Evolutionary implications of a complex pattern of DNA sequence homology extending far upstream of the hsp70 genes at loci 87A7 and 87C1 in Drosophila melanogaster

Variation at the 87A heat shock locus in Drosophila melanogaster

Restriction maps for 25 kilobases of DNA around the 87A7 heat shock locus have been determined in 29 chromosomes isolated from a natural population. The heterozygosity per nucleotide and the proportion of polymorphic nucleotide sites were estimated to be 0.0024 and 0.007, respectively. The mean number of insertional differences in this region between random pairs of chromosomes was 0.95. A significant amount of this variation was due to the insertion of large transposable elements. All the insertion/deletion events were found in a region less than 2 kilobases in size. This could either be due to nonrandom integration or to differences in the intensity of selection against DNA insertion at different sites.

Modification of heat-shock gene expression in Drosophila melanogaster populations via transposable elements

We report multiple cases in which disruption of hsp70 regulatory regions by transposable element (TE) insertions underlies natural variation in expression of the stress-inducible molecular chaperone Hsp70 in Drosophila melanogaster. Three D. melanogaster populations from different continents are polymorphic for jockey or P element insertions in the promoter of the hsp70Ba gene. All three TE insertions are within the same 87-bp region of hsp70Ba promoter, and we suggest that the distinctive promoter architecture of hsp genes may make them vulnerable to TE insertions. Each of the TE insertions reduces Hsp70 levels, and RNase protection assays demonstrate that such insertions can reduce transcription of the hsp70Ba gene. In addition, the TEs alter two measures of organismal fitness, inducible thermotolerance and female reproductive success. Thus, transposition can create quantitative genetic variation in gene expression within populations, on which natural selection can act.

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.

A DROSOPHILA MELANOGASTER Strain From Sub-Equatorial Africa Has Exceptional Thermotolerance But Decreased Hsp70 Expression

Drosophila melanogaster collected in sub-equatorial Africa in the 1970s are remarkably tolerant of sustained laboratory culture above 30°C and of acute exposure to much warmer temperatures. Inducible thermotolerance of high temperatures, which in Drosophila melanogaster is due in part to the inducible molecular chaperone Hsp70, is only modest in this strain. Expression of Hsp70 protein and hsp70 mRNA is likewise reduced and has slower kinetics in this strain (T) than in a standard wild-type strain (Oregon R). These strains also differed in constitutive and heat-inducible levels of other molecular chaperones. The lower Hsp70 expression in the T strain apparently has no basis in the activation of the heat-shock transcription factor HSF, which is similar in T and Oregon R flies. Rather, the reduced expression may stem from insertion of two transposable elements, H.M.S. Beagle in the intergenic region of the 87A7 hsp70 gene cluster and Jockey in the hsp70Ba gene promoter. We hypothesize that the reduced Hsp70 expression in a Drosophila melanogaster strain living chronically at intermediate temperatures may represent an evolved suppression of the deleterious phenotypes of Hsp70.

Drosophila melanogaster is polymorphic for a specific repeated (CATA) sequence in the regulatory region of hsp23

To identify sequence variation associated with a selection response for heat tolerance in Drosophila melanogaster, we sequenced 1400bp of the heat shock protein 23 gene (hsp23) promoter region in four heat-selected and two control lines. The region was found to be variable for a specific (CATA) repeated sequence, and the sequence CTT seems to be a hot spot for mutation. The repeated tetranucleotide sequence was located in several short repeats scattered throughout the entire region. Similar variable repeats are also located downstream the of hsp23 gene in the intergenic region between hsp23 and hsp27. We detected nine different hsp23 alleles. Their frequencies in the selection and control lines seemed to be mainly determined by genetic drift. The function of the CATA repeats is not yet known, though these regions have homology to SAR elements located in the intergenic region between two hsp70 genes, suggesting a similar function.

