The C-terminal fragment of the internal 110-kilodalton passenger domain of the Hap protein of nontypeable Haemophilus influenzae is a potential vaccine candidate

Nontypeable Haemophilus influenzae is a major causative agent of bacterial otitis media in children. H. influenzae Hap autotransporter protein is an adhesin composed of an outer membrane Hapβ region and a moiety of an extracellular internal 110-kDa passenger domain called Hap(S). The Hap(S) moiety promotes adherence to human epithelial cells and extracellular matrix proteins, and it also mediates bacterial aggregation and microcolony formation. A recent work (D. L. Fink, A. Z. Buscher, B. A. Green, P. Fernsten, and J. W. St. Geme, Cell. Microbiol. 5:175-186, 2003) demonstrated that Hap(S) adhesive activity resides within the C-terminal 311 amino acids (the cell binding domain) of the protein. In this study, we immunized mice subcutaneously with recombinant proteins corresponding to the C-terminal region of Hap(S) from H. influenzae strains N187, P860295, and TN106 and examined the resulting immune response. Antisera against the recombinant proteins from all three strains not only recognized native Hap(S) purified from strain P860295 but also inhibited H. influenzae Hap-mediated adherence to Chang epithelial cells. Furthermore, when mice immunized intranasally with recombinant protein plus mutant cholera toxin CT-E29H were challenged with strain TN106, they were protected against nasopharyngeal colonization. These observations demonstrate that the C-terminal region of Hap(S) is capable of eliciting cross-reacting antibodies that reduce nasopharyngeal colonization, suggesting utility as a vaccine antigen for the prevention of nontypeable H. influenzae diseases

PppA, a Surface-Exposed Protein of Streptococcus pneumoniae, Elicits Cross-Reactive Antibodies That Reduce Colonization in a Murine Intranasal Immunization and Challenge Model

The multivalent pneumococcal conjugate vaccine is effective against both systemic disease and otitis media caused by serotypes contained in the vaccine. However, serotypes not covered by the present conjugate vaccine may still cause pneumococcal disease. To address these serotypes, and the remaining otitis media due to Streptococcus pneumoniae, efforts have been devoted to identifying protective protein antigens. Immunity to conserved surface proteins important for adhesion, nutrient acquisition, or other functions could result in a reduction of colonization and a lower disease potential. We have been searching for conserved surface-exposed proteins from S. pneumoniae that may be involved in pathogenesis to test as vaccine candidates. Here, an ∼20-kDa protein that has significant homology to a nonheme iron-containing ferritin protein from Listeria innocua and other bactoferritins was identified as pneumococcal protective protein A (PppA). We expressed and purified recombinant PppA (rPppA) and evaluated its potential as a vaccine candidate. The antibodies elicited by purified rPppA were cross-reactive with PppA from multiple strains of S. pneumoniae and were directed against surface-exposed epitopes. Intranasal immunization of BALB/c mice with PppA protein and either a synthetic monophosphoryl lipid A analog, RC529AF, or a cholera toxin mutant, CT-E29H, used as an adjuvant reduced nasopharyngeal colonization in mice following intranasal challenge with a heterologous pneumococcal strain. PppA-specific systemic and local immunoglobulin G (IgG) and IgA antibody responses were induced. The antisera reacted with whole cells of a heterologous S. pneumoniae type 3 strain. These observations indicate that PppA may be a promising candidate for inclusion in a vaccine against pneumococcal otitis media

Preclinical evidence for the potential of a bivalent fHBP vaccine to prevent Neisseria meningitidis serogroup C disease

A bivalent factor H binding protein (fHBP) vaccine for the prevention of disease caused by Neisseria meningitidis serogroup B is currently in clinical development. Since fHBP is also expressed by other meningococcal serogroups, antifHBP antibodies may have bactericidal activity against meningococci independent of serogroup. To begin examining the susceptibility of other meningococcal serogroups to anti-fHBP antibodies, meningococcal serogroup C invasive isolates (n = 116) were collected from the Centers for Disease Control and Prevention's Active Bacterial Core surveillance (ABCs) sites during 2000–2001. These isolates were analyzed for the presence of the fhbp gene. All serogroup C isolates contained the gene, and sequence analysis grouped the proteins into two subfamilies, A and B. Flow cytometry analysis demonstrated that fHBP was expressed on the surface of ∼70% of isolates in vitro with varying levels of expression. fHBP was accessible to antibodies on the cell surface even in the presence of the polysaccharide capsule. Nine isolates from different geographic regions were identified which harboured an identical single nucleotide deletion that could result in a truncated subfamily B fHBP. Analysis by flow cytometry using a polyclonal fHBP antibody preparation revealed that a subpopulation of each of these isolates expressed fHBP. rabbit and non-human primate immune sera generated with bivalent fHBP vaccine were tested for bactericidal activity against a panel of diverse serogroup C clinical isolates using human complement. Sera from both species demonstrated serum bactericidal antibody activity against the serogroup C isolates tested. These promising findings suggest that a bivalent fHBP vaccine may be capable of providing protection against meningococcal disease caused by both serogroup C and B