Identification of type III protein kinase C in bovine aortic tissue

We identified a subtype of protein kinase C in bovine aortic tissue. In Western blots, both the soluble and the particulate fractions from the aorta reacted only with MC-3a. In the case of hydroxylapatite column chromatography, a single activity peak of protein kinase C from the soluble and the particulate fractions was obtained with about 140 mM of potassium phosphate, a finding similar to that with the Type III protein kinase C from rabbit brain. The sandwich-type enzyme immunoassay for protein kinase C, with which the contents of each protein kinase C isozyme can be determined in the crude extracts, revealed that the Type III bovine aortic protein kinase C included 25.9 ng/mg protein. These results strongly suggest that it is the Type III protein kinase C which is mainly expressed in aortic tissue. Kinetic parameters of the Type III protein kinase C of the soluble and the particulate fractions, with respect to the Km for ATP, were 33 and 15 microM and the Km values for myosin light chain from chicken gizzard were 6.3 and 4.6 microM, respectively.     

Differential localization of protein kinase C isozymes in retinal neurons

We report the immunohistochemical localization of protein kinase C isozymes (types I, II, and III) in the rabbit retina using the monospecific monoclonal antibodies MC-1a, MC-2a, and MC-3a. Using immunoblot analysis of partially purified protein kinase C preparations of rabbit retina, types II and III isozymes alone were detected. The activity of type III was the stronger. By light microscopic immunohistochemical analysis, retinal neurons were negative for type I and positive for type II and type III isozymes. Type II was more diffusely distributed through the retinal layers, but was distinctive in ganglion cells, bipolar cells, and outer segments. The immunoreactivity was stronger for type III isozyme, and it was observed in mop (rod) bipolar cells and amacrine cells. By using immunoelectron microscopy, the cytoplasm of the cell body, the axon, and dendrites of the mop bipolar cells were strongly immunoreactive for type III. The so-called rod bipolar cells were for the first time seen to form synapses with rod photoreceptor cells. These differential localizations of respective isozymes in retinal neurons suggest that each isozyme has a different site of function in each neuron.     

Immunoaffinity purification of type I protein kinase C

We designed a simple procedure for the purification of type I protein kinase C, using immunoaffinity chromatography with a monoclonal antibody, MC-1b, obtained by rescreening hybridoma cells available for an affinity ligand. Western blotting demonstrated that MC-1b specifically reacted with type I protein kinase C, and the enzyme molecule dissociated from MC-1b-coupled Sepharose 4B with mild eluants such as thiocyanate retained the kinase activity. A 1148-fold purification was achieved and 210 micrograms of type I protein kinase C was obtained from three rabbit brains, by means of a two-step procedure, using DEAE-cellulose and immunoaffinity chromatography. The resultant preparation was homogeneous, as indicated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis hydroxylapatite chromatography, and immunological analysis using MC-1a, MC-2a, and MC-3a.     

Immunohistochemical evidence for the overexpression of protein kinase C in proliferative diseases of human thyroid.

We report immunohistochemical evidence for the overexpression of protein kinase C in various proliferative diseases of human thyroid. Immunohistochemical characterization of various surgically removed thyroid tissues, viz., cancer tissues: papillary carcinoma and follicular carcinoma; adenoma tissues: tubular, trabecular and colloid adenomas; adenomatous goiter; and normal thyroid was done using the monospecific monoclonal antibodies MC-1a, MC-2a and MC-3a, each of which is specific for types I, II and III isozymes of protein kinase C, respectively. For protein kinase C type II, a remarkable difference in staining intensity was noted between the cancerous and normal tissues. The cytoplasm of papillary and follicular carcinoma cells stained more intensely than that of normal thyroid cells. In the benign tumor and adenomatous goiter tissues, stronger staining was noted in the papilliform-proliferating portion and cubic epithelial cells. In the normal thyroid tissues, epithelial cells of greater height were more strongly stained than simple squamous epithelial cells. These results indicated that protein kinase C type II isozyme is expressed in larger amounts in cancerous and proliferative tissues of the human thyroid.     

