Two structural transitions in membrane pore formation by pneumolysin, the pore-forming toxin of Streptococcus pneumoniae.

The human pathogen Streptococcus pneumoniae produces soluble pneumolysin monomers that bind host cell membranes to form ring-shaped, oligomeric pores. We have determined three-dimensional structures of a helical oligomer of pneumolysin and of a membrane-bound ring form by cryo-electron microscopy. Fitting the four domains from the crystal structure of the closely related perfringolysin reveals major domain rotations during pore assembly. Oligomerization results in the expulsion of domain 3 from its original position in the monomer. However, domain 3 reassociates with the other domains in the membrane pore form. The base of domain 4 contacts the bilayer, possibly along with an extension of domain 3. These results reveal a two-stage mechanism for pore formation by the cholesterol-binding toxins.     

Structure and molecular mechanism of a functional form of pneumolysin: a cholesterol-dependent cytolysin from Streptococcus pneumoniae

One of the key steps in understanding human disease arising from gram-positive bacteria lies in the mechanisms of the cholesterol-dependent cytolysins (CDCs). Pneumolysin (PLY), a CDC from Streptococcus pneumoniae, is of special importance due to the severe impacts of pneumococcal infections on mortality and morbidity worldwide. We have overexpressed, purified, and characterized PLY in its fully functional complex form with the enzyme bound to its receptor activator on target cells, cholesterol. The circular dichroism studies of PLY in solution with an excess of cholesterol show a change in the far UV spectrum consistent with a decrease in the beta-sheet and an increase in the random coil structures of the enzyme. Pore formation in membranes leading to cell lysis is the functional target for this cytolysin. The sedimentation velocity and equilibrium analyses of the cholesterol-bound enzyme show hydrodynamic properties different from those of the cholesterol-free form. The soluble form of the cholesterol-free enzyme exists in solution as a mixture of monomers and dimers, whereas the cholesterol-bound form exists only as a monomer. A mechanism of formation of PLY pores in the lipid bilayer of the target cells is discussed.     

Structure and function of pneumolysin, the multifunctional, thiol-activated toxin of Streptococcus pneumoniae

Pneumolysin is a thiol-activated, membrane-damaging, multifunctional toxin and a known virulence factor of Streptococcus pneumoniae. The toxin can interfere with the functioning of both cellular and soluble components of the human immune system which protects against pneumococcal infection. Different amino acids within the toxin which are important in promoting oligomerization of the toxin in membranes and for the generation of functional lesions have been identified by site-directed mutagenesis. Pneumolysin can also activate the classical pathway of complement, and this appears to involve antibody binding (via Fc) by a region of the toxin homologous to C-reactive protein, a human acute-phase protein also capable of classical pathway activation and implicated in host defence against pneumococcal infection.     

Essential role of domain 4 of pneumolysin from Streptococcus pneumoniae in cytolytic activity as determined by truncated proteins

Pneumolysin (PLY), an important virulence factor of Streptococcus pneumoniae, is one of the members of thiol-activated cytolysins (TACYs) consisting of four domains. TACYs commonly bind to membrane cholesterol and oligomerize to form transmembrane pore. We have constructed full-length and various truncated PLYs to study the role of domains of PLY in the cytolytic activity. Full-length PLY had binding ability to both cell membrane and immobilized cholesterol. A truncated PLY which comprised only domain 4 molecule, the C-terminal domain of PLY, sustained the binding ability to cell membrane and cholesterol, whereas domain 1-3 molecule had no binding ability to them. Furthermore, the domain 4 molecule inhibited both the membrane binding and the hemolytic activity of full-length PLY. Accordingly, the present results provided the direct evidence that domain 4 was essential for the initial binding to membrane cholesterol and the interaction led to the subsequent membrane damage process.     

Characterization of Streptococcus pneumoniae isolated from children with otitis media

Streptococcus pneumoniae is the main causative agent of acute otitis media in children. Serotype-based vaccines have provided some protection against otitis media, but not as much as anticipated, demonstrating the need for alternative vaccine options. Pneumococcal otitis media isolates were obtained from children 5 years old or younger from hospitals around Mississippi in the prevaccine era (1999-2000). These isolates were compared by capsular typing, pneumococcal surface protein A (PspA) family typing, antibiotic susceptibility, and DNA fingerprinting. Our study shows that there is great genetic variability among pneumococcal clinical isolates of otitis media, except with regard to PspA. Therefore, efforts focused on the development of a PspA-based pneumococcal vaccine would be well placed.     

