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Infection and Immunity, September 2006, p. 5319-5324, Vol. 74, No. 9
0019-9567/06/$08.00+0     doi:10.1128/IAI.00543-06
Copyright © 2006, American Society for Microbiology. All Rights Reserved.

The Contribution of PspC to Pneumococcal Virulence Varies between Strains and Is Accomplished by Both Complement Evasion and Complement-Independent Mechanisms

Alison R. Kerr,1 Gavin K. Paterson,1,{dagger} Jackie McCluskey,1 Francesco Iannelli,2 Marco R. Oggioni,2 Gianni Pozzi,2 and Tim J. Mitchell1*

Division of Infection and Immunity, IBLS, University of Glasgow, Glasgow, G12 8TA, United Kingdom,1 Laboratory of Molecular Microbiology and Biotechnology, Department of Molecular Biology, University of Siena, 53100 Siena, Italy2

Received 4 April 2006/ Returned for modification 16 May 2006/ Accepted 26 June 2006


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ABSTRACT
 
Pneumococcal surface protein C (PspC) is a virulence factor of Streptococcus pneumoniae previously shown to play a role in bacterial adherence, invasion, and evasion of complement. We investigated the role of this protein in our murine models of pneumococcal pneumonia with different pneumococcal strains. The deletion of pspC in strains of serotypes 2, 3, and 19F did not significantly alter host survival times in the pneumonia model. In contrast, pspC deletion significantly reduced the virulence of the serotype 4 strain, TIGR4, in both the pneumonia and bacteremia models. Therefore, pspC is a systemic and pulmonary virulence determinant for S. pneumoniae, but its effects are influenced by the pneumococcal strain. Finally, pneumonia infection of complement-deficient (C3–/–) mice enhanced pspC virulence, illustrating that PspC-mediated complement evasion contributes to virulence. However, other functions of PspC also contribute to virulence, as demonstrated by the finding that the pspC-deficient TIGR4 mutant was still attenuated relative to the wild-type parent, even in the absence of C3.


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INTRODUCTION
 
Streptococcus pneumoniae (the pneumococcus) is a human pathogen capable of causing diseases such as otitis media, meningitis, bacteremia, and pneumonia. Control of S. pneumoniae is impaired by increasing antibiotic resistance and suboptimal vaccines. As a result, there is a need for better characterization of pneumococcal virulence factors and potential vaccine antigens. One such virulence factor and vaccine candidate is pneumococcal surface protein C (PspC, also referred to as Sp2190, CbpA, SpsA, PbcA, and Hic). The pspC gene was found in all clinical strains analyzed, and a high level of variability was detected at both the pspC coding sequence and locus levels. PspC proteins show a common organization, but two major groups differing in anchor sequences may be distinguished. The first group of proteins is characterized by a typical choline binding domain while the second group shows a C-terminal LPXTG anchoring domain (13).

PspC has proven a promising vaccine candidate in mouse models (2, 5, 19). It has also been shown to contribute to virulence and nasopharyngeal colonization in mouse and rat models (2, 11, 12, 20, 27). PspC has been shown to be involved in ability to cause sepsis in an intravenous model of infection with strains of serotype 2 and 3 (12). Several functions are accredited to PspC that may contribute to its role in virulence. These include complement evasion through the binding of the complement regulator, factor H, and its recruitment onto the pneumococcal surface (8, 14, 15, 26). PspC can also bind complement component C3, human secretory immunoglobulin A (IgA), and the human polymeric Ig receptor and contributes to pneumococcal attachment and invasion (9, 10, 17, 27, 28). Recent findings indicate that the lack of PspC significantly enhances the susceptibility of pneumococci to both bactericidal activity and secretory response by the microglial cells, suggesting that this molecule may play an important role in the invasion of the central nervous system by pneumococcus (24).