ATP-dependent nucleosome disruption at a heat-shock promoter mediated by binding of GAGA transcription factor

Genetic control elements are usually situated in local regions of chromatin that are hypersensitive to structural probes such as DNase I. We have reconstructed the chromatin structure of the hsp70 promoter using an in vitro nucleosome assembly system. Binding of the GAGA transcription factor on existing nucleosomes leads to nucleosome disruption, DNase I hypersensitivity at the TATA box and heat-shock elements, and rearrangement of adjacent nucleosomes. ATP hydrolysis facilitates this process, suggesting that an energy-dependent pathway is involved in chromatin remodelling.

Inhibition of calcium/calmodulin-dependent protein kinase in Drosophila disrupts behavioral plasticity

One of the major mediators of calcium action in neurons is the multifunctional calcium/calmodulin-dependent protein kinase (CaM kinase), an enzyme with the capability of directly regulating its own activity by autophosphorylation. To assess the involvement of CaM kinase in experience-dependent behavior in an intact animal, we have designed a specific peptide inhibitor of CaM kinase and made transgenic Drosophila that express it under control of an inducible promoter. These flies fail to learn normally in two behavioral plasticity paradigms: acoustic priming, a nonassociative measure of sensitization, and courtship conditioning, a measure of associative learning. The magnitude of the learning defect in the associative paradigm appears to be proportional to the level of expression of the peptide gene in the two transgenic lines and can be increased by heat shock induction of gene expression. These results suggest that CaM kinase activity is required for plastic behaviors in an intact animal.

Stress-induced oligomerization and chromosomal relocalization of heat-shock factor

The induction of heat-shock transcription factor (HSF) binding to DNA is accomplished by a heat-induced oligomerization. The transition to the induced state is accompanied by a chromosomal redistribution of HSF to the heat-shock puff sites. Over 150 additional chromosomal sites also accumulate HSF, including developmental loci that are repressed during heat shock. These findings suggest an unforeseen role for HSF as a repressor of normal gene activity during heat stress.

Positive autoregulation of sex-lethal by alternative splicing maintains the female determined state in Drosophila

Sex-lethal is a binary switch gene that controls all aspects of Drosophila sexual dimorphism. It must be active in females and inactive in males. The on/off regulation reflects alternative RNA splicing in which full-length proteins are produced only in females. Here we investigate the role of Sxl in maintaining sexual pathway commitments. By ectopic expression of a female Sxl cDNA in transgenic male flies, we show that Sxl protein induces a rapid switch from male- to female-specific splicing. The ectopically expressed Sxl protein wil trans-activate an endogenous wild-type Sxl gene. This establishes a feedback loop in which Sxl proteins induce their own synthesis by directing the female-specific splicing of Sxl transcripts. We conclude that the female determined state is maintained by Sxl through positive autoregulation, while the male determined state is maintained by default.

Interaction of topoisomerase 1 with the transcribed region of the Drosophila HSP 70 heat shock gene

Topoisomerase I cleavage sites have been mapped in vivo on the Hsp70 heat shock gene of Drosophila melanogaster cells using the drug camptothecin. Topoisomerase I cleavage was only observed when the Hsp70 gene was transcriptionally active. Site-specific single-strand DNA cleavage by topoisomerase I was confined to the transcribed region of the Hsp70 gene and occurred on both the transcribed and nontranscribed DNA strands. A number of the single-strand breaks on the complementary DNA strands occurred in close proximity giving rise to double-stranded DNA breaks. Inhibition of heat-induced Hsp70 transcription by either Actinomycin D (Act D) or 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) inhibited topoisomerase I cleavage except at the 5' and to a lesser extent the 3' end of the gene. Camptothecin (100 microM) inhibited transcription of the Hsp70 gene greater than 95%. These results suggest that topoisomerase I is intimately associated with and has an integral part in Hsp70 gene transcription.

