Involvement of glutathione in the inhibition of sea urchin egg mitosis by phenyl glyoxal

Cell division in fertilized sea urchin eggs was reversibly inhibited when the ketoaldehyde phenyl glyoxal (PG) at a concentration of 0.1 mM was added to eggs for ten minutes prior to the formation of the mitotic spindle. We investigated whether inhibition of mitosis was due to PG binding to the cell surface (as previously suggested by Stein and Berestecky, '74) or to some intracellular effect. When 14C-PG was added to eggs, label was readily taken up into the egg cytoplasm; very little label was associated with the egg surface. In the cytoplasm PG combined with equimolar amounts of reduced glutathione (GSH), decreasing the levels of cellular GSH to less than 15% of normal and accounting for at least 50% of the PG taken up by eggs. The concentrations of oxidized and protein-bound glutathione were unaffected by PG treatment. We showed that glyoxalase enzymes were present in sea urchin eggs and were capable of metabolizing the PG-GSH complex, thereby restoring GSH to normal levels after PG was removed from the sea water. Though some other effect of PG cannot be ruled out, the major fate of PG in eggs was to combine with GSH, and the transient decrease in GSH which resulted could lead to inhibition of mitosis. While other reports (Nath and Rebhun, '76; Oliver et al., '76) have shown that reagents which oxidize GSH disrupt microtubule-related events, our results showed that such inhibition could be caused by decreased GSH levels alone.     

Studies on cyclic AMP levels and phosphodiesterase activity in developing sea urchin eggs : Effects of puromycin, 6-dimethylamino purine and aminophylline

Cyclic adenosine monophosphate (CAMP) was measured in sea urchin eggs by the binding assay method of Gilman and with a radioimmune assay procedure. Intracellular concentrations of the nucleotide in unfertilized eggs were about 1.5 × 10⁻⁷ M and rose to about 3 times this value at first cleavage. Aminophylline, a known inhibitor of phosphodiesterase was shown to cause an increase in intracellular levels of CAMP by first cleavage and to inhibit phosphodiesterase activity in homogenates of both unfertilized and fertilized eggs. Puromycin and its purine component, 6-dimethylaminopurine (DMAP), did not cause an increase in intracellular CAMP levels and did not inhibit phosphodiesterase activity at concentrations an order of magnitude higher than those at which they inhibit cell division.     

The glutathione thiol-disulfide status in the sea urchin egg during fertilization and the first cell division cycle

The intracellular levels of GSH, GSSG, and protein-glutathione disulfide (protein-SSG) have been measured in the eggs and developing embryos of the sea urchins Lytechinus pictus and Strongylocentrotus purpuratus. Total cellular glutathione is maintained in a very highly reduced state during these initial stages of development. Thus for unfertilized eggs of L. pictus the results (μmol/g dry weight) were 11 ± 1 for GSH, 0.02 ± 0.01 for GSSG, and 0.07 ± 0.02 for protein-SSG. No significant change in these values was observed upon fertilization of the eggs or during the first cell division cycle. The values obtained with S. purpuratus were somewhat greater, but were also found to exhibit no significant variations upon fertilization or cell division. These observations indicates that changes in the total cellular glutathione thiol-disulfide status are not involved in the control mechanisms which operate during fertilization or the first cell division cycle in the sea urchin egg.     

CHANGES IN ACTIVITIES OF THYMIDYLATE SYNTHASE AND DIHYDROFOLATE REDUCTASE IN SEA URCHIN EGGS AFTER FERTILIZATION

Thymidylate synthase activity in sea urchin eggs increases just after fertilization and decreases 30 min later. Then, cyclic variation in the activity occurs in association with the cleavage cycle. Dihydrofolate reductase activity in fertilized eggs is almost the same as in unfertilized eggs and shows no marked change within 3 hr after fertilization. Aminopterin, an analogue of dihydrofolate, inhibits dihydrofolate reductase, and arrests cleavage. On incubation in sea water containing aminopterin (20-100μM) from the time of fertilization, the development of Clypeaster and Pseudocentrotus eggs was arrested at the 32–64 cell stage, and that of Anthocidaris eggs was arrested at the morula stage. Dihydrofolate (100μM) counteracts the inhibitory effect of aminopterin on egg cleavage. Thymidine at concentrations above 10μM also prevents inhibition by aminopterin. Other deoxyribonucleosides at concentrations of 10μM to 100μM do not affect inhibition of egg cleavage by aminopterin. Deoxyadenosine at concentrations above 5 mM inhibits egg cleavage, but other deoxyribonucleosides have no effect.     

