FlyMine: an integrated database for Drosophila and Anopheles genomics.

FlyMine is a data warehouse that addresses one of the important challenges of modern biology: how to integrate and make use of the diversity and volume of current biological data. Its main focus is genomic and proteomics data for Drosophila and other insects. It provides web access to integrated data at a number of different levels, from simple browsing to construction of complex queries, which can be executed on either single items or lists.

Genomic anatomy of the Tyrp1 (brown) deletion complex.

Chromosome deletions in the mouse have proven invaluable in the dissection of gene function. The brown deletion complex comprises >28 independent genome rearrangements, which have been used to identify several functional loci on chromosome 4 required for normal embryonic and postnatal development. We have constructed a 172-bacterial artificial chromosome contig that spans this 22-megabase (Mb) interval and have produced a contiguous, finished, and manually annotated sequence from these clones. The deletion complex is strikingly gene-poor, containing only 52 protein-coding genes (of which only 39 are supported by human homologues) and has several further notable genomic features, including several segments of >1 Mb, apparently devoid of a coding sequence. We have used sequence polymorphisms to finely map the deletion breakpoints and identify strong candidate genes for the known phenotypes that map to this region, including three lethal loci (l4Rn1, l4Rn2, and l4Rn3) and the fitness mutant brown-associated fitness (baf). We have also characterized misexpression of the basonuclin homologue, Bnc2, associated with the inversion-mediated coat color mutant white-based brown (B(w)). This study provides a molecular insight into the basis of several characterized mouse mutants, which will allow further dissection of this region by targeted or chemical mutagenesis.

Constitutive DNA damage is linked to DNA replication abnormalities in Bloom's syndrome cells.

Bloom's syndrome (BS) is an autosomal recessive disorder associated with an elevated incidence of cancers. The gene mutated in BS, BLM, encodes a RecQ helicase family member. BS cells exhibit genomic instability, including excessive homologous recombination and chromosomal aberrations. We reported previously that BS cells also demonstrate increased error-prone nonhomologous endjoining, which could contribute to genomic instability in these cells. Here, we show that BS cells display an abnormality in the timing of replication of both early-replicating genes and late-replicating loci such as chromosomal fragile sites. This delayed replication is associated with a constitutively increased frequency of sites of DNA damage and repair, as determined by the presence of DNA repair factors such as RAD51 and Ku86. In addition, another RecQ family helicase, WRN, also localizes to these repair sites. The presence of these repair sites correlates with the temporal appearance of cyclin B1 expression, indicative of the cells having progressed beyond mid-S phase in the cell division cycle. Critically, these defects in BS cells are the direct result of loss of BLM function, because BS cells phenotypically 'reverted' following transfection with the BLM cDNA no longer show such defects. Thus, our data indicate that constitutive DNA damage is coupled to delayed DNA replication in BS cells.