Cloning of Hsp21 gene and its expression in Chinese shrimp Fenneropenaeus chinensis in response to WSSV challenge

In the present study, a DNA sequence encoding a small heat shock protein gene (FcHsp21) in the Chinese shrimp, Fenneropenaeus chinensis, was cloned, and its expression was analyzed after white spot syndrome virus (WSSV) infection. The FcHsp21 gene contained an open reading frame (ORF) of 555 bp in length, encoding a 184 amino acid protein with a theoretical size of about 21 kDa and a predicted isoelectric point of 5.38. The mRNA of the Hsp21 had a long Poly(A) tail (748 bp) with six polyadenylation signals (AATAA) downstream from the terminator. In addition, the gene contained a relatively long intron (507 bp), which has not been described in shrimps. The intron contained a long compound type microsatellite repeat sequence. The analysis of the phylogenetics revealed that the Hsp21 was highly conserved among the genomes of animals. Our results show that the expression modes of FcHsp21 can be changed by different WSSV infection methods. The expression of FcHsp21 was inhibited by muscle-injecting WSSV, but induced by feeding WSSV.     

Cloning and expression analysis of hsp70 gene from freshwater planarian Dugesia japonica

Heat shock protein 70 (HSP70) is an important member of the heat shock protein family. It plays a key role in the process of protecting cells by facilitating the folding of nascent peptides as well as the cellular stress response. We isolated and sequenced a full-length HSP70 cDNA from planarian Dugesia japonica (designated Djhsp70) using rapid amplification of cDNA ends (RACE). Djhsp70 cDNA is highly homologous to other reported hsp70 family genes, and the deduced amino acid sequence shares several eukaryotic HSP70 family motifs. The length of the Djhsp70 ORF from planarian genomic DNA and cDNA was identical, which indicated the absence of introns in the Djhsp70 gene. Semi-quantitative RT-PCR was employed to detect the expression levels of Djhsp70 in response to stressors. Our results indicated that Djhsp70 was an inducible gene, expressed in response to temperature changes, amputation and starvation. Interestingly, the phylogenetic analysis of DjHSP70 supports the idea that planarians belong to a new phylogenetic position — Lophotrochozoans. This is the first molecular analysis of a heat shock protein gene in planarians.     

Characterization and regulation of the major histocompatibility complex-encoded proteins Hsp70-Hom and Hsp70-1/2

Vertebrate cells contain at least 12 different genes for Hsp70 proteins, 3 of which are encoded in the major histocompatibility complex (MHC) class III region. In the human MHC, these are named Hsp70-1, -2, and -Hom. To characterize these proteins, we have determined their substrate binding specificity, their cellular and tissue distribution, and the regulation of their expression. We show for the first time (1) peptide binding specificity of Hsp70-Hom; (2) endogenous expression of Hsp70-Hom in human cell lines; (3) cytoplasmic location of Hsp70-Hom protein under basal conditions and concentration in the nucleus after heat shock; (4) unique RNA expression profiles in human tissues for each of the MHC-encoded Hsp70s, significantly different from that for the constitutive Hsc70; (5) a relative increase in levels of Hsp70-Hom protein, compared with other Hsp70s, in response to interferon gamma; and (6) a specific increase on lipopolysaccharide (LPS) treatment of in vivo messenger RNA levels for the MHC-encoded Hsp70s and the DnaJ homologue, hdj2, relative to other chaperones. The unique tissue distributions and specific up-regulation by LPS of the MHC-encoded Hsp70s suggest some specialization of functions for these members of the Hsp70 family, possibly in the inflammatory response.     

Comparative expression analysis of two paralogous Hsp70s in rainbow trout cells exposed to heat stress

Heat-shock protein 70 (Hsp70) is the major stress-inducible protein in vertebrates and highly conserved throughout evolution. To accurately investigate the mRNA expression profiles of multiple Hsp70s in rainbow trout Oncorhynchus mykiss, we isolated full-length cDNA clones encoding Hsp70 from the fish and investigated their mRNA expression profiles during heat stress. Consequently, two Hsp70s, Hsp70a and Hsp70b, were identified and found to have 98.1% identity in their deduced amino acid sequences. Southern blot analysis indicated that the two Hsp70s are encoded by distinct genes in the genome. Northern blot analysis showed that each of Hsp70a and Hsp70b expressed two mRNA species having different sizes by heat stress in rainbow trout RTG-2 cells. The induction levels of total Hsp70b mRNAs were consistently higher than Hsp70a counterparts during heat stress, although the expression profiles of the two genes were similar to each other in temperature shift and time course experiments. Interestingly, an mRNA species with a larger molecular size was expressed only under severe heat stress not less than 28 degrees C irrespective of Hsp70a and Hsp70b. These results suggest that the comprehensive identification of duplicated genes is a prerequisite to examining the gene expression profiles for tetraploid species such as rainbow trout.     

