Rapid sequence divergence in a heat shock locus of Drosophila

Unusual Drosophila virilis stress-puff at 20CD: cytological localization of a heat sensitive locus and some peculiarities of the heat shock response

Using a series of chromosome aberrations a heat shock (hs) inducible site of the Drosophila virilis heat shock puff 20CD has been cytologically localized in the distal 20C subdivision: the hs puff was not observable in chromosome 2 carrying the Df(2)ebTG-52 deficiency; the bands in the proximal 20D subdivision could not autonomously be activated by hs in aberrant chromosomes that have this deficiency or the In(2)ebPC-19 inversion. An electron microscopy (EM) analysis of the successive stages of puff development in the 20CD and 20F regions shows that the 20CD puff is intially formed from the right part of the 20C6-7 band. In the maximally developed puff, the neighboring bands of the 20C and 20D regions are only partially decondensed; they are seen as discrete compact chromatin clumps. Specific differences in the ultrastructural organization and in response to hs have been found between the D. virilis "unusual" 20CD and typical 20F hs puffs.

Evolution and arrangement of the hsp70 gene cluster in two closely related species of the virilis group of Drosophila

To investigate the genetic basis of differing thermotolerance in the closely related species Drosophila virilis and Drosophila lummei, which replace one another along a latitudinal cline, we characterized the hsp70 gene cluster in multiple strains of both species. In both species, all hsp70 copies cluster in a single chromosomal locus, 29C1, and each cluster includes two hsp70 genes arranged as an inverted pair, the ancestral condition. The total number of hsp70 copies is maximally seven in the more thermotolerant D. virilis and five in the less tolerant D. lummei, with some strains of each species exhibiting lower copy numbers. Thus, maximum hsp70 copy number corresponds to hsp70 mRNA and Hsp70 protein levels reported previously and the size of heat-induced puffs at 29C1. The nucleotide sequence and spacing of the hsp70 copies are consistent with tandem duplication of the hsp70 genes in a common ancestor of D. virilis and D. lummei followed by loss of hsp70 genes in D. lummei. These and other data for hsp70 in Drosophila suggest that evolutionary adaptation has repeatedly modified hsp70 copy number by several different genetic mechanisms.

Evolution of thermotolerance and the heat-shock response: evidence from inter/intraspecific comparison and interspecific hybridization in the virilis species group of Drosophila. I. Thermal phenotype

Species in the virilis group of Drosophila (fruit flies), which overlap or replace one another along climatic gradients, exhibit corresponding differences in basal thermotolerance, inducible thermotolerance and the heat-shock response. The low-latitude species D. virilis exceeds the high-latitude species D. lummei in these measures of thermotolerance, the temperature threshold for heat-shock factor (HSF) activation and the ability to express hsp70 mRNA and diverse heat-shock proteins (e.g. Hsp70, Hsp83 and small Hsps) after intense heat shock (e.g. 40-41 degrees C). The xeric species D. novamexicana differs from the mesic species D. texana in much the same way for many of these traits. By contrast, intraspecific variation in these traits is small. Because D. virilis and D. lummei can readily be crossed to yield partially fertile progeny, genetic analysis of interspecific differences is possible. Interspecific hybrids are intermediate to the parental species in basal thermotolerance and inducible thermotolerance and resemble D. virilis in Hsp concentrations after intense heat shock and Hsp70 protein electromorphs.

Hsp70 duplication in the Drosophila melanogaster species group: how and when did two become five?

To determine how the modern copy number (5) of hsp70 genes in Drosophila melanogaster evolved, we localized the duplication events that created the genes in the phylogeny of the melanogaster group, examined D. melanogaster genomic sequence to investigate the mechanisms of duplication, and analyzed the hsp70 gene sequences of Drosophila orena and Drosophila mauritiana. The initial two-to-four hsp70 duplication occurred 10--15 MYA, according to fixed in situ hybridization to polytene chromosomes, before the origin and divergence of the melanogaster and five other species subgroups of the melanogaster group. Analysis of more than 30 kb of flanking sequence surrounding the hsp70 gene clusters suggested that this duplication was likely a retrotransposition. For the melanogaster subgroup, Southern hybridization and an hsp70 restriction map confirmed the conserved number (4) and arrangement of hsp70 genes in the seven species other than D. melanogaster. Drosophila melanogaster is unique; tandem duplication and gene conversion at the derived cluster yielded a fifth hsp70 gene. The four D. orena hsp70 genes are highly similar and concertedly evolving. In contrast, the D. mauritiana hsp70 genes are divergent, and many alleles are nonfunctional. The proliferation, concerted evolution, and maintenance of functionality in the D. melanogaster hsp70 genes is consistent with the action of natural selection in this species.

