Sequence and immunogenicity of the 70-kDa heat shock protein of Mycobacterium leprae

The gene encoding the Mycobacterium leprae 70-kDa heat shock protein has been isolated from a cosmid library using a fragment of the clone JKL2. Southern blot analysis of a positive clone identified a 4.4-kb fragment containing the entire coding region of the gene plus 2.4 kb upstream. Sequencing revealed the gene to encode a 621-amino acid protein, bearing 56% identity with the Escherichia coli dnaK gene product and 47% and 46% identity with the human and Caenorhabditis elegans hsp70, respectively. Comparison with the C-terminal 203 amino acids of the Mycobacterium tuberculosis 71-kDa Ag yielded 70% identity. Recombinant M. leprae p70 was produced in E. coli as a fusion protein (rp70f) with a portion of the schistosomal glutathione-S-transferase, using the expression vector, pGEX-2T. Cleavage with thrombin resulted in the release of a 70.0-kDa protein (rp70c) from the glutathione-S-transferase. Examination of the proteins by immunoblotting demonstrated that anti-M. leprae mAb, L7, and sera from lepromatous leprosy patients bound to both the cleaved and fusion proteins. We compared the T cell reactivity of the M. leprae recombinant proteins with that of mAb affinity-purified bacille Calmette-Guerin (BCG) 70-kDa Ag using proliferation assays. PBMC of BCG vaccinees responded to both M. leprae cleaved and fusion p70, though more subjects responded to the rp70c (18 of 20) than to rp70f (13 of 20). Responses were generally higher to rp70c than to rp70f, however all responses to the M. leprae recombinant proteins were lower than to mAb affinity-purified BCG p70. Thus, the M. leprae 70-kDa heat shock protein elicits T and B cell responses in subjects exposed to mycobacteria, despite its homology with the human hsp70.     

Mycobacterium leprae-specific T cells from a tuberculoid leprosy patient suppress HLA-DR3-restricted T cell responses to an immunodominant epitope on 65-kDa hsp of mycobacteria.

The polar tuberculoid type (TT) of leprosy, characterized by high T cell reactivity to Mycobacterium leprae, is associated with HLA-DR3. Surprisingly, DR3-restricted low T cell responsiveness to M. leprae was found in HLA-DR3-positive TT leprosy patients. This low responsiveness was specifically induced by M. leprae but not by M. tuberculosis and was seen only in patients and not in healthy controls. We studied this patient-specific, M. leprae-induced, DR3-restricted low T cell responsiveness in depth in one representative HLA-DR3-positive TT leprosy patient by using T cell clones. From this patient two types of T cell clones were obtained: one type was cross-reactive with M. tuberculosis and recognized an immunodominant epitope (amino acids 3 to 13) on the 65-kDa heat shock protein (hsp) the other type was M. leprae specific and reacted to a protein other than the 65-kDa one. To examine whether these M. leprae-specific T cell clones were responsible for the DR3-restricted low responsiveness to M. leprae, we tested them for the ability to suppress the proliferation of the DR3-restricted, 65-kDa, hsp-reactive clones. The DR3-restricted, M. leprae-specific T cells completely suppressed the proliferative responses of DR3-restricted, cross-reactive T cell clones to the 65-kDa hsp from the same patient as well as from other individuals. Also, DR3-restricted responses to an irrelevant Ag were suppressed by the M. leprae-specific T cell clones. However, no suppression of non-DR3-restricted T cell responses was seen. Although the mechanism must still be elucidated, this M. leprae-induced, DR3-restricted immunosuppression may at least partly explain the observed DR3-associated low T cell responsiveness in TT leprosy patients.     

The antibody repertoire to proteins of Mycobacterium leprae. Genetic influences at the antigen and epitope level.

