Alexander H. Lucas

Recurrent variable region gene usage and somatic mutation in the human antibody response to the capsular polysaccharide of Streptococcus pneumoniae type 23F.

ABSTRACT Combinatorial cloning and expression library analysis were used to isolate human antibody Fab fragments specific for the capsular polysaccharide of Streptococcus pneumoniae serotype 23F. Thirty 23F-specific Fabs were isolated from seven vaccinated donors, and the sequences of the heavy (H)- and light (L)-chain variable regions were determined. All individuals utilized either the Vκ A23 L chain, the Vκ L6 L chain, or both chains in forming the 23F-specific combining site. Vκ A23 L chains paired primarily with VH3-23 H chains. Vκ L6 L chains were more promiscuous in heavy-chain usage between individuals. Both H and L chains were mutated, primarily in the complementarity-determining regions, compared to their closest germ line counterpart, suggesting a recall response that has undergone affinity maturation. H-chain isotypes were reflective of those found in the serum. Shared somatic modifications demonstrated that immunoglobulin G2 (IgG2) and IgA antibodies arose from the same somatically matured B cell. Our results indicate that the response to the serotype 23F pneumococcal capsular polysaccharide is oligoclonal within the individual, with one or two paratope families accounting for the majority of expressed antibody. We also determined that, in spite of the combinatorial diversity available to the immune system, the 23F-specific response is highly restricted at the population level, with the same two L-chain-determined paratope families recurring in all individuals. Lastly, analysis of the isolated Fabs indicate all have undergone extensive somatic mutation, as well as class switch, maturational events that presumably require the participation of T cells.

Increased Immunogenicity and Induction of Class Switching by Conjugation of Complement C3d to Pneumococcal Serotype 14 Capsular Polysaccharide

ABSTRACT Previous studies have demonstrated an adjuvant effect for the C3d fragment of complement C3 when coupled to T-dependent protein antigens. In this study, we examined the antibody response to covalent conjugates of C3d and a T-independent antigen, the capsular polysaccharide of serotype 14 Streptococcus pneumoniae (PPS14). We prepared a conjugate of mouse C3d and PPS14 and compared its immunogenicity with that of a conjugate of PPS14 and ovalbumin (OVA). When BALB/c mice were immunized with PPS14-C3d, there was a significant increase in serum anti-PPS14 concentrations compared with either native PPS14 or control PPS14-glycine conjugates. This was accompanied by a switch in anti-PPS14 from predominantly immunoglobulin M (IgM) to IgG1 by day 25 following primary immunization. Following secondary immunization with PPS14-C3d, there was a marked booster response and a further increase in the ratio of IgG1 to IgM anti-PPS14. Although the primary antibody response to the PPS14-OVA conjugate exceeded that induced by immunization with PPS14-C3d, serum anti-PPS14 concentrations after a second injection of PPS14-C3d were nearly identical to those induced by secondary immunization with PPS14-OVA. Experiments with athymic nude mice suggested that T cells were not required for the adjuvant effect of C3d on the primary immune response to PPS14 but were necessary for enhancement of the memory response after a second injection of PPS14-C3d. These studies show that the adjuvant effects of C3d extend to T-independent antigens as well as T-dependent antigens. As a means of harnessing the adjuvant potential of the innate immune system, C3d conjugates may prove useful as a component of vaccines against encapsulated bacteria.

Effect of immunity to the carrier protein on antibody responses to Haemophilus influenzae type b conjugate vaccines

The anticapsular antibody responses to some Haemophilus influenzae type b (Hib) conjugate vaccines may be enhanced by prior or simultaneous administration of the carrier protein used in the conjugate. Currently, there are two Hib conjugate vaccines licensed in the USA for use in infants beginning at 2 months of age: Hib polysaccharide coupled to an outer membrane protein complex of Neisseria meningitidis (PRP-OMPC), and Hib oligosaccharides conjugated to CRM197, a non-toxic mutant diphtheria toxin (HbOC). The PRP-OMPC conjugate vaccine is immunogenic in infant monkeys and infant humans in the absence of carrier priming or additional carrier vaccination. The mechanism responsible for this immunogenicity is unknown but may relate to the adjuvanticity of the OMPC carrier. In contrast, data from infant rhesus monkeys and infant humans suggest that there may be a need for vaccination with diphtheria toxoid in order to maximize anti-PRP antibody responses to the HbOC conjugate. In addition, immunization with HbOC alone appears to be insufficient to elicit an antibody response to diphtheria toxoid. Thus, the need for additional vaccination with diphtheria toxoid in order to generate consistent anti-PRP antibody responses to HbOC may be a result of failure of the CRM197 protein carrier to elicit T-cell help. In infants in whom diphtheria-tetanus-pertussis (DTP) vaccination is deferred because of medical contraindications, vaccination with the PRP-OMPC conjugate would appear to be preferable to HbOC because of the ability of the former to elicit antibody responses in the absence of diphtheria toxoid vaccination.