Changes in thermotolerance and Hsp70 expression with domestication in Drosophila melanogaster

To examine how the duration of laboratory domestication may affect Drosophila stocks used in studies of thermotolerance, we measured expression of the inducible heat‐shock protein Hsp70 and survival after heat shock in D. melanogaster strains recently collected from nature and maintained in laboratory culture for up to 50 or more generations. After an initial increase in both Hsp70 expression and thermotolerance immediately after transfer to laboratory medium, both traits remained fairly constant over time and variation among strains persisted through laboratory domestication. Furthermore, variation in heat tolerance and Hsp70 expression did not correlate with the length of time populations evolved in the laboratory. Therefore, while environmental variation likely contributed most to early shifts in strain tolerance and Hsp70 expression, other population parameters, for example genetic drift, inbreeding, and selection likely affected these traits little. As long as populations are maintained with large numbers of individuals, the culture of insects in the laboratory may have little effect on the tolerance of different strains to thermal stress.     

Molecular cloning and expression analysis of a cytosolic Hsp70 gene from Antarctic ice algae Chlamydomonas sp. ICE-L

A cDNA encoding heat shock protein 70 of Antarctic ice algae Chlamydomonas sp. ICE-L (designated as CiHsp70) was identified by RT-PCR and rapid amplification of cDNA ends approaches. The full-length cDNA of CiHsp70 was 2,232 bp, consisting of a 5′-terminal untranslated region (UTR) of 76 bp, a 3′-terminal UTR of 203 bp with a poly (A) tail, and an open reading frame of 1,953 bp. The CiHsp70 cDNA encoded a polypeptide of 651 amino acids with an ATPase domain of 388 amino acids, the substrate peptide binding domain of 246 amino acids and a C-terminus domain of 17 amino acids. The inducible CiHsp70 cDNA was highly homologous to other plant cytosolic Hsp70 genes and clustered together with green algae and higher plant rather than brown algae, diatom and Cryptophyta. Antarctic ice algae were treated with different stress conditions and messenger RNA (mRNA) expression levels of CiHsp70 were quantified by quantitative RT-PCR. The results showed that both cold and heat shock treatments could stimulate CiHsp70 mRNA expression. Meanwhile, CiHsp70 mRNA expression level increased 2.9-fold in response to UV-B radiation for 6 h, while the expression levels of CiHsp70 were remarkably increased after removing the UV-B radiation and immediately providing additional 6 h visible light. Furthermore, treating with 62 or 93‰ NaCl for 2 h, CiHsp70 mRNA expression level increased 3.0- and 2.1-fold, respectively. Together, our observations revealed that CiHsp70 as a molecular chaperone might play an important role in Antarctic ice algae Chlamydomonas sp. ICE-L acclimatizing to polar environment.     

Lack of an HSP70 heat shock response in two Antarctic marine invertebrates

Members of the HSP70 gene family comprising the inducible (HSP70) genes and GRP78 (glucose-regulated protein 78 kDa) were identified in an Antarctic sea star (Odontaster validus) and an Antarctic gammarid (Paraceradocus gibber). These genes were surveyed for expression levels via Q-PCR after an acute 2-hour heat shock experiment in both animals and a time course assay in O. validus. No significant up-regulation was detected for any of the genes in either of the animals during the acute heat shock. The time course experiment in O. validus produced slightly different results with an initial down regulation in these genes at 2°C, but no significant up-regulation of the genes either at 2 or 6°C. Therefore, the classical heat shock response is absent in both species. The data is discussed in the context of the organisms’ thermal tolerance and the applicability of HSP70 to monitor thermal stress in Antarctic marine organisms.     

Hsp70 genes are linked to the Xenopus major histocompatibility complex

Some of the inducible forms of the heat shock protein 70 (Hsp70) gene family are encoded in the class III region of the major histocompatibility complex (MHC) of mammals. This study was undertaken to determine whether Hsp 70 genes are linked to the MHC of Xenopus, an amphibian last sharing a common ancestor with mammals 300–350 million years ago. Segregation analyses involving seven haplotypes demonstrated the linkage of two or three inducible Hsp70 genes to the frog MHC. Another Hsp70 gene is not closely linked to the MHC. We conclude that the physical association of MHC class I and class II genes with Hsp70 genes is ancient. Correspondence to: M. F. Flajnik.     