Phosphorylation of aortic plasma membranes by protein kinase C

A calcium-sensitive, phospholipid-dependent protein kinase (protein kinase C) and its three isozymes were purified from rat heart cytosolic fractions utilizing a rapid purification method. The purified protein kinase C enzyme showed a single polypeptide band of 80 KDa on SDS-polyacrylamide gel electrophoresis, and was totally dependent on the presence of Ca²⁺ and phospholipid for activity. Diacylglycerol was also found to stimulate enzymatic activity. Autophosphorylation of the purified PKC showed an 80 KDa polypeptide. The identity of the purified protein was also verified with monoclonal antibodies specific for PKC. Further fractionation of the purified PKC on a hydroxylapatite column yielded three distinct peaks of enzyme activity, corresponding to type I, II and III based on similar chromatographic behaviour as the rat brain enzyme. All three forms were entirely Ca^2– and phosphatidylserine dependent. Type II was found to be the most abundant. Type I was found to be highly unstable. PKC activity studies demonstrate that types II and III isozymic forms are different with respect to their sensitivity to Ca²⁺.Abbreviations PKC Protein Kinase C - SDS Sodium Dodecyl Sulfate - PAGE Polyacrylamide Gel Electrophoresis - K_m Michaelis constant - NBT Nitro-Blue Tetrazolium - BCIP 5-Bromo-4-Chloro-3-Indolyl Phosphate     

Immunocytochemical detection of Ca2+-dependent subspecies of protein kinase C in mouse embryos before and during compaction

Summary To confirm the possibility that protein kinase C is involved in compaction of mouse embryos, the presence and distribution pattern of Ca²⁺-dependent subspecies of this enzyme in mouse embryos, before and during compaction, were examined immunocytochemically with three different monoclonal antibodies. These were MC-1a, MC-2a and MC-3a, which selectively interact with the subspecies of the enzyme known as types I, II and III, respectively. Only when embryos were incubated with MC-3a, was immunofluorescence clearly detected in all cells of embryos before and during compaction. This result demonstrates the presence of type III protein kinase C in embryos before and during compaction and suggests the possibility that the type III enzyme may be involved in compaction. No marked differences were found in the distribution pattern of the type III enzyme between embryos examined before and during compaction.     

Monoclonal antibody studies of the antigenic determinants of human plasma retinol-binding protein

A battery of monoclonal antibodies (MoAbs) against human retinol-binding protein (RBP) was produced to obtain useful probes for the study of the antigenic determinants of RBP. The 12 antibodies all reacted with human RBP by immunoblotting. Based on antibody cross-competition radioimmunoassays, four distinct and different groups of antibodies were identified: group I, 1A4 and 2F4; group II, 1G10, 5C5, 6F4, and 7G3; group III, 5H6, 6C7, 10G5, and 14E3; and group IV, 5H9 and 13A1. Information about the epitopes of RBP recognized by these MoAbs was obtained by testing the reactivity of each antibody with human, rabbit, and rat RBPs by immunoblotting. Group I and group IV antibodies reacted to a similar extent with human, rabbit, and rat RBPs. Group II antibodies reacted strongly with human and rabbit RBPs, but reacted very weakly with rat RBP. Group III antibodies reacted strongly with human RBP, but did not react with rabbit or rat RBP. Thus, the epitopes for group I and group IV antibodies appear to be regions of the RBP molecule that are conserved across the three species, whereas group III antibodies recognized only human RBP. In a preliminary study, the reactivity of each antibody with purified cyanogen bromide fragments of RBP was tested by slot immunoblotting. None of the MoAbs reacted with any of the cyanogen bromide fragments. This study shows that MoAbs specific for at least four different regions of the RBP molecule can be produced; hence, RBP contains at least four major antigenic domains.     

