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6. Diversity of Endolysin Domain Architectures in Bacteriophages Infecting Bacilli.

Author

Koposova, Olga N., Kazantseva, Olesya A., and Shadrin, Andrey M.

Subjects
*AMIDASES, *CATALYTIC domains, *GRAM-positive bacteria, *BACILLUS (Bacteria), *GLYCOSYLTRANSFERASES
Abstract

The increasing number of antibiotic-resistant bacterial pathogens is a serious problem in medicine. Endolysins are bacteriolytic enzymes of bacteriophages, and a promising group of enzymes with antibacterial properties. Endolysins of bacteriophages infecting Gram-positive bacteria have a modular domain organization. This feature can be used to design enzymes with new or improved properties by modifying or shuffling individual domains. This work is a detailed analysis 1of the diversity of endolysin domains found in bacteriophages infecting bacilli. During the course of the work, a database of endolysins of such bacteriophages was created, and their domain structures were analyzed using the NCBI database, RASTtk, BLASTp, HHpred, and InterPro programs. A phylogenetic analysis of endolysins was performed using MEGA X. In 438 phage genomes, 454 genes of endolysins were found. In the endolysin sequences found, eight different types of catalytic domains and seven types of cell wall binding domains were identified. The analysis showed that many types of endolysin domains have not yet been characterized experimentally. Studies of the properties of such domains will help to reveal the potential of endolysins for the creation of new antibacterial agents. [ABSTRACT FROM AUTHOR]

Published
2024
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7. New-Generation Antibacterial Agent—Cellulose-Binding Thermostable TP84_Endolysin.

Author

Ponikowska, Małgorzata, Żebrowska, Joanna, and Skowron, Piotr M.

Abstract

The increasing antibiotic resistance among bacteria challenges the biotech industry to search for new antibacterial molecules. Endolysin TP84_28 is a thermostable, lytic enzyme, encoded by the bacteriophage (phage) TP-84, and it effectively digests host bacteria cell wall. Biofilms, together with antibiotic resistance, are major problems in clinical medicine and industry. The challenge is to keep antibacterial molecules at the site of desired action, as their diffusion leads to a loss of efficacy. The TP84_28 endolysin gene was cloned into an expression-fusion vector, forming a fusion gene cbd_tp84_28_his with a cellulose-binding domain from the cellulase enzyme. The Cellulose-Binding Thermostable TP84_Endolysin (CBD_TP84_28_His) fusion protein was biosynthesized in Escherichia coli and purified. Thermostability and enzymatic activities against various bacterial species were measured by a turbidity reduction assay, a spot assay, and biofilm removal. Cellulose-binding properties were confirmed via interactions with microcellulose and cellulose paper-based immunoblotting. The high affinity of the CBD allows for a high concentration of the fusion enzyme at desired target sites such as cellulose-based wound dressings, artificial heart valves and food packaging. CBD_TP84_28_His exhibits a lytic effect against thermophilic bacteria Geobacillus stearothemophilus, Thermus aquaticus, Bacillus stearothermophilus, and Geobacillus ICI and minor effects against mesophilic Bacillus cereus and Bacillus subtilis. CBD_TP84_28_His retains full activity after preincubation in the temperatures of 30–65 °C and exhibits significant activity up to its melting point at 73 °C. CBD_TP84_28_His effectively reduces biofilms. These findings suggest that integrating CBDs into thermostable endolysins could enable the development of targeted antibacterial recombinant proteins with diverse clinical and industrial applications. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Saccharomyces cerevisiae secretion of recombinant bacteriophage endolysin LysKB317 inhibits Limosilactobacillus fermentum in corn mash fermentation.

Author

Shao-Yeh Lu, Patel, Maulik H., Hector, Ronald E., Bowman, Michael J., and Skory, Christopher D.

