Changes of gamma-tubulin expression and distribution in the zebrafish (Danio rerio) ovary, oocyte and embryo

The tubulin gene family is important for individual zebrafish development from the oocyte through to hatching. This involves often rapid, complex changes in the gametes and embryonic cells that are reflected in underlying gene expression changes. Tubulin dynamics, i.e., the interchange of polymeric and soluble forms in zebrafish oogenesis and embryogenesis, is important for microtubule (MT) cellular functions. Nevertheless, our understanding of how tubulin gene expression changes during zebrafish development is not clear. Previous data showed that soluble alpha-tubulin and gamma-tubulin are associated with large molecular weight complexes (>2MDa) which are reduced by the blastula stage, with a concomitant decrease in soluble tubulin amount. Complexes (<2MDa) then increased in the gastrula with an increase in soluble tubulin. Microarray revealed similar patterns of tubulin gene product expression for zebrafish ovary and eggs while both differed from day 4 larva. In situ hybridization with gamma-tubulin oligonucleotide probes revealed diffuse label in oocytes, with a marked localization to the primordial blastodisc upon maturation. These findings, together with recent work on gamma-tubulin ring complexes in other species, suggest that gamma-tubulin (protein complexes) may be involved in regulating tubulin dynamics, thus is important for zebrafish oogenesis and embryogenesis.     

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.     

Changes in zinc,copper and metallothionein contents during oocyte growth and early development of the teleost Danio rerio (zebrafish)

In the present report, we investigated zinc, copper and metallothionein (MT) contents in zebrafish oocytes and embryos. Our results demonstrate that the metal content increases during oocytes maturation. Zinc increases from 30 ng/oocyte (stage-1 oocytes) to 100 ng/oocyte (stage-3 oocytes); copper varied from 1 ng/oocyte (stage-1 oocytes) to 3.5 ng/oocyte (stage-3 oocytes). During embryogenesis, zinc and copper contents dramatically increase after fertilisation around the 512-cells stage, then slowly decrease until the mid-gastrula stage. During oocyte growth, the changes in the MT level are proportional to metal content, whereas during embryogenesis the pattern of MT accumulation does not parallel that of the two metals. Indeed, the maternal pool of MT decreases steadily during the early stages of the development until the gastrula stage. We have examined the effect of cadmium on the expression of MT during zebrafish development. After cadmium exposure, MT content increases in embryos at the blastula stage, whereas no induction occurs in embryos at the gastrula stage. However, pre-treatment of embryos at the gastrula stage with 5-aza-2'-deoxycytidine induces MT synthesis following exposure to cadmium. These observations show that changes in metal levels are not correlated to MT content in the embryo, whereas DNA methylation is one of the factors regulating MT expression.     

Distribution of gamma-tubulin differs in primary and secondary oocytes of Ephestia kuehniella (Pyralidae,Lepidoptera)

In a previous study, barrel-shaped spindles were found in metaphase I oocytes of Ephestia kuehniella (Pyralidae, Lepidoptera). Aster microtubules (MTs) were missing (Wolf, 1993: Cell Motil Cytoskeleton 24:200-204). This points to an acentriolar organization of the spindle apparatus. The present study was aimed at the question of whether gamma-tubulin, a newly detected member of the tubulin superfamily that has often been identified in microtubule-organizing centers, plays a role in the nucleation of MTs in meiotic spindles of the moth. To this end, the distribution of gamma tubulin was examined in oocytes of E. kuehniella using an antibody against gamma-tubulin in combination with indirect immunofluorescence. The antibody evenly decorated spindle MTs in metaphase I oocytes of the moth. Enhanced staining of the spindle poles was not detectable In subsequent stages of meiosis, gamma-tubulin was gradually lost from spindle MTs and was then found at the surface of the so-called elimination chromatin. Female meiosis in Lepidoptera is achiasmatic. The elimination chromatin, i.e., modified and persisting synaptonemal complexes, is believed to keep homologous chromosomes linked until the onset of anaphase I. In meiosis I of female Lepidoptera, the elimination chromatin persists at the spindle equa or between the segregating chromatin masses. It is plausible to assume that gamma-tubulin is involved in spindle organization in the absence of canonical centrosomes. In MTs of metaphase II spindles of E. kuehniella, gamma-tubulin was no longer detectable with our immunological approach. This points to a far-reaching change in spindle organization during transition from meiosis I to meiosis II. © 1996 Wiley-Liss, Inc.     

