Conservation of brown gene trans-inactivation in Drosophila

Position effect variegation and viability are both sensitive to dosage of constitutive heterochromatin in Drosophila

The dosage effect of Y-chromosome heterochromatin on suppression of position effect variegation (PEV) has long been well-known in Drosophila. The phenotypic effects of increasing the overall dosage of Y heterochromatin have also been demonstrated; hyperploidy of the Y chromosome produces male sterility and many somatic defects including variegation and abnormal legs and wings. This work addresses whether the suppression of position effect variegation (PEV) is a general feature of the heterochromatin (independent of the chromosome of origin) and whether a hyperdosage of heterochromatin can affect viability. The results show that the suppression of PEV is a general feature of any type of constitutive heterochromatin and that the intensity of suppression depends on its amount instead of some mappable factor on it. We also describe a clear dosage effect of Y heterochromatin on the viability of otherwise wild-type embryos and the modification of that effect by a specific gene mutation. Together, our results indicate that the correct balance between heterochromatin and euchromatin is essential for the normal genome expression and that this balance is genetically controlled.

Nuclear organization and gene expression: homologous pairing and long-range interactions

Genetic studies have demonstrated that pairing interactions between homologous chromosomes and long-range associations between nonhomologous sites can influence gene expression. Recent work has revealed that such influences are widespread in eukaryotes and that chromosome architecture is likely to be of fundamental importance for nuclear structure and function.

Isolation and sequence of the Drosophila virilis 60 A gene, a transforming growth factor-beta superfamily member related to vertebrate bone morphogenetic proteins

The complete protein-coding region of the Drosophila virilis 60 A gene, a member of the transforming growth factor-beta superfamily, was isolated and sequenced. The mature domain of the protein-coding region is 99% identical to the Drosophila melanogaster 60 A gene and 73% identical to human bone morphogenetic protein 5. In the pro-domain, a number of large blocks of amino acids are also highly conserved, indicating an important functional role for this portion of the protein as well. In the putative 5' and 3' untranslated regions, several short sequence motifs are conserved between D. virilis and D. melanogaster.

Copy number and orientation determine the susceptibility of a gene to silencing by nearby heterochromatin in Drosophila

The classical phenomenon of position-effect variegation (PEV) is the mosaic expression that occurs when a chromosomal rearrangement moves a euchromatic gene near heterochromatin. A striking feature of this phenomenon is that genes far away from the junction with heterochromatin can be affected, as if the heterochromatic state "spreads." We have investigated classical PEV of a Drosophila brown transgene affected by a heterochromatic junction approximately 60 kb away. PEV was enhanced when the transgene was locally duplicated using P transposase. Successive rounds of P transposase mutagenesis and phenotypic selection produced a series of PEV alleles with differences in phenotype that depended on transgene copy number and orientation. As for other examples of classical PEV, nearby heterochromatin was required for gene silencing. Modifications of classical PEV by alterations at a single site are unexpected, and these observations contradict models for spreading that invoke propagation of heterochromatin along the chromosome. Rather, our results support a model in which local alterations affect the affinity of a gene region for nearby heterochromatin via homology-based pairing, suggesting an alternative explanation for this 65-year-old phenomenon.

Germline transformation of Drosophila virilis mediated by the transposable element hobo

A laboratory strain of Drosophila virilis was genetically transformed with a hobo vector carrying the miniwhite cassette using a helper plasmid with an hsp70-driven hobo transposase-coding sequence. The rate of transformation was 0.5% per fertile GO animal. Three transgenic insertions were cloned and characterized and found to be authentic hobo insertions. These results, together with the known widespread distribution of hobo in diverse insect species, suggest that hobo and related transposable elements may be of considerable utility in the germline transformation of insects other than D. melanogaster.