Additive inhibition of complement deposition by pneumolysin and PspA facilitates Streptococcus pneumoniae septicemia

Streptococcus pneumoniae is a common cause of septicemia in the immunocompetent host. To establish infection, S. pneumoniae has to overcome host innate immune responses, one component of which is the complement system. Using isogenic bacterial mutant strains and complement-deficient immune naive mice, we show that the S. pneumoniae virulence factor pneumolysin prevents complement deposition on S. pneumoniae, mainly through effects on the classical pathway. In addition, using a double pspA-/ply- mutant strain we demonstrate that pneumolysin and the S. pneumoniae surface protein PspA act in concert to affect both classical and alternative complement pathway activity. As a result, the virulence of the pspA-/ply- strain in models of both systemic and pulmonary infection is greatly attenuated in wild-type mice but not complement deficient mice. The sensitivity of the pspA-/ply- strain to complement was exploited to demonstrate that although early innate immunity to S. pneumoniae during pulmonary infection is partially complement-dependent, the main effect of complement is to prevent spread of S. pneumoniae from the lungs to the blood. These data suggest that inhibition of complement deposition on S. pneumoniae by pneumolysin and PspA is essential for S. pneumoniae to successfully cause septicemia. Targeting mechanisms of complement inhibition could be an effective therapeutic strategy for patients with septicemia due to S. pneumoniae or other bacterial pathogens.     

A role in cell-binding for the C-terminus of pneumolysin, the thiol-activated toxin of Streptococcus pneumoniae

Abstract Cell binding of pneumolysin to target cells is an important step in the lysis of cells by this toxin. We sought to locate the cell-binding region of pneumolysin. Deletion of the six C-terminal amino acids decreased cell-binding activity by 98%. Furthermore mutagenesis of an amino acid near the C-terminus decreased the cell-binding activity of full-length pneumolysin by 90%. The C-terminus of pneumolysin has an important role in cell-binding activity.     

Expression and purification of FtsW and RodA from Streptococcus pneumoniae,two membrane proteins involved in cell division and cell growth,respectively

FtsW and RodA are homologous integral membrane proteins involved in bacterial cell division and cell growth, respectively. Both proteins from Streptococcus pneumoniae were overexpressed in Escherichia coli as N-terminal His-tagged fusions. Their membrane addressing in E. coli was demonstrated by cell fractionation and was confirmed for FtsW by immunolocalization. Recombinant FtsW and RodA were solubilized from membranes using 3-(laurylamido)-N,N'-dimethylaminopropylamine oxide (LAPAO). The detergent was exchanged to polyoxyethylene 8 lauryl ether (C12E8) during one-step purification procedure by Co(2+)-affinity chromatography. This procedure yielded 50-150 microg protein per litre of culture. Both proteins are likely to be folded as they are resistant to trypsin digestion and could be incorporated into reconstituted lipid vesicles.     

Characterization of Streptococcus pneumoniae N-acetylglucosamine-6-phosphate deacetylase as a novel diagnostic marker

The identification of novel diagnostic markers of pathogenic bacteria is essential for improving the accuracy of diagnoses and for developing targeted vaccines. Streptococcus pneumoniae is a significant human pathogenic bacterium that causes pneumonia. N-acetylglucosamine-6-phosphate deacetylase (NagA) was identified in a protein mixture secreted by S. pneumoniae and its strong immunogenicity was confirmed in an immuno-proteomic assay against the anti-serum of the secreted protein mixture. In this study, recombinant S. pneumoniae NagA protein was expressed and purified to analyze its protein characteristics, immunospecificity, and immunogenicity, thereby facilitating its evaluation as a novel diagnostic marker for S. pneumoniae. Mass spectrometry analysis showed that S. pneumoniae NagA contains four internal disulfide bonds and that it does not undergo post-translational modification. S. pneumoniae NagA antibodies successfully detected NagA from different S. pneumoniae strains, whereas NagA from other pathogenic bacteria species was not detected. In addition, mice infected with S. pneumoniae generated NagA antibodies in an effective manner. These results suggest that NagA has potential as a novel diagnostic marker for S. pneumoniae because of its high immunogenicity and immunospecificity.     

