Molecular cloning of cDNA for rat mitochondrial 3-oxoacyl-CoA thiolase

Messenger RNA of rat 3-oxoacyl-CoA thiolase (acetyl-CoA acyltransferase), a mitochondrial matrix enzyme involved in fatty acid beta-oxidation, was enriched by immunoprecipitation of rat liver free polysomes and recombinant plasmids were prepared from the enriched mRNA by a modification of the vector-primer method of Okayama and Berg. The transformants were initially screened for 3-oxoacyl-CoA thiolase cDNA sequences by differential colony hybridization with [32P]cDNAs, synthesized from the immunopurified and unpurified mRNAs. The cDNA clones for 3-oxoacyl-CoA thiolase were identified by hybrid-arrested translation and hybrid-selected translation. One of the clones, designated pT1-1, contained a 700-base insert and hybridized to a mRNA species of 1.6 X 10(3) bases in rat liver. The transformants were rescreened using the cDNA insert of pT1-1 as a hybridization probe and a clone (pT1-19) with a 1.5 X 10(3)-base insert was obtained. Activity and concentration of 3-oxoacyl-CoA thiolase mRNA were quantified by in vitro translation and dot-blot analysis using the cDNA insert as a hybridization probe. The level of translatable and hybridizable mRNA in rat liver was increased about 5.1-fold and 4.6-fold, respectively, after administration of di-(2-ethylhexyl)phthalate, a potent inducer of the enzyme. The 3-oxoacyl-CoA thiolase mRNA levels thus determined correlated closely with levels of the activity and amount of this enzyme.     

Expression of the Tribolium castaneum （Coleoptera： Tenebrionidae） hsp83 gene and its relation to oogenesis during ovarian maturation

Heat shock proteins (HSP) can protect organisms and cells from thermal damage. In this study, we cloned the full length cDNA encoding the HSP83 protein (the homologue of HSP90) of Tribolium castaneum (red flour beetle). The isolated cDNA contains the full coding sequence, a partial 5′ untranslated region of 55 bp and the complete 3′ untranslated region. We found the hsp83 gene is located on chromosome 5 of the T. castaneum genome. The predicted HSP83 protein sequence has a high similarity (on average 86.77%) with that of other insect species. The expression of the hsp83 gene in the whole body and in the ovary could be induced with heat stress (40°C for 1 h) in newly hatched (within 3 h post emergence) and mature (10 days post emergence) beetles. Under normal conditions, the hsp83 expression in the ovary is about 3-fold higher than in the whole body at both stages. No significant difference in hsp83 expression was observed between the two ovarian developmental stages regardless if the beetles were treated with heat shock or not. The expression of the HSP83 protein in the whole body could also be induced with heat stress in newly hatched and mature beetles. However, in the ovary, HSP83 was only expressed in the follicle cells of mature beetles and not in newly hatched beetles, regardless if the beetles were treated with heat shock or not. Furthermore, the females were not able to produce mature oocytes after knock-down of the hsp83 expression by injecting dsRNA. These results suggest that the HSP83 protein is involved in protection against heat stress and could be involved in oogenesis during ovarian maturation of T. castaneum.     

Regulation of HSP70 synthesis by messenger RNA degradation.

When Drosophila cells are heat shocked, hsp70 messenger RNA (mRNA) is stable and is translated at high efficiencies. During recovery from heat shock, hsp70 synthesis is repressed and its messenger RNA (mRNA) is degraded in a highly regulated fashion. Dramatic differences in the timing of repression and degradation are observed after heat treatments of different severities. The 3' untranslated region (UTR) of the hsp70 mRNA was sufficient to transfer this regulated degradation to heterologous mRNAs. Altering the translational efficiency of the message or changing its natural translation-termination site did not alter its pattern of regulation, although in some cases it changed the absolute rate of degradation. We have previously shown that hsp70 mRNA is very unstable when it is expressed at normal growth temperatures (from a metallothionein promoter). We report here that the 3' untranslated region of the hsp70 mRNA is responsible for this instability as well. We postulate that a mechanism for degrading hsp70 mRNA pre-exists in Drosophila cells, that it is inactivated by heat shock and that it is the reactivation of this mechanism that is responsible for hsp70 repression during recovery. This degradation system may be the same as that used by other unstable mRNAs.     

70-Kilodalton heat shock polypeptides from rainbow trout: characterization of cDNA sequences.