The effects of both H-2 and non-H-2 genes on the antibody response to the proteins of Mycobacterium leprae were investigated. Using a B10 series of congenic mice we found that the repertoire of antibody responses was under H-2 gene control, and that non-H2 genes were also involved. By Western blotting, differences in the number and m.w. of proteins recognised by mice of different genetic background were apparent. Such differences were also reflected in the total antibody response to a soluble extract of M. leprae (M. leprae sonicate), as measured by ELISA. Concentrating on one particular Ag, the 65-kDa heat shock protein, we found that all strains of mice developed antibodies following immunization with the purified recombinant protein, although there was a continuous distribution in the titer of antibodies obtained, with differences between individual strains indicating both H-2 and non-H-2 effects. Using a library of overlapping peptides based on the amino acid sequence of this protein, we have mapped the B cell epitopes in the different strains of mice. H-2 genes had no effect on the structure and number of epitopes recognized, although this was influenced by non-H-2 genes. There was a high level of concordance between actual epitopes recognized and those predicted by calculations of antigenic index, and B cell epitopes were located in similar positions to previously determined T cell epitopes.     

Natural killer cell clones can efficiently process and present protein antigens.

NK cell clones obtained from three different donors were tested for their ability to present soluble proteins to Ag-specific T cell clones. All NK clones were CD2+CD3-CD56+, whereas the expression of CD16 varied from clone to clone. The NK cell clones were able to process and present tetanus toxoid (TT) to TT-specific T cell clones in a class II HLA restricted manner. The capacity of NK cell clones to function as APC was also observed using the house dust mite allergen Der p I and the Der p I-derived peptide Val89-Cys117. As with EBV-transformed B cell line, NK cell clones could present the peptide 3-13 derived from the 65-kDa heat shock protein of Mycobacterium leprae, but they were unable to present the whole M. leprae Ag. Freshly isolated NK cells, IL-2-activated NK cells, and NK cell lines expanded in vitro could also process and present TT. The ability of the different NK populations to act as accessory cells correlated with their levels of class II HLA expression. These data demonstrate that NK cell clones can efficiently function as APC, however they may be restricted in the types of Ag that they can process.     

The mapping of epitopes of the 18-kDa protein of Mycobacterium leprae recognized by murine T cells in a proliferation assay

The 18-kDa protein of Mycobacterium leprae was purified from recombinant plasmids pUL108 and pML-3 grown in Saccharomyces cerevisiae and Escherichia coli, respectively. Significant lymphoproliferative responses were observed when T cells from immunized mice were challenged in culture with purified 18-kDa protein. Synthetic peptides have been prepared that span most of the 148 amino acid residues that constitute the sequence of the 18-kDa protein and used to map epitopes recognized by T cells. When mice were immunized with 18-kDa protein and lymph node cells subsequently prepared and challenged in microculture proliferative assays by using synthetic peptides, only one region of the intact protein appeared stimulatory. This T cell epitope was located between residues 116 and 121, adjacent to an epitope between residues 110 and 115 which we have previously shown to bind the L5 mAb. Immunization of mice with peptides, and subsequent challenge of lymph node cells in assays by using the 18-kDa protein as Ag revealed that residues 111-125 were the most effective in priming responses. Furthermore, the ability of 18-kDa primed lymph node cells to recognize determinants on both M. leprae and Mycobacterium tuberculosis indicates that in addition to possessing an M. leprae-specific B cell determinant, the 18-kDa protein contains a cross-reactive T cell epitope(s).     

A systematic molecular analysis of the T cell-stimulating antigens from Mycobacterium leprae with T cell clones of leprosy patients. Identification of a novel M. leprae HSP 70 fragment by M. leprae-specific T cells

