A mRNA localized to the vegetal cortex of Xenopus oocytes encodes a protein with a nanos-like zinc finger domain

Apparent continuity between the messenger transport organizer and late RNA localization pathways during oogenesis in Xenopus

The localization of RNAs at the vegetal cortex in Xenopus oocytes is a complex process, involving at least two different pathways. The early, or messenger transport organizer (METRO), pathway, localizes RNAs such as Xlsirts, Xcat2 and Xwnt11 during stages 1 and 2 of oogenesis, while the late pathway localizes RNAs such as Vg1 during stages 2-4. We demonstrate that the onset of Vg1 localization is characterized by its microtubule-independent binding to a subdomain of the endoplasmic reticulum (ER). The formation of this unique ER structure is intimately associated with the movement of the mitochondrial cloud toward the vegetal cortex. In addition, we demonstrate that the mitochondrial cloud contains a gamma-tubulin-positive structure that may function as a microtubule organizing center for establishing microtubule tracks for Vg1 localization. These data, support, although they do not prove, a model in which the development of the late pathway machinery relies upon the prior functioning of the early pathway.

Nanos and Pumilio have critical roles in the development and function of Drosophila germline stem cells

The zinc-finger protein Nanos and the RNA-binding protein Pumilio act together to repress the translation of maternal hunchback RNA in the posterior of the Drosophila embryo, thereby allowing abdomen formation. nanos RNA is localized to the posterior pole during oogenesis and the posteriorly synthesized Nanos protein is sequestered into the germ cells as they form in the embryo. This maternally provided Nanos protein is present in germ cells throughout embryogenesis. Here we show that maternally deposited Nanos protein is essential for germ cell migration. Lack of zygotic activity of nanos and pumilio has a dramatic effect on germline development of homozygous females. Given the coordinate function of nanos and pumilio in embryonic patterning, we analyzed the role of these genes in oogenesis. We find that both genes act in the germline. Although the nanos and pumilio ovarian phenotypes have similarities and both genes ultimately affect germline stem cell development, the focus of these phenotypes appears to be different. While pumilio mutant ovaries fail to maintain stem cells and all germline cells differentiate into egg chambers, the focus of nanos function seems to lie in the differentiation of the stem cell progeny, the cystoblast. Consistent with the model that nanos and pumilio have different phenotypic foci during oogenesis, we detect high levels of Pumilio protein in the germline stem cells and high levels of Nanos in the dividing cystoblasts. We therefore suggest that, in contrast to embryonic patterning, Nanos and Pumilio may interact with different partners in the germline.

Germ plasm in Caenorhabditis elegans, Drosophila and Xenopus

Special cytoplasm, called germ plasm, that is essential for the differentiation of germ cells is localized in a particular region of Caenorhabditis elegans, Drosophila and Xenopus eggs. The mode of founder cell formation of germline, the origin and behavior of the germline granules, and the molecules localized in germline cells are compared in these organisms. The common characteristics of the organisms are mainly as follows. First, the founder cells of germline are established before the initiation of gastrulation. Second, the germline granules or their derivatives are always present in germline cells or germ cells throughout the life cycle in embryos, larvae, and adults. Lastly, among the proteins localized in the germ plasm, only Vasa protein or its homolog is detected in the germline cells or germ cells throughout the life cycle. As the protein of vasa homolog has been reported to be also localized in the germline-specific structure or nuage in some of the organisms without the germ plasm, the possibility that the mechanism for differentiation of primordial germ cells is basically common in all organisms with or without the germ plasm is discussed.

A Xenopus DAZ-like gene encodes an RNA component of germ plasm and is a functional homologue of Drosophila boule

We have identified a localized RNA component of Xenopus germ plasm. This RNA, Xdazl (Xenopus DAZ-like), encodes a protein homologous to human DAZ (Deleted in Azoospermia), vertebrate DAZL and Drosophila Boule proteins. Human males deficient in DAZ have few or no sperm and boule mutant flies exhibit complete azoospermia and male sterility. Xdazl RNA was detected in the mitochondrial cloud and vegetal cortex of oocytes. In early embryos, the RNA was localized exclusively in the germ plasm. Consistent with other organisms, Xdazl RNA was also expressed in the spermatogonia and spermatocytes of frog testis. Proteins in the DAZ-family contain a conserved RNP domain implying an RNA-binding function. We have shown that Xdazl can function in vitro as an RNA-binding protein. To determine if the function of Xdazl in spermatogenesis was conserved, we introduced the Xdazl cDNA into boule flies. This resulted in rescue of the boule meiotic entry phenotype, including formation of spindles, phosphorylation of histone H3 and completion of meiotic cell division. Overall, these results suggest that Xdazl may be important for primordial germ cell specification in the early embryo and may play a role analogous to Boule in promoting meiotic cell division.

