Protein serotyping of Streptococcus pneumoniae based on reactivity to six monoclonal antibodies

The Modified Surface Killing Assay Distinguishes between Protective and Nonprotective Antibodies to PspA

The most important finding of this study is that the MSKA can be used as an in vitro functional assay. Such an assay will be critical for the development of PspA-containing vaccines. The other important findings relate to the locations and nature of the protection-eliciting epitopes of PspA. There are limited prior data on the locations of protection-eliciting PspA epitopes, but those data along with the data presented here make it clear that there is not a single epitope or domain of PspA that can elicit protective antibody and there exists at least one region of the αHD which seldom elicits protective antibody. Moreover, these data, in concert with prior data, strongly make the case that protective epitopes in the αHD are highly conformational (≥100-amino-acid fragments of the αHD are required), whereas at least some protection-eliciting epitopes in the proline-rich domain are encoded by ≤15-amino-acid sequences.

Pneumococcal surface protein A (PspA) elicits antibody protective against lethal challenge by Streptococcus pneumoniae and is a candidate noncapsular antigen for inclusion in vaccines. Evaluation of immunity to PspA in human trials would be greatly facilitated by an in vitro functional assay able to distinguish protective from nonprotective antibodies to PspA. Mouse monoclonal antibodies (MAbs) to PspA can mediate killing by human granulocytes in the modified surface killing assay (MSKA). To determine if the MSKA can distinguish between protective and nonprotective MAbs, we examined seven MAbs to PspA. All bound recombinant PspA, as detected by enzyme-linked immunosorbent assay and Western blotting; four gave strong passive protection against fatal challenge, two were nonprotective, and the seventh one only delayed death. The four that were able to provide strong passive protection were also most able to enhance killing in the MSKA, the two that were not protective in mice were not effective in the MSKA, and the MAb that was only weakly protective in mice was weakly effective in the MSKA (P < 0.001). One of the four most protective MAbs tested reacted to the proline-rich domain of PspA. Two of the other most protective MAbs and the weakly protective MAb reacted with a fragment from PspA’s α-helical domain (αHD), containing amino acids (aa) 148 to 247 from the N terminus of PspA. The fourth highly protective MAb recognized none of the overlapping 81- or 100-aa fragments of PspA. The two nonprotective MAbs recognized a more N-terminal αHD fragment (aa 48 to 147).

IMPORTANCE The most important finding of this study is that the MSKA can be used as an in vitro functional assay. Such an assay will be critical for the development of PspA-containing vaccines. The other important findings relate to the locations and nature of the protection-eliciting epitopes of PspA. There are limited prior data on the locations of protection-eliciting PspA epitopes, but those data along with the data presented here make it clear that there is not a single epitope or domain of PspA that can elicit protective antibody and there exists at least one region of the αHD which seldom elicits protective antibody. Moreover, these data, in concert with prior data, strongly make the case that protective epitopes in the αHD are highly conformational (≥100-amino-acid fragments of the αHD are required), whereas at least some protection-eliciting epitopes in the proline-rich domain are encoded by ≤15-amino-acid sequences.

Epitope analyses of pneumococcal surface protein A: a combination of two monoclonal antibodies detects 94% of clinical isolates

Immunisation of BALB/c mice with seven heat-treated Norwegian clinical isolates of Streptococcus pneumoniae of different serotypes elicited mainly monoclonal antibodies (mAbs) to pneumococcal surface protein A (PspA). It was remarkable that the fusions resulted only in a few mAbs directed against other protein antigens. Dot blot analysis with 16 mAbs using clinical isolates representing 23 different capsular types and the uncapsulated reference strain R36A showed that some of the mAbs bound to PspA epitopes expressed by a low number of strains whereas others bound to broadly distributed epitopes. On the basis of their reactivities, seven of these mAbs could be divided into two groups recognising different subsets of pneumococci. The three mAbs in the narrow reacting group bound to epitopes found in 21-25% of the strains whereas the four mAbs in the broad reacting group detected more than 57% of the analysed strains. The epitopes for these seven antibodies were surface exposed on live exponential phase grown pneumococci as shown by flow cytometry. The finding that a combination of mAb 180,C-1 (IgG2a) from the first group and mAb 170,E-11 (IgG2a) from the second group detected 94% of the examined strains is interesting because PspA has been reported by others to be a serological highly variable protein.

