A Chimeric LysK-Lysostaphin Fusion Enzyme Lysing Staphylococcus aureus Cells: a Study of Both Kinetics of Inactivation and Specifics of Interaction with Anionic Polymers.

A staphylolytic fusion protein (chimeric enzyme K-L) was created, harboring three unique lytic activities composed of the LysK CHAP endopeptidase, and amidase domains, and the lysostaphin glycyl-glycine endopeptidase domain. To assess the potential of possible therapeutic applications, the kinetic behavior of chimeric enzyme K-L was investigated. As a protein antimicrobial, with potential antigenic properties, the biophysical effect of including chimeric enzyme K-L in anionic polymer matrices that might help reduce the immunogenicity of the enzyme was tested. Chimeric enzyme K-L reveals a high lytic activity under the following optimal (opt) conditions: pHopt 6.0-10.0, topt 20-30 °C, NaClopt 400-800 mM. At the working temperature of 37 °C, chimeric enzyme K-L is inactivated by a monomolecular mechanism and possesses a high half-inactivation time of 12.7 ± 3.0 h. At storage temperatures of 22 and 4 °C, a complex mechanism (combination of monomolecular and bimolecular mechanisms) is involved in the chimeric enzyme K-L inactivation. The optimal storage conditions under which the enzyme retains 100 % activity after 140 days of incubation (4 °C, the enzyme concentration of 0.8 mg/mL, pH 6.0 or 7.5) were established. Chimeric enzyme K-L is included in complexes with block-copolymers of poly-L-glutamic acid and polyethylene glycol, while the enzyme activity and stability are retained, thus suggesting methods to improve the application of this fusion as an effective antimicrobial agent.

Triple-acting Lytic Enzyme Treatment of Drug-Resistant and Intracellular Staphylococcus aureus.

Multi-drug resistant bacteria are a persistent problem in modern health care, food safety and animal health. There is a need for new antimicrobials to replace over used conventional antibiotics. Here we describe engineered triple-acting staphylolytic peptidoglycan hydrolases wherein three unique antimicrobial activities from two parental proteins are combined into a single fusion protein. This effectively reduces the incidence of resistant strain development. The fusion protein reduced colonization by Staphylococcus aureus in a rat nasal colonization model, surpassing the efficacy of either parental protein. Modification of a triple-acting lytic construct with a protein transduction domain significantly enhanced both biofilm eradication and the ability to kill intracellular S. aureus as demonstrated in cultured mammary epithelial cells and in a mouse model of staphylococcal mastitis. Interestingly, the protein transduction domain was not necessary for reducing the intracellular pathogens in cultured osteoblasts or in two mouse models of osteomyelitis, highlighting the vagaries of exactly how protein transduction domains facilitate protein uptake. Bacterial cell wall degrading enzyme antimicrobials can be engineered to enhance their value as potent therapeutics.

Lytic activity of the staphylolytic Twort phage endolysin CHAP domain is enhanced by the SH3b cell wall binding domain.

Increases in the prevalence of antibiotic-resistant strains of Staphylococcus aureus have elicited efforts to develop novel antimicrobials to treat these drug-resistant pathogens. One potential treatment repurposes the lytic enzymes produced by bacteriophages as antimicrobials. The phage Twort endolysin (PlyTW) harbors three domains, a cysteine, histidine-dependent amidohydrolases/peptidase domain (CHAP), an amidase-2 domain and a SH3b-5 cell wall binding domain (CBD). Our results indicate that the CHAP domain alone is necessary and sufficient for lysis of live S. aureus, while the amidase-2 domain is insufficient for cell lysis when provided alone. Loss of the CBD results in ∼10X reduction of enzymatic activity in both turbidity reduction and plate lysis assays compared to the full length protein. Deletion of the amidase-2 domain resulted in a protein (PlyTW Δ172-373) with lytic activity that exceeded the activity of the full length construct in both the turbidity reduction and plate lysis assays. Addition of Ca(2+) enhanced the turbidity reduction activity of both the full length protein and truncation constructs harboring the CHAP domain. Chelation by addition of EDTA or the addition of zinc inhibited the activity of all PlyTW constructs.

Evolutionarily distinct bacteriophage endolysins featuring conserved peptidoglycan cleavage sites protect mice from MRSA infection.