RTG-2 cells, a line of fibroblasts from rainbow trout (Salmo gairdnerii), are induced to synthesize a distinct set of heat-shock polypeptides after exposure to elevated temperature or to low concentrations of sodium arsenite. We isolated and characterized two cDNA sequences, THS70.7 and THS70.14, encoding partial information for two distinct species of 70-kilodalton heat shock polypeptide (hsp70) from these cells. These sequences are identical at 73.3% of the nucleotide positions in their regions of overlap, and their degree of sequence conservation at the polypeptide level is 88.1%. The two derived trout hsp70 polypeptide sequences show extensive homology with derived amino acid sequences for hsp70 polypeptides from Drosophila melanogaster and Saccharomyces cerevisiae. Northern blot analysis of RNA from arsenite-induced RTG-2 cells, with the trout hsp70 cDNAs as probes, revealed the presence of three hsp70 mRNA species. Southern blot analysis of trout testis DNA cleaved with various restriction endonucleases revealed a small number of bands hybridizing to the hsp70 cDNAs, suggesting the existence of a small family of hsp70 genes in this species. Finally, trout hsp70 cDNA sequences cross-hybridized with restriction fragments in genomic DNA from HeLa cells, bovine liver, Caenorhabditis elegans, and D. melanogaster.     

Isolation of major heat shock protein (hsp70) gene-related sequences from rat genome

Rat genome was assayed for the presence of hsp70 gene-related sequences. Southern blots prepared from rat DNA digested with EcoRI or HindIII restriction endonucleases were hybridized with mouse, human and fruit fly hsp 70 gene probes at increasing stringencies. At the stringency which allows sequences divergent up to about 30% to form stable complexes all three probes detected 25–30 restriction fragments. Increased stringency of the hybridization reduced the number of detectable bands to a few and among them the DNA fragments hybridizing specifically either with mouse or human hsp70 gene probes were detected. Most of the genomic fragments containing hsp70 gene-related sequences were subsequently isolated by screening the rat genomic library with mouse hsp70 gene probe. 168 positive clones were plaque purified and on the basis of the restriction and hybridization pattern we deduced that inserts represented 20 different genomic regions. Partial restriction maps of all isolated genomic fragments were constructed and regions containing hsp70 gene related as well as highly repetitive DNA sequences were localized. A putative sequence rearrangement in the proximity of the hsp70 gene-related sequence was detected in one of the isolated genomic segments.     

Selective postmortem degradation of inducible heat shock protein 70 (hsp70) mRNAs in rat Brain

Summary 1. Altered mRNA levels in postmortem brain tissue from persons with Alzheimer's disease (AD) or other neurological diseases are usually presumed to be characteristic of the disease state, even though both agonal state (the physiological state immediately premortem) and postmortem interval (PMI) (the time between death and harvesting the tissue) have the potential to affect levels of mRNAs measured in postmortem tissue. Although the possible effect of postmortem interval on mRNA levels has been more carefully evaluated than that of agonal state, many studies assume that all mRNAs have similar rates of degradation postmortem.2. To determine the postmortem stability of inducible heat shock protein 70 (hsp70) mRNAs, themselves unstablein vivo at normal body temperature, rats were heat shocked in order to induce synthesis of the hsp70 mRNAs. hsp70 mRNA levels in cerebellum and cortex were then compared to those of their heat shock cognate 70 (hsc70) mRNAs, as well as to levels of 18S rRNAs, at 0 and at 24 hr postmortem.3. Quantiation of northern blots after hybridization with an hsp70 mRNA-specific oligo probe indicated a massive loss of hsp70 mRNA signal in RNAs isolated from 24-hr postmortem brains; quantitation by slot-blot hybridization was 5- to 15-fold more efficient. Even using the latter technique, hsp70 mRNA levels were reduced by 59% in 24-hr-postmortem cerebellum and by 78% in cortex compared to mRNA levels in the same region of 0-hr-postmortem brain. There was little reduction postmortem in levels of the hsp70 mRNAs or of 18S rRNAs in either brain region.4.In situ hybridization analysis indicated that hsp70 mRNAs were less abundant in all major classes of cerebellar cells after 24 hr postmortem and mRNAs had degraded severalfold more rapidly in neurons than in glia. There was no corresponding loss of intracellular 18S rRNA in any cell type.5. We conclude from these results that the effect of postmortem interval on mRNA degradation must be carefully evaluated when analyzing levels of inducible hsp70 mRNAs, and perhaps other short-lived mRNAs, in human brain.     

An improved Escherichia coli expression vector for the construction and identification of full-length cDNA clones

An Escherichia coli expression vector designed for the efficient synthesis and identification of a full-length cDNA clone is constructed. The vector allows the synthesis of double-stranded cDNAs downstream from the tandem lac control regions employing the vector-primer and linker procedure of Okayama and Berg [Mol. Cell Biol. 2 (1982) 161-170]. Full-length cDNA clones carrying the 5'-noncoding region in addition to the entire coding and 3'-noncoding regions can be expressed in E. coli cells without fusing their coding region to that of E. coli proteins; these clones are identified by colony immunoassay. The entire cDNA insert can be easily excised from the plasmid, since the multiple cloning sites in the vector are duplicated at both ends of the cDNA insert during its synthesis.     

