Immunochemical specificity of antisera raised against the synthetic encephalitogenic peptide SH624, residues 59–74 of the myelin basic protein

Synthetic peptide SH624 (SHHPARTAHYGSLPQK), residues 59–74 of human myelin basic protein (MBP) was found to be encephalitogenic in the rabbit. Four antisera raised, against the peptide were employed in a liquid-phase equilibrium competitive radioimmunoassay with a series of synthetic peptide analogs of the region to probe the structural requirements of the B-cell determinant subsumed within SH624. The cross-reactivities of the four antisera with intact MBP were also examined. Immunochemical analyses of the four antisera suggested specificities directed against a conformational determinant dependent upon residues from the more phylogenetically conserved carboxyl C-terminal region, residues 65–74 (TAHYGSLPQK) of the synthetic immunogen. Peptide analogs shorter than SH624 from the C-terminal end showed no cross-reactivity with any of the reagent antisera while analogs shorter from the N-terminal end and including the encephalitogenic sequence TTHYGSLPQK, as well as, HYGSLPQK were reactive under equilibrium competitive conditions. SH624-reactive antibodies, cross-reactive with purified heterologous MBPs from 10 different species were also identified in all four reagent antisera. The results of these experiments support previous investigations demonstrating the accessibility of the encephalitogenic 65–74 region in intact MBP. They also underscore the importance of B-cell recognition of organ specific antigenic determinants with respect to MBP immunology and, in particular, the recognition of autoreactive determinants in the neighborhood of encephalitogenic centers.     

A rabbit B cell determinant for a conserved portion of myelin basic protein, rabbit encephalitogenic sequence 65-74

Synthetic peptide S24 (TTHYGSLPQKG) represents residues 65-74 of myelin basic protein (MBP) and contains the major determinant involved in the development of experimental allergic encephalomyelitis (EAE) in rabbits. This peptide is completely conserved in all nonprimate mammals for which sequence information is available. Although it is clear that peptides containing the S24 region are capable of inducing EAE, previous serologic studies have resulted in the conclusion that the determinant is "buried" or sequestered in intact MBP. Employing a liquid phase radioimmunoassay, we studied Ab responses to the S24 determinant in six rabbits injected with rat myelin. Two of the six animals developed small but measurable responses to the S24 determinant. In one of these rabbits, the response was boosted with a covalent conjugate of S82 and methylated BSA (MBSA). We also measured antibodies to the S24 determinant in rabbit antisera to human, monkey, dog, bovine, and the large and small forms of rat MBP. By nonequilibrium inhibition analysis, we determined that the antibody responses to these antigens were all directed to a determinant composed of residues 66-71 of MBP, and that intact MBP inhibits the binding of these antibodies to radiolabeled S24. The results demonstrate that the rabbit encephalitogenic region of myelin basic protein is exposed in the intact molecule both as an immunogen and as a reactant in liquid-phase assays; furthermore, they demonstrate that MBP antigenicity leading to B cell responses does not necessarily depend on sequence differences between the injected protein and its counterpart in the host species. The latter finding reinforces the contention of Atassi that autoantibody responses are not exclusive to "evolutionary hypervariable locations."     

Synthetic peptides from region 65–84 of bovine myelin basic protein: Radioimmunoassays and equilibrium competitive inhibition studies with antibodies prepared against myelin basic protein

