Chi-Jen Lee

Virulence, Immunity, and Vaccine Related to Streptococcus pneumoniae

The pathogenesis of bacterial infection involves a series of interactions between the virulence determinants of the microorganisms and the immunity of the host. Studies on the molecular structure and immunological properties of pneumococcal virulence factors have provided general knowledge for the chemical basis of immunogenicity and prevention of bacterial infection. Antibody responses to PS and protein antigens can be greatly affected by their physicochemical properties, e.g., molecular size, specific determinants, conformation, etc. Characterization of group 19 pneumolysins and cloning of their ply genes were studied to examine the relationship of ply to virulence. Group 19 pneumococci all contained ply; the disease-isolated types of 19F and 19A appeared to show a higher specific hemolytic activity and yield than the nonpathogenic types, 19B and 19C. Genomic DNA that contained the ply gene from group 19 strains were analyzed by the polymerase chain reaction (PCR). Type 2 oligonucleotide primers recognized and initiated synthesis of an identical 1.5 kb DNA fragment in types 2, 19F, 19A, 19B, and 19C. Their sizes of restriction DNA fragments were also found to be homologous. Thus, group 19 ply genes showed remarkably similar characteristics. A difficult problem in the development of vaccines against bacterial diseases is the poor immune response of young children to purified PSs. The efficacy of pneumococcal vaccine might be improved by supplementation with inactivated pneumolysin in the form of a PS-protein conjugate.

Pneumococcal Infection and Immunization in Children

Pneumococcal infection persists as a major cause of pneumonia, bacteremia, and otitis media and is the important cause of meningitis in young children. Children less than 2 years of age show the highest incidence of pneumococcal diseases. Pneumococcal types 6A + 6B, 7F, 9V, 14, 18C, 19F + 19A, and 23F account for the large majority of disease isolates in the pediatric population. Bacterial clearance and antibody response were studied in young mice from mothers injected with pneumococcal type 9V polysaccharide (PS) conjugated with the inactivated pneumolysin to examine the protective immunity of young mice to pneumococcal infection. The injection of mice with pneumococcal PS-protein conjugate conferred the protective immunity to pneumococcal infection. The efficacy of pneumococcal vaccine might be enhanced by addition of inactivated pneumolysin in the form of PS-protein conjugate. The molecular size of pneumococcal type 19F PS or oligosaccharide used for preparing the PS-protein conjugate has a profound effect on the antibody response to the PS. The conjugate immunogen prepared from a large molecule of 19F PS produced a high antibody response to the PS in young mice. Development of a PS-protein conjugate vaccine for selected pneumococcal types will help in solving problems of poor immunogenicity of pneumococcal PS vaccine in young children.

Immunogenicity in mice of pneumococcal glycoconjugate vaccines using pneumococcal protein carriers.

Antibody response and protective immunity were evaluated in mice immunized with pneumococcal glycoconjugate vaccines using two pneumococcal protein carriers. Mice injected with type 9V polysaccharide (PS) conjugated to inactivated pneumolysin (Ply) or autolysin (Aly) produced high levels of IgG and IgM antibodies to both the PS and the protein carrier. Higher PS antibody titers to the pneumococcal PS conjugates were measured by ELISA using PS-Ply or PS-tetanus toxoid (TT) conjugate as a coating antigen compared with PS mixed with methylated human serum albumin. Type 9V PS (10 microg) inhibited most of the 9V IgM and IgG antibody binding to the 9V-TT coated plate. In contrast, absorption with 19F PS did not inhibit 9V antibody binding. The avidity index of IgG antibodies in the 9V PS-Ply serum was 55.5 +/- 0.9, compared with 47.8 +/- 1.4 for 9V PS-Aly serum. Thus, high avidity of serum antibodies in conjugate-immunized mice can provide more effective functional activity for protection against pneumococcal infection. Mice immunized with these glycoconjugates exhibited rapid bacterial clearance from blood and provided cross-protection against challenge with heterologous serotypes of virulent pneumococci. These results reveal that conjugates using pneumococcal protein carriers can induce opsonophagocytic activity to destroy homologous and heterologous pneumococci, indicating that such conjugates can confer broader protective immunity than conjugates using non-pneumococcal proteins.

Protective Immunity of Pneumococcal Glycoconjugates

Pneumococcal polysaccharides (PSs), designated as T-cell independent type 2 (TI-2) antigens, induce poor immune responses in young children. Splenic marginal zone B cells, associated with CD21, CD19 and C3d, play an important role in TI-2 antibody responses, and provide host defense against bacterial pathogens. Antibody response, avidity, and opsonophagocytic activity of antisera were examined in mice immunized with type 9V PS conjugated to inactivated pneulmolysin (Ply) or to autolysin (Aly). Compared to mice given 9V PS alone, serum IgG and IgM concentrations against the 9V PS were higher in mice immunized with conjugates. High concentrations of serum antibodies were maintained for over 12 weeks. The relative avidities of IgG and IgM antibodies and opsonophagocytic activity against 9V pneumococci were high in mice immunized with conjugates. Thus, conjugate vaccines can induce high as well as long duration of antibody response and effective functional activity. In another study, mice received intranasal immunization with type 9V conjugate or 9V PS. These animals produced 9V PS IgG and IgA antibodies in their serum, spleen, intestine, lung, Peyers patch and fecal extract samples. Mice immunized with these glycoconjugates exhibited opsonophagocytic activity and rapid bacterial clearance from blood and provided homologous and cross-protection against challenge with virulent pneumococci. These results indicate that intranasal immunization with glycoconjugate vaccines may serve as an alternative and convenient approach for prevention of pneumococcal infection.

