Characterization of maturation-activated histone H1 and ribosomal S6 kinases in sea star oocytes

Effects of methoxychlor, dieldrin and lindane on sea urchin fertilization and early development

We have studied the effects of methoxychlor (MXC), dieldrin, and lindane on fertilization and early development of sea urchin egg. These organochlorine pesticides have often been found in polluted ground and water near agricultural sites, and have therefore been detected from time to time in the food chain and in drinking water. They have been reported to alter various reproduction functions in various animals including marine populations. We observed that the rate of fertilization decreased when the sperm was incubated with dieldrin or lindane. Treatment of eggs with each pesticide did not prevent fertilization, but increased the rate in polyspermy, delayed or blocked the first mitotic divisions, and altered early embryonic development. Moreover, all pesticides could alter several intracellular biochemical pathways that control first mitotic divisions and early development, including intracellular calcium homeostasis, MPF (mitosis promoting factor) activity and formation of the bipolar mitotic spindle. We found that lindane was the most potent of the three pesticides to alter all biochemical events. All these effects were observed at relatively high concentrations. However, bio-accumulation in sediments and aquatic organisms have been reported. Sea urchin eggs may then be in contact with very high concentrations of these pesticides in areas where these pesticides are not handled or stocked properly, and then develop into abnormal embryos.

Roscovitine and other purines as kinase inhibitors. From starfish oocytes to clinical trials

This article reviews the steps that have led us from very fundamental research on the cell division cycle, investigated with the starfish oocyte model, to the identification of drugs now being evaluated against cancer in the clinic. Among protein kinases activated during entry in M phase, the cyclin-dependent kinase CDK1/cyclin B was initially identified as a universal M-phase promoting factor. It was then used as a screening target to identify pharmacological inhibitors. The first inhibitors to be discovered were 6-dimethylaminopurine and isopentenyladenine, from which more potent and selective inhibitors were optimized (olomoucine, roscovitine, and purvalanols). All were cocrystallized with CDK2 and found to localize in the ATP-binding pocket of the kinase. Their selectivity and cellular effects have been thoroughly investigated. Following encouraging results obtained in preclinical tests and favorable pharmacological properties, one of these purines, roscovitine (CYC202), is now entering phase II clinical trials against cancers and phase I clinical tests against glomerulonephritis. CDK inhibitors are also being evaluated, at the preclinical level, for therapeutic use against neurodegenerative diseases, cardiovascular disorders, viral infections, and parasitic protozoa. This initially unexpected scope of potential applications and the large number and chemical diversity of pharmacological inhibitors of CDKs now available constitute a very encouraging stimulus to pursue the search for optimization and characterization of protein kinase inhibitors, from which we expect numerous therapeutic applications.

Cyclic nucleotide-independent phosphorylation of vitellin by casein kinase II purified from Rhodnius prolixus oocytes

In this study we show that Vitellin (VT) phosphorylation in chorionated oocytes of Rhodnius prolixus is completely inhibited by heparin (10 microg/ml), a classical casein kinase II (CK II) inhibitor. VT phosphorylation is not affected by modulators of cyclic nucleotide-dependent protein kinases such as c-AMP (10 microM), H-8 (1 microM) and H-89 (0.1 microM). We have obtained a 3000-fold VT-free enriched preparation of CK II. Autophosphorylation of this enzyme preparation in the presence of (32)P-ATP demonstrated that it lacks any endogenous substrates. Rhodnius CK II is strongly inhibited by heparin (Ki = 9 nM) and uses ATP (Km = 36 microM) or GTP (Km = 86 microM) as phosphate donors. Incubation of VT with purified Rhodnius CK II and (32)P-ATP led to the incorporation of 2 mols of phosphate/mol VT. However, the total number of phosphorylation sites available can be altered by previous incubation of VT with alkaline phosphatase. These data show that an insect yolk protein contain phosphorylation sites for a cyclic nucleotide-independent protein kinase such as CK II.

Regulation of the meiosis-inhibited protein kinase, a p38(MAPK) isoform, during meiosis and following fertilization of seastar oocytes

A p38(MAPK) homolog Mipk (meiosis-inhibited protein kinase) was cloned from seastar oocytes. This 40-kDa protein shares approximately 65% amino acid identity with mammalian p38-alpha isoforms. Mipk was one of the major tyrosine-phosphorylated proteins in immature oocytes arrested at the G(2)/M transition of meiosis I. The tyrosine phosphorylation of Mipk was increased in response to anisomycin, heat, and osmotic shock of oocytes. During 1-methyladenine-induced oocyte maturation, Mipk underwent tyrosine dephosphorylation and remained dephosphorylated in mature oocytes and during the early mitotic cell divisions until approximately 12 h after fertilization. At the time of differentiation and acquisition of G phases in the developing embryos, Mipk was rephosphorylated on tyrosine. In oocytes that were microinjected with Mipk antisense oligonucleotides and subsequently were allowed to mature and become fertilized, differentiation was blocked. Because MipK antisense oligonucleotides and a dominant-negative (K62R)Mipk when microinjected into immature oocytes failed to induce germinal vesicle breakdown, inhibition of Mipk function was not sufficient by itself to cause oocyte maturation. These findings point to a putative role for Mipk in cell cycle control as a G-phase-promoting factor.

Effect of wortmannin, an inhibitor of phosphatidylinositol 3-kinase, on the first mitotic divisions of the fertilized sea urchin egg

We have reported earlier that the polyphosphoinositide messenger system may control mitosis in sea urchin eggs. Besides phospholipase C activation and its second messengers, phosphatidylinositol (PI) 3-kinase has been proposed to affect a wide variety of cellular processes in other cellular systems. Therefore, we have investigated whether PI 3-kinase could play a role in regulating the sea urchin early embryonic development. Our data presented here suggest that PI 3-kinase is present in sea urchin eggs. We found that wortmannin, an inhibitor of PI 3-kinase, led to arrest of the cell cycle. Chromosome condensation, nuclear envelope breakdown, microtubular aster polymerization, protein and DNA synthesis were not affected when fertilization was performed in the presence of the drug. However, maturation-promoting factor (MPF) activation was inhibited and centrosome duplication was perturbed preventing the formation of a bipolar mitotic spindle in wortmannin treated eggs. We discuss how PI 3-kinase might be involved in the cascade of events leading to the first mitotic divisions of the fertilized sea urchin egg.