Both protective immunity and immunopathology induced by mycobacteria are dependent on Ag-specific, CD4+ MHC class II-restricted T lymphocytes. The identification of Ag recognized by T cells is fundamental to the understanding of protective and pathologic immunity as well as to the design of effective immunoprophylaxis and immunotherapy strategies. Although some T cell clones are known to respond to recombinant mycobacterial heat shock proteins (hsp) like hsp3 65, the specificity of most T cells has remained unknown. We therefore have undertaken a specificity analysis of 48 well defined Mycobacterium leprae- and/or Mycobacterium tuberculosis-reactive (Th-1-like) T cell clones. Most clones (n = 44) were derived from different leprosy patients, and the remainder from one healthy control. Their HLA restriction molecules were DR2, DR3, DR4, DR5, DR7, DQ, or DP. T cell clones were stimulated with large numbers (n = 20 to 40) of mycobacterial SDS-PAGE-separated fractions bound to nitrocellulose. Each clone recognized a single fraction or peak with a particular Mr range. Some of the clones (n = 7) recognized the fraction that contained the hsp 65 as confirmed with the recombinant Ag. Most clones (n = 41), however, responded to Ag other than the hsp 65. Nine clones responded to a 67- to 80-kDa fraction. Five of them responded also to an ATP-purified, 70-kDa M. leprae protein, but only one of these five (that was HLA-DR2 restricted and cross-reactive with M. tuberculosis) recognized the recombinant C-terminal half (amino acids 278-621) of the M. leprae hsp 70 molecule and also recognized the recombinant M. tuberculosis hsp 70. We therefore have used the 5' part of the M. leprae hsp 70 gene that we have cloned recently. This fragment (that encodes amino acids 6-279) was indeed recognized by the other four M. leprae-specific T cells that were all HLA-DR3 restricted and did not cross-react with the highly homologous (95%) M. tuberculosis hsp 70. These results suggest that this novel fragment is a relevant T cell-stimulating Ag for leprosy patients. A panel of other recombinant Ag, including hsp 18 was tested. The majority of T cell clones appeared to recognize antigenic fractions distinct from hsp. In conclusion, T cells of leprosy patients see a large variety of different Ag including non-hsp, and one newly recognized moiety is the N-terminal M. leprae hsp 70 fragment.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization of Mycobacterium leprae cell wall-associated proteins with the use of T lymphocyte clones

Development of a vaccine against leprosy depends on the identification of Ag that stimulate cell-mediated immune responses. We have previously demonstrated that cell wall proteins of Mycobacterium leprae are highly immunogenic. By using human cell wall-specific T cell clones we have begun to characterize soluble proteins that integrate into the cell wall skeleton. T cells from leprosy lesions were expanded with IL-2 in vitro yet retained specificity to Ag of the insoluble cell wall core (CWC) in vitro, indicating that T cells had been activated by CWC Ag in vivo. A cell wall protein-peptidoglycan complex and cell wall protein preparations lacking carbohydrates and lipids from CWC retained T cell reactivity. To identify immunogenic protein component(s) of cell wall protein, T cell lines were established to cell walls and tested against M. leprae proteins separated by SDS-PAGE and transferred to nitrocellulose. Greatest T cell reactivity was observed to proteins of Mr 7 kDa, 16 kDa, and 28 kDa. T cell clones reactive with 7-kDa and 16-kDa Ag from gels failed to respond to proteins of other Mr separated under either reducing or nonreducing conditions, indicating that these molecules are not subunits of larger proteins and may represent monomeric units polymerized into cell walls. The approaches described herein for characterization of immunodominant T cell Ag of M. leprae may be useful for study of T cell Ag in cell walls of bacterial pathogens of man.     

Expression profiles of low molecular mass heat shock proteins by Mycobacterium avium and Mycobacterium intracellulare

Closely related non-tuberculous mycobacterial species, Mycobacterium avium and Mycobacterium intracellulare, were compared for the profiles of their production of low molecular mass heat shock proteins at 45 degrees C, by performing polyacrylamide gel electrophoresis analysis of bacterial cell lysate proteins. All of the M. intracellulare but not M. avium strains potently increased the production of the 18-kDa heat shock protein, when cultured at 45 degrees C. Half of the M. intracellulare strains with high sensitivity to 45 degrees C produced not only the 18-kDa heat shock protein but also the 16-kDa heat shock protein at 45 degrees C. These findings indicate that M. avium and M. intracellulare differentially respond to 45 degrees C heat shock in terms of the production of low molecular mass heat shock proteins.     

