Synaptosomal Protein Kinase C Subspecies: A. Dynamic Changes in the Hippocampus and Cerebellar Cortex Concomitant with Synaptogenesis

The expression of protein kinase C (PKC) subspecies in synaptosomes prepared from a number of adult brain regions was compared. Cerebral cortical and thalamic/striatal synaptosomes were found to express three peaks of enzyme activity upon hydroxyapatite chromatography, corresponding to the type I(gamma), type II(beta), and type III(alpha) subspecies. Synaptosomes prepared from either the hippocampus or the cerebellar cortex, however, contained only two major peaks, corresponding to the alpha- and beta-subspecies, with barely detectable levels of the gamma-subspecies, even though these tissue areas were enriched in the latter enzyme. When the ontogenic pattern of hippocampal synaptosomal PKC subspecies was examined, it was found that at postnatal day 7, significant quantities of the gamma-subspecies were present and that this subspecies reached its peak levels at around postnatal day 14, before steadily declining to its adult level. Similar changes were observed also for the gamma-subspecies in cerebellar cortex synaptosomes. The dynamic changes in the synaptosomal PKC subspecies take place at a critical period in the development of the rat brain, concomitant with an active period of synaptogenesis, suggesting that it may play a role in synaptogenesis.     

The expression and stage-specific localization of protein kinase C isotypes during mouse preimplantation development

Signaling events mediate many processes that act during embryogenesis to initiate the program of early development. Within the cell many of these changes are mediated through the activation or inactivation of kinases and phosphatases. Protein kinase C (PKC) is one kinase that has been shown to be involved in at least two developmental transitions during early development, fertilization and embryonic compaction. PKC is a family of kinases whose various isotypes have differing requirements for activation of the kinase that include the availability of calcium, diacylglycerol, and negatively charged phospholipids. The presence of more than one isotype in an egg or blastomere of the embryo would provide the possibility that different isotypes mediate distinct signaling pathways in the cells. To address this possibility the different isotypes of PKC were examined at the mRNA and protein levels during preimplantation development in the mouse. Our results demonstrate that seven isotypes of PKC are present during preimplantation development in mouse, some are of maternal origin and others appear after fertilization. Two isotypes have a stage-dependent nuclear localization. In addition, within each blastomere PKC isotypes occupy different subcellular locations in a stage-dependent fashion.     

Differential down-regulation of protein kinase C subspecies in KM3 cells

The down-regulation of protein kinase C (PKC) subspecies in KM3 cells (a pre-B, pre-T cell line) has been examined. The PKC from KM3 cells was resolved into two subspecies, type II (mainly beta II) and type III (alpha), upon hydroxyapatite column chromatography. Biochemical and immunocytochemical analysis revealed that, when these cells were treated with 12-O-tetradecanoylphorbol 13-acetate (TPA), the time course of down-regulation of the PKC subspecies was different; type II PKC was translocated and depleted from the cell more quickly than type III enzyme. The results suggest that each PKC subspecies plays a different role in the cellular response to TPA and probably to other external stimuli.     

Changes of glycoconjugate expression profiles during early development

A variety of glycoconjugates, including glycosphingolipids (GSLs), expressed in mammalian tissues and cells were isolated and characterized in early biochemical studies. Later studies of virus-transformed fibroblasts demonstrated the association of GSL expression profiles with cell phenotypes. Changes of GSL expression profile were observed during mammalian embryogenesis. Cell surface molecules expressed on embryos in a stage-specific manner appeared to play key roles in regulation of cell-cell interaction and cell sorting during early development. Many mAbs showing stage-specific reactivity with mouse embryos were shown to recognize carbohydrate epitopes. Among various stage-specific embryonic antigens (SSEAs), SSEA-1 was found to react with neolacto-series GSL Le^x, while SSEA-3 and SSEA-4 reacted with globo-series Gb5 and monosialyl-Gb5, respectively. GSL expression during mouse early development was shown to shift rapidly from globo-series to neolacto/lacto-series, and then to ganglio-series. We found that multivalent Le^x caused decompaction of mouse embryos, indicating a functional role of Le^x epitope in the compaction process. Autoaggregation of mouse embryonal carcinoma (EC) F9 cells provided a useful model of the compaction process. We showed that Le^x-Le^x interaction, a novel type of molecular interavction termed carbohydrate-carbohydrate interaction (CCI), was involved in cell aggregation. Similar shifting of GSL expression profiles from globo-series and neolacto/lacto-series to ganglio-series was observed during differentiation of human EC cells and embryonic stem (ES) cells, reflecting the essential role of cell surface glycoconjugates in early development.     