Development and evaluation of pneumococcal conjugate vaccines: Clinical trials and control tests

Streptococcus pneumoniae is a major cause of pneumonia, meningitis, and otitis media and is responsible for disease in young children, the elderly, and immunocompromised individuals. Emerging high-level resistance to penicillin, multiple antibiotics, and tolerance to vancomycin emphasizes the importance of preventing pneumococcal infection by alternative methods such as immunization. The development of pneumococcal conjugate vaccines using the same carrier proteins as those used in Hemophilus influenzae type b vaccines has enhanced the immune response in infants and children compared with polysaccharide vaccines and has significantly improved the ability to prevent pneumococcal disease in this population worldwide. Here we review the clinical trials of multivalent pneumococcal conjugate vaccines under evaluation, identify potential carrier proteins considered for development of future pneumococcal conjugate vaccines, discuss issues regarding licensure of new candidate vaccines from a clinical trial and quality control perspective, and alternative vaccine strategies for the prevention of pneumococcal disease.

Mucosal immunity induced by pneumococcal glycoconjugate.

Host defenses against Streptococcus pneumoniae involve opsonophagocytosis mediated by antibodies and complement. Because the pneumococcus is a respiratory pathogen, mucosal immunity may play an important role in the defense against infection. The mechanism for protection in mucosal immunity consists of induction of immunity by the activation of lymphocytes within the mucosal-associated lymphoid tissues, transport of antigen-specific B and T cells from inductive sites through bloodstream and distribute to distant mucosal effector sites. Secretory IgA is primarily involved in protection of mucosal surfaces. Mucosal immunization is an effective way of inducing immune responses at mucosal surfaces. Several mucosal vaccines are in various stages of development. A number of mucosal adjuvants have been proposed. CpG oligodeoxynucleotide (ODN) has been shown to be an effective mucosal adjuvant for various antigens. Mucosal immunity induced by intranasal immunization was studied with a pneumococcal glycoconjugate, using CpG ODN as adjuvant. Mice immunized with type 9V polysaccharide (PS) conjugated to inactivated pneumolysin (Ply) plus CpG produced high levels of 9V PS IgG and IgA antibodies compared to the group that received the conjugate alone. High levels of subclasses of IgG1, IgG2 and IgG3 antibodies were also observed in sera of mice immunized with 9V PS-Ply plus CpG. In addition, high IgG and IgA antibody responses were observed in sera of young mice immunized with 9V PS-Ply plus CpG or the conjugate plus non-CpG compared with the group received the conjugate alone. These results reveal that mucosal immunization with pneumococcal glycoconjugate using CpG as adjuvant can confer protective immunity against pneumococcal infection.

Immunologic Epitope, Gene, and Immunity Involved in Pneumococcal Glycoconjugate

Pneumococcal infection persists as a major cause of pneumonia, otitis media, and meningitis in infants. Children less than 2 years of age show the highest incidence of pneumococcal diseases. Production of monoclonal antibody (MAb) to polysaccharide (PS) and binding characteristics to PS epitopes were studied. Removal of the O-acetyl group from 9V PS by alkali hydrolysis resulted in a decreased binding with rabbit 9V antiserum (AS). However, the binding reaction with 9V MAb was less affected by the loss of O-acetyl content. Type 9V IgG MAb provided passive protection and enhanced the opsonophagocytic activity of polymorphonuclear (PMN) leukocytes to kill type 9V pneumococci. The pathogenecity of pneumococci is attributed to various virulence factors distributed on the cell surface, including capsular polysaccharide and protein antigens, for example, pneumolysin, autolysin, pneumococcal surface protein A (PspA), pneumococcal surface adhesion (PsaA), and hemin binding protein. Some of these protein antigens may be used as a component to combine with pneumococcal PS vaccine or as a carrier of conjugate vaccine. Clinical trials of pneumococcal conjugate vaccines showed that covalent linkage of capsular PS to protein carriers improved the immunogenicity of the PS. Development of glycoconjugate vaccine for selected pneumococcal types will help solve the problem of poor immunogenecity of PS vaccine in young children used for prevention of pneumococcal infection.

Production, binding characteristics and protective immunity of monoclonal antibody to pneumococcal type-9V conjugate

A monoclonal antibody (MAb) to pneumococcal type‐9V polysaccharide (PS) was produced using PS conjugated to inactivated pneumolysin as the immunogen. The MAb to 9V PS was of the IgG1 subclass. The antigen‐antibody reaction increased rapidly at low concentrations and reached a plateau at 10 μg PS/ml as measured by nephelometry of the group 9 PS against 9V MAb binding. In contrast, the binding of group 9 PS against rabbit 9V antiserum (AS) increased proportionally and continued to increase up to the highest concentration of PS tested (20 μg PS/ml). The 9V MAb reacted with all group 9 PSs (9A, 9L, 9N and 9V) by immunodiffusion. In the homologous 9V Ag‐MAb reaction, there were marked differences in the inhibition of binding by the cross‐reactive 9L PS (19.2% inhibition) and the 9N PS (0.2%). In contrast, inhibition of the homologous 9V Ag‐rabbit AS binding by cross‐reactive 9L and 9N PSs ranged from 57.8 to 62.7%. Removal of the O‐acetyl group from 9V PS by alkali hydrolysis resulted in decreased binding with rabbit 9V AS. However, the binding reaction with 9V MAb was less affected by the loss of O‐acetyl content. The 9V MAb was both opsonic and passively protected young mice against challenge with type‐9V pneumococci.