Isolation of polar granules and the identification of polar granule-specific protein.

During early embryogenesis in Drosophila melanogaster the posterior polar plasm has the capacity to induce the formation of primordial germ cells. Polar granules, organelles located exclusively in this polar plasm, have been implicated in this determinative capacity. Using cell populations enriched for pole cells as starting material, we have obtained a particulate subcellular fraction that by EM analysis consists predominately of polar granules. The chemical nature of the polar granule has been defined by establishing a strict correlation between the morphological entity and the presence of specific chemical components. We have identified a basic protein with a molecular weight on SDS-polyacrylamide gels of 95,000 daltons that is unique to embryonic cell populations containing pole cells. This protein is enriched specifically in particulate subcellular fractions containing polar granules and is the only major protein species present in preparations in which polar granules are the major morphological constituent. Based on these data, polar granules appear to be composed primarily of one major basic protein species.     

Isolation of new polar granule components in Drosophila reveals P body and ER associated proteins

Germ plasm, a specialized cytoplasm present at the posterior of the early Drosophila embryo, is necessary and sufficient for germ cell formation. Germ plasm is rich in mitochondria and contains electron dense structures called polar granules. To identify novel polar granule components we isolated proteins that associate in early embryos with Vasa (VAS) and Tudor (TUD), two known polar granule associated molecules. We identified Maternal expression at 31B (ME31B), eIF4A, Aubergine (AUB) and Transitional Endoplasmic Reticulum 94 (TER94) as components of both VAS and TUD complexes and confirmed their localization to polar granules by immuno-electron microscopy. ME31B, eIF4A and AUB are also present in processing (P) bodies, suggesting that polar granules, which are necessary for germ line formation, might be related to P bodies. Our recovery of ER associated proteins TER94 and ME31B confirms that polar granules are closely linked to the translational machinery and to mRNP assembly.     

Drosophila tudor is essential for polar granule assembly and pole cell specification, but not for posterior patterning

Pole cells and posterior segmentation in Drosophila are specified by maternally encoded genes whose products accumulate at the posterior pole of the oocyte. Among these genes is tudor (tud). Progeny of hypomorphic tud mothers lack pole cells and have variable posterior patterning defects. We have isolated a null allele to further investigate tud function. While no pole cells are ever observed in embryos from tud-null mothers, 15% of these embryos have normal posterior patterning. OSKAR (OSK) and VASA (VAS) proteins, and nanos (nos) RNA, all initially localize to the pole plasm of tud-null oocytes and embryos from tud-null mothers, while localization of germ cell-less (gcl) and polar granule component (pgc), is undetectable or severely reduced. In embryos from tud-null mothers, polar granules are greatly reduced in number, size, and electron density. Thus, tud is dispensable for somatic patterning, but essential for pole cell specification and polar granule formation.     

Targeting and anchoring Tudor in the pole plasm of the Drosophila oocyte

Background

Germline formation is a highly regulated process in all organisms. In Drosophila embryos germ cells are specified by the pole plasm, a specialized cytoplasmic region containing polar granules. Components of these granules are also present in the perinuclear ring surrounding nurse cells, the nuage. Two such molecules are the Vasa and Tudor proteins. How Tudor localizes and is maintained in the pole plasm is, however, not known.

Methodology/Principal Findings

Here, the process of Tudor localization in nuage and pole plasm was analyzed. The initial positioning of Tudor at the posterior pole of stage 9 oocytes was found to occur in the absence of a structurally detectable nuage. However, in mutants for genes encoding components of the nuage, including vasa, aubergine, maelstrom, and krimper, Tudor was detached from the posterior cortex in stage 10 oocytes, suggesting a prior passage in the nuage for its stability in the pole plasm. Further studies indicated that Valois, which was previously shown to bind in vitro to Tudor, mediates the localization of Tudor in the pole plasm by physically interacting with Oskar, the polar granule organizer. An association between Tudor and Vasa mediated by RNA was also detected in ovarian extracts.