Subjects
SACCHAROMYCES cerevisiae, BACTERIOPHAGES, FERMENTATION, BACTERIAL contamination, PROTEINS, WESTERN immunoblotting
Abstract

This study investigated the secretion of endolysin LysKB317 integrated into the HO locus of Saccharomyces cerevisiae strain NRRL Y-2034 to enable the yeast to simultaneously perform ethanol fermentation and control bacterial contaminants frequently present in ethanol refineries. The cell wall hydrolase gene was expressed using TEF1 and NAT5 promoter and terminator sequences with α-MF secretion signal and an N-terminus poly-histidine tag. LysKB317 was detectable by western blot analysis, which showed a molecular weight slightly larger than the 33 kDa native protein, presumably due to residual amino acids from the α-MF secretion signal peptide or S. cerevisiae glycosylation. Secreted LysKB317 was confirmed to be active using turbidity reduction and cell viability assay. Contaminated corn mash fermentations with yeast secreting LysKB317 demonstrated a significant reduction in bacterial contamination by at least 2-log compared to the contamination controls without LysKB317 expression. Moreover, LysKB317 expression led to a 73% decrease in acetic acid concentration and a 67% decrease in lactic acid levels. Contaminated fermentations with yeast expressing LysKB317 also exhibited a 16% improvement in ethanol production over the contamination controls without LysKB317, with no significant difference observed when compared to yeastonly controls during a 72-h corn mash fermentation. These findings suggest that a yeast endolysin secretion platform holds promise for mitigating bacterial contamination in biorefineries and potentially reducing reliance on antibiotics usage. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Unveiling Hidden Allies: In Silico Discovery of Prophages in Tenacibaculum Species.

Author

Ramírez, Carolina and Romero, Jaime

Subjects
BACTERIOPHAGES, AMINO acids, GENOMES, AQUACULTURE, SPECIES
Abstract

Tenacibaculosis, caused by Tenacibaculum species, is a significant disease in aquaculture, leading to high mortality and economic losses. Antibiotic treatment raises concerns about resistance, making phage therapy an interesting alternative. Analyzing phage traces in Tenacibaculum genomes is crucial for developing these bacteriophage-based strategies. Methods: We assessed the presence of prophages in 212 Tenacibaculum genomes/assemblies available in the NCBI repository, comprising several species and global locations, using the PHASTEST program. Then, we focused on those regions classified as intact, evaluating the most common phages found using VICTOR. The protein of interest discovered in the prophages was evaluated using the ProtParam, DeepTMHMM, InterPro, and Phyre2 tools. In addition, we evaluated the presence of antiphage defense systems in those genomes with intact prophages using the DefenseFinder tool. Results: We identified 25 phage elements in 24 out of the 212 Tenacibaculum genomes/assemblies analyzed, with 11% of the assemblies containing phage elements. These were concentrated in T. maritimum and T. mesophilum, which harbored 10 and 7 prophage regions, respectively. Of the identified elements, six were classified as intact, including four in T. maritimum, with the most common phages belonging to the Pippivirus and Siphoviridae families. Bioinformatic analysis showed that the putative endolysin is a stable protein of 432 amino acids and 49.8 kDa, with three transmembrane helices and a CHAP domain, structurally similar to the CHAP lytic domain of S. aureus bacteriophage K. Conclusions: Key prophage elements in Tenacibaculum, especially in T. maritimum, show promise for phage therapy against tenacibaculosis, supporting sustainable, antibiotic-free treatments in aquaculture. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Molecular Docking of Endolysins for Studying Peptidoglycan Binding Mechanism.

Author

Arakelian, Arina G., Chuev, Gennady N., and Mamedov, Timur V.

Subjects
*MOLECULAR docking, *BINDING energy, *BACTERIAL diseases, *BIOFILMS, *BACTERIOPHAGES, *LIGAND binding (Biochemistry)
Abstract