Rho, Rho-kinase, and the actin cytoskeleton regulate the Na+ -H+ exchanger in sea urchin eggs

At fertilization, the sea urchin egg undergoes an internal pH (pHi) increase mediated by a Na+ -H+ exchanger. We used antibodies against the mammalian antiporters NHE1 and NHE3 to characterize this exchanger. In unfertilized eggs, only anti-NHE3 cross-reacted specifically with a protein of 81-kDa, which localized to the plasma membrane and cortical granules. Cytochalasin D, C3 exotoxin (blocker of RhoGTPase function), and Y-27632 (inhibitor of Rho-kinase) prevented the pHi change in fertilized eggs. These inhibitors blocked the first cleavage division of the embryo, but not the cortical granule exocytosis. Thus, the sea urchin egg has an epithelial NHE3-like Na+ -H+ exchanger which can be responsible for the pHi change at fertilization. Determinants of this pHi change can be: (i) the increase of exchangers in the plasma membrane (via cortical granule exocytosis) and (ii) Rho, Rho-kinase, and optimal organization of the actin cytoskeleton as regulators, among others, of the intrinsic activity of the exchanger.     

Cleavage inhibition in marine eggs by puromycin and 6-dimethylaminopurine

The possibility is discussed that puromycin may not inhibit cleavage in marine eggs solely by inhibiting protein synthesis. It is suggested that part of the effect of puromycin is through 6-dimethylaminopurine (DMAP) (the purine component of puromycin) a potent cleavage inhibitor which appears to enhance protein synthesis in sea urchin eggs.     

The use of the oxidant"diamide" for studying the non-mitochondrial reducing capacity of Ehrlich ascites tumor cells

Diazenedicarboxylic acid bis(N,N-dimethylamide), (“diamide”) lowered non-mitochondrial NAD(P)H stores in Ehrlich ascites tumor cells in vitro by indirect reactions involving oxidation of glutathione and reduction of GSSG via glutathione reductase. The concentrations of diamide used did not alter the mitochondrial capacity to reduce NAD(P)H under anaerobic conditions. “Endogenous substrates” could be removed by multiple additions of diamide which indirectly inhibited NAD(P)H and GSH regeneration because of a lack of cellular reducing capacity. The regenerative power of the cells was restored by the addition of glucose. We conclude that diamide may prove to be a useful agent for studying the reducing capacity as well as the redox compartmentalization of cells in vitro.     

A possible bio-assay for chromosome movement in isolated mitotic apparatus

We isolated mitotic apparatus (MA) from sea urchin zygotes using several methods. The isolated MA were injected into nucleated frog eggs or into enucleated frog eggs, and 24 h later we determined whether or not the eggs had undergone normal cleavage. Normal cleavage occurred in about 50% of the cases when MA isolated in glycerol-dimethyl sulphoxide were injected into either nucleated or enucleated frog eggs. Likewise for MA isolated initially in hexylene glycol and transferred immediately into glycerol-dimethyl sulphoxide. No cleavage occurred when MA isolated in hexylene glycol (and stored in hexylene glycol) were injected into frog eggs. We discuss two possible interpretations of the results. In one interpretation cleavage of the frog eggs is a bioassay, measuring the ability of the isolated MA to support chromosome movement. In the other interpretation the isolated MA contribute only nuclear material and cleavage initiation factors, and there is no chromosome movement in the isolated MA per se.     

Kohamaic acid A,a novel sesterterpenic acid,inhibits activities of DNA polymerases from deuterostomes

We previously found and isolated a novel natural product, designated kohamaic acid A (KA-A), which inhibited the first cleavage of fertilized sea urchin eggs. In this paper, we report that this compound could selectively inhibit the activities of DNA polymerases (pol. alpha, beta, gamma, delta and epsilon ) only from species in the deuterostome branch in the animal kingdom, like sea urchin, fish and mammals, but not from protostomes including insects (fruit fly, Drosophila melanogaster) and mollusks (octopus and oyster). Inhibition of deuterostome DNA polymerases was dose dependent. IC(50) values for DNA polymerases of mammals and fish occurred at approximately 5.8-14.9 microM and those of sea urchin at 6.1-30.3 microM. In the sea urchin DNA polymerases, the activities of the replicative DNA polymerases such as alpha, delta and epsilon were more strongly inhibited than that of the repair-related pol. beta. KA-A is an inhibitor of replicative DNA polymerases from the deuterostome species, and subsequently, the inhibition of the first cleavage of fertilized sea urchin eggs might occur as a result of the suppression of DNA replication.     

