Pharmacology of the serotonin-induced meiosis reinitiation in Spisula solidissima oocytes

Germinal vesicle breakdown (GVBD) is the first visible response of the oocyte of Spisula solidissima to the neurohormone serotonin. Pharmacological characterization of this response was performed by using 24 serotonin-related compounds. Dose-response curves were assessed by quantification of GVBD. Rank orders of potency obtained were among agonists: serotonin greater than 8-hydroxy-2-(di-N-propylamino)tetralin hydrobromide greater than 2-methyl-serotonin greater than 1-(3-trifluoromethylphenyl)piperazine; among antagonists; ritanserin ritanserin greater than ICS205930 greater than mianserin = ketanserin = propranolol greater than metoclopramide = yohimbine greater than spiperone. Various other monoaminergic compounds tested were inefficient, demonstrating the specificity of the oocyte response to serotonin. Transduction mechanisms underlying this response were then investigated. Ca2+ appeared to be involved since serotonin induced an increase in the uptake of 45Ca2+ and since it was inefficient in calcium-free sea water. The absence of synergy between serotonin and KCl suggested that both compounds use a common transduction pathway. Exposure of the oocyte to the protein kinase C activator TPA inhibited serotonin-dependent maturation. Our data thus point to an original, previously uncharacterized pharmacological profile and transduction mechanism by which serotonin induces oocyte meiosis reinitiation in Spisula solidissima.     

Protein kinase C activity, protein phosphorylation and germinal vesicle breakdown in Spisula oocytes

To test the possible role of protein kinase C (C-kinase) in regulating germinal vesicle breakdown (GVBD) in Spisula oocytes, we studied the effects of phorbol esters and antagonists of C-kinase on GVBD and protein phosphorylation. Responses to these agents were compared to those elicited by fertilization or increased extracellular K+. The tumor-promoting phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA), a potent agonist of C-kinase, elicited GVBD with half-maximal stimulation at 20 nM. By contrast, 4 alpha-phorbol-12,13-didecanoate, a phorbol ester which does not stimulate C-kinase, did not trigger GVBD. TPA accelerated GVBD when induced by excess K+, but it did not affect the time course of the process when initiated by fertilization. Three structurally different antagonists of C-kinase (W-7, H-7, and retinol) all blocked GVBD when induced by fertilization or TPA. When oocytes were preincubated with [32P]orthophosphate and then stimulated to undergo GVBD by fertilization, TPA, or 45 mM K+, protein phosphorylation was greatly increased, especially for a polypeptide(s) of about 45 kDa. Phosphorylation increased prior to GVBD. Retinol inhibited phosphorylation in activated eggs. C-kinase activity was demonstrated in oocyte extracts. These results strongly suggest that protein phosphorylation by C-kinase is involved in the pathway that regulates GVBD in Spisula oocytes.     

Lamin dimers. Presence in the nuclear lamina of surf clam oocytes and release during nuclear envelope breakdown

The nuclear lamina of surf clam oocytes contains dimers of 67-kDa lamin which are stabilized by both noncovalent interactions and disulfide bonds. The latter can be reduced but re-form when the reducing agent is removed. The cysteine residues involved in these disulfide bonds are inaccessible to alkylating agents unless the protein is unfolded in urea. During nuclear envelope breakdown the lamin is released as a mixture of oligomers in which disulfide-stabilized dimers are associated noncovalently with lamin monomers. Concurrent with solubilization, both dimers and monomers are phosphorylated to a similar extent, indicating that the interactions which maintain these complexes are not destabilized by lamin phosphorylation. Our results suggest the existence of two types of interactions between the lamin molecules in the polymer, which react differently to phosphorylation during nuclear envelope breakdown.     

Sperm nuclear transformations consist of enlargement and condensation coordinate with stages of meiotic maturation in fertilized Spisula solidissima oocytes

Rates of sperm nuclear expansion were measured and correlated with processing of the maternal chromatin in synchronous populations of fertilized surf clam (Spisula solidissima) oocytes fixed at regular intervals following insemination and stained with the DNA fluorochrome Hoechst 33342. Sperm nuclei expanded in four distinct phases each temporally coordinate with events of meiotic maturation: germinal vesicle stage (phase A), germinal vesicle breakdown (phase B), polar body formation (phase C), and female pronuclear development (phase D). Sperm nuclei were essentially unchanged during phase A (rate = 0.1 micron2/min, enlarged during phases B (rate = 8.2 microns2/min) and D (rate = 6.2 microns2/min), and condensed during phase C (rate = -1.9 micron2/min). Sperm nuclear enlargement during phase D was significantly less in polyspermic and polygynic zygotes. The effects of various treatments (temperature, microtubule disruption, pH alterations, and metabolic and protein synthesis inhibitions) which perturbed sperm nuclear enlargement and meiotic processing of the maternal chromatin indicated that the two processes are coupled and may be linked by common regulatory agents.     

