Importance of the carboxyl terminus in the folding and function of alpha-hemolysin of Staphylococcus aureus

Evaluation of recombinant leukocidin domain of VvhA exotoxin of Vibrio vulnificus as an effective toxoid in mouse model

Vibrio vulnificus hemolysin A (VvhA) is a pore forming toxin and plays an important role in the pathogenesis. The hemolytic and cytotytic property of VvhA toxin is associated with N-terminal leukocidin domain which triggers apoptotic signaling cascade in epithelial cells. The present study was undertaken to assess the protective efficacy of recombinant VvhA leukocidin domain (rL/VvhA) against VvhA toxin challenge using in vitro and in vivo assays. The rL/VvhA protein was found to be non-toxic with no significant hemolytic or cytotoxic effects. Intraperitoneal (I.P.) immunization of BALB/c mice with rL/VvhA protein elicited significantly higher specific serum antibody titer with mixed Th1/Th2 mediated immune responses. HeLa cell monolayer supplemented with anti-rL/VvhA antibodies were effectively protected (viability 86.69%) against lethal 5 LD50 toxin challenge. An effective in vitro proliferation of lymphocyte was observed upon re-stimulation of rL/VvhA primed splenocytes with formalin inactivated VvhA toxin (fVvhA). Co-expression of Th1/Th2 polarized cytokines (IFN-γ, IL-12 and IL-4), were seen in the cell culture supernatant. In contrast to sham immunized mice, rL/VvhA immunized mice demonstrated significant protection (90% survival) against native toxin challenge in vitro and in vivo infection models. These results suggested leukocidin domain of the VvhA toxin as protective immunogen for possible protection against V. vulnificus VvhA.

Generation and characterization of an inter-generic bivalent alpha domain fusion protein αCS from Clostridium perfringens and Staphylococcus aureus for concurrent diagnosis and therapeutic applications

AIM

 To evaluate an inter-generic recombinant alpha domain fusion protein for simultaneous detection and neutralization of Clostridium perfringens and Staphylococcus aureus alpha toxins.

METHODS AND RESULTS

 Truncated portions of clostridial and staphylococcal alpha haemolysin genes were PCR amplified and linked to each other through a hydrophilic flexible Glycine linker sequence using overlap-extension PCR to form a chimeric gene αCS. The recombinant αCS fusion protein was expressed and characterized for its toxicity, cell binding capacity and haemolysis inhibition properties. The fusion protein was nontoxic and effectively retarded staphylococcal alpha haemolysis, probably by competitively interacting with putative staphylococcal alpha haemolysin receptors on erythrocytes. Murine hyperimmune polysera raised against r-αCS specifically detected 42-kDa and 33-kDa proteins when culture supernatants of Cl. perfringens (clostridial alpha toxin) and Staph. aureus (staphylococcal alpha toxin), respectively, were analysed in Western blot. The polyclonal antisera effectively diminished the haemolytic action of both the wild-type toxins in vitro.

CONCLUSIONS

 The r-αCS fusion protein was nontoxic competitive inhibitor of staphylococcal alpha haemolysin. The protein elicited specific immune response against Cl. perfringens and Staph. aureus alpha toxins. The antisera also neutralized the toxicities of both the native wild-type toxins in vitro.

SIGNIFICANCE OF THE STUDY

 The bivalent recombinant αCS protein could be a novel intervention in the field of diagnostics and therapeutics against Cl. perfringens and Staph. aureus infections, particularly, in case of co-infections like gangrenous ischaemia, gangrenous mastitis, etc.

Molecular characterization of tlyA gene product, Rv1694 of Mycobacterium tuberculosis: a non-conventional hemolysin and a ribosomal RNA methyl transferase

Background

Mycobacterium tuberculosis is a virulent bacillus causing tuberculosis, a disease responsible for million deaths each year worldwide. In order to understand its mechanism of pathogenesis in humans and to help control tuberculosis, functions of numerous Mycobacterium tuberculosis genes are being characterized. In this study we report the dual functionality of tlyA gene product of Mycobacterium tuberculosis annotated as Rv1694, a 268 amino acid long basic protein.