Expression and distribution of cell adhesion molecule uvomorulin in mouse preimplantation embryos

We have examined the synthesis and distribution of the cell adhesion molecule uvomorulin in mouse preimplantation embryos. Uvomorulin can already be detected on the cell surface of unfertilized and fertilized eggs but is not synthesized in these cells. Uvomorulin synthesis starts in late two-cell embryos and seems not to be correlated with the onset of compaction. The first signs of compaction are accompanied by a redistribution of uvomorulin on the surface of blastomeres. During compaction uvomorulin is progressively removed from the apical membrane domains of peripheral blastomeres. In compact morulae uvomorulin is no longer present on the outer surface of the embryo but is localized predominantly in membrane domains involved in cell-cell contacts of adjacent outer blastomeres. On inner blastomeres of compact morulae uvomorulin remains evenly distributed. This uvomorulin distribution once established during compaction is maintained and also found in the blastocyst: on trophectodermal cells uvomorulin localization is very similar to that in adult intestinal epithelial cells while uvomorulin remains evenly distributed on the surface of inner cell mass cells. The possible role of the redistribution of uvomorulin for the generation of trophectoderm and inner cell mass in early mouse embryos is discussed.     

Discrepancy of protein kinase C translocation and platelet aggregation--immunocytobiochemical evidence

We searched for possible relationships between platelet aggregation induced by 12-O-tetradecanoyl phorbol 13-acetate (TPA) or thrombin and the translocation of protein kinase C. Using monoclonal antibodies against subspecies of protein kinase C, we noted a predominant expression of the isozyme, type II, in human platelets (M. Watanabe, M. Hagiwara, K. Onoda, and H. Hidaka, 1988, Biochem. Biophys. Res. Commun. 152, 642). Analysis of the subcellular distribution of protein kinase C revealed that 65% of the kinase activity was present in the cytosolic fraction in unstimulated platelets, with the remaining activity in the membrane fraction. Treatment of platelets with 100 nM TPA resulted in a greater than 60% decrease in protein kinase C activity in the cytosolic fraction and a greater than 200% increase in the activity in the membrane fraction, within 10 min after treatment. Translocation of the enzyme was also found after treatment of platelets with thrombin, although the response was of lower magnitude than that induced by TPA. Similar results were obtained by immunoblotting using MC-2a, an anti-type II protein kinase C monoclonal antibody. We also examined localization of the enzyme, by electron microscopic immunocytochemistry. The presence of type II protein kinase C seemed to be localized mostly in hyaluromeres and not in granulomeres. When platelets were fixed just after the addition of TPA (within 1 min), protein kinase C was localized at the submembranal region with no remarkable change in shape but there was a decrease in the number of granules in the cytoplasma and the open canalicular system was dilated. We then investigated the effects of cytochalasin B, W-7, ML-9, and H-7 on TPA-induced platelet aggregation and the translocation of protein kinase C. W-7 and ML-9 potently inhibited platelet aggregation but none of these compounds hampered the translocation. Thus, activation of protein kinase C may not be a complete requirement for the initiation of platelet aggregation.     

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.     

Monoclonal antibody recognition of two subtype forms of protein kinase C in human platelets

Using a hydroxylapatite column chromatographic technique, we obtained the evidence for two subtype forms of protein kinase C in human platelets. These subtypes had a similar chromatographic property to Type II, Type III protein kinase C from the rabbit brain. In addition, in monoclonal antibodies (MC-1a, 2a, 3a) (1) which reacted with specifically Type I, II, III rabbit brain protein kinase C, respectively, only MC-2a and MC-3a reacted with human platelet protein kinase C. All these brain and platelet subtypes have a similar Km value for ATP, the range being from 8.0 to 20.0 microM and a similar IC50 value with regard to the effect of the protein kinase C inhibitor, H-7. Thus, the possibility that specific functions of platelet may be derived from a deficiency of Type I protein kinase C warrants attention.     