Endolysins of bacteriophages, which degrade the bacterial cell wall peptidoglycan, are applicable in many industries to deal with biofilms and bacterial infections. While multi-domain endolysins have both enzymatically active and cell wall-binding domains, single-domain endolysins consist only of an enzymatically active domain, and their mechanism of peptidoglycan binding remains unexplored, for this is a challenging task experimentally. This research aimed to explore the binding mechanism of endolysins using computational approaches, namely molecular docking and bioinformatical tools, and analyze the performance of these approaches. The docking engine Autodock Vina 1.1.2 and the 3D-RISM module of AmberTools 24 were studied in the current work and used for receptor–ligand affinity and binding energy calculations, respectively. Two possible mechanisms of single-domain endolysin–ligand binding were predicted by Autodock Vina and verified by the 3D-RISM. As a result, the previously obtained experimental results on peptidoglycan binding of the isolated gamma phage endolysin PlyG enzymatically active domain were supported by molecular docking. Both methods predicted that single-domain endolysins are able to bind peptidoglycan, with Autodock Vina being able to give accurate numerical estimates of protein–ligand affinities and 3D-RISM providing comparative values. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Role of hypothetical protein PA1-LRP in antibacterial activity of endolysin from a new Pantoea phage PA1.

Author

Tian, Ye, Xu, Xinyan, Ijaz, Munazza, Shen, Ying, Shahid, Muhammad Shafiq, Ahmed, Temoor, Ali, Hayssam M., Yan, Chengqi, Gu, Chunyan, Lu, Jianfei, Wang, Yanli, Ondrasek, Gabrijel, and Li, Bin

Subjects
TRANSMEMBRANE domains, PHYTOPATHOGENIC microorganisms, LYSIS, BACTERIAL diseases, GRAM-negative bacteria
Abstract

Introduction: Pantoea ananatis has emerged as a significant plant pathogen affecting various crops worldwide, causing substantial economic losses. Bacteriophages and their endolysins offer promising alternatives for controlling bacterial infections, addressing the growing concerns of antibiotic resistance. Methods: This study isolated and characterized the Pantoea phage PA1 and investigated the role of PA1-LRP in directly damaging bacteria and assisting endolysin PA1-Lys in cell lysis, comparing its effect to exogenous transmembrane domains following the identification and analysis of the PA1-Lys and the PA1-LRP based on whole genome analysis of phage PA1. Additionally, this study also explored how hydrophobic region of PA1-LRP (HPP) contributes to bacterial killing when combined with PA1-Lys and examined the stability and lytic spectrum of PA1-Lys under various conditions. Results and discussion: Phage PA1 belonging to the Chaseviridae family exhibited a broad host range against P. ananatis strains, with a latent period of 40 minutes and a burst size of 17.17 phages per infected cell. PA1-Lys remained stable at pH 6-10 and temperatures of 20-50°C and showed lytic activity against various Gram-negative bacteria, while PA1-Lys alone could not directly lyse bacteria, its lytic activity was enhanced in the presence of EDTA. Surprisingly, PA1-LRP inhibited bacterial growth when expressed alone. After 24 h of incubation, the OD600 value of pET28a-LRP decreased by 0.164 compared to pET28a. Furthermore, the lytic effect of co-expressed PA1-LRP and PA1-Lys was significantly stronger than each separately. After 24 h of incubation, compared to pET28a-LRP, the OD600 value of pET28a-Lys-LRP decreased by 0.444, while the OD420 value increased by 3.121. Live/dead cell staining, and flow cytometry experiments showed that the fusion expression of PA1-LRP and PA1-Lys resulted in 41.29% cell death, with bacterial morphology changing from rod-shaped to filamentous. Notably, PA1-LRP provided stronger support for endolysin-mediated cell lysis than exogenous transmembrane domains. Additionally, our results demonstrated that the HPP fused with PA1-Lys, led to 40.60% cell death, with bacteria changing from rod-shaped to spherical and exhibiting vacuolation. Taken together, this study provides insights into the lysis mechanisms of Pantoea phages and identifies a novel lysis-related protein, PA1-LRP, which could have potential applications in phage therapy and bacterial disease control. [ABSTRACT FROM AUTHOR]

Published
2024
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12. Engineering of bacteria towards programmed autolysis: why, how, and when?

