SCM, a novel M-like protein from Streptococcus canis, binds (mini)-plasminogen with high affinity and facilitates bacterial transmigration

Streptococcus canis is an important zoonotic pathogen capable of causing serious invasive diseases in domestic animals and humans. In the present paper we report the binding of human plasminogen to S. canis and the recruitment of proteolytically active plasmin on its surface. The binding receptor for plasminogen was identified as a novel M-like protein designated SCM (S. canis M-like protein). SPR (surface plasmon resonance) analyses, radioactive dot-blot analyses and heterologous expression on the surface of Streptococcus gordonii confirmed the plasminogen-binding capability of SCM. The binding domain was located within the N-terminus of SCM, which specifically bound to the C-terminal part of plasminogen (mini-plasminogen) comprising kringle domain 5 and the catalytic domain. In the presence of urokinase, SCM mediated plasminogen activation on the bacterial surface that was inhibited by serine protease inhibitors and lysine amino acid analogues. Surface-bound plasmin effectively degraded purified fibrinogen as well as fibrin clots, resulting in the dissolution of fibrin thrombi. Electron microscopic illustration and time-lapse imaging demonstrated bacterial transmigration through fibrinous thrombi. The present study has led, for the first time, to the identification of SCM as a novel receptor for (mini)-plasminogen mediating the fibrinolytic activity of S. canis.     

Impact of different environmental conditions on the aggregation of biogenic U(IV) nanoparticles synthesized by <Emphasis Type="Italic">Desulfovibrio alaskensis</Emphasis> G20

This study investigates the impact of specific environmental conditions on the formation of colloidal U(IV) nanoparticles by the sulfate reducing bacteria (SRB, Desulfovibrio alaskensis G20). The reduction of soluble U(VI) to less soluble U(IV) was quantitatively investigated under growth and non-growth conditions in bicarbonate or 1,4-piperazinediethanesulfonic acid (PIPES) buffered environments. The results showed that under non-growth conditions, the majority of the reduced U nanoparticles aggregated and precipitated out of solution. High resolution transmission electron microscopy revealed that only a very small fraction of cells had reduced U precipitates in the periplasmic spaces in the presence of PIPES buffer, whereas in the presence of bicarbonate buffer, reduced U was also observed in the cytoplasm with greater aggregation of biogenic U(IV) particles at higher initial U(VI) concentrations. The same experiments were repeated under growth conditions using two different electron donors (lactate and pyruvate) and three electron acceptors (sulfate, fumarate, and thiosulfate). In contrast to the results of the non-growth experiments, even after 0.2 μm filtration, the majority of biogenic U(IV) remained in the aqueous phase resulting in potentially mobile biogenic U(IV) nanoparticles. Size fractionation results showed that U(IV) aggregates were between 18 and 200 nm in diameter, and thus could be very mobile. The findings of this study are helpful to assess the size and potential mobility of reduced U nanoparticles under different environmental conditions, and would provide insights on their potential impact affecting U(VI) bioremediation efforts at subsurface contaminated sites.     

Products of fermentation in the roots of alders (Alnus Mill.)

The aim of this work was to discover the products of carbohydrate fermentation in alder roots. Experiments were done with roots of trees growing in naturally wet soils. Detached, anaerobic roots accumulated ethanol, and ethanol was the major labelled product of metabolism of [U-¹⁴C]sucrose. Glycerol was not labelled from [U-¹⁴C]sucrose, and did not accumulate in detached or attached roots. In both winter and summer, roots in the field contained little or no glycerol, and the amount was less than that in the aerobic parts of the tree. Roots in the field contained substantial amounts of ethanol. We conclude that ethanol is the major product of fermentation in alder roots, and that glycerol is not a significant product. These results are not consistent with Crawford's metabolic theory of flooding tolerance.     

Domain structure and conserved epitopes of Sfb protein, the fibronectin-binding adhesin of Streptococcus pyogenes

Streptococcus pyogenes expresses a fibronectin-binding surface protein (Sfb protein) which mediates adherence to human epithelial cells. The nucleotide sequence of the sfb gene was determined and the primary sequence of the Sfb protein was analysed. The protein consists of 638 amino acids and comprises five structurally distinct domains. The protein starts with an N-terminal signal peptide followed by an aromatic domain. The central part of the protein is formed by four proline-rich repeats which are flanked by non-repetitive spacer sequences. A second repeat region, consisting of four repeats that are distinct from the proline repeats and have been shown to form the fibronectin-binding domain, is located in the Cterminal part of the protein. The protein ends with a typical cell wall and membrane anchor region. Comparative sequence analysis of the N-terminal aromatic domain revealed similarities with carbohydrate-binding sites of other proteins. The proline repeat region of the Sfb protein shares characteristic features with proline-rich repeats of functionally distinct surface proteins from pathogenic Gram-positive cocci. Immunoelectron microscopy revealed an even distribution of the fibronectin-binding domain of Sfb protein on the surface of streptococcal cells. Analyses of 38 sfb genes originating from different S. pyogenes isolates revealed primary sequence variability in regions coding for the N-termini of mature Sfb proteins, whereas sequences coding for the central and C-terminal repeats were highly conserved. The repeat sequences are postulated to act as target sites for intragenic recombination events that result in variable numbers of repeats within the different sfb genes. A model of the Sfb protein is presented.     