Three distinct forms of rat brain protein kinase C: differential response to unsaturated fatty acids

Although the three distinct forms of protein kinase C isolated from rat brain soluble fraction are structurally very similar, they respond differently to free unsaturated fatty acids such as arachidonic acid to exhibit their catalytic activity. Type I enzyme encoded by gamma-sequence, as predicted by cDNA clone analysis, responds to these fatty acids only slightly, whereas Type III enzyme determined by alpha-sequence is activated by free unsaturated fatty acids in the presence of Ca2+ in a comparable manner to phosphatidylserine plus diacylglycerol. Type II, a mixture of two enzymes encoded by beta I- and beta II-sequence, resulting from alternative splicing, shows properties in between those of Type I and Type III. Some of these forms of protein kinase C may function at a relatively later phase of cellular responses when large amounts of unsaturated fatty acids and Ca2+ are mobilized.     

Immunochemical detection of arachidonoyl-preferential phospholipase A2.

Monoclonal antibodies were raised against rabbit platelet cytosolic arachidonoyl-preferential phospholipase A2. The antibodies precipitated the arachidonoyl-preferential phospholipase A2 activity in the soluble fraction of a rabbit platelet lysate in combination with an immobilized anti-mouse immunoglobulin antibody, and reacted predominantly with a protein exhibiting a molecular weight of approximately 88,000 on immunoblotting analysis. All three antibodies established so far reacted with human platelet arachidonoyl-preferential phospholipase A2 as effectively as the rabbit platelet enzyme. One of them reacted with the rat platelet arachidonoyl-preferential enzyme, whereas none of them reacted with rabbit platelet secretory 14-kDa group II phospholipase A2. The existence of an immunologically related phospholipase A2 was further shown in rabbit granulocytes, brain, lung, and liver, rat and mouse mast cells, and human monocytoma U937 cells. Thus, an arachidonoyl-preferential phospholipase A2 with similar structural properties appeared to be expressed in a variety of cells and tissues.     

Mode of activation and kinetic properties of three distinct forms of protein kinase C from rat brain

Three types of protein kinase C, designated types I, II, and III, were purified from rat brain cytosol, and have been shown to correspond to the cDNA clones gamma, beta, and alpha, respectively. Their relative activities in the whole brain tissue were roughly 26, 49, and 25% with H1 histone as a substrate. Type II enzyme was an unequal mixture of two subspecies (roughly 1:7) encoded by beta I and beta II sequences which differ from each other only in a short range of their carboxyl-terminal end regions. Although the three types have closely similar structures, they showed slightly different modes of activation and kinetic properties. Type I enzyme was less sensitive to diacylglycerol but was significantly activated by low concentrations of free arachidonic acid. Type II enzyme exhibited substantial activity without elevated Ca2+ levels, and responded well to diacylglycerol and, to some extent, arachidonic acid. The type III enzyme responded to diacylglycerol as well as to arachidonic acid. The mode of activation of the enzyme by arachidonic acid required elevated levels of Ca2+ but not phospholipid. In the presence of phospholipid, phorbol esters could activate all three types in a manner similar to diacylglycerol. Among various phospholipids tested, phosphatidylserine was the most effective for all three types. Type III enzyme was most sensitive to 1-stearoyl-2-arachidonylglycerol for activation. Conversely, type I enzyme was activated most efficiently by synthetic permeable diacylglycerols, such as 1,2-didecanoylglycerol and 1,2-dioctanoylglycerol. Many heavy metal ions exerted variable and distinct effects on the catalytic activities of these three types.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence for the identity of nuclear and cytoplasmic adenosine-3':5'-monophosphate-dependent protein kinase from porcine ovaries and nuclear translocation of the cytoplasmic enzyme.

