The Enigma of Y Chromosome Degeneration: Tram, a Novel Retrotransposon Is Preferentially Located on the Neo-Y Chromosome of Drosophila Miranda

We have cloned a novel transposable element from the neo-Y chromosome of Drosophila miranda. The size of the element, designated as TRAM, is 3.452 bp, including on both sides long terminal direct repeats (LTRs) of 372 bp, respectively. The element is flanked by a 5-bp target site duplication, ATATG. The putative primer binding site (PBS) for minus-strand priming is complementary to 18 nucleotides of the 3'-end of tRNA(Trp). Data base screens for DNA sequence identities were negative, apart from the sequence motif of the PBS. The deduced amino acid sequence from the large ORF does not reveal identities described for other transposons. In situ hybridizations with TRAM subclones show a biased distribution in the genome, with a massive accumulation of TRAM in the neo-Y chromosome, while the former homologue, the X2 chromosome is devoid of TRAM sites. The enriched occurrence of the TRAM element at the evolving neo-Y chromosome of D.miranda adds compelling evidence in favor of the view that Y chromosome degeneration is driven by the accumulation of transposable elements.     

Evolution of the Larval Cuticle Proteins Coded by the Secondary Sex Chromosome Pair: X2 and Neo-Y of Drosophila miranda: I. Comparison at the DNA Sequence Level

The larval cuticle protein genes (Lcps) represent a multigene family located at the right arm of the metacentric autosome 2 (2R) in Drosophila melanogaster. Due to a chromosome fusion the Lcp locus of Drosophila miranda is situated on a pair of secondary sex chromosomes, the X2 and neo-Y chromosome. Comparing the DNA sequences from D. miranda and D. melanogaster organization and the gene arrangement of Lcp1–Lcp4 are similar, although the intergene distances vary considerably. The greatest difference between Lcp1 and Lcp2 is due to the occurrence of a pseudogene in D. melanogaster which is not present in D. miranda. Thus the cluster of the four Lcp genes existed already before the separation of the melanogaster and obscura group. Intraspecific homogenizations of different cluster units must have occurred repeatedly between the Lcp1/Lcp2 and Lcp3/Lcp4 sequence types. The most obvious example is exon 2 of the Lcp3 gene in D. miranda, which has been substituted by the corresponding section of the Lcp4 gene rather recently. The homogenization must have occurred before the translocation which generated the neo-Y chromosome. Lcp3 of D. melanogaster has therefore no orthologous partner in D. miranda. Rearrangements in the promoter regions of the D. miranda Lcp genes have generated new, potentially functional CAAT-box motifs. Since three of the Lcp alleles on the neo-Y are not expressed and Lcp3 is expressed only at a reduced level, it is suggestive to speculate that the rearrangements might be involved as cis-regulatory elements in the up-regulation of the X2-chromosomal Lcp alleles, in Drosophila an essential process for dosage compensation. The Lcp genes on the neo-Y chromosome have accumulated more base substitutions than the corresponding alleles on the X2. Received: 27 December 1995 / Accepted: 30 April 1996     

Evolution of the Larval Cuticle Proteins Coded by the Secondary Sex Chromosome Pair: X2 and Neo-Y of Drosophila miranda: II. Comparison at the Amino Acid Sequence Level

The larval cuticle proteins (LCPs) are encoded by a multigene family, Lcp1–4, located at the right arm of the metacentric autosome 2 (2R) in Drosophila melanogaster. Due to a chromosome fusion the Lcp locus of Drosophila miranda is situated on a pair of secondary sex chromosomes, the X2 and neo-Y chromosomes. Comparing the deduced amino acid sequences of the autosomal D. melanogaster loci with the sex-chromosomal loci of D. miranda, we were able to trace the evolution of the Lcp loci with respect to their different chromosomal inheritance. The length of the signal peptide is conserved in all four LCPs, while the size of the mature LCPs varies. Conserved protein motifs became obvious from the alignment, indicating regions of structural and functional importance. Analyzing intra- and interspecific sequence similarities of the Lcp gene families allowed us to reconstruct the phylogeny of the gene cluster. Alignment with cuticle amino acid sequences originating from divergent insect species reveals motifs already present in the primordial insect LCPs. These motifs indicate different levels of constraint acting during the evolution of the LCPs. Received: 27 December 1995 / Accepted: 30 April 1996