Xgrip109: A γ Tubulin–Associated Protein with an Essential Role in γ Tubulin Ring Complex (γTuRC) Assembly and Centrosome Function

Previous studies indicate that γ tubulin ring complex (γTuRC) can nucleate microtubule assembly and may be important in centrosome formation. γTuRC contains approximately eight subunits, which we refer to as Xenopus gamma ring proteins (Xgrips), in addition to γ tubulin. We found that one γTuRC subunit, Xgrip109, is a highly conserved protein, with homologues present in yeast, rice, flies, zebrafish, mice, and humans. The yeast Xgrip109 homologue, Spc98, is a spindle–pole body component that interacts with γ tubulin. In vertebrates, Xgrip109 identifies two families of related proteins. Xgrip109 and Spc98 have more homology to one family than the other. We show that Xgrip109 is a centrosomal protein that directly interacts with γ tubulin. We have developed a complementation assay for centrosome formation using demembranated Xenopus sperm and Xenopus egg extract. Using this assay, we show that Xgrip109 is necessary for the reassembly of salt-disrupted γTuRC and for the recruitment of γ tubulin to the centrosome. Xgrip109, therefore, is essential for the formation of a functional centrosome.     

Immunolocalization of a nuclear protein bound to the sphere organelle during oogenesis and embryogenesis inPleurodeles waltl

Summary The distribution of a nuclear antigen ofPleurodeles waltl oocytes, recognized by the monoclonal antibody B24/1, has been studied during oogenesis and early embryonic development. In stage I oocytes the antigen was localized in the nucleoplasm and on two atypical structures of lampbrush chromosomes, the spheres (S) and the mass (M). The immunostaining increased as the oocyte developed. In stage VI oocytes, the nucleoplasm and spheres showed intense staining. At this stage, the nucleoplasm often contained free spheres which were also labelled. The staining of M diminished during oogenesis, as did its size. Immunoblots of nuclear proteins of oocytes at different stages confirmed that there was an accumulation of this protein during oogenesis. During embryonic development, the nuclei of all the cells of blastula and gastrula were labelled by this antibody: there was no embryonic regionalization. Starting from the neurula stage, the staining progressively disappeared from the nuclei of ectodermal and mesodermal cells. In the tailbud stage, only the endodermal cell nuclei showed faint staining. Immunoblots of proteins from embryos of different stages showed that the quantity of this protein was constant until the young gastrula stage and then decreased progressively; in the young tailbud stage, this protein was practically absent. B24/1 is the first described protein of the sphere. This protein is accumulated in the oocyte nucleus and behaves like a maternal polypeptide, shifting early in the nuclei during embryonic development. Thus, B24/1 probably has a function required from the early developmental stages, perhaps in relation with small nuclear ribonucleoproteins.     

Small nuclear U-ribonucleoproteins in Xenopus laevis development. Uncoupled accumulation of the protein and RNA components

The accumulation of protein and RNA components of small nuclear U-ribonucleoprotein particles is non-co-ordinate during oogenesis and early embryogenesis in Xenopus laevis. Northern blot hybridization of a cloned Xenopus U2-RNA gene to oocyte and embryo RNAs demonstrates that the amount of small nuclear U2-RNA per oocyte reaches a plateau early in oogenesis (at the start of yolk deposition); further accumulation is not observed in oogenesis, nor in embryogenesis until the late blastula stage. In contrast, we show by immunoblot analysis that the proteins that bind to small nuclear U-RNAs continue to be accumulated after vitellogenesis begins, reaching maximum amounts only at the end of oocyte development. No further accumulation of these proteins is seen during embryogenesis. The consequences of this non-co-ordinate synthesis of small nuclear RNA and small nuclear RNA-binding proteins are as follows: a 10- to 20-fold excess of the protein components of the small ribonucleoprotein particles over small nuclear RNA exists in large oocytes; the bulk of the protein is cytoplasmic, while the RNA is nuclear. Thus the excess protein in the cytoplasm is uncomplexed with RNA. The imbalance between protein and RNA is not corrected until the late blastula or early gastrula stages of embryogenesis, when a tenfold increase in the amount of small nuclear U2-RNA is detected. Thus the protein, but not the RNA, components of small nuclear U-ribonucleoprotein particles are stockpiled in oocytes for later use in embryonic development. During the course of these studies, we also found that there are tissue-specific differences in the Sm-antigenic proteins of X. laevis.     