Results

The recombinant purified Rv1694 protein was found to exhibit hemolytic activity in vitro. It showed concentration and time-dependent hemolysis of rabbit and human erythrocytes. Multiple oligomeric forms (dimers to heptamers) of this protein were seen on the membranes of the lysed erythrocytes. Like the oligomers of conventional, well-known, pore-forming toxins, the oligomers of Rv1694 were found to be resistant to heat and SDS, but were susceptible to reducing agents like β-mercaptoethanol as it had abolished the hemolytic activity of Rv1694 indicating the role of disulfide bond(s). The Rv1694 generated de novo by in vitro transcription and translation also exhibited unambiguous hemolysis confirming the self assembly and oligomerization properties of this protein. Limited proteolytic digestion of this protein has revealed that the amino terminus is susceptible while in solution but is protected in presence of membrane. Striking feature of Rv1694 is its presence on the cell wall of E. coli as visualized by confocal microscopy. The surface expression is consistent with the contact dependent haemolytic ability of E. coli expressing this protein. Also, immune serum specific to this protein inhibits the contact dependent hemolysis. Moreover, Rv1694 protein binds to and forms stable oligomers on the macrophage phagosomal membranes. In addition to all these properties, E. coli expressing Rv1694 was found to be susceptible to the antibiotic capreomycin as its growth was significantly slower than mock vector transformed E. coli. The S30 extract of E. coli expressing the Rv1694 had poor translational activity in presence of capreomycin, further confirming its methylation activity. Finally, incorporation of methyl group of [³H]-S-adenosylmethionine in isolated ribosomes also confirmed its methylation activity.

Conclusions

The Rv1694 has an unusual dual activity. It appears to contain two diverse functions such as haemolytic activity and ribosomal RNA methylation activity. It is possible that the haemolytic activity might be relevant to intra-cellular compartments such as phagosomes rather than cell lysis of erythrocytes and the self-assembly trait may have a potential role after successful entry into macrophages by Mycobacterium tuberculosis.

Channel-forming abilities of spontaneously occurring alpha-toxin fragments from Staphylococcus aureus

Pore formation by four spontaneously occurring alpha-toxin fragments from Staphylococcus aureus were investigated on liposome and erythrocyte membranes. All the isolated fragments bound to the different types of membranes and formed transmembrane channels in egg-phosphatidyl glycerol vesicles. Fragments of amino acids (aa) 9-293 (32 kD) and aa 13-293 (31 kD) formed heptamers, similar to the intact toxin, while the aa 72-293 (26 kD) fragment formed heptamers, octamers, and nonamers, as judged by gel electrophoresis of the liposomes. All isolated fragments induced release of chloride ions from large unilamellar vesicles. Channel formation was promoted by acidic pH and negatively charged lipid head groups. Also, the fragments' hemolytic activity was strongly decreased under neutral conditions but could be partially restored by acidification of the medium. We paid special attention to the 26-kD fragment, which, despite the loss of about one-fourth of the N-terminal part of alpha-toxin, did form transmembrane channels in liposomes. In light of the available data on channel formation by alpha-toxin, our results suggest that proteolytic degradation might be better tolerated than previously reported. Channel opening could be inhibited and open channels could be closed by zinc in the medium. Channel closure could be reversed by addition of EDTA. In contrast, digestion at the C terminus led to premature oligomerization and resulted in species with strongly diminished activity and dependent on protonation.

Biological relevance of natural alpha-toxin fragments from Staphylococcus aureus

Serine proteases represent an essential part of cellular homeostasis by generating biologically active peptides. In bacteria, proteolysis serves two different roles: a major housekeeping function and the destruction of foreign or target cell proteins, thereby promoting bacterial invasion. In the process, other virulence factors such as exotoxins become affected. In Staphylococcus aureus culture supernatant, the pore-forming alpha-toxin is cleaved by the coexpressed V8 protease and aureolysin. The oligomerizing and pore-forming abilities of five such spontaneously occurring N- and C-terminal alpha-toxin fragments were studied. (3)H-marked alpha-toxin fragments bound to rabbit erythrocyte membranes but only fragments with intact C termini, missing 8, 12 and 71 amino acids from their N-terminal, formed stable oligomers. All isolated fragments induced intoxication of mouse adrenocortical Y1 cells in vitro, though the nature of membrane damage for a fragment, degraded at its C terminus, remained obscure. Only one fragment, missing the first eight N-terminal amino acids, induced irreversible intoxication of Y1 cells in the same manner as the intact toxin. Four of the isolated fragments caused swelling, indicating altered channel formation. Fragments missing 12 and 71 amino acids from the N terminus occupied the same binding sites on Y1 cell membranes, though they inhibited membrane damage caused by intact toxin. In conclusion, N-terminal deletions up to 71 amino acids are tolerated, though the kinetics of channel formation and the channel's properties are altered. In contrast, digestion at the C terminus results in nonfunctional species.