Propranolol, a beta-adrenergic receptor blocker, affects microfilament organization, but not microtubules, during the first division in sea urchin eggs

Propranolol, a beta-adrenergic receptor blocker, blocks the formation of the cleavage furrow, while karyokinesis is unaffected during first division in the sea urchins Paracentrotus lividus or Lytechinus pictus. This effect is reversed by adrenalin, indicating that it is mediated by an adrenergic mechanism. The staining of F-actin microfilaments by rhodamine phalloidin in eggs in which the cleavage is blocked by the drug has revealed that propranolol affects both the distribution and the organization of actin microfilaments. A low-voltage scanning electron microscopy (LVSEM) study of microvilli in these eggs shows an extensive rearrangement of the egg surface. Anti-tubulin immunofluorescence microscopy of eggs treated with propranolol shows that they form normal mitotic asters. This indicates that while cleavage is affected, mitotic spindle formation is not. These results suggest that neurotransmitter monoamines known to be present in the sea urchin egg might be involved in the reorganization of the actin cytoskeleton underlying the formation of the cleavage furrow.     

THE EFFECT OF PENICILLIN ON EGGS OF THE SEA URCHIN,ARBACIA PUNCTULATA

1. Penicillin in the range of concentration from 250 U/ml. to approximately 2650 U/ml. inhibits the rate of cell division of the fertilized sea urchin egg from 0 to 100 per cent. 2. Penicillin in the same range of concentrations has no effect on the oxygen consumption of the unfertilized or the fertilized eggs. 3. Penicillin is bound by some component of the sea urchin egg in amounts sufficiently large to lower the initial concentration, this binding apparently not being related to the inhibitory action.     

Widespread occurrence in animal tissues of an enzyme catalyzing the conversion of NAD+ into a cyclic metabolite with intracellular Ca2+-mobilizing activity

A metabolite with intracellular Ca2+-mobilizing activity can be produced by incubating NAD+ with extracts from sea urchin eggs. Structural determination indicates it is a cyclized ADP-ribose, and we have proposed cyclic ADP-ribose as a common name for it. In this study, we addressed the question of how widespread is the occurrence of the synthesizing enzyme for this NAD+ metabolite. Incubation of NAD+ with extracts prepared from rabbit liver resulted in a progressive increase in Ca2+ release activity which was monitored by a biological assay using sea urchin egg homogenates. The half-maximal concentration of NAD+ required was about 1 mM. The reaction was stereospecific, and the extracts were sensitive to protease treatment and heat, as well as alkaline pH of about 9.0, indicating the reaction was catalyzed by a protein. The active metabolite was purified by an identical high pressure liquid chromatography (HPLC) procedure used for cyclic ADP-ribose. Functionally, the liver metabolite behaved similarly to cyclic ADP-ribose. Both discharged the same Ca2+ stores in sea urchin egg homogenates with the same half-maximal effective concentrations. Both were active in inducing the cortical exocytosis reaction when microinjected into sea urchin eggs. That they are indeed identical compounds was demonstrated by structural analyses showing that they coeluted on a Partisil 5 SAX HPLC column and had identical 1H NMR spectra. Mass spectrometry indicated a mass of 540.0529 for the molecular ion (M - H)- of the liver metabolite, which was identical to within 0.74 ppm of cyclic ADP-ribose. Furthermore, their collisional activated decomposition mass spectra were virtually superimposable. Extracts from rabbit brain, heart, spleen, and kidney were all active in producing similar Ca2+-releasing metabolites which could be isolated by the same HPLC procedure and had similar elution times on both the mixed mode and the Partisil 5 SAX column. It is therefore apparent that the synthesizing enzyme for cyclic ADP-ribose is a very common enzyme.     

Studies on the cytotoxicity of cucurbitacins isolated from Cayaponia racemosa (Cucurbitaceae)

The cytotoxic potential of three cucurbitacins, 2,3,16,20(R),25-pentahydroxy-11,22-dioxo-cucurbita-5-en (cucurbitacin P, 1), 2,3,16,20(R),25-pentahydroxy-22-oxocucurbita-5-en (2) and 2,3,16,20(R),25-pentahydroxy-22-oxocucurbita-5,23(E)-diene (deacetylpicracin, 3), obtained from Cayaponia racemosa was evaluated as their ability to induce brine shrimp lethality, to inhibit the development of sea urchin eggs and tumor cell proliferation, and to lysis mouse erythrocytes. Compounds 1 and 2 were highly toxic with LC50 of (29.6+/-.1) (56.8) and (38.8 +/-.0) (76.6) micro/mL (umicro), respectively, while compound 3 was not effective at the tested concentrations. All tested compounds possessed an inhibitory effect on the proliferation of tumor cell lines, compound 1 being the most active, followed by 2 and 3. Nevertheless, no hemolytic activity or inhibition of the development of sea urchin eggs was observed for these compounds.     