Combinatorial library cloning of human antibodies to Streptococcus pneumoniae capsular polysaccharides: Variable region primary structures and evidence for somatic mutation of Fab fragments specific for capsular serotypes 6B, 14, and 23F

ABSTRACT Antibodies specific for capsular polysaccharides play a central role in immunity to encapsulated Streptococcus pneumoniae, but little is known about their genetics or the variable (V) region polymorphisms that affect their protective function. To begin to address these issues, we used combinatorial library cloning to isolate pneumococcal polysaccharide (PPS)-specific Fab fragments from two vaccinated adults. We determined complete V region primary structures and performed antigen binding analyses of seven Fab fragments specific for PPS serotype 6B, 14, or 23F. Fabs were of the immunoglobulin G2 or A isotype. Several VHIII gene segments (HV 3-7, 3-15, 3-23, and 3-11) were identified. VL regions were encoded by several κ genes (KV 4-1, 3-15, 2-24, and 2D-29) and a λ gene (LV 1-51). Deviation of the VH and VL regions from their assigned germ line counterparts indicated that they were somatically mutated. Fabs of the same serotype specificity isolated from a single individual differed in affinity, and these differences could be accounted for either by the extent of mutation among clonal relatives or by usage of different V-region genes. Thus, functionally disparate anti-PPS antibodies can arise within individuals both by activation of independent clones and by intraclonal somatic mutation. For one pair of clonally related Fabs, the more extensively mutated VH was associated with lower affinity for PPS 14, a result suggesting that somatic mutation could lead to diminished protective efficacy. These findings indicate that the PPS repertoire in the adult derives from memory B-cell populations that have class switched and undergone extensive hypermutation.

Variable region expression in the antibody responses of infants vaccinated with Haemophilus influenzae type b polysaccharide-protein conjugates. Description of a new lambda light chain-associated idiotype and the relation between idiotype expression, avidity, and vaccine formulation. The Collaborative Vaccine Study Group.

Haemophilus influenzae b polysaccharide (Hib PS)-protein conjugate vaccines differ chemically and immunologically. To determine whether anti-Hib PS variable region expression might differ according to vaccine formulation, infants were vaccinated at 2, 4, and 6 mo of age with Hib PS coupled to either meningococcal outer membrane protein complex (Hib PS-OMPC) or tetanus toxoid (Hib PS-T), or Hib PS oligomers coupled to a mutant diphtheria toxin (Oligo-CRM). Two anti-Hib PS idiotypes were measured in sera obtained after the third injection: HibId-1, expressed by anti-Hib PS antibodies having the kappa II-A2 variable region, and HibId-2, a newly defined cross-reactive idiotype associated with a subset of anti-Hib PS antibodies having lambda VII variable regions. HibId-1 was present in 33, 68, and 64% of infants given either Hib PS-OMPC, Oligo-CRM, or Hib PS-T, respectively (P < 0.001). The respective values for HibId-2 were 47, 18, and 10% (P = 0.001). Subjects who were vaccinated with Hib PS-OMPC or Hib PS-T and who produced detectable HibId-1-positive antibody, had significantly higher mean antibody avidity than subjects who did not produce HibId-1 positive antibodies. In contrast, Oligo-CRM evoked high avidity anti-Hib PS antibodies, irrespective of the idiotypic profile. These findings indicate fundamental differences in both variable region content and antibody quality elicited by different Hib PS conjugate vaccines.

Induction of opsonic antibodies to the γ-D-glutamic acid capsule of Bacillus anthracis by immunization with a synthetic peptide-carrier protein conjugate

The capsule of Bacillus anthracis, a polymer of gamma-D-glutamic acid, functions as a virulence determinant and is a poor immunogen. In this study we show that antibodies reactive with the B. anthracis capsule can be elicited in mice by immunization with a conjugate consisting of a synthetic gamma-D-glutamic acid nonamer peptide (gamma-D-glu9) covalently coupled to keyhole limpet hemocyanin. The serum response to gamma-D-glu9 was comprised primarily of IgG antibodies that recognized an epitope requiring a minimum of four gamma-linked D-glutamic acid residues. Antibodies to (gamma-D-glu9) bound to the surface of encapsulated B. anthracis cells and mediated opsonophagoctosis. These findings suggest that anti-capsular antibodies could mediate the clearance of vegetative B. anthracis cells in vivo. Thus, inclusion of an immunogenic capsular component as well as protective antigen in new anthrax vaccines would generate immune responses targeting both the bacteremic and toxigenic aspects of anthrax infection and thus may increase protective efficacy.

Polysaccharide vaccines as probes of antibody repertoires in man.