Aromatic residues of Caveolin-1 binding motif of alpha-hemolysin are essential for membrane penetration

We have created single cysteine Caveolin-1 binding motif mutants (SCCBMMs) of staphylococcal alpha-HL for understanding assembly and penetration. All SCCBMMs have normal folding like alpha-HL as examined by limited proteolysis, intrinsic fluorescence emission, no hemolytic activity and do not form hetero oligomers with alpha-HL indicating that the conformational changes occurred at the cell membrane are different to that of alpha-HL. While modification of SCCBMMs with a membrane impermeant reagent has resulted in reduced binding, badan modification has resulted in the enhancement of badan fluorescence with time of assembly (incubation time) indicating the change in environment of the badan and the need for the penetration of the aromatic amino acids. Our studies indicate that the conformational changes are probably initiated at the Caveolin-1 binding motif and provide a basis for differential mode of interaction of the Caveolin-1 binding motif depending upon the nature of the target cell membrane.

Caveolin-1 binding motif of alpha-hemolysin: its role in stability and pore formation

We have identified a nine amino sequence in alpha-hemolysin (alpha-HL) of Staphylococcus aureus, which binds Caveolin-1. Surface plasmon resonance studies clearly show a concentration dependent interaction of alpha-HL with the scaffolding domain of Caveolin-1. Mutants of alpha-HL, devoid of Caveolin-1 recognition motif, exhibit an alpha-HL like proteinase K digestion profile but the resultant 'half-like' domains are highly susceptible to further proteolysis. They also had the same intrinsic fluorescence emission maxima as the native alpha-HL indicating normal folding. However, these mutants bind 1-anilino-8-naphthalene sulfonic acid probably due to exposure of their hydrophobic core. Moreover, these mutants are non-lytic and do not undergo conformational changes on rabbit RBC membrane surface. Purified Caveolin-1 blocks the hemolysis of RBCs by alpha-HL. Our studies indicate that the Caveolin-1 binding motif of alpha-HL provides stability and shields the hydrophobic core of alpha-HL. The motif also acts as trigger point for initiation of conformational changes.

Functional domains of a pore-forming cardiotoxic protein, volvatoxin A2

Volvatoxin A2 (VVA2), a novel pore-forming cardiotoxic protein was isolated from the mushroom Volvariella volvacea. We identified an N-terminal fragment (NTF) (1-127 residues) of VVA2 as a domain for oligomerization by limited tryptic digestion. On preincubation of NTF with VVA2, NTF was found to inhibit VVA2 hemolytic activity by inducing VVA2 oligomerization in the solution in the same manner as liposomes. By site-directed mutagenesis, the amphipathic alpha-helix B of NTF or VVA2 was shown to be indispensable for its biological functions. Interestingly, at a molar ratio of recombinant NTF (reNTF)/VVA2 as low as 0.01, reNTF was able to inhibit VVA2 hemolytic activity and induce VVA2 oligomerization. This indicates that reNTF can trigger VVA2 oligomerization by a seeding effect. Furthermore, the recombinant C-terminal fragment (128-199 residues) was found to be a functional domain that mediates the membrane binding of VVA2. We found a fragment localized at the C-terminal half of VVA2 containing beta6, -7, and -8, which is protected from protease digestion because of its insertion of a membrane. We also identified a putative heparin binding site (HBS) located in the VVA2 C terminus (166-194 residues), which was conserved among 10 kinds of snake venom cardiotoxins. VVA2 or the reHBS fragment was shown to interact with sulfated glycoaminoglycans by affinity column chromatography. The finding of a higher number of glycoaminoglycans in the membrane of cardiac myocytes suggested that they could be the specific membrane target for VVA2. Taken together, these findings indicate that VVA2 contains two functional domains, NTF and CTF. The NTF domain is responsible for VVA2 oligomerization and the CTF domain for membrane binding and insertion. Our results support a model whereby the formation of VVA2 oligomeric pre-pore complexes precedes their membrane insertion.

Modulation of EGF receptor autophosphorylation by alpha-hemolysin of Staphylococcus aureus via protein tyrosine phosphatase

In the presence of assembled alpha-hemolysin (alpha-HL) of Staphylococcus aureus, the epidermal growth factor receptor (EGFr) is rapidly dephosphorylated. Several obvious possibilities that otherwise would have contributed to the dephosphorylation were ruled out. Instead, an elevation in the activity of a protein tyrosine phosphatase appears to be responsible for the observed loss of phosphorylation signal of EGFr. For this dephosphorylation, the assembly of alpha-HL is necessary while lytic pore formation is not required. In summary, the EGFr is unable to retain its phosphorylation signal in the presence of alpha-HL and the process is irreversible.