Alan Basset

RrgA and RrgB Are Components of a Multisubunit Pilus Encoded by the Streptococcus pneumoniae rlrA Pathogenicity Islet

ABSTRACT The rlrA pathogenicity islet in Streptococcus pneumoniae TIGR4 encodes three surface proteins, RrgA, RrgB, and RrgC, and three sortase enzymes. Using transmission electron microscopy, cell fractionation, cell wall sorting signal domain swapping, and Western blotting, we show that RrgA and RrgB are incorporated into a multisubunit pilus in S. pneumoniae.

Antibody-Independent, CD4+ T-Cell-Dependent Protection against Pneumococcal Colonization Elicited by Intranasal Immunization with Purified Pneumococcal Proteins

ABSTRACT Immunity to pneumococcal colonization in mice by exposure to live or killed pneumococci has been shown to be antibody independent but dependent on CD4+ T cells. Here we show that intranasal immunization with pneumococcal proteins (pneumococcal surface protein C, adhesin A, and a pneumolysoid) can elicit a similar mechanism of protection. Colonization could be significantly reduced in mice congenitally deficient in immunoglobulins after intranasal immunization with this mixture of proteins; conversely, the depletion of CD4+ T cells in immunized wild-type mice at the time of challenge eliminated the protection afforded by immunization. Overall, our results show that intranasal immunization with a mixture of pneumococcal proteins protects against colonization in an antibody-independent, CD4+ T-cell-dependent manner.

Protection against Nasopharyngeal Colonization by Streptococcus pneumoniae Is Mediated by Antigen-Specific CD4 T Cells

ABSTRACT CD4+ T-cell-dependent acquired immunity confers antibody-independent protection against pneumococcal colonization. Since this mechanism is poorly understood for extracellular bacteria, we assessed the antigen specificity of the induction and recall of this immune response by using BALB/c DO11.10Rag−/− mice, which lack mature B and T cells except for CD4+ T cells specific for the OVA323-339 peptide derived from ovalbumin. Serotype 6B Streptococcus pneumoniae strain 603S and unencapsulated strain Rx1ΔlytA were modified to express OVA323-339 as a fusion protein with surface protein A (PspA) (strains 603OVA1 and Rx1ΔlytAOVA1) or with PspA, neuraminidase A, and pneumolysin (Rx1ΔlytAOVA3). Whole-cell vaccines (WCV) were made of ethanol-killed cells of Rx1ΔlytA plus cholera toxin (CT) adjuvant, of Rx1ΔlytAOVA1 + CT (WCV-OVA1), and of Rx1ΔlytAOVA3 + CT (WCV-OVA3). Mice intranasally immunized with WCV-OVA1, but not with WCV or CT alone, were protected against intranasal challenge with 603OVA1. There was no protection against strain 603S in mice immunized with WCV-OVA1. These results indicate antigen specificity of both immune induction and the recall response. Effector action was not restricted to antigen-bearing bacteria since colonization by 603S was reduced in animals immunized with vaccines made of OVA-expressing strains when ovalbumin or killed Rx1ΔlytAOVA3 antigen was administered around the time of challenge. CD4+ T-cell-mediated protection against pneumococcal colonization can be induced in an antigen-specific fashion and requires specific antigen for effective bacterial clearance, but this activity may extend beyond antigen-expressing bacteria. These results are consistent with the recruitment and/or activation of phagocytic or other nonspecific effectors by antigen-specific CD4+ T cells.

Association of the Pneumococcal Pilus with Certain Capsular Serotypes but Not with Increased Virulence

ABSTRACT The recent discovery of a mobile genetic element encoding a pilus-like structure in Streptococcus pneumoniae and the demonstration of a role for the pilus in virulence in mice have led to the proposal of the use of the pilus as a candidate pneumococcal vaccine. We examined the frequency of occurrence of the pneumococcal pilus, as determined by the presence of the rrgC gene, and analyzed its association with virulence, capsular serotypes, and multilocus sequence types in the American Indian pneumococcal collection and isolates of S. pneumoniae from blood cultures collected at Childrens Hospital Boston. Overall, 21.4% of strains in the American Indian collection had the rrgC gene, but there was no difference between isolates obtained from the nasopharynx and those obtained from sterile sites (blood or cerebrospinal fluid). Vaccine-type strains were significantly more likely than non-vaccine-type strains to have this pilus gene (P < 0.001). Among isolates with identical multilocus sequence types, there was a high concordance (95%) between the multilocus sequence type and the presence or the absence of rrgC. Finally, in the era of the pneumococcal conjugate vaccine, the frequency of rrgC in isolates from Childrens Hospital Boston has decreased significantly (42.8% before 2000 versus 21.3% after 2000; P = 0.019). Therefore, our data show that the pilus is present in a minority of strains and is associated with certain serotypes and that its frequency has been reduced by the conjugate pneumococcal vaccine.