Vaccination equally enables both genetically susceptible and resistant mice to control infection with group A streptococci

There is substantial evidence that host genetic factors are important in determining susceptibility to infection with group A streptococci (GAS). Several studies have revealed that, similarly to humans, a genetic component may be important in determining susceptibility to GAS infection in mice. Thus, C3H/HeN mice are much more susceptible to streptococcal infection than BALB/c mice. We have determined here whether vaccination makes genetically susceptible mice as capable as genetically resistant mice to control GAS infection. Resistant BALB/c and susceptible C3H/HeN mice were immunized either systemically with heat-killed GAS or through the mucosal route with an M protein-based subunit vaccine, and challenged with live bacteria. Vaccination elicited in both mouse strains similar levels of bactericidal anti-GAS IgG antibodies and also antigen-specific mucosal IgA. Vaccination provided mice of both strains with an increased and equal capacity to express immunity against GAS as indicated by the reduced level of bacteria in the organs and the ability of vaccinated mice to survive infection. Protection in vaccinated mice was dependent on the presence of T cell-dependent bactericidal antibodies as shown by the ability of serum elicited in immunocompetent mice but not of serum elicited in T cell-deficient nu/nu mice to passively transfer anti-GAS immunity. In conclusion, the results presented here demonstrated that the presence of anti-GAS specific, T cell-dependent bactericidal antibodies elicited after vaccination overcomes the innate genetic susceptibility of C3H/HeN mice and makes both resistant and susceptible mice equally capable of controlling GAS infection.     

Identification of a novel plasmin(ogen)-binding motif in surface displayed alpha-enolase of Streptococcus pneumoniae

The interaction of Streptococcus pneumoniae with human plasmin(ogen) represents a mechanism to enhance bacterial virulence by capturing surface-associated proteolytic activity in the infected host. Plasminogen binds to surface displayed pneumococcal alpha-enolase (Eno) and is subsequently activated to the serine protease plasmin by host-derived tissue plasminogen activator (tPA) or urokinase (uPA). The C-terminal lysyl residues of Eno at position 433 and 434 were identified as a binding site for the kringle motifs of plasmin(ogen) which contain lysine binding sites. In this report we have identified a novel internal plamin(ogen)-binding site of Eno by investigating the protein-protein interaction. Plasmin(ogen)-binding activity of C-terminal mutated Eno proteins used in binding assays as well as surface plasmon resonance studies suggested that an additional binding motif of Eno is involved in the Eno-plasmin(ogen) complex formation. The analysis of spot synthesized synthetic peptides representing Eno sequences identified a peptide of nine amino acids located between amino acids 248-256 as the minimal second binding epitope mediating binding of plasminogen to Eno. Binding of radiolabelled plasminogen to viable pneumococci was competitively inhibited by a synthetic peptide FYDKERKVYD representing the novel internal plasmin(ogen)-binding motif of Eno. In contrast, a synthetic peptide with amino acid substitutions at critical positions in the internal binding motif identified by systematic mutational analysis did not inhibit binding of plasminogen to pneumococci. Pneumococcal mutants expressing alpha-enolase with amino acid substitutions in the internal binding motif showed a substantially reduced plasminogen-binding activity. The virulence of these mutants was also attenuated in a mouse model of intranasal infection indicating the significance of the novel plasminogen-binding motif in the pathogenesis of pneumococcal diseases.     

Streptococcus pyogenes recruits collagen via surface-bound fibronectin: a novel colonization and immune evasion mechanism

This study aimed to characterize matrix assembly mechanisms on the surface of the human pathogen Streptococcus pyogenes. Among 125 S. pyogenes isolates, 61% were able to recruit collagen type IV via surface-bound fibronectin. Streptococcus gordonii expressing the fibronectin-binding repeat domain of S. pyogenes SfbI protein was equally potent in recruiting collagen, indicating that this domain was sufficient to promote fibronectin-mediated collagen recruitment. Electron microscopic analysis of streptococci revealed that fibronectin-mediated collagen recruitment led to matrix deposition on and between streptococcal cells, which induced the formation of large bacterial aggregates. Furthermore, collagen-recruiting streptococci were able to colonize collagen fibres and were protected from adhering to human polymorphonuclear cells in the presence of opsonizing antibodies. Fibronectin-mediated collagen recruitment thus represents a novel aggregation, colonization and immune evasion mechanism of S. pyogenes.     

Inhibition of gene expression with double strand RNA interference in Entamoeba histolytica

In order to inhibit gene expression in Entamoeba histolytica, we have developed a method based on expressing double strand RNA interference constructs in stable transformants. The 5' end of Eh Dia was cloned head to head with an intervening non-specific stuffer fragment in the E. histolytica expression vector pJST4. This construct was transformed in E. histolytica HM1:IMSS trophozoites and stable transformants were selected with 20microg/ml G418. Our results show that expression of Eh Dia was completely inhibited in these transformants. These stable transformants could be maintained indefinitely without expression of Eh Dia. This method therefore provides an effective tool to study the phenotypic changes, which occur due to inhibition of gene expression in the absence of mutants and other microbiological manipulations in this protozoan parasite.