Structure and expression of the nerve growth factor gene in Xenopus oocytes and embryos

A large part of the coding portion of the Xenopus nerve growth factor (NGF) gene has been identified and cloned by the use of a chicken cDNA probe and its sequence has been determined. Comparison of the derived amino acid sequence of mature Xenopus NGF with that of other species showed a high conservation, whereas comparison of the prepropeptide showed large divergent regions alternated with short conserved regions. Expression of the NGF gene was examined during development of oocytes and embryos. Surprisingly, NGF mRNA was found in the oocyte; it is present in small previtellogenic as well as in fully grown oocytes. NGF mRNA, passed to the embryo at fertilization, is degraded before the gastrula stage and starts accumulating again around the stage of the neurula. The association of NGF mRNA with polysomes is indicative of NGF synthesis during oogenesis. In fact, by using antibodies against mouse NGF it was possible to reveal NGF molecules present as precursors. These molecules accumulate during oogenesis and are maintained in the embryos up to the blastula stage; a very faint band corresponding to a smaller size peptide is sometimes detected. A maternal role for the NGF can be proposed, although a possible activity of NGF in the oocyte cannot be ruled out.     

银鲫pou2基因在胚胎发育过程中的时空表达图式

用RACE-PCR方法从原肠期SMART文库中扩增到银鲫pou2基因的全长cDNA,其全长为2421bp,开放阅读框为1416bp,编码471个氨基酸,与斑马鱼pou2基因的氨基酸序列一致性高达91.0%。我们用RT-PCR和整体原位杂交的方法研究了银鲫pou2基因在胚胎发育过程中的时空表达图式。RT-PCR结果显示,银鲫pou2基因有母源转录本,其合子基因在高囊胚期强烈表达,在50%下包期和90%下包期也有高量的转录本,但在100%下包期表达量急剧降低,至体节期时已经完全检测不到其转录本。胚胎整体原位杂交结果显示其母源转录本在所有的胚盘细胞中。在高囊胚期和50%下包期,高度表达的合子转录本仍在所有的胚盘细胞中,但至90%下包期时,pou2的表达向胚胎背部的正中线汇聚,集中在神经板的两侧区域和脑部的两条横向条带。在100%下包期时,pou2的表达集中在神经板的中间区域以及预期形成的中后脑区域。至体节期时,转录本消失,这与RT-PCR结果高度一致。银鲫pou2基因的表达图式提示该基因在胚胎发育的早期具有重要作用,它可能参与调控神经板的形成和中后脑细胞的发育命运。     

Stage-specific inhibition of Xenopus embryogenesis by aprotinin, a serine protease inhibitor.

We examined the effects of various protease inhibitors on Xenopus laevis embryogenesis. Aprotinin, a serine protease inhibitor, was found to inhibit embryogenesis markedly, but other protease inhibitors had virtually no effect. The inhibitory effect of aprotinin was specific for embryos at the blastula or gastrula stage. These results suggest that an aprotinin-sensitive protease involved in embryonic development is secreted from the embryos or appears on the surface of embryonic cells at these stages. We found that various serine proteases are in fact secreted from the embryos with their development and that some of them are sensitive to aprotinin.     

The role of Xgrip210 in gamma-tubulin ring complex assembly and centrosome recruitment

The gamma-tubulin ring complex (gammaTuRC), purified from the cytoplasm of vertebrate and invertebrate cells, is a microtubule nucleator in vitro. Structural studies have shown that gammaTuRC is a structure shaped like a lock-washer and topped with a cap. Microtubules are thought to nucleate from the uncapped side of the gammaTuRC. Consequently, the cap structure of the gammaTuRC is distal to the base of the microtubules, giving the end of the microtubule the shape of a pointed cap. Here, we report the cloning and characterization of a new subunit of Xenopus gammaTuRC, Xgrip210. We show that Xgrip210 is a conserved centrosomal protein that is essential for the formation of gammaTuRC. Using immunogold labeling, we found that Xgrip210 is localized to the ends of microtubules nucleated by the gammaTuRC and that its localization is more distal, toward the tip of the gammaTuRC-cap structure, than that of gamma-tubulin. Immunodepletion of Xgrip210 blocks not only the assembly of the gammaTuRC, but also the recruitment of gamma-tubulin and its interacting protein, Xgrip109, to the centrosome. These results suggest that Xgrip210 is a component of the gammaTuRC cap structure that is required for the assembly of the gammaTuRC.     

Immunological detection of changes in genomic DNA methylation during early zebrafish development.

