mRNA localization patterns in zebrafish oocytes

In both invertebrate and vertebrate systems, the localization of maternal mRNAs is a common mechanism used to influence developmental processes, including the establishment of the dorsal/ventral axis, anterior/posterior axis, and the germ line (for review, see Bashirullah et al., 1998. Annu. Rev. Biochem. 67, 335-394). While the existence of localized maternal mRNAs has been reported in the zebrafish, Danio rerio, the precise localization patterns of these molecules during oogenesis has not been determined. In this study, in situ hybridization experiments were performed on zebrafish ovaries and activated eggs to examine different mRNA localization patterns. The results establish that while some maternal mRNAs remain ubiquitously distributed throughout the oocyte, other mRNAs follow specific localization patterns, including localization to the animal pole, localization to the vegetal pole, and cortical localization. The animal/vegetal axis is first apparent in stage II oocytes when the earliest mRNA localization is seen. Unique patterns of localization are seen in mature eggs as well. Some mRNAs maintain their oocyte localization patterns, while others localize upon egg activation (fertilization).     

Vegetal localization of the maternal mRNA encoding an EDEN-BP/Bruno-like protein in zebrafish

Asymmetric distribution of maternal mRNAs has not been well documented in zebrafish. Recently, we have shown that dazl mRNA is localized at the vegetal pole. Here we report a novel zebrafish gene, bruno-like (brul), which provides another example of vegetal mRNA localization. brul encodes an Elav-type RNA-binding protein that belongs to the Bruno-like family that includes mammalian CUG-BP, Xenopus EDEN-BP, and Drosophila Bruno. At 24 hpf, brul mRNA was abundant in lens fiber cells. At the onset of embryogenesis, maternal brul mRNA was detected at the vegetal pole, and it then migrated rapidly toward the blastoderm through yolk cytoplasmic streams. During oogenesis, brul mRNA became localized at the vegetal cortex at stage II, later than dazl mRNA. We found that anchoring of brul mRNA was dependent on microfilaments.     

Functioning of the Drosophila orb gene in gurken mRNA localization and translation.

The orb gene encodes an RNA recognition motif (RRM)-type RNA-binding protein that is a member of the cytoplasmic polyadenylation element binding protein (CPEB) family of translational regulators. Early in oogenesis, orb is required for the formation and initial differentiation of the egg chamber, while later in oogenesis it functions in the determination of the dorsoventral (DV) and anteroposterior axes of egg and embryo. In the studies reported here, we have examined the role of the orb gene in the gurken (grk)-Drosophila epidermal growth factor receptor (DER) signaling pathway. During the previtellogenic stages of oogenesis, the grk-DER signaling pathway defines the posterior pole of the oocyte by specifying posterior follicle cell identity. This is accomplished through the localized expression of Grk at the very posterior of the oocyte. Later in oogenesis, the grk-DER pathway is used to establish the DV axis. Grk protein synthesized at the dorsal anterior corner of the oocyte signals dorsal fate to the overlying follicle cell epithelium. We show that orb functions in both the early and late grk-DER signaling pathways, and in each case is required for the localized expression of Grk protein. We have found that orb is also required to promote the synthesis of a key component of the DV polarity pathway, K(10). Finally, we present evidence that Orb protein expression during the mid- to late stages of oogenesis is, in turn, negatively regulated by K(10).     

The cytoskeleton and mRNA localization.

The localization of mRNA appears to facilitate protein sorting, so that proteins are synthesized in specific cellular regions. The spatial information on the mRNA may be transduced by proteins that recognize specific localizing sequences on the 3' end and then chaperone the mRNA, presumably along filaments, to its destination. Additional sequences such as poly(A), or the nascent chains of cytoskeleton-associated proteins, may then anchor mRNAs on the cytoskeleton.     

Determinants of mRNA localization

RNA localization provides a mechanism for protein targeting within developing or differentiating cells. Specific cis-acting sequences on mRNA mediate this process. Such 'localizer' or 'zipcode' nucleic acid sequences have been restricted to the 3' untranslated region of several mRNAs. The presence of genetic information denoting a spatial component of translation adds a new dimension to gene expression.     