Inosine-5'-monophosphate dehydrogenase is a rate-determining factor for p53-dependent growth regulation

We have proposed that reduced activity of inosine-5'-monophosphate dehydrogenase (IMPD; IMP:NAD oxidoreductase, EC 1.2.1.14), the rate-limiting enzyme for guanine nucleotide biosynthesis, in response to wild-type p53 expression, is essential for p53-dependent growth suppression. A gene transfer strategy was used to demonstrate that under physiological conditions constitutive IMPD expression prevents p53-dependent growth suppression. In these studies, expression of bax and waf1, genes implicated in p53-dependent growth suppression in response to DNA damage, remains elevated in response to p53. These findings indicate that under physiological conditions IMPD is a rate-determining factor for p53-dependent growth regulation. In addition, they suggest that the impd gene may be epistatic to bax and waf1 in growth suppression. Because of the role of IMPD in the production and balance of GTP and ATP, essential nucleotides for signal transduction, these results suggest that p53 controls cell division signals by regulating purine ribonucleotide metabolism.

On cyclins, oocytes, and eggs

Oocyte and egg are suitable model systems for studying cell division since meiotic maturation resembles a G2/M transition and early embryonic divisions are precisely timed and occur without zygotic transcription. The analysis of oocytes and eggs from different species provides the opportunity to understand the roles of proteins that the critical to the progression and maintenance of the cell cycle. Among them, cyclins are certainly worthy of investigation. Mitotic cyclins (cyclins A and B) are clearly implicated in meiosis and early embryonic cell cycles. More recent studies have revealed that G1-type cyclins (cyclins E and D) could also play a role in both processes and cyclin H has been suggesed to participate to CAK activity (cdc2-activating kinase) in oocytes. The study of cyclins in oocytes and eggs clearly offer insights into their roles during the cell cycle.

Ribosomal S6 kinase p90rsk and mRNA cap-binding protein eIF4E phosphorylations correlate with MAP kinase activation during meiotic reinitiation of mouse oocytes

During meiotic reinitiation of the mouse oocyte, entry into M-phase is regulated by changes of protein phosphorylation and by the stimulation of selective mRNA translation following the nuclear membrane dissolution. Our results reveal that M-phase kinases (MAP kinase and histone H1 kinase) are being activated together with S6 kinase and with the phosphorylation of eIF4E, the cap-binding subunit of the initiation factor eIF-4F. In order to test which signaling pathway(s) is(are) involved, okadaic acid and cycloheximide have been used as tools for differentially modulating MAP and histone H1 kinase activities. A role for MAP kinases in the phosphorylation of eIF4E and the activation of S6 kinase is suggested. The possible implication of p90rsk and/or of p70s6k in the overall increase in S6 kinase activity has been examined. p70s6k does not appear to be involved since phosphorylated forms are found in prophase and maturing oocytes. In contrast, p90rsk is phosphorylated and activated in maturing oocytes. p90rSk phosphorylation correlates with the activation of S6 kinase. These results suggest that the overall increase of S6 kinase activity is mostly due to p90rsk activation. The roles of eIF4E phosphorylation and S6 kinase activation in the physiological induction of M-phase and in the okadaic acid-induced premature mitotic events are discussed.

Microfilament dynamics: regulation of actin polymerization by actin-fragmin kinase and phosphatases

Based on the phosphorylation of the purified actin-fragmin complex, an 80 kDa monomeric kinase (AFK) has been isolated from Physarum polycephalum. Protein chemical analysis and studies involving kinase inhibitors and effectors establish that the AFK is a unique kinase that cannot be classified so far in one of the conventional kinase families. The actin-fragmin kinase behaves as an "independent" kinase since its activity towards the actin-fragmin complex is apparently not regulated by the binding of a ligand (e.g., the cyclic-nucleotides, Ca2+, calmodulin, phosphatidylserine and diolein). Rigorous screening of the substrate specificity suggests that the actin-fragmin complex represents the only substrate for this kinase. This kinase phosphorylates the actin moiety of the actin-fragmin complex at two consecutive threonine residues which constitute one of the contact sites for DNase I (37) and which are also located at one of the proposed actin-actin contact sites along the long-pitch helix of F-actin (38, 39). The physiological importance of this phosphorylation was demonstrated by studying the effect of phosphorylation on the nucleation and the capping activity of the actin-fragmin complex using fluorescence enhancement analysis. As could be demonstrated, the nucleation of actin filaments by the actin-fragmin complex is completely abolished upon phosphorylation by the AFK. Phosphorylation of the complex also interferes with its capping activity, which becomes Ca(2+)-dependent. In addition, capping and nucleating activity is regulated in vitro by phosphoinositides, of which PIP2 displays the highest activity and specificity. PIP2 partially inhibits the nucleation and capping activity of the unphosphorylated actin-fragmin. The capping activity of the phosphorylated actin-fragmin complex was inhibited by PIP2 to a much greater extent as compared to the unphosphorylated actin-fragmin complex. Among all phospholipids tested, PIP2 displayed the highest specificity. Initial experiments with purified preparations of the PP-1, PP-2A, PP-2B, alkaline phosphatase and acid phosphatases showed that PP-1 and PP-2A phosphatases were capable of dephosphorylating the phospho actin-fragmin complex. These findings raised the question of whether these or other protein phosphatases were involved in the dephosphorylation of this substrate in vivo. To address this question, Physarum extracts were subjected to fractionation by ion exchange chromatography, and the column fractions were assayed in a variety of conditions, to identify the protein phosphatases involved in the dephosphorylation of this substrate and to identify the elution position of the major Ser/Thr protein phosphatases present in the Physarum extract.(ABSTRACT TRUNCATED AT 400 WORDS)

Anaphase is initiated by proteolysis rather than by the inactivation of maturation-promoting factor

We have used frog egg extracts that assemble mitotic spindles to identify the event that triggers sister chromatid separation. Adding a nondegradable form of cyclin B prevents maturation-promoting factor (MPF) inactivation but does not block sister chromatid separation, showing that MPF inactivation is not needed to initiate anaphase. In contrast, adding an N-terminal fragment of cyclin, which acts as a specific competitor for cyclin degradation, produces a dose-dependent delay in MPF inactivation and sister chromatid separation. Methylated ubiquitin, which inhibits ubiquitin-mediated proteolysis, also delays sister chromatid separation, suggesting that ubiquitin-mediated proteolysis is necessary to initiate anaphase. The N-terminal cyclin fragment inhibits chromosome separation even in extracts that contain only nondegradable forms of cyclin, suggesting that proteins other than the known cyclins must be degraded to dissolve the linkage between sister chromatids.