OBJECTIVES: In the light of increasing drug resistance in Staphylococcus aureus, bacteriophage endolysins [peptidoglycan hydrolases (PGHs)] have been suggested as promising antimicrobial agents. The aim of this study was to determine the antimicrobial activity of nine enzymes representing unique homology groups within a diverse class of staphylococcal PGHs. METHODS: PGHs were recombinantly expressed, purified and tested for staphylolytic activity in multiple in vitro assays (zymogram, turbidity reduction assay and plate lysis) and against a comprehensive set of strains (S. aureus and CoNS). PGH cut sites in the staphylococcal peptidoglycan were determined by biochemical assays (Park-Johnson and Ghuysen procedures) and MS analysis. The enzymes were tested for their ability to eradicate static S. aureus biofilms and compared for their efficacy against systemic MRSA infection in a mouse model. RESULTS: Despite similar modular architectures and unexpectedly conserved cleavage sites in the peptidoglycan (conferred by evolutionarily divergent catalytic domains), the enzymes displayed varying degrees of in vitro lytic activity against numerous staphylococcal strains, including cell surface mutants and drug-resistant strains, and proved effective against static biofilms. In a mouse model of systemic MRSA infection, six PGHs provided 100% protection from death, with animals being free of clinical signs at the end of the experiment. CONCLUSIONS: Our results corroborate the high potential of PGHs for treatment of S. aureus infections and reveal unique antimicrobial and biochemical properties of the different enzymes, suggesting a high diversity of potential applications despite highly conserved peptidoglycan target sites.

Physicochemical characterization of the staphylolytic LysK enzyme in complexes with polycationic polymers as a potent antimicrobial.

Staphylococcus aureus causes many serious visceral, skin, and respiratory diseases. About 90% of its clinical strains are multi-drug resistant, but the use of bacteriophage lytic enzymes offers a viable alternative to antibiotic therapy. LysK, the phage K endolysin, can lyse S. aureus when purified and exposed externally. It has been investigated in its complexes with polycationic polymers (poly-l-lysines (PLLs) of molecular weights 2.5, 9.6, and 55.2 kDa and their block copolymers with polyethylene glycol PLL10-PEG114, PLL30-PEG114, and PLL30-PEG23) as a basis for creating active and stable antimicrobial. Complexing with polycationic PLLs produces a stabilizing effect on LysK due to structure ordering in its molecules and break-down of aggregates as a result of electrostatic interaction. The stability of LysK in the presence of PLL-PEG block copolymers improves by both electrostatic and hydrophobic mechanisms. Complexes of LysK with 2.5, 9.6, 55.2 kDa poly-l-lysines and PLL30-PEG114 have demonstrated sufficient stability at the temperatures of physiological activity (37 °C) and storage (4 °C and 22 °C).

Staphylococcal phage 2638A endolysin is lytic for Staphylococcus aureus and harbors an inter-lytic-domain secondary translational start site.

Staphylococcus aureus is a notorious pathogen highly successful at developing resistance to virtually all antibiotics to which it is exposed. Staphylococcal phage 2638A endolysin is a peptidoglycan hydrolase that is lytic for S. aureus when exposed externally, making it a new candidate antimicrobial. It shares a common protein organization with more than 40 other reported staphylococcal peptidoglycan hydrolases. There is an N-terminal M23 peptidase domain, a mid-protein amidase 2 domain (N-acetylmuramoyl-L-alanine amidase), and a C-terminal SH3b cell wall-binding domain. It is the first phage endolysin reported with a secondary translational start site in the inter-lytic-domain region between the peptidase and amidase domains. Deletion analysis indicates that the amidase domain confers most of the lytic activity and requires the full SH3b domain for maximal activity. Although it is common for one domain to demonstrate a dominant activity over the other, the 2638A endolysin is the first in this class of proteins to have a high-activity amidase domain (dominant over the N-terminal peptidase domain). The high activity amidase domain is an important finding in the quest for high-activity staphylolytic domains targeting novel peptidoglycan bonds.

Chimeric phage lysins act synergistically with lysostaphin to kill mastitis-causing Staphylococcus aureus in murine mammary glands.