Expression of isotocin-neurophysin mRNA in developing zebrafish

Neurohypophysial peptides are important regulators of homeostasis, reproduction and behavior. We have sequenced a zebrafish cDNA representing isotocin-neurophysin (IT-NP) mRNA. The developmental expression pattern of zebrafish IT-NP mRNA was determined by whole-mount in situ hybridization histochemistry. At 32 h post fertilization (hpf) no IT-NP mRNA is detected. However, by 36 hpf, staining for IT-NP mRNA is detected in a tight bilateral cluster of cells located in the anterior hypothalamus. The IT-NP mRNA expression pattern remains remarkably stable throughout further development at least until 120 hpf.     

Maternal and zygotic activity of the zebrafish ogon locus antagonizes BMP signaling.

The dorsal-ventral axis of vertebrate embryos is thought to be specified by a gradient of bone morphogenetic protein (BMP) activity, which, in part, arises through the interaction of dorsally expressed antagonists Chordin and Noggin with the ventralizing BMPs. The zebrafish mercedes(tm305), ogon(m60), and short tail(b180) mutations produce ventralized phenotypes, including expanded bmp2b/4 expression domains. We find that the three mutations are allelic and that the locus they define, renamed ogon (ogo), maps to linkage group 25. The ogo(m60) and ogo(b180) mutations are deficiencies and thus represent null alleles, whereas the ENU-induced allele ogo(tm305) retains partial function. Aspects of the ogo(m60) and ogo(tm305) mutant phenotypes are fully suppressed by overexpression of BMP antagonists. Moreover, swirl(tc300), a null mutation in bmp2b, is epistatic to ogo(m60) mutation, providing further evidence that ogo normally functions in a BMP-dependent manner. Embryonic patterning is highly sensitive to maternal and zygotic ogo gene dosage, especially when the level of zygotic chordin activity is also reduced. However, elimination of the zygotic activity of both genes does not result in a completely ventralized embryo. Thus, while ogo and chordin are required to limit activity of BMPs, additional mechanisms must exist to block these ventralizing signals. We have ruled out zebrafish noggin homologues as candidates for the ogo gene, including a newly identified gene, nog1, which is specifically expressed in the gastrula organizer. The results suggest that ogo encodes an as yet unidentified dorsalizing factor that mediates dorsoventral patterning by directly or indirectly antagonizing BMP activity.     

Progress towards cell-mediated gene transfer in zebrafish.

Although the zebrafish possesses several favourable characteristics that make it an ideal model for genetic studies of vertebrate development, one disadvantage of this model system is the absence of methods for the production of gene knockouts. The authors' laboratory, and others, are working to develop zebrafish pluripotent embryonic stem (ES) and primordial germ cell (PGC) cultures that can be used for cell-mediated gene transfer and the production of knockout mutant lines of fish. Progress has been made in developing short-term cell cultures that possess the ability to contribute to multiple tissues, including the germ line of a host embryo, and transgenic lines of zebrafish have been established using the embryo cell cultures. Work is in progress to extend the length of time that the embryo cells can be maintained in culture without losing their ability to generate germ-line chimeras.     

A mutation in the zebrafish maternal-effect gene nebel affects furrow formation and vasa RNA localization

BACKGROUND: In many animals, embryonic patterning depends on a careful interplay between cell division and the segregation of localized cellular components. Both of these processes in turn rely on cytoskeletal elements and motor proteins. A type of localized cellular component found in most animals is the germ plasm, a specialized region of cytoplasm that specifies the germ-cell fate. The gene vasa has been shown in Drosophila to encode an essential component of the germ plasm and is thought to have a similar function in other organisms. In the zebrafish embryo, the vasa RNA is localized to the furrows of the early cellular divisions. RESULTS: We identified the gene nebel in a pilot screen for zebrafish maternal-effect mutations. Embryos from females homozygous for a mutation in nebel exhibit defects in cell adhesion. Our analysis provides genetic evidence for a function of the microtubule array that normally develops at the furrow in the deposition of adhesive membrane at the cleavage plane. In addition, nebel mutant embryos show defects in the early localization of vasa RNA. The vasa RNA localization phenotype could be mimicked with microtubule-inhibiting drugs, and confocal microscopy suggests an interaction between microtubules and vasa-RNA-containing aggregates. CONCLUSIONS: Our data support two functions for the microtubule reorganization at the furrow, one for the exocytosis of adhesive membrane, and another for the translocation of vasa RNA along the forming furrow.     

