The structural genes for three Drosophila glue proteins reside at a single polytene chromosome puff locus.

The polytene chromosome puff at 68C on the Drosophila melanogaster third chromosome is thought from genetic experiments to contain the structural gene for one of the secreted salivary gland glue polypeptides, sgs-3. Previous work has demonstrated that the DNA included in this puff contains sequences that are transcribed to give three different polyadenylated RNAs that are abundant in third-larval-instar salivary glands. These have been called the group II, group III, and group IV RNAs. In the experiments reported here, we used the nucleotide sequence of the DNA coding for these RNAs to predict some of the physical and chemical properties expected of their protein products, including molecular weight, amino acid composition, and amino acid sequence. Salivary gland polypeptides with molecular weights similar to those expected for the 68C RNA translation products, and with the expected degree of incorporation of different radioactive amino acids, were purified. These proteins were shown by amino acid sequencing to correspond to the protein products of the 68C RNAs. It was further shown that each of these proteins is a part of the secreted salivary gland glue: the group IV RNA codes for the previously described sgs-3, whereas the group II and III RNAs code for the newly identified glue polypeptides sgs-8 and sgs-7.     

Adjacent chromosomal regions can evolve at very different rates: Evolution of theDrosophila 68C glue gene cluster

Summary The 68C puff is a highly transcribed region of theDrosophila melanogaster salivary gland polytene chromosomes. Three different classes of messenger RNA originate in a 5000-bp region in the puff; each class is translated to one of the salivary gland glue proteins sgs-3, sgs-7, or sgs-8. These messenger RNA classes are coordinately controlled, with each RNA appearing in the third larval instar and disappearing at the time of puparium formation. Their disappearance is initiated by the action of the steroid hormone ecdysterone. In the work reported here, we studied evolution of this hormone-regulated gene cluster in themelanogaster species subgroup ofDrosophila. Genome blot hybridization experiments showed that five other species of this subgroup have DNA sequences that hybridize toD. melanogaster 68C sequences, and that these sequences are divided into a highly conserved region, which does not contain the glue genes, and an extraordinarily diverged region, which does. Molecular cloning of this DNA fromD. simulans, D. erecta, D. yakuba, andD. teissieri confirmed the division of the region into a slowly and a rapidly evolving protion, and also showed that the rapidly evolving region of each species codes for third instar larval salivary gland RNAs homologous to theD. melanogaster glue mRNAs. The highly conserved region is at least 13,000 bp long, and is not known to code for any RNAs.     

A trans-acting regulatory product necessary for expression of the Drosophila melanogaster 68C glue gene cluster

The mutation I(1)npr-1 is located at cytological location 2B5 on the X chromosome in Drosophila melanogaster. We have found that this mutation causes absence of the normal product of the 2B5 locus and that it has the following phenotypes: the 68C glue puff on the third chromosome does not regress when mutant salivary glands are cultured in the presence of ecdysterone; the three 68C glue protein mRNAs are not synthesized; and a transformed Drosophila strain carrying both a normal resident 68C Sgs-3 gene and an introduced functional Sgs-3 gene with only a few kb of flanking sequences expresses neither Sgs-3 RNA if the I(1)npr-1 mutation is crossed into the stock. Thus the normal product of the I(1)npr11 gene is required for regression of the 68C puff, and the I(1)npr-1 gene product allows expression of the Sgs-3 gene by interacting, either directly or indirectly, with DNA sequences near this glue protein gene.     

Sequences sufficient for correct regulation of Sgs-3 lie close to or within the gene.

The Drosophila melanogaster 68C chromosomal locus is the site of a prominent polytene chromosome puff that harbors the genes Sgs-3, Sgs-7 and Sgs-8. These genes code for proteins that are part of the salivary glue that Drosophila larvae secrete as a means of fixing themselves to an external substrate for the duration of the pre-pupal and pupal period. The 68C glue genes are regulated by the steroid hormone ecdysterone, with the hormone required for both initiation and cessation of gene expression during the third larval instar. Previous work has defined sequences sufficient for expression of abundant levels of Sgs-3 mRNA at the correct time and in the correct tissue. We show here that sequences sufficient for normal tissue- and stage-specific accumulation of Sgs-3 RNA, but adequate only for low levels of expression, lie within 130 bp of the 5' end of the gene, or within the gene.     