Author

Changying Dong, Shenghao Cui, Jialuan Ren, Guoli Gong, Jian Zha, and Xia Wu

Subjects
Autolysis, Endolysin, Release, Control, Bio-product, Microbiology, QR1-502
Abstract

Abstract Programmed autolytic bacteria, also termed controlled self-disruptive or self-destructive bacteria, are bacterial systems that express certain lytic genes and undergo cell lysis at a predetermined time point to release the intracellular contents or to commit suicide. Such systems have wide applications in high-throughput screening of protein libraries, synthesis and recovery of bio-products, population control of heterogeneous cultures or synthetic co-cultures, drug delivery, and food fermentation. Recently, great achievements have been reported regarding on-demand control of cell autolysis for different purposes, highlighting the potential of autolytic strains in biomanufacturing and biomedicine. In this review article, we first introduce the various applications of such bacteria, followed by a summarization of the approaches used in the establishment of autolytic bacterial systems, including cell autolysis mediated by cell wall hydrolases with or without facilitating proteins and by membrane-disturbing proteins. Next, we describe in detail the methodologies adopted to control and initiate cell lysis, including induction by chemical inducers, stimulation by physical signals, auto-induction by metabolic status or nutrient limitation, and constitutive expression of the lytic genes. This article is ended with discussions on the remaining problems and possible future directions. This review provides comprehensive information on autolytic bacteria and insightful guidance to the development of highly efficient, robust, and smart autolytic bacterial platforms.

Published
2024
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13. Engineering of bacteria towards programmed autolysis: why, how, and when?

Author

Dong, Changying, Cui, Shenghao, Ren, Jialuan, Gong, Guoli, Zha, Jian, and Wu, Xia

Subjects
*FOOD fermentation, *LYSIS, *HIGH throughput screening (Drug development), *AUTOLYSIS, *GREEN business, *BACTERIAL cell walls
Abstract

Programmed autolytic bacteria, also termed controlled self-disruptive or self-destructive bacteria, are bacterial systems that express certain lytic genes and undergo cell lysis at a predetermined time point to release the intracellular contents or to commit suicide. Such systems have wide applications in high-throughput screening of protein libraries, synthesis and recovery of bio-products, population control of heterogeneous cultures or synthetic co-cultures, drug delivery, and food fermentation. Recently, great achievements have been reported regarding on-demand control of cell autolysis for different purposes, highlighting the potential of autolytic strains in biomanufacturing and biomedicine. In this review article, we first introduce the various applications of such bacteria, followed by a summarization of the approaches used in the establishment of autolytic bacterial systems, including cell autolysis mediated by cell wall hydrolases with or without facilitating proteins and by membrane-disturbing proteins. Next, we describe in detail the methodologies adopted to control and initiate cell lysis, including induction by chemical inducers, stimulation by physical signals, auto-induction by metabolic status or nutrient limitation, and constitutive expression of the lytic genes. This article is ended with discussions on the remaining problems and possible future directions. This review provides comprehensive information on autolytic bacteria and insightful guidance to the development of highly efficient, robust, and smart autolytic bacterial platforms. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Characteristics of the Enterococcus Phage vB_EfS_SE, and the Properties of Its Chimeric Endolysins Harboring a PlySE-Carbohydrate-Binding Domain and a Synthetic Enzymatic Domain.

Author

Buzikov, Rustam M., Kulyabin, Vladislav A., Koposova, Olga N., Arlyapov, Vyacheslav A., and Shadrin, Andrey M.

Subjects
*ENTEROCOCCUS faecalis, *DRUG development, *ENTEROCOCCUS faecium, *GENE expression, *MOLECULAR cloning
Abstract

Background/Objectives: The World Health Organization has selected enterococci as one of the priority multidrug-resistant microorganisms for the development of new antibacterial drugs. Bacteriophages are promising antibacterial agents, but the biology of bacteriophages requires deeper understanding. Methods: The vB_EfS_SE phage which is capable of infecting four species of the genus Enterococci was isolated from sewage plant. The complete genome of the vB_EfS_SE phage was sequenced using illumina technology. The endolysin gene was cloned into pBAD18 expression vector. Two chimeric endolysins were engineered using the vB_EfS_SE carbohydrate-binding domain (CBD) and replacing its enzymatically active domain (EAD). Results: The bacteriophage exhibits promising lytic properties and persists at temperatures of 40 °C and below, and under pH conditions ranging from 5 to 11. The genome sequence is 57,904 bp in length. The vB_EfS_SE endolysin PlySE and chimeric endolysins PlyIME-SE and PlySheep-SE were found to have the same range of specificity, but different thermostability properties and a different pH range for enzyme activity. Conclusions: Taking together the results obtained in this work and other published studies, we can highly appreciate the potential of Saphexavirus phages and their endolysins as novel antibacterial compounds. [ABSTRACT FROM AUTHOR]

Published
2024
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15. Elucidating the molecular properties and anti-mycobacterial activity of cysteine peptidase domain of D29 mycobacteriophage endolysin.

