The 13-valent pneumococcal conjugate vaccine (PCV13) elicits cross-functional opsonophagocytic killing responses in humans to Streptococcus pneumoniae serotypes 6C and 7A.

The introduction of a 7-valent pneumococcal conjugate vaccine (PCV7) in 2000 dramatically reduced the incidence of invasive pneumococcal disease (IPD) caused by the seven serotypes covered by the vaccine. Following the introduction of PCV7, which contains a serotype 6B conjugate, some decrease in IPD due to serotype 6A was noted suggesting that the serotype 6B conjugate provided some partial cross-protection against serotype 6A. However, no effect on serotype 6C was observed. In 2010, a pneumococcal conjugate vaccine with expanded serotype coverage (PCV13) was introduced that expanded the serotype coverage to 13 serotypes including serotype 6A. To assess whether the 6A conjugate in PCV13 could potentially induce functional anti-6C antibody responses, an opsonophagocytic assay (OPA) for serotype 6C was developed. Randomly chosen subsets of immune sera collected from infants receiving three doses of PCV7 or PCV13 were tested in OPA assays for serotype 6A, 6B and 6C. PCV7 immune sera demonstrated strong OPA responses, defined as percentage of subjects having an OPA titer ≥1:8, to serotype 6B (100% responders), partial responses to serotype 6A (70% responders) but only minimal responses to serotype 6C (22% responders). In contrast, PCV13 immune sera showed strong OPA responses to serotypes 6A (100% responders), 6B (100% responders) and 6C (96% responders). Furthermore, during pre-clinical work it was observed that serotype 7F (included in PCV13) and serotype 7A (not included in PCV13) shared serogroup-specific epitopes. To determine whether such epitopes also may be eliciting cross-functional antibody, PCV13 immune sera were also tested in serotype 7A and 7F OPA assays. All PCV13 immune sera demonstrated OPA responses to both of these serotypes. Taken together these results suggest that immunization with PCV13 has the potential to induce cross-protective responses to related serotypes not directly covered by the vaccine.

Immunogenicity and safety of CRM197 conjugated 9-valent pneumococcal and meningococcal C combination vaccine in healthy infants.

Streptococcus pneumoniae and Neisseria meningitidis cause invasive disease in children aged <2 years. While individual conjugate vaccines are available to protect this age group against these pathogens, availability of a vaccine combining these antigens into a single injection is desirable. This study randomized 467 healthy infants to receive 4 doses of combination 9-valent pneumococcal and meningococcal serogroup C conjugate vaccine (9vPnC-MnCC) or 9-valent pneumococcal conjugate vaccine (9vPnC). Percentages of subjects achieving immunoglobulin G (IgG) antibody concentrations ≥0.35µg/mL and geometric mean IgG concentrations for each pneumococcal serotype in the 9vPnC-MnCC group were noninferior compared to the 9vPnC group. Both vaccines were well-tolerated.

13-valent pneumococcal conjugate vaccine immune sera protects against pneumococcal serotype 1, 3, and 5 bacteremia in a neonatal rat challenge model.

PCV7 was first licensed in the United States in 2000 based on clinical efficacy studies. Since the introduction, PCV7 has demonstrated protective effectiveness for each of the vaccine serotypes. More recently, PCV13 has been licensed in more than 60 countries based on serological noninferiority to PCV7 for the shared serotypes and noninferiority to the least immunogenic serotypes of PCV7 for the additional 6 serotypes in PCV13. To evaluate whether the functional antibody responses to serotypes 1, 3, and 5 were sufficient to protect animals challenged with virulent strains of these serotypes, rhesus macaques were immunized with three clinical doses of PCV13. The macaques mounted robust anti-capsular polysaccharide IgG and opsonophagocytic killing (OPA) responses to each serotype contained in the vaccine. Pooled pre-immunization sera and post-immunization serum pools were tested in a neonatal rat bacteremia model. Passive transfer of pooled post-immunization sera, but not pre-immunization sera, protected neonatal rats from lethal IP challenge with serotype 1, 3, or 5 strains. The functional activity of PCV13 immune sera against a virulent type 3 strain was further evaluated using sera from human children immunized with 4 doses of PCV7 or PCV13. Pooled sera from children immunized with PCV13, but not pooled sera from children immunized with PCV7, which does not contain the serotype 3 polysaccharide conjugate, protected neonatal rats from lethal IP challenge with a highly encapsulated and virulent serotype 3 strain. These data suggest that PCV13 will provide protection against pneumococcal serotype 1, 3, and 5 disease in human populations, even at relatively low OPA titers.

Thermodynamics and density of binding of a panel of antibodies to high-molecular-weight capsular polysaccharides.

The interaction between antipolysaccharide (anti-PS) antibodies and their antigens was investigated by the use of isothermal titration calorimetry to determine the thermodynamic binding constant (K), the change in the enthalpy of binding (DeltaH), and the binding density (N) to high-molecular-weight PSs. From these values, the change in the entropy of binding (DeltaS) was calculated. The thermodynamic parameters of binding to high-molecular-weight capsular PSs are reported for two monoclonal antibodies (MAbs) with different specificities for meningococcal serogroup C PS, five MAbs specific for different pneumococcal serotypes, and the Fab fragments of two antipneumococcal MAbs. The K values were in the range of 10(6) to 10(7) M(-1), and these values were 1 to 2 orders of magnitude greater than the previously reported K values derived from antibody-oligosaccharide interactions. The DeltaH associated with binding was favorable for each MAb and Fab fragment. The DeltaS associated with binding was also generally favorable for both the MAbs and the Fab fragments, with the exception of the anti-serotype 14 MAb and its Fab fragment. N provides information regarding how densely MAbs or Fabs can bind along PS chains and, as expressed in terms of monosaccharides, was very similar for the seven MAbs, with an average of 12 monosaccharides per bound MAb. The value of N for each Fab was smaller, with five or seven monosaccharides per bound Fab. These results suggest that steric interactions between antibody molecules are a major influence on the values of N of high-affinity MAbs to capsular PSs.