Maturation hormone induced an increase in the translational activity of starfish oocytes coincident with the phosphorylation of the mRNA cap binding protein, eIF-4E, and the activation of several kinases

The stimulation of translation in starfish oocytes by the maturation hormone, 1-methyladenine (1-MA), requires the activation or mobilization of both initiation factors and mRNAs [Xu and Hille, Cell Regul. 1:1057, 1990]. We identify here the translational initiation complex, eIF-4F, and the guanine nucleotide exchange factor for eIF-2, eIF-2B, as the rate controlling components of protein synthesis in immature oocytes of the starfish, Pisaster orchraceus. Increased phosphorylation of eIF-4E, the cap binding subunit of the eIF-4F complex, is coincident with the initial increase in translational activity during maturation of these oocytes. Significantly, protein kinase C activity increased during oocyte maturation in parallel with the increase in eIF-4E phosphorylation and protein synthesis. An increase in the activities of cdc2 kinase and mitogen-activated myelin basic protein kinase (MBP kinase) similarly coincide with the increase in eIF-4E phosphorylation. However, neither cdc2 kinase nor MBP kinase phosphorylates eIF-4E in vitro. Casein kinase II activity does not change during oocyte maturation, and therefore, cannot be responsible for the activation of translation. Treatment of oocytes with phorbol 12-myristate 13-acetate, an activator of protein kinase C, for 30 min prior to the addition of 1-MA resulted in the inhibition of 1-MA-induced phosphorylation of eIF-4E, translational activation, and germinal vesicle breakdown. Therefore, protein kinase C may phosphorylate eIF-4E, after very early events of maturation. Another possibility is that eIF-4E is phosphorylated by an unknown kinase that is activated by the cascade of reactions stimulated by 1-MA. In conclusion, our results suggest a role for the phosphorylation of eIF-4E in the activation of translation during maturation, similar to translational regulation during the stimulation of growth in mammalian cells.

Early responses in mitogenic signaling, bombesin induced protein phosphorylations in Swiss 3T3 cells

The amphibian tetradecapeptide bombesin as well as the bombesin-related mammalian peptides are potent mitogens for Swiss 3T3 cells. Other sole mitogens for Swiss 3T3 cells, such as PDGF and FGF, invariably signal through a tyrosine kinase receptor. The bombesin receptor has been cloned from Swiss 3T3 fibroblasts and was shown to be a member of the family of G-protein-linked neuropeptide receptors, whose sequence does not reveal a protein kinase domain. Upon binding to its receptor, bombesin evokes a complex cascade of early biochemical events including inositol 1,4,5-trisphosphate-induced mobilization of intracellular Ca2+, Na+ and K+ fluxes, PK-C activation, transmodulation of the EGF-receptor, accumulation and expression of the proto-oncogenes c-fos and c-myc and cAMP production. The intermediates in this signaling pathway are still largely unknown. Since many hormones and neuropeptides that signal through similar receptors with seven membrane spanning domains are by themselves not mitogenic for Swiss 3T3 fibroblasts, we suggest that bombesin acts through a rather special signaling pathway. Although its receptor does not feature a cytoplasmic tyrosine kinase domain, bombesin rapidly stimulates the tyrosine phosphorylation of multiple protein substrates, which are however quite distinct from the usual targets of tyrosine kinase receptors. Yet, a similar cascade of Ser/Thr protein kinases is activated downstream of these differentiating tyrosine kinase events, since, like EGF or insulin, bombesin rapidly stimulates the activity of two MBP kinases as well as several S6 peptide kinases. The present report furthermore implicates CK-2 in the early signal transduction pathway of this mitogen, and it is postulated that the activation of CK-2 may be an intrinsic property of "sole mitogens" like bombesin, as it may be a compulsory event leading to cell division. In that respect, CK-2 may also be the point of integration of multiple signaling pathways, initiated by several different growth factors which by their synergistic actions make cell proliferation possible.

M-phase-specific histone H1 kinase in fish oocytes. Purification, components and biochemical properties

We demonstrate, for the first time in fish, that a Ca(2+)-independent and cyclic-nucleotide-independent histone H1 kinase activity oscillates according to the cell cycle of the oocyte, peaking at the first and the second meiotic metaphase with a transient drop between them. The kinase, M-phase-specific histone H1 kinase (M-H1K), was purified from mature carp oocytes by using two exogenous substrates for assaying its activity: histone H1 and a synthetic peptide (SP peptide, KKAAKSPKKAKK) containing the sequence KSPKK, which includes the consensus sequence of the site phosphorylated by a serine/threonine-specific protein kinase encoded by the fission yeast cdc2+ gene (cdc 2 kinase). The M-H1K and maturation-promoting factor (MPF) activities coincided closely throughout four steps of purification, strongly suggesting the identity of M-H1K and MPF. The final preparation was purified 5000-fold with a recovery of 4%, when histone H1 was used for the kinase assay, and 10,000-fold with a recovery of 7% when SP peptide was used. The purified molecular mass of the kinase was estimated to be 100 kDa by gel filtration and contained four proteins of 33, 34, 46 and 48 kDa. Anti-PSTAIR antibody recognizing cdc2 kinase cross-reacted with the 33-kDa and 34-kDa proteins, while the 46-kDa and 48-kDa bands cross-reacted with monoclonal antibodies raised against cyclin B. The 33-kDa protein was also recognized by an antibody against a goldfish cdk2 (Eg1) kinase, a cdc2-related kinase which has the PSTAIR sequence and binds to p13suc1 but does not form a complex with cyclin B. M-H1K activity corresponded well to the 34-kDa, 46-kDa and 48-kDa proteins but not to the 33-kDa protein. These results strongly suggest that M-H1K consists of cdc2 kinase forming a complex with cyclin B, and that cdk2 kinase is not a component of M-H1K, although it is found in the highly purified M-H1K. The purified M-H1K utilized Mg2+, Mn2+, ATP and GTP, and had a wide pH optimum ranging over 8.0-10.5. The kinase was thermolabile and sensitive to freezing/thawing.

Interaction between the cell-cycle-control proteins p34cdc2 and p9CKShs2. Evidence for two cooperative binding domains in p9CKShs2

A universal intracellular factor, the 'M-phase-promoting factor' (MPF), displaying histone H1 kinase activity and constituted of at least two subunits, p34cdc2 and cyclin Bcdc13, triggers the G2----M transition of the cell cycle in all organisms. The yeast p13suc1 and p18CKS1 subunits and their functionally interchangeable human homologues, p9CKShs1 and p9CKShs2, directly interact with p34cdc2 and may actually be part of the MPF complex. We have chemically synthesized p9CKShs2 and several of its peptide domains in order to investigate the binding of p9CKShs2 and p34cdc2. Several arguments support the hypothesis that the N-terminal half (peptide B) and the C-terminal half (peptide E) each contain a p34cdc2-binding site and that these two binding domains cooperate in establishing a stable p9CKShs2-p34cdc2 complex: (a) only the combination of peptides B + E, and not B or E alone, is able to elute the cdc2 kinase from p9CKShs1-Sepharose beads; (b) only immobilized peptides B + E, and not immobilized B or E, bind the cdc2 kinase; (c) only the peptides B + E combination, and not B or E alone, can compete with p9CKShs1 for cdc2 kinase binding; (d) only when supplemented with E or B free peptide does the cdc2 kinase bind to B- or E-Sepharose beads, respectively. No binding occurs in the absence of free peptide. This additivity cannot be attributed to the formation of a B-E complex mimicking the full-length p9CKShs2. The cyclin B subunit is not required for the formation of the p9CKShs2-p34cdc2 complex through these two binding domains. The implications of the existence of two cooperative p34cdc2-binding domains in p9CKShs2 on the structure of the active M-phase-specific kinase is discussed.