Protein phosphokinase activity from a 0.5 M NaCl extract of purified porcine ovary nuclei has been resolved by Sephadex G-200 gel filtration into three forms of kinase, protein kinase I and III, both independent of adenosine 3':5'-monophosphate (cyclic AMP), and cyclic-AMP-dependent protein kinase II. Cyclic AMP-binding activity was associated with protein kinase II but not with protein kinases I and III. Protein kinases I, II, and III exhibited different cyclic nucleotide dependency and substrate specificity. Protein kinase II was inhibited by a heat-stable protein from rabbit skeletal muscle, whereas protein kinases I and III were not inhibited. According to previously established criteria [Traugh, J.A., Ashby, C.D. and Walsh, D.A. (1974) nuclear protein kinase II can be classified as cyclic-AMP-dependent protein kinase consisting of regulatory and catalytic subunits. Nuclear protein kinases I and III are cyclic-AMP-independent enzymes. Evidence for the identity of nuclear cyclic-AMP-dependent protein kinase II with cytosol (105 000 X g supernatant fraction) cyclic-AMP-dependent protein kinase was obtained in several ways. Nuclear and cytosol cyclic-AMP-dependent protein kinases exhibited identical elution characteristics on DEAE-cellulose and Sephadex G-200 indicating that both kinases are of similar molecular size and possess similar ionic charge. Both kinases exhibited an identical Km for ATP of 8 muM, showed similar substrate specificity, and revealed similar antigenic properties. Cyclic-AMP-dependent protein kinase II was also identified in nuclei isolated in nonaqueous media, eliminating the possibility that the cyclic-AMP-dependent protein kinase activity identified in nuclei isolated in aqueous media may have arisen as the result of cytoplasmic contamination. After incubation of neonatal porcine ovaries which lack nuclear cyclic-AMP-dependent protein kinase with 0.1 muM 8-p-chlorophenylthio cyclic AMP, considerable cyclic-AMP-dependent protein kinase II activity was identified in nuclei isolated in nonaqueous media. From these data it is concluded that the nuclear cyclic-AMP-dependent protein kinase II is related to or identical with the ovary cytoplasmic cyclic-AMP-dependent protein kinase, supporting the concept that nuclear cyclic-AMP-dependent protein kinase is of cytoplasmic origin.     

Phosphorylation of the EGF receptor from A431 epidermoid carcinoma cells by three distinct types of protein kinase C

Three distinct types of protein kinase C obtained from rat brain cytosol phosphorylated the EGF receptor of A431 epidermoid carcinoma cells at different rates. This receptor was phosphorylated most rapidly by type III protein kinase C, but slowly by type I enzyme. Type II enzyme showed intermediate activity. Chromatographic analysis indicated that A431 cells possessed only one of the three types found in rat brain, which apparently corresponded to type III enzyme. This type of protein kinase C, that is encoded by the alpha-sequence or a closely related sequence, appeared to be expressed commonly in many tissues and organs. The result implies that type III enzyme may play roles in growth promotion.     

Parietal cell protein kinases. Selective activation of type I cAMP-dependent protein kinase by histamine

cAMP-dependent protein kinases have been characterized in parietal cells isolated from rabbit gastric mucosa. Both Type I and Type II cAMP-dependent protein kinase isozymes are present in these cells. Type II isozymes were detected in 900, 14,000, and 100,000 X g particulate fractions as well as 100,000 X g cytosolic fractions; Type I isozymes were found predominately in the cytosolic fraction. When parietal cells were stimulated with histamine, an agent that elevates intracellular cAMP content and initiates parietal cell HCl secretion, cAMP-dependent protein kinase activity was increased in homogenates of these cells as measured by an increase in the cAMP-dependent protein kinase activity ratio. Histamine activation of cAMP-dependent protein kinase was correlated with parietal cell acid secretory responses which were measured indirectly as increased cellular uptake of the weak base, [14C]aminopyrine. These results suggest that cAMP-dependent protein kinase(s) is involved in the control of parietal cell HCl secretion. The parietal cell response to histamine may be compartmentalized because histamine appears to activate only a cytosolic Type I cAMP-dependent protein kinase isozyme, as determined by three different techniques including 1) ion exchange chromatography; 2) Sephadex G-25 to remove cAMP and allow rapid reassociation of the Type II but not the Type I isozyme; and 3) 8-azido-[32P]cAMP photoaffinity labeling. Forskolin, an agent that directly stimulates adenylate cyclases, was found to activate both the Type I and Type II isozymes. Several cAMP-dependent protein kinases were also detected in parietal cell homogenates, including a Ca2+-phospholipid-sensitive or C kinase and two casein kinases which were tentatively identified as casein kinase I and II. At least two additional protein kinases with a preference for serine or lysine-rich histones, respectively, were also detected. The function of these enzymes in parietal cells remains to be shown.     