Two copies of a subelement from the Vg1 RNA localization sequence are sufficient to direct vegetal localization in Xenopus oocytes

Localization of mRNA has emerged as a fundamental mechanism for generating polarity during development. In vertebrates, one example of this phenomenon is Vg1 RNA, which is localized to the vegetal cortex of Xenopus oocytes. Vegetal localization of Vg1 RNA is directed by a 340-nt sequence element contained within its 3′ untranslated region. To investigate how such cis-acting elements function in the localization process, we have undertaken a detailed analysis of the precise sequence requirements for vegetal localization within the 340-nt localization element. We present evidence for considerable redundancy within the localization element and demonstrate that critical sequences lie at the ends of the element. Importantly, we show that a subelement from the 5′ end of the Vg1 localization element is, when duplicated, sufficient to direct vegetal localization. We suggest that the Vg1 localization element is composed of smaller, redundant sequence motifs and identify one such 6-nt motif as essential for localization. These results allow insight into what constitutes an RNA localization signal and how RNA sequence elements may act in the localization process.

Localized maternal proteins in Xenopus revealed by subtractive immunization

It has long been appreciated that the localization of cytoplasmic determinants in the egg can provide the foundation for patterning in the embryo. Differences in cell fate among the early blastomeres are thus a consequence of asymmetric distributions of informational molecules prior to fertilization. The frog egg has a single axis of asymmetry present prior to fertilization, the animal/vegetal axis, and the localization of developmental information appears to be polarized along this axis. Such developmental information can be localized as either RNA or protein; localized RNAs are well documented in the Xenopus oocyte, and some are thought to play roles in axial patterning. While it is apparent that not all of the localized maternal components are RNAs, much less is known about maternal proteins that might be localized in the egg. In the present study, we have taken a novel approach to identify localized maternal proteins within the Xenopus egg. Using a subtractive immunization strategy, we have generated monoclonal antibodies which recognize antigens that are restricted to the vegetal cortex of fertilized eggs. Analysis of biogenesis during oogenesis reveals two distinct patterns of localization to the cortex. At least three of these localized antigens are proteins, and these localized proteins could represent maternal determinants with roles in patterning.

Dorsal determinants in the Xenopus egg are firmly associated with the vegetal cortex and behave like activators of the Wnt pathway

The Xenopus egg contains maternal dorsal determinants that are specifically located at the vegetal cortex. To study physical and functional properties of the dorsal determinants, we took advantage of the animal-vegetal reversed embryo. The animal-vegetal reversed embryo is produced by inversion of the fertilized egg, which results in formation of ectoderm and endoderm from the unpigmented and the pigmented halves, respectively [Neff et al. (1983). Dev. Biol. 97, 103-112; Black and Gerhart (1985). Dev. Biol. 108, 310-324]. We demonstrated by cytoplasmic transplantation that the dorsal activity was specifically localized to the unpigmented cortical cytoplasm of the inverted egg, which is segregated into the future ectodermal lineage. This result suggests that the dorsal determinants are associated with the unpigmented cortex and are not dislodged by the inversion. In addition, we found that two vegetally localized transcripts, Xcat2 and Vg1 mRNAs, were present in the reversed animal pole of the inverted egg, suggesting their association with the unpigmented cortex. In order to compare the dorsal determinant activity with known dorsalizing molecules, we examined the expression pattern of Xnr3 and Siamois in the reversed embryo because these two genes are activated by the Wnt-pathway activators (Xwnt-8, beta-catenin, etc.) but not by other dorsalizing molecules (noggin, BVg1, etc.). Animal cap of the reversed embryo, which received the unpigmented cortex of the egg, expressed Xnr3 and Siamois. However, Mix.1, a marker expressed in endoderm and mesoderm in the normal embryo in response to mesodermal inducers, was not detected in the animal cap of the reversed embryo. In addition, we found that beta-catenin protein accumulated in nuclei of unpigmented animal pole cells of the reversed embryo. These results suggest that the maternal dorsal determinants behave more similarly to the Wnt-pathway activators than noggin or BVg1.

