Time-related effect of GnRH on histone H1 kinase activity in the goldfish follicle-enclosed oocyte.

The level of cyclin B-associated cdc2 kinase, a component of maturation promoting factor (MPF), is known to be high during metaphase of the meiotic maturation of oocytes. The time-related action of gonadotropin-releasing hormones (GnRH) on histone H1 kinase activity (known to reflect cdc2 kinase activity) was investigated in vitro in follicle-enclosed goldfish oocytes. Germinal vesicle breakdown (GVBD) and testosterone production were also investigated in the same follicle-enclosed goldfish oocytes to determine the temporal relationship between GnRH-induced histone H1 kinase activity and the reinitiation of meiosis and steroidogenesis. Treatments with gonadotropin (GTH) or GnRH stimulated the histone H1 kinase activity to the same maximum level. However, sGnRH- and cGnRH-II-induced histone H1 kinase activity were significantly higher compared with controls after 2 hours of treatment, whereas the GTH-induced increase became significantly higher after 6-8 hours of incubation. Overall, the results demonstrate a close temporal relationship between GVBD response and histone H1 kinase activity induced by GTH and sGnRH-cGnRH-II.

Disappearance of a novel protein component of the 26S proteasome during Xenopus oocyte maturation.

We have prepared polyclonal antibodies against Xenopus 20S proteasomes. The antibodies cross-react with several proteins that are common to 20S and 26S proteasomes and with at least two proteins that are unique to 26S proteasomes. The antibodies were used to analyze changes in the components of proteasomes during oocyte maturation and early development of Xenopus laevis. A novel protein with a molecular weight of 48 kDa, p48, was clearly detected in immature oocytes, but was found at very low levels in mature oocytes and ovulated eggs. p48 was reduced to low levels during oocyte maturation, after maturation-promoting factor was activated. The amount of p48 in eggs remained low during early embryonic development, but increased again after the midblastula transition. These results show that at least one component of 26S proteasomes changes during oocyte maturation and early development and suggest that alterations in proteasome function may be important for the regulation of developmental events, such as the rapid cell cycles, of the early embryo.

Activation of the p42 mitogen-activated protein kinase pathway inhibits Cdc2 activation and entry into M-phase in cycling Xenopus egg extracts.

We have added constitutively active MAP kinase/ERK kinase (MEK), an activator of the mitogen-activated protein kinase (MAPK) signaling pathway, to cycling Xenopus egg extracts at various times during the cell cycle. p42MAPK activation during entry into M-phase arrested the cell cycle in metaphase, as has been shown previously. Unexpectedly, p42MAPK activation during interphase inhibited entry into M-phase. In these interphase-arrested extracts, H1 kinase activity remained low, Cdc2 was tyrosine phosphorylated, and nuclei continued to enlarge. The interphase arrest was overcome by recombinant cyclin B. In other experiments, p42MAPK activation by MEK or by Mos inhibited Cdc2 activation by cyclin B. PD098059, a specific inhibitor of MEK, blocked the effects of MEK(QP) and Mos. Mos-induced activation of p42MAPK did not inhibit DNA replication. These results indicate that, in addition to the established role of p42MAPK activation in M-phase arrest, the inappropriate activation of p42MAPK during interphase prevents normal entry into M-phase.

Nuclear responses to MPF activation and inactivation in Xenopus oocytes and early embryos.

