The alpha-amylase gene in Drosophila melanogaster: nucleotide sequence, gene structure and expression motifs.

We present the complete nucleotide sequence of a Drosophila alpha-amylase gene and its flanking regions, as determined by cDNA and genomic sequence analysis. This gene, unlike its mammalian counterparts, contains no introns. Nevertheless the insect and mammalian genes share extensive nucleotide similarity and the insect protein contains the four amino acid sequence blocks common to all alpha-amylases. In Drosophila melanogaster, there are two closely-linked copies of the alpha-amylase gene and they are divergently transcribed. In the 5'-regions of the two gene-copies we find high sequence divergence, yet the typical eukaryotic gene expression motifs have been maintained. The 5'-terminus of the alpha-amylase mRNA, as determined by primer extension analysis, maps to a characteristic Drosophila sequence motif. Additional conserved elements upstream of both genes may also be involved in amylase gene expression which is known to be under complex controls that include glucose repression.     

DNA sequence variation at a duplicated gene: excess of replacement polymorphism and extensive haplotype structure in the Drosophila melanogaster bicoid region

The bicoid (bcd) gene of Drosophila has played an important role in understanding the system of developmental regulatory genes that controls segmentation in the fruit fly. Several studies in Drosophila and closely related insects suggest that bcd may be the result of a gene duplication in the Dipteran lineage. In addition, the presence of a large, conserved secondary structure in the 3' untranslated region (UTR) makes the bcd gene a good candidate for studying compensatory evolution and the relationship between RNA secondary structure and patterns of standing variation in natural populations. Despite these interesting aspects, a population-level analysis has until now not been performed on bcd. In this study, DNA sequence variation was examined for a 4-kb region of the bcd gene, including a portion of the 5' UTR, the entire coding region, and the 3' UTR, for 25 Drosophila melanogaster isofemale lines from Zimbabwe and one allele from D. simulans. Statistical tests revealed a significant excess of replacement polymorphisms in the D. melanogaster lineage that are clustered in two putative linker regions of the Bicoid protein. This result is consistent with a relaxation of selective constraints in these regions. In addition, we found a distinct haplotype structure and a significantly smaller number of haplotypes than predicted by the standard neutral model. It is unlikely that the haplotype structure is maintained by epistatic selection acting on the secondary structure in the 3' UTR or by the association of the bcd gene with polymorphic inversions. Instead, our two main observations, namely the occurrence of a haplotype structure and the excess of replacement polymorphisms, may indicate that the selective history of this gene is rather complex, involving both the relaxation of purifying selection in some parts of the protein and the action of positive selection in other parts of the gene region.     

DNA sequence, structure, and tyrosine kinase activity of the Drosophila melanogaster Abelson proto-oncogene homolog.

We report our molecular characterization of the Drosophila melanogaster Abelson gene (abl), a gene in which recessive loss-of-function mutations result in lethality at the pupal stage of development. This essential gene consists of 10 exons extending over 26 kilobase pairs of genomic DNA. The DNA sequence encodes a protein of 1,520 amino acids with strong sequence similarity to the human c-abl proto-oncogene beginning in the type lb 5' exon and extending through the region essential for tyrosine kinase activity. When the tyrosine kinase homologous region was expressed in Escherichia coli, phosphorylation of proteins on tyrosine residues was observed with an antiphosphotyrosine antibody. These results show that the abl gene is highly conserved through evolution and encodes a functional tyrosine protein kinase required for Drosophila development.     

DNA sequence of the white locus of Drosophila melanogaster

The DNA sequence of the white locus of Drosophila melanogaster is presented. This 14,100 base-pair sequence includes the region of the locus required for wild-type levels of expression and control of expression. We also report the sequence of a complementary DNA clone which established the position of the 3' end of the white RNA on this genomic sequence. The probable exon-intron structure of the gene has been predicted from the DNA sequence of the regions known to be represented in the RNA. The amino acid sequence of the protein which would be produced by translation of this RNA suggests that the white locus gene product may be a membrane protein. The DNA sequence rearrangements associated with seven insertion mutants (white-dominant-zeste-like (wDZL), white-spotted (wsp), white-honey (wh), white-zeste-mottled (wzm), white-apricot (wa), white-buff (wbf) and white-hd81b11 (whd81b11)), one deletion mutant (white-spotted 4 (wsp4)) and one internal duplication mutant (white-ivory (wi)) have been determined and positioned on the wild-type sequence. The positions of these insertions and those of previously characterized insertions associated with six other mutations suggest that some insertions within an intron may still allow the production of correctly spliced RNA, but affect the amount, and correspondingly the expression of the w locus.     

