Cytological Effects of Heat-Shocks on Xenopus Oocytes and Eggs

Heat-shocks (80 min at 34°c) induce the appearance of aster-like fibrous structures (cytasters) in maturing Xenopus oocytes. Cytaster formation is suppressed by treatments with colchicine or nocodazole of heat-shocked maturing oocytes. Heat-shocks destroy the meiotic spindle, but have no effect on cytasters induced by D₂O treatment.
Heat-shocks (20 min at 36°c) also induce the formation of cytasters in unfertilized and freshly fertilized eggs of some females, but not in cleaving eggs. They suppress amphimixy, induce the regression of existing cleavage furrows and destroy the mitotic apparatuses in cleaving eggs. The arrested blastomeres often contain micronuclei (probably unfused telophase swollen chromosomes) where small basophilic nucleoli are frequently seen.
The significance of these results is discussed.     

The complex dynamic network of microtubule and microfilament cytasters of the leech zygote

The organization of the cytoskeleton in the early first interphase zygote and its involvement in organelle redistribution were studied in the glossiphoniid leech Theromyzon trizonare by confocal and electron microscopy, immunofluorescence, and time-lapse video imaging after microinjection of labeled tubulin and/or actin and loading with a mitotracker. The cytoskeleton consists of an inner or endoplasmic and an outer or ectoplasmic domain. The inner domain consists of a monaster whose fibers retract from the zygote periphery by the end of the early first interphase. The outer domain is built upon a network of microtubules and microfilaments cytasters. Short pulses of microinjected labeled actin or tubulin and Taxol treatment demonstrate that cytasters are centers of microtubule and microfilament nucleation. Immunostaining with anti-centrophilin, anti-BX-63, and anti-AH-6 indicates that the network of cytasters includes centrosomal antigens. Cytasters move in an orderly fashion at speeds of 0.5-2 micrometer/min, in an energy-dependent process retarded and finally blocked by the ATP analogue AMP-PNP and high concentrations of Taxol. Colliding cytasters fuse and form larger cytoskeletal nucleation centers. The leech zygote is a highly compartmentalized cell whose cytasters function as articulated components of a very dynamic cytoskeletal system engaged in bulk transportation of organelles during ooplasmic segregation.     

The induction of de novo centrioles in sea urchin eggs: a possible common mechanism for centriolar activation among parthenogenetic procedures

Eggs from two species of sea urchins were subjected to a variety of novel two-step parthenogenetic activation procedures. These treatments readily resulted in the formation of cytasters and centrioles. Centrioles are restricted to the cytasters, as well as to the broad perinuclear zone, and it appears that all cytasters contain one or more centrioles. The mode of centriolar origin and maturation, as revealed by these new procedures, is identical to that of centrioles induced by other procedures. Both centriolar and cytastral development are retarded by the parthenogenetic treatments; also, mitosis is generally delayed. These results, along with those of others, reveal that parthenogenetic agents have opposing effects on eggs. The agents are stimulatory in that they activate latent centrioles and the cell cycle, in general. They are inhibitory in that they suppress a variety of physiochemical events. Of these events, only one appears to be common to all parthenogenetic agents: the inhibition of protein synthesis. Egg centrioles may be kept in a latent state by repressor proteins. If these proteins normally cycle rapidly, then an inhibition of their continuous synthesis will disrupt their normal replacement rate. As such, a delay in replacement will allow functioning repressor proteins, associated with latent centrioles, to become nonfunctional, which in turn allows latent centrioles to become derepressed. This deblocking reaction would then activate the appearance of de novo centrioles in eggs.     

Reorganization and translocation of the ectoplasmic cytoskeleton in the leech zygote by condensation of cytasters and interactions of dynamic microtubules and actin filaments

