Cytostatic factor (CSF) activity in cytosols extracted from Xenopus laevis eggs

Cytostatic factor (CSF), found in the cytoplasm of unfertilized eggs of amphibians, causes metaphase arrest when microinjected into cleaving blastomeres. Although CSF from Rana pipiens eggs has been extracted and characterized, little is known about CSF extracted from eggs of other species. We investigated the conditions required to preserve CSF activity in cytosols extracted from Xenopus laevis eggs and found that it was necessary to expose the eggs to CO2 prior to extraction and that the extraction buffer must contain sodium beta-glycerophosphate. CSF activity disappeared after 24 h of storage at 2 degrees C. Cytological examination showed that the arrested blastomeres injected with cytosols had been arrested at metaphase and contained a spindle lacking polar asters, in which highly condensed chromosomes were embedded.     

Molecular characteristics of cytostatic factors in amphibian egg cytosols

In amphibians, zygotes microinjected with cytosol of unactivated eggs are arrested at metaphase of mitosis. The factor responsible for this effect has been designated 'cytostatic factor, (CSF)'. CSF is inactivated by Ca2+ addition to cytosols. During storage of the Ca(2+)-containing cytosols, a stable CSF activity develops. Therefore, the first Ca(2+)-sensitive CSF and the second Ca(2+)-insensitive CSF have been referred to as primary CSF (CSF-1) and secondary CSF (CSF-2), respectively. We have partially purified CSF-1, which had been stabilized with NaF and ATP, and CSF-2 from cytosols of Rana pipiens eggs by ammonium sulphate (AmS) precipitation and sucrose density gradient centrifugation or gel filtration, and investigated their molecular characteristics. CSF-1 was sensitive to protease, but resistant to RNAse, and inactivated within 2 h at 25 degrees C. CSF-1 could be sedimented in a sucrose density gradient from a fresh cytosol or its crude fraction precipitated at 20-30% saturation of AmS, showing the sedimentation coefficient 3S. When analyzed by SDS-polyacrylamide gel electrophoresis (PAGE), all the proteins in partially purified CSF-1 samples entered the gel and were separated into numerous peptide bands. In contrast, CSF-2 was an extremely large molecule, being eluted from Sepharose columns as molecules larger than 2 x 10(6), and failed to enter the gel when analyzed by SDS-PAGE. It could be purified 40 times from cytosols. CSF-2 was a highly stable molecule, being neither inactivated nor dissociated at pH 11.5 or by 4M-NaCl and LiCl and 8 M-urea. It was also resistant to RNAse treatment. However, CSF-2 could be broken down into small peptides of variable sizes by trypsin, alpha-chymotrypsin, and papain, but not by S. aureus V8 protease, although it was less sensitive to proteases than CSF-1. The dose-dependency test showed that the activity of CSF-2 is independent of its concentration and that an amount of CSF-2 could cause cleavage arrest earlier when injected into a blastomere in a larger volume.     

Role of amphibian egg transglutaminase in the development of secondary cytostatic factor in vitro

Fresh cytosols extracted from unfertilized amphibian eggs contain a cytostatic factor (CSF) which arrests the cell cycle at metaphase when microinjected into cleaving blastomeres. This CSF is sensitive to Ca²⁺, and is designated primary CSF (1°CSF). During storage of Ca²⁺-containing cytosols at 2°C, stable CSF activity appears, designated secondary CSF (2°CSF). In Rana pipiens egg cytosols, the development of 2°CSF coincides with the formation of a protein complex with a molecular weight above 2,000 kDa, and this large molecule exhibits a high 2°CSF activity when purified (Shibuya and Masui, 1989: Development 106:799–808). The present study shows that both the formation of 2°CSF protein complex and the development of its activity are inhibited by ethylamine and glycine-ethyl-ester (GEE), both known as potent transglutaminase (TGase) inhibitors. An affinity-purified polyclonal antibody raised against mammalian transglutaminase reacts with an approximately 68-kDa protein in fresh egg cytosols, as well as with the 2°CSF protein complex. In cytosols deprived of transglutaminase by immunoprecipitation, neither the development of 2°CSF activity nor the formation of its protein complex can occur. These results indicate that transglutaminase of Rana pipiens eggs is responsible for the formation of 2°CSF, and that transglutaminase itself is incorporated into 2°CSF molecules. Mol. Reprod. Dev. 47:302–311, 1997. © 1997 Wiley-Liss, Inc.     

