The Drosophila gene torso encodes a putative receptor tyrosine kinase

The maternal gene torso, required for determination of anterior and posterior terminal structures in the Drosophila embryo, was cloned using P-element tagging. Genetic evidence suggests that the action of the gene product is spatially restricted to the terminal regions; the torso messenger RNA, however, is evenly distributed. Structural similarities of the predicted torso protein with growth-factor receptor tyrosine kinases suggest that the spatial restriction of torso activity results from a localized activation of the torso protein at the anterior and posterior egg pole.     

A Drosophila Minute gene encodes a ribosomal protein

Minute genes have long constituted a special problem in Drosophila genetics. For at least 50-60 different genes scattered throughout the genome, dominant mutations and/or deficiencies have been recognized which result in a common phenotype consisting of short thin bristles, slow development, reduced viability, rough eyes, small body size and etched tergites. Schultz proposed that the Minute loci encode similar but separate functions involved in growth and division common to all cells. Atwood and Ritossa suggested that Minute loci encode components of the protein synthetic machinery, specifically the transfer RNA genes; this now seems unlikely on grounds of both mapping and mutability studies. More recently, we and others suggested that the Minute loci are ribosomal protein genes. We report here that transformation with a cloned 3.3-kilobase (kb) region containing the gene encoding the large subunit ribosomal protein 49 (rp49) suppresses the dominant phenotypes of Minute (3)99D, a previously undescribed Minute associated with a chromosomal deficiency of the 99D interval. This activity is specific to the 99D Minute as it does not suppress other Minute loci elsewhere in the genome. This result provides direct evidence that the Minute locus at the 99D interval encodes the ribosomal protein 49.     

Similarity of the product of the Drosophila neurogenic gene big brain to transmembrane channel proteins.

Cells in the neurogenic region of Drosophila embryos are initially bipotential; they can become either neuroblasts or epidermoblasts. Cell-cell interaction seems to play an important part in this developmental decision, which involves the function of a group of genes (the neurogenic genes). Loss-of-function mutations in any of the neurogenic genes result in nervous system hyperplasia and epidermal hypoplasia. Of the six known zygotic neurogenic genes, big brain (bib) is unique in several aspects. Most notably, all the other known neurogenic genes seem to fit into a cascade defined by genetic interactions, whereas bib does not show any detectable interaction with them. To understand how bib functions, we have now cloned the bib genomic and complementary DNAs. The predicted bib product shows significant sequence similarity to a family of transmembrane proteins, some of which form channels permeable to small molecules. Together with genetic studies, our results indicate that the bib product may mediate intercellular communication in a pathway separate from the one involving the products of the other neurogenic genes.     

Feedback of the Drosophila period gene product on circadian cycling of its messenger RNA levels

Mutations in the period (per) gene of Drosophila melanogaster affect both circadian and ultradian rhythms. Levels of per gene product undergo circadian oscillation, and it is now shown that there is an underlying oscillation in the level of per RNA. The observations indicate that the cycling of per-encoded protein could result from per RNA cycling, and that there is a feedback loop through which the activity of per-encoded protein causes cycling of its own RNA.     

A product of the prune locus of Drosophila is similar to mammalian GTPase-activating protein.

The X-linked prune (pn) eye-colour mutation of Drosophila melanogaster has a highly specific, complementary lethal interaction with the conditional dominant Killer of prune (awdK-pn) mutation. Although awdK-pn flies have no apparent phenotype on their own, pn awdK-pn double mutants die as second or third larval instars. The awd locus encodes a nucleoside diphosphate kinase, an enzyme that catalyses the transfer of high-energy phosphate bonds between nucleoside diphosphates and nucleoside triphosphates, which is essential for the normal development of Drosophila. Analysis of the pn locus has suggested that the complementary DNA, TcD37, encodes a putative pn+ product. Here we report the nucleotide sequence of TcD37 and the similarity of its deduced protein product to the catalytic domain of mammalian GTPase-activating proteins (GAPs); GAPs stimulate the GTPase activity of Ras (ref. 6), which are plasma membrane-bound proteins involved in the regulation of cell proliferation and differentiation. These results suggest that the Drosophila TcD37 protein participates in a biochemical pathway similar to that of Ras and GAPs in mammals and yeast. We propose that the interaction between pn and awd is due to a neomorphic mutation that enhances the ability of AwdK-pn nucleoside diphosphate kinase to induce a regulatory GTPase into a GTP-bound 'on' state, whereas Pn modulates the activity of this GTPase either by switching it to a GDP-bound 'off' state or by interfering with its effector function.     