Characterization of Streptococcus pneumoniae TrmD, a tRNA methyltransferase essential for growth

Down-regulation of expression of trmD, encoding the enzyme tRNA (guanosine-1)-methyltransferase, has shown that this gene is essential for growth of Streptococcus pneumoniae. The S. pneumoniae trmD gene has been isolated and expressed in Escherichia coli by using a His-tagged T7 expression vector. Recombinant protein has been purified, and its catalytic and physical properties have been characterized. The native enzyme displays a molecular mass of approximately 65,000 Da, suggesting that streptococcal TrmD is a dimer of two identical subunits. In fact, this characteristic can be extended to several other TrmD orthologs, including E. coli TrmD. Kinetic studies show that the streptococcal enzyme utilizes a sequential mechanism. Binding of tRNA by gel mobility shift assays gives a dissociation constant of 22 nM for one of its substrates, tRNA(Leu)(CAG). Other heterologous nonsubstrate tRNA species, like, tRNA (Thr)(GGT), tRNA(Phe), and tRNA (Ala)(TGC), bind the enzyme with similar affinities, suggesting that tRNA specificity is achieved via a postbinding event(s).     

Characterization of IS1515, a Functional Insertion Sequence in Streptococcus pneumoniae

We describe the characterization of a new insertion sequence, IS1515, identified in the genome of Streptococcus pneumoniae I41R, an unencapsulated mutant isolated many years ago (R. Austrian, H. P. Bernheimer, E. E. B. Smith, and G. T. Mills, J. Exp. Med. 110:585–602, 1959). A copy of this element located in the cap1E_I41R gene was sequenced. The 871-bp-long IS1515 element possesses 12-bp perfect inverted repeats and generates a 3-bp target duplication upon insertion. The IS encodes a protein of 271 amino acid residues similar to the putative transposases of other insertion sequences, namely IS1381 from S. pneumoniae, ISL2 from Lactobacillus helveticus, IS702 from the cyanobacterium Calothrix sp. strain PCC 7601, and IS112 from Streptomyces albus G. IS1515 appears to be present in the genome of most type 1 pneumococci in a maximum of 13 copies, although it has also been found in the chromosome of pneumococcal isolates belonging to other serotypes. We have found that the unencapsulated phenotype of strain I41R is the result of both the presence of an IS1515 copy and a frameshift mutation in the cap1E_I41R gene. Precise excision of the IS was observed in the type 1 encapsulated transformants isolated in experiments designed to repair the frameshift. These results reveal that IS1515 behaves quite differently from other previously described pneumococcal insertion sequences. Several copies of IS1515 were also able to excise and move to another locations in the chromosome of S. pneumoniae. To our knowledge, this is the first report of a functional IS in pneumococcus.     

Characterization of colony morphology variants isolated from Streptococcus pneumoniae biofilms

In this study, we report the isolation of colony morphology variants from Streptococcus pneumoniae serotype 3 biofilms. The colony variants differed in colony size (large, medium, and small) and their mucoid appearance on blood agar. The small nonmucoid variant (SCV) emerged during the initial attachment stage of S. pneumoniae biofilm formation and dominated over the course of biofilm growth. Mucoid variants appeared at later biofilm developmental stages. The reduction in colony size/mucoidy correlated with a decrease in capsule production and an increase in initial attachment. The large mucoid variant formed flat unstructured biofilms, failed to aggregate in liquid culture, and adhered poorly to solid surfaces. In contrast, SCVs autoaggregated in liquid culture, hyperadhered to solid surfaces, and formed biofilms with significant three-dimensional structure, mainly in the form of microcolonies. The variants showed similar antibiotic resistance/susceptibility based on a modified Kirby-Bauer test and when grown as biofilms. However, antimicrobial treatment of S. pneumoniae biofilms altered the colony variant's distribution and mainly affected the most interior areas of biofilm microcolonies. To further explore the nature of the variants, the capsule biosynthetic operon (cps3DSUM) was explored in greater detail. The genetic analysis indicated that the emergence of nonmucoid variants was due to a deletion comprising cps3DSU as well as additional genes upstream of the cps3 operon. Overall, our findings suggest that in vitro biofilm formation of S. pneumoniae serotype 3 coincides with the emergence of colony variants with distinct genotypic and phenotypic characteristics.     