Synthetic peptides with various and overlapping sequences represented by the residue region 65–84 of bovine myelin basic protein (MBP-bov) were tested in sodium sulfate radioimmunoassays for their reactivity with 15 rabbit antisera against MBPs from six different animal species and nine pools of syngeneic Lewis rat anti-MBP antisera. Three of the peptides were labeled with¹²⁵I and studied by direct binding reactions: (1) the prototype peptide S82 sequence TTHYG-SLPQKAQGHRPQDEG, corresponding to residues 65–84 of bovine MBP except for the C-terminal glycine, which is encephalitogenic in rabbits: (2) S81, which lacks the first three residues of S82 and is nonencephalitogenic in rabbits; and (3) S79, which represents the C-terminal half of S82 and which, because of its C-terminal glycine instead of asparagine, is nonencephalitogenic in Lewis rats. Fourteen of the rabbit anti-MBP antisera were reactive with [¹²⁵I]S82 (two borderline) including 2 of 3 antisera against human MBP, one against monkey MBP, and one against chicken MBP. The cross-reactions with [¹²⁵I]S81 were somewhat fewer and less intense. There were no cross-reactions with [¹²⁵I]S79. None of nine different pools of syngeneic rat MBP antisera cross-reacted with any of the three labeled peptides. With the use of a rabbit anti-MBP-rat antiserum that crossreacted strongly with [¹²⁵I]S82, 15 additional peptides with overlapping sequences within the residue region 65–84, as well as five MBP preparations from four different species, were tested by equilibrium and nonequilibrium competitive inhibition RIAs. Unlabeled S82 and MBP-bov were completely competitive with [¹²⁵I]S82 in the equilibrium assays; S81 and three other peptides had low degrees of cross-reactivity; but none of the remaining eight unlabeled peptides or unlabeled MBP preparations of guinea pig, rat, or mouse origin gave any evidence of competitive activity. Nonequilibrium competitive inhibition RIAs, however, did reveal cross-reactivities among several of the peptides as well as guinea pig and rat MBP. It was concluded that the N-terminal half of S82, particularly residues 68–74 (YGSLPQK), must contain an immunodeterminant of amino acid residues which identifies with the corresponding and exposed sequence in intact MBP-bov.This research was supported at Duke University by research grants 833-E-5 from the National Multiple Sclerosis Society and NS-10237 from the National Institutes of Health of the U.S. Public Health Service; at St. Luke's Hospital Center and Columbia University by grant RG1197-A-5 from the National Multiple Sclerosis Society; and at Northwestern University by grant NS-06262 from the National Institutes of Health of the U.S. Public Health Service.     

Immunochemical cross-reactivity between intact purified myelin basic protein (MBP) and the synthetic encephalitogenic peptide S49

Three antisera to myelin basic protein—a rabbit antiserum pool against rat myelin, a rabbit antiserum pool against rat myelin basic protein (MBP), and a monkey antiserum against bovine MBP—were found to contain detectable levels of antibodies that would bind radiolabeled S49 (GSLPQKAQRPQDENG). Strongly encephalitogenic in Lewis rat, S49 is a synthetic peptide representing residues 69–84 of bovine MBP with a deletion of glycine-76 and histidine-77 to make it analogous to rat and guinea pig MBPs. The rabbit antimyelin antiserum and the monkey anti-MBP antiserum contained antibodies directed against a non-sequential determinant that required asparagine 84, the glycine-histidine deletion, and residues 69–71 for maximal activity. S49-reactive antibodies from the rabbit anti-MBP antiserum were directed solely against a sequential determinant comprising residues 69–71. S49-reactive antibodies from all three antisera reacted in liquid phase with purified intact rat, guinea pig, and bovine MBP showing that the determinant is exposed for B cell recognition even in bovine MBP and can serve both as immunogen and reactant.This work supported at Duke University Medical Center by Research Grant NS-10237 from the National Institutes of Health of the U.S. Public Health Service and the Medical Scientist Training Program Grant #5-T32-OMO-7171-08; at St. Luke's Hospital Center by NS-15322 from the National Institutes of Health of the U.S. Public Health Service; and at Northwestern University by Research Grant NS-06262 from the National Institutes of Health of the U.S. Public Health Service.     

Equilibrium and nonequilibrium competitive inhibitions of antipeptide antibody binding by parent myelin basic protein and 18 related peptide sequences

Equilibrium and nonequilibrium competitive inhibition analyses of a number of antisera to peptide S81 and S82 sequences were carried out through the use of inhibition radioimmunoassays with [¹²⁵I]S81, [¹²⁵I]S82, and [¹²⁵I]S79 and a panel containing 18 related peptides and five myelin basic protein preparations. Two principal determinants were identified, one of them sequential, the other nonsequential. The sequential determinant involved a peptide at or near the C-terminal end of S82 that could be blocked by an interchange of asparagine for glycine at the C terminus. The nonsequential determinant was dominant for a number of rabbit and rat antisera, both anti-S82 and anti-S81, and was shared not only by S81 and S82 but also by S8 and S80, i.e., the family of residues of bovine MBP sequence 69–83. Neither determinant was expressed in any of the myelin basic protein preparations, and the nonsequential determinant was not expressed in peptide sequences smaller than S8.     

