The Drosophila mus101 gene, which links DNA repair, replication and condensation of heterochromatin in mitosis, encodes a protein with seven BRCA1 C-terminus domains.

The mutagen-sensitive-101 (mus101) gene of Drosophila melanogaster was first identified 25 years ago through mutations conferring larval hypersensitivity to DNA-damaging agents. Other alleles of mus101 causing different phenotypes were later isolated: a female sterile allele results in a defect in a tissue-specific form of DNA synthesis (chorion gene amplification) and lethal alleles cause mitotic chromosome instability that can be observed genetically and cytologically. The latter phenotype presents as a striking failure of mitotic chromosomes of larval neuroblasts to undergo condensation of pericentric heterochromatic regions, as we show for a newly described mutant carrying lethal allele mus101(lcd). To gain further insight into the function of the Mus101 protein we have molecularly cloned the gene using a positional cloning strategy. We report here that mus101 encodes a member of the BRCT (BRCA1 C terminus) domain superfamily of proteins implicated in DNA repair and cell cycle checkpoint control. Mus101, which contains seven BRCT domains distributed throughout its length, is most similar to human TopBP1, a protein identified through its in vitro association with DNA topoisomerase IIbeta. Mus101 also shares sequence similarity with the fission yeast Rad4/Cut5 protein required for repair, replication, and checkpoint control, suggesting that the two proteins may be functional homologs.

Drosophila PLUTONIUM protein is a specialized cell cycle regulator required at the onset of embryogenesis.

Unfertilized eggs and fertilized embryos from Drosophila mothers mutant for the plutonium (plu) gene contain giant polyploid nuclei resulting from unregulated S-phase. The PLU protein, a 19-kDa ankyrin repeat protein, is present in oocytes and early embryos but is not detectable after the completion of the initial rapid S-M cycles of the embryo. The persistence of the protein during the early embryonic divisions is consistent with a direct role in linking S-phase and M-phase. When ectopically expressed in the eye disc, PLU did not perturb the cell cycle, suggesting that PLU regulates S-phase only in early embryonic development. The pan gu (png) and giant nuclei (gnu) genes also affect the S-phase in the unfertilized egg and early embryo. We show that functional png is needed for the presence of PLU protein. By analyzing png mutations of differing severity, we find that the extent of the png mutant phenotype inversely reflects the level of PLU protein. Our data suggest that PLU protein is required at the time of egg activation and the completion of meiosis.

The inhibitor of DNA replication encoded by the Drosophila gene plutonium is a small, ankyrin repeat protein.

The plutonium (plu) gene product controls DNA replication early in Drosophila development. plu mutant females lay unfertilized eggs that have undergone extensive DNA synthesis. In fertilized embryos from plu mutant mothers, S-phase is uncoupled from mitosis. The gene is expressed only in ovaries and embryos, null alleles are strict maternal effect mutations, and the phenotype of inappropriate DNA replication is the consequence of loss-of-gene function. plu therefore negatively regulates S-phase at a time in early development when commitment to S-phase does not depend on cyclic transcription. plu encodes a protein with two ankyrin-like repeats, a domain for protein-protein interaction. plu is immediately adjacent to, but distinct from, the PCNA gene.

Mutations in the Drosophila melanogaster gene three rows permit aspects of mitosis to continue in the absence of chromatid segregation.

We have cloned the three rows (thr) gene, by a combination of chromosome microdissection and P element tagging. We describe phenotypes of embryos homozygous for mutations at the thr locus. Maternal mRNA and protein appear to be sufficient to allow 14 rounds of mitosis in embryos homozygous for thr mutations. However, a small percentage of cells in syncytial blastoderm stage thr embryos sink into the interior of the embryo as if they have failed to divide properly. Following cellularisation all cells complete mitosis 14 normally. All cells become delayed at mitosis 15 with their chromosomes remaining aligned on the spindle in a metaphase-like configuration, even though both cyclins A and B have both been degraded. As cyclin B degradation occurs at the metaphase-anaphase transition, subsequent to the microtubule integrity checkpoint, the delay induced by mutations at the thr locus defines a later point in mitotic progression. Chromosomes in the cells of thr embryos do not undertake anaphase separation, but remain at the metaphase plate. Subsequently they decondense. A subset of nuclei go on to replicate their DNA but there is no further mitotic division.

Drosophila contains three genes that encode distinct isoforms of protein phosphatase 1.