Nanos and pumilio establish embryonic polarity in Drosophila by promoting posterior deadenylation of hunchback mRNA

Nanos protein promotes abdominal structures in Drosophila embryos by repressing the translation of maternal hunchback mRNA in the posterior. To study the mechanism of nanos-mediated translational repression, we first examined the mechanism by which maternal hunchback mRNA is translationally activated. In the absence of nanos activity, the poly(A) tail of hunchback mRNA is elongated concomitant with its translation, suggesting that cytoplasmic polyadenylation directs activation. However, in the presence of nanos the length of the hunchback mRNA poly(A) tail is reduced. To determine if nanos activity represses translation by altering the polyadenylation state of hunchback mRNA, we injected various in vitro transcribed RNAs into Drosophila embryos and determined changes in polyadenylation. Nanos activity reduced the polyadenylation status of injected hunchback RNAs by accelerating their deadenylation. Pumilio activity, which is necessary to repress the translation of hunchback, is also needed to alter polyadenylation. An examination of translation indicates a strong correlation between poly(A) shortening and suppression of translation. These data indicate that nanos and pumilio determine posterior morphology by promoting the deadenylation of maternal hunchback mRNA, thereby repressing its translation.

A nanos homolog in leech

From the glossiphoniid leech Helobdella robusta, we have cloned and determined the complete coding sequence of Hro-nos, a gene homologous to the nanos gene from Drosophila melanogaster. Developmental northern blots show that Hro-nos, like nanos, is a maternal transcript that decays rapidly during early development. A polyclonal antiserum raised against the HRO-NOS protein was used in developmental western blots and for immunostaining leech embryos of different developmental stages. The HRO-NOS protein is first detectable in 2-cell embryos (4-6 hours of development) and exhibits a transient expression peaking during fourth cleavage (9-12 cells; 8–14 hours of development). The HRO-NOS protein exhibits a graded distribution along the primary embryonic axis and is partitioned unequally between the sister cells DNOPQ and DM, progeny of macromere D' at fourth cleavage: DNOPQ is the segmental ectoderm precursor cell and exhibits levels of HRO-NOS protein that are at least two-fold higher than in cell DM, the segmental mesoderm precursor cell. The observed expression pattern suggests that Hro-nos plays a role in the decision between ectodermal and mesodermal cell fates in leech.

Requirement for a noncoding RNA in Drosophila polar granules for germ cell establishment

In Drosophila embryos, germ cell formation is induced by specialized cytoplasm at the posterior of the egg, the pole plasm. Pole plasm contains polar granules, organelles in which maternally produced molecules required for germ cell formation are assembled. An untranslatable RNA, called Polar granule component (Pgc), was identified and found to be localized in polar granules. Most pole cells in embryos produced by transgenic females expressing antisense Pgc RNA failed to complete migration and to populate the embryonic gonads, and females that developed from these embryos often had agametic ovaries. These results support an essential role for Pgc RNA in germline development.

Complex formation between stage-specific oocyte factors and a Xenopus mRNA localization element

It is a long-standing proposal that localization of maternal factors in eggs can provide the basis for pattern formation in the early embryo. The localized information can be stored as RNA, one example being Vg1 RNA, which is localized exclusively to the vegetal hemisphere of Xenopus oocytes and eggs. Localization of Vg1 mRNA is directed by a 340-nt sequence element contained within its 3' untranslated region. To understand the mechanism of localization, I have tested whether factors from the oocyte interact specifically with the RNA localization sequence. Results presented here show that a set of oocyte proteins form complexes with the localization element both in vitro and in vivo. These proteins are specifically enriched in the stages of oogenesis during which localization occurs and recognize sub-elements of the RNA localization element that are essential for localization in vivo. These data suggest that formation of a localization-specific RNA-protein complex may be the first step in directing Vg1 mRNA to its subcellular destination.

The Xenopus T-box gene, Antipodean, encodes a vegetally localised maternal mRNA and can trigger mesoderm formation

We have used differential display to identify genes inducible by activin and isolated a novel member of the T-box gene family that includes the Xenopus genes Xbrachyury and Eomesodermin. Here we show that this novel gene is unique within the T-box family because it is maternally expressed at a high level. Furthermore, it belongs to a rare class of maternal mRNAs in Xenopus that are localised to the vegetal hemisphere of the egg and we have therefore named it Antipodean. We show here that low amounts of Antipodean injected into ectoderm (animal cap cells) strongly induce pan mesodermal genes such as Xbrachyury and ventral mesodermal genes such as Xwnt-8. Overexpression of Antipodean generates mesoderm of ventral character, and induces muscle only weakly. This property is consistent with the observed late zygotic Antipodean mRNA expression in the posterior paraxial mesoderm and ventral blastopore, and its exclusion from the most dorsal mesodermal structure, the notochord. Antipodean is induced by several molecules of the TGF-beta class, but in contrast to Xbrachyury, not by bFGF. This result suggests that the expression of these T-box genes may be under the control of different regulatory pathways. Finally, we demonstrate that Antipodean and Eomesodermin induce each other and both are able to induce Xbrachyury. The early zygotic expression of Antipodean is not induced by Xbrachyury, though later it is to some extent. Considering its maternal content, Antipodean could initiate a cascade of T-box gene activations. The expression of these genes may, in turn, sustain each other's expression to define and maintain the mesoderm identity in Xenopus.

