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.

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.

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.

Starfish oocyte maturation: evidence for a cyclic AMP-dependent inhibitory pathway

Oocyte maturation (meiosis reinitiation) in starfish is induced by the natural hormone 1-methyladenine (1-MeAde). Cyclic AMP seems to play a negative role in maturation since 1-MeAde triggers a decrease of the oocyte cAMP concentration and since intracellular microinjections of cAMP delay or inhibit maturation. Cyclic GMP is also inhibitory but other nucleotides such as cCMP, cIMP, and cUMP are inactive. The involvement of cAMP and cGMP in the control of oocyte maturation has been further investigated by the use of the stereoisomers of the phosphodiesterase-stable adenosine and guanosine 3',5'-phosphorothioates (cAMPS and cGMPS). The Sp isomers of cAMPS and cGMPS respectively activate cAMP-dependent protein kinase and cGMP-dependent kinase, while the Rp isomers inhibit the kinases. Extracellular addition of these cAMPS and cGMPS isomers has no effect on the oocytes. Intracellular microinjection of the kinase-activating (Sp)-cAMPS and (Sp)-cGMPS delays or inhibits 1-MeAde-induced maturation in a concentration-dependent manner (I50, 30 and 300 microM, respectively). Microinjections of (Rp)-cAMPS and (Rp)-cGMPS have no inhibitory effects and neither trigger nor facilitate maturation. Using various analogs, we found that the delaying or inhibiting effect is restricted to the compounds activating cAMP-dependent kinase, while the compounds inactive on or inhibiting the kinase have no effects on maturation. The inhibitory effect of (Sp)-cAMPS can be reversed by comicroinjection of the heat-stable inhibitor of cAMP-dependent protein kinase, by comicroinjection of the antagonist (Rp)-cAMPS, or by an increase in the 1-MeAde concentration. The negative effects of (Sp)-cAMPS or (Sp)-cGMPS are observed only when these isomers are microinjected during the hormone-dependent period. These results suggest that a cAMP-dependent inhibitory pathway participates in the maintenance of the prophase arrest of oocytes and that 1-MeAde acts both by inhibiting this negative pathway (dis-inhibitory pathway) and by stimulating a parallel activatory pathway leading to oocyte maturation. The generality of this mechanism is discussed.

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.

cdc2 is a component of the M phase-specific histone H1 kinase: evidence for identity with MPF

A so-called "growth-associated" or "M phase-specific" histone H1 kinase (H1K) has been described in a wide variety of eukaryotic cell types. In starfish oocytes, the hormone 1-methyladenine triggers synchronous meiotic divisions that are accompanied by a rapid 30-fold stimulation of H1K activity. We have substantially purified this activated enzyme and find that it is enriched for a protein of 34 kd. Quantitative immunoblotting of the column fractions with antibodies raised against p34, the product of the fission yeast cdc2 gene, revealed complete coelution of the H1K activity and a 34 kd anti-cdc2 cross-reactive protein. Starfish H1K also displayed the same apparent molecular weight, on a molecular sizing column, as the mitotically activated p13/p34/p62 protein kinase complex of HeLa cells. p13, the product of the fission yeast suc1+ gene, interacts tightly with p34 in yeast, Xenopus, and HeLa cells. H1K from starfish binds strongly to p13-Sepharose and the time course of 1-methyladenine-induced H1K activation, whether assayed in crude extract or on p13-Sepharose beads, is identical. These results indicate that a cdc2 homolog is a subunit of the M phase-specific H1K of starfish meiotic oocytes. Since this protein is also a subunit of the M-phase promoting factor (MPF) of Xenopus oocytes, we suggest that H1K and MPF are the same entity, and that histone H1 is likely to be one substrate of the pleiotropic MPF.