Elucidation of a minimal immunoreactive site of vertebrate calmodulin

The heptapeptide AsnTyrGluGluPheValGlnNH₂ corresponding to residues 137–143 of vertebrate calmodulin is as immunoreactive as the entire 148-residue protein. A reproducible and rapid procedure for producing antisera against vertebrate calmodulin has been previously described (L. J. Van Eldik and D. M. Watterson (1981) J. Biol. Chem.256, 4205–4210). Most of the antisera elicited by this method react with a major immunoreactive region (residues 127–144) in the COOH-terminal domain of vertebrate calmodulin. In this report, the minimum segment of calmodulin required for reactivity with an antiserum that readily distinguishes various types of calmodulins is defined. These studies demonstrate that a linear segment of seven amino acid residues shows a competition curve in radioimmunoassay resembling the competition curve of intact calmodulin. This heptapeptide is the smallest calmodulin segment and the only sevenresidue segment in the 135–145 region that shows quantitative immunoreactivity with the anti-calmodulin serum. These data demonstrate that this heptapeptide is a major immunoreactive site of calmodulin. However, when this immunoreactive site heptapeptide is conjugated to a carrier and injected into rabbits, it does not elicit antisera that react with the native protein. These studies demonstrate that quantitative immunoreactivity of antisera produced in animals can be found in small peptide segments and that, for calmodulin, the requirements for production of anti-peptide antibodies that react with the native protein molecule are not as simple as surface exposure of the peptide region.     

Multiple epitopes in a dodecapeptide of myelin basic protein determined by monoclonal antibodies

Three custom synthesized myelin basic protein (MBP) peptides, bovine peptide 79-88, human peptide 80-89, and human peptide 82-91, were used to produce four murine monoclonal antibodies (MAb) that were selected on the basis of reaction in a solid phase radioimmunoassay (SRIA) with human MBP. The MAb were compared with respect to antigen specificity against intact MBP and 10 overlapping MBP peptides. One MAb recognized an epitope near the amino-terminus of bovine MBP peptide 79-88. A second MAb was directed towards an epitope that is more reactive in human MBP peptide 45-89 than in intact MBP, but is not recognized in any of the small MBP peptides examined. The third MAb detected an epitope near the middle of human MBP peptide 80-89, whereas the fourth MAb reacted with the carboxyl-terminal portion of human MBP peptide 82-91. Epitopes recognized in SRIA were sometimes not detected by the same MAb in a fluid phase double antibody radioimmunoassay. These results demonstrate the multiplicity of potential epitopes in a dodecapeptide of MBP and do not support the concept of a single, dominant epitope in the region of MBP peptide 80-89.     

Lipid-induced recognition of a conformational determinant (residues 65 to 83) in myelin basic protein

The precipitation by antibodies to intact myelin basic protein (BP) and to synthetic peptides containing a sequence based on the region 65 to 83 of bovine BP, S82, S81, S79, and S24, of intact BP in solution or bound to lipid vesicles was compared, using 125I-BP or 14C-DPPC-labeled lipid-BP vesicles. The antipeptide antibodies were shown earlier to recognize conformational determinants which are not expressed in the intact protein in solution. Several anti-BP antibodies precipitated more of the BP free in solution than when bound to lipid vesicles, suggesting that some of the determinants recognized by these antibodies were either sequestered in the bilayer or were altered in conformation. In contrast, one anti-peptide antisera, which had a high titer for the conformational determinant in two of these peptides, S82 and S81, precipitated the protein to a significant degree when it was bound to PG vesicles, even though it did not react with the intact protein in solution. These results indicated that PG was able to confer on the protein the unique peptide conformation recognized by this antibody. PS was less effective, and other lipids were ineffective at conferring this conformation on the protein, supporting earlier results which showed that the conformation of the protein is influenced by the lipid composition of its environment. None of the other anti-peptide antibodies studied bound to the protein either in solution or in lipid vesicles. These results indicate that the lipid environment can sequester or alter the conformation of some antigenic determinants, preventing recognition by some anti-BP antibodies, and can expose or generate other conformational determinants, allowing recognition by an anti-peptide antiserum.     