The assay of the activity of protein kinase C with the synthetic oligopeptide substrate designed for histone kinase II

The activity of histone kinase II was determined on the basis of its ability to phosphorylate the nonapeptide Ala-Ala-Ala-Ser-Phe-Lys-Ala-Lys-Lys-amide designed previously as a specific substrate for this enzyme. Histone kinase II was purified from calf thymus extract by DEAE-cellulose chromatography followed by hydroxylapatite chromatography and high-performance liquid chromatography on a Protein Analysis column (I-125). The Mr value of histone kinase II estimated by the latter method was 50,000-55,000, but several observations indicated that histone kinase II was a product of a proteolytic process. Since the substrate specificity determinants for histone kinase II known from our previous investigations are very similar to those for protein kinase C, it was presumable that histone kinase II was the proteolytic fragment of protein kinase C. Therefore, the nonapeptide was tested as a substrate for protein kinase C prepared from rabbit brain extract by DEAE-cellulose chromatography. The activity of histone kinase II was also detected in brain extract. Histone kinase II was eluted from the DEAE-cellulose in the known position of the proteolytic fragment of protein kinase C. The nonapeptide Ala-Ala-Ala-Ser-Phe-Lys-Ala-Lys-Lys-amide proved to be a better substrate than H1 histone for the detection of the activity of protein kinase C because it was not phosphorylated by the cAMP-dependent protein kinase and the Vmax of protein kinase C was about one order of magnitude higher with the peptide than with H1 histone. The apparent Km of protein kinase C for the peptide was identical with that of histone kinase II (0.2 mM).     

Biochemical characterization of rat brain protein kinase C isozymes

Biochemical characteristics of three rat brain protein kinase C isozymes, types I, II, and III, were compared with respect to their protein kinase and phorbol ester-binding activities. All three isozymes appeared to be alike in their phorbol ester-binding activities as evidenced by their similar Kd for phorbol 12,13-dibutyrate and requirements for Ca2+ and phospholipids. However, differences with respect to the effector-mediated stimulation of protein kinase activity were detectable among these isozymes. The type I enzyme could be stimulated by cardiolipin to a greater extent than those of the type II and III enzymes. In the presence of cardiolipin, the concentrations of dioleoylglycerol or phorbol 12,13-dibutyrate required for half-maximal activation (A1/2) of the type I enzyme were nearly an order of magnitude lower than those for the type II and III enzymes. In the presence of phosphatidylserine, differences in the A1/2 of dioleoylglycerol and phorbol 12,13-dibutyrate for the three isozymes of protein kinase C were less significant than those measured in the presence of cardiolipin. Nevertheless, the A1/2 of these two activators for the type I enzyme were lower than those for the type II and III enzymes. At high levels of phosphatidylserine (greater than 15 mol %), binding of phorbol 12,13-dibutyrate to the type I enzyme evoked a corresponding stimulation of the kinase activity, whereas binding of this phorbol ester to the type II and III enzymes produced a lesser degree of kinase stimulation. For all three isozymes, the concentrations of phosphatidylserine required for half-maximum [3H]phorbol 12,13-dibutyrate binding were almost an order of magnitude less than those for kinase stimulation. Consequently, neither isozyme exhibited a significant kinase activity at lower levels of phosphatidylserine (less than 5 mol %) and phorbol 12,13-dibutyrate (50 nM), a condition sufficient to promote near maximal phorbol ester binding. In addition to their different responses to the various activators, the three protein kinase C isozymes also have different Km values for protein substrates. The type I enzyme appeared to have lower Km values for histone IIIS, myelin basic protein, poly(lysine, serine) (3:1) polymer, and protamine than those for the type II and III enzymes. These results documented that the three protein kinase C isozymes were distinguishable in their biochemical properties. In particular, the type I enzyme, which is a brain-specific isozyme, is distinct from the type II and III enzymes, both have a widespread distribution among different tissues.     