Temporal control of nuclear envelope assembly by phosphorylation of lamin B receptor

The nuclear envelope of metazoans disassembles during mitosis and reforms in late anaphase after sister chromatids have well separated. The coordination of these mitotic events is important for genome stability, yet the temporal control of nuclear envelope reassembly is unknown. Although the steps of nuclear formation have been extensively studied in vitro using the reconstitution system from egg extracts, the temporal control can only be studied in vivo. Here, we use time-lapse microscopy to investigate this process in living HeLa cells. We demonstrate that Cdk1 activity prevents premature nuclear envelope assembly and that phosphorylation of the inner nuclear membrane protein lamin B receptor (LBR) by Cdk1 contributes to the temporal control. We further identify a region in the nucleoplasmic domain of LBR that inhibits premature chromatin binding of the protein. We propose that this inhibitory effect is partly mediated by Cdk1 phosphorylation. Furthermore, we show that the reduced chromatin-binding ability of LBR together with Aurora B activity contributes to nuclear envelope breakdown. Our studies reveal for the first time a mechanism that controls the timing of nuclear envelope reassembly through modification of an integral nuclear membrane protein.     

Acid release following activation of surf clam (Spisula solidissima) eggs.

Acid release was observed after activation of Spisula eggs with excess KCI. This acid release begins within 20 sec after the activation and continues for 9–15 min. The amount of acid released was 6.8 μmole per milliliter of packed eggs. In Ca-free or Na-free sea water, the acid release is completely inhibited; subsequent addition of the deficient ion leads to acid release and breakdown of germinal vesicles. These results suggest that Spisula eggs release protons after activation in a manner similar to that of sea urchin eggs, and that acid release with concomitant increase in cytoplasmic pH is probably a general event on activation of marine eggs.     

Sperm nuclear dispersion coordinate with meiotic maturation in fertilized Spisula solidissima eggs

Investigations were carried out with fertilized Spisula solidissima eggs, in which changes in incorporated sperm nuclei were determined by measurement of the diameter of dispersing paternal chromatin. Results of such an analysis demonstrated that sperm nuclear dispersion does not proceed at a constant rate and consists of four phases (1–4), coordinate with major changes in the status of the maternal chromatin. (1) The first phase was a short lag period prior to germinal vesicle breakdown in which the size of the sperm nucleus increased only slightly. (2) This was followed by a rapid dispersion of the sperm nucleus coordinate with germinal vesicle breakdown. With the development of the first meiotic spindle, sperm chromatin dispersion slowed dramatically; this phase (3) lasted until the completion of the meiotic divisions at which time the sperm chromatin underwent a second rapid increase in size (4) that was correlated with development of the female pronucleus. When zygotes were treated with agents that inhibited germinal vesicle breakdown (verapamil, sodium-free seawater, and chloroquine), sperm nuclear dispersion did not occur. Evidence is presented indicating that nucleocytoplasmic interactions coincident with germinal vesicle breakdown induce sperm nuclear dispersion in Spisula zygotes.     

Microtubule cycles in oocytes of the surf clam, Spisula solidissima: an immunofluorescence study

Oocytes of the surf clam, Spisula solidissima, underwent germinal vesicle breakdown and two meiotic divisions to give off polar bodies when they were fertilized or parthenogenetically activated with KCl. Fertilized eggs further proceeded to mitosis and cleaved, while parthenogenetically activated eggs remained uncleaved. We examined changes in microtubule-containing structures during meiotic divisions and subsequent mitotic processes by immunofluorescence. A monoclonal anti-tubulin antibody was applied to alcohol-fixed eggs from which the vitelline membrane had been removed by protease digestion. Up to the stage of second polar body formation, the pattern of microtubule organization in the first and second meiotic spindles was identical in both fertilized and parthenogenetically activated eggs. However, while fertilized eggs formed a sperm aster and mitotic spindles later, activated eggs formed only monaster- or ring-shaped microtubule-containing structures which underwent cycles of alternating formation and breakdown. Lactoorecin staining of parthenogenetically activated eggs revealed that the chromosome cycle could occur in these eggs, in phase with this microtubule cycle.     