The effects of phorbol ester on mouse blastomeres: a role for protein kinase C in compaction?

The effects of phorbol myristate acetate (PMA) and other activators of protein kinase C on the cytoskeletal organization of mouse oocytes and early embryos have been examined. The effects observed depended on the developmental stage on exposure to PMA. PMA had little effect on the cytoskeletal or microvillous organization of unfertilized oocytes. Interphase cells from embryos prior to compaction showed limited disruption and loss of microvilli when exposed to PMA and foci of polymerized actin remained visible in the cytocortex of embryos up to the early 8-cell stage. When compacted late 8-cell embryos were exposed to PMA, most microvilli were lost and little polymerized actin remained in the cytocortex. PMA also caused loss of microtubules from compact 8-cell embryos under some experimental conditions. Intercellular flattening was both prevented and reversed. The relevance of these observations to the rearrangement of cell-cell contacts and cytoskeletal organization seen during compaction at the 8-cell stage is discussed and a possible role for protein kinase C in the generation of cell polarity proposed.     

The segregation of inner and outer cells in porcine embryos follows a different pattern compared to the segregation in mouse embryos

The mammalian blastocyst consists of an inner cell mass (ICM) enclosed by the trophectoderm. The origin of these two cell populations lies in the segregation of inner and outer cells in the early morula. In the present study, the segregation of inner and outer cells has been studied in porcine embryos and is compared with segregation in mouse embryos. For this, nuclei of inner and outer cells were differentially labelled with two fluorochromes after partial complement-mediated lysis of the outer cells. In porcine and mouse embryos compaction and the first appearance of inner cells occur at different stages of development. In porcine embryos compaction was observed as early as the 4-cell stage, while in mouse embryos compaction occurred in the 8-cell stage. The first inner cells segregated in porcine embryos which were in the transition from four to eight cells and inner cells were added during two subsequent cell cycles. In mouse embryos inner cells segregated predominantly during the fourth cleavage division. From the results obtained we conclude that the segregation of inner and outer cells follows a different pattern in mouse and in porcine embryos.     

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.     

Trypsin-like Hatching Enzyme of Mouse Blastocysts: Evidence for Its Participation in Hatching Process before Zona Shedding of Embryos6

Effects of twelve protease inhibitors on hatching of mouse embryos were investigated. Mouse hatching was strongly or moderately inhibited by trypsin inhibitors including p-toluenesulfonyl-Lys-CH₂Cl (TLCK) and chicken ovomucoid, while inhibitors for chymotrypsin and elastase showed weak or no inhibition. These results indicate the participation of a trypsin-like protease in the hatching of mouse embryos as a hatching enzyme., Since TLCK is the strongest and an irreversible inhibitor for the enzyme, timing of the participation of the hatching enzyme in the hatching process was examined by pulse treatment of embryos with TLCK before and during the zona shedding. The results indicated that a trypsin-like hatching enzyme functions before, but not during, the zona shedding of embryos, especially during a 15 h period immediately before the beginning of the shedding.     

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.     

Patterns of organelle distribution in mouse embryos during preimplantation development

We have evaluated the distribution of mitochondria and acidic organelles using, respectively, the specific vital fluorescent dyes rhodamine 123 and acridine orange during preimplantation embryonic development in the mouse. Under conditions used to visualize organelles in living embryos, staining with either dye was found to have no effect on either the rate or extent of in vitro development of five- to eight-cell embryos up to the blastocyst stage. Mitochondria were randomly distributed throughout the cytoplasm and located around nuclei in blastomeres of uncompacted embryos. During compaction, mitochondria initially reorganized to the blastomere cortex; however, these organelles were later confined to the perinuclear region in the trophectoderm (TE) of expanded blastocysts. Acidic organelles were randomly distributed in the cytoplasm of uncompacted embryos, but following compaction, they were concentrated in cortical and perinuclear locations. Moreover, in TE cells of expanded blastocysts, acidic organelles were found exclusively in a tight perinuclear pattern. Microtubules and microfilaments in TE cells were localized in fixed embryos stained with antitubulin antibodies and rhodamine phalloidin, respectively; these structures were found primarily in the cortical cytoplasm at areas of cell-cell contact and secondarily in a perinuclear location. Thus mitochondria and acidic organelles undergo stage-specific redistributions from a diffuse or cortical pattern at the eight-cell stage to a tight perinuclear localization in the TE. We conclude that the polarized distributions of some organelles and cytoskeletal proteins during compaction may not be reliable permanent markers of the mature TE.     