To gain more insight into the role of pspC in pneumococcal virulence, we assessed pspC-deficient mutants in different strains in our murine pneumonia model. We show that the contribution of pspC to virulence in pneumonia differs between strains. In addition, the use of complement-deficient (C3–/–) mice shows that pspC contributes to virulence both through its interaction with complement and through other, complement-independent functions.


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MATERIALS AND METHODS
 
Mice. Female, 8- to 12-week-old, outbred MF1 mice (25 to 30 g) (Harlan Olac, Bicester, United Kingdom) and C57BL/6 mice (20 to 25 g) (Harlan Olac) gender matched with complement C3-deficient mice (C3/ mice [30]; bred in house; 20 to 25 g) were used. All experiments were carried out in accordance with the United Kingdom Animals (Scientific Procedures) Act 1986.

Bacteria. The pneumococcal strains used were serotype 2 (D39, NCTC 7466; Central Public Health Laboratory, London, United Kingdom), serotype 3 (HB565, a derivative of strain A66 [12]), serotype 4 (TIGR4, ATCC BAA-334), and serotype 19F (G54) (25). The PspC types of the strains (as defined in reference 13) are D39 (PspC3.1), TIGR4 (PspC3.4), G54 (PspC7.1), and HB565 (Hic). Pneumococci were cultured on blood agar base number 2 (Oxoid, Basingstoke, United Kingdom) plus 5% (vol/vol) horse blood (E&O Laboratories, Bonnybridge, United Kingdom) or brain heart infusion broth (Oxoid, Basingstoke, United Kingdom). Strains were validated via the Quellung reaction, sensitivity to optochin and multilocus sequence typing (performed at the Scottish Meningococcus and Pneumococcus Reference Laboratory, Stobhill Hospital, Glasgow, United Kingdom). The production of pspC-negative D39 and HB565 has been described elsewhere (12). In these strains, the pspC gene was deleted with a chloramphenicol resistance cassette joined by PCR on both sides to sequences flanking the pspC locus. The same cassette was used to delete the pspC locus from strains TIGR4 and G54.

For in vivo studies, pneumococci were passaged intraperitoneally through mice and stored at –80°C as previously described (1). Bacteria for infections were thawed rapidly, harvested by centrifugation, and resuspended in sterile phosphate-buffered saline (PBS; Oxoid).

Infection of mice. To induce pneumonia, mice were anesthetized with halothane and the inoculum administered intranasally in a 50-µl volume. The infectious dose for each pneumococcal strain was predetermined (106 CFU for serotypes 2, 3, and 4 and 107 CFU for serotype 19F).

For the intravenous infection for the bacteremia model, 104 CFU of wild-type and pspC-deficient TIGR4 pneumococci in a 50-µl volume were injected via a tail vein.

For both infections, signs of disease were monitored frequently until mice were deemed to have irreversibly succumbed to the infection, at which time they were humanely sacrificed. Mice displaying no signs of illness for 336 h were considered to have survived the infection.

Sample collection and processing. Following cervical dislocation, cardiac blood was sampled. To lavage the nasopharynx, the trachea was clamped and 2 ml sterile PBS passed through the nasopharynx via a 16-gauge nonpyrogenic angiocatheter (F. Baker Scientific, Runcorn, United Kingdom) was used to lavage the lungs with 2 ml PBS to give bronchoalveolar lavage fluid. Lavaged lungs were then removed and homogenized in 5 ml PBS by using a glass hand-held tissue homogenizer (Jencons, Leighton Buzzard, United Kingdom). Viable bacteria in samples were then counted by plating out serial 10-fold dilutions.

Statistical analysis. Bacteriology results are expressed as means ± 1 standard error of the mean. Samples containing fewer CFU per ml than the detection limit (log 1.92 CFU per ml for blood and log 0.92 CFU per ml for nasopharyngeal, airway, and lung samples) were ascribed a value just below the detection limit (log 1.91 or 0.91 CFU per ml). Comparisons of bacterial loads were performed using unpaired Student's t tests. Survival times were analyzed using nonparametric Mann-Whitney U analysis.