Unusual DNA structures at the integration site of an HIV provirus

Supercoiled pHXBc2 DNA (containing the genome of the human immunodeficiency virus type 1 and human sequences) migrated more slowly than linear DNA in native and ethidium bromide agarose gel electrophoresis at 4.5 volts/cm, suggesting the presence of unusual DNA structures. S1 nuclease analysis of pHXBc2 revealed two S1 hypersensitive sites. Site I was located within a 25 bp direct repeat in host DNA 0.6 kB upstream from the 5' LTR. Site II was mapped 0.2 kB upstream from the vif gene start site. Sequence analysis showed that Site I sequences could assume different unusual DNA structures, whereas sequences at Site II could assume either slipped or H-DNA forms. Unusual DNA structures in host DNA may be associated with active chromatin regions and may favor proviral integration.

Nucleotide sequence of the Stp-1 gene coding for rat spermatid nuclear transition protein 1 (TP1): homology with protamine P1 and assignment of the mouse Stp-1 gene to chromosome 1

Spermatid transition protein 1 (TP1) is a 54 amino acid (aa), highly basic chromosomal protein found in mammals during the brief period when histones are being replaced by protamines in the haploid phase of spermatogenesis. Using a cDNA clone as probe, we have isolated the gene (Stp-1) coding for rat TP1 from a population of recombinant bacteriophage lambda. The nucleotide (nt) sequence was established from a point 126 nt upstream from the mRNA cap site to a point about 30 nt downstream from the predicted site of polyadenylation. The gene contains a single intron separating the codon for aa 45 of the mature protein. Comparison of the nucleotide sequences for Stp-1 and the mouse gene coding for protamine P1 suggests a possible evolutionary relationship. Southern blot hybridization to genomic DNA isolated from a panel of mouse-hamster somatic cell hybrids unambiguously mapped Stp-1 to mouse chromosome 1.

Purification and properties of Drosophila heat shock activator protein

Drosophila heat shock activator protein, a rare transacting factor which is induced upon heat shock to bind specifically to the heat shock regulatory sequence in vivo, has been purified from shocked cells to more than 95 percent homogeneity by sequence-specific duplex oligonucleotide affinity chromatography. The purified protein has a relative molecular mass of 110 kilodaltons, binds to the regulatory sequence with great affinity and specificity, and strongly stimulates transcription of the Drosophila hsp70 gene. Studies with this regulatory protein should lead to an understanding of the biochemical pathway underlying the heat shock phenomenon.

Sequence dependence of Drosophila topoisomerase II in plasmid relaxation and DNA binding

The sequence dependence of Drosophila topoisomerase II supercoil relaxation and binding activities has been examined. The DNA substrates used in binding experiments were two fragments from Drosophila heat shock locus 87A7. One of these DNA fragments includes the coding region for the heat shock protein hsp70, and the other includes the intergenic non-coding region that separates two divergently transcribed copies of the hsp70 gene at the locus. The intergenic region was previously shown to have a much higher density of topoisomerase cleavage sites than the hsp70 coding region. Competition nitrocellulose filter binding assays demonstrate a preferential binding of the intergene fragment, and that binding specificity increases with increasing ionic strength. Dissociation kinetics indicate a greater kinetic stability of topoisomerase II complexes with the intergene DNA fragment. To study topoisomerase II relaxation activity, we used supercoiled plasmids that contained the same fragments from locus 87A7 cloned as inserts. The relative relaxation rates of the two plasmids were determined under several conditions of ionic strength, and when the plasmid substrates were included in separate reactions or when they were mixed in a single reaction. The relaxation properties of these two plasmids can be explained by a coincidence of high-affinity binding sites, strong cleavage sites, and sites used during the catalysis of strand passage events by topoisomerase II. Sequence dependence of topoisomerase II catalytic activity may therefore parallel the sequence dependence of DNA cleavage by this enzyme.