Author

Gangakhedkar, Rutuja and Jain, Vikas

Subjects
*MYCOBACTERIUM smegmatis, *SMALL molecules, *MYCOBACTERIUM tuberculosis, *SITE-specific mutagenesis, *GRAM-negative bacteria, *PEPTIDASE
Abstract

Emergence of antibiotic resistance in pathogenic Mycobacterium tuberculosis (Mtb) has elevated tuberculosis to a serious global threat, necessitating alternate solutions for its eradication. D29 mycobacteriophage can infect and kill several mycobacterial species including Mtb. It encodes an endolysin LysA to hydrolyze host bacteria peptidoglycan for progeny release. We previously showed that out of the two catalytically active domains of LysA [N-terminal domain (NTD) and lysozyme-like domain], NTD, when ectopically expressed in Mycobacterium smegmatis (Msm), is able to kill the bacterium nearly as efficiently as full-length LysA. Here, we dissected the functioning of NTD to develop it as a phage-derived small molecule anti-mycobacterial therapeutic. We performed a large-scale site-directed mutagenesis of the conserved residues in NTD and examined its structure, stability, and function using molecular dynamic simulations coupled with biophysical and biochemical experiments. Our data show that NTD functions as a putative cysteine peptidase with a catalytic triad composed of Cys41, His112, and Glu137, acting as nucleophile, base, and acid, respectively, and showing characteristics similar to the NlpC/P60 family of cysteine peptidases. Additionally, our peptidoglycan hydrolysis assays suggested that NTD hydrolyzes only mycobacterial peptidoglycan and does not act on Gram-positive and Gram-negative bacterial peptidoglycans. More importantly, the combined activity of exogenously added NTD and sub-lethal doses of anti-mycobacterial drugs kills Msm in vitro and exhibits disruption of pre-formed mycobacterial biofilm. We additionally show that NTD treatment increases the permeability of antibiotics in Msm, which reduces the minimum inhibitory concentration of the antibiotics. Collectively, we present NTD as a promising phage-derived therapeutic against mycobacteria. [ABSTRACT FROM AUTHOR]

Published
2024
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16. Estimation of the In-Vitro Synergistic Effect of Vancomycin with Bacteriophage and its Endolysin on Iraqi Local Isolates of Enterococcus faecalis.

Author

Hafidh, Rand R., Hamed, Zainab Oday, Awni, Abdullah A., and Jassas, Manal N.

Subjects
MULTIDRUG resistance in bacteria, LYSINS, ENTEROCOCCUS faecalis, BACTERIAL cells, ANTIBACTERIAL agents, ENTEROCOCCUS
Abstract

Copyright of Baghdad Science Journal is the property of Republic of Iraq Ministry of Higher Education & Scientific Research (MOHESR) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2024
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17. Advances in the development of phage-mediated cyanobacterial cell lysis.

Author

Jin, Haojie, Ge, Wanzhao, Li, Mengzhe, Wang, Yan, Jiang, Yanjing, Zhang, Jiaqi, Jing, Yike, Tong, Yigang, and Fu, Yujie

Subjects
*CELL envelope (Biology), *LYSIS, *CYANOBACTERIAL blooms, *HETEROTROPHIC bacteria, *BACTERIAL cells
Abstract