Statistical analyses were carried out using StatView 4.1 (Abacus Concepts, Berkeley, Calif.) with P values of <0.05 considered statistically significant for all analyses.


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RESULTS
 
The influence of pspC on murine survival during pneumococcal pneumonia varies between strains. We investigated the role of pspC in pneumococcal virulence in four different strains, each of a different serotype. Mice infected intranasally with D39 (serotype 2) or G54 (serotype 19F) and deficient in pspC had survival times and survival rates similar to those of mice infected with the wild-type bacteria (Fig. 1A and D). Infection of mice with pspC-deficient HB565 (serotype 3) pneumococci resulted in survival times that were not significantly different from those of wild-type bacteria, although there was a trend towards attenuation of the mutant (Fig. 1B). Mice infected with pspC-deficient HB565 had a median survival time of 140 h, while those infected with wild type had a median survival time of 75 h. It has already been shown that D39 and HB565 strains deficient in pspC are deficient in their ability to cause sepsis following intravenous infection (12).


Figure 1
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  		FIG. 1. Survival of MF1 mice (n = 5) following intranasal infection with wild-type or pspC mutant S. pneumoniae in strains D39 (A), HB565 (A66 derivative) (B), TIGR4 (C), and G54 (D). *, longer survival for mice infected with the pspC mutant bacteria than wild-type bacteria (P < 0.01).

In contrast to the case for the strains described above, there was a significant attenuation following intranasal challenge when pspC was deleted from the serotype 4 strain TIGR4. Mice intranasally infected with TIGR4 deficient in pspC survived significantly longer than those infected with wild-type bacteria (P < 0.01) (Fig. 1C). Four of five mice infected with TIGR4 pspC survived the experiment, with one dying at 98 h (median, >336 h). In contrast, all mice infected with wild-type TIGR4 succumbed by 33 h postinfection (median, 31.5 h).

To further characterize the attenuation seen with the pspC-deficient TIGR4 mutant, bacterial viable counts in the lung tissues and blood were assessed following intranasal infection. When examined 24 h following infection, the levels of pspC-deficient TIGR4 were significantly reduced within the nasopharynx, lung airways, lung tissue, and blood compared to wild-type TIGR4 (P < 0.01 for all sites) (Fig. 2).


Figure 2
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  		FIG. 2. Bacterial loads within the nasopharynx (A), lung airways (B), lung tissue (C), and blood (D) of MF1 mice (n = 5) 24 h following intranasal infection with wild-type or pspC mutant TIGR4. The dashed line represents the detection limit of the viable count assay. *, higher counts for the wild type than the mutant (P < 0.01).

TIGR4 deficient in pspC is also attenuated following intravenous infection. Following intravenous infection, mice challenged with the pspC-deficient TIGR4 mutant survived longer than mice infected with wild-type TIGR4 (P < 0.01) (Fig. 3). Four of five mice in the pspC-deficient TIGR4 group survived (median, >336 h), while all animals infected with TIGR4 died (median, 32 h). When bacterial counts were assessed 24 h postinfection, wild-type TIGR4 had reached significantly higher levels of bacteremia than the pspC mutant (P < 0.01). Mice infected with wild-type TIGR4 had ~106 CFU/ml, while pspC-deficient TIGR4 counts were only ~102 CFU/ml. All five mice infected intravenously with wild-type bacteria were bacteremic at 24 h, but only 2/5 mice infected with the pspC mutant had detectable pneumococci within their bloodstream.


