G J Boulnois

A system for the production of monoclonal antibodies, particularly of the IgG type, against weakly immunogenic bacterial polysaccharide antigens is described. This system, which is based on the autoimmune NZB mouse strain, has been used to produce a monoclonal IgG2a antibody against the meningococcus group B and Escherichia coli K1 polysaccharides, identical homopolymers of alpha (2----8)-linked units of N-acetylneuraminic acid that are extremely poor immunogens. Comparison of the humoral immune responses of normal BALB/c mice and autoimmune NZB mice to hyperimmunization with group A, B, and C meningococci showed that, although both strains mounted a weak meningococcal B polysaccharide-specific IgM response, only the NZB strain mounted an IgG response. Similarly, NZB mice mounted a stronger IgG response to the more immunogenic group C meningococcal polysaccharide than did BALB/c mice, although this difference was less pronounced than that observed with meningococcal B polysaccharide. No difference between the two strains of mice was demonstrable with the strongly antigenic group A meningococcal polysaccharide. These results indicate that the NZB system may be generally useful for the production of monoclonal antibodies against weakly antigenic bacterial determinants.

A recombinant lambda bacteriophage has been isolated that carries DNA from Streptococcus pneumoniae and expresses a potent hemolysin that has been shown to be pneumolysin, the sulfhydryl-activated toxin of the pneumococcus. Hemolytic activity is inhibited by cholesterol and neutralized by serum against streptolysin O. The cloned gene expresses two polypeptides (Mrs, 56,000 and 53,000) in an Escherichia coli in vitro transcription-translation system, and both are precipitated by the addition of anti-alveolysin serum and anti-streptolysin O serum in the presence of Staphylococcus aureus cells. Expression of pneumolysin occurs when the gene is cloned in both possible orientations in pUC8. The DNA sequence of a 5-kilobase ClaI fragment that carries the pneumolysin gene has been determined. An open reading frame was identified that encodes a polypeptide of 471 amino acids that is hydrophobic in character and has an N-terminal amino acid sequence which is identical to that deduced from amino acid sequencing of the purified protein. The predicted amino acid sequence of the polypeptide reveals a single cysteine residue located 44 residues from the C terminus. Putative promoter and ribosome binding sites have been identified 5' to the pneumolysin coding sequence.

Mice were infected intranasally with a serotype 2 pneumococcus, a pneumolysin-negative derivative (PLN-A), or an autolysin-negative derivative (AL-2). Numbers of wild type pneumococci were seen in the lung from approximately 12 h after infection and were first detected in the blood around this time. Immunofluorescent staining of lung sections showed that pneumolysin was produced in vivo. Pneumococcal infection resulted in alteration of the composition of the blood but not the bone marrow. Some of the hematologic changes did not occur after PLN-A. PLN-A had a slower growth rate in the lung and bacteremia was delayed. AL-2 was rapidly cleared from the lungs and was not detected in the blood. These events paralleled the pattern of histology in the lung, with the severity of inflammation reduced with PLN-A and no inflammation or hematologic changes with AL-2.

Pneumolysin, a membrane-damaging toxin, is known to activate the classical complement pathway. We have shown that 1 microgram ml-1 of pneumolysin can activate complement, which is a much lower level than observed previously. We have identified two distinct regions of pneumolysin which show homology with a contiguous sequence within acute-phase proteins, including human C-reactive protein (CRP). Site-directed mutagenesis of the pneumolysin gene was used to change residues common to pneumolysin and CRP. Some of the modified toxins had a reduced ability both to activate complement and bind antibody. We suggest that the ability of pneumolysin to activate complement is related to its ability to bind the Fc portion of immunoglobulin G.

As part of an ongoing study concerned with improving human vaccines against Streptococcus pneumoniae, the genes for two defined pneumolysin (PL) toxoids (pneumolysoids), Pd-A (PL with a Cys----Gly substitution at amino acid 428) and Pd-B (PL with a Trp----Phe substitution at position 433), were inserted into the high-expression vector pKK233-2 in Escherichia coli and the pneumolysoids were purified. Groups of mice which had been immunized with either Pd-A, Pd-B, or native PL purified from S. pneumoniae were then challenged either intranasally or intraperitoneally with virulent pneumococci. Mice in all immunized groups survived significantly longer than sham-immunized controls. Both pneumolysoids were more effective than PL as protective immunogens. Pneumolysoid Pd-B was conjugated covalently with pneumococcal type 19F capsular polysaccharide (19F PS), and the immunogenicities of both the protein and the PS moieties of the conjugate in mice were determined. Significant anti-PL titers were obtained, and the immunogenicity of the 19F PS moiety was markedly enhanced compared with that of unconjugated PS. Conjugation also appears to have converted the 19F PS into an antigen capable of inducing a booster effect. These results support the notion that the efficacy of human, PS-based antipneumococcal vaccines might be improved by supplementation with pneumolysoid in the form of a covalent pneumolysoid-PS conjugate.