Rabbit anti-HMG-17 antibodies recognize similar epitopes on the HMG-17 molecule as lupus autoantibodies. Relation with histone H1 defined epitopes.

HMG-17 is a nucleosomal protein which is an immune target of autoantibodies in systemic lupus erythematosus (SLE) and other autoimmune diseases. Autoantibody production in SLE is believed to result from autoantigen specific immune stimulation and subsequently, it is expected that antigenic determinants recognized by SLE autoantibodies and induced antibodies by immunization are quite similar. To examine this issue, rabbits were immunized with purified HMG-17. The produced antiserum showed cross reactivity on blots and in inhibition ELISA with histone H1, even after its affinity purification with immobilized HMG-17. Finally, purification of the antiserum over H1 absorbed on nitrocellulose membrane produced specific anti-HMG-17 antibodies in the supernatant and anti-HMG-17/H1 antibodies that were bound to H1. SLE sera positive for HMG-17 had also cross reactivity with H1, and following the same procedure as before we received HMG-17 specific SLE autoantibodies and anti-HMG-17/H1 autoantibodies. Using the multipin epitope mapping technology, 19 overlapping 15-mer HMG-17 peptides and six 15-peptides, corresponding to known epitopes of histone H1, were synthesized. Four major epitopes were identified on the HMG-17 molecule, reactive with induced anti-HMG-17 antibodies, and these were the same as major autoepitopes In SLE. The sequence 25-51 of HMG-17, part of its DNA-binding domain, was recognized by the anti-HMG-17/H1 antibodies that were bound to H1. These antibodies recognized also defined epitopes of H1. Our results show that SLE autoantibodies can be directed against the same or similar epitopes as do IgGs evoked during the active immunization of animals, and provide additional evidence that autosensitization with an autoantigen might be operative. The possibility that the same or similar epitopes are found on different molecules (in this study HMG-17 and H1) supports the fact that there are rules by which nature selects the most dominant immunodeterminant to a given protein, which often represents functional or structural sites in the autoantigen.     

Monoclonal antibodies as probes for the complexity, phylogeny, and chromatin distribution of high mobility group chromosomal proteins 1 and 2

Monoclonal antibodies were prepared against the high mobility group (HMG) proteins 1, 2a, and 2b from hen erythrocyte chromatin. One antibody that recognized multiple sites along HMG-1, -2a, and -2b reacted strongly with HMG proteins from all vertebrates tested. In contrast, five antibodies that detected unique epitopes on chicken HMG-1 and -2a recognized antigenic sites that exhibited restricted phylogenic distributions. The differential reactivity of these antibodies on vertebrate proteins was in agreement with traditional taxonomy in that the avian HMGs were most closely related to those from reptiles and less related to those from mammals, amphibians, bonyfish, and especially the jawless fish. Mononucleosomes generated by mild digestion of erythrocyte chromatin with micrococcal nuclease were highly enriched in HMG-2a. One antigenic determinant located within the N-terminal domain of HMG-2a was freely accessible to its antibody when the protein was bound to these mononucleosomes. In contrast, two antibodies that recognized determinants in the central region of HMG-2a exhibited little chromatin binding activity. The masking of the central domain by DNA binding was presumably not responsible for these results because all three determinants were available for antibody binding when HMG-2a was bound to DNA in vitro. Therefore, the central region of HMG-2a may be masked from antibody binding by protein-protein interactions in chromatin.     

Serological analysis of species specificity in the high mobility group chromosomal proteins.

The non-histone chromosomal protein of the high mobility group (HMG-1) present in mouse liver was purified to homogeneity. Antibodies against this protein as well as pure HMG-1 derived from calf thymus and HMG-E purified from duck erythrocytes were elicited in rabbits. The interaction between the antibodies and the immunogens was measured by passive hemoagglutination and by quantitative microcomplement fixation. Quantitative microcomplement fixation assays revealed that the immunological distance between HMG-1 from calf thymus and HMG-1 from mouse liver and duck erythrocytes was 15. This corresponds to 3% sequence differences. It was estimated that amino acid substitution occurred at about seven positions in the polypeptide chain. Thus, HMG-1 proteins display remarkable evolutionary conservation in their primary sequence, similar to that displayed by histones H4 and H3, suggesting that their biological function is dependent on stringent structural requirements. HMG-E protein is significantly different from both HMG-1 and HMG-2 derived from calf thymus. As such, it is a protein unique to avian erythrocytes.     

Antibodies against chromosomal HMG proteins stain the cytoplasm of mammalian cells.

Antibodies specific to protein HMG-1 were purified by affinity chromatography on Sepharose columns to which HMG-1 was covalently bound. Immunofluorescence studies with these antibodies reveal that HMG-1 or components which immunologically cross-react with HMG-1 are present in the cytoplasm of Chinese hamster V-79, rat liver TR-12 and bovine trachea EBTr-NBL-4 cells. At selected antibody concentrations, the fluorescence present in the cytoplasm is more intense than that observed in the nucleus. The presence of HMG-1 protein in the cytoplasm of rat liver cells was verified by direct examination of the protein content of selected cytoplasmic fractions. A protein with electrophoretic mobility identical to HMG-1 was detected by electrophoresis on polyacrylamide gels containing either sodium dodecylsulfate or urea. Furthermore, the cytoplasmic extracts yielded a positive complement fixation with anti-HMG-1, while no reaction was obtained with control anti-H1 sera. We suggest that HMG protins, rather than functioning in the nucleus alone, are important structural elements of the entire cell.     