Summary: Antibodies specific for capsular polysaccharide epitopes mediate immunity to encapsulated bacterial pathogens, and accordingly, vac‐cine development has focused upon the induction of these specificities. Efficacious vaccines, consisting of either polysaccharide alone or polysaccharide coupled to protein carriers, have been developed for a number of pathogens. Their clinical importance not with standing, these vaccines serve as model antigens to study the genetic and somatic forces molding adaptive immunity in man. In this article we review progress aimed at delineating the structure and dynamics of the human antibody repertoire to the Hoemophilus influenzoe type b poiysaccharide (Hib PS), a system which has been studied from infancy to old age. Collectively, the data reveal a repertoire which is encoded by a relatively iarge number of germline variable (V) region gene segments, but which is typically expressed within individuals as a markedly restricted, oligoclonal population. One particular V domain has attained canonical status because of its high penetrance at the population level and its predominance in individual repertoires, Although this combining site is assembled in early infancy and retains its prominence throughout life, its frequency of expression, affinity and protective function are dictated by the molecular form of the Hib PS immunogen (vaccine). The determinants of Hib PS binding affinity can include both germline and somatically‐acquired V region polymorphisms. We discuss how these properties of the Hib PS repertoire could impact immunity to Htb, and we consider the implications of these findings towards understanding die evolution of immunoglobulin germline V genes.

Functional activity of anti-Neisserial surface protein A monoclonal antibodies against strains of Neisseria meningitidis serogroup B.

ABSTRACT Neisserial surface protein A (NspA) is currently being investigated with humans as a candidate vaccine for the prevention of meningococcal disease. Although NspA is highly conserved, the ability of anti-NspA antibodies to bind to or elicit complement-mediated bactericidal activity against diverse Neisseria meningitidis serogroup B strains is controversial. To evaluate strain differences in NspA surface accessibility and susceptibility to bactericidal activity, we prepared murine immunoglobulin G2a anti-NspA monoclonal antibodies (MAbs) and evaluated their functional activity against 10 genetically diverse N. meningitidis serogroup B strains. By colony Western blot, all 10 strains expressed NspA as detected by one or more MAbs. By flow cytometry, two MAbs were found to bind to the bacterial surface of 6 of the 10 strains. In addition, two strains showed variable NspA surface accessibility for the MAbs despite being uniformly positive for NspA expression by colony Western blotting. Only 4 of the 10 strains were susceptible to anti-NspA complement-mediated bacteriolysis. Passively administered MAb protected infant rats from developing bacteremia after challenge with N. meningitidisserogroup B strain 8047 (surface binding positive, susceptible to anti-NspA bacteriolysis), was poorly protective against strain BZ232 (surface binding variable, resistant to bacteriolysis), and did not protect against strain M986 (surface binding negative, resistant to bacteriolysis). Finally, NspA does not appear to be critical for causing bacteremia, as an NspA knockout from strain 8047 was highly virulent in infant rats. Taken together, these findings suggest that an NspA-based vaccine will need to incorporate additional antigens to elicit broad protection against N. meningitidis serogroup B.

Carbohydrate Moieties as Vaccine Candidates

Abstract Carbohydrate epitopes or glycotopes are structurally diverse, occur in a variety of chemical contexts, and are present on the surfaces of cells in the body and on the surfaces of pathogens. These various structures and modes of presentation affect how they are perceived and processed by the body and dictate the outcome of the immune response directed against them. This review focuses on mechanisms of carbohydrate immunity, with an emphasis on carbohydrate vaccines that have been or are being developed for protection against encapsulated bacterial pathogens. We discuss the cellular basis of carbohydrate immunity, newly identified glycotope processing pathways and recognition capabilities, and the synthetic and microarray technologies that are being developed that will permit new experimental approaches to carbohydrate vaccine development and the exploration of the interaction of the immune system with self and nonself glycans.

Igg subclass-restricted immune responses to allergens

The IgG responses to a variety of allergens are predominated by IgG1 and IgG4 antibodies. With several allergens, the IgG1 response appears to precede the IgG4 response and this switch may be driven by repeated allergen exposure. It remains to be determined whether there is any causal relationship between subclass restriction and the regulation of specific IgE. The question of whether IgG4 antibodies are protective or pathological is still unresolved. Human models are needed to further analyze the interrelationships between T cells, cytokines and B cell isotype expression. The antibody response to allergens appears to be an ideal experimental system for studying antigen-specific isotype regulation in humans. The subclass patterns are remarkably reproducible between individuals, and allergic and normal human subjects, who have been immunized naturally or therapeutically, are readily available as a source of cells. Isolation of allergen-specific T cells that putatively regulate subclass expression would seem to be a worthwile endeavor. Understanding the molecular and cellular events that initiate and control isotype expression will play an important role in the rational design of immunogens and therapeutics, aimed at optimizing protective immunity and diminishing the pathological effects of autoimmune and allergic responses.