Cytostatic factor (CSF) in the eggs of Xenopus laevis

Cytostatic factor (CSF) in unfertilized egg cytoplasm causes metaphase arrest when microinjected into zygotes. This was originally described in Rana pipiens eggs In Xenopus laevis, CSF has also been demonstrated. but only when the calcium-chelating agent, EGTA, was injected into the egg cytoplasm. In the present study, however, CSF was demonstrated in Xenopus eggs when donor egg activation was prevented by treatment with CO2 and Mg2+ instead of by EGTA, and recipient blastomere degeneration was prevented by increasing the KCl in the surrounding medium.     

The cytostatic effect of the cytoplasm of mature, non-activated and cleaving eggs of Rana temporaria, Acipenser stellatus and Xenopus laevis

Corroborated here is the fact, earlier established by Chulitskaya and Felgengauer (1977), that the cytoplasm of mature non-activated eggs of Rana temporaria and Acipenser stellatus, unlike that of Rana pipiens, exerts no cytostatic effect on the nuclei of the cleaving embryo, but acquires such a capacity after being treated with EGTA. EGTA treatment imparts cytostatic properties also to the cytoplasm of cleaving embryos. Revealed is the dependence of the cytostatic effect and death of injected embryos on the dose of EGTA introduced into the egg. No mitotic figures have been detected in embryos with a cytostatic effect. Upon reciprocal transplantation of the cytoplasm between Rana temporaria and Xenopus laevis, only the latter's cytoplasm possessed a cytostatic effect, while the arrest at a metaphase was found only in a few arrested blastomeres.     

Study of the cytostatic action of the cytoplasm of oocytes and mature ova of the common frog and sturgeon (Acipenser stellatus)]

The presence of the cytostatic factor found by Masui and Markert (1971) in the cytoplasm of oocytes and eggs of Rana pipiens was verified in the cytoplasm and mature inactivated eggs of the common frog Rana temporaria and sevryuga Acipenser stellatus. The cytoplasm was injected to the embryos of the same species at different phases of the first cleavage division in the animal region of one of the two blastomeres. The injection of cytoplasm did not cause the arrest of cleavage divisions. Many embryos proceeded to gastrulation. The cytoplasm of maturing oocyte and mature egg in the common frog and sevryuga, unlike in R. pipiens, has no cytostatic effect.     

Chromosome condensation activity in Rana pipiens eggs matured in vivo and in blastomeres arrested by cytostatic factor (CSF)

The ability of brain nuclei to give rise to condensed chromosomes was studied inRana pipiens eggs which had undergone meiotic maturation in vivo, in blastomeres of two-cell embryos which had been arrested at metaphase by the injection of cytostatic factor (CSF) from mature eggs, and in immature fully grown ovarian oocytes with and without prior CSF injection. Chromosomes from brain nuclei were found to condense within 4 h in mature eggs and this chromosome condensation activity was enhanced by the chelation of free Ca²⁺ in the nuclear isolation medium. Chromosomes also condensed in CSF-arrested blastomeres whether they were placed in the blastomere 30 min before the CSF injection or as long as 22 h after the CSF. Both the Ca²⁺-sensitive CSF, 1CSF, and the Ca²⁺-insensitive CSF, 2CSF, resulted in chromosome condensation within arrested blastomeres. The condensation was accompanied by the formation of multipolar spindles and asters. However, it was found that cytoplasm in CSF-arrested blastomeres does not arrest mitosis at metaphase when transferred into a cleaving blastomere. Other experiments demonstrated that chromosome condensation does not occur in ovarian oocytes even when supplied with CSF. The results are interpreted as indicating that CSF does not directly bring about chromosome condensation, but arrests the cell cycle at metaphase and stabilizes the cytoplasmic conditions of metaphase which, in turn, induce chromosome condensation in foreign nuclei as well as spindle and aster formation.     