Immunological relatedness of high mobility group chromosomal proteins from calf thymus.

The non-histone proteins HMG-1, HMG-2, HMG-3, HMB-8, HMG-14, and HMG-17 (Goodwin, G. H., SANDERS, C., and Johns, E. W. (1973) Eur. J. Biochem. 38, 14) were purified from calf thymus. The apparent molecular weights on polyacrylamide gels run in the presence of sodium dodecyl sulfate of the high mobility group (HMB) proteins were determined. Those for HBG-1 and HMG-2 agreed with the molecular weights determined by sedimentation; that for HMG-17 was anomalously high. Antibodies against HMG-1 were elicited in rabbits. The interaction between HMG-1 and anti-HBG-1 was measured by quantitative precipitation and by the microcomplement fixation technique. Quantitative microcomplement fixation assays revealed that the indices of dissimilarity between HMG-1 and HMG-2, HMG-3, HMG-8, HMG-14, and HMG-17 were 2.0, 1.0, 3.8, 10.0, and 6.1, respectively. These correspond to 6%, 0%, 12%, 20%, and 16% sequence difference between HMG-1 and the other five HMG proteins, although the immunological distance between HMG-1 and HMG-14 may be too large to allow a good correlation between the sequence and the immunological reaction. Antibodies to HMB-1 bind to chromatin purified from calf thymus. Therefore, we suggest that the in situ organization of HMG proteins in chromatin and chromosomes may be studied by serological techniques.     

Monoclonal antibody against non-histone chromosomal protein high mobility group 1 Co-migrates with high mobility group 1 into the nucleus

Non-histone chromosomal protein high mobility group 1 (HMG-1) rapidly migrates into the nucleus when injected into the cytoplasm of bovine fibroblasts and HeLa cells by red cell-mediated microinjection (Rechsteiner, M., and Kuehl, L. (1979) Cell 16, 901-908). We isolated hybridomas secreting monoclonal antibodies against HMG-1. One of these monoclonal antibodies, FR-1, inhibited in vitro binding of 125I-HMG-1 to chromatin isolated from FL cells. When 125I-HMG-1 was co-introduced with antibody FR-1 by red cell-mediated microinjection, antibody FR-1 did not prevent the accumulation of 125I-HMG-1 in the nucleus. When 125I-antibody FR-1 or fluorescein isothiocyanate antibody FR-1 was introduced into the cytoplasm of FL cells, most of the antibody did not accumulate in the nucleus. But when 125I- or fluorescein isothiocyanate antibody FR-1 was co-introduced with HMG-1 into the cytoplasm of FL cells, it did migrate into the nucleus.     

Evidence that high mobility group protein 17 is not phosphorylated in human colon carcinoma cells

The high mobility group proteins 14 and 17 were reported previously to be phosphorylated in murine and human tumor cell lines. Recently, it was suggested that subgroups of HMG-14, HMG-14a and 14b, but not HMG-17, were phosphorylated in situ in HeLa cells. In order to definitively determine whether HMG-17 is indeed phosphorylated or whether the protein previously identified as [³²P]HMG-17 was a subgroup of HMG-14, we have used the technique of electroblotting in conjunction with an immunochemical procedure utilizing anti-HMG-17 IgG. Our results indicate that HMG-17 was not phosphorylated in human colon carcinoma cell line HT-29 incubated for 18 h with ³²P_i, but that HMG-14a and HMG-14b were phosphorylated. In contrast, HMG-14a, -14b and -17 were phosphorylated in vitro in isolated nuclei incubated with [γ-³²P]ATP.     

Studies on the stability of the higher-order structure of rat liver chromatin containing high-mobility-group proteins

The stability of the higher-order structure of chromatin containing high-mobility-group (HMG) proteins has been studied in rat liver nuclei by mild micrococcal nuclease digestion at low temperature and fractionation by sucrose gradient centrifugation. Nuclei preparation and digestion, chromatin solubilization and analysis have been carried out in two ionic conditions, 140 mM and 40 mM monovalent cation concentration, avoiding drastic changes in ionic conditions and temperature during preparation and analysis. During the time course of digestion at 140 mM ionic strength a material stable at 80 S appears, whose DNA is cleaved at values around 12 nucleosomes. The distribution of HMG proteins in different chromatin fractions was analyzed by immunodot using antibodies elicited against proteins HMG-1, HMG-2, and HMG-14 and 17. It appears that these proteins have a distribution distinctly different from the bulk of chromatin. They are never found in the chromatin fragments that keep their internucleosomal interactions, indicating that these proteins tend to accumulate in points where the chromatin has a less stable structure.     