Cyclic activation of histone H1 kinase during sea urchin egg mitotic divisions

Fertilized sea urchin eggs undergo a series of rapid and synchronized mitotic divisions. Extracts were made at various times throughout the first three mitotic divisions and assayed for phosphorylating activity toward histone H1. Histone H1 kinase (HH1K) undergoes a transient activation (8- to 10-fold increase) 20 min before each cleavage. The amplitude of the HH1K peak strongly depends on the synchrony of the egg population. Concomitant cytological observations show that the time-course of HH1K correlates with the time-course of nuclear envelope breakdown and of metaphase. This correlation is observed at each cell division cycle. HH1K from each of the three first mitoses show identical time- and concentration-dependence curves as well as identical dose-inhibition curves with 6-dimethylaminopurine and quercetin, suggesting that the same (group of) kinase(s) is (are) activated before each cleavage. Ionophore A23187 does not trigger, but inhibits, HH1K activation; however, partial activation of the eggs with ammonia at pH 9.0 (but not at pH 8.0) triggers the transient HH1K activation. Appearance of the HH1K cycle requires protein synthesis since it is completely abolished in emetine-treated eggs. Although cytochalasin B blocks egg cleavage, it does not inhibit HH1K activation nor nuclear divisions. A prolonged HH1K activation cycle is observed in eggs arrested in metaphase with colchicine or nocodazole. Despite the existence of a cycle in cAMP concentration during mitosis, forskolin, an activator of adenylate cyclase, does not modify the time-course of HH1K activation and of cell division. The cycling HH1K is independent of calcium-calmodulin, calcium-phospholipids, or cyclic AMP. It clearly resembles the mammalian "growth-associated histone kinase." The relationship between the transient activation of HH1K and the intracellular mitotic factors driving the cell cycle is discussed.

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

DEAE-Sephacel chromatography of cytosolic extracts from sea star oocytes resolved at least two distinct peaks of maturation-activated protein kinase activity, each of which catalyzed the phosphorylation of histone H1, ribosomal protein S6, and Arg-Arg-Leu-Ser-Ser-Leu-Arg-Ala (RRLSSLRA), a synthetic peptide based on the sequence of a phosphorylation site in the latter protein. The first peak (elution conductivity approximately equal to 6 mmho) contained the major activated kinase with respect to the phosphorylation of histone H1, and the second peak (elution conductivity approximately equal to 10.5 mmho) contained the major activated kinase with respect to the phosphorylation of S6 and RRLSSLRA. These kinase activities were barely detectable in extracts from immature oocytes. The major stimulated histone H1 kinase exhibited an apparent Mr of approximately 90 000 on Sephacryl S-300 but eluted from TSK-400 with an apparent Mr of approximately 10 000. After DEAE-Sephacel fractionation, this kinase was shown to utilize both ATP (apparent Km approximately equal to 45 microM) and GTP (apparent Km approximately equal to 10 microM), although the Vmax was 8-fold higher with ATP than with GTP. The enzyme phosphorylated histone H1 with an apparent Km approximately equal to 50 micrograms/mL. Its properties resembled those of the growth-associated histone kinase. The major stimulated RRLSSLRA kinase had an apparent Mr of approximately 84 000 on Sephacryl S-300 and approximately 40 000 on TSK-400. After DEAE-Sephacel chromatography, this kinase selectively utilized ATP (apparent Km approximately equal to 25 microM).(ABSTRACT TRUNCATED AT 250 WORDS)

Differential regulation of histone H1 and ribosomal S6 kinases during sea star oocyte maturation

In the preceding paper [Pelech, S.L., Meijer, L., & Krebs, E.G. (1987) Biochemistry (preceding paper in this issue)], at least three activated kinases were detected in soluble extracts from sea star oocytes induced to undergo maturation by 1-methyladenine (1-MeAde). Coincident with nuclear envelope breakdown (20 min after exposure to 1-MeAde), there was a rapid activation of a histone H1 kinase that eluted from DEAE-Sephacel with a conductivity of approximately 6 mmho. By contrast, 60-min treatment of the oocytes with 1-MeAde was required for maximal activation of two kinases, each of which phosphorylated a synthetic peptide, Arg-Arg-Leu-Ser-Ser-Leu-Arg-Ala (RRLSSLRA), patterned after a phosphorylation site sequence from ribosomal protein S6. These RRLSSLRA kinases were released from DEAE-Sephacel with elution conductivities of approximately 6 and approximately 10.5 mmho. The 1-MeAde dose-response curves for maturation induction and activation of the histone H1 and RRLSSLRA kinases were superimposable. Both oocyte maturation and the activation of the kinases required the presence of 1-MeAde during the hormone-dependent period. When 1-MeAde was removed after this period, full histone H1 kinase activation still occurred and maturation was induced. Forskolin pretreatment of the oocytes, by elevating the basal cAMP level more than 35-fold, doubled the hormone-dependent period and similarly delayed the onset of histone H1 kinase activation by 1-MeAde. However, postmaturation activation of the RRLSSLRA kinases was completely blocked by forskolin.(ABSTRACT TRUNCATED AT 250 WORDS)

Starfish oocyte maturation: 1-methyladenine triggers a drop of cAMP concentration related to the hormone-dependent period