Protein phosphorylation during activation of surf clam oocytes

We have investigated the increase of phosphorylated proteins upon activation of surf clam (Spisula solidissima) oocytes, by measuring the cumulative incorporation of 32P in proteins and by performing an SDS-PAGE and autoradiographic analysis of 32P-labeled proteins, from oocytes initially radiolabeled with 32P-orthophosphate. The phosphorylation inhibitor 6-dimethylaminopurine (6-DMAP) inhibits both germinal vesicle breakdown (GVBD) and the normal increase in phosphorylated proteins observed upon activation by KCl, in a reversible and dose-dependent manner. Using different artificial seawaters (normal, Ca(2+)-free, Na(+)-free), we observed that the increase of phosphorylated proteins, upon K+ stimulation, occurs only when GVBD is allowed to proceed along with an increased Ca2+ influx, in normal or Na(+)-free seawater. Stimulation of oocytes by ammonia, which directly raises intracellular pH (pHi) but does not trigger GVBD, is without effect on the level or pattern of phosphorylated proteins. The link between the Ca2+ influx and the level of phosphorylated proteins was further investigated using conditions altering the duration or the level of Ca2+ influx upon K+ stimulation. In all conditions tested, both GVBD and the level of phosphorylated proteins were similarly affected by alterations of the Ca2+ influx, indicating that these processes are tightly coupled one with another. Upon activation of oocytes, six major proteins of estimated molecular weights of 31, 41, 48, 56, 80 and 86 kDa undergo an increased phosphorylation that is reversibly sensitive to 6-DMAP. Our results suggest that increased protein phosphorylation, sensitive to 6-DMAP, is necessary for GVBD and that it is indirectly linked to the increased Ca2+ influx that stands as an upstream trigger for activation, while an elevated pHi alone has no effect on these processes.

Nuclear protein kinases in rat liver: evidence for increased histone H1 phosphorylating activity during liver regeneration

Comparison of protein kinase activity in normal and regenerating rat liver nuclei indicates that exogenous histone H1 is hyperphosphorylated in 22-h regenerating nuclei. The protein kinase involved is not sensitive to protein kinase A inhibitor, is inhibited by staurosporine and by an anti-PKC polyclonal antibody, utilizes only ATP, and also phosphorylates the C-terminal fragment of histone H1. These data suggest that protein kinase C is responsible for the observed effects, in agreement with the presence of this enzyme in normal and regenerating nuclei demonstrated by immunoblotting.

Erbstatin and tyrphostins block protein-serine kinase activation and meiotic maturation of sea star oocytes

The effects of ten putative protein-tyrosine kinase inhibitors on the activation of protein-serine kinases and germinal vesicle breakdown (GVBD) in maturing sea star oocytes were investigated. Erbstatin and tyrphostins such as AG18 and AG125 blocked 1-methyladenine-induced GVBD in sea star oocytes with IC50 values of less than 20 microM. Inhibition of the rate of GBVD was achieved even when these compounds were added up to 15 min after exposure of the oocytes to 1-methyladenine. The action of these substances on oocyte maturation was reversed by subsequent washing and culturing of the cells in natural sea water free of the inhibitors. Cell viability was maintained for at least 12 h in their presence, as assessed by Trypan blue dye exclusion. These inhibitors prevented the 1-methyladenine-induced activations of the histone H1 kinase p34cdc2, the myelin basic protein kinase p44mpk and a ribosomal S6 peptide kinase. Erbstatin, AG18 and AG125 prevented 1-methyladenine-induced tyrosine dephosphorylation of p34cdc2, and they inhibited tyrosine phosphorylation of p44mpk. These studies imply that activation of a protein-tyrosine kinase may be necessary for stimulation of p34cdc2 in maturing sea star oocytes.

Tyrosine phosphorylation and activation of homologous protein kinases during oocyte maturation and mitogenic activation of fibroblasts

Meiotic maturation of Xenopus and sea star oocytes involves the activation of a number of protein-serine/threonine kinase activities, including a myelin basic protein (MBP) kinase. A 44-kDa MBP kinase (p44mpk) purified from mature sea star oocytes is shown here to be phosphorylated at tyrosine. Antiserum to purified sea star p44mpk was used to identify antigenically related proteins in Xenopus oocytes. Two tyrosine-phosphorylated 42-kDa proteins (p42) were detected with this antiserum in Xenopus eggs. Xenopus p42 chromatographs with MBP kinase activity on a Mono Q ion-exchange column. Tyrosine phosphorylation of Xenopus p42 approximately parallels MBP kinase activity during meiotic maturation. These results suggest that related MBP kinases are activated during meiotic maturation of Xenopus and sea star oocytes. Previous studies have suggested that Xenopus p42 is related to the mitogen-activated protein (MAP) kinases of culture mammalian cells. We have cloned a MAP kinase relative from a Xenopus ovary cDNA library and demonstrate that this clone encodes the Xenopus p42 that is tyrosine phosphorylated during oocyte maturation. Comparison of the sequences of Xenopus p42 and a rat MAP kinase (ERK1) and peptide sequences from sea star p44mpk indicates that these proteins are close relatives. The family members appear to be tyrosine phosphorylated, and activated, in different contexts, with the murine MAP kinase active during the transition from quiescence to the G1 stage of the mitotic cell cycle and the sea star and Xenopus kinases being active during M phase of the meiotic cell cycle.

Tyrosine phosphorylation and activation of homologous protein kinases during oocyte maturation and mitogenic activation of fibroblasts

Meiotic maturation of Xenopus and sea star oocytes involves the activation of a number of protein-serine/threonine kinase activities, including a myelin basic protein (MBP) kinase. A 44-kDa MBP kinase (p44mpk) purified from mature sea star oocytes is shown here to be phosphorylated at tyrosine. Antiserum to purified sea star p44mpk was used to identify antigenically related proteins in Xenopus oocytes. Two tyrosine-phosphorylated 42-kDa proteins (p42) were detected with this antiserum in Xenopus eggs. Xenopus p42 chromatographs with MBP kinase activity on a Mono Q ion-exchange column. Tyrosine phosphorylation of Xenopus p42 approximately parallels MBP kinase activity during meiotic maturation. These results suggest that related MBP kinases are activated during meiotic maturation of Xenopus and sea star oocytes. Previous studies have suggested that Xenopus p42 is related to the mitogen-activated protein (MAP) kinases of culture mammalian cells. We have cloned a MAP kinase relative from a Xenopus ovary cDNA library and demonstrate that this clone encodes the Xenopus p42 that is tyrosine phosphorylated during oocyte maturation. Comparison of the sequences of Xenopus p42 and a rat MAP kinase (ERK1) and peptide sequences from sea star p44mpk indicates that these proteins are close relatives. The family members appear to be tyrosine phosphorylated, and activated, in different contexts, with the murine MAP kinase active during the transition from quiescence to the G1 stage of the mitotic cell cycle and the sea star and Xenopus kinases being active during M phase of the meiotic cell cycle.