The formation and bipolar translocation of an ectoplasmic cytoskeleton of rings and meridional bands was studied in interphase zygotes of the glossiphoniid leech Theromyzon trizonare. Zygotes consisted of a peripheral organelle-rich ectoplasm and an internal yolk-rich endoplasm. After microinjection of labeled tubulin and/or actin, zygotes were examined by time-lapse video imaging, immunofluorescence and confocal microscopy. The rings and meridional bands were formed by condensation of a network of moving cytasters that represented ectoplasmic secondary centers of microtubule and actin filament nucleation. In some cases the network of cytasters persisted between the rings. The cytoskeleton had an outer actin layer and an inner microtubule layer that merged at the irregularly-shaped boundary zone. Bipolar translocation of the rings, meridional bands, or the network of cytasters led to accumulation of the cytoskeleton at both zygote poles. Translocation of the cytoskeleton was slowed or arrested by microinjected taxol or phalloidin, in a dose-dependent fashion. Results of drug treatment probably indicate differences in the degree and speed at which the cytoskeleton becomes stabilized. Moreover, drugs that selectively stabilized either microtubules or actin filaments stabilized and impaired movement of the entire cytoskeleton. Microtubule poisons and latrunculin-B failed to disrupt the cytoskeleton. It is concluded that the microtubule and actin cytoskeletons are dynamic, presumably cross-linked and resistant to depolymerizing drugs. They probably move along each other by a sliding mechanism that depends on the instability of microtubules and actin filaments.     

Ca2+-stimulated ATPase during the early development of parthenogenetically activated eggs of the sea urchin Paracentrotus lividus

A Ca²⁺-stimulated ATPase shows fluctuations in the activity in parthenogenetically activated sea urchin eggs very similar to those described earlier for fertilized eggs. Besides activity peaks in the first part of a cell cycle the enzyme activity increases when the mitotic apparatus (MA) or MA-like structures like monasters or cytasters are formed. A possible function of the enzyme in the assembly of the MA is discussed.     

Cytological effects of urethan on cleavage induction in parthenogenetically activated sea urchin eggs

The effect of urethan on artificial induction of cleavage in eggs of the sea urchin, Hemicentrotus pulcherrimus, was studied. When the eggs were exposed for 20 minutes to seawater containing urethan (final concentration, 0.08 M) after butyric acid-activation and then treated with hypertonic seawater, the cleavage rate was enchanced by about 1.5 times as compared with the nontreated eggs. In the eggs exposed to urethan–seawater for over 70 minutes many clear spots appeared throughout the cytoplasm. Simultaneously, the pigment granules, which had been embedded within the cortex, migrated to the inner cytoplasm and encircled a monastral centrosphere and clear spots. The clear spots were composed of microtubules much like cytasters, and in the central region of them centrioles were not yet found. The eggs in which the pigment granules disappeared from the cortex may be more susceptible to cleavage induction by succeeding hypertonic treatment.     

The segmentation of eggs of Asterias forbesii deprived of chromatin

Summary The unfertilized egg ofAsterias forbesii from which the first polar spindle, or second polar spindle and first polar body were removed, was immersed for a period of five minutes in carbonated sea water and returned to sea water, where it developed cytasters and divided completely into a number of parts.

---

Zusammenfassung Die unbefruchteten Eier vonAsterias forbesii, aus denen die erste Richtungsspindel oder die zweite Richtungsspindel und der erste Richtungskörper entfernt worden sind, wurden 5 Minuten in mit Kohlensäure versehenes Seewasser eingelegt und dann in reines Seewasser Übertragen. Darin entwickelten sie Cytasteren und zerteilten sich in eine Anzahl vollkommen getrennter Teile.

---

---

Contribution from the Laboratory of the Bureau of Fisheries at Woods Hole, Mass.     

Changes in microtubule structures during the first cell cycle of physiologically polyspermic newt eggs

The unfertilized egg of the newt, Cynops pyrrhogaster, has a second meiotic spindle at the animal pole and numerous cortical cytasters. After physiologically polyspermic fertilization, all sperm nuclei incorporated into the egg develop sperm asters, and the cortical cytasters change into bundles of cortical microtubules. The size of the sperm asters in the animal hemisphere is ∼5.6-fold larger than that in the vegetal hemisphere. Only one sperm nucleus moves toward the center of the animal hemisphere to form a zygote nucleus with the egg nucleus. This movement is inhibited by nocodazole, but not by cytochalasin B. The centrosome in the zygote nucleus divides into two parts to form a bipolar spindle for the first cleavage synchronously with the nuclear cycle, but centrosomes of accessory sperm nuclei in the vegetal hemisphere remained to form monopolar interphase asters and subsequently degenerate around the first cleavage stage. The size of sperm asters in monospermically fertilized Xenopus eggs was ∼37-fold larger than those in Cynops eggs. Since sperm asters that formed in polyspermically fertilized Xenopus eggs exclude each other, the formation of a zygote nucleus is inhibited. Cynops sperm nuclei form larger asters in Xenopus eggs, whereas Xenopus sperm nuclei form smaller asters in Cynops eggs compared with those in homologous eggs. Since there was no significant difference in the concentration of monomeric tubulin between those eggs, the size of sperm asters is probably regulated by a component(s) in egg cytoplasm. Smaller asters in physiologically polyspermic newt eggs might be useful for selecting only one sperm nucleus to move toward the egg nucleus. Mol. Reprod. Dev. 47:210–221, 1997. © 1997 Wiley-Liss, Inc.     