Unidirectional microtubule assembly in cell-free extracts of Spisula solidissima oocytes is regulated by subtle changes in pH

Most, if not all, microtubules in vivo grow unidirectionally from a nucleation site such as the centrosome. This organized growth of microtubules can generate and maintain the radially symmetrical array of interphase microtubules as well as the bipolar mitotic apparatus. To investigate the regulation of polarized microtubule growth, we have prepared a cell-free extract from surf clam oocytes that exhibits unidirectional microtubule assembly. Immunofluorescence microscopy was used to visualize the net assembly of microtubules onto the fast (plus)- and slow (minus)- growing ends of isolated ciliary axonemes. All detectable microtubule growth in these cytoplasmic extracts occurred at the plus (+) ends and the extent of (+) end growth was regulated by subtle changes in pH. Microtubule assembly in these crude extracts was highly favored at pH 7.3, the pH of the post-fertilization cytoplasm. In contrast, when tubulin was purified from these oocyte extracts, integral components were lost, and microtubule growth became predominantly bidirectional and was favored at acidic pH. These results indicate that cytoplasmic factors may inhibit bidirectional growth in vivo and that temporal or local changes in cytoplasmic pH may influence microtubule assembly during the cell cycle.     

C. elegans nuclear envelope proteins emerin, MAN1, lamin, and nucleoporins reveal unique timing of nuclear envelope breakdown during mitosis

Emerin, MAN1, and LAP2 are integral membrane proteins of the vertebrate nuclear envelope. They share a 43-residue N-terminal motif termed the LEM domain. We found three putative LEM domain genes in Caenorhabditis elegans, designated emr-1, lem-2, and lem-3. We analyzed emr-l, which encodes Ce-emerin, and lem-2, which encodes Ce-MAN1. Ce-emerin and Ce-MAN1 migrate on SDS-PAGE as 17- and 52-kDa proteins, respectively. Based on their biochemical extraction properties and immunolocalization, both Ce-emerin and Ce-MAN1 are integral membrane proteins localized at the nuclear envelope. We used antibodies against Ce-MAN1, Ce-emerin, nucleoporins, and Ce-lamin to determine the timing of nuclear envelope breakdown during mitosis in C. elegans. The C. elegans nuclear envelope disassembles very late compared with vertebrates and Drosophila. The nuclear membranes remained intact everywhere except near spindle poles during metaphase and early anaphase, fully disassembling only during mid-late anaphase. Disassembly of pore complexes, and to a lesser extent the lamina, depended on embryo age: pore complexes were absent during metaphase in >30-cell embryos but existed until anaphase in 2- to 24-cell embryos. Intranuclear mRNA splicing factors disassembled after prophase. The timing of nuclear disassembly in C. elegans is novel and may reflect its evolutionary position between unicellular and more complex eukaryotes.     

Cyclic nucleotide content and protein phosphorylation during maturation of Spisula oocytes

Cyclic nucleotide levels in the oocytes of the surf clam Spisula solidissima were measured during germinal vesicle breakdown (GVBD) induced by fertilization. The level of cAMP and cGMP in untreated oocytes was 8.23 ± 0.95 and 4.89 ± 0.39 pmol/10⁶ oocytes. The ratio of cAMP to cGMP ranged from 1.5 to 2.0. The cAMP level in Spisula oocytes fluctuated after fertilization and before GVBD. The cGMP level showed minimal fluctuation, with a tendency to decrease initially followed by a subsequent rise to the basal level in a nonsynchronous manner. These changes were not statistically significant. There was a general increase in protein phosphorylation during the period after fertilization and before GVBD. The greatest increase occurred with proteins of estimated molecular weights of 52, 18, and 12 kD, analyzed by gel electrophoresis and autoradiography.     

Structural characterization of the trypsin-resistant core in the nuclear sperm-specific protein from Spisula solidissima

Trypsin digestion of the protamine-like protein from Spisula solidissima has revealed the existence of an internal resistant core. The peptide contains 75 amino acid residues, and its primary structure shows some conserved sequences that are common to those found in the core of the somatic histone H5 from chicken erythrocytes. The secondary structure of this core exhibits 33% antiparallel beta-sheet, 18% beta-turns, 37% random coil, and only 10% alpha-helix, in contrast to histone H5. Hydrodynamic measurements indicate a compact globular assembly for the tertiary structure of this peptide, when compared to the more extended shape observed for the whole protein. The possible relatedness of this protein to the histone H1 family is discussed.     

Stimulatory effect of okadaic acid, an inhibitor of protein phosphatases, on nuclear envelope breakdown and protein phosphorylation in mouse oocytes and one-cell embryos.

Treatment of one-cell mouse embryos with okadaic acid (OA), which is an inhibitor of protein phosphatases 1 and 2A, induces a concentration-dependent precocious nuclear envelope breakdown (NEBD) of the pronuclei; at 10 microM okadaic acid, NEBD starts to occur after 1 hr and the embryos become committed to NEBD after about 45 min. Correlated with NEBD is the conversion of a protein of Mr 32,000 (p32) to more highly phosphorylated forms. One-cell embryos cultured continuously in OA-containing medium do not cleave, whereas one-cell embryos incubated for 15-60 min prior to transfer to OA-free medium reveal a time-dependent inhibition in their ability to cleave. OA treatment of oocytes that are arrested from resuming spontaneous maturation by either a phosphodiesterase inhibitor or biologically active phorbol diester results in germinal vesicle breakdown and the maturation-associated changes in the pattern of protein phosphorylation, which include the apparent phosphorylation of p32. Results of these experiments implicate protein phosphatases in the G2 to M transition of the cell cycle in both meiotic and mitotic cells.     