Conclusions/Significance

The present data challenge the view that the assembly of the polar granules occurs in a stepwise and hierarchical manner and, consequently, a revised model of polar granule assembly is proposed. In this model Oskar recruits two downstream components of the polar granules, Vasa and Tudor, independently from each other: Vasa directly interacts with Oskar while Valois mediates the recruitment of Tudor by interacting with Oskar and Tudor.     

Interspecific transplantation of polar plasm between Drosophila embryos

Posterior polar plasm of the Drosophila egg has been shown to function autonomously in germ cell determination after transplantation to either the anterior or mid-ventral region of the early embryo. By means of similar transplantations, we have tested the ability of polar plasm of Drosophila immigrans to induce the formation of pole cells in a Drosophila melanogaster embryo. After the transplantation of polar plasm, "hybrid" pole cells were found in which both pole cell-specific organelles, the polar granules and nuclear body, were structurally similar to those characteristic of the transplanted cytoplasm. In order to determine whether these hybrid cells can function as germ cell precursors, these cells were transplanted to the posterior tip of genetically marked embryos. Approximately 5% of the flies obtained from embryos receiving potential pole cells produce offspring derived from the induced pole cells. This result demonstrates that polar plasm can function in interspecific species combinations and indicates that the molecular mechanisms of germ cell determination are conservative in evolution. Finally, in order to test whether there is any evidence for cytoplasmic inheritance of polar granules, embryos derived from hybrid pole cells were examined for their polar granule morphology. The fine structure of the granules conformed to that of the nucleus. Thus, no evidence was found for the cytoplasmic inheritance of these particular organelles.     

Three-dimensional ultrastructural analysis of RNA distribution within germinal granules of Xenopus.

The germ plasm is a specialized region of oocyte cytoplasm that contains determinants of germ cell fate. In Xenopus oocytes, the germ plasm is a part of the METRO region of mitochondrial cloud. It contains the germinal granules and a variety of coding and noncoding RNAs that include Xcat2, Xlsirts, Xdazl, DEADSouth, Xpat, Xwnt11, fatVg, B7/Fingers, C10/XFACS, and mitochondrial large and small rRNA. We analyzed the distribution of these 11 different RNAs within the various compartments of germ plasm during Xenopus oogenesis and development by using whole-mount electron microscopy in situ hybridization. Serial EM sections were used to reconstruct a three-dimensional image of germinal granule distribution within the METRO region of the cloud and the distribution of RNAs on the granules in oocytes and embryos. We found that, in the oocytes, the majority of RNAs were associated either with the precursor of germinal granules or with the germ plasm matrix. Only Xcat2, Xpat, and DEADSouth RNAs were associated with the mature germinal granules in oocytes, while only Xcat2 and Xpat were associated with germinal granules in embryos. However, Xcat2 was the only RNA that was consistently sequestered inside the germinal granules, while the others were located on the periphery. Xdazl, which functions in germ cell migration/formation, was detected on the matrix between granules. Later in development, Xcat2 mRNA was released from the germinal granules. This coincides with the timing of its translational derepression. These results demonstrate that there is a dynamic three-dimensional architecture to the germinal granules that changes during oogenesis and development. They also indicate that association of specific RNAs with the germinal granules is not a prerequisite for their serving a germ cell function; however, it may be related to their state of translational repression.     

The ontogeny of germ plasm during oogenesis in Drosophila

Primordial germ cells can be induced at both the anterior and ventral region of the Drosophila egg by transplanted posterior polar plasm. Two questions arise from these results: (1) Is fertilization required for germ plasm to be functional, and (2) at what stage during oogenesis does the posterior polar plasm become established as a germ-cell determinant?Polar plasm from unfertilized eggs and from oocytes at stage 10 to 14 of Drosophila melanogaster was implanted into the anterior region of cleavage embryos. Some injected embryos were analyzed at the ultrastructural level during blastoderm formation. Polar plasm from unfertilized eggs and from oocytes of stages 13 and 14 was found to be integrated into several anterior cells that resembled morphologically normal pole cells. The formation of such cells, however, could not be detected in embryos injected with polar plasm from oogenetic stages 10 to 12. Experimentally induced pole cells proved to be capable of differentiating into functional germ cells when cycled through the germ line of genetically different host embryos. About 5% of the flies developing from these embryos produced progeny that originated from the induced pole cells. Germ-line mosaicism in those flies also could be detected histochemically in their gonads. No germ cells were recovered with polar plasm transplants from oogenetic stages 10 to 12.The results show that posterior polar plasm of the unfertilized egg is functional in germ-cell determination, and that prior to egg maturation this cytoplasm has already acquired its determinative ability. This is the first demonstration that specific developmental information stored in the cytoplasm can be traced back to a particular region of the oocyte.     