Reduced levels of cardiac cAMP-dependent protein kinase in spontaneously hypertensive rat

Cardiac cAMP-dependent protein kinases were compared between the spontaneously hypertensive rat and the age-matched normotensive Wistar-Kyoto rat by DEAE-cellulose chromatography, photoaffinity labeling with 8-N3[32P]cAMP, and Western blots using the antiregulatory and 125I-anticatalytic subunit antibodies. DEAE-cellulose chromatography revealed that the ratio of type I to type II cAMP-dependent protein kinase was 3:1 in the cytoplasmic soluble proteins from the heart of normotensive rat. In contrast, the ratio of type I to type II was 1:1 in the heart of hypertensive rat. Type I protein kinase was reduced by 3-fold in hypertensive rat compared to normotensive rat. The levels of type II protein kinase were similar in both normotensive and hypertensive rats. The ratio of regulatory subunits of type I (RI) to type II (RII) cAMP-dependent protein kinase was 2.5 in the soluble proteins from the heart of normotensive rat compared to a ratio of 0.62 for hypertensive rat. RI was reduced by 4-fold in hypertensive rat compared to normotensive rat. The decrease in RI from hypertensive rat was also demonstrated by photoaffinity labeling with 8-N3[32P] cAMP. Western blot analysis of the catalytic subunit revealed a 2-fold decrease in catalytic subunit (C) in the soluble proteins from the hypertensive rat compared to normotensive rat. These results show that the reduced level of activity of cardiac type I protein kinase in hypertensive rat was the result of a decrease in both the RI and C subunits, thus reducing the number of type I cAMP-dependent protein kinase holoenzyme molecules. Comparison of type I protein kinase from "prehypertensive" and "hypertensive" stages of hypertensive rat indicated that the type I protein kinase was reduced by 3-fold before an increase in the blood pressure was detectable. Cardiac type I protein kinase is predominantly associated with the cytoplasmic proteins in both the normotensive and hypertensive rats. The levels of RI, RII, and C associated with the membrane-solubilized proteins were not affected in the hypertensive rat. The levels of RII were similar in the brain tissue of normotensive and hypertensive rats, suggesting that the decrease in type I protein kinase is specific in hypertensive rat. In conclusion, a decrease in cardiac type I cAMP-dependent protein kinase may affect the degree of phosphorylation of cardiac regulatory proteins, thus impairing normal cardiac physiology in hypertensive rat.     