Specificity and neutralizing capacity of antibodies elicited by a synthetic peptide of scorpion toxin

Polyclonal antibodies raised against a synthetic peptide (sequence 50-59) of Androctonus australis Hector toxin II can neutralize the effects of toxin II in vivo. The antigenic specificities of anti-peptide and anti-toxin antibodies were compared by competitive aqueous phase radioimmunoassay by using 125I-toxin II, chemically modified or homologous toxins, and the synthetic peptide 50-59, either free or bound to bovine serum albumin (BSA). The antipeptide and anti-toxin antibodies had a comparable high affinity for the native toxin, but anti-peptide antibodies exhibited a lower binding capacity. Anti-peptide antibodies had a higher affinity for native toxin than for the peptide 50-59 bound to BSA, used as immunogen, and were unable to recognize the free peptide. These results suggest that it is necessary to restrict the conformational freedom of the immunizing peptide in order to obtain anti-peptide antibodies with a high affinity for the toxin. The lysine residue at position 58 of toxin II, essential for toxicity, appears to be immunogenic when immunization is with peptide 50-59 bound to BSA and not with the native toxin. This residue is antigenic in the native toxin, however, as shown by the anti-peptide antibodies.     

Intragenic suppressor mutations that restore export of maltose binding protein with a truncated signal peptide

A deletion mutation, malE delta 12-18, removes seven residues from the hydrophobic core of the maltose binding protein (MBP) signal peptide and thus prevents secretion of this protein to the periplasm of E. coli. Intragenic suppressor mutations of malE delta 12-18 have been obtained, some highly efficient in their ability to restore proper MBP export. Twelve independently isolated suppressors represent six unique mutational events. Five result in alterations within the MBP signal peptide; one changes the amino acid at residue 19 of the mature MBP. Analysis of these suppressors indicates that the length of the hydrophobic core is a major determinant of signal peptide function. The experiments further suggest that the hydrophobic core region serves primarily a structural role in mediating protein secretion, and that other sequences outside of this region may be responsible for providing the initial recognition of the MBP nascent chain as a secreted protein.     

Unusual pattern of surface marker expression on peripheral lymphocytes from aged humans suggestive of a population of less differentiated cells

SJL/J, PL/J, and (SJL/J x PL/J)F1 mice were immunized with bovine, guinea pig, mouse, or rat myelin basic proteins (MBP) in adjuvant containing Mycobacterium tuberculosis H37Ra. Twenty-four and 72 hr later, Bordetella pertussis vaccine was given i.v. All MBP tested induced experimental allergic encephalomyelitis (EAE) in SJL/J and F1 mice; however, bovine MBP was inactive in PL/J mice. Each strain was immunized in a similar manner with peptic peptides, residues 1-37, 43-88, and 89-169 of guinea pig MBP. In contrast to the SJL/J strain, which has been shown to recognize a major encephalitogenic determinant in peptide 89-169, PL/J and F1 mice responded primarily to an encephalitogenic determinant within peptide 1-37. Analysis of antibody levels showed that SJL/J mice made no antibody to peptide 1-37, although anti-peptide 89-169 antibodies were consistently found. Conversely, PL/J mice responded well to peptide 1-37, but only an occasional animal made a significant response to peptide 89-169. (SJL/J x PL/J)F1 mice were more susceptible to EAE than either parental strain, as shown by the percentage of animals showing neurologic signs and by clinical severity.     