Oocyte maturation (meiosis reinitiation) in starfish is induced by the natural hormone 1-methyladenine (1-MeAde). Oocytes of Evasterias troschelii contain 0.43 pmole cyclic AMP/mg protein and 0.47 pmole cyclic GMP/mg protein. Upon stimulation by 1-MeAde the oocytes undergo a moderate (10-30%) decrease in their cAMP concentration. The concentration of cGMP remains unaltered. Oocytes treated with forskolin, an activator of adenylate cyclase, increase their cAMP concentration over 35-fold, up to 16 pmole cAMP/mg protein. When stimulated by 1-MeAde these forskolin-pretreated oocytes undergo a major (50-70%) decrease in their cAMP concentration. A similar decrease is triggered by mimetics of 1-MeAde, such as dithiothreitol, arachidonic acid (AA), and 8-hydroxyeicosatetraenoic acid (8-HETE), but not by adenine which is inactive. 1-MeAde-stimulated oocytes of Pisaster ochraceus also undergo a decrease in cAMP content, the size of which is increased by forskolin. Although a decrease in cAMP begins at sub-threshold 1-MeAde concentrations, the maximal decrease occurs at the same concentration of 1-MeAde needed for maturation induction and a further 1000-fold increase of the 1-MeAde concentration has no further effect. Upon removal of 1-MeAde, the cAMP concentration immediately increases to its original level. Sequential addition and removal of 1-MeAde triggers a sequential decrease and increase of the cAMP concentration, illustrating the continuous requirement for 1-MeAde for eliciting the decrease. Successive additions of 1-MeAde, however, do not trigger further decreases of the cAMP concentration. The temperature dependences of the cAMP concentration decrease and of the hormone-dependent period (HDP; the time of contact with 1-MeAde required for induction of maturation) are closely related. Forskolin, which increases the cAMP concentration, also increases the duration of the HDP (2.5-fold), delays the time course of protein phosphorylation burst and germinal vesicle breakdown, and inhibits AA- and 8-HETE-induced maturation. We conclude that 1-MeAde triggers a drop in cAMP concentration, which is tightly associated with the hormone-dependent period of oocyte maturation.

Stereospecific induction of starfish oocyte maturation by (8R)-hydroxyeicosatetraenoic acid

Oocyte maturation (meiosis reinitiation) in starfish is induced by the natural hormone 1-methyladenine. This induction of meiotic divisions can be triggered also by four fatty acids: 5,8,11-20:3; 5,8,11,14-20:4 (arachidonic acid); 6,9,12,15-20:4; 5,8,11,14,17-20:5, all other fatty acids being completely inactive. This maturation triggered by eicosanoids occurs in the micromolar range and is facilitated by the presence of calcium. A variety of arachidonic acid derivatives (esters, epoxides, etc.) and metabolites (cyclooxygenase and lipoxygenase products) has been tested; the biological activity is restricted to 8-hydroxyeicosatetraenoic acid (8-HETE), other mono- and poly-HETEs being completely inactive. Maturation triggered by 8-HETE occurs around 10 nM and is insensitive to the presence of calcium. 8-HETE methyl ester and 8-hydroperoxyeicosatetraenoic acid are able to induce maturation at higher concentrations. Both (8S) and (8R) stereoisomers have been tested; the biological activity is strictly restricted to the (8R) isomer. 8-HETE triggers a complete maturation, i.e. maturation-promoting factor appearance, germinal vesicle breakdown, emission of the polar bodies, and formation of a female pronucleus. (8R)-HETE, but not (8S)-HETE, triggers the typical decrease in cyclic AMP concentration induced by 1-methyladenine and the burst of protein phosphorylation associated with maturation. Starfish oocytes oxidize exogenous arachidonic acid into 8-HETE and other HETEs. 8-HETE was identified, after high pressure liquid chromatography purification, by gas chromatography mass spectrometry. Furthermore, it was found that the starfish oocytes only produce the (8R)-HETE isomer. This highly stereospecific induction of oocyte maturation by (8R)-HETE suggests that this fatty acid, or a very closely related fatty acid, may play a role in the transduction of the 1-methyladenine message at the plasma membrane level.

Contrasting effects of fatty acids on oocyte maturation in several starfish species

Oocyte maturation (meiosis reinitiation) in starfish is induced by the natural hormone 1-methyladenine. In some species (group 2) oocyte maturation can be induced by micromolar concentrations of a few fatty acids such as arachidonic and eicosapentaenoic acids or by nanomolar concentrations of hydroxyeicosatetraenoic acid. Complete maturation is triggered: increased protein phosphorylation, appearance of the cytoplasmic "maturation-promoting factor", germinal vesicle breakdown, emission of the two polar bodies and formation of the female pronucleus. In other species (group 1), however, no maturation can be induced by the fatty acids active in the species of group 2, despite a large variety of experimental conditions.

