Chromosome Rearrangements Induce Both Variegated and Reduced, Uniform Expression of Heterochromatic Genes in a Development-Specific Manner

Chromosome Rearrangements Induce Both Variegated and Reduced, Uniform Expression of Heterochromatic Genes in a Development-Specific Manner

Karen S. Weiler^a and Barbara T. Wakimoto^a
^a Department of Zoology, University of Washington, Seattle, Washington 98195

Corresponding author: Barbara T. Wakimoto, Department of Zoology, University of Washington, Kincaid Hall, Box 351800, Seattle, WA 98195-1800, wakimoto{at}u.washington.edu (E-mail).

Communicating editor: J. A. BIRCHLER

In Drosophila melanogaster, chromosome rearrangements that juxtaposeeuchromatin and heterochromatin can result in position effectvariegation (PEV), the variable expression of heterochromaticand euchromatic genes in the vicinity of the novel breakpoint.We examined PEV of the heterochromatic light (lt) and concertina(cta) genes in order to investigate potential tissue or developmentaldifferences in chromosome structure that might be informativefor comparing the mechanisms of PEV of heterochromatic and euchromaticgenes. We employed tissue pigmentation and in situ hybridizationto RNA to assess expression of lt in individual cells of multipletissues during development. Variegation of lt was induced inthe adult eye, larval salivary glands and larval Malpighiantubules for each of three different chromosome rearrangements.The relative severity of the effect in these tissues was nottissue-specific but rather was characteristic of each rearrangement.Surprisingly, larval imaginal discs did not exhibit variegatedlt expression. Instead, a uniform reduction of the lt transcriptwas observed, which correlated in magnitude with the degreeof variegation. The same results were obtained for cta expression.These two distinct effects of rearrangements on heterochromaticgene expression correlated with the developmental stage of thetissue. These results have implications for models of heterochromatinformation and the nuclear organization of chromosomes duringdevelopment and differentiation.

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