Mitochondrial trafficking through Rhot1 is involved in the aggregation of germinal granule components during primordial germ cell formation in Xenopus embryos

In many animals, the germ plasm is sufficient and necessary for primordial germ cell (PGC) formation. It contains germinal granules and abundant mitochondria (germline‐Mt). However, the role of germline‐Mt in germ cell formation remains poorly understood. In Xenopus, the germ plasm is distributed as many small islands at the vegetal pole, which gradually aggregates to form a single large mass in each of the four vegetal pole cells at the early blastula stage. Polymerized microtubules and the adapter protein kinesin are required for the aggregation of germ plasm. However, it remains unknown whether germline‐Mt trafficking is important for the cytoplasmic transport of germinal granules during germ plasm aggregation. In this study, we focused on the mitochondrial small GTPase protein Rhot1 to inhibit mitochondrial trafficking during the germ plasm aggregation. Expression of Rhot1ΔC, which lacks the C‐terminal mitochondrial transmembrane domain, inhibited the aggregation of germline‐Mt during early development. In Rhot1‐inhibited embryos, germinal granule components did not aggregate during cleavage stages, which reduced the number of PGCs on the genital ridge at tail‐bud stage. These results suggest that mitochondrial trafficking is involved in the aggregation of germinal granule components, which are essential for the formation of PGCs.     

Maternal Messenger RNA as a Determinant of Pole Cell Formation in Drosophila Embryos

Some polar plasm components are UV-sensitive. Messenger RNA extracted from oocytes or cleavage embryos can to induce pole cells in embryos that have been deprived of ability to form pole cells by UV-irradiation. This article reviews studies on the role of this mRNA in the developmental pathway leading to germ cell formation.     

Identification of a component of Drosophila polar granules

Information necessary for the formation of pole cells, precursors of the germ line, is provided maternally and localized to the posterior pole of the Drosophila egg. The maternal origin and posterior localization of polar granules suggest that they may be associated with pole cell determinants. We have generated an antibody (Mab46F11) against polar granules. In oocytes and early embryos, the Mab46F11 antigen is sharply localized to the posterior embryonic pole. In pole cells, it becomes associated with nuclear bodies within, and nuage around, the nucleus. Immunoreactivity remains associated with cells of the germ line throughout the life cycle of both males and females. This antibody recognizes a 72-74 X 10(3) Mr protein and is useful both as a pole lineage marker and in biochemical studies of polar granules.     

Expression of axolotl DAZL RNA, a marker of germ plasm: widespread maternal RNA and onset of expression in germ cells approaching the gonad

How germ cell specification occurs remains a fundamental question in embryogenesis. The embryos of several model organisms contain germ cell determinants (germ plasm) that segregate to germ cell precursors. In other animals, including mice, germ cells form in response to regulative mechanisms during development. To investigate germ cell determination in urodeles, where germ plasm has never been conclusively identified, we cloned a DAZ-like sequence from axolotls, Axdazl. Axdazl is homologous to Xdazl, a component of Xenopus germ plasm found in the vegetal pole of oocytes and eggs. Axdazl RNA is not localized in axolotl oocytes, and, furthermore, these oocytes do not contain the mitochondrial cloud that localizes Xdazl and other germ plasm components in Xenopus. Maternal Axdazl RNA is inherited in the animal cap and equatorial region of early embryos. At gastrula, neurula, and tailbud stages, Axdazl RNA is widely distributed. Axdazl first shows cell-specific expression in primordial germ cells (PGCs) approaching the gonad at stage 40, when nuage (germ plasm) appears in PGCs. These results suggest that, in axolotls, germ plasm components are insufficient to specify germ cells.     