NuMA expression and function in mouse oocytes and early embryos

Nuclear mitotic apparatus protein (NuMA), originally described as a nuclear protein, is an essential component in the formation and maintenance of mitotic spindle poles. In this study, we analyze the expression pattern and function of NuMA in mouse oocytes and early embryos. In germinal vesicle-stage occytes, NuMA was detected both at the centrosome and in the nucleus. However, after nuclear maturation and extrusion of the first polar body, NuMA was concentrated at the broad meiotic spindle poles and at cytasters (centers of cytoplasmic microtubule asters) of mature metaphase II oocytes. Cold-induced depolymerization of microtubules appeared to disassociate NuMA foci from the cytoplasmic cytasters. During fertilization, NuMA was relocated into the reformed male and female pronuclei. Microinjection of anti-NuMA antibody into 1 of 2 cells of 2-cell-stage embryos inhibited normal cell division. These results suggest that NuMA might play an important role in cell division during early embryonic mitosis.     

Live-cell analysis of mitotic spindle formation in taxol-treated cells

Taxol functions to suppress the dynamic behavior of individual microtubules, and induces multipolar mitotic spindles. However, little is known about the mechanisms by which taxol disrupts normal bipolar spindle assembly in vivo. Using live imaging of GFP-alpha tubulin expressing cells, we examined spindle assembly after taxol treatment. We find that as taxol-treated cells enter mitosis, there is a dramatic re-distribution of the microtubule network from the centrosomes to the cell cortex. As they align there, the cortical microtubules recruit NuMA to their embedded ends, followed by the kinesin motor HSET. These cortical microtubules then bud off to form cytasters, which fuse into multipolar spindles. Cytoplasmic dynein and dynactin do not re-localize to cortical microtubules, and disruption of dynein/dynactin interactions by over-expression of p50 "dynamitin" does not prevent cytaster formation. Taxol added well before spindle poles begin to form induces multipolarity, but taxol added after nascent spindle poles are visible-but before NEB is complete-results in bipolar spindles. Our results suggest that taxol prevents rapid transport of key components, such as NuMA, to the nascent spindle poles. The net result is loss of mitotic spindle pole cohesion, microtubule re-distribution, and cytaster formation.     

Immunocytochemical evidence for centrosomal phosphoproteins in mitotic sea urchin eggs

The change in distribution of centrosomal phosphoproteins was examined in sea urchin eggs from fertilization to the first cleavage by immunofluorescence staining with the anti-phosphoprotein antibodies, MPM-1 and MPM-2. The antibodies reacted with female pronuclei in unfertilized eggs as well as centriolar complexes located at the base of sperm flagella. After insemination, male and female pronuclei fused together to form a zygotic nucleus which was visualized by staining of fertilized eggs with the antiphosphoprotein antibodies. No major change in staining pattern was detected in extracted whole eggs until mitosis. As the fertilized eggs approached mitosis, however, the antigens started to redistribute from nuclei to the perinuclear position where the mitotic centrosomes were located. Detailed immunofluorescence observation of isolated spindles revealed that the phosphoantigens were retained in isolated structures. A major 225 kd polypeptide was recognized by the antibodies, suggesting that the 225 kd protein is a phosphocomponent of centrosomes. The area recognized by the antibody in mitotic poles enlarged with the progress of mitosis, suggesting that the antigens were apparently localized in the centrosphere. Centrospheres prepared from isolated spindles by salt extraction strongly reacted with the antibodies. One or two bright dots, which may represent centrioles, were visible in the isolated centrosphere. At the end of mitosis, the antigens again appeared in the newly formed daughter nuclei. Centriole-containing cytasters and centriole-free monasters were parthenogenetically induced in unfertilized eggs (Kuriyama and Borisy, (1983) J. Cell Sci. 61: 175-189). The antibodies stained centers of both the asters whether they contained centrioles or not, indicating that the antibodies recognizes the components of the pericentriolar material.     