Identifying a single-copy DNA sequence associated with the expression of a heterochromatic gene, the light locus of Drosophila melanogaster

Although little is known about the molecular organization of most genes within heterochromatin, the unusual properties of these chromosomal regions suggest that genes therein may be organized and expressed very differently from those in euchromatin. We report here the cloning, by P transposon tagging, of sequences associated with the expression of the light locus, an essential gene found in the heterochromatin of chromosome 2 of Drosophila melanogaster. We conclude that this DNA is either a segment of the light locus, or a closely linked, heterochromatic sequence affecting its expression. While other functional DNA sequences previously described in heterochromatin have been repetitive, light gene function may be associated, at least in part, with single-copy DNA. This conclusion is based upon analysis of DNA from mutations and reversions induced by P transposable elements. The cloned region is unusual in that this single-copy DNA is embedded within middle-repetitive sequences. The in situ hybridization experiments also show that, unlike most other sequences in heterochromatin, this light-associated DNA evidently replicates in polytene chromosomes, but its diffuse hybridization signal may suggest an unusual chromosomal organization.     

Molecular evolution of the Est-6 gene in Drosophila melanogaster: contrasting patterns of DNA variability in adjacent functional regions

We have investigated nucleotide polymorphism at the esterase 6 gene (Est-6) gene, including the complete coding region (1686 bp), as well as the 5'-flanking (1183 bp) and 3'-flanking (193 bp) regions of the gene, in 30 strains of Drosophila melanogaster and in one strain of Drosophila simulans. The level of silent variation is similar in the coding and in the 3'-flanking region, but smaller in the 5'-flanking region. Strong linkage disequilibrium occurs within each region; and also, although less pronounced, between the 5'-flanking region and the rest of the gene, including the 3'-flanking region. We suggest that the pattern of nucleotide polymorphism of Est-6 may be shaped by: (1) directional and balancing selection acting on the promoter and the coding region; and (2) interactions between the two regions that involve variable degrees of hitchhiking. The patterns of linkage disequilibrium, as well as the statistics Z(nS) (Genetics 146 (1997)1197) and B and Q (Genet. Res. 74 (1999) 65), may be interpreted as there being multiple targets of selection within the gene. The previously reported Est-6 allozyme latitudinal clines may be accounted for by the interaction between selective processes in the promoter and coding regions.     

Conservation of gene order, structure and sequence between three closely linked genes in Drosophila melanogaster and Drosophila virilis

In Drosophila melanogaster, the apparently unrelated genes anon-66Da, RpL14, and anon-66Db (from telomere to centromere) are located on a 5547 bp genomic fragment on chromosome arm 3L at cytological position 66D8. The three genes are tightly linked, and flanked by two relatively large genes with unknown function. We have taken a comparative genomic approach to investigate the evolutionary history of the three genes. To this end we isolated a Drosophila virilis 7.3 kb genomic fragment which is homologous to a 5.5 kb genomic region of D. melanogaster. Both fragments map to Muller's element D, namely to section 66D in D. melanogaster and to section 32E in D. virilis, and harbor the genes anon-66Da, RpL14, and anon-66Db. We demonstrate that the three genes exhibit a high conservation of gene topography in general and in detail. While most introns and intergenic regions reveal sequence divergences, there are, however, a number of interspersed conserved sequence motifs. In particular, two introns of the RpL14 gene contain a short, highly conserved 60 nt long sequence located at corresponding positions. This sequence represents a novel Drosophila small nucleolar RNA, which is homologous to human U49. Whereas DNA flanking the three genes shows no significant interspecies homologies, the 3'-flanking region in D. virilis contains sequences from the transposable element Penelope. The Penelope family of transposable elements has been shown to promote chromosomal rearrangements in the D. virilis species group. The presence of Penelope sequences in the D. virilis 7.3 kb genomic fragment may be indicative for a transposon-induced event of transposition which did not yet scramble the order of the three genes but led to the breakdown of sequence identity of the flanking DNA.     

DNA sequence analysis of X-ray-induced deletions at the white locus of Drosophila melanogaster

We have determined the nucleotide sequence of 5 X-ray-induced white mutants containing small rearrangements. Comparison with wild-type sequences showed deletions in the coding region ranging in size between 6 bp and 29 bp. These small deletions are distributed non-randomly over the white locus. Two mutants contain the same 29-bp deletion, while the other 3 deletions are clustered. All 5 deletions have occurred between 2 and 3 bp repeats. One of the repeats is preserved in the novel junction formed by the deletion. Our results suggest that recombinational processes may be involved in the generation of X-ray-induced deletions.     