The sequences of two Drosophila and one rabbit protein phosphatase (PP) 1 catalytic subunits were determined from their cDNA. The sequence of Drosophila PP1 alpha 1 was deduced from a 2.2-kb cDNA purified from an embryonic cDNA library, while that for Drosophila PP1 beta was obtained from overlapping clones isolated from both a head cDNA library and an eye imaginal disc cDNA library. The gene for Drosophila PP1 alpha 1 is at 96A2-5 on chromosome 3 and encodes a protein of 327 amino acids with a calculated molecular mass of 37.3 kDa. The gene for Drosophila PP1 beta is localized at 9C1-2 on the X chromosome and encodes a protein of 330 amino acids with a predicted molecular mass of 37.8 kDa. PP1 alpha 1 shows 96% amino acid sequence identity to PP1 alpha 2 (302 amino acids), an isoform whose gene is located in the 87B6-12 region of chromosome 3 [Dombrádi, V., Axton, J. M., Glover, D.M. Cohen, P.T.W. (1989) Eur. J. Biochem. 183, 603-610]. PP1 beta shows 85% identity to PP1 alpha 1 and PP1 alpha 2 over the 302 homologous amino acids. These results demonstrate that at least three genes are present in Drosophila that encode different isoforms of PP1. Drosophila PP1 alpha 1 and PP1 beta show 89% amino acid sequence identity to rabbit PP1 alpha (330 amino acids) [Cohen, P.T.W. (1988) FEBS Lett. 232, 17-23] and PP1 beta (327 amino acids), respectively, demonstrating that the structures of both isoforms are among the most conserved proteins known throughout the evolution of the animal kingdom. The presence of characteristic structural differences between PP1 alpha and PP1 beta, which have been preserved from insects to mammals, implies that the alpha and beta isoforms may have distinct biological functions.

Protein phosphatase 1 activity in Drosophila mutants with abnormalities in mitosis and chromosome condensation.

A Drosophila gene encoding a protein phosphatase 1 (PP1) has been sequenced, and lethal mutations in this locus (87B) analysed. Two mutants (ck19e211 and ck19hs46), which disrupt mitosis, lack the 87B isoenzyme and express only approximately 20% of wild type PP1 activity. The promoter region of the gene is deleted in the ck19e211 mutant. A third mutant (ck19e078), which shows suppression of position effect variegation, but has little effect on mitosis, possesses approximately 35% of wild type PP1 activity. The results indicate that the PP1 87B isoenzyme is involved in regulation of chromosome condensation at interphase as well as mitosis.

The structure of protein phosphatase 2A is as highly conserved as that of protein phosphatase 1.

cDNA coding for protein phosphatase 2A (PP2A) has been isolated from Drosophila head and eye imaginal disc libraries. Drosophila PP2A mRNA is expressed throughout development, but is most abundant in the early embryo. The cDNA hybridises to a single site on the left arm of the second chromosome at position 28D2-4. The deduced amino acid sequence (309 residues) of Drosophila PP2A shows 94% identity with either rabbit PP2A alpha or PP2A beta, indicating that PP2A may be the most conserved of all known enzymes.

One of the protein phosphatase 1 isoenzymes in Drosophila is essential for mitosis.

Drosophila has four loci encoding type 1 protein serine/threonine phosphatases (PP1s). Here we describe mutations in one of these genes, at 87B on chromosome 3. Mutants die at the larval-pupal boundary with little or no imaginal cell proliferation. Neuroblasts are delayed in progress through mitosis and show defective spindle organization, abnormal sister chromatid segregation, hyperploidy, and excessive chromosome condensation. Germline transformation of mutant flies with the wild-type PP1 87B gene restores normal mitosis, viability, and fertility. These results show that PP1 activity is required for mitotic progression and that the other loci cannot supply sufficient activity to complement loss of expression of the PP1 87B gene. Alternatively, the PP1 87B product may have a distinct specialized function in mitosis.

Cloning and chromosomal localization of Drosophila cDNA encoding the catalytic subunit of protein phosphatase 1 alpha. High conservation between mammalian and insect sequences.

A 1.2-kb clone containing the full coding sequence of a protein phosphatase 1 catalytic subunit has been isolated from a Drosophila head cDNA library. It encodes a polypeptide of 302 amino acids with a molecular mass of 34.5 kDa. The predicted protein sequence is 92% identical (94% similar) to rabbit protein phosphatase 1 alpha (PP-1 alpha) demonstrating strict conservation of the phosphatase catalytic subunit over a considerable evolutionary distance. Abundant 1.6-kb and 2.5-kb mRNA transcripts were detected throughout Drosophila development. The clone hybridised to four sites on Drosophila salivary gland polytene chromosomes. The major site is at 87B6-12 on the right arm of chromosome 3. In addition, there are three secondary sites, one on the same chromosome at 96A2-5 and two on the X chromosome at 9C1-2 and 13C1-2. Isolation of a further cDNA clone, hybridising to 9C1-2 and encoding part of the catalytic subunit 88% similar to Drosophila PP-1 alpha, proves the existence of at least two transcriptionally active genes for protein phosphatase 1.