A novel function for the Sm proteins in germ granule localization during C. elegans embryogenesis

General mRNA processing factors are traditionally thought to function only in the control of global gene expression. Here we show that the Sm proteins, core components of the splicesome, also regulate germ granules during early C. elegans development. Germ granules are large cytoplasmic particles that localize to germ cells and their precursors during embryogenesis of diverse organisms. In C. elegans, germ granules, called P granules, are segregated to the germline precursor cells during embryogenesis by asymmetric cell division, and they remain in germ cells at all stages of development. We found that at least some Sm proteins are components of P granules. Moreover, disruption of Sm activity caused defects in P granule localization to the germ cell precursors during early embryogenesis. In contrast, loss of other splicing factor activities had no effect on germ granule control in the embryo. These observations suggest that the Sm proteins control germ granule integrity and localization in the early C. elegans embryo and that this role is independent of pre-mRNA splicing. Thus, a highly conserved splicing factor may have been adapted to control both snRNP biogenesis and the localization of components important for germ cell function.     

Localization of vasa, a component of Drosophila polar granules, in maternal-effect mutants that alter embryonic anteroposterior polarity

Cytoplasm at the posterior pole of the early Drosophila embryo, known as polar plasm, serves as a source of information necessary for germ cell determination and for specification of the abdominal region. Likely candidates for cytoplasmic elements important in one or both of these processes are polar granules, organelles concentrated in the cortical cytoplasm of the posterior pole. Females homozygous for any one of the maternal-effect mutations, tudor, oskar, staufen, vasa, or valois give rise to embryos that lack localized polar granules, fail to form the germ cell lineage and have abdominal segment deletions. Using antibodies against a polar granule component, the vasa protein, we find that vasa synthesis or localization is affected by these mutations. In vasa mutants, synthesis of vasa protein is absent or severely restricted. In oskar and staufen mutant females, vasa synthesis appears normal, but the vasa protein is not localized. In tudor and valois mutant females, vasa is localized to the posterior pole of oocytes, but this localization is lost following egg activation. In addition to the posterior localized vasa, there is a low level of vasa distributed throughout the embryo. A function for this distributed vasa is postulated based on the observation that embryos from Bicaudal-D mothers, in which abdominal determinants are incorrectly localized to the anterior pole, do not show any ectopic vasa localization, though abdomen development at the anterior end depends on the amount of vasa protein in the embryo.     

Fat facets interacts with vasa in the Drosophila pole plasm and protects it from degradation

Anterior-posterior patterning and germ cell specification in Drosophila requires the establishment, during oogenesis, of a specialized cytoplasmic region termed the pole plasm. Numerous RNAs and proteins accumulate to the pole plasm and assemble in polar granules. Translation of some of these RNAs is generally repressed and active only in pole plasm. Vasa (VAS) protein, an RNA helicase and a component of polar granules, is essential maternally for posterior patterning and germ cell specification, and VAS is a candidate translational activator in the pole plasm. VAS is stabilized within the pole plasm in that it is initially present throughout the entire embryo but strictly limited to the pole cells by the cellular blastoderm stage. hsp83 mRNA, which accumulates in the pole plasm through a stabilization-degradation mechanism, is another example. Here, we used a biochemical approach to identify proteins that copurify with VAS in crosslinked extracts. Prominent among these proteins was the ubiquitin-specific protease Fat facets (FAF), a pole plasm component [7], but one whose roles in posterior patterning and germ line specification have remained unclear. We present evidence that FAF interacts with VAS physically and reverses VAS ubiquitination, thereby stabilizing VAS in the pole plasm.     

tudor, a gene required for assembly of the germ plasm in Drosophila melanogaster

Developmental analysis of a newly isolated maternal effect grandchildless mutant, tudor (tud), in Drosophila melanogaster indicates that tud+ activity is required during oogenesis for the determination and/or formation of primordial germ cells (pole cells) and for normal embryonic abdominal segmentation. Regardless of their genotype, progeny of females homozygous for strong alleles (tud1 and tud3) never form pole cells, apparently lack polar granules in the germ plasm, and approximately 40% of them die during late embryogenesis exhibiting severe abdominal segmentation pattern defects. Females carrying weak allele, tud4, produce progeny with some functional pole cells and form polar granules approximately one-third the size of those observed in wild-type oocytes and embryos. No segmentation abnormalities are observed in the inviable embryos derived from tud4/tud4 females.     