High expression of Cyp6g1, a cytochrome P450 gene, does not necessarily confer DDT resistance in Drosophila melanogaster

Cytochrome P450 monooxygenases, a family of detoxifying enzymes, are thought to confer resistance to various insecticides including DDT. Daborn et al. [Daborn, P., Yen, J.L., Bogwitz, M., Le Goff, G., Feil, et al. 2002. A single p450 allele associated with insecticide resistance in Drosophila. Science 297, 2253-2256.] suggested that the Accord transposable element causes overexpression of a Cyp6g1 allele, which has spread globally and is the basis of DDT resistance in Drosophila melanogaster populations. To determine whether the same phenomenon also operates in other Drosophila strains, we investigated 91-R, 91-C, ry(506), Wisconsin, Canton-SH and Hikone-RH strains. While the LC(50) values for the 91-R and Wisconsin strains are 8348 microg and 447 microg of DDT, respectively, values for the other four strains range between 0.74 to 20.9 microg. As expected, the susceptible ry(506) and 91-C strains have about 16-33-fold lower levels of CYP6G1 mRNA than the resistant 91-R and Wisconsin strains. Surprisingly, CYP6G1 mRNA and protein levels in the Canton-SH and Hikone-RH strains are as high as in the two resistant strains, yet they are as susceptible as the 91-C strain. The susceptible phenotype of the Canton-SH and Hikone-RH strains is not due to mutation in the Cyp6g1 gene; sequence analysis showed that Cyp6g1 alleles of resistant and susceptible strains are very similar and cannot be classified into resistant and susceptible alleles. As observed by others, we also found that only the 5'-upstream DNA of overexpressing alleles of Cyp6g1 has an insertional DNA, which is similar to Accord and Ninja elements. To examine the role of Cyp6g1 in DDT resistance, we substituted the Cyp6g1 allele of the 91-R strain with the allele from the susceptible 91-C strain via recombination and synthesized three recombinant lines. All three lines lacked Accord insertion and showed low expression of Cyp6g1 like the 91-C strain, yet they were as highly resistant as the 91-R strain. We conclude a strain may not have to have Accord insertion in the Cyp6g1 gene and the Cyp6g1 itself may not have to be overexpressed for DDT resistance to occur.     

Molecular analysis of the responder satellite DNA in Drosophila melanogaster: DNA bending, nucleosome structure, and Rsp-binding proteins.

The Responder (Rsp) locus of Drosophila melanogaster, the target locus of segregation distortion, is a satellite DNA array. This repeat array imparts some fitness advantage to the chromosomes bearing it. In this paper, we report the following three related molecular properties of this satellite repeat: (1) Sequence-directed curvature--On a polyacrylamide gel, Rsp-containing fragments migrate slower than would be predicted on the basis of their physical sizes. The extent of migration retardation correlates with the size and position of the Rsp sequence in a DNA fragment, suggesting that Rsp DNA is bent. The bending is shown to be affected by a DNA-binding drug (Hoechst 33258). (2) Nucleosome structure--Nucleosomes associated with Rsp repeats have an unusual spacing pattern. Instead of being spaced at approximately 190-bp intervals as is the bulk chromatin, they are separated at approximately 240-bp intervals, roughly the size of a dimeric Rsp repeat. The nucleosomal structure in the Rsp region is preferentially disrupted by Hoechst 33258, whereas the bulk chromatin appears to be insensitive to the drug. (3) Rsp-DNA binding proteins--Gel mobility-shift assays using nuclear extracts from pupae and end-labeled Rsp repeat demonstrate the presence of three distinct DNA-protein complexes. Competition assays suggest that these complexes are specific to the Rsp sequence, and two of these nucleoprotein complexes seem to be influenced by the presence of Hoechst 33258. The observed complexes are formed by nonhistone proteins of somatic origin and may be related to the normal functions of Rsp, rather than to the germ-line segregation distortion activities.     

A DNA sequence of Drosophila melanogaster with a differential telomeric distribution

A DNA sequence (8–19T) of 2.3 kilobase pairs (kb) of Drosophila melanogaster was localized by in situ hybridization to the extreme ends of polytene chromosomes and to the chromocenter. The relative abundance of this sequence at the ends of polytene chromosomes X2L2R3L3R is 13.41.902.7. This differential distribution is probably due to different copy numbers at the individual telomeric regions. Restriction enzyme analysis of genomic DNA shows that 8–19T sequences are interspersed with other sequences. The clone 8–19T, which contains most of this interspersed repetitive sequence, is itself not internally repetitive but has a complex sequence composition. Some of these sequences are transcribed into poly(A)⁺RNA. We suggest that the ends of Drosophila chromosomes are of a complex arrangement with some sequences common to all ends.