Multiple Sites of the Cleavage of 21- and 25-Mer Encephalytogenic Oligopeptides Corresponding to Human Myelin Basic Protein (MBP) by Specific Anti-MBP Antibodies from Patients with Systemic Lupus Erythematosus

IgGs from patients with multiple sclerosis and systemic lupus erythematosus (SLE) purified on MBP-Sepharose in contrast to canonical proteases hydrolyze effectively only myelin basic protein (MBP), but not many other tested proteins. Here we have shown for the first time that anti-MBP SLE IgGs hydrolyze nonspecific tri- and tetrapeptides with an extreme low efficiency and cannot effectively hydrolyze longer 20-mer nonspecific oligopeptides corresponding to antigenic determinants (AGDs) of HIV-1 integrase. At the same time, anti-MBP SLE IgGs efficiently hydrolyze oligopeptides corresponding to AGDs of MBP. All sites of IgG-mediated proteolysis of 21-and 25-mer encephalytogenic oligopeptides corresponding to two known AGDs of MBP were found by a combination of reverse-phase chromatography, TLC, and MALDI spectrometry. Several clustered major, moderate, and minor sites of cleavage were revealed in the case of 21- and 25-mer oligopeptides. The active sites of anti-MBP abzymes are localised on their light chains, while heavy chains are responsible for the affinity of protein substrates. Interactions of intact globular proteins with both light and heavy chains of abzymes provide high affinity to MBP and specificity of this protein hydrolysis. The affinity of anti-MBP abzymes for intact MBP is approximately 1000-fold higher than for the oligopeptides. The data suggest that all oligopeptides interact mainly with the light chains of different monoclonal abzymes of total pool of IgGs, which possesses a lower affinity for substrates, and therefore, depending on the oligopeptide sequences, their hydrolysis may be less specific than globular protein and can occur in several sites.     

Targeting of specific domains of diphtheria toxin by site-directed antibodies.

Antibodies highly selective for two functionally distinct regions of diphtheria toxin (DTx) were prepared using synthetic peptide conjugates as immunogens. Three peptides were selected for synthesis: sequence DTx141-157 on fragment A, which contains the putative protein elongation factor (EF-2) ADP-ribosyltransferase site; DTx224-237 on fragment B, selected on the basis of forming a predicted surface loop; and DTx513-526 on fragment B, forming a part of the region containing the putative receptor binding domain. All of the anti-peptide antibodies recognized the corresponding peptide, and also reacted with the toxin, specifically with the fragment containing the sequence against which they were raised, confirming the utility of this approach in generating fragment-specific antibodies. The anti-peptide antibody with the highest binding titre both to the peptide and to the native toxin was the one prepared against the sequence with the highest surface and loop likelihood indices of the three peptides selected. The similarity of the reactivity profiles with peptide and native and denatured toxin is consistent with the prediction that the region selected occurs in a surface loop and that the structure of the peptide is similar to the conformation of this region in the native protein. The epitopes for two of the anti-peptide antibodies were mapped. The results indicated that even though the antisera were raised to peptides containing 14 amino acids (aa) they were directed predominantly against a narrow region within the peptide, consisting of only 5-6 aa residues.(ABSTRACT TRUNCATED AT 250 WORDS)     

An immunodominant site of γ-zein1 is in the region of tandem hexapeptide repeats

The immunochemical data from studies with polyclonal antisera to γ-zein₁, the 27 kD component of the maize prolamin, indicated that the region containing 8 tandem repeats of the sequence PPPVHL is an immunodominant site. In one case, the entire antibody repertoire of an antiserum recognized epitope(s) within this region. Three 17-mer oligopeptides corresponding to the predicted antigenic epitopes of γ-zein₁ were synthesized and reacted with three different anti-γ-zein₁ sera in order to map antigenic sites in the intact protein. These antisera yielded positive reactions with a 17-mer peptide (peptide 37), which was not in a hydrophilic maximum but derived from the repeat region. The same antisera gave little or no reaction with other peptides (peptides 38 and 39), both of which were in a hydrophilic maximum. In addition, an antiserum to peptide 37 reacted strongly with both the homologous antigen and the intact γ-zein₁. Peptide 37 also blocked the binding of antisera to γ-zein₁ in competition assays. Subsequently, the shorter 6-mer (peptide 82) and 12-mer (peptide 80) versions of peptide 37 were synthesized, and both reacted with anti-peptide 37 serum and also with each of the three anti-γ-zein₁ sera. In these reactions and in competition assays, the reactivity and the blocking ability increased in proportion to the length of the peptide. Based on these data, it was concluded that the repeat region of γ-zein₁ is the site of one or more continuous immunodominant epitopes. The data also suggest that the repeat region is exposed on the surface of the folded protein and probably occur as a mobile, random coil.     