On the role of serotonin and 5-methoxy-tryptamine in the regulation of cell division in sea urchin eggs

The presence of serotonin in sea urchin eggs has been ascertained by high-performance liquid chromatography and thin-layer chromatography analysis of tissue-free bioamines. The results show the presence of both serotonin and 5-methoxytryptamine. The role of these substances in the cell division process has been studied by using the serotonin antagonists, gramine and metergoline. Both antagonists cause a significant delay of the cell division which, however, can be prevented by the addition of either 5-hydroxytryptophane, serotonin, or 5-methoxytryptamine. The effect of gramine on the different stages of the cell division process has also been investigated. Neither S phase nor mitosis are affected by the serotonin antagonist, while cleavage is delayed. The effect of serotonin seems mediated by calcium ions and cAMP. Gramine causes a marked increase in radio-calcium efflux from the fertilized egg, and at the same time lowers the cAMP level.     

Partial characterization of a nuclear proteolytic activity from fertilized sea urchin eggs

The nuclei from fertilized sea urchin eggs, obtained 80 min after fertilization, contains a neutral proteolytic activity. Optimal action on casein was observed at pH 7-8 and a Km value of 1.2 mg/ml was determined for this substrate. The proteolytic activity was stimulated 1.5 fold by the addition of 3 M urea and decreased at higher urea concentrations. NaCl and CaCl2 were inhibitory whereas MgCl2 increased the enzyme activity. Isolated histones from sea urchin sperms, and especially histones H1, H2A, H2B and H3, were degraded by the nuclear activity. A partial inhibition of histones degradation was caused by sodium bisulfite and NaCl. The proteolytic activity was found associated to the chromatin of fertilized sea urchin eggs.     

Effects of Inhibitors of Myosin Light Chain Kinase and Other Protein Kinases on the First Cell Division of Sea Urchin Eggs

We investigated effects of protein kinase inhibitors on the first cell division in sea urchin eggs on the assumption that phosphorylation of myosin is requisite for the formation and/or the contraction of the contractile ring. ML-7 or ML-9, which inhibits myosin light chain kinase (MLCK), inhibited cytokinesis with a half maximal inhibition at 0.1–0.2 mM. The nuclear division was accomplished normally at 0.2–0.25 mM where the cytokinesis was completely blocked. Fluorescent staining of actin filaments with rhodamine-labeled phalloidin revealed that the contractile ring was not formed in the cleavage-inhibited eggs. H-7 which inhibits cAMP-dependent protein kinase, cGMP-dependent protein kinase and protein kinase C arrested the process of the division at mid-cleavage at 0.25–0.3 mM and at metaphase or anaphase at 0.5 mM. H-8 and HA1004, which inhibit cAMP-dependent and cGMP-dependent protein kinases did not show significant effect at millimolar order. In the presence of micromolar concentrations of staurosporine which preferentially inhibits protein kinase C and MLCK small mitotic apparatuses were formed, in which chromosomes did not form the metaphase plate. The role of phosphorylation in the cell division is discussed.     

ADP-ribosyl cyclase: an enzyme that cyclizes NAD+ into a calcium-mobilizing metabolite.

Cyclic ADP-ribose (cADPR) is a metabolite of NAD+ that is as active as inositol trisphosphate (IP3) in mobilizing intracellular Ca2+ in sea urchin eggs. The activity of the enzyme responsible for synthesizing cADPR is found not only in sea urchin eggs but also in various mammalian tissue extracts, suggesting that cADPR may be a general messenger for Ca2+ mobilization in cells. An aqueous soluble enzyme, thought to be an NADase, has been purified recently from the ovotestis of Aplysia californica (Hellmich and Strumwasser, 1991). This paper shows that the Aplysia enzyme catalyzes the conversion of NAD+ to cADPR and nicotinamide. The Aplysia enzyme was purified by fractionating the soluble extract of Aplysia ovotestis on a Spectra/gel CM column. The purified enzyme appeared as a single band of approximately 29,000 Da on SDS-PAGE but could be further separated into multiple peaks by high-resolution, cation-exchange chromatography. All of the protein peaks had enzymatic activity, indicating that the enzyme had multiple forms differing by charge. Analysis of the reaction products of the enzyme by anion-exchange high-pressure liquid chromatography (HPLC) indicated no ADP-ribose was produced; instead, each mole of NAD+ was converted to equimolar of cADPR and nicotinamide. The identification of the product as cADPR was further substantiated by proton NMR and also by its Ca(2+)-mobilizing activity. Addition of the product to sea urchin egg homogenates induced Ca2+ release and desensitized the homogenate to authentic cADPR but not to IP3. Microinjection of the product into sea urchin eggs elicited Ca2+ transients as well as the cortical exocytosis reaction. Therefore, by the criteria of HPLC, NMR, and calcium-mobilizing activity, the product was identical to cADPR. To distinguish the Aplysia enzyme from the conventional NADases that produce ADP-ribose, we propose to name it ADP-ribosyl cyclase.     