A kinesin-like protein is required for germ plasm aggregation in Xenopus

In embryos of X. laevis, and many other species, early development requires targeted movements of molecules and molecular aggregates within the oocyte or egg cytoplasm. One well-known example in Xenopus is the aggregation of germ plasm, a group of cytoplasmic islands that become distributed during the first few cell cycles to cells that will give rise to the germ line. Nothing is known about the cytoskeletal motor proteins that may drive these movements. We show here that a recently identified Xenopus kinesin-like protein, Xklp1, is required for the aggregation of germ plasm in early Xenopus embryos, thus assigning this protein a role in a developmentally important cytoplasmic localization.

The mRNA encoding a beta subunit of heterotrimeric GTP-binding proteins is localized to the animal pole of Xenopus laevis oocyte and embryos

In order to provide evidence for a potential role of heterotrimeric GTP-binding proteins in the transduction of developmental signals, we prepared cDNAs from Xenopus laevis embryos and looked for fragments amplified between primers located in conserved sequences of the different subtypes of beta subunit. Using the amplified fragment as a probe, we cloned a member of the beta subunit family. The deduced protein sequence of the amphibian cDNA is highly homologous to the beta 1 subtype and, accordingly, we have named the Xenopus gene XG beta 1. In situ hybridization and RNase protection assay revealed that XG beta 1 mRNA is confined to the animal hemisphere of the mature oocyte. This localization of XG beta 1 mRNA is established at stage V during oogenesis. Following fertilization, the maternal mRNAs cosegregate with animal cells during cleavage stages. At gastrulation, transcripts are expressed in the dorsal ectoderm layer that will give rise to the central nervous system. Thus, XG beta 1 mRNA belongs to the small family of localized maternal mRNAs; as a transducing protein, its restriction to a subset of embryonic cells could mediate the distinct responsiveness which contributes to the patterning of the embryo.

Localization of Xcat-2 RNA, a putative germ plasm component, to the mitochondrial cloud in Xenopus stage I oocytes

The mitochondrial cloud is a unique cell structure found in stage I Xenopus oocytes that plays a role in mitochondriogenesis and in the distribution of germ plasm to the vegetal pole. Xcat-2 RNA specifically localizes to the mitochondrial cloud and moves with it to the vegetal subcortex in stage II oocytes. Later, in the 4-cell embryo, it is found in a pattern identical to the germ plasm. Following microinjection into stage I oocytes, synthetic Xcat-2 RNAs localize to the mitochondrial cloud within 22 hours. Transcripts are stable over this time period with very little evidence of degradation. The Xcat-2 3′untranslated region was found to be both required and sufficient for mitochondrial cloud localization. Further deletion analysis narrowed this localization signal to a 250 nucleotide region at the proximal end of the 3′untranslated region. This region is different from, but overlaps with, a domain previously shown to be sufficient to direct Xcat-2 to the vegetal cortex in stage IV oocytes. Examination of early stage I oocytes reveals a time when Xcat-2 is uniformly distributed, arguing against vectorial nuclear export into the mitochondrial cloud. Analysis of localization at different time points does not suggest active transport to the mitochondrial cloud. We postulate that localization occurs by selective entrapment of Xcat-2 within the cloud by localized binding sites.

Essential role of the posterior morphogen nanos for germline development in Drosophila

In many animal groups, factors required for germline formation are localized in germ plasm, a region of the egg cytoplasm. In Drosophila embryos, germ plasm is located in the posterior pole region and is inherited in pole cells, the germline progenitors. Transplantation experiments have demonstrated that germ plasm contains factors that can form germline, and germ plasm also directs abdomen formation. Genetic analysis has shown that a common mechanism directs the localization of the abdomen and germline-forming factors to the posterior pole. The critical factor for abdomen formation is the nanos (nos) protein (nanos). Here we show that nos is also essential for germline formation in Drosophila; pole cells lacking nanos activity fail to migrate into the gonads, and so do not become functional germ cells. In such pole cells, gene expression, which normally initiates within the gonad, begins prematurely during pole-cell migration. Premature activation of genes in germline precursors may mean that these cells fail to develop normally. A function for nos protein in Drosophila germline formation is compatible with observations of its association with germ plasm in other animals.