Pneumococcal diversity: considerations for new vaccine strategies with emphasis on pneumococcal surface protein A (PspA)

Streptococcus pneumoniae is a problematic infectious agent, whose seriousness to human health has been underscored by the recent rise in the frequency of isolation of multidrug-resistant strains. Pneumococcal pneumonia in the elderly is common and often fatal. Young children in the developing world are at significant risk for fatal pneumococcal respiratory disease, while in the developed world otitis media in children results in substantial economic costs. Immunocompromised patients are extremely susceptible to pneumococcal infection. With 90 different capsular types thus far described, the diversity of pneumococci contributes to the challenges of preventing and treating S. pneumoniae infections. The current capsular polysaccharide vaccine is not recommended for use in children younger than 2 years and is not fully effective in the elderly. Therefore, innovative vaccine strategies to protect against this agent are needed. Given the immunogenic nature of S. pneumoniae proteins, these molecules are being investigated as potential vaccine candidates. Pneumococcal surface protein A (PspA) has been evaluated for its ability to elicit protection against S. pneumoniae infection in mouse models of systemic and local disease. This review focuses on immune system responsiveness to PspA and the ability of PspA to elicit cross-protection against heterologous strains. These parameters will be critical to the design of broadly protective pneumococcal vaccines.

Comparison of the PspA sequence from Streptococcus pneumoniae EF5668 to the previously identified PspA sequence from strain Rx1 and ability of PspA from EF5668 to elicit protection against pneumococci of different capsular types

PspA (pneumococcal surface protein A) is a serologically varied virulence factor of Streptococcus pneumoniae. In mice, PspA has been shown to elicit an antibody response that protects against fatal challenge with encapsulated S. pneumoniae, and the protection-eliciting residues have been mapped to the alpha-helical N-terminal half of the protein. To date, a published DNA sequence for pspA is available only for S. pneumoniae Rx1, a laboratory strain. PspA/EF5668 (EF5668 indicates the strain of origin of the PspA) is serologically distinct from PspA/Rx1. Sequencing of the gene encoding PspA/EF5668 revealed 71% identity with that of PspA/Rx1. The greatest amount of divergence between the two proteins was seen in their alpha-helical portions, which are surface exposed and probably under selective pressure to diversify serologically. In spite of the diversity within the alpha-helical regions of PspAs, we have observed that recombinant PspA (rPspA)/EF5668, like rPspA/Rx1, can elicit cross-protection against pneumococci of different capsular and PspA serological types.

Molecular localization of variable and conserved regions of pspA and identification of additional pspA homologous sequences in Streptococcus pneumoniae

PspA is anchored to the surface of all pneumococci by the C-terminal end of the molecule. The N-terminal half of PspA is known to be serologically variable and to be able to elicit protective immune responses. Molecular analysis with DNA probes spanning different regions of pspA was carried out to identify homologous sequences among pneumococcal isolates. At high stringency, DNA probes derived from the 3'-half of pspA (encoding the C-terminal half of PspA) hybridized to all of 37 pneumococcal isolates tested, representing 20 capsular serotypes and 12 PspA serotypes. Most strains had two sequences highly homologous to this region of pspA. Using derivatives of strain Rx1, with insertion mutations in pspA, it was possible to identify the functional pspA sequence. At 50% stringency, the 3' pspA probes also detected lytA and additional sequences. lytA encodes autolysin and shares homology with the 3' portion of pspA. A probe derived from the 5'-half of pspA (encoding the N-terminal half of PspA) hybridized with only 75% of strains and generally detected only one of the two sequences recognized by the 3' probes. Thus, the 3'-half of pspA appears to contain more highly conserved sequences than the 5'-half of pspA and shares homology with several additional sequences, suggesting that the pneumococcus might make several proteins that interact with the surface by the same mechanism as PspA.

Strong association between capsular type and virulence for mice among human isolates of Streptococcus pneumoniae

The relationship between capsular type and virulence for mice was examined with 69 fresh human isolates of Streptococcus pneumoniae. These isolates represented eight capsular types or groups. Serologic and molecular weight differences in PspA (pneumococcal surface protein A) indicated that the strains were clonally distinct. Mice were infected intravenously with washed bacteria of all 69 isolates in sterile salt solutions. Twenty-eight of the isolates were also injected intraperitoneally to permit comparisons between the intravenous and intraperitoneal routes. With a few exceptions, there was concordance between the ability of strains to cause fatal infections by the two routes. About 30% of the 69 isolates were virulent for mice. The abilities of the isolates to kill mice and the length of time between inoculation and death were strongly associated with capsular type. All type 4 isolates, 40% of type 3 isolates, and 60% of group 6 isolates were virulent for mice; type 1 isolates were marginally virulent; and all type or group 14, 19, and 23 isolates were avirulent. Times to death were generally longer for mice infected with group 6 or type 1 than for those infected with type 3 or 4 pneumococci. There was no relationship between clinical diagnosis or tissue source of the isolates and virulence for mice.