Variation of B Chromosome Associated with Tissue Culture in Wheat-rye Cross

In vitro variation of B chromosomes was studied by examining the callus cells derived from the immature embryos from a cross of Chinese Spring wheat ( Triticum aestivum L.) and Fin 7416 rye ( Secale cereale L.) carrying two B chromosomes. In 40-d-old callus cells, the numbers of B chromosomes ranged from one to four in 65.6% of the cells observed. The distribution of B chromosome numbers was associated with the ploidy levels of the normal chromosomes (A chromosomes). The frequency of the cells with high numbers of B chromosomes (i.e., three or four B chromosomes) in the amphiploid cells with 56 A chromosomes was greater than those in the haploid cells with 28 A chromosomes. Although structural changes in the rye A chromosomes were observed, cytological observation and genomic in situ hybridization demonstrated that the rye B chromosomes were conserved in morphological appearance following tissue culture.     

蜘蛛的B染色体研究——Ⅰ.武汉地区粽管巢蛛的B染色体(蜘蛛目:管巢蛛科)

首次发现武汉地区粽管巢蛛胚胎细胞中存在B染色体,观察数目为1～28条,B染色体数目从有丝分裂晚前期到中期逐渐减少,在非整倍体细胞中,随着A染色体的减少逐渐增多。B染色体形态稳定;大多数为等臂染色体,少数具亚端着丝点和端着丝点;外观上明显小于A染色体。     

Structure and evolution of B chromosomes in amphibians

B chromosomes are known from 26 species of salamanders and frogs, equivalent to about 2% of amphibian species that have been karyotyped. In most cases, the structure of amphibian B chromosomes has not been extensively investigated. The exceptions are the B chromosomes of Hochstetter's frog, Leiopelma hochstetteri, from New Zealand, and the Coastal Giant salamander, Dicamptodon tenebrosus, from North America. Dicamptodon tenebrosus carries from 0 to 10 non-heterochromatic, telocentric B chromosomes per individual, averaging 0 to 3.4 B chromosomes per individual in populations throughout its extensive range. The B chromosomes of L. hochstetteri occur in frequencies averaging from 0 to 11.4 per individual in different populations, with a known maximum of 15 B chromosomes. Amphibian B chromosomes vary in size, heterochromatin, occurrence and frequency. They are commensurate in size and structure with the rest of the A set of chromosomes of the same species in which they occur. The B chromosomes are at least partly composed of repetitive DNA sequences which exist in numerous copies throughout the autosomes, in conformity to an hypothesis of intraspecific B chromosome origins.     

RanGTP and the actin cytoskeleton keep paternal and maternal chromosomes apart during fertilization

Zygotes require two accurate sets of parental chromosomes, one each from the mother and the father, to undergo normal embryogenesis. However, upon egg–sperm fusion in vertebrates, the zygote has three sets of chromosomes, one from the sperm and two from the egg. The zygote therefore eliminates one set of maternal chromosomes (but not the paternal chromosomes) into the polar body through meiosis, but how the paternal chromosomes are protected from maternal meiosis has been unclear. Here we report that RanGTP and F-actin dynamics prevent egg–sperm fusion in proximity to maternal chromosomes. RanGTP prevents the localization of Juno and CD9, egg membrane proteins that mediate sperm fusion, at the cell surface in proximity to maternal chromosomes. Following egg–sperm fusion, F-actin keeps paternal chromosomes away from maternal chromosomes. Disruption of these mechanisms causes the elimination of paternal chromosomes during maternal meiosis. This study reveals a novel critical mechanism that prevents aneuploidy in zygotes.     