The cell cycle of most organisms is highlighted by characteristic changes in the appearance and activity of the nucleus. Structural changes in the nucleus are particularly evident when a cell begins to divide. At this time, the nuclear envelope is disassembled, the chromatin condenses into metaphase chromosomes, and the chromosomes associate with a newly formed spindle. Upon completion of cell division the nuclear envelope reassembles around the chromosomes as they form telophase nuclei, and subsequently interphase nuclei, in the daughter cells. The cytoplasmic control of nuclear behavior has been the theme of Yoshio Masui's research for much of his career. His pioneering demonstration that the cytoplasm of maturing amphibian oocytes causes the resumption of the meiotic cell cycle when it is injected into an immature oocyte provided unequivocal evidence that a cytoplasmic factor could initiate the transition from interphase to metaphase (M-phase) in intact cells. As described in several reviews in this and the previous issue of Biology of the Cell (see Beckhelling and Ford; Duesbery and Vande Woude; Maller), Masui initially called this activity maturation promoting factor (MPF), but when it was realized that it was a ubiquitous regulator of both mitotic and meiotic cell cycles, MPF came to stand for M-phase promoting factor. Biochemical evidence indicates that MPF activity is composed of a mitotic B-type cyclins and cyclin-dependent kinase 1. The increase in the protein kinase activity of cdk1 initiates the changes in the nucleus associated with oocyte maturation and with the entry into mitosis. This article will attempt to provide a brief summary of the responses of the nucleus to the activation of MPF. In addition, the effect of MPF inactivation on nuclear envelope assembly at the end of mitosis will be discussed. This article is written as a tribute to Yoshio Masui on his retirement from the University of Toronto, and as an expression of gratitude for his guidance while I was a student in his laboratory. I have felt very privileged to have known him as a mentor and a friend.

Cell cycle-regulated degradation of Xenopus cyclin B2 requires binding to p34cdc2.

The protein kinase activity of the cell cycle regulator p34cdc2 is inactivated when the mitotic cyclin to which it is bound is degraded. The amino (N)-terminus of mitotic cyclins includes a conserved "destruction box" sequence that is essential for degradation. Although the N-terminus of sea urchin cyclin B confer cell cycle-regulated degradation to a fusion protein, a truncated protein containing only the N-terminus of Xenopus cyclin B2, including the destruction box, is stable under conditions where full length molecules are degraded. In an attempt to identify regions of cyclin B2, other than the destruction box, involved in degradation, the stability of proteins encoded by C-terminal deletion mutants of cyclin B2 was examined in Xenopus egg extracts. Truncated cyclin with only the first 90 amino acids was stable, but other C-terminal deletions lacking between 14 and 187 amino acids were unstable and were degraded by a mechanism that was neither cell cycle regulated nor dependent upon the destruction box. None of the C-terminal deletion mutants bound p34cdc2. To investigate whether the binding of p34cdc2 is required for cell cycle-regulated degradation, the behavior of proteins encoded by a series of full length Xenopus cyclin B2 cDNA with point mutations in conserved amino acids in the p34cdc2-binding domain was examined. All of the point mutants failed to form stable complexes with p34cdc, and their degradation was markedly reduced compared to wild-type cyclin. Similar results were obtained when the mutant cyclins were synthesized in reticulocyte lysates and when cyclin mRNA was translated directly in a Xenopus egg extract. These results indicate that mutations that interfere with p34cdc2 binding also interfere with cyclin destruction, suggesting that p34cdc2 binding is required for the cell cycle-regulated destruction of Xenopus cyclin B2.

Mitotic arrest caused by the amino terminus of Xenopus cyclin B2.

Progression through mitosis requires the inactivation of the protein kinase activity of the p34cdc2-cyclin complex by a mechanism involving the degradation of cyclin. We have examined the stability in Xenopus egg extracts of radiolabeled Xenopus or sea urchin B-type cyclins synthesized in reticulocyte lysates. Xenopus cyclin B2 and sea urchin cyclin B were stable in metaphase extracts from unfertilized eggs but were specifically degraded following addition of Ca2+ to the extracts. The degradation of either cyclin was inhibited by the addition of an excess of unlabeled Xenopus cyclin B2 but not by the addition of a number of control proteins. A truncated protein containing only the amino terminus of Xenopus cyclin B2, including sequences known to be essential for cyclin degradation in other species, also inhibited cyclin degradation, even though the truncated protein was stable in extracts following Ca2+ addition. The addition of the truncated protein did not stimulate histone H1 kinase activity in extracts but prevented the loss of H1 kinase activity that normally follows Ca2+ addition to metaphase extracts. When the amino-terminal fragment was added to extracts capable of several cell cycles in vitro, progression through the first mitosis was inhibited and elevated histone H1 kinase activity was maintained. These results indicate that although the amino terminus of cyclin does not contain all of the information necessary for cyclin destruction, it is capable of interacting with components of the cyclin destruction pathway and thereby preventing the degradation of full-length cyclins.

