These are classified into three groups. (1) the Ca-activated -, -,and -PKCs which display a Ca-binding site (C2); (2) the Ca-insensitive -, -, -, -, and -PKCs. The kinases that belong to both of these groups display two cystein-rich domains (C1) which bind phorbol esters (for recent review on PKC structure, see [4]). (3) The third group was named atypical PKCs and include , , and -PKCs that lack both the C2 and one cystein-rich domain. Consequently, these isoforms are Ca-insensitive and cannot be activated by phorbol esters [5]. In the heart. evidence that multiple PKC isoforms exist was first provided by Kosaka et al. [6] who identified by chromatography at least two PKC-related isoenzymes. Numerous studies were thus devoted to the biochemical characterization of these isoenzymes (see [7] for review on cardiac PKCs) as well as to the identification of their substrates.This overview aims at updating the present knowledge on the expression, activation and functions of PKC isoforms in cardiac cells. (Mol Cell Biochem 157: 65–72, 1996)     

A specific requirement for protein kinase C in activation of the respiratory burst oxidase of fertilization

Partially reduced oxygen species are toxic, yet activated sea urchin eggs produce H2O2, suggesting that the control of oxidant stress might be critical for early embryonic development. We show that the Ca2(+)-stimulated NADPH oxidase that generates H2O2 in the "respiratory burst" of fertilization is activated by a protein kinase, apparently to regulate the synthesis of this potentially lethal oxidant. The NADPH oxidase was separated into membrane and soluble fractions that were both required for H2O2 synthesis. The soluble fraction was further purified by anion exchange chromatography. The factor in the soluble fraction that activated the membrane-associated oxidase was demonstrated to be protein kinase C (PKC) by several criteria, including its Ca2+/phophatidylserine/diacyl-glycerol-stimulated histone kinase activity, its response to phorbol ester, its inhibition by a PKC pseudosubstrate peptide, and its replacement by purified mammalian PKC. Neither calmodulin-dependent kinase II, the catalytic subunit of cyclic AMP-dependent protein kinase, casein kinase II, nor myosin light chain kinase activated the oxidase. Although the PKC family has been ubiquitously implicated in cellular regulation, enzymes that require PKC for activation have not been identified; the respiratory burst oxidase is one such enzyme.     

Novel yeast protein kinase (YPK1 gene product) is a 40-kilodalton phosphotyrosyl protein associated with protein-tyrosine kinase activity.

Extracts of bakers' yeast (Saccharomyces cerevisiae) contain protein-tyrosine kinase activity that can be detected with a synthetic Glu-Tyr copolymer as substrate (G. Schieven, J. Thorner, and G.S. Martin, Science 231:390-393, 1986). By using this assay in conjunction with ion-exchange and affinity chromatography, a soluble tyrosine kinase activity was purified over 8,000-fold from yeast extracts. The purified activity did not utilize typical substrates for mammalian protein-tyrosine kinases (enolase, casein, and histones). The level of tyrosine kinase activity at all steps of each preparation correlated with the content of a 40-kDa protein (p40). Upon incubation of the most highly purified fractions with Mn-ATP or Mg-ATP, p40 was the only protein phosphorylated on tyrosine. Immunoblotting of purified p40 or total yeast extracts with antiphosphotyrosine antibodies and phosphoamino acid analysis of 32P-labeled yeast proteins fractionated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that the 40-kDa protein is normally phosphorylated at tyrosine in vivo. 32P-labeled p40 immunoprecipitated from extracts of metabolically labeled cells by affinity-purified anti-p40 antibodies contained both phosphoserine and phosphotyrosine. The gene encoding p40 (YPK1) was cloned from a yeast genomic library by using oligonucleotide probes designed on the basis of the sequence of purified peptides. As deduced from the nucleotide sequence of YPK1, p40 is homologous to known protein kinases, with features that resemble known protein-serine kinases more than known protein-tyrosine kinases. Thus, p40 is a protein kinase which is phosphorylated in vivo and in vitro at both tyrosine and serine residues; it may be a novel type of autophosphorylating tyrosine kinase, a bifunctional (serine/tyrosine-specific) protein kinase, or a serine kinase that is a substrate for an associated tyrosine kinase.