Polyoma virus transforming protein associates with the product of the c-src cellular gene

Polyoma virus can transform the growth properties of rodent cells grown in culture and form tumours in susceptible animals, an activity largely due to one of the virus-encoded proteins, called middle T. Middle T has an associated tyrosine-specific protein kinase activity in vitro and interacts with cellular membranes, but the biochemical basis of its ability to transform remains unclear. Although there is some correlation between the transforming activity of different polyoma virus mutants and their ability to accept phosphate on tyrosine in middle T in the in vitro kinase reaction, the abundance of phosphotyrosine in protein is not elevated in polyoma virus-transformed cells and no cellular substrates for the putative kinase have been identified. It is also not yet known whether the tyrosine kinase of middle T is an intrinsic activity of the protein itself or the property of an associated enzyme. The experiments described here indicate that a fraction of middle T forms a stable complex with pp60c-src, the product of a cellular oncogene, and lead us to propose that the middle T associated kinase at least in part is a property of pp60c-src rather than middle T itself.     

Three loci related to the src oncogene and tyrosine-specific protein kinase activity in Drosophila

Rous sarcoma virus (RSV) is an acutely oncogenic avian retrovirus which induces sarcomas in animals and transforms fibroblasts in cell culture. Genetic analysis indicates that the viral src gene (v-src) mediates neoplastic transformation. The product of v-src is a 60,000 molecular weight (MW) phosphoprotein (pp60v-src) possessing the enzymatic activity of a tyrosine-specific protein kinase. The viral src gene is derived from a cellular gene (c-src) which also encodes a 60,000 MW phosphoprotein (pp60c-src) with tyrosine-specific protein kinase activity. Both birds and mammals are known to possess c-src. Shilo and Weinberg have reported that the genome of the fruit fly, Drosophila melanogaster, contains nucleotide sequences that are homologous to v-src. We report here the molecular cloning and chromosomal mapping of three loci from the Drosophila genome that contain such sequences. We also show that Drosophila contain both phosphotyrosine and a tyrosine-specific protein kinase activity immunoprecipitated by antisera directed against pp60v-src. It should now be possible to identify the precise locus that encodes a src-specific protein kinase in Drosophila, and to explore the role of c-src in the growth and development of D. melanogaster.     

Dynamin-like protein encoded by the Drosophila shibire gene associated with vesicular traffic.

Temperature-sensitive paralysis is the most striking defect of adult Drosophila carrying the shibire mutation. This is believed to be due to a reversible block of endocytosis, which prevents membrane cycling and thus depletes synaptic vesicles. The shibire mutation also affects many tissues outside the nervous system. We have now mapped and characterized the shibire gene. A 275-kilobase yeast artificial chromosome was subcloned into cosmids, among which the gene was then located by analysing with restriction-fragment length polymorphisms. A 15-kilobase fragment of wild-type DNA rescues the mutant phenotype and the sequence of two mutant alleles show differences with wild type, demonstrating that we have isolated the shibire gene. The gene encodes a protein that is highly similar to rat dynamin, 69% of the amino-acid sequence is identical. Dynamin is a GTP-driven mechanochemical enzyme related to mammalian mx-proteins and to the yeast vps 1 gene product. Because the shibire gene product and dynamin have extensive similarity, we propose that they are cognate homologues. Dynamin causes microtubules to slide along each other in vitro and in extracts it is associated with a distinct, but so far uncharacterized, membrane fraction. In light of the shibire phenotype, we suggest that these proteins provide the motor for vesicular transport during endocytosis.     

