R1 and R2 Retrotransposition and Deletion in the rDNA Loci on the X and Y Chromosomes of Drosophila melanogaster

R1 and R2 Retrotransposition and Deletion in the rDNA Loci on the X and Y Chromosomes of Drosophila melanogaster

César E. Pérez-González^a, William D. Burke^a, and Thomas H. Eickbush^a
^a Department of Biology, University of Rochester, Rochester, New York 14627

Corresponding author: Thomas H. Eickbush, Department of Biology, University of Rochester, Rochester, NY 14627-0211., eick{at}mail.rochester.edu (E-mail)

Communicating editor: S. HENIKOFF

The non-LTR retrotransposons R1 and R2 insert into the 28S rRNAgenes of arthropods. Comparisons among Drosophila lineages haveshown that these elements are vertically inherited, while studieswithin species have indicated a rapid turnover of individualcopies (elimination of old copies and the insertion of new copies).To better understand the turnover of R1 and R2, 200 retrotranspositionsand nearly 100 eliminations have been scored in the Harwichmutation-accumulation lines of Drosophila melanogaster. Becausethe rDNA arrays in D. melanogaster are present on the X andY chromosomes and no exchanges were detected in these lines,it was possible to show that R1 retrotranspositions occur predominantlyin the male germ line, while R2 retrotranspositions were moreevenly divided between the germ lines of both sexes. The rateof elimination of elements from the Y rDNA array was twice thatof the X rDNA array with both chromosomal loci containing regionswhere the rate of elimination was on average eight times higher.Most R1 and R2 eliminations appear to occur by large intrachromosomalevents (i.e., loop-out events) that involve multiple rDNA units.These findings are interpreted in light of the known abundanceof R1 and R2 elements in the X and Y rDNA loci of D. melanogaster.

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