High-mobility-group proteins P1, I and Y as substrates of the M-phase-specific p34cdc2/cyclincdc13 kinase

All dividing cells entering the M phase of the cell cycle undergo the transient activation of an M-phase-specific histone H1 kinase which was recently shown to be constituted of at least two subunits, p34cdc2 and cyclincdc13. The DNA-binding high-mobility-group (HMG) proteins 1, 2, 14, 17, I, Y and an HMG-like protein, P1, were investigated as potential substrates of H1 kinase. Among these HMG proteins, P1 and HMG I and Y are excellent substrates of the M-phase-specific kinase obtained from both meiotic starfish oocytes and mitotic sea urchin eggs. Anticyclin immunoprecipitates, extracts purified on specific p34cdc2-binding p13suc1-Sepharose and affinity-purified H1 kinase display strong HMG I, Y and P1 phosphorylating activities, demonstrating that the p34cdc2/cyclincdc13 complex is the active kinase phosphorylating these HMG proteins. HMG I and P1 phosphorylation is competitively inhibited by a peptide mimicking the consensus phosphorylation sequence of H1 kinase. HMG I, Y and P1 all possess the consensus sequence for phosphorylation by the p34cdc2/cyclincdc13 kinase (Ser/Thr-Pro-Xaa-Lys/Arg). HMG I is phosphorylated in vivo at M phase on the same sites phosphorylated in vitro by H1 kinase. P1 is phosphorylated by H1 kinase on sites different from the sites of phosphorylation by casein kinase II. The three thermolytic phosphopeptides of P1 phosphorylated in vitro by purified H1 kinase are all present in thermolytic peptide maps of P1 phosphorylated in vivo in proliferating HeLa cells. These phosphopeptides are absent in nonproliferating cells. These results demonstrate that the DNA-binding proteins HMG I, Y and P1 are natural substrates for the M-phase-specific protein kinase. The phosphorylation of these proteins by p34cdc2/cyclincdc13 may represent a crucial event in the intense chromatin condensation occurring as cells transit from the G2 to the M phase of the cell cycle.

Identification of a major maturation-activated acetyl-CoA carboxylase kinase in sea star oocytes as p44mpk

Maturation-activated protein-serine/threonine kinases were investigated in the high-speed supernatant fractions from sea-star oocytes harvested at the time of germinal vesicle breakdown. One of the major stimulated protein kinases able to phosphorylate acetyl-CoA carboxylase in these extracts was found to co-purify with a 44 kDa myelin basic protein kinase (p44mpk) that is activated with a similar time course during oocyte maturation. Purified sea-star oocyte p44mpk phosphorylated acetyl-CoA carboxylase (purified from rat liver) predominantly on serine and to a small extent on threonine. Furthermore, the phosphorylation of acetyl-CoA carboxylase occurred principally on a tryptic phosphopeptide which displayed electrophoretic and chromatographic properties very similar to those of the peptide that has previously been shown to undergo increased phosphorylation in response to insulin in rat adipocytes [Brownsey & Denton (1982) Biochem. J. 202, 77-86]. The acetyl-CoA carboxylase was phosphorylated at a similar rate and to a similar extent by casein kinase II, which was also purified from maturing sea-star oocytes. Although casein kinase II was also activated approximately 3-fold near the time of nuclear envelope breakdown, it was responsible for only a minor component of the total enhanced acetyl-CoA carboxylase kinase activity measured in the soluble extracts from maturing oocytes. Acetyl-CoA carboxylase was a relatively poor substrate for the major S6 peptide kinase activity that was also stimulated during resumption of meiosis in the oocytes. The properties of the p44mpk are reminiscent of those of a microtubule-associated protein 2 (MAP-2) kinase that is activated in response to insulin and other mitogens in mammalian cells [Ray & Sturgill (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 3753-3757; Hoshi, Nishida & Sakai (1988) J. Biol. Chem. 263, 5396-5401]. It is intriguing that several of the mammalian protein kinases that are acutely activated after mitogenic prompting of quiescent mouse fibroblasts (i.e. G0 to G1 transition), such as MAP-2 kinase, casein kinase II and S6 kinase II, have counterparts that are activated during M-phase in maturing sea star oocytes.

Identification of mitosis-specific p65 dimer as a component of human M phase-promoting factor

Antisera raised against two mitosis-specific protein kinases from human cells recognized a single 65-kDa polypeptide (p65) that is present in similar amounts in interphase and mitotic cell extracts. Immunoblot analysis of reduced and unreduced extracts revealed that p65 exists as a 65-kDa monomer during interphase but forms a 130-kDa disulfide-linked homodimer during mitosis. Several different antibodies recognizing the p34cdc2 protein kinase and cyclin B components of M phase-promoting factor (MPF) coprecipitated p65 from mitotic but not from interphase extracts. In addition, an anti-p65 immunoaffinity column substantially depleted mitotic extracts of histon H1 kinase activity assayed under conditions diagnostic for MPF. These results suggest that active human MPF may be a complex of p34cdc2, cyclin B, and dimeric p65. A sulfhydryl cycle, proposed in the earlier literature on the biochemistry of mitosis, might underlie the dimerization of p65 and formation of active MPF.

Identification and partial purification of a chromatin bound calmodulin activated histone 3 kinase from calf thymus

A calcium-calmodulin (Ca2(+)-CaM) stimulated histone H3 phosphorylating activity was identified as a component of a nuclear protein complex purified from a 150 mM NaCl extract of calf thymus chromatin. This activity bound to a CaM-Sepharose affinity column in a Ca2+ dependent manner and was eluted off the column in the presence of EGTA. Equilibrium centrifugation of the EGTA eluate on a sucrose density gradient revealed that the activity is a component of a larger complex identified at 25% sucrose. This complex consisted of two major proteins, having Mr of 65 and 75 kDa. Using [125I] CaM and the gel overlay technique it was shown that the 75 kDa protein is the major CaM binding protein in the complex.