Characterization of an antibody-binding epitope from the 18-kDa protein on Mycobacterium leprae

A murine mAb, designated L5, appears to be specific for an epitope on a protein from Mycobacterium leprae of restricted distribution within the mycobacteria. This protein, of Mr 18,000 (18 kDa) is of interest because monoclonal antibodies raised against it do not appear to cross-react with other mycobacterial pathogens. The L5 antibody-binding epitope has been mapped by two complementary methods; expression of gene fragments and synthesis of short peptides. This L5-binding region of the 18-kDa protein (amino acids 109 to 115) shows some homology to a region of the GroEL heat shock family of proteins. Characterization of this antibody-binding epitope may lead to a reagent of use in early diagnosis of infection.     

Characterization of T cell antigens associated with the cell wall protein-peptidoglycan complex of Mycobacterium tuberculosis

Mycobacterium tuberculosis cell walls are likely to contain critical T cell Ag capable of inducing protective immunity against the development of tuberculosis in animal models. Therefore, we characterized cell wall-associated Ag that stimulate T lymphocytes in tuberculosis patients and clinically well tuberculin-positive individuals. A protein-peptidoglycan complex isolated from the M. tuberculosis cell wall had potent immunologic activity, evoking PBMC proliferative responses similar to those induced by sonicated whole M. tuberculosis. In order to characterize the immunoreactive protein determinants associated with the protein-peptidoglycan complex, T cell lines were established to cell wall Ag and used to probe M. tuberculosis proteins separated by SDS-PAGE. These T cell lines proliferated primarily to protein Ag of 10, 19, 23, 28, 30, 40 to 50, and 65 kDa. Cell wall-reactive T cell clones that recognized the 10-, 23-, 28-, and 30-kDa proteins as single bands on SDS-PAGE did so under reducing and nonreducing conditions, suggesting that these are not proteolytic fragments or subunits of larger protein aggregates. We propose that these protein monomers, when post-translationally complexed with peptidoglycan, are the key ingredients of the immunogenic protein-peptidoglycan complex. In order to assess the relationship of the cell wall-associated Ag to those secreted proteins from "early culture filtrates" of actively growing M. tuberculosis recently implicated in eliciting protective immunity, cell wall-reactive T cell clones were tested for their ability to recognize early culture filtrates. Results revealed that at least three proteins shared with the cell wall complex are contained within early culture filtrates. Our data indicate that antigenic determinants associated with the protein-peptidoglycan complex of the M. tuberculosis cell wall may be involved in protective immunity and hence are potential candidates for inclusion in an effective antituberculosis vaccine.     

Patterns of protein synthesis in various cells after extreme heat shock

The analysis of proteins synthesized in rat thymocytes and mouse teratocarcinoma PCC-4 Aza 1 and myeloma Sp2/0 cells after 1 h of treatment at 42 or 44 degrees C was carried out. Shock at 42 degrees C reduced the total synthetic rate of proteins in all three cell lines and induced "classical" heat-shock protein with a mass of 70 kDa (hsp 70). Heat shock at 44 degrees C resulted in almost complete inhibition of protein synthesis; only a small amount of hsp 70 was synthesized. Meanwhile a new 48-kDa polypeptide (pI = 7.5) was found in the cells exposed to severe heat shock. This protein was compared by peptide mapping with other known polypeptides of the same size: heat-shock protein from chicken embryo cells and mitogen-stimulated polypeptide from human lymphoid cells. The peptide maps were not identical. It was also shown that after a shock at 44 degrees C teratocarcinoma cells were able to accumulate anomalous amounts of hsp 70 despite hsp 70 synthesis inhibition. The data show that reaction of various cells to extreme heat shock depends heavily on cell type.     