Sequences involved in temperature and ecdysterone-induced transcription are located in separate regions of a Drosophila melanogaster heat shock gene

The transcriptional regulation of the Drosophila melanogaster hsp27 (also called hsp28) gene was studied by introducing altered genes into the germ line by P element-mediated transformation. DNA sequences upstream of the gene were defined with respect to their effect on steroid hormone-induced and heat-induced transcription. These two types of control were found to be separable; the sequences responsible for 80% of heat-induced expression were located more than 1.1 kilobases upstream of the RNA initiation site, while the sequences responsible for the majority of ecdysterone induction were positioned downstream of the site at -227 base pairs. We have determined the DNA sequence of the intergenic region separating hsp23 and hsp27 and have located putative heat shock and ecdysterone consensus sequences. Our results indicate that the heat shock promoter of the hsp27 gene is organized quite differently from that of hsp70.

In vivo localization of DNA topoisomerase II cleavage sites on Drosophila heat shock chromatin

Similar to its inhibitory effect on mammalian DNA topoisomerase II, the cytotoxic drug VM26 (teniposide) also interferes with the breakage-reunion reaction of Drosophila melanogaster DNA topoisomerase II. VM26 induces topoisomerase II-mediated DNA breakage in vitro and in cultured D. melanogaster cells presumably by stabilizing an enzyme-DNA cleavable complex. The drug-induced DNA breaks on D. melanogaster hsp70 genes were mapped in cultured cells using the indirect end-labeling procedure. Multiple and specific cleavage sites occurred at both the 3' and 5' ends of the hsp70 genes. A number of these cellular topoisomerase II cleavage sites mapped close to the DNase I-hypersensitive regions of the hsp70 genes. The intensities of several topoisomerase II cleavage sites changed significantly on heat shock induction. Treatment of cultured D. melanogaster cells with VM26 at 25 degrees C resulted in the stimulation of transcription of the hsp70 genes. These results suggest that inhibition of DNA topoisomerase II may lead to heat shock transcription.

Detection, sequence patterns and function of unusual DNA structures

Unusual DNA structures were detected by an electrophoretic procedure in which DNA fragments were separated according to size on agarose gels and then by shape on polyacrylamide gels. Fragments from yeast centromeres migrated faster in polyacrylamide than predicted from their base composition and size and this property was attributed to a nonrandom distribution of oligomeric A tracts that exhibited minima at 10-11 base intervals. Fragments from seven loci in 107 kb of DNA migrated anomalously slow and these fragments contained blocks of A2-6 in a 10-11 base periodicity which is indicative of bent DNA. The most pronounced bent sequences were found within yeast ARS1 and centered at 245 and 240 bp from the left and right ends of the adenovirus genome. Each sequence is approximately 150 bp away from a replication origin and the adenovirus sequences are within 50 bp of enhancers. Nuclear matrix attachment sites, which are also adjacent to enhancers, contain sequences characteristic of bent DNA. These results suggest that bent structures reside at the base of DNA loops in chromosomes.

Substrate utilization for lactate and energy production by heat-shocked L929 cells

The hypothesis that heat shock protein (HSP) induction depends on inhibition of respiration was tested by examining the effects of heat shock on tricarboxylic acid (TCA) cycle function. In control L929 cell cultures, glucose and exogenous pyruvate were converted primarily to lactate, and glutamine was extensively oxidized, accounting for more than one-half of the calculated ATP production. During heat shock at 42 degrees C, lactate production from all of the labeled substrates and total unlabeled lactate production increased significantly while oxygen consumption increased slightly. TCA cycle oxidation of pyruvate decreased during this period while that of glutamine increased. Uncoupling of oxidative phosphorylation caused large increases in oxygen consumption at both 37 degrees C and 42 degrees C, indicating that the capacity of the respiratory chain is not exceeded during heat shock. The net effect of these alterations in substrate utilization were decreased ATP generation and increased NADH utilization. Both 14CO2 and lactate production declined during the 24-h period after cultures were returned to 37 degrees C. On the basis of these data, we conclude that while inhibition of respiration plays no apparent role, other metabolic consequences of heat shock related to energy metabolism may be involved in HSP induction.