Maternal cadmium exposure induces mt2 and smtB mRNA expression in zebrafish (Danio rerio) females and their offspring

The present study aimed to identify the effects of maternal cadmium (Cd(2+)) exposure on the mRNA expression of mt2 (metallothionein-2) and smtB (similar to metallothionein-B) in female zebrafish (Danio rerio) and their offspring (F1 larvae). Zebrafish females were exposed to 0, 8.9, 17.8, and 35.6 μM Cd(2+) for 72 h, and their ovaries and F1 larvae were collected to measure their Cd(2+) contents and their smtB and mt2 mRNA expression. Cd(2+) contents and the mRNA expression of smtB and mt2 in F1 larvae all showed positive correlations with the maternal Cd(2+) treatment dose. The mt2 was 1.9- to 3.4-fold higher than smtB in F1 larvae. Furthermore, F1 larvae had noticeably enhanced Cd(2+) tolerance after maternal Cd(2+) treatment. These results demonstrate that maternal Cd(2+) was transferred to larval fish and induced mt2 and smtB mRNA expression to protect larva against the impacts of Cd(2+). In female ovaries, mt2 expression showed a noticeable increase after exposure to a metal environment, while smtB did not show exactly the same effect. The study can only conclude that smtB might have a much different role other than just protecting against the impacts of metals.     

Redundant RNA recognition events in bicoid mRNA localization.

A cis-acting signal in the 3' UTR of the Drosophila bicoid mRNA directs both the transport of the mRNA from the nurse cells to the oocyte and its anterior localization within the oocyte. Here we demonstrate that the signal mediates redundant RNA recognition events, A and B, that initiate largely overlapping programs of mRNA localization during oogenesis. Recognition event A requires a region encompassing stem-loops IV/V of the predicted secondary structure, and can be eliminated by a single nucleotide mutation. Localization initiated through event B begins slightly later in oogenesis, and requires sequences that have not been narrowly defined. Using forms of the 3' UTR lacking this RNA recognition redundancy, we reexamine the roles of the swallow, staufen, and exuperantia genes, which are all required for normal bicoid mRNA localization. Our results reveal that exuperantia first becomes essential for localization at a time when well-defined microtubule tracks between the nurse cells and oocyte disappear. Thus, exuperantia may specifically facilitate a form of nurse cell-to-oocyte mRNA transport not dependent on the microtubule tracks.     

Expression pattern of the single-minded gene in zebrafish embryos.

Recently we isolated a homolog of the Drosophila single-minded (sim) gene from a zebrafish cDNA library. The 4380-bp of zebrafish sim cDNA encodes a polypeptide of 585 amino acids with strikingly conserved bHLH and PAS A/B domains in the amino-terminal region. During embryogenesis, sim mRNA appears in the animal hemisphere as early as 3 h post-fertilization and is expressed in a widespread pattern throughout the epiblast at the 75% epiboly stage. During the segmentation stage, sim mRNA is prominently expressed in the primordium of the hindbrain and appears as a transverse stripe in the epithelial layers of the mid-diencephalic boundary (MDB). During the pharyngula stage, sim is no longer expressed in the hindbrain, but continues to be expressed in the MDB and extends to the caudal diencephalon along the ventral midline. In addition, sim mRNA is prominent in the two pharyngeal arches. During the larval stage, sim mRNA is transcribed in the esophagus, liver, pancreas, and intestine. In contrast, sim mRNA is no longer detectable in the forebrain after hatching. In adult fish, sim is widely expressed in brain, eyes, gill, heart, liver, and intestine.     

Vasa protein expression and localization in the zebrafish

Primordial germ cell (PGC) development in the zebrafish is poorly understood. The expression of vasa RNA, the only molecular marker so far found to be expressed in fish PGCs, suggests its function in the establishment of the germline. The protein product of vasa is present throughout the life cycle in the germline of Drosophila, Caenorhabditis and Xenopus. The expression pattern of the Vasa protein in zebrafish, is still unresolved. We generated an anti-Vasa polyclonal antibody and show that it is maternally expressed initially throughout the embryo. Interestingly, from the two-cell- to the 1000-cell stage the protein is highly concentrated in two 'dots' near the center of the blastomeres and as such remains longest detectable in the animal pole blastomeres. The first distinct cell-specific expression occurs at 60% epiboly on one side of the blastoderm margin. The Vasa protein in the PGCs is organized in a subcellular granular-like conformation which is dynamic throughout development.