Identification of new localized RNAs in the Xenopus oocyte by differential display PCR

We have identified localized transcripts in full-grown Xenopus oocytes by differential display PCR. One clone, An4a, has two transcripts, which localize to the animal half of the stage VI oocyte. The transcripts are expressed throughout early development, with embryonic expression primarily in anterior neural tissues. An4a has a high degree of sequence identity to a human cDNA clone of unknown function. Another clone, the previously identified beta-transducin repeat containing protein (beta-TrCP), has three transcripts with a unique pattern of localization, one localized to the animal half and two localized primarily to the vegetal cortex. This cDNA has previously been shown to rescue a yeast cell division cycle mutant, raising the possibility that the different Xenopus transcripts are involved in animal and vegetal cell cycles. Embryonic expression is primarily in the cement gland. These new localized transcripts contribute to the general observation that the vegetal cortex, but not the animal cortex, is a specific site for RNA localization.

Localization of ribosomal protein L5 mRNA in myoplasm during ascidian development

We have isolated and characterized the cDNA clone ScYC26a from the ascidian Styela clava based on its relationship to the non-coding yellow crescent (YC) RNA. The ScYC26a mRNA has a long 5' non-coding sequence that is complementary to YC RNA. The deduced amino acid sequence indicates that ScYC26a encodes the ribosomal protein L5. The ScYC26a mRNA is probably encoded by a single copy gene, which shares genomic DNA restriction fragments with the gene encoding YC RNA, suggesting that the ScYC26a and YC genes are closely linked in the S. clava genome. Northern blot hybridization showed that S. clava eggs and embryos contain maternal ScYC26a mRNA and that zygotic ScYC26a transcripts do not accumulate until after metamorphosis. In situ hybridization showed that maternal ScYC26a mRNA is localized in the myoplasm and is segregated primarily to the muscle cell lineages during embryogenesis. The interaction of YC and ScYC26a transcripts may be involved in translational control or localization of L5 mRNA in the myoplasm.

Xenopus poly (A) binding protein maternal RNA is localized during oogenesis and associated with large complexes in blastula

Maternal mRNAs are synthesized during oogenesis and often stored for use during early embryogenesis, before the onset of zygotic transcription. The temporal and spatial regulation of maternal RNAs is likely to be crucial mechanism for the establishment of the body pattern. In the course of a study that identified a Xenopus maternal mRNA that is translationally regulated along the dorsoventral axis, several RNAs were found to behave anomalously in polysomal analysis and are further characterized here. As controls for polysome analysis, elF4E RNA and D7.1 RNA were equally translated in both dorsal and ventral cells, whereas the cell-cell signaling factor noggin RNA was not translated in either cell type. Maternal RNAs encoding poly (A) binding protein (PABP), Vg1 and Xcat-2 were associated with large complexes that, in contrast to polysomes, were not dissociated in magnesium-free buffer. Vg1 and Xcat-2 maternal mRNAs have been shown to be localized during oogenesis to the vegetal hemisphere of the oocyte [Rebagliati et al., 1985; Mosquera et al., 1993]. In situ hybridization analysis indicated that PABP RNA was also localized during oogenesis, to the animal hemisphere in stage VI oocytes. This suggests that association of maternal mRNAs with large EDTA-insensitive mRNP complexes is correlated with intracellular localization, but the specific localization within the oocyte is dependent upon the RNA species.

Localisation of metallothionein isoform mRNAs in rat hepatoma (H4) cells

The localisation of metallothionein isoform mRNAs in rat hepatoma (H4) cells was investigated using two approaches, namely Northern hybridisation of total RNA extracted from free, cytoskeletal-bound and membrane-bound polysomes isolated by a sequential detergent/salt extraction procedure and in situ hybridisation. The cytoskeletal-bound polysomes were enriched in metallothionein-I (MT-I) and c-myc mRNAs but showed a significantly lower enrichment in MT-II mRNA. These findings indicate that the MT-I mRNA is localised to the cytoskeleton during translation. In situ hybridisation using a biotin-labelled oligonucleotide probe revealed a predominantly perinuclear localisation for the MT-I mRNA.

Properties of the dorsal activity found in the vegetal cortical cytoplasm of Xenopus eggs