Ultrastructural studies of oocytes and embryos derived from females flies carrying the grandchildless mutation in Drosophila subobscura

The maternal effect mutant grandchildless in Drosophila subobscura has been analyzed with the electron microscope. The original mutation was linked to a visible genetic marker and established in a balanced stock. Oocytes and early embryos were examined by both transmission and scanning electron microscopy. The earliest defect is seen in mutant eggs and occurs at the end of oogenesis. In the cortex, at both the anterior and the posterior tips, regions appear which are free of ribosomes, mitochondria, and other cytoplasmic organelles. Most of the polar granules are included in these regions at the posterior tip. Following oviposition, this cytoplasmic segregation is no longer observed and most polar granules have disappeared. The few remaining granules are presumed to derive from the peripheral polar plasm which does not become segregated. During embryogenesis there is a retarded movement of nuclei to the anterior and posterior cortices. At the posterior tip nuclei are delayed in reaching the lateral sides and never move directly into the posterior polar plasm. Pole cells never form. After the last syncytial division the lateral nuclei move under the posterior polar plasm to complete the blastoderm. The posterior polar plasm itself protrudes during blastoderm formation as long cytoplasmic extensions which separate from the blastoderm as cytoplasmic blebs. Neither polar granules nor mitochondria are found in these blebs. The grandchildless phenotype is due to the failure of nuclei to migrate directly into the posterior polar plasm. The defect in the polar plasm presumably is related to the process in mature eggs whereby portions of the cortex become segregated at both anterior and posterior tips. This process may change the properties of the posterior polar plasm so that nuclei do not penetrate into it.     

The role of mitochondrial rRNAs and nanos protein in germline formation in Drosophila embryos

Germ cells, represented by male sperm and female eggs, are specialized cells that transmit genetic material from one generation to the next during sexual reproduction. The mechanism by which multicellular organisms achieve the proper separation of germ cells and somatic cells is one of the longest standing issues in developmental biology. In many animal groups, a specialized portion of the egg cytoplasm, or germ plasm, is inherited by the cell lineage that gives rise to the germ cells (germline). Germ plasm contains maternal factors that are sufficient for germline formation. In the fruit fly, Drosophila, germ plasm is referred to as polar plasm and is distinguished histologically by the presence of polar granules, which act as a repository for the maternal factors required for germline formation. Molecular screens have so far identified several of these factors that are enriched in the polar plasm. This article focuses on the molecular functions of two such factors in Drosophila, mitochondrial ribosomal RNAs and Nanos protein, which are required for the formation and differentiation of the germline progenitors, respectively.     

Delocalization of polar plasm components caused by grandchildless mutations, gs(1)N26 and gs(1)N441, in Drosophila melanogaster

Two maternal-effect grandchildless (gs) mutations of Drosophila melanogaster, gs(1)N26 and gs(1)N441, cause delay in nuclear arrival at the polar plasm. In mutant embryos, polar plasm loses its ability to induce pole cells during retarded nuclear migration to the posterior pole of embryos. In the present study, it was shown that in N26 and N441 embryos, mitochondrial large rRNA (mtlrRNA), an essential factor for pole cell formation, is delocalized during the delay in nuclear arrival. This suggests that the loss of mtlrRNA causes failure of the mutants to form pole cells. Furthermore, it was shown that all of the other polar plasm components examined, namely Vasa protein, Germ cell-less protein, nanos mRNA and Polar granule component RNA start to be delocalized during the delay in nuclear arrival. This suggests that polar plasm integrity is not maintained in mutant embryos. It was finally shown that Vas is also delocalized in embryos that are inhibited to form pole cells by reducing the amount of mtlrRNA. This indicates that the segregation of polar plasm into pole cells is required to maintain polar plasm integrity. The mechanism regulating polar plasm integrity in embryos is discussed.