In vivo localization of DNA topoisomerase II cleavage sites on Drosophila heat shock chromatin

Similar to its inhibitory effect on mammalian DNA topoisomerase II, the cytotoxic drug VM26 (teniposide) also interferes with the breakage-reunion reaction of Drosophila melanogaster DNA topoisomerase II. VM26 induces topoisomerase II-mediated DNA breakage in vitro and in cultured D. melanogaster cells presumably by stabilizing an enzyme-DNA cleavable complex. The drug-induced DNA breaks on D. melanogaster hsp70 genes were mapped in cultured cells using the indirect end-labeling procedure. Multiple and specific cleavage sites occurred at both the 3' and 5' ends of the hsp70 genes. A number of these cellular topoisomerase II cleavage sites mapped close to the DNase I-hypersensitive regions of the hsp70 genes. The intensities of several topoisomerase II cleavage sites changed significantly on heat shock induction. Treatment of cultured D. melanogaster cells with VM26 at 25 degrees C resulted in the stimulation of transcription of the hsp70 genes. These results suggest that inhibition of DNA topoisomerase II may lead to heat shock transcription.

Sequences involved in temperature and ecdysterone-induced transcription are located in separate regions of a Drosophila melanogaster heat shock gene

The transcriptional regulation of the Drosophila melanogaster hsp27 (also called hsp28) gene was studied by introducing altered genes into the germ line by P element-mediated transformation. DNA sequences upstream of the gene were defined with respect to their effect on steroid hormone-induced and heat-induced transcription. These two types of control were found to be separable; the sequences responsible for 80% of heat-induced expression were located more than 1.1 kilobases upstream of the RNA initiation site, while the sequences responsible for the majority of ecdysterone induction were positioned downstream of the site at -227 base pairs. We have determined the DNA sequence of the intergenic region separating hsp23 and hsp27 and have located putative heat shock and ecdysterone consensus sequences. Our results indicate that the heat shock promoter of the hsp27 gene is organized quite differently from that of hsp70.

Chromosomal loop anchorage of the kappa immunoglobulin gene occurs next to the enhancer in a region containing topoisomerase II sites

Introduction of torsional stress into active chromatin domains requires that linear DNA molecules be anchored in vivo to impede free rotation. While searching for these anchorage elements, we have localized a nuclear matrix association region (MAR) within the mouse immunoglobulin kappa gene that contains two topoisomerase II sites and is adjacent to the tissue-specific enhancer. The same matrix contact occurs when the kappa locus is in germ-line (inactive) or rear-ranged (transcribed) configurations. This constitutive anchorage site partitions the gene into V-J and C region chromatin domains. We demonstrate that at least 10,000 similar and evolutionarily conserved MAR binding sites exist in the nucleus. We propose that these sites, in association with topoisomerase II and possibly in conjunction with enhancers, play fundamental roles in the functional organization of chromatin loop domains.

DNA sequence of a 3.8 kilobase pair region controlling Drosophila chorion gene amplification

During Drosophila oogenesis, two clusters of chorion genes and their flanking DNA sequences undergo amplification in the ovarian follicle cells. Amplification results from repeated rounds of initiation and bidirectional replication within the chorion gene regions, possibly from a single origin, producing nested replication forks. Previously we have shown that following reintroduction into the Drosophila genome, a specific 3.8 kilobase pair DNA segment from the amplified third chromosome domain could induce developmentally regulated amplification at its site of insertion. Here we present the complete nucleotide sequence of this "amplification control element" and of genes encoding the chorion structural proteins s18-1 and s15-1, which are contained within it. Sequences that may be involved in the regulation of chorion gene amplification and expression are identified.

The heat shock response

The response of cells to a heat shock or other stresses is the activation of a small number of genes which were previously inactive or transcribed at low levels. This response has been observed in a wide variety of bacterial, plant, and animal species. Evidence is accumulating that at least some of the proteins found in diverse species are similar, indicating a conservation of the response and the proteins in evolution. In a number of organisms a strong positive correlation has been found between the presence of heat shock proteins and ability of the organism to withstand thermal stress. This review attempts to assess the available data concerning the homology of proteins in different species, the localization of the proteins in cells, and the relationship between heat shock proteins and thermoresistance.