The Xenopus egg contains a maternal dorsal determinant that is specifically localized to the vegetal cortex. We have previously shown that vegetal cortical cytoplasm can generate a full dorsal axis when it is injected into ventral vegetal blastomeres of a cleavage-stage embryo. In this study, we have defined further the properties of the dorsal activity. The cortical dorsal activity arises during oocyte maturation after germinal vesicle breakdown. When injected into the four extreme animal pole blastomeres of ultraviolet-ventralized 32-cell embryos, vegetal cortical cytoplasm partially rescued dorsal axial structures. As revealed by lineage tracing, these axial structures formed ectopically from the progeny of the cells that were injected. Injection of animal cortical cytoplasm had no effect. When mid-blastula (stage 8) animal caps from these injected embryos were isolated and cultured, both vegetal cortex-enriched and animal cortex-enriched animal caps produced only epidermis. Therefore vegetal cortex, on its own, is not a mesoderm inducer. Between stage 8 (blastula) and stage 10 (gastrula), a ventral mesoderm-inducing signal spreads from vegetal cells towards the animal pole. We tested whether this natural mesoderm-inducing factor interacts with the activity found in the vegetal cortex. Injection of vegetal cortex enhanced the formation of neural tissue and cement gland when animal caps were isolated at stage 10. When cultured from stage 8 in the presence of the ventral mesoderm-inducing fibroblast growth factor, animal caps enriched in vegetal cortex developed significantly more neural tissue and cement gland than ones enriched in animal cortex. These results indicate that the dorsal activity localized to the egg vegetal cortex alters the response of cells to mesoderm inducers.

Activation of posterior gap gene expression in the Drosophila blastoderm

The process of body prepatterning during Drosophila blastoderm formation relies on the localized activities of zygotic segmentation genes, which are controlled by asymmetrically distributed maternal determinants. The anterior determinant bicoid, a homeodomain transcription factor, forms an anterior-to-posterior concentration gradient. It interacts with the maternal transcription factor hunchback to activate the anterior zygotic patterning genes, including the central gap gene Krüppel (Kr). In contrast, the posterior maternal system does not provide such a decisive transcription factor, but rather prevents the repressor hunchback from acting in the posterior half so that the gap genes giant (gt) and knirps (kni) are activated by an as yet unknown transcription factor. Here we show that caudal, a conserved homeodomain protein that forms a posterior-to-anterior concentration gradient, and the anterior determinant bicoid cooperate to form a partly redundant activator system in the posterior region of the embryo.

nanos is an evolutionarily conserved organizer of anterior-posterior polarity

In Drosophila melanogaster, nanos functions as a localized determinant of posterior pattern. Nanos RNA is localized to the posterior pole of the maturing egg cell and encodes a protein that emanates from this localized source. Nanos acts as a translational repressor and thereby establishes a gradient of the morphogen Hunchback. Here we show that the mechanism by which nanos acts in Drosophila is a common developmental strategy in Dipteran insects. We used cytoplasmic transplantation assays to demonstrate that nanos activity is found in posterior poleplasm of five diverse Dipteran species. Genes homologous to nanos were identified from Drosophila virilis, the housefly Musca domestica, and the midge Chironomus samoensis. These genes encode RNAs that are each localized, like nanos, to the embryonic posterior pole. Most importantly, we demonstrate that these homologues can functionally substitute for nanos in D. melanogaster. These results suggest that nanos acts in a similar pathway for axis determination in other insects. Comparison of the Nanos sequences reveals only 19% overall protein sequence similarity; high conservation of a novel zinc finger near the carboxy terminus of the protein defines a region critical for nanos gene function.

Isolation of cDNAs from maternal mRNAs specifically present during early development

In many animals the regulation of early embryonic development is under the control of mRNAs of maternal origin. We describe here the construction and characterization of a subtractive cDNA library to isolate genes whose expression is restricted to early development. Such genes might be potentially involved in developmental diseases, if accidentally expressed during adult life. Seven yet unknown genes preferentially expressed in the oocyte and present during early development were isolated from this library by differential screening. Their transcription patterns provide evidence for a selective expression during oogenesis and the existence of a gene family specifically implicated in functions linked to early embryogenesis.

The intracellular localization of messenger RNAs

As I hope this review has made clear, mRNA localization plays an important role in directing specific proteins to their correct position within a cell. Although the study of this process is still in its infancy, it is already apparent that there are several ways that mRNAs can be targeted to particular subcellular sites. However, the molecular mechanisms responsible for these different localization pathways are still largely obscure, and their elucidation must await the identification of the specific factors that mediate the interactions between the localized mRNAs and more general components such as the cytoskeleton. Most examples of localized mRNAs are likely to share several common features. First, the site of localization will be determined by the preexisting polarity of the cell, and this will most often depend on the organization of the cytoskeleton, either directly, in the case of active transport, or indirectly, when localization is mediated by localized anchoring sites or stability factors. Second, mRNA localization is likely to be tightly coupled to translational control. If it is important for a cell to synthesize a protein in a particular place, then the translation of the mRNA must be repressed until it is localized. Indeed, there are already several examples where the direct linkage between translational control and localization has been demonstrated, and these are discussed in the accompanying review by Curtis et al. (1995).