The heterogeneity of protein kinase C in various rat tissues

Expression of multiple subspecies of protein kinase C (PKC) was studied in various rat tissues. Three types of the enzyme designated type I, II, and III were analyzed, which have the structures of gamma-, beta- (beta I- and beta II-), and alpha-sequence, respectively. Type I enzyme was found only in the central nervous tissue, whereas type III enzyme appeared to be commonly present in various tissues such as liver, spleen, lung, testis, heart, and kidney. Type II enzyme was also found in these tissues. However, immunoblot and biochemical analysis indicated that type II enzyme of lung and heart was distinct from that of other tissues. The tissue-specific expression of PKC suggests that each subspecies of this enzyme has a defined function in processing and modulating tissue responses to external stimuli.     

Growth-promoting effects of gastrin on mouse colon cancer cells in vitro: Absence of autocrine effects

Summary We have previously demonstrated trophic effects of gastrin on mouse colon cancer (MC-26) cells, in vivo, and demonstrated the presence of gastrin receptors (GR) on these cells. The cellular and intracellular mechanism by which gastrin expresses trophic effects on colon cancer cells is, however, as yet unknown. For us to start investigating the possible mechanisms involved, it was important that we first develop an in vitro model, in which gastrin expresses its trophic effects directly on the MC-26 cells. The growth-promoting effects of gastrin on the MC-26 cells were examined in various in vitro culture models, in terms of [³H]thymidine incorporation and cell number. A significant trophic effect of gastrin could be demonstrated on quiescent cells in culture, in the absence of serum. The optimal cell-culture conditions for observing trophic effects of gastrin were defined and included a 24-h period of rapid growth of MC-26 cells in serum-supplemented normal growth medium, followed by a 24-h period of culture in serum-free medium containing an optimal dose (1.0 mM) of thymidine, to achieve growth-arrest of the cells. Addition of gastrin (0.5 to 25 nM) to the quiescent, growth-arrested cells resulted in significant dose-dependent increases in both the incorporation of [³H]thymidine uptake by the cells, and a significant increase in cell number. The concentration of GR on the growth-arrested quiescent MC-26 cells in culture was significantly increased compared to the GR concentration on the control, asynchronized cells. The increased presence of GR on the growth-arrested, synchronized MC-26 cells may have allowed us to observe a significant trophic effect of gastrin on the MC-26 cells, in vitro itself. To determine if gastrin was functioning as an autocrine growth factor for MC-26 cells, we examined the effect of gastrin antibodies on the growth of MC-26 cells; no significant effect of the antigastrin IgG on the growth of MC-26 cells was observed. Supported by grants from the National Institutes of Health, Bethesda, MD (PO1 DK 35608 and CA 38651, and a grant from the American Cancer Society, Washington, DC (PDT-220).     

Regulation of cell adhesion during embryonic compaction of mammalian embryos: Roles for PKC and β‐catenin

Beta‐catenin has a number of roles in early development including involvement in cell adhesion, cell signaling, and developmental fate specification. This study investigates the mechanisms that regulate embryonic compaction, the first cell adhesion event in early mammalian development. Mammalian embryos can be induced to compact at an earlier developmental stage than normal by treatment with agonists that activate protein kinase C (PKC), and this treatment is used to identify and analyze the minimum essential changes required for embryonic compaction. It was predicted that: (1) since activation of PKC can induce compaction prematurely in mouse embryos, phosphorylation of the protein components of the adherens complex would occur during induced compaction and that these components would be required for the cell adhesive event; (2) these same proteins should be phosphorylated during compaction in normal development; (3) new, highly‐specific inhibitors of PKC activity would inhibit compaction during normal development and induced compaction; and (4) some PKC isotypes would become localized to the junctional membranes during the process of compaction. In agreement with these predictionst, β‐catenin became phosphorylated on serine/threonine residues both during induced compaction and normal development. Inhibitors to PKC, but not inhibitors to other kinases, blocked compaction. Furthermore, the alpha isotype of PKC is recruited to the membranes of the apposing blastomeres both during induced compaction and during normal development immediately before compaction begins and before β‐catenin becomes part of the detergent‐resistant cytoskeleton at the junction. Mol. Reprod. Dev. 54:135–144, 1999. © 1999 Wiley‐Liss, Inc.     