Chromosomal homology and molecular organization of Muller's elements D and E in the Drosophila repleta species group

Thirty-three DNA clones containing protein-coding genes have been used for in situ hybridization to the polytene chromosomes of two Drosophila repleta group species, D. repleta and D. buzzatii. Twenty-six clones gave positive results allowing the precise localization of 26 genes and the tentative identification of another nine. The results were fully consistent with the currently accepted chromosomal homologies and in no case was evidence for reciprocal translocations or pericentric inversions found. Most of the genes mapped to chromosomes 2 and 4 that are homologous, respectively, to chromosome arms 3R and 3L of D. melanogaster (Muller's elements E and D). The comparison of the molecular organization of-these two elements between D. melanogaster and D. repleta (two species that belong to different subgenera and diverged some 62 million years ago) showed an extensive reorganization via paracentric inversions. Using a maximum likelihood procedure, we estimated that 130 paracentric inversions have become fixed in element E after the divergence of the two lineages. Therefore, the evolution rate for element E is approximately one inversion per million years. This value is comparable to previous estimates of the rate of evolution of chromosome X and yields an estimate of 4.5 inversions per million years for the whole Drosophila genome.

The heat shock genes in the Drosophila montium subgroup: chromosomal localization and evolutionary implications

The hsp70, hsp83, hsromega, and the small heat shock protein genes were mapped on the polytene chromosomes of six species, representative of the geographical distribution of the Drosophila montium subgroup of the melanogaster species group. In addition, based on hybridization conditions, the putative locus of the hsp68 gene is given. In contrast to the situation in the melanogaster subgroup species, the hsp70 locus is single in the montium species. The hsp83, hsromega and the small hsp loci are also single in the montium genomes studied here, a common feature of all Drosophila species. Among the hsp genes studied, the small hsp genes and the hsromega-homologous sequences exhibit a higher degree of divergence between the melanogaster and the montium subgroups. Our results support the idea that the montium subgroup species has a genome organization closer to that of the common ancestor compared with the melanogaster subgroup species.

The Afrotropical Drosophila montium subgroup: Balbiani ring 1, polytene chromosomes, and heat shock response of Drosophila vulcana

A detailed photographic map of the salivary gland polytene chromosomes of Drosophila vulcana, an Afrotropical species of the montium subgroup of the melanogaster group, is presented, along with chromosomal rearrangements, such as reverse tandem duplications and inversions, the well-formed Balbiani ring 1, and the most prominent puffs during normal larval and white prepupal development and after ecdysone treatment. In addition, the heat inducible protein and puffing pattern and the loci of the major heat shock genes, namely, hsp70, hsp83, the "small" hsps, and a putative hsp68, of this species were studied. In the light of the data revealed by the above studies, phylogenetic relationship among the montium subgroup species are attempted.

The 93D (hsr-omega) locus of Drosophila: non-coding gene with house-keeping functions

The 93D, or hsr-omega (heat-shock RNA-omega), locus of Drosophila melanogaster and other species of Drosophila, besides being induced as a member of the heat shock gene family, is also selectively and singularly inducible by a variety of agents, notably benzamide, colchicine and vitamin B6 (in species other than D. melanogaster). The genomic structure of this locus is highly conserved in all species, although the primary base sequence has diverged rapidly between species. Three transcripts (two nuclear and one cytoplasmic) are produced by this locus but none of them has any significant protein coding capacity. The profile of the three transcripts varies in a developmental and inducer-specific manner. This locus is developmentally active in nearly all cell types and is essential for viability of flies. Its induction during heat shock is independent of the other members of the heat shock gene family. The other selective inducers act on this locus through separate response elements. hsr-omega activity has a characteristic effect on transcription/turnover of the heat shock induced hsp70 and the alpha-beta transcripts in D. melanogaster. It appears that the hsr-omega locus has important house-keeping functions in transport and turnover of some transcripts and in monitoring the 'health' of the translational machinery of the cell.

The heat shock protein hsp70 binds in vivo to subregions 2-48BC and 3-58D of the polytene chromosomes of Drosophila hydei

Multiple interactions of members of the hsp70 family with cellular components have already been described. We present, however, the first evidence that upon heat shock treatment hsp70 molecules interact with specific chromosomal subdivisions of the polytene chromosomes of Drosophila hydei. After a heat shock treatment of 20 min the protein binds to subdivision 3-58D1 and to the heat shock inducible subdivisions 2-48B3-6 and 2-48C1-2. Hsp70 molecules were also observed in subdivision 3-58D1 during recovery at 25 degrees C but not in subdivisions 2-48B3-6 and 2-48C1-2. Our data suggest that this interaction is stress specific. DNase and RNase experiments suggest, moreover, that the hsp70 molecules bind to RNA from ribonucleoproteins (RNPs) in subdivisions 2-48B3-6 and 2-48C1-2 and to DNA in subdivision 3-58D1. The DNA sequences in subdivision 3-58D1 seem to have the potential to adopt the Z-DNA conformation.