Phosphorylation of myosin-II regulatory light chain by cyclin-p34cdc2: a mechanism for the timing of cytokinesis.

To understand how cytokinesis is regulated during mitosis, we tested cyclin-p34cdc2 for myosin-II kinase activity, and investigated the mitotic-specific phosphorylation of myosin-II in lysates of Xenopus eggs. Purified cyclin-p34cdc2 phosphorylated the regulatory light chain of cytoplasmic and smooth muscle myosin-II in vitro on serine-1 or serine-2 and threonine-9, sites known to inhibit the actin-activated myosin ATPase activity of smooth muscle and nonmuscle myosin (Nishikawa, M., J. R. Sellers, R. S. Adelstein, and H. Hidaka. 1984. J. Biol. Chem. 259:8808-8814; Bengur, A. R., A. E. Robinson, E. Appella, and J. R. Sellers. 1987. J. Biol. Chem. 262:7613-7617; Ikebe, M., and S. Reardon. 1990. Biochemistry. 29:2713-2720). Serine-1 or -2 of the regulatory light chain of Xenopus cytoplasmic myosin-II was also phosphorylated in Xenopus egg lysates stabilized in metaphase, but not in interphase. Inhibition of myosin-II by cyclin-p34cdc2 during prophase and metaphase could delay cytokinesis until chromosome segregation is initiated and thus determine the timing of cytokinesis relative to earlier events in mitosis.

Regulation of nuclear envelope precursor functions during cell division.

Previously, we have shown that nuclear envelope assembly in cell-free extracts of Xenopus eggs requires two distinct vesicle-containing fractions, called Nuclear Envelope Precursor Fractions A and B (NEP-A and NEP-B). These fractions are characterized further in this paper and the manner in which they are regulated during metaphase is examined. Antisera against the NEP-B fraction recognized several proteins common to NEP-B and Xenopus oocyte or liver nuclei, but not to NEP-A or cytosol. A known glycoprotein component of the nuclear pore complex, p62, also co-fractionated with NEP-B, whereas the Xenopus egg lamin LIII did not. Together, these results provide further evidence that the NEP-B fraction contains precursors of the nuclear envelope. The regulation of NEP-A and -B function during metaphase, when the nuclear envelope is disassembled, was examined by treating each fraction with metaphase cytosol or purified protein kinase preparations isolated from metaphase-arrested eggs. Treatment of NEP-B with metaphase cytosol, under conditions where proteins are irreversibly phosphorylated, inhibited the subsequent assembly of the nuclear envelope by preventing the binding of NEP-B to chromatin. In contrast, similar treatment of NEP-A did not affect its ability to form nuclear envelopes. The changes in NEP-B during metaphase did not appear to be regulated directly by either p34cdc2/cyclin B, S6 kinase II or MAP kinase.

A distinct vesicle population targets membranes and pore complexes to the nuclear envelope in Xenopus eggs.

Extracts from Xenopus eggs capable of nuclear envelope assembly in vitro were fractionated by differential and density gradient centrifugation. Nuclear envelope assembly was found to require soluble components in the cytosol and two distinct particulate fractions, which we have called nuclear envelope precursor fractions A and B (NEP-A and NEP-B). Both NEP-A and NEP-B are sensitive to treatments with trypsin, sodium carbonate, and detergents, but can be distinguished from each other by their sensitivities to high salt and N-ethylmaleimide and by their levels of alpha-glucosidase activity. Vesicles in NEP-B bind to chromatin, whereas those in NEP-A do not. NEP-B may therefore be involved in the targeting of membranes to the surface of the chromatin, whereas NEP-A may provide a pool of vesicles that contributes many of the nuclear envelope membranes. NEP-B may also play a role in the assembly of nuclear pore complexes because the density of nuclear pores in the resulting envelope is dependent on the ratio of NEP-B to NEP-A in the reconstituted extract.