Heat shock response in mycoplasmas, genome-limited organisms.

We have measured the effect of heat shock on three mycoplasmas (Acholeplasma laidlawii K2 and JA1 and Mycoplasma capricolum Kid) and demonstrated the induction of mycoplasma heat shock proteins under these conditions. Increased synthesis of at least 5 heat shock proteins in A. laidlawii K2, 11 heat shock proteins in A. laidlawii JA1, and 7 heat shock proteins in M. capricolum was observed by electrophoretic analysis of proteins from heat-shocked cells in sodium dodecyl sulfate-polyacrylamide gels. In all three strains, major heat shock proteins (66 to 68 and 26 to 29 kilodaltons [kDa]) were found. The 66- to 68-kDa protein cross-reacted with antibody to Escherichia coli DnaK protein, suggesting that this heat shock protein has been conserved in spite of major reductions in genetic complexity during mycoplasma evolution. A. laidlawii also contained a 60-kDa protein that cross-reacted with eubacterial GroEL protein and a 40-kDa protein that cross-reacted with E. coli RecA protein. Unlike with coliphages, the mycoplasma virus L2 progeny yield was not increased when virus was plated on heat-shocked A. laidlawii host cells. However, UV-irradiated L2 virus could be host cell reactivated by both A. laidlawii SOS repair and heat shock systems.     

Biochemical analysis of two cell surface glycoprotein complexes, very common antigen 1 and very common antigen 2. Relationship to very late activation T cell antigens

Two mouse monoclonal antibodies (mAb), AJ2 and J143, define two related human cell surface protein complexes, very common antigen 1 (VCA-1) and very common antigen 2 (VCA-2). In the present report, these complexes have been defined with respect to: (i) subunit arrangement; (ii) monoclonal antibody binding sites; (iii) carbohydrate content; (iv) homology to other cell surface protein complexes; and (v) possible functional roles. Analysis of the antigens from a human melanoma cell line, MeWo, reveals that VCA-1 is a noncovalently linked heterodimer of 170- and 140 (designated 1401)-kDa polypeptides. mAb AJ2 reacts with an epitope on the 1401-kDa polypeptide. VCA-2 is composed of the same 1401-kDa polypeptide as VCA-1 and another 170-kDa species; this 170-kDa species consists of a second distinct 140-kDa (designated 140(2)) and a 30-kDa polypeptide which are disulfide-bonded. Indirect evidence indicates that mAb J143 reacts with an epitope on this 170-kDa complex. Peptide mapping has shown that the complexes are members of a family of cell surface proteins that include antigens present on activated T cells (designated very late activation antigens). Since VCA-2 is found predominantly on the basal membrane of adherent cells and its expression increases 12-fold when HUT-102 lymphoblastoid cells are grown as an adherent cell culture, we suggest that VCA-2 plays a role in cellular adherence.     

Synthesis of shock proteins in cultured fetal mouse myocardial cells

We examined the synthesis of shock proteins in cultured fetal mouse myocytes. The preparation is free from fibroblasts, and the cells are vital and morphologically intact with respect to beat frequency and electron microscopy. Cultured myocytes from fetal mouse heart respond to heat shock and cadmium chloride, H2O2, allylamine, cyclosporine, and azathioprine exposure with the synthesis of shock proteins. Heat shock induces the de novo synthesis of two proteins of 71 and 68 kDa; cadmium chloride induces, in addition, a protein of 30 kDa. The other substances tested provoke the synthesis only of the 30-kDa polypeptide. The formation of heat shock proteins is concentration-dependent: Cyclosporine provokes the de novo synthesis of the 30-kDa polypeptide at concentrations above 10 ng/ml, whereas azathioprine causes the same effect at concentrations above 50 micrograms/ml. Hence cyclosporine might be cardiotoxic already at concentrations below the pharmacological dosages while azathioprine influences the myocytes only at concentrations much higher than the therapeutic level. Our results indicate that heat shock protein expression in cultured myocytes may be a useful tool to monitor cardiotoxicity.     