Estimating the protective concentration of anti-pneumococcal capsular polysaccharide antibodies.

Estimates of minimum protective antibody concentrations for vaccine preventable diseases are of critical importance in assessing whether new vaccines will be as effective as those for which clinical efficacy was shown directly. We describe a method for correlating pneumococcal anticapsular antibody responses of infants immunized with pneumococcal conjugate (PnC) vaccine (Prevenar) with clinical protection from invasive pneumococcal disease (IPD). Data from three double blind controlled trials in Northern Californian, American Indian and South African infants were pooled in a meta-analysis to derive a protective concentration of 0.35 microg/ml for anticapsular antibodies to the 7 serotypes in Prevenar. This concentration has been recommended by a WHO Working Group as applicable on a global basis for assessing the efficacy of future pneumococcal conjugate vaccines. The WHO Working Groups anticipated that modifications in antibody assays for pneumococcal anticapsular antibodies would occur. The principles for determining whether such assay modifications should change the protective concentration are outlined. These principles were applied to an improvement in the ELISA for anticapsular antibodies, i.e. absorption with 22F pneumococcal polysaccharide, which increases the specificity of the assay for vaccine serotype anticapsular antibodies by removing non-specific antibodies. Using sera from infants in the pivotal efficacy trial in Northern California Kaiser Permanente (NCKP), 22F absorption resulted in minimal declines in pneumococcal antibody in Prevenar immunized infants but significant declines in unimmunized controls. Recalculation of the protective concentration after 22F absorption resulted in only a small decline from 0.35 microg/ml to 0.32 microg/ml. These data support retaining the 0.35 microg/ml minimum protective concentration recommended by WHO for assessing the efficacy of pneumococcal conjugate vaccines in infants.

Avidity of the immunoglobulin G response to a Neisseria meningitidis group C polysaccharide conjugate vaccine as measured by inhibition and chaotropic enzyme-linked immunosorbent assays.

Antibody avidity, the strength of the multivalent interaction between antibodies and their antigens, is an important characteristic of protective immune responses. We have developed an inhibition enzyme-linked immunosorbent assay (ELISA) to measure antibody avidity for the capsular polysaccharide (PS) of Neisseria meningitidis group C (MnC) and determined the avidity constants (K(D)s) for 100 sera from children immunized with an MnC PS conjugate vaccine. The avidity constants were compared to the avidity indices (AI) obtained for the same sera using a chaotropic ELISA protocol. After the primary immunization series, the geometric mean (GM) K(D) was 674 nM and did not change in the months following immunization. However, the GM avidity did increase after the booster dose (GM K(D), 414 nM 1 month after booster immunization). In contrast, the GM AI increased from an initial value of 118 after the primary immunization series to 147 6 months after the completion of the primary immunization series and then further increased to 178 after booster immunization. At the individual subject level, the avidity constant and AI correlated after the primary immunization series and after booster immunization but not prior to boosting. This work suggests that the AI, as measured by the chaotropic ELISA, in contrast to the K(D), reflects changes that render antibody populations less susceptible to disruption by chaotropic agents without directly affecting the strength of the binding interactions.

Analysis of human serum immunoglobulin G against O-acetyl-positive and O-acetyl-negative serogroup W135 meningococcal capsular polysaccharide.

The capsular polysaccharide of Neisseria meningitidis serogroup W135 is expressed in both O-acetyl-positive (OA+) and O-acetyl-negative (OA-) forms. This study investigates the impact of OA status (OA+ versus OA-) on serological measurements of anti-W135 immunoglobulin G (IgG) antibodies in immunized adults. W135-specific serum antibody assignments were made for 28 postimmunization sera from adults by enzyme-linked immunosorbent assay using the meningococcal standard reference serum CDC1992. The established IgG concentration in micrograms per milliliter ([IgG]microg/ml) for CDC1992 against OA+ antigen (16.2 microg/ml) was used as a reference to assign a concentration of 10.13 microg/ml IgG against OA- antigen by cross-standardization. Overall, the IgG assignments for these sera were higher against OA+ antigen (geometric mean concentration [GMC] = 7.16 microg/ml) than against OA- antigen (GMC = 2.84 microg/ml). However, seven sera showed higher specific [IgG]microg/ml values against the OA+ antigen than against the OA- antigen. These sera were also distinguished by the inability of fluid-phase OA- antigen to compete for antibody binding to OA+ solid-phase antigen. Although there was no overall difference in functional activity measured by complement-mediated serum bactericidal assay (SBA) against OA+ and OA- target bacteria (geometric mean titers of 9,642 and 9,045, respectively), three serum specimens showed a large difference in SBA antibody titers against OA+ versus OA- W135 target bacteria, which may reflect different epitope specificities for these sera. Our data indicate that, for some sera, the agreement in anti-OA+ versus anti-OA- W135 IgG assignments is serum specific and does not reflect the functional (killing) activity in vitro.