Regulation of heat shock protein 70 gene expression by c-myc

The myc gene seems to have a causal role in tumour formation in man, mouse and avian systems. The myc gene product has been localized to the nucleus, suggesting that it may be involved in the regulation of gene expression. The level of expression of the mammalian heat shock protein 70 (HSP70) gene is elevated in several tumour cell lines, implying that a cellular function expressed in these tumour lines can stimulate HSP70 production. We report here that the gene product of a rearranged mouse c-myc gene is capable of stimulating expression of chimaeric genes containing a Drosophila hsp70 promoter region and 5'-flanking sequences. This stimulation is dependent on sequences located more than 200 bases 5' of the normal start of hsp70 transcription.

Organization of the higher-order chromatin loop: specific DNA attachment sites on nuclear scaffold

Data are presented for sequence-specific chromatin-loop organization in histone-depleted nuclei from Drosophila melanogaster Kc cells. We find one loop for each of the tandemly repeated histone gene clusters. The attachment site is localized in the A + T rich H1-H3 spacer on a 657 bp fragment. In the cluster of the hsp70 heat-shock genes, in both control and heat-shocked cells, we find two attachment sites in close proximity upstream of regulatory elements. The transcribed sequences are not associated with the nuclear scaffold in control or in heat-shocked cells. A family of attachment sites related by hybridization to those of the hsp70 genes was discovered.

Transcription, export and turnover of Hsp70 and alpha beta, two Drosophila heat shock genes sharing a 400 nucleotide 5' upstream region

A highly homologous 400 nucleotide sequence flanks the 5' end and extends 64 NT into the transcribed portion of all five hsp70 and seven alpha beta heat shock genes in Drosophila melanogaster (1-4). To determine the extent to which this sequence dictates coordinate regulation, we compared the total mass, continuous labeling and pulse-labeling of hsp70 and alpha beta RNAs at different times and temperatures of heat shock. By all these measurements, expression of both hsp70 and alpha beta genes increased and decreased in parallel. Hsp70 RNA was generally synthesized at a higher rate and accumulated to a greater extent than alpha beta RNA. As the temperature of heat shock increased, however, the rate of synthesis and accumulation of hsp70 relative to alpha beta RNA decreased. Another difference was that a larger fraction of hsp 70, as compared to alpha beta RNA was exported from the nucleus. For both RNAs, export decreased as the heat shock temperature was increased. The hsp70 and alpha beta genes are thus expressed in parallel, but the homologous 5' upstream sequences do not dictate equal rates of transcription or export from the nucleus.

Two protein-binding sites in chromatin implicated in the activation of heat-shock genes

The resistance to exonuclease digestion of two regions of chromatin at the 5' end of heat-shock genes in Drosophila implies they have protein bound to them. The pattern of resistance before and after induction of gene expression suggests that heat-shock genes are activated by the sequential binding of at least two protein factors.

Chromatin organization of the 87A7 heat shock locus of Drosophila melanogaster

We have examined the chromatin structure of the hsp 70 gene complex at the 87A7 heat shock locus of Drosophila melanogaster. Our results indicate that this locus has a complex chromatin organization. Heat induction causes highly specific alterations in the chromatin throughout the locus. There are major changes within the heat shock gene transcription units, and in both the upstream and downstream flanking spacers.

Mouse and Drosophila genes encoding the major heat shock protein (hsp70) are highly conserved

We used a cloned Drosophila melanogaster hsp70 gene to hybrid-select heat shock-induced mouse mRNA and showed that this mRNA encodes the major mouse heat shock protein. This result suggests that the sequence of the hsp70 gene(s) is highly conserved.