The starfish egg mRNA responsible for meiosis reinitiation encodes cyclin

During meiotic maturation and early embryonic cycles, the activity of maturation-promoting factor (MPF) cycles in exact correspondence with the mitotic cycles. For the appearance of MPF activity in starfish, protein synthesis is required except in the first meiotic cycle. In order to identify newly synthesized proteins involved in the regulation of MPF activity, we extracted poly(A)+ RNA from starfish eggs, and found that the egg poly(A)+ RNA induced germinal vesicle breakdown (GVBD) upon injection into immature oocytes of starfish and Xenopus. The molecular size of the poly(A)+ RNA responsible for GVBD was estimated to be approximately 22S by sucrose density gradient centrifugation. Since these characteristics of the starfish egg poly(A)+ RNA are similar to those of cyclin mRNAs from sea urchin and surf clam eggs, we synthesized a 50-mer antisense-cyclin oligonucleotide probe coding for a part of the sea urchin cyclin cDNA and used this to screen starfish RNA. The Northern blot analysis showed that the starfish egg RNA contained cyclin homologous transcripts. Incubation of the starfish egg poly(A)+ RNA and the antisense-cyclin oligonucleotide with RNase H completely destroyed its GVBD-inducing activity. These results indicated that starfish cyclin mRNA was the only poly(A)+ RNA responsible for GVBD. We constructed a starfish egg cDNA library to clone starfish cyclin cDNA. The longest cDNA clone containing 2190 base pairs was sequenced. The longest open reading frame consisted of 395 amino acid residues, and the predicted molecular size was 48 kDa. Comparison of the deduced amino acid sequences of starfish cyclin with known cyclins indicated that the starfish cyclin belongs to the B-type. Injection of synthetic mRNA of starfish cyclin caused GVBD in immature oocytes of starfish and Xenopus, while injection of synthetic mRNA of human CDC2 had no effect. The Northern blot analysis of starfish RNA extracted at various stages of the meiotic cycles suggested that the starfish cyclin transcript was stored in its polyadenylated form even in immature oocytes and was further polyadenylated at maturation.

Mitosis-specific phosphorylation of nucleolin by p34cdc2 protein kinase

Nucleolin is a ubiquitous multifunctional protein involved in preribosome assembly and associated with both nucleolar chromatin in interphase and nucleolar organizer regions on metaphasic chromosomes in mitosis. Extensive nucleolin phosphorylation by a casein kinase (CKII) occurs on serine in growing cells. Here we report that while CKII phosphorylation is achieved in interphase, threonine phosphorylation occurs during mitosis. We provide evidence that this type of in vivo phosphorylation involves a mammalian homolog of the cell cycle control Cdc2 kinase. In vitro M-phase H1 kinase from starfish oocytes phosphorylated threonines in a TPXK motif present nine times in the amino-terminal part of the protein. The same sites which matched the p34cdc2 consensus phosphorylation sequence were used in vivo during mitosis. We propose that successive Cdc2 and CKII phosphorylation could modulate nucleolin function in controlling cell cycle-dependent nucleolar function and organization. Our results, along with previous studies, suggest that while serine phosphorylation is related to nucleolin function in the control of rDNA transcription, threonine phosphorylation is linked to mitotic reorganization of nucleolar chromatin.

Mitosis-specific phosphorylation of nucleolin by p34cdc2 protein kinase

Nucleolin is a ubiquitous multifunctional protein involved in preribosome assembly and associated with both nucleolar chromatin in interphase and nucleolar organizer regions on metaphasic chromosomes in mitosis. Extensive nucleolin phosphorylation by a casein kinase (CKII) occurs on serine in growing cells. Here we report that while CKII phosphorylation is achieved in interphase, threonine phosphorylation occurs during mitosis. We provide evidence that this type of in vivo phosphorylation involves a mammalian homolog of the cell cycle control Cdc2 kinase. In vitro M-phase H1 kinase from starfish oocytes phosphorylated threonines in a TPXK motif present nine times in the amino-terminal part of the protein. The same sites which matched the p34cdc2 consensus phosphorylation sequence were used in vivo during mitosis. We propose that successive Cdc2 and CKII phosphorylation could modulate nucleolin function in controlling cell cycle-dependent nucleolar function and organization. Our results, along with previous studies, suggest that while serine phosphorylation is related to nucleolin function in the control of rDNA transcription, threonine phosphorylation is linked to mitotic reorganization of nucleolar chromatin.

Activation of M-phase-specific histone H1 kinase by modification of the phosphorylation of its p34cdc2 and cyclin components

An M-phase-specific histone H1 kinase (H1K) has been described in a wide variety of eukaryotic cell types undergoing the G2/M transition in the cell division cycle. We have used p13suc1-Sepharose affinity chromatography to purify H1K to near homogeneity from matured starfish oocytes. A yield of 67% was obtained. Active H1K behaves as a 90- to 100-kD protein and appears to be constituted of equimolar amounts of cyclin and p34cdc2. The p34cdc2 subunit becomes tyrosine-dephosphorylated as the H1K is activated during entry of the oocytes into M phase, whereas the cyclin subunit is reciprocally phosphorylated. Acid phosphatase treatment of inactive p34cdc2/cyclin complex induces p34cdc2 dephosphorylation and three- to eightfold stimulation of the enzyme activity. These results suggest that active M-phase-specific H1K is constituted of both dephosphorylated p34cdc2 and phosphorylated cyclin.

Control of programmed cyclin destruction in a cell-free system

To ask what controls the periodic accumulation and destruction of the mitotic across the cell cycle, we have developed a cell-free system from clam embryos that reproduces several aspects of cyclin behavior. One or more rounds of cyclin proteolysis and resynthesis occur in vitro, and the destruction of the cyclins is highly specific. The onset, duration, and extent of cyclin destruction and the appropriately stagered disappearance of cyclin A and cyclin B are correctly regulated during the first cycle in the cell-free system. Just as in intact cells, lysates made from early interphase cells require further protein synthesis to reach the cyclin destruction point, and lysates made from later stages do not. Using the cell-free system we show that cyclin disappearance requires ATP and Mg2+. By combining lysates from different cell cycle stages, we show that (a) interphase lysates do not contain a dominant inhibitor of cyclin destruction and (b) the timing of cyclin destruction is determined by the cell cycle stage of the cytoplasm rather than the cell cycle stage of the substrate cyclins themselves. Among a large variety of agents tested, only a few affect cyclin destruction. Tosyl-lysine chlormethyl ketone (TLCK, a protease inhibitor), 6-dimethylaminopurine (6-DMAP, a kinase inhibitor), certain sulfhydryl-blocking agents, ZnCl2 and EDTA (but not EGTA) completely block cyclin destruction in vitro. Addition of 1 mM Ca2+ to the cell-free system has no effect on cyclin stability, but 5 mM Ca2+ leads to the rapid destruction of cyclins and a small number of other proteins.