Length-dependent deactivation of ventricular trabeculae in the bivalve, Spisula solidissima

Shortening-deactivation has been identified and characterized in ventricular trabeculae of the bivalve, Spisula solidissima (Heterodonta, Mactridae). This muscle had ultrastructural similarities to vertebrate smooth muscle. Deactivation was defined as the fraction of maximal force lost during a contraction when a muscle is shortened rapidly (by a quick-release, QR) to a known length, relative to a control isometric contraction at that same length. The magnitude of deactivation was dependent on the size of the release and the point at which the release was applied during the cycle of contraction. QR/quick-stretch (QS) perturbations at the same point during the contraction resulted in negligible deactivation. The magnitude of deactivation was independent of shortening rate. Deactivation was attenuated by applying caffeine (100 μM) and blocked with high extracellular Ca²⁺ (56 mM). The Ca²⁺ ionophore, A23187 (10 μM), augmented deactivation as did the positive inotrope serotonin (100 nM). Treatment with ryanodine (5 μM) had no significant effect on deactivation. These results suggest that a reduction in Ca²⁺ at the contractile element and/or sequestration of Ca²⁺ may occur during shortening. Deactivation may minimize the magnitude of work done during active shortening of bivalve cardiac muscle, particularly against the low afterload exhibited in the bivalve peripheral circulatory system. Intracellular Ca²⁺ fluxes during sudden length perturbations may explain the effect of stretch on action potential duration in the bivalve heart, as shown previously.     

Pathway of incorporation of microinjected lamin A into the nuclear envelope

When microinjected into the cytoplasm of 3T3 cells, biotinylated human lamin A rapidly enters the nucleus and gradually becomes incorporated into the nuclear lamina region as determined by immunofluorescence. The incorporation of the microinjected material takes several hours and progresses through a series of morphologically identifiable stages. Within minutes after microinjection, lamin A is found in spots distributed throughout the nucleus, except in nucleolar regions. Over a time course of up to 6 h, these spots appear to decrease in size and number as the biotinylated lamin A becomes associated with the endogenous nuclear lamina. Eventually, the typical nuclear rim staining pattern normally revealed by immunofluorescence with nuclear lamin antibodies is seen with antibiotin. This latter rim staining property is passed on to daughter cells following mitosis. These results indicate that the microinjected biotinylated nuclear lamin A retains those properties required for its integration into the lamina, as well as those necessary for the disassembly and subsequent reassembly of the nuclear lamina during cell division. The initial rapid accumulation into foci and the subsequent slower incorporation into the nuclear lamina appear to be analogous to the stages of incorporation following the microinjection of cytoskeletal intermediate filament proteins such as vimentin and keratin (Vikstrom, K., G. G. Borisy, and R. D. Goldman. 1989. Proc. Natl. Acad. Sci. USA. 86:549-553; Miller, R. K., K. Vikstrom, and R. D. Goldman. 1991. J. Cell Biol. 113:843-855). Foci are also observed in some uninjected cells using nuclear lamin antibodies, indicating that these features are a genuine component of nuclear substructure. Evidence is presented that shows the appearance of these nuclear structures is cell cycle dependent.     

Identification of cell cycle-regulated phosphorylation sites on nuclear lamin C

The mechanism by which MPF induces nuclear lamin disassembly and nuclear envelope breakdown during mitosis was studied in a frog egg extract in which the transition from interphase to mitosis can be induced by the addition of MPF. Bacterially expressed human nuclear lamin C, assembled in vitro into filaments, showed increased phosphorylation on specific sites in the extract in response to MPF. Phosphorylation was accompanied by disassembly of the lamin filaments. We determined the sequences of the sites phosphorylated both in the presence and absence of MPF. The sequence data suggest that multiple protein kinases act on the lamins, and S6 kinase II was identified as one potentially important lamin kinase.     

Vesicle formation from the nuclear envelope in amphibian oocytes

Conclusions Electron microscopic evidence has been presented which suggests that the cytoplasmic vesicles observed in amphibian oocytes are derived by blebbing from the nuclear envelope and migrate to the periphery. The mechanism of bleb formation is discussed.This work was supported by a U.S.P.H.S. research grant RG5803(C2) and was carried out during the tenure of a U.S.P.H.S. Special Research Fellowship (5356).