AbstractCyanobacteria, the only oxygenic photoautotrophs among prokaryotes, are developing as both carbon building blocks and energetic self-supported chassis for the generation of various bioproducts. However, one of the challenges to optimize it as a more sustainable platform is how to release intracellular bioproducts for an easier downstream biorefinery process. To date, the major method used for cyanobacterial cell lysis is based on mechanical force, which is energy-intensive and economically unsustainable. Phage-mediated bacterial cell lysis is species-specific and highly efficient and can be conducted under mild conditions; therefore, it has been intensively studied as a bacterial cell lysis weapon. In contrast to heterotrophic bacteria, biological cell lysis studies in cyanobacteria are lagging behind. In this study, we reviewed cyanobacterial cell envelope features that could affect cell strength and elicited a thorough presentation of the necessary phage lysin components for efficient cell lysis. We then summarized all bioengineering manipulated pipelines for lysin component optimization and further revealed the challenges for each intent-oriented application in cyanobacterial cell lysis. In addition to applied biotechnology usage, the significance of phage-mediated cyanobacterial cell lysis could also advance sophisticated biochemical studies and promote biocontrol of toxic cyanobacteria blooms. [ABSTRACT FROM AUTHOR]

Published
2024
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18. Genomic Characterization of Phage ZP3 and Its Endolysin LysZP with Antimicrobial Potential against Xanthomonas oryzae pv. oryzae.

Author

Zhang, Muchen, Xu, Xinyan, Lv, Luqiong, Luo, Jinyan, Ahmed, Temoor, Alsakkaf, Waleed A. A., Ali, Hayssam M., Bi, Ji'an, Yan, Chengqi, Gu, Chunyan, Shou, Linfei, and Li, Bin

Subjects
*TRANSMEMBRANE domains, *XANTHOMONAS oryzae, *TRANSMISSION electron microscopy, *BIOLOGICAL pest control agents, *NUCLEOTIDE sequencing
Abstract

Xanthomonas oryzae pv. oryzae (Xoo) is a significant bacterial pathogen responsible for outbreaks of bacterial leaf blight in rice, posing a major threat to rice cultivation worldwide. Effective management of this pathogen is crucial for ensuring rice yield and food security. In this study, we identified and characterized a novel Xoo phage, ZP3, isolated from diseased rice leaves in Zhejiang, China, which may offer new insights into biocontrol strategies against Xoo and contribute to the development of innovative approaches to combat bacterial leaf blight. Transmission electron microscopy indicated that ZP3 had a short, non-contractile tail. Genome sequencing and bioinformatic analysis showed that ZP3 had a double-stranded DNA genome with a length of 44,713 bp, a G + C content of 52.2%, and 59 predicted genes, which was similar to other OP1-type Xoo phages belonging to the genus Xipdecavirus. ZP3's endolysin LysZP was further studied for its bacteriolytic action, and the N-terminal transmembrane domain of LysZP is suggested to be a signal–arrest–release sequence that mediates the translocation of LysZP to the periplasm. Our study contributes to the understanding of phage–Xoo interactions and suggests that phage ZP3 and its endolysin LysZP could be developed into biocontrol agents against this phytopathogen. [ABSTRACT FROM AUTHOR]

Published
2024
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19. Agents Targeting the Bacterial Cell Wall as Tools to Combat Gram-Positive Pathogens.

Author

Zhydzetski, Aliaksandr, Głowacka-Grzyb, Zuzanna, Bukowski, Michal, Żądło, Tomasz, Bonar, Emilia, and Władyka, Benedykt

Subjects
*BACTERIAL cell walls, *ANTIBIOTIC synthesis, *PEPTIDOGLYCAN hydrolase, *ANTI-infective agents, *ANTIBACTERIAL agents, *BETA lactam antibiotics, *PEPTIDE antibiotics
Abstract