Binding of pumilio to maternal hunchback mRNA is required for posterior patterning in Drosophila embryos

Posterior patterning in Drosophila embryos is governed by nanos (nos), which acts by repressing the translation of maternal transcripts of the hunchback (hb) gene. Sites in hb mRNA that mediate this repression, named nanos response elements (NREs), have been identified. However, we know of no evidence of a direct interaction between nos, or any other protein, and the NRE. Here, we show that two proteins present in embryonic extracts, neither one nos, bind specifically to the NRE in vitro. Furthermore, we show that binding in vitro correlates with NRE function in vivo. One of the NRE-binding factors is encoded by pumilio (pum), a gene that, like nos, is essential for abdominal segmentation. These and other observations suggest that pum acts by recognizing the NRE and then recruiting nos. Presumably, the resulting complex inhibits some component of the translation machinery.

Molecular mechanisms of tissue determination and pattern formation in amphibian embryos

Factors of the TGF-beta superfamily (activin, vegetalizing factor) and the FGF family determine endoderm and mesoderm. The dorsoventral polarity of the mesoderm depends on additional factors (BMP-4, Wnt-8, noggin). Activin can directly activate gene transcription by signal transduction. Mesoderm is determined by factors prelocalized in the marginal zone. Its differentiation depends also on the animal ectoderm. Neural inducing factors have been partially purified. A masked neuralizing factor in the ectoderm is activated by induction of the ectoderm to the nervous system. Phorbolester can evoke neuralization signaling.

Two distinct pathways for the localization of RNAs at the vegetal cortex in Xenopus oocytes

We found that there are two major pathways by which RNAs are localized at the vegetal cortex during oogenesis of Xenopus laevis. One of these, through which Xlsirts, Xcat2 and Xwnt11 are localized, involves transport during stages 1 and 2 of oogenesis via a region of the mitochondrial cloud that we call the message transport organizer or METRO. This pathway involved three steps, transport of RNA from the GV to the mitochondrial cloud, sorting of the RNAs to specific regions of the METRO, and translocation to and anchoring at the vegetal cortex. These three RNAs exhibit a distinct pattern of spatial localization within the METRO when they approach the vegetal cortex. The other pathway is used by Vg1. We detected Vg1 throughout the oocyte cytoplasm during stages 1 and 2. During stage 3 it was translocated to the vegetal cortex and associated with the cortex overlapping the region at which the Xlsirt, Xcat2, and Xwnt11 RNAs are anchored. Our results also showed that anchoring of these RNAs was dependent in part on actin microfilaments, but was independent of microtubules. These results demonstrate a novel mechanism of translocation and RNA sorting used by RNAs several of which may be involved in the establishment of the embryonic body axis.

Translational control of activin in Xenopus laevis embryos

Activin is a potent mesoderm inducing factor present in embryos of Xenopus laevis. Recent evidence has implicated activin in the inhibition of neural development in addition to the well-established induction of mesoderm in ectodermal explants. These diverse effects are critically dependent on the concentration of activin yet little is known about the mechanisms regulating the level of activin in the embryo. We report that the 3' untranslated region (3' UTR) of activin beta B mRNA inhibits the translation of activin in embryos. Micro-injection of activin mRNA from which the 3' UTR has been deleted is 8-10-fold more potent in inducing mesoderm than mRNA containing the 3' UTR. Truncation of the 3' UTR also leads to a marked enhancement of activin protein levels in embryos but has no effect when the truncated mRNA is translated in vitro. The 3' UTR also confers translational inhibition on a heterologous mRNA. These data show that a maternal factor(s) present in X. laevis regulates the translation of injected activin beta B mRNA. This factor(s) could be responsible for regulating the levels of endogenous activin beta B protein during mesoderm induction and the specification of ectodermal derivatives such as neural and epidermal tissues.

Developmental evolution: insights from studies of insect segmentation

Rapid advances have been made in the understanding of the genetic basis of development and pattern formation in a variety of model systems. By examining the extent to which these developmental systems are conserved or altered between different organisms, insight can be gained into the evolutionary events that have generated the diversity of organisms around us. The molecular and genetic basis of early pattern formation in Drosophila melanogaster has been particularly well studied, and comparisons to other insects have revealed conservation of some aspects of development, as well as differences that may explain variations in early patterning events.

Translational repression as a conserved mechanism for the regulation of embryonic polarity

The mechanisms used to establish embryonic polarity are still largely unknown. A recent paper(1) describes the expression pattern of the gene glp-1, which is required for induction events during development of the nematode Caenorhabditis elegans. Although glp-1 RNA is found throughout the early embryo, Glp-1 protein is only expressed in anterior cells. This negative translational regulation in posterior cells is shown to be mediated through sequences in the glp-1 3'untranslated region (3'UTR). Thus in nematodes, as in Drosophila, translational repression is one mechanism used to establish the embryonic anterior-posterior axis.

