The RNA-binding protein Tsunagi interacts with Mago Nashi to establish polarity and localize oskar mRNA during Drosophila oogenesis.

In Drosophila melanogaster, formation of the axes and the primordial germ cells is regulated by interactions between the germ line-derived oocyte and the surrounding somatic follicle cells. This reciprocal signaling results in the asymmetric localization of mRNAs and proteins critical for these oogenic processes. Mago Nashi protein interprets the posterior follicle cell-to-oocyte signal to establish the major axes and to determine the fate of the primordial germ cells. Using the yeast two-hybrid system we have identified an RNA-binding protein, Tsunagi, that interacts with Mago Nashi protein. The proteins coimmunoprecipitate and colocalize, indicating that they form a complex in vivo. Immunolocalization reveals that Tsunagi protein is localized within the posterior oocyte cytoplasm during stages 1-5 and 8-9, and that this localization is dependent on wild-type mago nashi function. When tsunagi function is removed from the germ line, egg chambers develop in which the oocyte nucleus fails to migrate, oskar mRNA is not localized within the posterior pole, and dorsal-ventral pattern abnormalities are observed. These results show that a Mago Nashi-Tsunagi protein complex is required for interpreting the posterior follicle cell-to-oocyte signal to define the major body axes and to localize components necessary for determination of the primordial germ cells.

The transmembrane molecule kekkon 1 acts in a feedback loop to negatively regulate the activity of the Drosophila EGF receptor during oogenesis.

We have identified the Drosophila transmembrane molecule kekkon 1 (kek1) as an inhibitor of the epidermal growth factor receptor (EGFR) and demonstrate that it acts in a negative feedback loop to modulate the activity of the EGFR tyrosine kinase. During oogenesis, kek1 is expressed in response to the Gurken/EGFR signaling pathway, and loss of kek1 activity is associated with an increase in EGFR signaling. Consistent with our loss-of-function studies, we demonstrate that ectopic overexpression of kek1 mimics a loss of EGFR activity. We show that the extracellular and transmembrane domains of Kek1 can inhibit and physically associate with the EGFR, suggesting potential models for this inhibitory mechanism.

Zimp encodes a homologue of mouse Miz1 and PIAS3 and is an essential gene in Drosophila melanogaster.

The related mouse proteins Miz1 and PIAS3, which have predicted zinc finger domains, interact with the transcription factors Msx2 and STAT3, modulating the ability of Msx2 and STAT3 to regulate transcription. Here, we describe a Drosophila gene, zimp, that encodes a protein with similarity to Miz1 and PIAS3. The zimp gene appears to be post-transcriptionally regulated, as three alternatively spliced forms are detected in a cDNA library screen and on an RNA blot. In addition, all three zimp transcripts are detected in embryonic mRNA, but only two of the transcripts are detected in adult mRNA. The three transcripts have the ability to encode two proteins, of 554 and 522 amino acids. The two Zimp amino acid sequences share an amino-terminal 515-amino-acid region and differ in their carboxy-termini. These proteins and related proteins in other organisms, including mammals, C. elegans, yeast, and plants, share a highly conserved region predicted to form a zinc finger. Deletion of the zimp gene or P-element insertion in zimp is lethal; thus, zimp is an essential gene in Drosophila. These data underscore the potential importance of Zimp-related proteins cross-species, and conservation of the putative zinc finger domain suggests that it is functionally important.

mago nashi mediates the posterior follicle cell-to-oocyte signal to organize axis formation in Drosophila.

Establishment of the anteroposterior and dorsoventral axes in the Drosophila egg chamber requires reciprocal signaling between the germ line and soma. Upon activation of the Drosophila EGF receptor in the posterior follicle cells, these cells signal back to the oocyte, resulting in a reorganization of the oocyte cytoplasm and anterodorsal migration of the oocyte nucleus. We demonstrate that the gene mago nashi (mago) encodes an evolutionarily conserved protein that must be localized within the posterior pole plasm for germ-plasm assembly and Caenorhabditis elegans mago is a functional homologue of Drosophila mago. In the absence of mago+ function during oogenesis, the anteroposterior and dorsoventral coordinates of the oocyte are not specified and the germ plasm fails to assemble.

The mago nashi locus encodes an essential product required for germ plasm assembly in Drosophila.

In Drosophila, the localization of maternal determinants to the posterior pole of the oocyte is required for abdominal segmentation and germ cell formation. These processes are disrupted by maternal effect mutations in ten genes that constitute the posterior group. Here, the molecular analysis of one posterior group gene, mago nashi, is presented. Restriction fragment length polymorphisms and transcript alterations associated with mago nashi mutations were used to identify the mago nashi locus within a chromosomal walk. The mago nashi locus was sequenced and found to encode a 147 amino acid protein with no similarity to proteins of known or suspected function. The identification of the mago nashi locus was confirmed by sequencing mutant alleles and by P element-mediated transformation. Nonsense mutations in mago nashi, as well as a deletion of the 5' coding sequences, result in zygotic lethality. The original mago nashi allele disrupts the localization of oskar mRNA and staufen protein to the posterior pole of the oocyte during oogenesis; anterior localization of bicoid mRNA is unaffected by the mutation. These results demonstrate that mago nashi encodes an essential product necessary for the localization of germ plasm components to the posterior pole of the oocyte.

Distribution of tudor protein in the Drosophila embryo suggests separation of functions based on site of localization.