Chromosomal assignment of human genes for gastrin, thyrotropin (TSH)-beta subunit and C-erbB-2 by chromosome sorting combined with velocity sedimentation and Southern hybridization

Human genes for gastrin, thyrotropin (THS)-beta subunit and c-erbB-2 were assigned to specific chromosomes using a single-laser cell sorter. For this purpose, condensed human chromosomes prepared from a karyotypically normal lymphoblastoid cell line were preliminarily fractionated by velocity sedimentation, and then sorted using a fluorescence-activated cell sorter. DNA was then extracted from the chromosomes, cleaved by restriction enzymes, and subjected to Southern hybridization using gene-specific radioactive probes. When the assignment of specific chromosomes was not possible due to chromosomal size overlapping, sorted chromosomes from cell lines carrying chromosomal translocation or from hybrid cells carrying known human chromosomes were used in addition. The results indicate that human genes for gastrin, TSH-beta, and c-erbB-2 are located on chromosomes 17, 1 and 17, respectively.     

Sorting of chromosomes by magnetic separation

Summary Chromosomes were isolated from Chinese hamster x human hybrid cell lines containing four and nine human chromosomes. Human genomic DNA was biotinylated by nick translation and used to label the human chromosomes by in situ hybridization in suspension. Streptavidin was covalently coupled to the surface of magnetic beads and these were incubated with the hybridized chromosomes. The human chromosomes were bound to the magnetic beads through the strong biotin-streptavidin complex and then rapidly separated from nonlabeled Chinese hamster chromosomes by a simple permanent magnet. The hybridization was visualized by additional binding of avidin-FITC (fluorescein) to the unoccupied biotinylated human DNA bound to the human chromosomes. After magnetic separation, up to 98% of the individual chromosomes attached to magnetic beads were classified as human chromosomes by fluorescence microscopy.     

A brief history of human autosomes.

Comparative gene mapping and chromosome painting permit the tentative reconstruction of ancestral karyotypes. The modern human karyotype is proposed to differ from that of the most recent common ancestor of catarrhine primates by two major rearrangements. The first was the fission of an ancestral chromosome to produce the homologues of human chromosomes 14 and 15. This fission occurred before the divergence of gibbons from humans and other apes. The second was the fusion of two ancestral chromosomes to form human chromosome 2. This fusion occurred after the divergence of humans and chimpanzees. Moving further back in time, homologues of human chromosomes 3 and 21 were formed by the fission of an ancestral linkage group that combined loci of both human chromosomes, whereas homologues of human chromosomes 12 and 22 were formed by a reciprocal translocation between two ancestral chromosomes. Both events occurred at some time after our most recent common ancestor with lemurs. Less direct evidence suggests that the short and long arms of human chromosomes 8, 16 and 19 were unlinked in this ancestor. Finally, the most recent common ancestor of primates and artiodactyls is proposed to have possessed a chromosome that combined loci from human chromosomes 4 and 8p, a chromosome that combined loci from human chromosomes 16q and 19q, and a chromosome that combined loci from human chromosomes 2p and 20.     

Centromere organization and UU/V sex chromosome behavior in a liverwort

In 1917, sex chromosomes in plants were discovered in a liverwort with hetermorphic U and V chromosomes. Such heteromorphy is unexpected because, unlike the XY chromosomes in diploid-dominant plants, in haploid-dominant plants the female U and the male V chromosomes experience largely symmetrical potential recombination environments. Here we use molecular cytogenetics and super-resolution microscopy to study Frullania dilatata, a liverwort with one male and two female sex chromosomes. We applied a pipeline to Illumina sequences to detect abundant types of repetitive DNA and developed FISH probes to microscopically distinguish the sex chromosomes. We also determined the phenotypic population sex ratio because biased ratios have been reported from other liverworts with heteromorphic sex chromosomes. Populations had male-biased sex ratios. The sex chromosomes are monocentric, and of 14 probes studied (eight satellites, five transposable elements and one plastid region), four resulted in unique signals that differentiated the sex chromosomes from the autosomes and from each other. One FISH probe selectively marked the centromeres of both U chromosomes, so we could prove that during meiosis each U chromosome associates with one of the opposite telomeres of the V chromosome, resulting in a head-to-head trivalent. The similarity of the two U chromosomes to each other in size and in their centromere FISH signal positions points to their origin via a non-disjunction event (aneuploidy), which would fit with the general picture of sex chromosomes rarely crossing-over and being prone to suffer from non-disjunction.