Development of monoclonal antibodies reacting against mycobacterial 65 kDa heat shock protein by using recombinant truncated products.

A mycobacterial 65 kDa molecule is a member of the GroEL heat shock protein family. We developed mAbs reacting against recombinant 65 kDa protein by using a gene (pTB12) which encodes this protein. Three mAbs (B20, B97 and B167) reacted selectively with 65 kDa proteins of Mycobacterium tuberculosis, BCG and Mycobacterium leprae, although B20 and B167 may weakly react with a 15 kDa molecule of mammalian cells. One (B108) was obviously cross-reactive between mycobacterial 65 kDa and the mammalian intracytoplasmic protein. We also developed deletion mutants of pTB12. The localization of these mAb-defined epitopes was determined by using truncated proteins of the Mycobacterium tuberculosis 65 kDa molecule produced in E. coli. Immunohistochemical analysis showed that B20, B97 and B167 mAbs could detect this antigen in experimental granulomas induced by injection of BCG in the subcutaneous tissue of rats. These mAbs should be useful for analyzing the immunobiologic roles of mycobacterial 65 kDa molecules.     

Binding of heat shock proteins to the avian progesterone receptor.

The protein composition of the avian progesterone receptor was analyzed by immune isolation of receptor complexes and gel electrophoresis of the isolated proteins. Nonactivated cytosol receptor was isolated in association with the 90-kilodalton (kDa) heat shock protein, hsp90, as has been described previously. A 70-kDa protein was also observed and was shown by Western immunoblotting to react with an antibody specific to the 70-kDa heat shock protein. Thus, two progesterone receptor-associated proteins are identical, or closely related, to heat shock proteins. When the two progesterone receptor species, A and B, were isolated separately in the absence of hormone, both were obtained in association with hsp90 and the 70-kDa protein. However, activated receptor isolated from oviduct nuclear extracts was associated with the 70-kDa protein, but not with hsp90. A hormone-dependent dissociation of hsp90 from the cytosolic form of the receptor complex was observed within the first hour of in vivo progesterone treatment, which could explain the lack of hsp90 in nuclear receptor complexes. In a cell-free system, hsp90 binding to receptor was stabilized by molybdate but disrupted by high salt. These treatments, however, did not alter the binding of the 70-kDa protein to receptor. Association of the 70-kDa protein with the receptor could be disrupted by the addition of ATP at elevated temperatures (23 degrees C). The receptor-associated 70-kDa protein is an ATP-binding protein, as demonstrated by its affinity labeling with azido[32P]ATP. These results indicate that the two receptor-associated proteins interact with the progesterone receptor by different mechanisms and that they are likely to affect the structure or function of the receptor in different ways.     

Contrasting evolutionary rates in the duplicate chaperonin genes of Mycobacterium tuberculosis and M. leprae

A phylogenetic analysis of chaperonin (heat shock protein 60) sequences from prokaryotes and eukaryotes indicated that a single gene duplication event in the common ancestor of Mycobacterium tuberculosis, M. leprae, and Streptomyces albus gave rise to the duplicate chaperonin genes found in these species (designated HSP65 and GroEL in the mycobacterial species). Comparison of rates of synonymous and nonsynonymous nucleotide substitution in different gene regions suggested that the 5' end of the HSP65 gene was homogenized by an ancient recombination event between M. tuberculosis and M. leprae. In S. albus, the two duplicated chaperonin genes have evolved at essentially the same rate. In both M. tuberculosis and M. leprae, however, the GroEL gene has evolved considerably more rapidly at nonsynonymous nucleotide sites than has the HSP65 gene. Because this difference is not seen at synonymous sites, it must be due to a difference in selective constraint on the proteins encoded by the two genes, rather than to a difference in mutation rate. The difference between GroEL and HSP65 is striking in regions containing epitopes recognized by T cells of the vertebrate host; in certain cross-reactive epitopes conserved across all organisms, nonsynonymous sites in GroEL have evolved twice as fast as those in HSP65. It is suggested that these differences are correlated with differences in the way in which the duplicate chaperonins of M. tuberculosis and M. leprae interact with the host immune system.      

