Sequence of a sea urchin hsp70 gene and its 5' flanking region

We report the nucleotide sequence of a 4470-bp fragment derived from a sea urchin genomic clone containing part of a heat-shock protein 70 (Hsp70)-encoding gene. This fragment, named hsp70 gene II, contains 1271 bp of the flanking region and 3299 bp of structural gene sequence interrupted by five introns and encoding the N-terminal 371 amino acids (aa) of the protein. The 5' flanking region contains a putative TATA element, two CCAAT boxes, four heat-shock consensus sequence elements (hse) and one consensus sequence for binding of Sp1. Remarkable homologies were observed for deduced aa sequence and intron-exon organization between hsp70 gene II and rat hsc73 gene.     

Xenopus hsp 70 genes are constitutively expressed in injected oocytes.

Xenopus heat-shock genes are transiently heat-inducible in somatic cells, but they are also subject to a long-term developmental control in oogenesis and early embryogenesis. In order to understand whether different genes or different promoter elements are involved in the two types of control, several genomic clones coding for Xenopus heat-shock proteins, hsp 70 and hsp 30, were isolated, characterised and tested for expression in oocytes and COS cells. Three isolated hsp 70 genes are nearly identical in their promoter and mRNA leader sequences, indicating that there is only one type of hsp 70 gene. These promoters contain a consensus sequence element (CT-GAA--TTC-AG) upstream of the TATA-box, which is presumably required for their transient heat-inducibility. The two isolated hsp 30 genes show 5'-flanking sequences similar to each other, except that one of them shows a homology disruption precisely around the consensus sequence element. The same gene contains a frameshift mutation in the protein coding part and, since it cannot be expressed after introduction into oocytes or COS cells, it is probably a pseudogene. The other hsp 30 gene is strongly heat-inducible in injected oocytes or transfected COS cells. In contrast, the hsp 70 genes are strongly heat-inducible in COS cells, but their expression is highly efficient in injected oocytes at the normal temperature and is not increased during heat shock. This represents correct cell type-specific regulation of a cloned reintroduced gene, since the endogenous hsp 70 genes are constitutively activated during oogenesis, leading to the accumulation of stored hsp 70 mRNA in oocytes.     

Changes in hsp70 alter thermotolerance and heat-shock regulation in Drosophila.

To test the role of the heat shock protein hsp70 in induced thermotolerance and in the regulation of the heat-shock response, we established cell lines with altered expression of the Hsp70 gene. Underexpressing cells were created by transformation with antisense Hsp70 genes, and overexpressing cells by transformation with extra copies of the wild-type gene. Expression at normal temperatures was achieved by placing Hsp70 coding sequences under the control of the metallothionein promoter. Cells that expressed mutant hsp70s were created by transforming cells with deletion and frameshift mutations. The results indicate that hsp70 plays a major role in both thermotolerance and regulation. Surprisingly, they also indicate that these functions can be separated. Overexpression affected thermotolerance more than regulation; underexpression affected regulation more than thermotolerance. A carboxyl-terminal deletion of Hsp70 had a severe dominant-negative effect on thermotolerance but only a minor effect on regulation; an amino-terminal deletion strongly affected regulation but not thermotolerance. A model that explains these observations is presented.     

Comparison of regulatory and structural regions of the Xenopus laevis small heat-shock protein-encoding gene family.

We have isolated several unique Xenopus laevis hsp30 (encoding heat-shock protein 30) genomic clones, one of which contains two complete hsp30 genes (hsp30C and hsp30D), as well as the promoter and N-terminal coding region of a third gene (hsp30E). Nucleotide sequence and restriction enzyme analysis revealed that this gene cluster is different from a cluster isolated previously. The hsp30C and hsp30D genes encode proteins of approx. 24 kDa. In all, the hsp30 gene family contains a minimum of seven genes. The strand exchange and breakage of the duplication events which generated this gene family appear to have occurred within tracts of DNA which potentially can assume a Z-DNA conformation. Comparing the amino acid (aa) sequences of each known Hsp30 protein with bovine alpha-crystallin revealed a high degree of shared conservation of aa that constitute the major structural feature(s) of alpha-crystallin.     

Structure and Expression of a Heat-Shock Protein 83 Gene of Pharbitis nil

Four cDNA clones representing mRNAs whose levels were affected by a photoperiod that induces flowering in Pharbitis nil were isolated by a differential hybridization screening procedure. The level of mRNAs represented by three clones (12L, 15L, and 17L) increased following a photoperiod that induces flowering and that represented by the fourth clone (clone 27) increased under conditions in which flowering was inhibited. DNA sequence analysis showed that one cDNA, clone 17L, is homologous to members of the 83- to 90-kD heat-shock protein (hsp) gene family. The corresponding gene, hsp83A, was isolated and its DNA sequence was determined. hsp83A encodes a protein that exhibits 70% amino acid identity with Drosophila melanogaster HSP83. The P. nil hsp83A gene contains two introns within the coding region. hsp83A mRNA was not detectable in cotyledons of plants grown in continuous light, but its level increased transiently following a 14-h dark period and reached a maximum 2 h after the lights were turned on. A dramatic increase in the level of hsp83A mRNA was also found 2 h after an end-of-day dark treatment. Genomic Southern blot analysis demonstrated that the P. nil hsp83-90 gene family consists of at least six members, one of which appears to be constitutively expressed in the light.     

