Pairing-dependent mislocalization of a Drosophila brown gene reporter to a heterochromatic environment.

We describe the precise positioning of a reporter gene within heterochromatin where it may be silenced. A transposition of the 59E-60A region into pericentric heterochromatin ensnares distal 59E-60A via somatic pairing. The frequency with which a brown (bw) reporter gene in 59E is silenced is influenced by chromosomal configurations. Silencing occurs only when the bw+ reporter is unpaired due to heterozygosity with a deficiency, where the frequency of bw+ reporter expression is correlated with the extent of bw gene and flanking sequence present. Surprisingly, the frequency of pairing between the transposition in heterochromatin and distal 59E observed cytologically is indistinguishable from the frequency of pairing of homologous chromosomes at 59E in wild-type larval brains, regardless of configuration. Therefore, bringing a susceptible reporter gene into close proximity with heterochromatin does not necessarily affect its expression, but local pairing changes resulting from altered chromosomal configurations can lead to silencing. We also find that an ensnared distal copy of bw that is interrupted by a heterochromatic insertion enhances silencing. This demonstrates that bw can be simultaneously acted upon by pericentric and distal blocks of heterochromatin.

Comparative analysis of position-effect variegation mutations in Drosophila melanogaster delineates the targets of modifiers.

In Drosophila melanogaster, heterochromatin-induced silencing or position-effect variegation (PEV) of a reporter gene has provided insights into the properties of heterochromatin. Class I modifiers suppress PEV, and class II modifiers enhance PEV when the modifier gene is present in fewer than two doses. We have examined the effects of both class I and class II modifiers on four PEV mutations. These mutations include the inversions In(1)w(m4) and In(2R)bw(VDe2), which are classical chromosomal rearrangements that typify PEV mutations. The other mutations are a derivative of brown(Dominant), in which brown+ reporters are inactivated by a large block of heterochromatin, and a P[white+] transposon insertion associated with second chromosome heterochromatin. In general, we find that class I modifiers affect both classical and nonclassical PEV mutations, whereas class II modifiers affect only classical PEV mutations. We suggest that class II modifiers affect chromatin architecture in the vicinity of reporter genes, and only class I modifiers identify proteins that are potentially involved in heterochromatin formation or maintenance. In addition, our observations support a model in which there are different constraints on the process of heterochromatin-induced silencing in classical vs. nonclassical PEV mutations.

The ovarian tumor protein isoforms of Drosophila melanogaster exhibit differences in function, expression, and localization.

The Drosophila melanogaster ovarian tumor (otu) gene, required for normal proliferation and differentiation of the female germ-line, encodes two cytoplasmic protein isoforms, 98 and 104 kDa. Mutants with defects in this gene are typically grouped into one of three phenotypic classes: quiescent (germ cells do not proliferate), oncogenic or tumorous (germ-line cells proliferate uncontrollably), and differentiated (germ-line cells initiate but do not complete differentiation). Analysis of transformants expressing only one of the otu isoforms showed that the 104-kDa isoform (otu-104) can rescue all classes of otu mutants, whereas only differentiated mutants are rescued to a significant extent by the 98-kDa isoform (otu-98). Western analysis of protein extracts prepared from ovaries of various developmental stages indicated that otu-104 predominates in predifferentiated stages, while otu-98 is prevalent in differentiated egg chambers. Immunolocalization experiments demonstrated that otu protein is present in the cytoplasm of oogonial stem cells that populate third instar larvae and in all germ-line-derived cells until late in oogenesis. In stage 10 egg chambers, otu protein shifts to the subcortical region of nurse cells. This type of analysis also showed that upon formation of a 16-cell syncytium otu-104, but not otu-98, preferentially accumulates in the developing oocyte cytoplasm. The otu mutant protein does not show this pattern of enhanced accumulation, nor does it occur in ovaries of egalitarian and Bicaudal-D mutants, which are defective in oocyte determination. Thus, these studies indicate that the 104-kDa isoform is required for normal proliferation of female germline cells and perhaps for oocyte differentiation. The 98-kDa isoform appears to be dispensable but can provide an otu function needed for the completion of oocyte maturation.

Structure and expression of hybrid dysgenesis-induced alleles of the ovarian tumor (otu) gene in Drosophila melanogaster.

Mutations at the ovarian tumor (otu) gene of Drosophila melanogaster cause female sterility and generate a range of ovarian phenotypes. Quiescent (QUI) mutants exhibit reduced germ cell proliferation; in oncogenic (ONC) mutants germ cells undergo uncontrolled proliferation generating excessive numbers of undifferentiated cells; the egg chambers of differentiated (DIF) mutants differentiate to variable degrees but fail to complete oogenesis. We have examined mutations caused by insertion and deletion of P elements at the otu gene. The P element insertion sites are upstream of the major otu transcription start sites. In deletion derivatives, the P element, regulatory regions and/or protein coding sequences have been removed. In both insertion and deletion mutants, the level of otu expression correlates directly with the severity of the phenotype: the absence of otu function produces the most severe QUI phenotype while the ONC mutants express lower levels of otu than those which are DIF. The results of this study demonstrate that the diverse mutant phenotypes of otu are the consequence of different levels of otu function.