Structure and function of the proline-rich region of myelin basic protein

Myelin basic protein (MBP)--the major extrinsic membrane protein of central nervous system myelin--from several species contains a rarely encountered highly conserved triproline segment as residues 99-101 of its 170-residue sequence. Cis peptide bonds are known to arise at X-Pro junctions in proteins and may be of functional significance in protein folding, chain reversal, and/or maintenance of tertiary structure. We have examined the conformation of this proline-rich region using principally 13C nuclear magnetic resonance spectroscopy (125 MHz) both in intact bovine MBP and in several MBP fragment peptides which we synthesized, including octapeptide 97-104 (Arg-Thr-Pro-Pro-Pro-Ser-Gln-Gly). Results suggested an all-trans conformation in aqueous solution for the triproline segment in MBP hexapeptide (99-104), heptapeptide (98-104), and octapeptide. Comparison with the 13C spectrum of intact MBP (125 MHz) suggested that the proline-rich region, as well as all other X-Pro MBP peptide junctures, was also essentially all trans in aqueous solution. Although experiments in which octapeptide 97-104 was bound to a lipid preparation (4:1 dipalmitoylphosphatidylcholine/dimyristoylphosphatidic acid) demonstrated that cis-proline bonds do arise (to the extent of ca. 5%) in the membrane environment, a role of linear chain propagation is suggested for the triproline segment of myelin basic protein.     

A synthetic decapeptide of influenza virus hemagglutinin elicits helper T cells with the same fine recognition specificities as occur in response to whole virus

The immunogenicity of an isolated murine helper T cell determinant was studied. Mice were immunized with a synthetic peptide corresponding to amino acid residues 111-120 of the influenza PR8 hemagglutinin (HA) heavy chain, a region previously identified as a major target of the helper T cell response to the HA molecule in virus-primed BALB/c mice. Lymph node T cells from these mice were fused with BW 5147 cells to produce T hybrids for clonal analysis of their recognition specificities. Three T cell hybridoma clones, obtained from two different mice, responded to the immunizing peptide when presented by syngeneic antigen-presenting cells. All of these clones responded also to antigen provided as intact wild-type PR8 virus. The fine specificity of the peptide-induced T cell hybridomas, in response to a panel of mutant and variant influenza viruses, was indistinguishable from the fine specificities of T cells to the corresponding region of the HA1 chain of the HA molecule which had been generated by priming of mice with intact wild-type virus. These results suggest that an immunogenic determinant is contained within the 111-120 sequence that is able to elicit anti-influenza virus T cells with a similar repertoire to those elicited by immunization with whole virus.     

Autoimmune T cells: immune recognition of normal and variant peptide epitopes and peptide-based therapy

Experimental autoimmune encephalomyelitis (EAE) results from T helper (TH) cell recognition of myelin basic protein (MBP). We have characterized TH cell reactivity in B10.PL and PL/J (H-2u) mice to 39 N-terminal MBP peptide derivatives of different lengths and with individual amino acid substitutions. The peptide determinant of murine MBP can be divided into a minimal stimulatory core region (residues 1-6) and a tail region (residues 7-20) that alters the structure of the core region to affect both T cell recognition and MHC binding. Core recognition by B10.PL and PL/J mice is highly similar but in one case strain dependent. Peptide analogs that do not stimulate MBP-specific TH cells but bind to the I-Au molecule competitively inhibit T cell reactivity to MBP in vitro and prevent the induction of EAE in vivo.     