INDUCTION OF ASTER FORMATION AND CLEAVAGE IN EGGS OF THE SEA URCHIN HEMICENTROTUS PULCHERRIMUS BY INJECTION OF SPERM COMPONENTS*

Studies were made on which components of sperm were able to induce aster formation and cleavage of eggs of the sea urchin Hemicentrotus pulcherrimus. The sperm components were separated by homogenization and centrifugation into the following 3 fractions: the head-midpiece, midpiece and tail. The head-midpiece fraction was then divided into 2 sub-fractions, the centriole sub-fraction and the centriole-free sub-fractions. Each fraction was injected into unfertilized eggs and after 15–30 min the eggs were inseminated. The ability of a fraction or a sub-fraction to induce aster formation and cleavage was deduced from the frequency of multipolar cleavage. The head-midpiece fraction and the centriole sub-fraction were effective in inducing aster formation and cleavage, but the other fractions were not. It was concluded that isolated centrioles from sea urchin sperm act as division centers in the egg.     

Tumor promoters and diacylglycerol activate the Na+/H+ antiporter of sea urchin eggs

Various tumor promoters (TPA, lyngbyatoxin and aplysiatoxin) and diacylglycerol induced cytoplasmic alkalinization of sea urchin eggs independently of intracellular Ca2+ release. This response stimulated protein synthesis and was blocked by amiloride or a lack of extracellular Na+, procedures which inhibit the Na+/H+ antiporter. These results suggest that the antiporter which is responsible for cytoplasmic alkalinization in sea urchin eggs is activated directly or indirectly by protein kinase C in a Ca2+-independent manner.     

Caulerpenyne blocks MBP kinase activation controlling mitosis in sea urchin eggs

In a previous study, we demonstrated that caulerpenyne (Cyn), a natural sesquiterpene having an antiproliferative potency, blocked the mitotic cycle of sea urchin embryos at metaphase and inhibited the phosphorylation of several proteins, but did not affect histone H1 kinase activation (Pesando et al, 1998, Eur. J. Cell Biol. 77, 19-26). Here, we show that concentrations of Cyn that blocked the first division of the sea urchin Paracentrotus lividus embryos in a metaphase-like stage (45 microM) also inhibited the stimulation of mitogen-activated protein kinase (MAPK) activity in vivo as measured in treated egg extracts using myelin basic protein (MBP) as a substrate (MBPK). However, Cyn had no effect on MBP phosphorylation when added in vitro to an untreated egg extract taken at the time of metaphase, suggesting that Cyn acts on an upstream activation process. PD 98059 (40 microM), a previously characterized specific synthetic inhibitor of MAPK/extracellular signal-regulated kinase-1 (MEK1), also blocked sea urchin eggs at metaphase in a way very similar to Cyn. Both molecules induced similar inhibitory effects on MBP kinase activation in vivo, but had no direct effect on MBP kinase activity in vitro, whereas they did not affect H1 kinase activation neither in vivo nor in vitro. As a comparison, butyrolactone 1 (100 microM), a known inhibitor of H1 kinase activity, did inhibit H1 kinase of sea urchin eggs in vivo and in vitro, and blocked the sea urchin embryo mitotic cycle much before metaphase. Immunoblots of mitotic extracts, treated with anti-active MAP-kinase antibody, showed that both Cyn and PD 98059 reduced the phosphorylation of p42 MAP kinase (Erk2) in vivo. Our overall results suggest that Cyn blocks the sea urchin embryo mitotic cycle at metaphase by inhibiting an upstream phosphorylation event in the MBPK activation pathway. They also show that H1 kinase and MBPK activation can be dissociated from each other in this model system.