Dynamic changes in the structure and intracellular locale of the mammalian low-molecular-weight heat shock protein.

Mammalian cells grown at 37 degrees C contain a single low-molecular-weight heat shock (or stress) protein with an apparent mass of 28 kilodaltons (kDa) whose synthesis increases in cells after exposure to elevated temperatures or other forms of physiologic stress. Herein we present data demonstrating that heat shock protein 28 exists in a number of dynamic states depending upon the physiologic state of the cell. Biochemical fractionation of 37 degrees C cells in the absence of nonionic detergent revealed that the 28-kDa protein partitioned approximately equally between the soluble and insoluble fractions. The addition of detergent in the fractionation procedure resulted in all of the protein distributed within the soluble phase. In contrast, in cells first heat shocked and then fractionated in the presence of detergent, most of the 28-kDa protein was found within the insoluble fraction. These biochemical results appeared entirely consistent with indirect immunofluorescence experiments, demonstrating that the 28-kDa protein resided within the perinuclear region of 37 degrees C cells in close proximity to the Golgi complex. After heat shock treatment, the 28-kDa protein relocalized within the nucleus and resisted detergent extraction. The extent of 28-kDa protein redistribution into the nucleus and its detergent insolubility increased as a function of the severity of the heat shock treatment. With time of recovery from the heat treatment there occurred a gradual return of the 28-kDa protein into the detergent-soluble phase. Concomitant with these changes in 28-kDa protein solubility was a corresponding change in the apparent size of the protein as determined by gel filtration. While at 37 degrees C cells the protein exhibited a mass of 200 to 800 kDa; after heat shock the protein assumed sizes of 2 MDa or greater. Using immunoelectron microscopy, we show an accumulation of these aggregates of 28-kDa protein within the nucleus. Finally, we show that the heat-dependent redistribution of the 28-kDa protein from the cytoplasm into the nucleus was greatly diminished when the cells were first rendered thermotolerant, and we suggest that this simple assay (i.e., 28-kDa protein detergent solubility) may prove useful in evaluating the thermotolerant status of a cell or tissue.     

Characterization of a slow-migrating component of the rabies virus matrix protein strongly associated with the viral glycoprotein

We investigated multiple forms of rabies virus matrix (M) protein. Under non-reducing electrophoretic conditions, we detected, in addition to major bands of monomer forms (23- and 24-kDa) of M protein, an M antigen-positive slow-migrating minor band (about 54 kDa) in both the virion and infected cells. Relative contents of the 54-kDa and monomer components in the virion were about 20-30% and 70-80% of the whole M protein, respectively, while the content of the 54-kDa component was smaller (about 10-20% of the total M protein) in the cell than in the virion. The 54-kDa components could be extracted from the infected cells with sodium deoxycholate, but they were quite resistant to extraction with 1% nonionic detergents by which most monomer components were solubilized. The 54-kDa component was precipitated more efficiently than the monomer by a monoclonal antibody (mAb; #3-9-16), which recognized a linear epitope located at the N-terminal of the M protein. The mAb #3-9-16 coprecipitated the viral glycoprotein (G), which was demonstrated to be due to strong association between the G and 54-kDa component of the M protein. Monomers and the 54-kDa polypeptide migrated to the same isoelectric point (pI) in twodimensional (2-D) gel electrophoresis, implicating that the 54-kDa component was composed of component(s) of the same pI as that of the M protein monomers. From these results, we conclude that the M antigen-positive 54-kDa polypeptide is a homodimer of M protein, taking an N-terminal-exposed conformation, and is strongly associated with the viral glycoprotein. Possible association with a membrane microdomain of the cell will be discussed.