Abstract
Peptidoglycan hydrolytic enzymes are considered to be a promising alternative to conventional antibiotics in combating bacterial infections. To identify novel hydrolytic enzymes, we performed a database search with the sequences of two thermostable endolysins with high bactericidal activity, studied earlier in our laboratory. Both these enzymes originate from Thermus scotoductus bacteriophages MAT2119 and vB_Tsc2631. A lytic enzyme LysC from Clostridium intestinale URNW was found to have the highest amino acid sequence similarity to the bacteriophage proteins and was chosen for further analysis. The recombinant enzyme showed strong activity against its host bacteria C. intestinale, as well as against C. sporogenes, Bacillus cereus, Micrococcus luteus, and Staphylococcus aureus, on average causing a 5.12 ± 0.14 log reduction of viable S. aureus ATCC 25923 cells in a bactericidal assay. Crystallographic studies of the protein showed that the catalytic site of LysC contained a zinc atom coordinated by amino acid residues His50, His147, and Cys155, a feature characteristic for type 2 amidases. Surprisingly, neither of these residues, nor any other of the four conserved residues in the vicinity of the active site, His51, Thr52, Tyr76, and Thr153, were essential to maintain the antibacterial activity of LysC. Therefore, our attention was attracted to the intrinsically disordered and highly positively charged N-terminal region of the enzyme. Potential antibacterial activity of this part of the sequence, predicted by the Antimicrobial Sequence Scanning System, AMPA, was confirmed in our experimental studies; the truncated version of LysC (LysCΔ2–23) completely lacked antibacterial activity. Moreover, a synthetic peptide, which we termed Intestinalin, with a sequence identical to the first thirty amino acids of LysC, displayed substantial anti-staphylococcal activity with IC50 of 6 μg/mL (1.5 μM). This peptide was shown to have α-helical conformation in solution in the presence of detergents which is a common feature of amphipathic α-helical antimicrobial peptides.
Highlights
The discovery and introduction of antibiotics, starting with penicillin, made a revolutionary change in the way of treating bacterial infections
Despite unquestionable benefits associated with new therapies, it was immediately observed that microorganisms quickly start to develop resistance to antibiotics and bacterial infections again become a serious threat to human life
The basic local alignment search tool (BLASTP) sequence-similarity searches for proteins showing homology to eukaryotic peptidoglycan recognition proteins (PGRPs) and thermostable Ph2119 and Ts2631 endolysins allowed to identify in the genome of Clostridium intestinale URNW an open reading frame (ORF, coordinates 584335-584853 nt) encoding a 172 aa protein (Mr = 20,090; pI = 9.96) with a putative lytic function
Summary
The discovery and introduction of antibiotics, starting with penicillin, made a revolutionary change in the way of treating bacterial infections. Amidases cleave the amide bond connecting the stem-peptide to the glycan backbone of PG, glycosidases (N-acetylglucosaminidases and N-acetylmuramidases) catalyze the hydrolysis of the glycosidic linkages, whereas peptidases cleave amide bonds between amino acids in the PG chain [3]. Based on their origin and role, peptidoglycan hydrolases can be categorized into endolysins, exolysins, and autolysins [4]. Representatives of the third group, autolysins, cleave the peptidoglycan of bacteria that produce them They are mainly involved in cellular processes, including cell growth and division, cell-wall turnover, and peptidoglycan maturation
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