Vg1 and regional specification in vertebrates: a new role for an old molecule

The Vg1 protein was discovered some ten years ago in a screen for localized maternal RNA molecules involved in early embryonic patterning in the frog Xenopus laevis. The localization of this molecule to the vegetal pole suggested that Vg1 might function as a determinant of embryonic cell fate, and its DNA sequence revealed that it is related to factors involved in induction of the mesoderm. However, it is only in the past year that evidence hinting at the role of Vg1 in early development has emerged. It now seems that although the key component for specifying a vertebrate dorsal axis has been known to us for a decade, cryptic processing pathways have kept its role in this important process hidden from view.

Synergy between the hunchback and bicoid morphogens is required for anterior patterning in Drosophila

Anterior patterning of the Drosophila embryo is specified by the localized expression of the gap genes, which is controlled by the gradient of the maternal morphogen bicoid (bcd). Another maternal component, hunchback (hb), can substitute for bcd in the thorax and abdomen. Here we show that hb is required for bcd to execute all of its functions. Removal of both maternal and zygotic hb produces embryos with disrupted polarity that fail to express all known bcd target genes correctly. Proper expression of hb and the head gap genes requires synergistic activation by hb and bcd. We propose that it is the combined activity of bcd and hb, and not bcd alone, that forms the morphogenetic gradient that specifies polarity along the embryonic axis and patterns the embryo. bcd may be a newly acquired Drosophila gene, which is gradually replacing some of the functions performed by maternal hb in other species.

Delocalization of Vg1 mRNA from the vegetal cortex in Xenopus oocytes after destruction of Xlsirt RNA

The Xlsirts are a family of transcribed repeat sequence genes that do not code for protein. Xlsirt RNAs become localized to the vegetal cortex of Xenopus oocytes early in oogenesis, before the localization of the messenger RNA Vg1, which encodes a transforming growth factor-beta-like molecule involved in mesoderm formation, and coincident with the localization of Xcat2 transcripts, which encode a nanos-like molecule. Destruction of the localized Xlsirts by injection of antisense oligodeoxynucleotides into stage 4 oocytes resulted in the release of Vg1 transcripts but not Xcat2 transcripts from the vegetal cortex. Xlsirt RNAs, which may be a structural component of the vegetal cortex, are a crucial part of a genetic pathway necessary for the proper localization of Vg1 that leads to subsequent normal pattern formation.

Translational control of maternal glp-1 mRNA establishes an asymmetry in the C. elegans embryo

In C. elegans, the glp-1 gene encodes a membrane receptor that is required for anterior cell fates in the early embryo. We report that GLP-1 protein is localized to anterior blastomeres in 2- to 28-cell embryos. By contrast, glp-1 mRNA is present in all blastomeres until the 8-cell stage. Furthermore, the glp-1 3' untranslated region can restrict translation of a reporter mRNA to anterior blastomeres. Therefore, the translation of maternal glp-1 mRNA is temporally and spatially regulated in the C. elegans embryo. The regulation of maternal glp-1 mRNA has striking parallels to the regulation of maternal hunchback mRNA in the Drosophila embryo. Thus, the establishment of embryonic asymmetry in diverse organisms may involve conserved mechanisms of maternal mRNA regulation.

Inducing factors in Xenopus early embryos

Recent results make it possible to postulate credible candidates for each of the known inducing signals that act to determine cell fate during Xenopus early development. Experiments on biological activity, expression patterns and inhibition of function suggest that Vg-1 and Wnt-11 may act as the primary mesoderm-inducing signals, FGF and activin may serve to relay their effects, and noggin may be a major component of the dorsalizing and neural-inducing signals from the organizer.

Translocation of repetitive RNA sequences with the germ plasm in Xenopus oocytes

Xlsirts are a family of interspersed repeat RNAs from Xenopus laevis that contain from 3 to 13 repeat units (each 79 to 81 nucleotides long) flanked by unique sequences. They are homologous to the mammalian Xist gene that is involved in X chromosome inactivation. Xlsirt RNA appears first in the mitochondrial cloud (Balbiani body) in stage 2 oocytes and is then translocated as island-like structures to the vegetal cortex at early stage 3 coincident with the localization of the germ plasm. Exogenous Xlsirt RNA injected into oocytes translocates to the location of the endogenous RNA at that particular stage. The Xlsirt RNA repeat sequences are required for translocation and can cause the translocation of heterologous unique RNAs to the vegetal cortex.