Staphylococci cause bovine mastitis, with Staphylococcus aureus being responsible for the majority of the mastitis-based losses to the dairy industry (up to $2 billion/annum). Treatment is primarily with antibiotics, which are often ineffective and potentially contribute to resistance development. Bacteriophage endolysins (peptidoglycan hydrolases) present a promising source of alternative antimicrobials. Here we evaluated two fusion proteins consisting of the streptococcal λSA2 endolysin endopeptidase domain fused to staphylococcal cell wall binding domains from either lysostaphin (λSA2-E-Lyso-SH3b) or the staphylococcal phage K endolysin, LysK (λSA2-E-LysK-SH3b). We demonstrate killing of 16 different S. aureus mastitis isolates, including penicillin-resistant strains, by both constructs. At 100 µg/ml in processed cow milk, λSA2-E-Lyso-SH3b and λSA2-E-LysK-SH3b reduced the S. aureus bacterial load by 3 and 1 log units within 3 h, respectively, compared to a buffer control. In contrast to λSA2-E-Lyso-SH3b, however, λSA2-E-LysK-SH3b permitted regrowth of the pathogen after 1 h. In a mouse model of mastitis, infusion of 25 µg of λSA2-E-Lyso-SH3b or λSA2-E-LysK-SH3b into mammary glands reduced S. aureus CFU by 0.63 or 0.81 log units, compared to >2 log for lysostaphin. Both chimeras were synergistic with lysostaphin against S. aureus in plate lysis checkerboard assays. When tested in combination in mice, λSA2-E-LysK-SH3b and lysostaphin (12.5 µg each/gland) caused a 3.36-log decrease in CFU. Furthermore, most protein treatments reduced gland wet weights and intramammary tumor necrosis factor alpha (TNF-α) concentrations, which serve as indicators of inflammation. Overall, our animal model results demonstrate the potential of fusion peptidoglycan hydrolases as antimicrobials for the treatment of S. aureus-induced mastitis.

LysK, the enzyme lysing Staphylococcus aureus cells: specific kinetic features and approaches towards stabilization.

LysK, the enzyme lysing cells of Staphylococcus aureus, can be considered as perspective antimicrobial agent. Knowledge of LysK properties and behavior would allow optimizing conditions of its storage as well as formulating strategy towards its stabilization. Reaction of LysK with substrate (suspension of autoclaved Staphylococcus aureus cells) has been found to be adequately described by the two-stage Michaelis-Menten kinetic scheme. Ionization of the enzyme and enzyme-substrate complex is important for revealing catalytic activity, which is controlled by two ionogenic groups with pK 6.0 and 9.6. Ionization energy of the group with pK 6.0 is of 30 kJ/mol, thus, pointing out on His residue; pK 9.6 might be attributed to metal ion or metal-bound water molecule. At temperatures lower than 40 degrees C, LysK stability depends on its concentration, pH and presence of low molecular weight additives. Results of electrophoresis under native and denaturing conditions as well as sedimentation analysis strongly suggest that aggregation is behind LysK inactivation. Decrease in the enzyme concentration, as well as addition of low molecular mass polyols (glycerol, sorbitol, sucrose, trehalose) and Ca(2+) cations resulted in an enhanced (more than 100 times) stability of LysK. Dramatic stability decline observed in a narrow temperature range (40-42 degrees C) was accompanied by changes in LysK secondary structure as confirmed by CD spectroscopy studies. According to computer modeling data, Cys and His residues and metal cation might play a crucial role for LysK catalytic activity. Our data on the enzyme activity in the presence of ethylenediaminetetraacetic acid and different metal cations confirmed the importance of metal cation in LysK catalysis.

LysK CHAP endopeptidase domain is required for lysis of live staphylococcal cells.