Figure 3
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  		FIG. 3. Survival curve (A) and bacterial load (B) in the blood 24 h following intravenous infections of MF1 mice (n = 5) with wild-type or pspC-deficient TIGR4. The dashed line represents the detection limit of the viable count assay. *, higher counts for the wild type than the mutant (P < 0.01).

pspC contributes to virulence through complement-dependent and -independent functions. It is believed that a major role of PspC in virulence is evasion of the complement pathway via the recruitment of factor H onto the bacterial surface (14, 15, 26). We investigated this hypothesis by infecting transgenic mice deficient in complement component C3 with wild-type and pspC-deficient TIGR4. Interestingly, the deletion of C3 enhances the bacterial levels of the pspC mutant to levels similar to those seen with wild-type TIGR4 in wild-type mice in all tissues (Fig. 4). Hence, the absence of complement appears to enhance the virulence of the pspC mutant. In addition, the pspC mutant counts are significantly higher in the blood of C3–/– mice versus the pspC-deficient mutant counts in wild-type mice (Fig. 4D). There was also a trend for higher counts in the lung tissue (Fig. 4C) but not in the airway or nasopharynx (Fig. 4A and B). This indicates that evasion of complement is a major activity in which pspC is involved but that the importance of this interaction varies with body site, being most important in the blood but of minor importance in the airways and nasopharynx. However, in the absence of complement, the pspC mutant is still attenuated relative to wild-type TIGR4 with regards to bacterial counts in the airways, lung tissue, and blood. This indicates that pspC also contributes to virulence independently of its interaction with complement.


Figure 4
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  		FIG. 4. Bacterial loads within the nasopharynx (A), lung airways (B), lung tissue (C) and bloodstream (D) of C3–/– or C57BL/6 mice (n = 5) 24 h following intranasal challenge with wild-type or pspC mutant TIGR4. The dashed line represents the detection limit of the viable count assay. + and * denote levels of significance (P) of <0.05 and <0.01, respectively.

In addition, comparisons of the levels of bacteria in wild-type and C3–/– mice show the increased susceptibility of the gene knockout mice to both wild-type and mutant pneumococci (Fig. 4). Finally, in wild-type C57BL/6 mice, the pspC mutant is attenuated relative to wild-type TIGR4, showing that this phenotype is not restricted to a single mouse strain, as the earlier data were generated with MF1 mice.


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DISCUSSION
 
PspC is a known pneumococcal virulence factor with a variety of functions that likely contribute to the pathogenesis of disease. Previously, it has been shown to contribute to nasopharyngeal colonization, pneumonia, and bacteremia (2, 11, 12, 20, 27). To expand on previous data on the role of pspC during pneumococcal infections, we have compared the effect of pspC deletion in a four different strains. Furthermore, with the use of C3–/– mice, we have addressed the importance of PspC-complement interactions to virulence.

As determined by survival rates and survival times, the deletion of pspC caused significant attenuation only in the serotype 4 strain TIGR4 and not in the other three strains tested. While this does not rule out a role for pspC in the virulence of these other strains—indeed, there was a strong trend towards attenuation of the mutant in strain HB565—there was nonetheless a differential effect of deleting pspC between strains. Therefore, the influence of pspC in virulence varies between strains. Moreover, it is known that the deletion of pspC in strains D39 and HB565 causes attenuation when using a sepsis model (12). Thus, PspC seems to play a site-specific role (i.e., these strains are not attenuated in a pneumonia model but are in a sepsis model). Strain-to-strain variation in the influence of different pneumococcal virulence factors has been reported previously by our group and others (3, 7, 18, 21, 23). PspC is highly polymorphic, and this may contribute to the strain-specific effects we noted (9, 13). Interestingly, the ability to bind factor H is independent of capsule serotype. In this study, the attenuation of pspC-deficient TIGR4 was accompanied by significantly reduced bacterial counts in the lungs and blood of infected mice and was confirmed in a second mouse strain. Furthermore, the pspC-deficient TIGR4 mutant was also shown to be attenuated in a model of bacteremia following intravenous infection. Therefore, in TIGR4, pspC contributes to virulence in both pneumonia and bacteremia infections. Our data agree with and expand upon the identification of pspC in the TIGR4 signature-tagged mutagenesis screen of pneumonia virulence factors (11). Likewise, pspC has previously been shown to contribute to pneumococcal bacteremia, with strains A66 and D39 (2, 12), and to pneumonia, with strain EF3030 (2). In addition, in D39, it appears that pspC is important for translocation from the nasopharynx to the lungs and in crossing the brain-blood barrier (20). A role in colonization has also been suggested (2, 27).