Properties of a microtubule-associated cofactor-independent protein kinase from pig brain

A protein kinase activity was identified in pig brain that co-purified with microtubules through repeated cycles of temperature-dependent assembly and disassembly. The microtubule-associated protein kinase (MTAK) phosphorylated histone H1; this activity was not stimulated by cyclic nucleotides. Ca2+ plus calmodulin, phospholipids or polyamines. MTAK did not phosphorylate synthetic peptides which are substrates for cyclic AMP-dependent protein kinase, cyclic GMP-dependent protein kinase. Ca2+/calmodulin-dependent protein kinase II, protein kinase C or casein kinase II. MTAK activity was inhibited by trifluoperazine [IC50 (median inhibitory concn.) = 600 microM] in a Ca2+-independent fashion. Ca2+ alone was inhibitory [IC50 = 4 mM). MTAK was not inhibited by heparin, a potent inhibitor of casein kinase II, nor a synthetic peptide inhibitor of cyclic AMP-dependent protein kinase. MTAK demonstrated a broad pH maximum (7.5-8.5) and an apparent Km for ATP of 45 microM. Mg2+ was required for enzyme activity and could not be replaced by Mn2+. MTAK phosphorylated serine and threonine residues on histone H1. MTAK is a unique cofactor-independent protein kinase that binds to microtubule structures.

Nuclear envelope disassembly and nuclear lamina depolymerization during germinal vesicle breakdown in starfish

During germinal vesicle breakdown (GVBD) in starfish, the nuclear envelope disassembles before the nuclear lamina completely depolymerizes, judging from correlative ultrastructural, immunolabeling, and light microscopic analyses. At 13 degrees C, prophase-arrested oocytes of Pisaster ochraceus begin GVBD and rapidly undergo nuclear envelope disassembly about 50 min after addition of the maturation-inducing hormone 1-methyladenine (1-MA). The nuclear lamina of these oocytes, however, remains present for 10-20 min following the vesiculation of the nuclear envelope. Completion of GVBD, as evidenced by a blending of the nuclear contents with the surrounding cytoplasm, occurs within about 15 min after the nuclear lamina has fully depolymerized. Immunofluorescence studies also indicate that a marked increase in the phosphorylations of nuclear proteins precedes the structural reorganizations of the nuclear envelope and nuclear lamina during GVBD.

Cyclin is a component of the sea urchin egg M-phase specific histone H1 kinase

A so-called 'growth-associated' or 'M-phase specific' histone H1 kinase (H1K) has been described in a wide variety of eukaryotic cell types; p34cdc2 has previously been shown to be a catalytic subunit of this protein kinase. In fertilized sea urchin eggs the activity of H1K oscillates during the cell division cycle and there is a striking temporal correlation between H1K activation and the accumulation of a phosphorylated form of cyclin. H1K activity declines in parallel with proteolytic cyclin destruction of the end of the first cell cycle. By virtue of the high affinity of the fission yeast p13suc1 for the p34cdc2 protein, H1K strongly binds to p13-Sepharose beads. Cyclin, p34cdc2 and H1K co-purify on this affinity reagent as well as through several conventional chromatographic procedures. Anticyclin antibodies immunoprecipitate the M-phase specific H1K in crude extracts or in purified fractions. Sea urchin eggs appear to contain much less cyclin than p34cdc2, suggesting that p34cdc2 may interact with other proteins. These results demonstrate that cyclin and p34cdc2 are major components of the M-phase specific H1K.

M-phase-specific protein kinase from mitotic sea urchin eggs: cyclic activation depends on protein synthesis and phosphorylation but does not require DNA or RNA synthesis

Histone H1 kinase (H1K) undergoes a transient activation at each early M phase of both meiotic and mitotic cell cycles. The mechanisms underlying the transient activation of this protein kinase were investigated in mitotic sea urchin eggs. Translocation of active H1K from particulate to soluble fraction does not seem to be responsible for this activation. H1K activation cannot be accounted for by the transient disappearance of a putative H1K inhibitor present in soluble fractions of homogenates. Aphidicolin, an inhibitor of DNA synthesis, and actinomycin D, an inhibitor of RNA synthesis, do not impede the transient appearance of H1K activity. H1K activation therefore does not require DNA or RNA synthesis. Fertilization triggers a rise in intracellular pH responsible for the increase of protein synthesis. H1K activation is highly dependent on the intracellular pH. Ammonia triggers an increase of intracellular pH and stimulates protein synthesis and H1K activation. Acetate lowers the intracellular pH, decreases protein synthesis, and blocks H1K activation. Protein synthesis is an absolute requirement for H1K activation as demonstrated by their identical sensitivities to emetine concentration and to time of emetine addition. About 60 min after fertilization, H1K activation and cleavage become independent of protein synthesis. The concentration of p34, a homolog of the yeast cdc2 gene product which has been recently shown to be a subunit of H1K, does not vary during the cell cycle and remains constant in emetine-treated cells. H1K activation thus requires the synthesis of either a p34 postranslational modifying enzyme or another subunit. Finally, phosphatase inhibitors and ATP slow down in the in vitro inactivation rate of H1K. These results suggest that a subunit or an activator of H1K is stored as an mRNA in the egg before mitosis and that full activation of H1K requires a phosphorylation.

Mitogen-responsive S6 kinase

Many cell lines respond to mitogenic stimuli (serum, growth factors) with rapid phosphorylation of the ribosomal protein S6 at several serine sites. We have tried to identify the protein kinase(s) mediating this effect of growth stimuli. Examining post-DEAE chromatography fractions of S49 kin- cell extracts, we could detect a highly active effector-independent S6 kinase with specificity for serine residues. The study was extended to the presumably homologous human enzyme, using HeLa S3 cells as model system. Activity yields increased up to sevenfold when exhausted HeLa cells were supplied with fresh medium plus serum. The enzyme uses ATP, not GTP, as cosubstrate, 40-S or 80-S (reassociated from subunits) ribosomal particles being substrate. The optimal K+ concentration, measured at 3 mM Mg2+, is 35 mM. Under optimized assay conditions S6 phosphorylation proceeded faster in vitro than it appeared to do in vivo. The apparent Mr of the enzyme, as estimated by gel filtration on Sephadex G-100, is 56,000 (determination in the presence of 200 mM KCl in 25 mM phosphate buffer). Tighter binding to DEAE-Sephacel and higher specificity for S6 distinguishes this enzyme from the following S6-phosphorylating protein kinases: protein kinase C, protease-activated kinase II, histone-4 phosphotransferase and an enzyme with the properties of casein kinase I. In published summaries of observations shown here and in a follow-up study with chick embryo fibroblasts, the enzyme(s) has been referred to as mitogen-responsive S6 kinase(s) [Martini, O. H. W. and Lawen, A. (1985) in Hormones and cell regulation (Dumont, J. E., Hamprecht, B. and Nunez, J., eds) vol. 9, pp. 411-412, Elsevier Company, North-Holland, Amsterdam; Lawen, A. and Martini, O. H. W. (1985) FEBS Lett. 185, 272-276].