LysK is a staphylococcal bacteriophage endolysin composed of three domains: an N-terminal cysteine, histidine-dependent amidohydrolases/peptidases (CHAP) endopeptidase domain, a midprotein amidase 2 domain, and a C-terminal SH3b_5 (SH3b) cell wall-binding domain. Both catalytic domains are active on purified peptidoglycan by positive-ion electrospray ionization MS. The cut sites are identical to LytA (phi11 endolysin), with cleavage between d-alanine of the stem peptide and glycine of the cross-bridge peptide, and N-acetylmuramoyl-l-alanine amidase activity. Truncations of the LysK containing just the CHAP domain lyse Staphylococcus aureus cells in zymogram analysis, plate lysis, and turbidity reduction assays but have no detectable activity in a minimal inhibitory concentration (MIC) assay. In contrast, truncations harboring just the amidase lytic domain show faint activity in both the zymogram and turbidity reduction assays, but no detectable activity in either plate lysis or MIC assays. A fusion of the CHAP domain to the SH3b domain has near full-length LysK lytic activity, suggesting the need for a C-terminal binding domain. Both LysK and the CHAP-SH3b fusion were shown to lyse untreated S. aureus and the coagulase-negative strains. In the checkerboard assay, the CHAP-SH3b fusion achieves the same level of antimicrobial synergy with lysostaphin as the full-length LysK.

Differentially conserved staphylococcal SH3b_5 cell wall binding domains confer increased staphylolytic and streptolytic activity to a streptococcal prophage endolysin domain.

Staphylococcal peptidoglycan hydrolases are a potential new source of antimicrobials. A large subset harbors C-terminal SH3b_5 cell wall binding domains. These C-terminal domains have been shown to be necessary for accurate cell wall recognition and subsequent staphylolytic activity for some endolysins. Over fifty proteins of staphylococcal or phage origin containing SH3b domains were aligned, yielding five highly repetitive groups of proteins. Representative C-termini from these five groups, and six staphylococcal proteins for which no homologues have been identified, were aligned, revealing two distinct SH3b_5 subgroups with overlapping but differentially conserved residues. A premise behind this research is that there may be unique cell wall binding properties conferred by these staphylococcal domains that could be exploited to specifically enhance anti-staphylococcal efficacy in heterologous protein fusion constructs. To identify functional differences between the two subgroups, the native Cpl-7 cell wall binding domains of the streptococcal LambdaSa2 endolysin were replaced by staphylococcal SH3b domains from both subgroups. SH3b domains from either lysostaphin (bacteriocin) or LysK (phage endolysin) resulted in a approximately 5x increase in staphylolytic activity conferred on the streptococcal endopeptidase domain, and surprisingly these same fusions maintained significant streptolytic activity suggesting that the staphylococcal SH3b domains are not always staphylococcal-specific. A comparison of the differences in lytic activity conferred on the LambdaSa2 endopeptidase domain by either LysK or lysostaphin SH3b domain differed by no more than a factor of two. Through the collection of peptidoglycan hydrolase sequences, three new putative intron-containing phage endolysin genes were identified in public data sets for the phages G1, X2 and 85.

The phage K lytic enzyme LysK and lysostaphin act synergistically to kill MRSA.

LysK is the endolysin from the staphylococcal bacteriophage K, and can digest the cell wall of many staphylococci. Lysostaphin is a bacteriocin secreted by Staphylococcus simulans to kill Staphylococcus aureus. Both LysK and lysostaphin have been shown to lyse methicillin-resistant S. aureus (MRSA). This study describes optimal reaction conditions for the recombinant His-tagged LysK protein (pH range pH 6-10, and 0.3-0.5 M NaCl), and C-His-LysK MIC (32.85+/-4.87 mug mL(-1)). LysK and lysostaphin demonstrate antimicrobial synergy by the checkerboard assay.

Functional characterization of the competence protein DprA/Smf in Escherichia coli.

In several bacterial species that show natural transformation, dprA has been described as a competence gene. The DprA protein has been suggested to be involved in the protection of incoming DNA. However, members of the dprA gene family (also called smf) can be detected in virtually all bacterial species, which suggests that their gene products have a more general function. We examined the function of the DprA/Smf homologue of Escherichia coli. Escherichia coli dprA/smf is able to partially restore transformation in a Haemophilus influenzae dprA mutant, which shows that dprA/smf genes from competent and noncompetent species are interchangeable with respect to their involvement in natural transformation. From this, we conclude that natural transformation is probably an additional function of these genes. Subsequently, the dprA/smf gene was deleted in various recombination mutants of E. coli, and the resultant phenotype was tested. All the resultant E. coli dprA/smf mutants did not differ from their parent strains with respect to transformation, Hfr-conjugation, recombination and DNA repair. Therefore, a role of DprA/Smf in DNA recombination could not be established and the basic function of dprA/smf remains unclear.