Oligosaccharides containing fucose linked alpha(1-3) and alpha(1-4) to N-acetylglucosamine cause decompaction of mouse morulae

Two- to four-cell and eight-cell mouse embryos were incubated in various fucosylated and unfucosylated oligosaccharides, fucose binding protein, and fucosylated BSA. Compaction at the eight-cell stage was reversed by a mixture containing the oligosaccharides lacto-N-fucopentaose II (80-90%), in which fucose is linked alpha(1-4) to N-acetylglucosamine, and lacto-N-fucopentaose III (10-20%), in which fucose is linked alpha(1-3) to N-acetylglucosamine. Pure lacto-N-fucopentaose III (LNFP III) and 3-fucosyl lactose (containing fucose alpha(1-3)glucose) had a similar effect. All three molecules affected blastocyst formation. Various closely related fucosylated and unfucosylated oligosaccharides did not induce decompaction or inhibit blastocyst formation. The proportion of embryos incubated from the two- to four-cell stage in LNFP II/III which reached the eight-cell stage and formed blastocysts was reduced. Those which formed compact morulae subsequently decompacted. Precompact or early compacting eight-cell embryos incubated in LNFP II/III compacted normally but subsequently decompacted and failed to form blastocysts. Decompaction of eight-cell embryos in LNFP II/III occurred during a specific period of development (80-90 hr post-hCG) and was reversible up to 84-86 hr post-hCG, but not by 92 hr post-hCG. The period of sensitivity to LNFP II/III was associated with the decrease in the ability of calcium-free medium to cause decompaction. It appears that LNFP II/III interferes with a later calcium-independent phase of compaction and we propose that LNFP III and II inhibit an endogenous lectin-saccharide interaction between membranes involved in the stabilization of compaction.     

Requirement for ERK MAP kinase in mouse preimplantation development

Preimplantation development is a crucial step for successful implantation and pregnancy. Although both compaction and blastocyst formation have been extensively studied, mechanisms regulating the early cell division stages before compaction have remained unclear. Here, we show that extracellular signal regulated kinase (ERK) mitogen-activated protein (MAP) kinase function is required for early embryonic cell division before compaction. Our analysis demonstrates that inhibition of ERK activation in late two-cell-stage embryos leads to a reversible arrest in the G2 phase at the four-cell stage. The G2-arrested four-cell-stage embryos showed weakened cell-cell adhesion as compared with control embryos. Remarkably, microarray analyses showed that most of the programmed changes of upregulated and downregulated gene expression during the four- to eight-cell stages proceeded normally in four-cell-stage-arrested embryos that were subsequently released to resume development; however, the expression profiles of a proportion of genes in these embryos closely paralleled the stages of embryonic rather than normal development. These parallel genes included the genes encoding intercellular adhesion molecules, whose expression appeared to be positively regulated by the ERK pathway. We also show that, whereas ERK inactivation in eight-cell-stage embryos did not lead to cell division arrest, it did cause this arrest when cadherin-mediated cell-cell adhesion was disrupted. These results demonstrate an essential role of ERK function in two-cell to eight-cell-stage embryos, and suggest a loose parallelism between the gene expression programs and the developmental stages before compaction.     

Differential expression of multiple protein kinase C subspecies in rat central nervous tissue

Protein kinase C from a number of areas of rat central nervous tissue was resolved into three distinct fractions upon hydroxyapatite column chromatography. One of the enzyme fractions, designated type II, could be further distinguished into two subspecies with polyclonal antisera, which were raised against synthetic peptides specific for the predicted amino acid sequences of two alternative cDNA clones encoding this enzyme type. Using a combination of these biochemical and immunological techniques, the relative activity of the multiple subspecies of protein kinase C was assessed for each brain area. A distinct regional pattern of expression was found, which per se may be an important factor in determining the response of different neuronal cell types to extracellular stimuli.