DNA methylation reprogramming, the erasure of DNA methylation patterns shortly after fertilization and their reestablishment during subsequent early development, is essential for proper mammalian embryogenesis. In contrast, the importance of this process in the development of non-mammalian vertebrates such as fish is less clear. Indeed, whether or not any widespread changes in DNA methylation occur at all during cleavage and blastula stages of fish in a fashion similar to that shown in mammals has remained controversial. Here we have addressed this issue by applying the techniques of Southwestern immunoblotting and immunohistochemistry with an anti-5-methylcytosine antibody to the examination of DNA methylation in early zebrafish embryos. These techniques have recently been utilized to demonstrate that development-specific changes in genomic DNA methylation also occur in Drosophila melanogaster and Dictyostelium discoideum, both organisms for which DNA methylation was previously not thought to occur. Our data demonstrate that genome-wide changes in DNA methylation occur during early zebrafish development. Although zebrafish sperm DNA is strongly methylated, the zebrafish genome is not detectably methylated through cleavage and early blastula stages but is heavily remethylated in blastula and early gastrula stages.     

Localized synthesis of the Vg1 protein during early Xenopus development

The Xenopus Vg1 gene encodes a maternal mRNA that is localized to the vegetal hemisphere of both oocytes and embryos and encodes a protein related to the TGF-beta family of small secreted growth factors. We have raised antibodies to recombinant Vg1 protein and used them to show that Vg1 protein is first detected in stage IV oocytes and reaches maximal levels in stage VI oocytes and eggs. During embryogenesis, Vg1 protein is synthesized until the gastrula stage. The embryonically synthesized Vg1 protein is present only in vegetal cells of an early blastula. We find that Vg1 protein is glycosylated and associated with membranes in the early embryo. Our results also suggest that a small proportion of the full-length Vg1 protein is cleaved to give a small peptide of M(r) = approximately 17 x 10(3). These results support the proposal that the Vg1 protein is an endogenous growth-factor-like molecule involved in mesoderm induction within the amphibian embryo.     

Tubulin and Microtubules in the Early Development of the Axolotl and Other Amphibia

SYNOPSIS. Unfertilized eggs of the axolotl, Ambystoma mexicanum,contain a pool of soluble tubulin accumulated during oogenesis.After initiation of cleavage the tubulin pool decreases somewhatand then remains constant through early development. Some propertiesof tubulin alter during development, but at least some of thesechanges are not due to changes in tubulin perse. However, thetubulin in axolotl oocytes, eggs, and embryos differs in someelectrophoretic properties from tubulin in adult axolotl brainand testis. Equivalent differences were observed in Necturusmaculosus tubulins. Heterogeneity of axolotl tubulins was confirmedby peptide mapping: Different patterns of peptides were formedby specific limited proteolysis of soluble tubulin from eggsand testis. The heterogeneity was more marked in the a thanin the ß subunit. Mobilization of soluble tubulininto the mitotic apparatus depends on the functioning of microtubuleorganizing centers after activation of the egg at fertilization.In eggs of the nc mutant axolotl there is a lesion in some stepof activation, one effect of which is that even though the eggscontain an essentially normal pool of tubulin, microtubulesfail to assemble, no mitotic apparatus forms, and embryonicdevelopment does not begin. These eggs can be partially correctedby injection of heterologous microtubule fragments, which elicitthe mobilization of nc tubulin into arrays of microtubules,followed by initiation of cleavage and development to a partialblastula stage. The results of these experiments are discussedin comparison with other reports in the literature about thefunction of microtubule organizing centers during amphibianegg development.     

The kinetically dominant assembly pathway for centrosomal asters in Caenorhabditis elegans is gamma-tubulin dependent

gamma-Tubulin-containing complexes are thought to nucleate and anchor centrosomal microtubules (MTs). Surprisingly, a recent study (Strome, S., J. Powers, M. Dunn, K. Reese, C.J. Malone, J. White, G. Seydoux, and W. Saxton. Mol. Biol. Cell. 12:1751-1764) showed that centrosomal asters form in Caenorhabditis elegans embryos depleted of gamma-tubulin by RNA-mediated interference (RNAi). Here, we investigate the nucleation and organization of centrosomal MT asters in C. elegans embryos severely compromised for gamma-tubulin function. We characterize embryos depleted of approximately 98% centrosomal gamma-tubulin by RNAi, embryos expressing a mutant form of gamma-tubulin, and embryos depleted of a gamma-tubulin-associated protein, CeGrip-1. In all cases, centrosomal asters fail to form during interphase but assemble as embryos enter mitosis. The formation of these mitotic asters does not require ZYG-9, a centrosomal MT-associated protein, or cytoplasmic dynein, a minus end-directed motor that contributes to self-organization of mitotic asters in other organisms. By kinetically monitoring MT regrowth from cold-treated mitotic centrosomes in vivo, we show that centrosomal nucleating activity is severely compromised by gamma-tubulin depletion. Thus, although unknown mechanisms can support partial assembly of mitotic centrosomal asters, gamma-tubulin is the kinetically dominant centrosomal MT nucleator.