Functional properties of the heterochromatic sequences inducing w m4 position-effect variegation in Drosophila melanogaster

In position-effect variegation euchromatic genes are brought into the vicinity of heterochromatic sequences as a result of chromosomal rearrangements. This results in the inactivation of these genes in a proportion of cells causing a variegated phenotype. Tartof et al. (1984) have shown that the flanking heterochromatin in the w^m4variegating rearrangement in Drosophila melanogaster is homologous to the Type I inserts found in some portions of the rDNA repeats. We have studied the functional properties of these sequences using 51 revertant chromosomes, several variant lines of w^m4, strong enhancer mutations of position-effect variegation and X heterochromatin deletions. Our results suggest an array of tandemly repeated sequences showing additive effects and probably subject to magnification and reduction in number. Since only 3 of the 51 revertants isolated do not show variegation if strong enhancer mutations are introduced, only a very short sequence must be essential for the induction of white gene inactivation in w^m4. This suggests that the heterochromatic junction itself is sufficient to initiate the variegation of an adjacent gene. Parental source as well as paternal effects on the activity of these sequences have been detected. Revertant chromosomes of w^m4can be found after P-directed mutagenesis in hybrid dysgenic crosses suggesting mobile genetic elements at the breakpoints of inversion w^m4. These results are discussed with respect to the structural basis of positioneffect variegation as well as the function of certain heterochromatic sequences.