Localization of the hsp83 transcript within a 3292 nucleotide sequence from the 63B heat shock locus of D. melanogaster

We have determined the complete nucleotide sequence of a 3292 bp cloned segment derived from the 63B heat shock cytogenetic locus of D. melanogaster. Within this segment we have positioned the start of transcription and RNA splice sites of the unique gene that encodes the 83,000 d heat shock polypeptide (hsp83 gene) by S1 mapping and synthesis of cDNA from restriction fragment primed mRNA. The sequence begins at a point 879 bp upstream from the transcription start and includes the 149 bp nontranslated first exon, the 1139 bp intron and extends 1125 bp into the protein coding region. These data identify a single open translation reading frame for the first 375 amino acids of the 83,000 d polypeptide, beginning with the first ATG codon located at the 3' intron-exon junction. We discuss and demonstrate the use of E. coli exonuclease III generated single-strand DNA probes as an alternative to strand separation for S1 mapping of mRNA. We also use homology search criteria based upon known protein-DNA binding sites to compare our hsp83 sequence with other sequenced Drosophila heat shock genes. These comparisons indicate that a large region of approximately 80 bp centered around the transcription initiation point of the hsp83 gene shares only a 31% homology with the corresponding region of the hsp70 gene, whereas the hsp22, 23, 26, and 27 genes share a 54% homology with hsp70 in this region. The lower homology of the hsp83 gene is consistent with the deviant nature of this heat shock gene.

Mouse and Drosophila genes encoding the major heat shock protein (hsp70) are highly conserved

We used a cloned Drosophila melanogaster hsp70 gene to hybrid-select heat shock-induced mouse mRNA and showed that this mRNA encodes the major mouse heat shock protein. This result suggests that the sequence of the hsp70 gene(s) is highly conserved.

Structural polymorphism in DNA

We have used the enzyme micrococcal nuclease and the methylating reagent dimethyl sulfate to examine the structural properties of eukaryotic DNAs. Our studies demonstrate extensive structural polymorphism in the DNA double helix. Moreover, we find that the distribution of helical variants is in some instances correlated with the functional organization of the DNA. These observations raise the possibility that eukaryotic DNAs may be organized into discrete functional units having characteristic structural properties. In addition, we find that boundaries between different functional units are typically marked by DNA segments having unusual conformational properties. Such structural perturbations could serve as signals in the utilization of genetic information in eukaryotes, and may be important in a variety of different protein-DNA interactions.

Nucleotide sequence analysis of the Drosophila small heat shock gene cluster at locus 67B

The four small heat shock protein genes of Drosophila melanogaster clustered at cytological locus 67B have been characterized by DNA sequencing. Over 6250 nucleotides, covering the 5', protein-coding and 3' regions of these genes have been determined together with their predicted amino acid sequences. Each gene possesses characteristic eukaryotic 5' and 3' sequence elements and a single uninterrupted protein-coding region. The four encoded polypeptides of 19,700, 20,600, 23,000 and 23,600 Mr share a homologous stretch of 108 amino acid residues, representing 51 to 62% of their lengths. This region is flanked by sequences of dissimilar length and amino acid composition, located mainly at the amino-terminal end, but also at the extreme carboxyl termini of these proteins. The first 14 amino acids exhibit a small degree of homology, both amongst themselves and with some signal peptides and a transmembrane protein. Investigation of the hydrophilic/hydrophobic characteristics of the four polypeptides revealed, within the conserved 108 amino acid stretch, the presence of an alpha-helical region of very prominent local hydrophilicity, which probably represents a surface structural domain common to each protein. Sequence analysis with respect to transcription initiation and termination and possible regulatory signals is discussed together with some structural predictions for the four proteins.

A photoinduced cleavage of DNA useful for determining T residues

Irradiation of 5'-[32P]-phosphate labeled DNA fragments with ultraviolet light in the presence of primary amines followed by piperidine treatment resulted in base-specific cleavage of the DNA chain at T residues, accompanied by a less intensive G reaction. This simple, T greater than G cleavage offers an alternative method for determining T residues in chemical DNA sequencing.