The Role of "Cytostatic Factor (CSF)" in the Control of Oocyte Cell Cycles: A Summary of 20 Years of Study

Cytostatic Factor (CSF) is a cytoplasmic factor found in unfertilized eggs of the frog that causes metaphase arrest of cell cycles in the oocyte and zygote. CSF appears in maturing oocyte cytoplasm, but disappears during egg activation. CSF-injected zygotes are arrested at metaphase and show morphology and cellular activities strikingly similar to those of unfertilized eggs. Fresh cytosols extracted from unfertilized eggs contain unstable CSF, called "primary" CSF, which is highly sensitive to Ca ions. Cytosols incubated with Ca ions develop stable CSF, called "secondary" CSF, which is resistant to Ca ions. It has been hypothesized that primary CSF is responsible for the metaphase arrest of meiosis in the unfertilized egg, and its inactivation by a surge of Ca ions during fertilization releases the egg from metaphase arrest. Studies of molecular characteristics of partially purified primary and secondary CSFs suggest that they are both proteins. Recent studies in other laboratories indicate that primary CSF is the c-mos proto-oncogene product. The effect of CSF appears to be primarily stabilization of maturation-promoting factor (MPF), another oocyte cytoplasmic factor, that causes transition of the cell from interphase to metaphase. This paper will summarize the studies on CSF in the author's laboratory over the past 20 years, describe the development of the concept of CSF as a cell cycle regulator, and speculate on the mechanism of its action based on current knowledge.     

CNPase activity in the vertebrate retina, retinal pigmented epithelium, and choroid

The activity of the enzyme 2',3'-cyclic nucleotide 3'-phosphohydrolase (CNPase, E.C.3.1.4.37) has been studied in the retina of three vertebrate species. Activity was highest in the goldfish, followed by Xenopus laevis and Rana pipiens. Also, high activity levels were found in goldfish retinal pigment epithelium and choroid, but not in the other two species. When added to in vitro culture systems, 2',3'-cyclic nucleotides were found to have no effect on goldfish cone retinomotor movement, but caused a marked inhibition of Rana pipiens rod outer segment disc membrane shedding. It is suggested that CNPase may play a role in cellular processes requiring membrane structural reorganization.     

A comparative study of the membrane potential from before fertilization through early cleavage in two frogs, Rana pipiens and Xenopus laevis

The membrane potential of Rana pipiens eggs (-55.0 mV +/- 11.2(16)) was more likely to recover from impalement and was always more negative than that of eggs of Xenopus laevis (-19.3 mV +/- 4.2(68)). It was also much more negative than previously reported. Essentially similar membrane resistance changes were measured in the two frog species through fertilization and cleavage. Small transient depolarizations only associated with the onset of the fertilization potential in Xenopus could be prevented by hyperpolarizing the egg membrane prior to fertilization. Repolarization was variable and longer in Rana and often accompanied by large transient spontaneous depolarizations. Insemination time, the time between fertilization and cleavage and the first cleavage division cycle, were all about twice as long in Rana. Xenopus egg cleavage was invariably accompanied by pronounced transient hyperpolarizations that were essentially absent in Rana.     

A characterization of cytostatic factor activity from Xenopus eggs and c-mos-transformed cells

In Xenopus oocytes, the mos proto-oncogene product is required during meiosis I for the activation of maturation promoting factor (MPF) and the subsequent breakdown of the germinal vesicle (GVBD). In addition, the mos product has been shown to be a candidate "initiator" of meiotic maturation and is an active component of cytostatic factor (CSF), an activity responsible for metaphase II arrest. Here we demonstrate that pp39mos is required throughout oocyte maturation. We found that in progesterone stimulated oocytes, depletion of mos RNA immediately before GVBD terminally decreased MPF. Likewise, oocytes depleted of mos RNA and induced to mature with crude MPF proceeded through GVBD but lacked the MPF activity required to arrest mature oocytes at metaphase II. Thus, during maturation the mos product is required, directly or indirectly, to sustain MPF activity. On the other hand, mouse NIH/3T3 cells transformed by the constitutive expression of pp39mosxc possessed CSF activity but lacked constitutive levels of MPF or its associated histone H1 kinase activity. Moreover, cytosols prepared from transformed NIH/3T3 cells or Xenopus eggs had similar levels of CSF activity, but pp39mos levels were greater than 40-fold higher in the transformed cell extract. These analyses show that maintenance of CSF during interphase does not result in the maintenance of MPF.     

Cloning and characterization of Xenopus dicalcin, a novel S100-like calcium-binding protein in Xenopus eggs.