Maturation-promoting factor and the regulation of the cell cycle.

Maturation-promoting factor (MPF) is a cell cycle control element able to cause metaphase when injected into amphibian oocytes or when incubated with nuclei in a cell-free system. Highly purified MPF consists of a complex between a 34K (K = 10(3) Mr) serine/threonine protein kinase, identified as a Xenopus homolog of the cdc2+ gene product, p34cdc2, and a 45K substrate, identified as a Xenopus B-type cyclin. p34cdc2 is also present in purified preparations of chromatin-derived growth-associated histone H1 kinase from Novikoff hepatoma cells. p34cdc2 is active when dephosphorylated and inactive when phosphorylated during oocyte meiotic cell cycles and in mitotic cell cycles following egg activation. Analysis of the substrate specificity of p34cdc2 indicates a consensus sequence for phosphorylation of (K/R)S/TP(X)K/R. Among substrates identified with this consensus are histone H1 and the pp60c-src proto-oncogene, which is known to be activated and phophorylated in mitosis. MPF injection into oocytes activates ribosomal protein S6 kinase II, which is also a lamin kinase. The mechanism of activation is indirect, possibly involving the c-src proto-oncogene. Continued analysis of regulation of MPF activation/inactivation and characterization of substrates for phosphorylation will have important implications for cell cycle and cell growth control.

Induction of metaphase chromosome condensation in human sperm by Xenopus egg extracts.

Cell-free extracts of Xenopus eggs cause permeabilized Xenopus sperm to form pronuclei, which condense into metaphase chromosomes when the cytosol from metaphase-arrested unfertilized eggs is added to the extracts. In this paper, the ability of these cell-free extracts to cause similar changes in permeabilized human sperm was examined. Sperm that had been treated with the disulfide reducing agent dithiothreitol formed pronuclei, whereas untreated sperm did not. The addition of metaphase cytosol to the extracts caused the pronuclei to form metaphase chromosomes but only after incubation times that were two to three times longer than those required for Xenopus sperm nuclei. These results indicate that despite species differences, the Xenopus egg extracts can be used to visualize the chromosomes of human sperm and possibly those of other species.

Purification of maturation-promoting factor, an intracellular regulator of early mitotic events.

Maturation-promoting factor causes germinal vesicle breakdown when injected into Xenopus oocytes and can induce metaphase in a cell-free system. The cell-free assay was used to monitor maturation-promoting factor during its purification from unfertilized Xenopus eggs. Ammonium sulfate precipitation and six chromatographic procedures resulted in a preparation purified greater than 3000-fold that could induce germinal vesicle breakdown within 2 hr when injected into cycloheximide-treated oocytes. Proteins of 45 kDa and 32 kDa were correlated with fractions of highest activity in both assays. These fractions contained a protein kinase activity able to phosphorylate the endogenous 45-kDa protein, as well as histone H1, phosphatase inhibitor 1, and casein. The highly purified preparations described here should help to identify the mechanism of action of maturation-promoting factor and to elucidate the role of protein kinases in the induction of metaphase.

Metaphase protein phosphorylation in Xenopus laevis eggs.