The cell wall is an indispensable element of bacterial cells and a long-known target of many antibiotics. Penicillin, the first discovered beta-lactam antibiotic inhibiting the synthesis of cell walls, was successfully used to cure many bacterial infections. Unfortunately, pathogens eventually developed resistance to it. This started an arms race, and while novel beta-lactams, either natural or (semi)synthetic, were discovered, soon upon their application, bacteria were developing resistance. Currently, we are facing the threat of losing the race since more and more multidrug-resistant (MDR) pathogens are emerging. Therefore, there is an urgent need for developing novel approaches to combat MDR bacteria. The cell wall is a reasonable candidate for a target as it differentiates not only bacterial and human cells but also has a specific composition unique to various groups of bacteria. This ensures the safety and specificity of novel antibacterial agents that target this structure. Due to the shortage of low-molecular-weight candidates for novel antibiotics, attention was focused on peptides and proteins that possess antibacterial activity. Here, we describe proteinaceous agents of various origins that target bacterial cell wall, including bacteriocins and phage and bacterial lysins, as alternatives to classic antibiotic candidates for antimicrobial drugs. Moreover, advancements in protein chemistry and engineering currently allow for the production of stable, specific, and effective drugs. Finally, we introduce the concept of selective targeting of dangerous pathogens, exemplified by staphylococci, by agents specifically disrupting their cell walls. [ABSTRACT FROM AUTHOR]

Published
2024
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20. Characterization of Two Novel Endolysins from Bacteriophage PEF1 and Evaluation of Their Combined Effects on the Control of Enterococcus faecalis Planktonic and Biofilm Cells.

Author

Wang, Chen, Zhao, Junxin, Lin, Yunzhi, Lwin, Su Zar Chi, El-Telbany, Mohamed, Masuda, Yoshimitsu, Honjoh, Ken-ichi, and Miyamoto, Takahisa

Subjects
LYSINS, ENTEROCOCCUS faecalis, GRAM-negative bacteria, BACTERIAL diseases, ANTI-infective agents, ENTEROCOCCUS
Abstract

Endolysin, a bacteriophage-derived lytic enzyme, has emerged as a promising alternative antimicrobial agent against rising multidrug-resistant bacterial infections. Two novel endolysins LysPEF1-1 and LysPEF1-2 derived from Enterococcus phage PEF1 were cloned and overexpressed in Escherichia coli to test their antimicrobial efficacy against multidrug-resistant E. faecalis strains and their biofilms. LysPEF1-1 comprises an enzymatically active domain and a cell-wall-binding domain originating from the NLPC-P60 and SH3 superfamilies, while LysPEF1-2 contains a putative peptidoglycan recognition domain that belongs to the PGRP superfamily. LysPEF1-1 was active against 89.86% (62/69) of Enterococcus spp. tested, displaying a wider antibacterial spectrum than phage PEF1. Moreover, two endolysins demonstrated lytic activity against additional gram-positive and gram-negative species pretreated with chloroform. LysPEF1-1 showed higher activity against multidrug-resistant E. faecalis strain E5 than LysPEF1-2. The combination of two endolysins effectively reduced planktonic cells of E5 in broth and was more efficient at inhibiting biofilm formation and removing biofilm cells of E. faecalis JCM 7783T than used individually. Especially at 4 °C, they reduced viable biofilm cells by 4.5 log after 2 h of treatment on glass slide surfaces. The results suggest that two novel endolysins could be alternative antimicrobial agents for controlling E. faecalis infections. [ABSTRACT FROM AUTHOR]

Published
2024
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21. Construing the function of N‐terminal domain of D29 mycobacteriophage LysA endolysin in phage lytic efficiency and proliferation.

Author

Gangakhedkar, Rutuja and Jain, Vikas

Subjects
*CATALYTIC domains, *MYCOBACTERIUM tuberculosis, *LYSIS, *MYCOBACTERIA, *VIRION, *BACTERIOPHAGES
Abstract

Endolysins produced by bacteriophages hydrolyze host cell wall peptidoglycan to release newly assembled virions. D29 mycobacteriophage specifically infects mycobacteria including the pathogenic Mycobacterium tuberculosis. D29 encodes LysA endolysin, which hydrolyzes mycobacterial cell wall peptidoglycan. We previously showed that LysA harbors two catalytic domains (N‐terminal domain [NTD] and lysozyme‐like domain [LD]) and a C‐terminal cell wall binding domain (CTD). While the importance of LD and CTD in mycobacteriophage biology has been examined in great detail, NTD has largely remained unexplored. Here, to address NTD's significance in D29 physiology, we generated NTD‐deficient D29 (D29∆NTD) by deleting the NTD‐coding region from D29 genome using CRISPY‐BRED. We show that D29∆NTD is viable, but has a longer latent period, and a remarkably reduced burst size and plaque size. A large number of phages were found to be trapped in the host during the D29∆NTD‐mediated cell lysis event. Such poor release of progeny phages during host cell lysis strongly suggests that NTD‐deficient LysA produced by D29∆NTD, despite having catalytically‐active LD, is unable to efficiently lyse host bacteria. We thus conclude that LysA NTD is essential for optimal release of progeny virions, thereby playing an extremely vital role in phage physiology and phage propagation in the environment. [ABSTRACT FROM AUTHOR]