Glycosyltransferase domain of penicillin-binding protein 2a from Streptococcus pneumoniae is membrane associated

Penicillin-binding proteins (PBPs) are bacterial cytoplasmic membrane proteins that catalyze the final steps of the peptidoglycan synthesis. Resistance to beta-lactams in Streptococcus pneumoniae is caused by low-affinity PBPs. S. pneumoniae PBP 2a belongs to the class A high-molecular-mass PBPs having both glycosyltransferase (GT) and transpeptide (TP) activities. Structural and functional studies of both domains are required to unravel the mechanisms of resistance, a prerequisite for the development of novel antibiotics. The extracellular region of S. pneumoniae PBP 2a has been expressed (PBP 2a*) in Escherichia coli as a glutathione S-transferase fusion protein. The acylation kinetic parameters of PBP 2a* for beta-lactams were determined by stopped-flow fluorometry. The acylation efficiency toward benzylpenicillin was much lower than that toward cefotaxime, a result suggesting that PBP 2a participates in resistance to cefotaxime and other beta-lactams, but not in resistance to benzylpenicillin. The TP domain was purified following limited proteolysis. PBP 2a* required detergents for solubility and interacted with lipid vesicles, while the TP domain was water soluble. We propose that PBP 2a* interacts with the cytoplasmic membrane in a region distinct from its transmembrane anchor region, which is located between Lys 78 and Ser 156 of the GT domain.     

Genome-based identification of a carbohydrate binding module in Streptococcus pneumoniae hyaluronate lyase

Hyaluronate lyase enzymes degrade hyaluronan, the main polysaccharide component of the connective tissues of higher animals, thereby destroying the normal connective tissue structure and exposing the host tissue cells to various endo- and exogenous factors, including bacterial toxins. The 3D crystal structures of functionally active but truncated Streptococcus pneumoniae and S. agalactiae hyaluronate lyases, along with their substrate and product complexes, have been determined. The enzymes are multidomain proteins with helical barrel-like catalytic domains and two types of beta-sheet domains. Here, through genome-based bioinformatics studies we identify an additional beta-sheet domain present in the most N-terminal part of streptococcal hyaluronate lyases. Fold recognition and modeling studies show that the domain is structurally similar to carbohydrate binding modules and is therefore likely to be directly involved in hyaluronan binding. Likely carbohydrate binding residues were identified and electrostatic complementarity of the hyaluronate lyase domain with hyaluronan demonstrated. The newly identified presumed hyaluronan binding domain likely improves catalytic efficiency by colocalizing the enzyme and its substrate. Other possible functions are discussed. Two contacting aromatic residues are conserved in the hydrophobic core of the hyaluronate lyase domain and in many, perhaps all, families in the superfamily in which they may be placed. This observation may help the identification and classification of other carbohydrate binding modules.     

Isolation and analysis of cell wall components from Streptococcus pneumoniae

The complex and heterogeneous cell wall of the pathogenic bacterium Streptococcus pneumoniae is composed of peptidoglycan and a covalently attached wall teichoic acid. The net-like peptidoglycan is formed by glycan chains that are crosslinked by short peptides. We have developed a method to purify the glycan chains, and we show that they are longer than approximately 25 disaccharide units. From purified peptidoglycan, we released 50 muropeptides that differ in the length of their peptides (tri-, tetra-, or pentapeptides with or without mono- or dipeptide branch), the degree of peptide crosslinking (monomer, dimer, or trimer), and the presence of modifications in the glycan chains (N-deacetylation, O-acetylation, or lack of GlcNAc or GlcNAc-MurNAc) or peptides (glutamic acid instead of glutamine). We also established a method to isolate wall teichoic acid chains and show that the most abundant chains have 6 or 7 repeating units. Finally, we obtained solid-state nuclear magnetic resonance spectra of whole insoluble cell walls. These novel tools will help to characterize mutant strains, cell wall-modifying enzymes, and protein-cell wall interactions.     