To contribute to the study of the calcium-signaling mechanism of egg, we cloned and characterized a 26 kDa Ca(2+)-binding protein from Xenopus laevis eggs, a homologue of Rana catesbeiana dicalcin (renamed from p26olf) that was isolated from the olfactory epithelium. The primary structure of Xenopus dicalcin shows approximately 61% identity to that of Rana dicalcin and consists of two S100-like regions aligned in tandem, as seen in Rana dicalcin. Genomic Southern blot analysis indicated that Xenopus dicalcin is a unique orthologue of Rana dicalcin. Northern blot analysis showed that Xenopus dicalcin mRNA is expressed in Xenopus eggs and also in other tissues. These results indicated that Xenopus dicalcin is a novel S100-like Ca(2+)-binding protein in Xenopus eggs.     

Studies on the appearance and nature of a maturation-inducing factor in the cytoplasm of amphibian oocytes exposed to progesterone

Full-grown oocytes of amphibians respond in vitro to exogenous progesterone by undergoing physiological maturation (breakdown of the germinal vesicle (GVBD), meiosis, and acquisition of the capacity for activation). Both cytoplasm and “cytosol” from maturing oocytes have been shown to produce similar events when injected into unstimulated oocytes. This activity appeared within 4 hr after hormone treatment in Rana pipiens and Xenopus laevis and represents the earliest detectable, specific response of the oocyte yet observed, i.e., 6–8 hr before GVBD in Rana. Maturing oocytes retained activity as long as 100 hr after exposure to progesterone, and activity was also obtained from ovulated eggs and cleaving embryos. In addition, cytoplasm from Rana pipiens, Xenopus laevis, or Ambystoma mexicanum was effective in inducing maturation in oocytes of each other, indicating a lack of specificity.Recipient oocytes of Xenopus laevis consistently began to mature within 1.5–3 hr after injection of maturing cytoplasm, well before progesterone-treated controls. The timing of the response was closely related to the quantity of cytoplasm transferred, suggesting the presence of both a minimum and threshold level of cytoplasmic factor. Serial cytoplasmic transfer in Xenopus oocytes showed no significant loss of activity through 10 injections.     

Genomic potential of erythroid and leukocytic cells of Rana pipiens analyzed by nuclear transfer into diplotene and maturing oocytes

In order to determine whether differentiated somatic cells maintain genetic totipotency, nuclear transplantations from several differentiated somatic cell types into eggs and oocytes were performed previously in Rana pipiens and Xenopus laevis. The formation of postneurula embryos and tadpoles under the direction of the test nuclei demonstrated their genetic multipotency. In addition, Rana erythrocyte nuclei transplanted to oocytes directed more extensive tadpole development than those injected into eggs. We have extended our studies of the genomic potential of differentiated somatic nuclei from the peripheral blood of Rana pipiens. First, we show that the developmental potential of erythrocyte nuclei injected into oocytes at first meiotic metaphase was greater than those injected into diplotene oocytes. Second, we demonstrate that erythroblast and leukocyte nuclei transplanted to oocytes at first meiotic metaphase promoted more advanced tadpole development than those previously injected into Xenopus eggs. Third, erythrocyte nuclei were more successful in promoting advanced tadpole development compared with erythroblast and leukocyte nuclei. The results show that differentiated somatic nuclei transferred to the cytoplasm of oocytes at first meiotic metaphase display enhanced genomic and developmental potential over those transplanted to diplotene oocytes and eggs, at least for the three nuclear cell types tested from the peripheral blood.     

Postoperative analgesics in South African Clawed frogs (Xenopus laevis) after surgical harvest of oocytes

Heightened awareness for the welfare of earlier-evolved laboratory species has prompted increasing inquiries by institutional animal care committees, investigators, and laboratory animal veterinarians regarding the need for post-surgical analgesics in laboratory Xenopus. Basic research into the mechanisms and regulation of pain in Rana pipiens has demonstrated the clinical potential of opioid, alpha2-adrenergic, and non-opioid analgesic agents in amphibians. However, clinical studies using objectively established indices of amphibian pain, or pharmacological studies in either Rana pipiens or laboratory Xenopus have not been conducted. As discussed above, comparison of limited lethality data suggests that the safety index for these agents is quite narrow in Rana pipiens. Analgesic use in laboratory Xenopus has the added risk of drowning due to over sedation. Drug doses extrapolated from such studies and intended to provide pain relief in Xenopus should therefore be considered very carefully. An additional concern for laboratory Xenopus is that the effects of these agents on amphibian oogenesis, oocyte quality, and embryogenesis are unknown. As the numbers of laboratory Xenopus used in basic and biomedical research continues to increase, clinical studies that address all of these issues cannot come too soon.     