Protein phosphorylation and oocyte maturation. II. Inhibition of starfish oocyte maturation by intracellular microinjection of protein phosphatases 1 and 2A and alkaline phosphatase

Oocyte maturation (meiosis re-initiation) in starfish is induced by the natural hormone 1-methyladenine (1-MeAde). Following hormonal stimulation of the oocyte, an intracellular Maturation Promoting Factor (MPF) appears in the cytoplasm which triggers nuclear envelope breakdown and maturation divisions. Microinjection of pure preparations of the catalytic subunits of protein phosphatases 1 and 2A inhibits 1-MeAde-induced maturation in a dose-dependent manner. Calmodulin-dependent protein phosphatase 2B is inefficient. Maturation induced by mimetics of 1-MeAde, such as dithiothreitol (DTT), methylglyoxal-bis(guanylhydrazone) (MGBG), 8-hydroxyeicosatetraenoic acid (8 HETE) and arachidonic acid (AA) is also inhibited by these protein phosphatases. In all cases inhibition can be reversed by increasing the concentration of 1-Me-Ade or of mimetic. Alkaline phosphatase also inhibits maturation in a dose-dependent way and in a reversible manner. Microinjection of protein phosphatase is still effective when preformed long after the end of the hormone-dependent period, and can even be effective a few minutes before the breakdown of the nuclear envelope. No detectable MPF activity is found in 1-MeAde-treated phosphatase-injected oocytes. However, microinjection of phosphatase 2A simultaneously with MPF (obtained from 1-MeAde-treated donors) does not result in inhibition. These results constitute direct evidence for the necessity of an elevated level of phosphorylated proteins for MPF activity and maturation. The mode of action of 1-MeAde in inducing starfish oocyte maturation is discussed in relation to protein phosphorylation.

Protein phosphorylation and oocyte maturation. I. Induction of starfish oocyte maturation by intracellular microinjection of a phosphatase inhibitor, alpha-naphthylphosphate

Oocyte maturation (meiosis re-initiation) in starfish is induced by the natural hormone 1-methyladenine (1-MeAde). Following hormonal stimulation of the oocyte, an intracellular Maturation Promoting Factor (MPF) appears in the cytoplasm which triggers nuclear envelope breakdown and maturation divisions. alpha-Naphthylphosphate (alpha-NP), a widely used phosphatase inhibitor/substrate, was found to induce oocyte maturation when microinjected intracellularly (50% maturation of 3.5 mM; 100% above 6mM, final intracellular concentration) into oocytes of Marthasterias and Asterias but not of Astropecten. As 1-MeAde, alpha-NP triggers a complete maturation, i.e. germinal vesicle breakdown, extrusion of the two polar bodies and formation of the female pronucleus. The kinetics of alpha-NP-induced maturation (35-45 min) is, however, longer than the kinetics of 1-MeAde-induced maturation (18-20 min). The addition of alpha-NP externally to oocytes does not trigger maturation. Among several reported phosphatase inhibitors, including two natural protein phosphatase inhibitors and several products structurally related to alpha-NP, only alpha-NP was found capable of inducing maturation when microinjection into oocytes. alpha-NP triggers the appearance of MPF activity in the cytoplasm of oocytes into which it has been injected. Although alpha-NP-induced maturation is insensitive to inhibitors whose action is known to be restricted to the hormone-dependent period (such as the protease inhibitor leupeptin), it is blocked by inhibitors of MPF action (such as nicotinamide and lithium). Finally it was found that alpha-NP-induced maturation is inhibited by simultaneous microinjection of protein phosphatase-2A; also, alpha-NP, classically used as an inhibitor of acid and alkaline phosphatases, is able to inhibit protein phosphatases, is able to inhibit protein phosphatases 1 and 2 A. The addition of alpha-NP to oocytes increases the level of phosphorylated proteins. These results constitute direct evidence that an elevated level of phosphorylated proteins is sufficient to trigger MPF activity and to induce maturation.