Murine 86- and 84-kDa heat shock proteins, cDNA sequences, chromosome assignments, and evolutionary origins

The two forms of the approximately 90-kDa murine heat shock protein, referred to as HSP86 and HSP84, are coded for by separate but related genes. A full-length nucleotide sequence of the cDNA coding for HSP86 from a chemically induced tumor, Meth A, was determined. Sequences from a number of peptides from HSP86 were found to be in complete agreement with the nucleotide sequence. The HSP84 sequence from the same tumor was also completed. HSP86 and HSP84 are acidic polypeptides 733 and 724 amino acids long with calculated molecular weights of 84,796 and 83,290, respectively. The two proteins are 86% homologous. HSP86 was found to contain internal peptide repeats of Glu-Lys-Glu within a region of highly charged amino acid residues. The coding regions of the cDNAs were 76% homologous; however, this homology did not extend to the 5'- and 3'-untranslated regions. The 5'-untranslated region of hsp86 cDNA was considerably longer than that of hsp84 cDNA and, unlike that of hsp84, contained extraneous ATG triplets. Hsp86-related sequences were assigned to chromosomes 12, 11, and 3. An evolutionary tree constructed from HSP90-related protein sequences indicated that HSP86 and HSP84 were likely to have diverged more than 500 million years ago. The findings presented herein suggest that HSP86 and HSP84 may have different functions.     

Heat and sodium arsenite act synergistically on the induction of heat shock gene expression in Xenopus laevis A6 cells

Heat shock protein (HSP) synthesis was studied in the Xenopus epithelial cell line A6 in response to heat and sodium arsenite, either singly or together. Temperatures of 33-35 degrees C consistently brought about the synthesis of HSPs at 87, 73, 70, 54, 31, and 30 kilodaltons (kDa), whereas sodium arsenite at 25-100 microM induced the synthesis of HSPs at 73 and 70 kDa. In cultures exposed to 10 microM sodium arsenite at 30 degrees C, HSP synthesis in the 68- to 73-kDa and 29- to 31-kDa regions was much greater than the HSP synthesis in response to each treatment individually. RNA dot blot analysis using homologous genomic subclones revealed that heat shock induced the accumulation of HSP 70 and 30 mRNAs. The sizes of the HSP 70 and 30 mRNAs determined by Northern hybridization were 2.7 and 1.5 kilobases, respectively. Sodium arsenite (10-100 microM) also induced the accumulation of both HSP 70 and 30 mRNAs. Finally, a mild heat shock (30 degrees C) plus a low concentration of sodium arsenite (10 microM) acted synergistically on HSP 70 and 30 mRNA accumulation in A6 cells. Thus sodium arsenite and heat act synergistically at the level of both HSP synthesis and HSP mRNA accumulation.     

Molecular cloning of sequences encoding the human heat-shock proteins and their expression during hyperthermia

Plasmids containing cDNA copies of mRNAs induced in HeLa cells by heat shock have been isolated and characterized. In vitro translation of RNAs selected by hybridization to plasmid DNAs identified sequences representing the three major classes (89, 70 and 27-kDa) of heat-shock proteins (hsp) and a 60-kDa minor hsp. Plasmids with inserts specific for the 27, 60, and 70-kDa hsp each hybridize with a single discrete size class of heat-inducible mRNA. Plasmids specific for the 89-kDa protein, however, hybridize with either a 2.7- or 2.95-kb mRNA species. Both mRNAs are coordinately induced during heat shock. We show that the characteristic pattern of induction and repression of each class of hsp during sustained hyperthermia is the result of changes in the steady state level of each mRNA.     

Direct immunological identification of full-length cDNA clones for plant protein without gene fusion to E. coli protein

By immunological screening of a cDNA library constructed from potato tuber poly(A)+ RNA and Escherichia coli expression vector pUC8 by the vector-primer and linker procedure of Okayama and Berg [(1982) Mol. Cell Biol. 2, 161-170], nearly full-length cDNA clones for patatin, a major protein of potato tuber, were identified. The cDNA carrying part of the 5'-noncoding region of the patatin mRNA, in addition to entire coding and 3'-noncoding regions, expressed prepatatin in E. coli cells by translational initiation inside cDNA. These results suggest that nearly full-length cDNA clones with entire coding region can be identified directly by immunological screening without gene fusion to E. coli proteins at least for some plant mRNAs.