Immunochemical studies of streptococcal cell membrane antigens immunologically related to glomerular basement membrane.

Pursuing an autoimmune model for the etiology of poststreptococcal glomerulonephritis, protein antigens isolated from the cytoplasmic membrane of nephritogenic group A Type 12 Streptococcus pyogenes were immunochemically characterized using antistreptococcal cell membrane (SCM) monoclonal antibody (MAb) cross-reactive with glomerular basement membrane (GBM). Low molecular weight (9.2, 7.0, 4.7, 2.3 kDa) HPLC-purified SCM polypeptide antigens were characterized by competitive inhibition and equilibrium dialysis. Competitive inhibition of the MAb, by different sized SCM polypeptide antigens showed an inverse relationship between the size of these antigens and the molar amount required to obtain 50% inhibition of the MAb, confirming previous observations that suggested that these SCM antigens exhibit increasing epitope concentration with increasing size, that is constant epitope density. The observed changes in epitope concentration correlated with differences in the valence and affinity of the MAb as determined by equilibrium dialysis. The Kds of the MAb for 9.2-, 7.0-, 4.7-, and 2.3-kDa SCM antigens ranged from 7.42 x 10(-7) to 1.15 x 10(-5). The experimentally determined MAb valence for these antigens was 2 for the 9.2-kDa antigen and approached 10 for the smaller antigens. Finally, the similarity of these SCM antigens was reflected in similar amino acid compositions; of note, these data agreed with the compositions previously reported for sized GBM antigens. Concentrations of Asp, Thr, Ser, Glu, Gly, Ala, Val, Ile, and Leu paralleled increasing epitope concentration. Apparent N-terminal blocking prevented sequencing of these peptides, but these immunochemical data suggest that intact SCM antigen recognized by the anti-SCM MAb consists of repeating epitopes, an observation consistent with the cytoplasmic membrane source of the antigen.

Use of solid-phase C1Q to remove soluble antigen/antibody complexes in an inhibition ELISA for streptococcal cell membrane antigens.

Solid-phase C1q was used to remove antigen/antibody complexes in an inhibition ELISA for low molecular weight streptococcal cell membrane (SCM) polypeptide antigens. To selectively fix IgM monoclonal antibody bound to antigen, binding was carried out in C1q-coated ELISA plates; transfer of supernatants to SCM-coated plates for ELISA permitted measurement of residual antibody. When inhibition occurred in the presence of C1q, the maximal binding was 72-98%. In the absence of C1q the maximum apparent binding was only 45-50%, which we attribute to displacement of the initially bound SCM antigen by solid phase SCM antigen. Removal of antigen/antibody complexes by solid-phase Clq during inhibition assays may facilitate analysis of low affinity antigen/antibody interactions.

Isolation and partial characterization of antigens from basement membranes and streptococcal cell membrane (SCM) employing anti-SCM monoclonal antibody.

Monoclonal antibodies (mAb) against streptococcal cell membrane (SCM) antigen were used to identify specific cross-reactive peptides prepared by trypsin digestion of purified glomerular basement membrane (GBM) and lung basement membrane (LBM). Anti-SCM mAb-coupled HPLC columns were used to affinity isolate soluble LBM, GBM, and SCM antigens which then were sized by HPLC. Alternatively, SCM, GBM, and LBM digests were subjected to an initial separation by HPLC into component polypeptides, followed by affinity purification and ELISA of these fractions using anti-SCM mAb. Comparison of the antigenic reactivities by ELISA of the sized polypeptides on a nanomolar basis permitted the estimation of their individual relative epitope densities. The results for SCM antigens showed increasing epitope density with increasing molecular size, which suggests that intact SCM consists of repeating epitopes. Low mol. wt GBM polypeptides in nanogram amounts inhibited mAb binding to SCM, indicating that these small GBM polypeptides may similarly contain more than a single cross-reactive epitope. The identification of these cross-reactive epitopes in LBM and GBM has important implications for the etiology of post-streptococcal sequelae.