Arachidonic acid, 12- and 15-hydroxyeicosatetraenoic acids, eicosapentaenoic acid, and phospholipase A2 induce starfish oocyte maturation

In starfish oocyte maturation (meiosis reinitiation) is induced by the natural hormone 1-methyladenine (1-Me-Ade). This paper shows that arachidonic acid (AA) induces oocyte maturation at concentrations above 0.5 microM. This maturation shares many characteristics with 1-MeAde-induced maturation: same kinetics, same required contact time, same stimulations of protein phosphorylation and sodium influx. Although calcium facilitates the AA-induced but not the 1-MeAde-induced maturation, AA, like 1-MeAde, does not stimulate the uptake of calcium. Calcium does not facilitate the uptake of AA by oocytes. Out of 36 different fatty acids (saturated and unsaturated), only eicosatetraenoic (AA) and eicosapentaenoic acids were found to mimic 1-MeAde. Calcium-dependent phospholipases A2 from bee venom and Naja venom also induce maturation (0.1-1 unit/ml) when added externally to the oocytes. Phospholipase A2 inhibitors (quinacrine, bromophenacylbromide) block maturation; inhibition is reversed by increasing the 1-MeAde concentration and only occurs during the hormone-dependent period. AA is usually metabolized through oxidation by cyclooxygenase or lipoxygenase. Cyclooxygenase inhibitors (acetylsalicylic acid, indomethacin, tolazoline) do not block maturation; prostaglandins E2, D2, F2 alpha, I2, and thromboxane B2 do not induce meiosis reinitiation. On the other hand, lipoxygenase inhibitors (quercetin, butylated hydroxytoluene, and eicosatetraynoic acid) block 1-MeAde-induced maturation; although leukotrienes (A4, B4, C4, D4, E4) have no effects on oocytes, two other lipoxygenase products, 12- and 15-hydroxyeicosatetraenoic acids (and their corresponding hydroperoxy-) induce oocyte maturation (around 1 microM). The possible mode of action of the fatty acids inducing oocyte maturation is discussed.

Calmodulin in starfish oocytes. II. Trypsin treatment suppresses the trifluoperazine-sensitive step

The 1-methyladenine-induced oocyte maturation in starfish is reversibly inhibited by the anticalmodulin drug, trifluoperazine (TFP). However, when oocytes are exposed for 10 min to trypsin, they lose their sensitivity to TFP. Trypsin does not alter the length of the hormone-dependent period (1-methyladenine minimal contact time) or the 1-methyladenine concentration requirements. Trypsin-treated oocytes remain sensitive to other maturation inhibitors such as procaine, theophylline, caffeine, and D-600. Trypsin exposure modifies the protein pattern composition of the oocyte cortex (breakdown of a 140-kDa protein). TFP binding site localization was studied using fluorescence microscopy: in addition to a general diffuse fluorescence, staining is localized to probably acidic granules located in the cortex. Results are discussed in relation to calmodulin and plasma membrane calmodulin-dependent enzyme involvement in the stimulation of starfish oocyte maturation.

Immobilized methylglyoxal-bis(guanylhydrazone) induces starfish oocyte maturation

Methylglyoxal-bis(guanylhydrazone) diHCl (MGBG), an inhibitor of S-adenosylmethionine decarboxylase, was found to induce starfish oocyte maturation at concentrations above 30 microM. Among several analogs of MGBG three induce oocyte maturation and one lacks the maturation-inducing activity while possessing the S-adenosylmethionine decarboxylase-inhibiting activity. Although MGBG is required during a slightly longer period than the natural hormone 1-methyladenine (1-MeAde), the maturation kinetics are identical. MGBG-induced maturation is sensitive to the same inhibitors as 1-MeAde-induced maturation (theophylline, caffeine, procaine, nicotine, NH4Cl, dansylcadaverine, vinblastine, R24571, and trifluoperazine). Inhibition is reversed by increasing the MGBG concentration. MGBG also induces an increase of protein phosphorylation. MGBG and 1-MeAde were separated on the basis of charcoal adsorption, MgSO4 precipitation, and thin-layer chromatography. MGBG covalently linked to CH-Sepharose 4B induces maturation in oocytes whose jelly layer and vitelline coat have been removed by a moderate pronase treatment, but not in the untreated oocytes. The MGBG-CH-Sepharose 4B beads come in close contact with the plasma membrane only in the pronase-treated oocytes. The mode of action of MGBG and the implications of these results in the purification of the 1-MeAde receptor are discussed.

Activation of calmodulin-dependent NAD+ kinase by trypsin

Sea urchin egg NAD+ kinase (ATP:NAD+ 2'-phosphotransferase, EC 2.7.1.23), a calmodulin-dependent enzyme, can be activated by a moderate treatment with trypsin in a similar fashion to calmodulin. Stimulation by trypsin is dependent on its concentration (half-maximal dose: 1.5 microgram/ml) but independent of the presence of calcium. This suggests that limited proteolysis is able to activate NAD+ kinase as described for several other calmodulin-activated enzymes and that these enzymes may interact with calmodulin in a similar way.