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.     

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.     

Overlapping functional units in a cell division gene cluster in Escherichia coli

The ftsZ ( sulB ) coding sequence is preceded by two promoters, at least one of which lies within the coding sequence of the neighboring gene, ftsA . This region of the ftsA gene is required for full biological activity of ftsZ .     

Structure and sequence of the Drosophila zeste gene.

The zeste gene of Drosophila affects the expression of other genes in a manner that depends on the homologous pairing of the chromosomes bearing the target gene. Zeste mediates transvection effects, the ability of one gene to control the expression of its homologous copy on another chromosome. We have determined the structure of the zeste gene and several mutants bearing partial deletions and the sequence of the z+, z1, zop6 and z11G3 alleles. The predicted zeste protein has an unusual structure including runs of Gln, Ala and alternating Gln Ala. Contrary to expectations the z1, zop6 and z11G3 mutations can each be attributed to single amino acid changes. The analysis of the mutants suggests that the zeste gene product is required for normal expression of at least some genes and we argue that za mutants may have residual function.     

Euglena gracilis chloroplast transfer RNA transcription units. Nucleotide sequence analysis of a tRNAThr-tRNAGly-tRNAMet-tRNASer-tRNAGln gene cluster

The arrangement and the nucleotide sequence of the tRNA genes in the 2.0-kilobase-pair EcoRI restriction fragment EcoQ of Euglena gracilis Klebs, strain Z Pringsheim chloroplast DNA have been determined. This fragment, cloned in pBR325 to form the plasmid pEZC300, contains five tRNA genes. The DNA insert of this plasmid, a known tRNA gene locus (Orozco, E.M., Jr., and Hallick, R.B. (1982) J. Biol. Chem. 257, 3258-3264) has been mapped by Southern gel analysis using a 32P-labeled oligodeoxynucleotide tRNA gene probe. The DNA sequence of 870 base pairs (bp) from EcoQ containing the entire tRNA gene locus was determined. The organization of this tRNA gene cluster on the E. gracilis chloroplast chromosome is tRNAUUGGln-14-BP spacer-RNAGCUSer-175-bp spacer-tRNACAUMet-12-bp spacer-tRNAGCCGly-5-bp spacer-tRNAUGUThr. The tRNAUUGGln and tRNAGCUSer gene sequences are of the opposite polarity as the other three gene sequences, but of the same polarity as the rRNA genes. The tRNAMet gene is a putative initiator tRNA. The five tRNA genes are separated and flanked by A-T-rich spacer sequences. This gene arrangement is consistent with the model that E. gracilis chloroplast tRNA genes are transcribed into multicistronic tRNA precursors. The DNA sequences have been used to deduce the primary and secondary structures of the tRNAs.     

Overlapping deficiencies refine the map position of the sex-linked actin gene of Drosophila melanogaster

A ³H-labelled actin-specific probe was hybridized to Drosophila melanogaster X chromosomes heterozygous for deficiencies in the 5C region. The results suggest that the sex-linked actin gene resides in the overlap region of Df(1)C149 and Df(1)N73 at 5C3-4.