Mutations in the tudor locus of Drosophila affect two distinct determinative processes in embryogenesis; segmentation of the abdomen and determination of the primordial germ cells. The distribution of tudor protein during embryogenesis, and the effect of various mutations on its distribution, suggest that tudor protein may carry out these functions separately, based on its location in the embryo. The protein is concentrated in the posterior pole cytoplasm (germ plasm), where it is found in polar granules and mitochondria. Throughout the rest of the embryo, tudor protein is associated with the cleavage nuclei. Mutations in all maternal genes known to be required for the normal functioning of the germ plasm eliminate the posterior localization of tudor protein, whereas mutations in genes required for the functioning of the abdominal determinant disrupt the localization around nuclei. Analysis of embryos of different maternal genotypes indicates that the average number of pole cells formed is correlated with the amount of tudor protein that accumulates in the germ plasm. Our results suggest that tudor protein localized in the germ plasm is instrumental in germ cell determination, whereas nuclear-associated tudor protein is involved in determination of segmental pattern in the abdomen.

tudor, a posterior-group gene of Drosophila melanogaster, encodes a novel protein and an mRNA localized during mid-oogenesis.

The tudor (tud) locus of Drosophila melanogaster is required during oogenesis for the formation of primordial germ cells and for normal abdominal segmentation. The tud locus was cloned, and its product was identified by Northern analysis of wild-type and tud mutant RNAs. The locus encodes a single mRNA of approximately 8.0 kb that is expressed throughout the life cycle, beginning in the early stages of germ-line development in the female. During oogenesis, tud mRNA appears to be present in the oocyte precursor within the germarial cysts, and in stages 1-3 it accumulates within the developing oocyte. The transcript is localized to the posterior half of the oocyte during oogenetic stages 4-7 but is not detectable within the ooplasm by egg deposition and throughout early embryogenesis. The tud protein has a predicted molecular mass of 285,000 daltons and has no distinctive sequence similarity to known proteins or protein structural motifs. Taken together, these results indicate that the tud product is a novel protein required during oogenesis for establishment of a functional center of morphogenetic activity in the posterior tip of the Drosophila embryo.

Mutations in a newly identified Drosophila melanogaster gene, mago nashi, disrupt germ cell formation and result in the formation of mirror-image symmetrical double abdomen embryos.

The mago nashi (mago) locus is a newly identified strict maternal effect, grandchildless-like, gene in Drosophila melanogaster. In homozygous mutant mago females reared at 17 degrees C, mago+ function is reduced, the inviable embryos lack abdominal segments and 84-98% of the embryos die. In contrast, at 25 degrees C, some mago alleles produce a novel gene product capable of inducing the formation of symmetrical double abdomen embryos. Reciprocal temperature-shift experiments indicate that the temperature-sensitive period is during oogenetic stages 7-14. Furthermore, embryos collected from mago1 homozygous females contain no apparent functional posterior determinants in the posterior pole. In viable F1 progeny from mago mutant females, regardless of genotype and temperature, polar granules are reduced or absent and germ cells fail to form (the grandchildless-like phenotype). Thus, we propose that the mago+ product is a component of the posterior determinative system, required during oogenesis, both for germ cell determination and delineation of the longitudinal axis of the embryo.

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.

Organization of gene and non-gene sequences in micronuclear DNA of Oxytricha nova.

In order to study the derivation of the macronuclear genome from the micronuclear genome in Oxytricha nova micronuclear DNA was partially digested with EcoRI, size fractionated, and then cloned in the lambda phage Charon 8. Clones were selected a) at random b) by hybridization with macronuclear DNA or c) by hybridization with clones of macronuclear DNA. One group of these clones contains only unique sequence DNA, and all of these had sequences that were homologous to macronuclear sequences. The number of macronuclear genes with sequences homologous to these micronuclear clones indicates that macronuclear sequences are clustered in the micronuclear genome. Many micronuclear clones contain repetitive DNA sequences and hybridize to numerous EcoRI fragments of total micronuclear DNA, yielding similar but non-identical patterns. Some micronuclear clones containing these repetitive sequences also contained unique sequence DNA that hybridized to a macronuclear sequence. These clones define a major interspersed repetitive sequence family in the micronuclear genome that is eliminated during formation of the macronuclear genome.

Inverted terminal repeats are added to genes during macronuclear development in Oxytricha nova.

In the hypotrichous ciliate Oxytricha nova all of the macronuclear DNA is in the form of low molecular weight, gene-sized molecules with an average size of 2,200 base pairs. These molecules are produced during macronuclear development by excision from micronuclear chromosomes. All, or nearly all, of the small macronuclear DNA molecules possess an inverted terminal repeat sequence consisting of 5' C4A4 3' repeats. The hypothesis that this terminal sequence serves as a recognition signal for excision of gene-sized molecules from chromosomes has been tested. A sequence containing the C4A4 repeat has been isolated and used to screen clones of micronuclear DNA for the presence of the repeat sequence. The results show that the intact repeated C4A4 sequence is not present at the ends of macronuclear sequences as they exist in the micronuclear chromosomes. Therefore, the entire terminal repeat is not a recognition sequence for gene excision but must be added to the ends of gene-sized molecules during or after the excision process.

Cell types originating from kidney explants of young and old mice.

Explants from young and old mouse kidneys give rise to two different cell types when placed in organ culture dishes. The two cell types differ in morphology and ability to grow in vitro. Explants from young mice give rise to one predominant cell type; those from old mice give rise to another. Our data supports the mosaic theory of aging.