The interaction of PspC with factor H recruits this complement regulator to the pneumococcal surface and acts to protect the bacterium from complement-mediated clearance (14, 15). This PspC-mediated recruitment of factor H onto the pneumococcus has been shown to occur in vivo (26). The central role of complement in immunity to the pneumococcus (22) suggests that this interaction may be important to virulence. However, this has never been assessed directly in vivo although it has been shown that preincubation with factor H enhances survival of bacteria following intravenous infection (26). To address the issue of the importance of PspC-factor H interactions during infection, we used gene knockout mice lacking C3, a central component of the complement regardless of the activation pathway. If complement evasion contributes to the function of PspC during infection, the removal of complement should restore/enhance the virulence of the mutant. Indeed, the removal of complement enhanced pspC mutant bacterial counts to levels similar to those with wild-type TIGR4 in wild-type mice. Furthermore, removal of complement increased the counts of the pspC mutant in the blood, lung tissue, and airways compared to mutant counts in the presence of complement, albeit that the difference between the lung tissue and airways was not statistically significant. Thus, pspC-complement interactions do appear to contribute to virulence. This effect was not seen in the nasopharynx and was only minimal in the airways, and so the importance of this interaction seems dependent on anatomical location, being of most importance in the blood. This is the first demonstration of the in vivo significance of pspC-mediated complement evasion. However, in the airways, lung tissue, and blood, there is still attenuation of the pspC mutant bacteria compared to wild-type bacteria in the C3–/– mice. This suggests that PspC-complement interactions are not the only contribution of PspC in this infection and that other functions, such as adherence and invasion, must also contribute. This is in contrast to previous work with a pspA mutant (29). Infection of C3–/– mice fully restored the virulence of this mutant, showing that inhibition of complement was likely to be the major role in virulence for PspA (29). Therefore, PspC contributes to pneumococcal virulence via complement-dependent and -independent mechanisms. The results of our studies and those reported previously suggest that interaction of PspC with factor H is not a human-specific interaction (11), whereas the interaction with the polymeric Ig receptor is a human-specific trait (11). The complement-independent mechanisms observed in the mouse therefore do not involve the interaction with the polymeric Ig receptor. Finally, our data showing increased susceptibility of C3–/– mice to pneumococcal infection agree with our previous work and that from others in highlighting the importance of C3 in innate immunity to the pneumococcus (4, 6, 16).

Overall, in line with the polymorphic nature of the gene, the contribution of pspC to pneumococcal virulence varies between strains. This contribution, at least in TIGR4, appears to be via complement-dependent (evasion) and other, complement-independent functions likely to involve the role of PspC in adherence and invasion.


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ACKNOWLEDGMENTS
 
Thanks to C. E. Blue (University of Glasgow) for a critical reading of the manuscript.


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FOOTNOTES
 
* Corresponding author. Mailing address: Division of Infection and Immunity, IBLS, Glasgow Biomedical Research Centre, University of Glasgow, Glasgow, G12 8TA, United Kingdom. Phone: 44 141 330 3749. Fax: 44 141 330 3727. E-mail: T.Mitchell{at}bio.gla.ac.uk. Back

Editor: J. N. Weiser

{dagger} Present address: Biomedical Sciences, DSTL, Porton Down, Salisbury, SP4 0JQ, United Kingdom. Back


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Infection and Immunity, September 2006, p. 5319-5324, Vol. 74, No. 9
0019-9567/06/$08.00+0     doi:10.1128/IAI.00543-06
Copyright © 2006, American Society for Microbiology. All Rights Reserved.



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