A protein kinase encoded by the t complex responder gene causes non-mendelian inheritance

Males heterozygous for the t-haplotype form of mouse chromosome 17 preferentially transmit the t-chromosome to their progeny. Several distorter/sterility loci carried on the t-haplotype together impair flagellar function in all spermatozoa whereas the responder, Tcr, rescues t-sperm but not wild-type sperm. Thus, t-sperm have an advantage over wild-type sperm in fertilizing egg cells. We have isolated Tcr by positional cloning and show that it is a member of a novel protein kinase gene family, designated Smok, which is expressed late during spermiogenesis. Smok kinases are components of a signal cascade which may control sperm motility. Tcr has a reduced kinase activity, which may allow it to counterbalance a signalling impairment caused by the distorter/sterility loci. Tcr transgene constructs cause non-mendelian transmission of chromosomes on which they are carried, which leads to sex-ratio distortion when Tcr cosegregates with the Y chromosome.     

Sequence of a Drosophila segmentation gene: protein structure homology with DNA-binding proteins

Mutations in the fushi tarazu (ftz) locus of Drosophila result in embryos with half the usual number of body segments. The sequences of the wild-type gene, a temperature-sensitive allele and a dominant mutant allele are presented. A portion of the conserved protein domain present in ftz and several homoeotic genes resembles the DNA-binding region of prokaryotic DNA-binding proteins, and is also similar to products of the yeast mating-type locus.     

The cytoplasmic protein GAP is implicated as the target for regulation by the ras gene product

About 30% of human tumours contain a mutation in one of the three ras genes leading to the production of p21ras oncoproteins that are thought to make a major contribution to the transformed phenotype of the tumour. The biochemical mode of action of the ras proteins is unknown but as they bind GTP and GDP and have an intrinsic GTPase activity, they may function like regulatory G proteins and control cell proliferation by regulating signal transduction pathways at the plasma membrane. It is assumed that an external signal is detected by a membrane molecule (or detector) that stimulates the conversion of p21.GDP to p21.GTP which then interacts with a target molecule (or effector) to generate an internal signal. Recently a cytoplasmic protein, GAP, has been identified that interacts with the ras proteins, dramatically increasing the GTPase activity of normal p21 but not of the oncoproteins. We report here that GAP appears to interact with p21ras at a site previously identified as the 'effector' site, strongly implicating GAP as the biological target for regulation by p21.     

A yeast gene encoding a protein homologous to the human c-has/bas proto-oncogene product

Organisms amenable to easy genetic analysis should prove helpful in assessing the function of at least those proto-oncogene products which are highly conserved in different eukaryotic cells. One obvious possibility is to pursue the matter in Drosophila melanogaster DNA, which has sequences homologous to several vertebrate oncogenes. Another is to turn to the yeast Saccharomyces cerevisiae, if it contains proto-oncogene sequences. Here we report the identification of a gene in S. cerevisiae which codes for a 206 amino acid protein (YP2) that exhibits striking homology to the p21 products of the human c-has/bas proto-oncogenes and the transforming p21 proteins of the Harvey (v-rasH) and Kirsten (v-rasK) murine sarcoma viral oncogenes. The YP2 gene is located between the actin and the tubulin gene on chromosome VI and is expressed in growing cells. The protein it encodes might share the nucleotide-binding capacity of p21 proteins.     

A protein with several possible membrane-spanning domains encoded by the Drosophila segment polarity gene patched

The patterning of cells in insect segments requires the exchange of information between cells, which in Drosophila depends on the activity of members of the segment-polarity class of genes. Here we report the molecular characterization of one such gene, patched. We find that patched encodes a large protein with several possible membrane-spanning domains and is expressed in a complex pattern during embryogenesis.