Properties of a cytostatic factor from Xenopus laevis eggs.

The cytoplasm of mature eggs of Xenopus laevis was found to contain a cytostatic factor (CSF) which induces cleavage arrest at metaphase when microinjected into one blastomere of a two-cell embryo of Xenopus laevis or Rana pipiens. The Rana CSF was found to be incapable of arresting mitosis in Xenopus embryos. Both Xenopus and Rana CSF were stabilized during the transfer procedure by Ca²⁺-chelation in the donor egg. The Xenopus CSF was not present in the germinal vesicle of immature oocytes, but arose in the cytoplasm at the time of germinal vesicle breakdown and subsequently disappeared at the time of fertilization or egg activation.     

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.     

Soluble tubulin complexes in oocytes of the common leopard frog, Rana pipiens, contain gamma-tubulin

Oocytes of the leopard frog, Rana pipiens, contain soluble tubulin which was previously shown to exist predominantly in megadalton (MDa) fractions and that fails to readily assemble in vitro. In order to further characterize these tubulin complexes, DEAE Sepharose chromatography, Sephacryl S-300 size exclusion columns and specific immunoprecipitation were used. The results revealed the presence of alpha-, beta-, and gamma-tubulin associated with several other proteins in the soluble fraction of Rana pipiens ovarian oocytes. These Rana oocyte tubulin complexes appear to be analogous to those recently reported in Xenopus ovulated eggs as gamma-tubulin ring complexes. This seems true since both size (estimates, i.e. approximately 2MDa) and protein components are similar. Furthermore, both alpha- and gamma-tubulin antibodies immunoprecipitated identical protein bands from Rana oocyte soluble fraction. These putative Rana gamma-tubulin ring proteins include 107, 97, 95, 90 and 75 kDa components which are similar in size to those found in Xenopus and other species. Rana appears to belong to a select group in which gamma-tubulin complexes contain significant alpha- and beta-tubulin (i.e., Xenopus and sheep), while other species such as Drosophila, Aspergillus, Saccharomyces, human cells and many other mammalian cells tested lack the other tubulin components. The heterogeneity in both size and protein components of Rana oocyte gamma-tubulin ring complexes may reflect different states of tubulin complex assembly. The lower vertebrate oocyte is hypothesized to act as a repository and prestaging point for the assembly of gamma-tubulin ring complexes which will become the maternal contribution to the centrosomes of the embryo. While the gamma-tubulin ring complexes of vertebrate eggs have been described previously, this is the first report biochemically characterizing soluble gamma-tubulin complexes in vertebrate ovarian oocytes.     

Spindle checkpoint proteins Mad1 and Mad2 are required for cytostatic factor-mediated metaphase arrest

In cells containing disrupted spindles, the spindle assembly checkpoint arrests the cell cycle in metaphase. The budding uninhibited by benzimidazole (Bub) 1, mitotic arrest-deficient (Mad) 1, and Mad2 proteins promote this checkpoint through sustained inhibition of the anaphase-promoting complex/cyclosome. Vertebrate oocytes undergoing meiotic maturation arrest in metaphase of meiosis II due to a cytoplasmic activity termed cytostatic factor (CSF), which appears not to be regulated by spindle dynamics. Here, we show that microinjection of Mad1 or Mad2 protein into early Xenopus laevis embryos causes metaphase arrest like that caused by Mos. Microinjection of antibodies to either Mad1 or Mad2 into maturing oocytes blocks the establishment of CSF arrest in meiosis II, and immunodepletion of either protein blocked the establishment of CSF arrest by Mos in egg extracts. A Mad2 mutant unable to oligomerize (Mad2 R133A) did not cause cell cycle arrest in blastomeres or in egg extracts. Once CSF arrest has been established, maintenance of metaphase arrest requires Mad1, but not Mad2 or Bub1. These results suggest a model in which CSF arrest by Mos is mediated by the Mad1 and Mad2 proteins in a manner distinct from the spindle checkpoint.