Triggers of the HSP70 stress response: environmental responses and laboratory manipulation in an Antarctic marine invertebrate (Nacella concinna)

The Antarctic limpet, Nacella concinna, exhibits the classical heat shock response, with up-regulation of duplicated forms of the inducible heat shock protein 70 (HSP70) gene in response to experimental manipulation of seawater temperatures. However, this response only occurs in the laboratory at temperatures well in excess of any experienced in the field. Subsequent environmental sampling of inter-tidal animals also showed up-regulation of these genes, but at temperature thresholds much lower than those required to elicit a response in the laboratory. It was hypothesised that this was a reflection of the complexity of the stresses encountered in the inter-tidal region. Here, we describe a further series of experiments comprising both laboratory manipulation and environmental sampling of N. concinna. We investigate the expression of HSP70 gene family members (HSP70A, HSP70B, GRP78 and HSC70) in response to a further suite of environmental stressors: seasonal and experimental cold, freshwater, desiccation, chronic heat and periodic emersion. Lowered temperatures (−1.9°C and −1.6°C), generally produced a down-regulation of all HSP70 family members, with some up-regulation of HSC70 when emerging from the winter period and increasing sea temperatures. There was no significant response to freshwater immersion. In response to acute and chronic heat treatments plus simulated tidal cycles, the data showed a clear pattern. HSP70A showed a strong but very short-term response to heat whilst the duplicated HSP70B also showed heat to be a trigger, but had a more sustained response to complex stresses. GRP78 expression indicates that it was acting as a generalised stress response under the experimental conditions described here. HSC70 was the major chaperone invoked in response to long-term stresses of varying types. These results provide intriguing clues not only to the complexity of HSP70 gene expression in response to environmental change but also insights into the stress response of a non-model species.     

Inducible and constitutive heat shock gene expression responds to modification of Hsp70 copy number in Drosophila melanogaster but does not compensate for loss of thermotolerance in Hsp70 null flies

Background  

The heat shock protein Hsp70 promotes inducible thermotolerance in nearly every organism examined to date. Hsp70 interacts with a network of other stress-response proteins, and dissecting the relative roles of these interactions in causing thermotolerance remains difficult. Here we examine the effect of Hsp70 gene copy number modification on thermotolerance and the expression of multiple stress-response genes in Drosophila melanogaster, to determine which genes may represent mechanisms of stress tolerance independent of Hsp70.     

Molecular identification and expression of heat shock cognate 70 (hsc70) and heat shock protein 70 (hsp70) genes in the Pacific oyster Crassostrea gigas

The 70-kDa heat shock protein (Hsp) family is composed of both environmentally inducible (Hsp) and constitutively expressed (Hsc) family members. We sequenced 2 genes encoding an Hsp70 and an Hsc70 in the Pacific oyster Crassostrea gigas. The Cghsc70 gene contained introns, whereas the Cghsp70 gene did not. Moreover, the corresponding amino acid sequences of the 2 genes presented all the characteristic motifs of the Hsp70 family. We also investigated the expression of Hsp70 in tissues of oysters experimentally exposed to metal. A recombinant Hsc72 was used as an antigen to produce a polyclonal antibody to quantify soluble Hsp70 by enzyme-linked immunosorbent assay in protein samples extracted from oysters. Our results showed that metals (copper and cadmium) induced a decrease in cytosolic Hsp70 level in gills and digestive gland of oysters experimentally exposed to metal. These data suggest that metals may inhibit stress protein synthesis.     

Molecular Cloning and Analysis of a Cytosolic Hsp70 Gene from <Emphasis Type="Italic">Enteromorpha prolifera</Emphasis> (Ulvophyceae,Chlorophyta)

Heat shock protein 70 (Hsp70) is one of the important members of heat shock protein (Hsp) families and plays essential roles in folding nascent protein, translocation, refolding denatured protein, protein degradation, adverse stress resistance, and so on. In this study, homologous cloning coupled with the rapid amplification of cDNA ends was used to clone full-length cytosolic heat shock protein 70 of Enteromorpha prolifera (designed as EPHsp70). Bioinformatics was used to analyze structural feature, homologous relationship, and phylogenetic position of EPHsp70. The full length of EPHsp70 cDNA was 2,265 bp, with a 5′ untranslated region of 65 bp, a 3′ untranslated region of 217 bp, and an open-reading frame of 1,983 bp encoding a polypeptide of 660 amino acids with an estimated molecular weight of 71.39 kDa and an estimated isoelectric point of 5.03. EPHsp70 had five degenerate repeats of tetrapeptide GGMP and three typical Hsp70 signature motifs. The C-terminus amino acid sequence of cytosolic EPHsp70 was EEVD, and the conservation of EPHsp70 of N-terminus was higher than that of C-terminus. The homology between EPHsp70 and the cytosolic Hsp70s of other algae and land plants was more than 70%.