Cytoplasmic extracts of metaphase (M-phase)-arrested Xenopus laevis eggs support nuclear envelope breakdown and chromosome condensation in vitro. Induction of nuclear breakdown is inhibited by AMPP(NH)P, a nonhydrolyzable ATP analog, but not by ATP or gamma-S-ATP, a hydrolyzable ATP analog, suggesting that protein phosphorylation may be required for M-phase nuclear events in vitro. By addition of [gamma-32P]ATP, we have identified in cytoplasmic extracts and in intact eggs at least six phosphoproteins that are present during M-phase but absent in G1/S-phase. These phosphoproteins also appear in response to partially purified preparations of maturation-promoting factor. A subset of these proteins are thiophosphorylated by gamma-S-ATP under conditions that promote nuclear envelope breakdown and chromosome condensation. Each of these proteins is phosphorylated on serine and threonine, and one, a 42-kilodalton protein, is also phosphorylated on tyrosine both in extracts and in intact eggs. These results indicate that activation of protein kinases accounts for at least part of the increased phosphorylation in M-phase and that both protein-serine-threonine kinases and protein-tyrosine kinases may play a role in controlling M-phase nuclear behavior.

Induction of nuclear envelope breakdown, chromosome condensation, and spindle formation in cell-free extracts.

Incubation of demembranated sperm chromatin in cytoplasmic extracts of unfertilized Xenopus laevis eggs resulted in nuclear envelope assembly, chromosome decondensation, and sperm pronuclear formation. In contrast, egg extracts made with EGTA-containing buffers induced the sperm chromatin to form chromosomes or irregularly shaped clumps of chromatin that were incorporated into bipolar or multipolar spindles. The 150,000 g supernatants of the EGTA extracts could not alone support these changes in incubated nuclei. However, these supernatants induced not only chromosome condensation and spindle formation, but also nuclear envelope breakdown when added to sperm pronuclei or isolated Xenopus liver or brain nuclei that were incubated in extracts made without EGTA. Similar changes were induced by partially purified preparations of maturation-promoting factor. The addition of calcium chloride to extracts containing condensed chromosomes and spindles caused dissolution of the spindles, decondensation of the chromosomes, and re-formation of interphase nuclei. These results indicate that nuclear envelope breakdown, chromosome condensation, and spindle assembly, as well as the regulation of these processes by Ca2+-sensitive cytoplasmic components, can be studied in vitro using extracts of amphibian eggs.

Effects of Ca2+ ions on the formation of metaphase chromosomes and sperm pronuclei in cell-free preparations from unactivated Rana pipiens eggs.

Nuclei transplanted into unactivated amphibian eggs are known to condense into metaphase chromosomes whereas those transplanted into activated eggs decondense and enlarge. We have made cell-free cytoplasmic preparations from Rana pipiens eggs which can induce demembranated Xenopus laevis sperm to undergo changes similar to those seen in intact eggs. Sperm chromatin which is incubated for 3 hr in unactivated egg preparations made using a buffer containing 3 mM EGTA is induced to form metaphase chromosomes. However, decondensed interphase nuclei are formed when chromatin is incubated in unactivated egg preparations made without EGTA as well as in activated egg preparations. When Ca2+ ions are added to unactivated egg preparations made with EGTA, the preparations lose the ability to induce metaphase chromosome formation and become capable of decondensing sperm chromatin. Once the ability to decondense chromatin has developed, either in unactivated or activated egg preparations, it cannot be suppressed by the addition of EGTA. However, decondensation of sperm chromatin in activated egg preparations can be suppressed by the addition of unactivated egg preparations made with EGTA. In this case, the incubated sperm chromatin is induced to form metaphase chromosomes. These results may indicate that the chromosome condensation activity of unactivated egg cytoplasm can be sustained in cell-free preparations when Ca2+ ion levels are kept low, but when Ca2+ ion levels increase this activity is lost and replaced by a new activity which can decondense chromatin. Since this change in cytoplasmic activities is comparable to that occurring in the intact egg following fertilization, these results suggest that Ca2+ ions play a crucial role during activation in altering the cytoplasmic activities which control nuclear behavior.

Roles of cytosol and cytoplasmic particles in nuclear envelope assembly and sperm pronuclear formation in cell-free preparations from amphibian eggs.