Molecular cloning and chromosomal localization of a novel Drosophila protein phosphatase.

A 1.0 kilobase cDNA coding for the complete amino acid sequence of a putative protein phosphatase (314 amino acid residues, molecular mass 36 kDa) has been isolated from a Drosophila head cDNA library. The cDNA hybridises to a single site on the right arm of the second chromosome at cytological position 55A1-3. The deduced sequence of the protein, designated protein phosphatase-Y, is homologous to the catalytic subunits of Drosophila and rabbit protein phosphatase-1 alpha (64 and 59% identity, respectively) and rabbit protein phosphatase-2A (39% identity). These and other comparisons demonstrate that this novel enzyme is not the Drosophila counterpart of mammalian protein phosphatases 1, 2A, 2B, 2C or X.

Mitosis in Drosophila development.

Many aspects of the mitotic cycle can take place independently in syncytial Drosophila embryos. Embryos from females homozygous for the mutation gnu undergo rounds of DNA synthesis without nuclear division to produce giant nuclei, and at the same time show many cycles of centrosome replication (Freeman et al. 1986). S phase can be inhibited in wild-type Drosophila embryos by injecting aphidicolin, in which case not only do centrosomes replicate, but chromosomes continue to condense and decondense, the nuclear envelope undergoes cycles of breakdown and reformation, and cycles of budding activity continue at the cortex of the embryo (Raff and Glover, 1988). If aphidicolin is injected when nuclei are in the interior of the embryo, centrosomes dissociate from the nuclei and can migrate to the cortex. Pole cells without nuclei then form around those centrosomes that reach the posterior pole (Raff and Glover, 1989); the centrosomes presumably must interact with polar granules, the maternally-provided determinants for pole cell formation. The pole cells form the germ-line of the developing organism, and as such may have specific requirements for mitotic cell division. This is suggested by our finding that a specific class of cyclin mRNAs, the products of the cyclin B gene, accumulate in pole cells during embryogenesis (Whitfield et al. 1989). Other genes that are essential for mitosis in early embryogenesis and in later development are discussed.

Physical and immunological characterization of a guanine nucleotide-binding protein purified from bovine cerebral cortex.

ADP-ribosylation by pertussis toxin has been used to identify the alpha subunit of Ni, the guanine nucleotide-binding protein which mediates hormone and GTP inhibition of adenylate cyclase. Two proteins have been purified from bovine cerebral cortex which are substrates for ADP-ribosylation by pertussis toxin, a 41-kDa protein (alpha 41) and a 39-kDa protein (alpha 39). The 41-kDa protein is very similar to the subunit of Ni purified from other tissues while the function of the 39-kDa protein is unknown (Neer, E. J., Lok, J. M., and Wolf, L. G. (1984) J. Biol. Chem. 259, 14222-14229; Sternweis, P. C., and Robishaw, J. D. (1984) J. Biol. Chem. 259, 13806-13813). We now show that the purified alpha 39 protein from bovine brain is a relatively hydrophilic protein which associates with a hydrophobic beta gamma component. The complex can be dissociated by guanosine 5'-(3-O-thio)triphosphate. The alpha 39 component binds guanosine 5'-(3-O-thio)triphosphate with a KD of 27 nM. We have developed polyclonal antibodies to alpha 39 and beta. The antibodies to alpha 39 cross-react weakly with alpha 41 in an immunoblot assay indicating some homology between the two proteins but making it unlikely that alpha 39 is derived from alpha 41. Using the antibodies for quantitation we found that alpha 39 is 0.5% and beta is 0.7% of membrane proteins. While the antibodies cross-react with alpha 39 and beta proteins in many different species, central nervous system tissues always have more immunoreactivity than membranes from peripheral organs. Anti-beta antibody recognizes the beta subunit when it is associated with alpha 39 or alpha 41 and can immunoprecipitate both alpha . beta gamma trimers. The guanine nucleotide-dependent dissociation of the alpha 39 . beta gamma trimer suggests that the complex could inhibit adenylate cyclase by liberating free beta gamma units. The function of alpha 39 may not, however, be exclusively to regulate adenylate cyclase but may include coupling hormone receptors to other effectors. Antibodies specific for alpha 39 and beta will be useful tools in determining the functions of alpha 39 and beta in hormone-responsive cells.