Identification of ComW as a new component in the regulation of genetic transformation in Streptococcus pneumoniae

Regulation of competence for genetic transformation in Streptococcus pneumoniae depends on a quorum-sensing system, genes involved in DNA uptake and recombination and a link between these two gene sets. The alternative sigma factor ComX provides this link. ComE, the response regulator of the quorum-sensing system, is required for expression of ComX and other early genes. However, an unknown ComE-dependent regulator is also required for competence when comX is expressed under control of the raffinose-responsive promoter of the aga operon. The gene comW (SP0018) is required for a high level of competence and is regulated by the quorum-sensing system, but its function is unknown. To explore its role further, comW was cloned into the multicopy plasmid pMSP3535, under the control of a nisin-inducible promoter (P(N)), and transformed into pneumococcal strains containing a raffinose-inducible comX gene (P(R)::comX). Further introduction of a comE deletion blocked the endogenous CSP signal transduction pathway. In the resulting strain, competence was independent of CSP but depended on treatment with both nisin and raffinose, showing that coexpression of comW and comX complemented the comE deficiency. ComX protein accumulation and expression of a late competence gene in the above strain support the conclusion that ComW is a new positive factor involved in competence regulation.     

Pyruvate oxidase, as a determinant of virulence in Streptococcus pneumoniae

Pneumococcus has been shown to bind to epithelial cells of the nasopharynx and lung, and to endothelial cells of the peripheral vasculature. To characterize bacterial elements required for attachment to these cell types, a library of genetically altered pneumococci with defects in exported proteins was screened for the loss of attachment to glycoconjugates representative of the nasopharyngeal cell receptor, type II lung cells (LC) and human endothelial cells (EC). A mutant was identified which showed a greater than 70% loss in the ability to attach to all cell types. This mutant also showed decreased adherence to the glycoconjugates containing the terminal sugar residues GalNAcβ1-3Gal, GalNAcβ1-4Gal and the carbohydrate GlcNAc, which are proposed components of the pneumococcal receptors specific to the surfaces of LC and EC. Analysis of the locus altered in this mutant revealed a gene, spxB, that encodes a member of the family of bacterial pyruvate oxidases which decarboxylates pyruvate to acetyl phosphate plus H₂O₂ and CO₂. This mutant produced decreased concentrations of H₂O₂ and failed to grow aerobically in a chemically defined medium, unless supplemented with acetate which presumably restores acetyl phosphate levels by the action of acetate kinase, further suggesting that spxB encodes a pyruvate oxidase. The addition of acetate to the growth medium restored the adherence properties of the mutant indicating a link between the enzyme and the expression of bacterial adhesins. A defect in spxB corresponded to impaired virulence of the mutant in vivo. Compared to the parent strain, an spxB mutant showed reduced virulence in animal models for nasopharyngeal colonization, pneumonia, and sepsis. We propose that a mutation in spxB leads to down-regulation of the multiple adhesive properties of pneumococcus which, in turn, may correlate to diminished virulence in vivo     

Characterization of Inflammatory Responses During Intranasal Colonization with Streptococcus pneumoniae

Nasopharyngeal colonization by Streptococcus pneumoniae is a prerequisite to invasion to the lungs or bloodstream¹. This organism is capable of colonizing the mucosal surface of the nasopharynx, where it can reside, multiply and eventually overcome host defences to invade to other tissues of the host. Establishment of an infection in the normally lower respiratory tract results in pneumonia. Alternatively, the bacteria can disseminate into the bloodstream causing bacteraemia, which is associated with high mortality rates², or else lead directly to the development of pneumococcal meningitis. Understanding the kinetics of, and immune responses to, nasopharyngeal colonization is an important aspect of S. pneumoniae infection models.Our mouse model of intranasal colonization is adapted from human models³ and has been used by multiple research groups in the study of host-pathogen responses in the nasopharynx^4-7. In the first part of the model, we use a clinical isolate of S. pneumoniae to establish a self-limiting bacterial colonization that is similar to carriage events in human adults. The procedure detailed herein involves preparation of a bacterial inoculum, followed by the establishment of a colonization event through delivery of the inoculum via an intranasal route of administration. Resident macrophages are the predominant cell type in the nasopharynx during the steady state. Typically, there are few lymphocytes present in uninfected mice⁸, however mucosal colonization will lead to low- to high-grade inflammation (depending on the virulence of the bacterial species and strain) that will result in an immune response and the subsequent recruitment of host immune cells. These cells can be isolated by a lavage of the tracheal contents through the nares, and correlated to the density of colonization bacteria to better understand the kinetics of the infection.