A cell-free cytoplasmic preparation from activated Rana pipiens eggs could induce in demembranated Xenopus laevis sperm nuclei morphological changes similar to those seen during pronuclear formation in intact eggs. The condensed sperm chromatin underwent an initial rapid, but limited, dispersion. A nuclear envelope formed around the dispersed chromatin and the nuclei enlarged. The subcellular distribution of the components required for these changes was examined by separating the preparations into soluble (cytosol) and particulate fractions by centrifugation at 150,000 g for 2 h. Sperm chromatin was incubated with the cytosol or with the particulate material after it had been resuspended in either the cytosol, heat-treated (60 or 100 degrees C) cytosol or buffer. We found that the limited dispersion of chromatin occurred in each of these ooplasmic fractions, but not in the buffer alone. Nuclear envelope assembly required the presence of both untreated cytosol and particulate material. Ultrastructural examination of the sperm chromatin during incubation in the preparations showed that membrane vesicles of approximately 200 nm in diameter, found in the particulate fraction, flattened and fused together to contribute the membranous components of the nuclear envelope. The enlargement of the sperm nuclei occurred only after the nuclear envelope formed. The pronuclei formed in the cell-free preparations were able to incorporate [3H]dTTP into DNA. This incorporation was inhibited by aphidicolin, suggesting that the DNA synthesis by the pronuclei was dependent on DNA polymerase-alpha. When sperm chromatin was incubated greater than 3 h, the chromatin of the pronuclei often recondensed to form structures resembling mitotic chromosomes within the nuclear envelope. Therefore, it appeared that these ooplasmic preparations could induce, in vitro, nuclear changes resembling those seen during the first cell cycle in the zygote.

Roles of Ca ions and ooplasmic factors in the resumption of metaphase-arrested meiosis in Rana pipiens oocytes.

Fully grown amphibian oocytes are arrested at the diplotene stage of meiosis. When they undergo meiotic maturation, meiosis resumes and the oocyte chromosomes condense to metaphase. During this period, the oocyte cytoplasm develops 'chromosome condensation activity' (CCA), the ability to induce the formation of metaphase chromosomes from nuclei transplanted into the oocytes. The cytoplasm also produces 'maturation promoting factor' (MPF), the substance that induces meiotic maturation when injected into oocytes. Also, before meiosis is arrested again at the 2nd metaphase, the cytoplasm develops 'cytostatic factor' (CSF), the substance that causes metaphase arrest when injected into zygotes. Since CSF-arrested zygotes have properties similar to those of metaphase-arrested oocytes, including the potential to resume cell cycle activities, CSF appears to be a genuine factor that causes meiotic arrest. Following oocyte activation, meiosis is completed and the chromosomes decondense to form a pronucleus. During this period, the oocyte cytoplasm loses its CCA and develops 'chromosome decondensation activity' (CDA), the ability to decondense the chromatin of injected nuclei. Concomitantly, MPF and CSF disappear. Both MPF and CSF are inactivated by Ca2+ ions, in vitro. The sensitivity of CCA to Ca2+ and the requirement for Ca2+ during the development of CDA have also been demonstrated in vitro by incubating demembranated sperm nuclei in cell-free preparations from unactivated or activated oocytes. Preparations made from unactivated oocytes in the presence of EGTA exhibit CCA, whereas those made in the absence of EGTA, as well as those made from activated eggs, exhibit CDA. Unactivated ooplasmic preparations made using EGTA lose CCA and develop CDA when Ca2+ ions are added to them. However, at low Ca2+ concentrations CCA is sustained and, when unactivated and activated preparations are mixed, is able to overcome CDA. Therefore, it is likely that at low intracellular Ca2+ levels in unactivated oocytes, CSF is stable and CCA predominates over CDA, thus preventing oocyte chromosomes from decondensing. However, when Ca2+ levels are elevated during oocyte activation, CSF disappears and CCA is replaced by CDA. This change in cytoplasmic activities may allow meiosis to resume.