A protein antigen of Mycobacterium leprae is related to a family of small heat shock proteins.

The gene encoding an immunologically important 18-kilodalton protein antigen of Mycobacterium leprae has been sequenced, and the amino acid sequence of the antigen has been deduced. The 18-kilodalton antigen is strikingly similar in size and sequence to a family of eucaryotic heat shock proteins.     

The 14,000-molecular-weight antigen of Mycobacterium tuberculosis is related to the alpha-crystallin family of low-molecular-weight heat shock proteins.

Eight monoclonal antibodies (MAbs) directed against the 14,000-molecular-weight (14K) antigen of Mycobacterium tuberculosis reacted specifically with mycobacteria of the M. tuberculosis complex. The nucleotide sequence of the gene encoding the 14K antigen was determined by using recombinant DNA clones isolated from lambda gt11 and cosmid libraries of the M. tuberculosis genome. The DNA sequence of the 14K protein gene coded for a polypeptide of 144 amino acids with a calculated molecular mass of 16,277 Da. The 14K antigen has a marked homology with proteins belonging to the alpha-crystallin family of low-molecular-weight heat shock proteins, which includes the 18K antigen of M. leprae. The eight MAbs recognized at least four distinct epitopes localized within the following three regions of the 14K protein: amino acids 10 to 92 (MAbs F67-8 and F67-16), amino acids 41 to 92 (F159-1 and F159-11), and amino acids 41 to 144 (F23-41, F24-2, F23-49, and TB68).     

The multifunctional Drosophila melanogaster V-ATPase is encoded by a multigene family.

In animals, V-ATPases are believed to play roles in the plasma membrane, as well as endomembrane. To understand these different functions, it is necessary to adopt a genetic approach in a physiologically tractable model organism. For this purpose, Drosophila melanogaster is ideal, because of the powerful genetics associated with the organism and because of the unusually informative epithelial phenotype provided by the Malpighian tubule. Recently, the first animal "knockouts" of a V-ATPase were described in Drosophila. The resulting phenotypes have general utility for our understanding of V-ATPase function and suggest a screen for novel subunits and associated proteins. Genome project resources have accelerated our knowledge of the V-ATPase gene family size and the new Drosophila genes vhaSFD, vha100-1, vha100-2, vha100-3, vha16-2, vha16-3, vha16-4, vhaPPA1, vhaPPA2, vhaM9.7.1, and vhaM9.7.2 are described. The Drosophila V-ATPase model is thus well-suited to both forward and reverse genetic analysis of this complex multifunctional enzyme.     

A human gene family with sequence homology to Drosophila melanogaster Hsp70 heat shock genes

A growing literature describes the structure and regulation of prokaryotic and eukaryotic heat shock genes. We here report the isolation of several members of a human heat shock protein 70 (hsp 70) multigene family which contains at least 10 different genes and/or pseudogenes exhibiting sequence homology to the hsp70 gene of Drosophila melanogaster. Eight nonoverlapping recombinant lambda phages from a lambda-Charon4A human genomic library were studied by restriction mapping. One lambda clone was sequenced and characterized as a hsp70 pseudogene inserted into a rearranged human HindIII 1.9-kilobase repeated DNA sequence. This pseudogene is probably located on the X chromosome. Its predicted amino acid sequence shows extensive homology to those of Drosophila hsp70, trout hsp70, Xenopus hsp70, yeast hsp70, and some homology to the heat-inducible dnaK gene product of Escherichia coli. Amino acid homology is clustered, suggesting evolutionary conservation of domains critical to the function of this protein in both prokaryotic and eukaryotic cells.     

A heat shock protein is encoded within mitochondria of higher plants

A temperature shift from 25 to 41 degrees C initiates the synthesis of a specific set of proteins in maize, including a peptide of 60 kilodaltons. Using an in vitro mitochondrial protein synthesizing system, we provide evidence that this 60-kDa heat shock protein is encoded within the organelle. Further support for this heat-induced protein being encoded within mitochondria is that its synthesis is inhibited in whole seedlings by chloramphenicol. This 60-kDa heat shock protein is induced in all lines of maize we examined. Additionally, a heat-induced peptide of similar size (62 kDa) can be detected in isolated mitochondria of a dicot plant, Brassica campestris. The function of the heat shock protein encoded within the mitochondria remains unknown.     