Suppression of experimental autoimmune encephalomyelitis by oral administration of myelin basic protein and its fragments

We report that experimental autoimmune encephalomyelitis, a T cell-mediated autoimmune disease studied as a model for multiple sclerosis, can be suppressed in Lewis rats by the oral administration of myelin basic protein (MBP). Both the clinical and histopathologic manifestations of the disease were suppressed in a dose-dependent manner. In addition, proliferative responses to MBP and, to a lesser extent, serum levels of anti-MBP antibody were suppressed by feeding MBP. Suppression of clinical and histologic disease was observed whether animals were fed MBP before or after disease induction, although suppression was more complete when rats were fed before immunization. Disease was also suppressed by the oral administration of either encephalitogenic or nonencephalitogenic fragments and decapeptides of the MBP molecule, with more complete suppression observed when nonencephalitogenic fragments were fed, suggesting that suppressor determinants exist in the MBP molecule distinct from the encephalitogenic region. The oral administration of a non-disease-inducing portion of an autoantigen represents an antigen-specific method by which an experimental autoimmune disease can be immunoregulated.     

Human thyroid peroxidase: mapping of autoantibodies, conformational epitopes to the enzyme surface

The enzyme, thyroid peroxidase (TPO), is a dominant antigen in thyroid autoimmune diseases. Autoantibodies recognised two major dominant conformational epitopes termed A and B. The epitopes have been defined by mAbs, but the amino acid residues which constitute these determinants remain unknown. Using a model of TPO, built from the structure of myeloperoxidase (MPO), we have synthesised peptides corresponding to exposed loops and generated rabbit antibodies to the peptides. Antisera to peptide sequence 599-617 (peptide 14) representing a highly protrusive loop on the TPO, showed the highest inhibition in 65 sera from patients positive with anti-TPO antibodies. The inhibition was by 15-80% (mean 41%), and no other antibody showed any inhibition. Binding of hFabs to the B determinant on TPO was inhibited by anti-peptide 14 antibodies more then 85%, but not Fabs to the A determinant. In conclusion, the peptide 14 defines a sequence taking part in building up the B major conformational epitope. None of generated anti-peptide antibodies alone inhibited the binding of human Fabs to the A epitope, however a combination of four anti-peptide antibodies (P1, P12, P14 and P18) inhibits Fabs binding to the A determinant by more then 60% and autoantibodies binding from 65% to 94%. Combination of antibodies reacting with peptides outside the surface defined by those four antipeptide antibodies did not give any inhibition of Fabs to TPO. The inhibition of Fabs and auto Abs to TPO by this combination of anti-peptide Abs is the result of steric hindrance as none of these Abs individually inhibited auto Abs' or Fabs' binding to TPO. The four peptides define an area on the enzyme surface where the A and B major conformational epitopes are localised.     

Identification of a new group-specific determinant on hepatitis B surface antigen with a synthetic peptide.

In a recent study we demonstrated that a synthetic peptide representing residues 124-147 of the major protein of hepatitis B surface Ag (HBsAg) undergoes spontaneous oligomerization to reconstruct one or more conformational group-specific determinants on HBsAg. The present study was undertaken to identify and characterize the HBsAg-related antigenic determinants on this oligomeric peptide (peptide OS[124-147]). A panel of nine analogs of this peptide was generated by either deleting, substituting, or chemical side chain modification of specific amino acid residues. With HBsAg subtype-specific antisera a single "a" epitope was identified as one that includes Met133 and Lys141. In addition a "d" epitope toward the amino-terminal end of the sequence was also observed. Perturbation of certain amino acid residues was found to enhance a antigenicity and subsequent experiments indicated that maximal expression of this a antigenicity is dependent in part on accessibility of the Lys141 side chain and in part on the primary sequence. With a total of 50 human anti-HBsAg serum samples obtained from individuals vaccinated against hepatitis B, it was demonstrated that these sera recognize the Met133-Lys141-dependent a epitope as the dominant, and in many cases the only, determinant on peptide OS[124-147]. Finally, on immunization, peptide OS[124-147] elicits an anti-HBsAg response that is predominantly anti-a though a lesser contribution from an anti-d response was also obtained.