The genes coding for the hsp70 (dnaK) molecular chaperone machine occur in the moderate thermophilic archaeon Methanosarcina thermophila TM-1

The hsp70(dnaK) locus of the moderate thermophilic archaeon Methanosarcina thermophila TM-1 was cloned, sequenced, and tested in vitro to measure gene induction by heat and ammonia, i.e., stressors pertinent to the biotechnological ecosystem of this methanogen that plays a key role in anaerobic bioconversions. The locus' genes and organization, 5'-grpE-hsp70(dnaK)-hsp40 (dnaJ)-trkA-3', are the same as those of the closely related mesophile Methanosarcina mazei S-6, but different from those of the only other archaeon for which comparable sequence data exist, the thermophile Methanobacterium thermoautotrophicum deltaH, from another genus, in which trkA is not part of the locus. The proteins encoded in the TM-1 genes are very similar to the S-6 homologs, but considerably less similar to the deltaH proteins. The TM-1 Hsp70(DnaK) protein has the 23-amino acid deletion--by comparison with homologs from gram-negative bacteria first described in the S-6 molecule and later found to be present in all homologs from archaea and gram positives. The genes responded to a temperature elevation in a manner that demonstrated that they are heat-shock genes, functionally active in vivo. Ammonia also induced a heat-shock type of response by hsp70(dnaK), and a similar response by trkA. The data suggest that the moderate thermophile TM-1 has an active Hsp70(DnaK)-chaperone machine in contrast to hyperthermophilic archaea, and that trkA is a stress gene, inasmuch as it responds like classic heat-shock genes to stressors that induce a typical heat-shock response.     

The structure and expression of maize genes encoding the major heat shock protein, hsp70

We have isolated and sequenced two maize genomic clones that are homologous to the Drosophila hsp70 gene. One of the maize hsp70 clones contains the entire hsp70 coding region and 81 nucleotides of the 5' nontranslated sequence. The predicted amino acid sequence for this maize protein is 68% homologous to the hsp70 of Drosophila. The second maize hsp70 clone contains only part of the coding sequence and 1.1 kb of the 5' flanking sequence. This 5' flanking sequence contains two sequences homologous to the consensus heat-shock-element sequence. Both maize genes are thermally inducible and each contains an intron in the same position as that of the heat-shock-cognate gene, hsc1, of Drosophila. The presence of an intron in the maize genes is a distinguishing feature in that no other thermally inducible hsp70 genes described to date contain an intron. We have constructed a hybrid hsp70 gene containing the entire hsp70 coding sequence with an intron, and 1.1 kb of the 5' flanking sequence. We demonstrate that this hybrid gene is thermally inducible in a transgenic petunia plant and that the gene is expressed from its own promoter.     

Remarkable site specificity of local transposition into the Hsp70 promoter of Drosophila melanogaster

Heat-shock genes have numerous features that ought to predispose them to insertional mutagenesis via transposition. To elucidate the evolvability of heat-shock genes via transposition, we have exploited a local transposition technique and Drosophila melanogaster strains with EPgy2 insertions near the Hsp70 gene cluster at 87A7 to produce numerous novel EPgy2 insertions into these Hsp70 genes. More than 50% of 45 independent insertions were made into two adjacent nucleotides in the proximal promoter at positions -96 and -97, and no insertions were into a coding or 3'-flanking sequence. All inserted transposons were in inverse orientation to the starting transposon. The frequent insertion into nucleotides -96 and -97 is consistent with the DNase hypersensitivity, absence of nucleosomes, flanking GAGA-factor-binding sites, and nucleotide sequence of this region. These experimental insertions recapitulated many of the phenotypes of natural transposition into Hsp70: reduced mRNA expression, less Hsp70 protein, and decreased inducible thermotolerance. The results suggest that the distinctive features of heat-shock promoters, which underlie the massive and rapid expression of heat-shock genes upon heat shock, also are a source of evolutionary variation on which natural selection can act.     

Differential expression of heat-shock proteins and spontaneous synthesis of HSP70 during the life cycle of Blastocladiella emersonii

The heat-shock response in Blastocladiella emersonii is dependent on the developmental stage. Cells exposed to elevated temperatures at different stages of the life cycle (sporulation, germination or growth) show a differential synthesis of heat-shock proteins (hsps). Of a total of 22 polypeptides induced, particular subsets of hsps appear in each phase, demonstrating a non-coordinate heat-shock gene expression. In contrast, heat-shock-related proteins (hsp76, hsp70, hsp39a) are spontaneously expressed at a high level during sporulation. By the criteria of two-dimensional gel electrophoresis and partial proteolysis mapping, the 70,000-Da protein, whose synthesis is induced spontaneously during sporulation, is indistinguishable from the heat-inducible hsp70. The techniques of in vitro translation, and Northern analysis using a Drosophila hsp70 probe, demonstrated that enhanced synthesis of hsp70, which occurs during heat-shock treatment and spontaneously during sporulation, is associated with an accumulation of hsp70 mRNA. These observations suggest that hsp70 gene expression is induced during sporulation.