A single gene that promotes interaction of a phytopathogenic bacterium with its insect vector, Drosophila melanogaster

Insects are major vectors of plant and animal disease, and bacterial phytopathogens are often disseminated by flies. We have previously reported that some isolates of the phytopathogenic bacterial species Erwinia carotovora infect Drosophila and activate an immune response. Using a genetic screen, we have now identified two genes that are required by E. carotovora to infect Drosophila. One of these genes has a regulatory role whereas the other, evf, confers an infectious phenotype: its transfer to non‐infectious Erwinia strains or to several enterobacteria improves survival in the gut and triggers the immune response. Overexpression of Erwinia virulence factor(evf) allowed bacteria to colonize the apical side of the gut epithelium and in some cases to spread to the body cavity. Our results demonstrate a specific interaction between plant pathogens and flies that promote their dissemination.

The pneumococcal pilus predicts the absence of Staphylococcus aureus co-colonization in pneumococcal carriers

The determinants of the negative association between Streptococcus pneumoniae and Stapylococcus aureus colonization are unknown. In this matched case-control study, the odds of co-colonization with S. aureus were significantly lower for individuals carrying a piliated versus a nonpiliated S. pneumoniae strain, suggesting the pilus may be a determinant of the negative association.

Toll-like Receptor (TLR) 2 Mediates Inflammatory Responses to Oligomerized RrgA Pneumococcal Pilus Type 1 Protein

Background: The pneumococcal pilus is associated with increased inflammation. Results: A 49-amino acid region of the pilus protein RrgA activates TLR2 and is associated with increased inflammation and virulence. Conclusion: The pneumococcal pilus is a TLR2 agonist; RrgA is a key component. Significance: A better understanding of the pilus in bacterial pathogenesis is crucial for the development of novel strategies against this pathogen. The pneumococcal type 1 pilus is an inflammatory and adherence-promoting structure associated with increased virulence in mouse models. We show that RrgA, an ancillary pilus subunit devoid of a lipidation motif, particularly when presented as part of an oligomer, is a TLR2 agonist. The surface-exposed domain III, and in particular a 49-amino acid sequence (P3), of the protein is responsible for the TLR2 activity of RrgA. A pneumococcal mutant carrying RrgA with a deletion of the P3 region was significantly reduced in its ability to activate TLR2 and induce TNF-α responses after mouse intraperitoneal infection, whereas no such difference could be noted when TLR2−/− mice were challenged, further implicating this region in recognition by TLR2. Thus, we conclude that the type 1 pneumococcal pilus can activate cells via TLR2, and the ancillary pilus subunit RrgA is a key component of this activation.

Expression of the Type 1 Pneumococcal Pilus Is Bistable and Negatively Regulated by the Structural Component RrgA

ABSTRACT The pneumococcal type 1 pilus, which is present in 25 to 30% of clinical isolates, has been associated with increased adherence and inflammatory responses and is being evaluated as a potential vaccine candidate. Here we show that expression of the pilus is bistable as a result of the molecular interaction between the transcription activator RrlA and a structural component of the pilus called RrgA. Sampling various clinical pneumococcal isolates that harbor the type 1 pilus-encoding islet, we show that distinct populations of cells can be identified with either undetectable or prominent pilus expression. When these two populations are separated and regrown in liquid medium, they are phenotypically different: the nonexpressing population reverts to the previous bimodal distribution, whereas the expressing population retains the same high level of pilus expression. Controlled exogenous expression of the regulatory pilus gene rlrA in a strain from which the endogenous version has been deleted increases pilus expression steadily, suggesting that the bistable expression of the pilus observed in wild-type cells is dependent on the native rlrA promoter. Finally, we demonstrate that RrgA is a negative regulator of pilus expression and that this repression is likely mediated through direct interaction with RlrA. We conclude that type 1 pilus expression in pneumococcus exhibits a bistable phenotype, which is dependent upon the molecular interplay between the RlrA and RrgA proteins. We suggest that this flexibility in expression may assist adaptation to a range of immune conditions, such as evasion of antipilus antibodies, within potential hosts.

NKBOR, a mini-Tn10-based transposon for random insertion in the chromosome of Gram-negative bacteria and the rapid recovery of sequences flanking the insertion sites in Escherichia coli

We have constructed an R6K-based suicide vector that permits the random insertion of a mini-transposon named NKBOR into the chromosome of Gram-negative bacteria and the subsequent rapid cloning of sequences flanking the insertion site in Escherichia coli. This mini-transposon contains a conditional R6K plasmid origin of replication, a kanamycin resistance gene and unique restriction sites between the IS10 inverted repeats. NKBOR can be propagated by replication in an E. coli strain containing the R6K replicase pi protein. Alternatively the mini-transposon can be replicated in a pSC 101 derivative that is thermosensitive for its replication so that the mini-transposon acts as a suicide plasmid at nonpermissive temperatures. Efficient NKBOR transposition is ensured by expression of an adjacent transposase gene and has been demonstrated in E. coli, Klebsiella pneumoniae, and Erwinia carotovora. Sequences flanking the insertion sites in these strains can be rapidly recovered and identified in E. coli strains expressing the R6K pi protein.

An Epigenetic Switch Mediates Bistable Expression of the Type 1 Pilus Genes in Streptococcus pneumoniae

Expression of the pneumococcal type 1 pilus is bistable and positively regulated by the transcription factor RlrA. RlrA is also known to positively control its own expression. Here we present evidence that bistable expression of the type 1 pilus is mediated by the positive-feedback loop controlling rlrA expression.