Heat shock loci 93D of Drosophila melanogaster and 48B of Drosophila hydei exhibit a common structural and transcriptional pattern

A comparison of gene structure, sequence, and transcription pattern of heat shock loci 93D of Drosophila melanogaster and 48B of Drosophila hydei has been performed. Both heat shock loci consist of an unique region that is flanked by an internally repetitive element. Different members of these elements are highly conserved, repeat unit length, however, and primary sequence diverged totally. Whereas the overall gene structure in both species is substantially related, sequence conservation is only observed at very few sites in the unique region. These represent primarily sequences that are identified as regulatory elements for faithful transcription and processing. The number and size of transcripts obtained from heat shock locus 48B in third instar larvae closely resembles the pattern of heat shock locus 93D. Thus their quite alike structure and transcription pattern suggest strongly a conserved hitherto unknown function.

Heat shock locus 93D of Drosophila melanogaster: a spliced RNA most strongly conserved in the intron sequence

The Drosophila melanogaster heat shock locus at 93D encodes at least three overlapping transcripts, 10-12 kilobases (kb), 1.9 kb, and 1.2 kb. The abundance of the three transcripts is significantly increased during heat shock; however, all are also found in non-heat-shocked cells. The 1.2-kb transcript is found in the cytoplasm. Sequence analysis of a 1.1-kb cDNA clone representing sequences within the 1.2-kb transcript and comparison to genomic sequences indicate that it is spliced; 700 base pairs of sequence found in genomic DNA are removed from the middle of the transcript. Sequence analysis further suggests that this RNA does not encode a heat shock protein. The largest open reading frame beginning with a methionine codon would encode a polypeptide of 34 amino acids. We have not been able to detect a heat shock-induced polypeptide of this size. A DNA clone from the analogous heat shock puff of Drosophila hydei has been analyzed by hybridization with the small subclones used to sequence the D. melanogaster cDNA plus a genomic fragment containing the 700-base-pair intron. Results of this hybridization indicated strong homology of the intron fragment. Weaker homology was detected with the two small fragments flanking the intron. Other fragments of the D. melanogaster cDNA showed no hybridization to the cloned D. hydei puff DNA.

The unusual structure of heat shock locus 2-48B in Drosophila hydei

We have previously isolated a 500 bp-long cDNA clone, NO9-15, which is derived from a nuclear transcript originating from the heat shock locus 2-48B of Drosophila hydei (Peters et al. 1982). Sequence analysis shows that this clone carries 4 complete copies and 1 partial copy of a 115 bp repeat unit. The repeats are closely homologous with a maximal sequence divergence of about 10%. The sequence does not contain an open reading frame. The genomic organization of heat shock locus 2-48B, as probed with the cloned cDNA sequence NO9-15, is highly polymorphic. Four different allelic arrangements have been found in different inbred strains. A number of genomic clones isolated from region 2-48B, both in phage lambda and in cosmid vectors, all differ in length, mainly due to varying numbers of the NO9-15 repeat unit. These differences are found primarily in the proximal region of the locus. The transcribed region of these clones includes the distal sequence flanking the NO9-15 repeat as well as the NO9-15 repeat itself. An oligo A stretch was found between the distal flanking sequence and the NO9-15 repeat region.

Chromosomal arrangement of heat shock locus 2-48B in Drosophila hydei

cDNA, copied from nuclear RNA isolated from heat shocked Drosophila hydei cells, has been cloned. From this collection of clones a clone, N09-15, with a 450 bp insert has been isolated that hybridizes in situ to the heat shock locus-2-48B of Drosophila hydei. The N09-15 sequence is present in two different genomic arrangements, as shown by restriction mapping, in our wild type D. hydei population. These genomic arrangements are allelic. Both alleles contain multiple copies of the N09-15 sequence but differ in their lengths and in the distribution of Msp I and Taq I sites.

Rapid and high resolution detection of in situ hybridisation to polytene chromosomes using fluorochrome-labeled RNA

Fluorochrome-labeled RNA allows the rapid detection of in situ hybrids without the need for long exposure times as in the autoradiographical hybridisation methods. Resolution is high because of the high resolving power of fluorescence microscopy. The application of a previously reported method for the hybrido-cytochemical detection of DNA sequences to polytene chromosomes of Drosophilia is described. The specificity and sensitivity of the method are demonstrated by the hybridisation with polytene chromosomes of 1) rhodamine-labeled 5S RNA, to the 5S rRNA sites of D. melanogaster (56F) and D. hydei (23B), 2) rhodamine-labeled RNA complementary to a plasmid containing histone genes, to the 39DE region of D. melanogaster, 3) rhodamine-labeled D. melanogaster tRNA species (Gly-3 and Arg-2), to their respective loci in D. melanogaster, 4) rhodamine-labeled RNA complementary to the insert of plasmid 232.1 containing part of a D. melanogaster heat shock gene from locus 87C, to D. hydei heat shock locus 2-32A. In the latter instance it was possible to demonstrate the labeling of a double band which escaped unambiguous detection by autoradiography in the radioactive cytochemical hybridisation procedure because of the low topological resolution of autoradiograms. The sensitivity of the fluorochrome-labeled RNA method is compared with the radioactive methods which use 3H- or 125 I-labeled RNAs. The factors governing the sensitivity and the number of bound fluorochrome molecules to be expected are discussed.