A 43-kilodalton pneumococcal surface protein, PspA: isolation, protective abilities, and structural analysis of the amino-terminal sequence

PspA is an antigenically variable surface protein of Streptococcus pneumoniae that appears to be essential for full pneumococcal virulence. In addition, monoclonal antibodies to PspA protect mice against infection with specific strains of pneumococci virulent for mice. In this study, we have isolated the 43-kDa N-terminal half of the native 84-kDa PspA and determined the sequence of the first 45 amino acids. This sequence, the first obtained for a pneumococcal surface protein, is consistent with that of an amphiphatic coiled-coil alpha helix with a 7-residue periodicity common to fibrous proteins such as tropomyosin and streptococcal M protein. The 7-residue periodicity begins with residue 8 and extends throughout the remaining sequence for nearly 11 turns of the helix. Mice immunized with this purified PspA segment were protected from fatal pneumococcal challenge, thus demonstrating that those PspA epitopes eliciting protection were present in the N-terminal half of the molecule.

Pneumococcal surface protein A (PspA) is serologically highly variable and is expressed by all clinically important capsular serotypes of Streptococcus pneumoniae

Pneumococcal surface protein A (PspA) has been shown previously to elicit antibodies protective against pneumococcal infection and to be necessary for full pneumococcal virulence in mice. The protein was originally defined by the two mouse monoclonal antibodies Xi64 and Xi126, which together recognized PspA on 14% of pneumococcal isolates. Some PspA molecules reacted with both antibodies, but most reacted with only one or the other. In the present study we demonstrated that PspA is produced by all pneumococci, confirming our hypothesis that there are variants of PspA which are not detected by Xi64 and Xi126. We produced a rabbit antiserum and five additional monoclonal antibodies specific for PspA for these studies. The rabbit antiserum reacted with each of 95 pneumococcal isolated tested, comprising 16 capsular serotypes. One or more of the seven monoclonal anti-PspA antibodies reacted with 95% (53 of 57) of pneumococcal isolates tested. The specificity of the monoclonal and polyclonal antibodies to PspA was confirmed in two ways: (i) by detection of molecules on wild-type pneumococci that are identical in molecular weight to those detected in Western blots (immunoblots) with Xi64 and Xi126 and (ii) by the use of mutants of Streptococcus pneumoniae that fail to produce PspA or that produce a truncated form of PspA. By using the seven monoclonal antibodies, we observed 31 PspA types among the 57 isolates. When the 53 strains reactive with the monoclonal antibodies were analyzed by capsular type as well as by serologic type and molecular weight of PspA, we observed 50 different clonotypes of pneumococci.

Variation in the molecular weight of PspA (pneumococcal surface protein A) among Streptococcus pneumoniae

Pneumococcal surface protein A (PspA) has been shown to be a virulence factor of pneumococci and to elicit protective anti-pneumococcal antibodies in mice. PspAs from different pneumococcal isolates have been shown to exhibit antigenic variability. In previous studies with three strains, two different apparent molecular weights of PspA were observed. In this report we have studied the variation in molecular weight of PspA from 43 pneumococcal strains reactive with anti-PspA monoclonal antibodies, Xi64 and/or Xi126. The relative molecular mass (Mr) of the major PspA band ranged from 67 k to 99 k in the different strains. Variations in Mr of PspA were observed even within strains of the same capsular type. The molecular size of PspA from strain Rx1 was not affected by treatment with a variety of chemical, enzymatic, and physical procedures, suggesting that the differences in Mr of PspA among different strains, was not due to uncontrolled variations in PspA preparation. The Mr of PspA of a given strain was found to be stable both in vivo and in vitro. As a result variations in the Mr of PspA from clinical isolates, should allow discrimination between strains within a given capsular type in epidemiologic studies.

Antipneumococcal effects of C-reactive protein and monoclonal antibodies to pneumococcal cell wall and capsular antigens

Antibodies to pneumococcal capsular polysaccharides are well known for their ability to protect against pneumococcal infection. Recent studies indicate that antibodies to cell wall antigens, including pneumococcal surface protein A and the phosphocholine (PC) determinant of teichoic acids as well as human C-reactive protein (which also binds to PC), can protect mice against pneumococcal infection. In the present study we compared the protective effects of these agents as measured by mouse protection, the blood bactericidal assay, and clearance of pneumococci from the blood and peritoneal cavity. Our findings extend previous results indicating that human C-reactive protein and antibodies to noncapsular antigens are generally less protective than anticapsular antibodies. The new results obtained indicate the following: (i) mouse protection studies with intraperitoneal and intravenous infections provide very similar results; (ii) monoclonal immunoglobulin G2a (IgG2a) antibodies to PC, like IgG1, IgG2b, and IgG3 antibodies to PC, are highly protective against pneumococcal infection in mice; (iii) human antibody to PC is able to protect against pneumococcal infection in mice; (iv) antibodies to PspA are effective at mediating blood and peritoneal clearance of pneumococci; (v) complement is required for the in vivo protective effects of both IgG and IgM antibodies to PC; (vi) IgG1, IgG2b, and IgG3 anti-PC antibodies all mediate complement-dependent lysis of PC-conjugated erythrocytes; and (vii) antibodies and human C-reactive proteins that are reactive with capsular antigens but not cell wall antigens are able to mediate significant antibacterial activity in the blood bactericidal assay.