Organization of RNA transcripts from a vaccinia virus early gene cluster

The detailed organization of the RNAs transcribed from an early gene cluster encoded by vaccinia virus has been determined from the information derived from several complementary techniques. These include hybrid selection coupled with cell-free translation to locate DNA sequences complementary to mRNAs encoding specific polypeptides; RNA filter hybridization to size and locate on the DNA mature RNAs as well as higher-molecular-weight RNAs; S1 nuclease mapping to precisely locate the 5' and 3' ends of the RNAs; S1 nuclease mapping to precisely locate the 5' and 3' ends of the RNAs; and fractionation of hybrid-selected mRNAs in an agarose gel containing methyl mercury hydroxide followed by the cell-free translation of these mRNAs to definitively ascertain the size of the mRNA encoding each polypeptide. The early gene cluster is located between 21 and 26 kilobases from the left end of the vaccinia virus genome and is encoded by a 5.0-kilobase EcoRI fragment which spans the HindIII-N, -M, and -K fragments. Transcribed towards the left terminus are four mature mRNAs, 1,450, 950, 780, and 400 nucleotides in size, encoding polypeptides of 55, 30, 20, and 10 kilodaltons, respectively. These mRNAs are colinear with the DNA template and are closely spaced such that the 5' terminus of one mRNA is within 50 base pairs of the 3' terminus of the adjacent RNA. In addition to the mature size mRNAs, there are higher-molecular-weight RNAs, 5,000, 3,300, 2,350, 2,300, 1,800, 1,700, and 1,350 nucleotides in size. The 5' and 3' termini of the high-molecular-weight RNAs are coterminal with the 5' and 3' termini of the mature size mRNA. The implications of this arrangement and the biogenesis of these early mRNAs are discussed.     

An expandable gene that encodes a Drosophila glue protein is not expressed in variants lacking remote upstream sequences

The Drosophila melanogaster gene Sgs4 encodes one of the glue polypeptides, sgs-4, synthesized in the larval salivary gland. We have examined the structure and expression of Sgs4 in five strains that produce abundant amounts of sgs-4 and its mRNA and in four that do not. The nonproducers include three Japanese strains that accumulate trace amounts of mRNA and one strain, BER-1, that contains no detectable Sgs4 RNA. Sgs4 carries a tandem array of repeated 21 bp elements within its coding sequence. The number of elements per array varies, causing considerable differences in the lengths of Sgs4 and its mRNA among the strains. These differences in length are not correlated with differences in mRNA abundance; rather, the low or zero abundance in nonproducers correlates with the loss of DNA upstream from the gene. The Japanese nonproducers carry a 52 bp deletion 305 bp upstream from the 5′ end of Sgs4, and BER-1 carries a 95 bp deletion 392 bp upstream. Curiously, each deletion encompasses one or more of the salivary-gland-specific DNAase I-hypersensitive sites which are known to flank the Sgs4 gene.     

Concerted and divergent evolution within the rat gamma-crystallin gene family

The nucleotide sequences of six rat gamma-crystallin genes have been determined. All genes have the same mosaic structure: the first exons contain a relatively short (25 to 44 base-pair) 5' non-coding region and the first nine base-pairs of the coding sequence, the second exons encode protein motifs I and II, while protein motifs III and IV are encoded by the third exons. The third exons also contain a 60 to 67-base-pair long 3' non-coding region. In the gamma 1-2 gene, the splice acceptor site of the third exon has been shifted three base-pairs upstream. Hence, the protein product of this gene is one amino acid residue longer. The first introns, though varying in length from 85 to 100 base-pairs, are conserved in sequence. The second introns vary considerably in length (0.9 X 10(3) to 1.9 X 10(3) base-pairs) and sequence. The second exons of the genes show concerted evolution and have undergone multiple gene conversions. In contrast, the third exons show divergent evolution. From the sequences of the third exons, an evolutionary tree of the gene family was constructed. This tree suggests that three of the present genes derive directly from the genes that originated from a tandem duplication of a two-gene cluster. Two duplications of the last gene of the four-gene cluster then yielded the other three genes. Region a' of the third exon, encoding protein motif III, is variable, while the region encoding protein motif IV (b') is constant. We postulate that this variability in region a' is due to a period of radiation after each gene duplication. A comparison of the rat sequences with those of orthologous sequences from other species shows that the variation in region a' is now preserved. Hence, it might specify the specific functional property of each gamma-crystallin protein within the lens.     

The 82F late puff contains the L82 gene, an essential member of a novel gene family.

Metamorphosis in Drosophila results from a hierarchy of ecdysone-induced gene expression initiated at the end of the third larval instar. A now classical model of this hierarchy was proposed based on observations of the activity of polytene chromosome "puffs" which distinguished "early" puffs as those directly induced by ecdysone and "late" puffs as those which become active as a secondary response to the hormone. We report here the isolation and characterization of the L82 gene corresponding to the extensively characterized late puff at 82F. L82 is a complex gene that spans at least 50 kb of genomic DNA, produces at least seven different nested mRNAs, and has homology to a novel gene family. In contrast to most previously characterized puff genes, the broad developmental expression pattern of L82 suggests that it is controlled by both ecdysone-dependent and ecdysone-independent regulatory mechanisms. L82 mutations were identified by transgene rescue of developmental delay and eclosion lethal phenotypes.     

Drosophila: the genetics of two major larval proteins.

A series of irradiation-induced deficiencies covering 62 polytene chromosome bands in chromosome arm 3L of Drosophila melanogaster includes the loci of two abundant developmentally regulated larval proteins. The structural gene for larval serum protein 2 (LSP 2) lies at 68E3 or 4, and that for salivary glue secretion protein 3 between 68A8 and 68C11, coincident with a major intermoult puff active in the salivary gland at the time of glue synthesis. The structural genes for esterase 6 and four visible recessive loci lie within the same region.