Intracellular localization of heat shock proteins in Drosophila

When cells and tissues of Drosophila are subjected to elevated temperatures, the pattern of protein synthesis shifts from the production of a broad spectrum of different proteins to the vigorous production of a small number of new, heat shock proteins. The intracellular distribution of these proteins has been investigated through autoradiographic analysis of cells labeled with ³H-leucine at 25° and 37°C. After examining sections of cultured cells from D. melanogaster and polytene cells of D. virilis by electron and light microscopy, we conclude that little (if any) heat shock protein becomes associated with mitochondria, despite the many lines of evidence linking the response to respiratory stress. Confirming earlier reports on the presence of heat shock proteins in nuclei, we find the proteins are very highly concentrated there and that their transport to the nucleus occurs very rapidly. Interestingly, their free concentration in the nuclear sap is extremely low; they are, in fact, quantitatively associated with chromosomes. This association occurs in a nonrandom manner, their concentration in highly condensed chromatin being very low relative to that of other chromosomal loci.     

果蝇热激蛋白的研究进展

热休克蛋白(heat shock proteins,HSPs)是生物体受到应激刺激时诱导产生的一组保守性蛋白,普遍存在于各种生物体中。近年来,果蝇Drosophila作为生命科学与人类疾病研究的重要模式生物,其热激蛋白的研究取得了许多新的进展。文章对果蝇热激蛋白的类别、热激蛋白基因的表达调控机制、热激蛋白的分子伴侣功能、调节细胞存亡和影响发育及寿命等相关生物学功能进行综述,并对热激蛋白在神经退行性疾病治疗中的应用前景作展望。     

Ancient heat shock gene is dispensable.

Hsp83 is a major eucaryotic heat shock protein and one of the most conserved proteins known. We have isolated an Escherichia coli gene homologous to eucaryotic Hsp83 and used it to construct a deletion mutation. The E. coli mutant was viable but had a slight growth disadvantage that increased with temperature.     

CD14 is a member of the family of leucine-rich proteins and is encoded by a gene syntenic with multiple receptor genes.

We have isolated and characterized genomic and cDNA clones encoding the murine homolog of the human monocyte/granulocyte cell surface glycoprotein, CD14. As in man, the expression of murine CD14 is limited to the myeloid lineage. The murine and human CD14 genes are highly conserved in their intron-exon organization and nucleotide sequence. Their deduced protein sequences show 66% amino acid identity. In both mouse and man, the CD14 protein contains a repeating (10 times) leucine-rich motif (LXXLXLX) that is also found in a group of heterogeneous proteins from phylogenetically distant species. The CD14 gene has been mapped to mouse chromosome 18 which also contains at least five genes encoding receptors (Pdgfr, Adrb2r, li, Grl-1, Fms). Thus CD14 and the receptor genes form a conserved syntenic group localized on mouse chromosome 18 and human chromosome 5. The inclusion of CD14 in the family of leucine-rich proteins, its expression profile and the murine chromosomal localization support the hypothesis that CD14 may function as a receptor.     

Analysis of the expression of the two major proteins of the 70 kilodalton mammalian heat shock family

This study compares the expression after heat shock of the two major variants of the mammalian 70 kilodalton heat shock family in three separate systems. The ability of wild type and temperature sensitive mutant (ts85) FM3A cells to elicit a heat shock response following a 45 degrees C, 12 min exposure was examined. The ts85 cells were found to be both significantly more thermosensitive than parent FM3A cells and to induce a 66kDa heat shock protein (hsp66) not visibly synthesized in the parent line by this exposure. However, a constitutive (synthesized at 37 degrees C) 68kDa heat shock protein (hsp68) is comparably induced in both cell lines after heat. A relationship between the severity of the heat exposure as seen by the cell and hsp66 expression is suggested and tested in Chinese hamster ovary cells. In CHO cells a brief 45 degrees C heat shock induces the constitutive hsp68 (but not hsp66), while longer and more severe exposures are required for the expression of hsp66. The induction of these two proteins is also examined in situ in mouse skeletal muscle. In this case both hsp66 and hsp68 are induced following comparatively mild heat treatments, and the 'threshold' for hsp66 induction observed in cultured cells either does not occur or is greatly reduced. However, once again, hsp68 is naturally synthesized at 37 degrees C while hsp66 appears to be de novo synthesized after heat shock.     

Synthesis of heat shock proteins in Drosophila melanogaster embryos

The pattern of polypeptides synthesized in a cell-free protein synthesizing system containing polysomes isolated from heat-shocked (37 C) Drosophila embryos showed significant differences when compared with the pattern obtained when polysomes from normal embryos were used. The synthesis of normal embryonal proteins was reduced and the heat shock proteins were the major products of elongation. After short, 10 min, heat treatment mainly quantitative changes were observed suggesting that normal mRNAs were still present on polysomes, and their products could be completed in vitro in the heterologous cell-free system. The mRNAs coding for normal embryonal proteins were present in almost unchanged amounts in heat-shocked embryos as could be judged from the pattern of proteins synthesized in heterologous cell-free system supplemented with cytoplasmic RNA from normal and heat-shocked embryos. Thus the change in protein synthesis in heat-shocked embryos is not associated with degradation of normal embryonal mRNAs but with their inaccessibility for translation.