Regulation of p34cdc2 protein kinase during mitosis

The cell-cycle timing of mitosis in fission yeast is determined by the cdc25+ gene product activating the p34cdc2 protein kinase leading to mitotic initiation. Protein kinase activity remains high in metaphase and then declines during anaphase. Activation of the protein kinase also requires the cyclin homolog p56cdc13, which also functions post activation at a later stage of mitosis. The continuing function of p56cdc13 during mitosis is consistent with its high level until the metaphase/anaphase transition. At anaphase the p56cdc13 level falls dramatically just before the decline in p34cdc2 protein kinase activity. The behavior of p56cdc13 is similar to that observed for cyclins in oocytes. p13suc1 interacts closely with p34cdc2; it is required during the process of mitosis and may play a role in the inactivation of the p34cdc2 protein kinase. Therefore, the cdc25+, cdc13+, and suc1+ gene products are important for regulating p34cdc2 protein kinase activity during entry into, progress through, and exit from mitosis.

Protein phosphorylation during 1-methyladenine-induced maturation of Asterias oocytes

Maturation was induced in Asterias oocytes with 1-methyladenine (1-MA) at a final concentration of 2 microM. At 5, 10, and 30 min of treatment, oocytes were homogenized and the cytosolic fraction was prepared. The cytosol was incubated with [gamma-32P]ATP and [gamma-32P]GTP. The phosphorylated proteins were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and the radioactivity in the gels was determined by autoradiography. The cytosol prepared from 1-MA-treated oocytes incubated with [gamma-32P]ATP showed a marked increase in the radiolabeling of proteins with estimated molecular weights of 70,000 and 62,000 Da. With [gamma-32P]GTP a 56,000-Da protein showed increased radiolabeling. The present finding suggests that an early biochemical event of 1-MA-induced oocyte maturation in Asterias is the stimulation of phosphorylation of specific proteins.

Activation of human CDC2 protein as a histone H1 kinase is associated with complex formation with the p62 subunit

p34 kinase, the product of the CDC2 gene, is a cell-cycle regulated protein kinase that is most active during mitosis. In HeLa cells, p34 kinase has previously been shown to exist in both a low- and a high-molecular-mass form, the latter of which is only found in cells in the G2/M phase of the cell cycle and contains a 62-kDa subunit. Here we show that although each form of the kinase phosphorylates casein in vitro, only the high-molecular-mass form uses histone H1 as substrate. The high-molecular-mass form of p34 kinase from nocodazole-treated HeLa cells was purified 6700-fold. The apparent molecular mass of the mitotic CDC2-encoded protein kinase complex was 220 kDa. The purified enzyme phosphorylated not only its endogenous 62-kDa subunit but also phosphorylated histone H1 with a Km of 3 microM and used ATP 40 times more efficiently than GTP (Km 54 microM and 2 mM, respectively). The enzyme activity was unaffected by cAMP, calcium/calmodulin, or by the heat-stable inhibitor of cAMP-dependent protein kinase. These characteristics are typical of growth-associated histone H1 kinase from different organisms. These results suggest that CDC2 protein may be activated as an M-phase-specific protein kinase in part by its association with the p62 subunit.

The role of cyclin B in meiosis I

In clams, fertilization is followed by the prominent synthesis of two cyclins, A and B. During the mitotic cell cycles, the two cyclins are accumulated and then destroyed near the end of each metaphase. Newly synthesized cyclin B is complexed with a small set of other proteins, including a kinase that phosphorylates cyclin B in vitro. While both cyclins can act as general inducers of entry into M phase, the two are clearly distinguished by their amino acid sequences (70% nonidentity) and by their different modes of expression in oocytes and during meiosis. In contrast to cyclin A, which is stored solely as maternal mRNA, oocytes contain a stockpile of cyclin B protein, which is stored in large, rapidly sedimenting aggregates. Fertilization results in the release of cyclin B to a more disperse, soluble form. Since the first meiotic division in clams can proceed even when new protein synthesis is blocked, these results strongly suggest it is the fertilization-triggered unmasking of cyclin B protein that drives cells into meiosis I. We propose that the unmasking of maternal cyclin B protein allows it to interact with cdc2 protein kinase, which is also stored in oocytes, and that the formation of this cyclin B/cdc2 complex generates active M phase-promoting factor.

Insulin and progesterone activate a common synthetic ribosomal protein S6 peptide kinase in Xenopus oocytes

A synthetic peptide Arg-Arg-Leu-Ser-Ser-Leu-Arg-Ala, the structure of which is based on that of a phosphorylated sequence in ribosomal protein S6, was employed as a probe for stimulated kinase activity in Xenopus laevis oocytes induced to mature with insulin or progesterone. Insulin elicited an early (20-30 min) 3-fold stimulation of S6 peptide phosphorylating activity that was not evident with progesterone. However, both hormones produced a delayed 7-12-fold stimulation of S6 peptide phosphorylating activity at the time of germinal vesicle breakdown. The results of DEAE-Sephacel, Sephacryl S-200, TSK-400, and heparin-Sepharose chromatographic fractionation experiments imply that a common S6 peptide kinase is activated as a consequence of short and long term insulin exposure, as well as in long term progesterone treatment of oocytes. Omission of potassium from the oocyte culture medium greatly facilitated insulin-induced meiotic maturation.

Activation of myelin basic protein kinases during echinoderm oocyte maturation and egg fertilization

At least five activated protein kinases were detectable in soluble extracts from maturing as compared to immature sea star oocytes. These kinases could be distinguished on the basis of the time courses of their activation following exposure of the oocytes to 1-methyladenine, their substrate specificities, and their chromatographic properties on DEAE-Sephacel and Sephacryl S-200. A histone H1 kinase (HH1K) (Mr 110,000) underwent maximal activation near the time of 1-methyladenine-induced germinal vesicle breakdown (GVBD). When myelin basic protein (MBP) was used as a substrate, HH1K and two additional kinases (MBPK-I and MBPK-II) were detectable. MBPK-II (Mr 110,000) was fully activated at the time of GVBD, whereas peak activation of MBPK-I (Mr 45,000) occurred after this event. Two "ribosomal protein S6 kinases" (S6K-I and S6K-II) could be detected with a synthetic peptide (RRLSSLRA), which was patterned after a major phosphorylation site in S6. The two S6 kinases (Mr 110,000 for both) underwent activation post-GVBD. HH1K and S6K-I coeluted from DEAE-Sephacel at a conductivity of 5.5-6.0 mmho, whereas MBPK-I, MBPK-II, and S6K-II coeluted from this resin in a second peak at a conductivity = 10-11 mmho. The HH1K and MBPK-II activities both declined prior to the emission of the first polar body (i.e., meiotic cell division), but the MBPK-I, S6K-I, and S6K-II activities remained elevated during this time. The activities of these kinases were also examined during the early cell divisions in sea urchin embryos. Within 5 min after fertilization, the high level of MBPK-I activity in sea urchin eggs rapidly declined. However, along with the HH1K and MBPK-II activities, the MBPK-I activity was transiently increased prior to each cell division. No appreciable postfertilization changes in the S6K-I and S6K-II activities were apparent during the first three cycles of cell division.