Use of a series of ompF-ompC chimeric proteins for locating antigenic determinants recognized by monoclonal antibodies against the ompC and ompF proteins of the Escherichia coli outer membrane

A method is presented for the efficient location of antigenic determinants using a series of chimeric proteins. By means of in vivo homologous recombination between the ompC and ompF genes coding for OmpC and OmpF, homologous proteins of the Escherichia coli outer membrane, a series of ompF-ompC chimeric genes was constructed (Nogami, T., Mizuno, T., & Mizushima, S. (1985) J. Bacteriol. 164, 797-801, and this work). The OmpF-OmpC chimeric proteins expressed by these genes were successfully used to locate antigenic determinants recognized by monoclonal antibodies, which specifically react with either the OmpC or OmpF protein. Interaction between monoclonal antibodies and the chimeric proteins was examined by means of either enzyme-linked immunosorbent assay or immunoblot analysis. The antigenic determinants recognized by three anti-OmpC antibodies and one anti-OmpF antibody were thus located. Finally, the polypeptides covering these regions were chemically synthesized for two of them and then tested as to their reactivity with the antibodies. The peptides reacted with the corresponding antibodies when the former were chemically coupled with bovine serum albumin. Most of the monoclonal antibodies isolated in this work were highly specific to the unfolded monomer of the protein against which the antibody was raised. But they did not react with the trimer, the native form. These results are discussed in relation to the structures and functions of the OmpC and OmpF proteins. The use of a series of monoclonal antibodies for studying the mechanism of protein translocation across the cytoplasmic membrane is also discussed.     

Immunochemical analysis of the exposure of high mobility group protein 14 and 17 surfaces in chromatin

Antisera were elicited against synthetic peptides corresponding either to regions common to all members of the high mobility group 14 and 17 protein family protein or to distinct domains of the HMG-14 or HMG-17 subgroup. The antisera were used to probe the accessibility of various HMG domains in chromatin. Competitive enzyme-linked immunosorbent assays indicate that the central region of the proteins, which contains their DNA binding domain and is positively charged, is exposed to a smaller degree than the C-terminal region of the proteins, which has a net negative charge. The C-terminal regions of the HMG-14 and HMG-17 proteins are exposed and available to interact with other proteins.     

Immunochemical detection of chromosomal protein HMG-17 in chromatin subunits

Chromosomal protein HMG-17, purified from calf thymus, has been used to elicit specific antibodies in rabbits. Specific serological reaction between the antigen and the antisera is demonstrated by solid-phase radioimmunoassay and by competitive inhibition assays. The antisera did not cross-react with histones or other chromosomal HMG proteins. The antisera bound specifically to chromatin subunits isolated from HeLa cells, demonstrating that it may be used to study the in situ organization of this chromosomal protein. Chromatin purified from HeLa nuclei was digested with micrococcal nuclease, and the resulting mono- and oligonucleosomes were fractionated on a sucrose gradient. Analyses of the content of chromosomal proteins HMG-1, HMG-17, and H4 in different size nucleosomal particles, by the solid-phase radioimmunoassay, reveal that the distribution of HMG-17 was the same as that of H4, but different from that of HMG-1.     

Monoclonal antibodies against distinct determinants of histone H5 bind to chromatin

A series of monoclonal antibodies specific for distinguishable epitopes in chromosomal protein histone H5 were obtained from mice immunized with either free H5 or H5 . RNA complexes. The antibodies elicited by H5 could be distinguished from those elicited by H5 . RNA by their binding to native or acid-denatured H5, by their interaction with the globular region of H5, and by their cross-reactivity with H1o. The specificity of the antibodies was assessed by enzyme-linked immunosorbent assay (ELISA) and immunoblotting experiments. The antibodies could distinguish between H5 and the closely related histones H1 and H1o. The binding of some of the antibodies to the antigens was dependent on the type of assay used, suggesting nonrandom binding of the antigen to the solid supports used in ELISA and immunoblotting. Competitive ELISA experiments indicate that 8 of the 11 antibodies characterized bind to distinct epitopes. Three monoclonal antibodies bind to epitopes which are in close spatial proximity, causing mutual steric hindrance. The monoclonal antibodies bind to nuclei of fixed cells and to isolated chromatin, indicating that the epitopes are present both in the purified protein and in chromatin-complexed H5. These monoclonal antibodies can be used to study the organization of distinct regions of histones H5 and H1o in chromatin and chromosomes.     

Production of monoclonal antibodies against nucleocapsid proteins of herpes simplex virus types 1 and 2.

We prepared mouse hybrid cell lines which produced antibodies against herpes simplex virus type 1 and 2 nucleocapsids. Cell lines 1D4 and 3E1, respectively, secreted immunoglobulin G1 herpes simplex virus type 1 and immunoglobulin G1 herpes simplex virus type 2 antibodies which immunoprecipitated proteins designated p40 and p45 from homologous nucleocapsid preparations but precipitated no proteins from heterologous preparations. In contrast, guinea pig antisera prepared against either herpes simplex virus type 1 or 2 p40 precipitated p40 and p45 from both homologous and heterologous preparations. These findings suggest that p40 and p45 possess similar antigenic determinants and that the monoclonal antibodies that were tested reacted preferentially with the homologous determinants.