Tissue distribution and developmental expression of protein kinase C isozymes

Protein kinase C is a ubiquitous enzyme found in a variety of mammalian tissues and is especially highly enriched in brain and lymphoid organs. Based on biochemical and immunological analyses, we have identified three types of protein kinase C isozyme (designated types I-III) from rat brain. Monospecific antibodies against each of the protein kinase C isozymes were prepared for the determination of tissue distribution, subcellular localization, and developmental changes of these enzymes. The various protein kinase C isozymes were found to be distinctively distributed in different tissues: the type I enzyme in brain; the type II enzyme in brain, pituitary and pineal glands, spleen, thymus, retina, lung, and intestine; and the type III enzyme in brain, pineal gland, retina, and spleen. The rat brain enzymes were differentially distributed in different subcellular fractions. The type I enzyme appeared to be most lipophilic and was recovered mostly in the particulate fractions (80-90%) regardless of the EGTA- or Ca2+-containing buffer used in the homogenization. Significant amounts (30-40%) of the type II and III enzymes were recovered in the cytosolic fraction with EGTA-containing buffer. The expressions of different protein kinase C isozymes appear to be differently controlled during development. In rat brain, both type II and III enzymes were found to increase progressively from 3 days before birth up to 2-3 weeks of age and remained constant thereafter. However, the expression of the type I enzyme displayed a different developmental pattern; it was very low within 1 week, and an abrupt increase was observed between 2 and 3 weeks of age. In thymus, the type II enzyme was found to be maximal shortly after birth; whereas the same kinase in spleen was very low within 2 weeks of age, and a significant increase was observed between 2 and 3 weeks. These results demonstrate that protein kinase C isozymes are distinctively distributed in different tissues and subcellular locales and that their expressions are controlled differently during development.     

Purification, characterization, and distribution of enolase isozymes in chicken

Chicken brain enolase was found to show multiple forms (I, II and III) separable by DEAE-cellulose column chromatography, whereas enolase from chicken skeletal muscle showed a single form. Brain enolase I, enolase III and muscle enolase were purified to electrophoretic homogeneity. These three isozymes were dimeric enzymes, each being composed of two identical subunits, alpha, gamma and beta, having molecular weight of 51,000 +/- 600, 52,000 +/- 550 and 51,500 +/- 650, respectively, as determined by SDS-polyacrylamide gel electrophoresis analysis. Brain enolases I, II and III and muscle enolase had similar catalytic parameters, including almost the same Km values and pH optima. Specific antibodies against brain enolase I, enolase III and muscle enolase, raised in rabbit, showed no cross-reactivity with each other. Antibodies for brain enolases I and III also reacted with brain enolase II, indicating that brain enolase II was the hybrid form (alpha gamma) of brain enolases I (alpha alpha) and III (gamma gamma). Enolases from chicken liver, kidney and heart reacted with the antisera for brain enolase I, but not with those for brain enolase III or muscle enolase. Developmental changes in enolase isozyme distribution were observed in chicken brain and skeletal muscle. In brain, the alpha gamma and gamma gamma forms were not detected in the early embryonic stage and increased gradually during the development of the brain, whereas the alpha alpha form existed at an almost constant level during development. In skeletal muscle, complete switching from alpha alpha enolase to beta beta was observed during the period around hatching.     

Primary structures of human protein kinase C beta I and beta II differ only in their C-terminal sequences

Two types of cDNA clones encoding human protein kinase C (PKC) were isolated from a spleen cDNA library using rabbit protein kinase C beta I/beta II cDNA as a hybridization probe. Nucleotide sequence analyses of these cDNA inserts revealed complete primary structures of two distinct types of human protein kinase C beta I and beta II which differ only in their C-terminal 50 or 52 amino acid residues. It was concluded that there exist four distinct types of PKC, PKC alpha, beta I, beta II and gamma, in human as well as rabbit, and that the corresponding sequences are strictly conserved among mammalian species.     

Properties of protein kinase C subspecies in human platelets

Protein kinase C (PKC) from human platelets was resolved into two fractions by hydroxyapatite column chromatography. One of the enzymes was indistinguishable from the brain type III PKC having alpha-sequence in its kinetic and immunological properties. The other enzyme was kinetically different from any of the brain PKC subspecies so far isolated, although it resembled the brain type II PKC having beta-sequence. With H1 histone as substrate, this platelet enzyme was not very sensitive to Ca2+, and activated partly by phosphatidylserine plus diacylglycerol or by free arachidonic acid. Both platelet enzymes could phosphorylate the P47 protein in vitro, but the enzyme physiologically responsible for the P47 protein phosphorylation in the activated platelets remains to be identified.