Published
2024
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22. From DNA to lytic proteins: transcription and translation of the bacteriophage T5 holin/endolysin operon.

Author

Chernyshov, Sergei V., Masulis, Irina S., and Mikoulinskaia, Galina V.

Subjects
*GENETIC transcription, *GENETIC translation, *OPERONS, *DNA, *ESCHERICHIA coli, *BACTERIOPHAGES
Abstract

The analysis of transcriptional activity of the bacteriophage T5 hol/endo operon conducted in the paper revealed a strong constitutive promoter recognized by E. coli RNA polymerase and a transcription initiation point of the operon. It was also shown that the only translational start codon for holin was a non-canonical TTG. Translation initiation regions (TIRs) of both genes of the operon (hol and endo) were further analyzed using chimeric constructs, in which parts of the hol/endo regulatory regions were fused with the gene of a reporter protein (EGFP). It was found that TIR of hol was 20 times less effective than that of endo. As it turned out, the level of EGFP production was influenced by the composition of the constructs and the type of the hol start codon. Apparently, the translational suppression of holin's accumulation and posttranslational activation of endolysin by Ca2+ are the main factors ensuring the proper timing of the host cell lysis by bacteriophage T5. The approach based on the use of chimeric constructs proposed in the paper can be recommended for studying other native or artificial operons of any complexity: analyzing the impacts of separate DNA regions, as well as their coupled effect, on the processes of transcription and translation of recombinant protein(s). [ABSTRACT FROM AUTHOR]

Published
2024
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23. Investigating novel Streptomyces bacteriophage endolysins as potential antimicrobial agents

Author

Jindanuch Maneekul, Amanda Chiaha, Rachel Hughes, Faith Labry, Joshua Saito, Matthew Almendares, Brenda N. Banda, Leslie Lopez, Nyeomi McGaskey, Melizza Miranda, Jenil Rana, Brandon R. Zadeh, and Lee E. Hughes

Subjects
endolysin, Streptomyces phage, bioinformatics, antimicrobial activity, Microbiology, QR1-502
Abstract

ABSTRACT As antibiotic resistance has become a major global threat, the World Health Organization (WHO) has urgently called for alternative strategies for control of bacterial infections. Endolysin, a phage-encoded protein, can degrade bacterial peptidoglycan (PG) and disrupt bacterial growth. According to the WHO, there are only three endolysin products currently in clinical phase development. In this study, we explore novel endolysins from Streptomyces phages as only a few of them have been experimentally characterized. Using several bioinformatics tools, we identified nine different functional domain combinations from 250 Streptomyces phages putative endolysins. LazerLemon gp35 (CHAP; LL35lys), Nabi gp26 (amidase; Nb26lys), and Tribute gp42 (PGRP/amidase; Tb42lys) were selected for experimental studies. We hypothesized that (i) the proteins of interest will have the ability to degrade purified PG, and (ii) the proteins will have potential antimicrobial activity against bacteria from families of importance in antibiotic resistance, such as ESKAPE safe relatives (Enterococcus raffinosus, Staphylococcus epidermidis, Klebsiella aerogenes, Acinetobacter baylyi, Pseudomonas putida, and Escherichia coli). LL35lys, Nb26lys, and Tb42lys exhibit PG-degrading activity on zymography and hydrolysis assay. The enzymes (100 µg/mL) can reduce PG turbidity to 32%–40%. The killing assay suggests that Tb42lys has a broader range (E. coli, P. putida, A. baylyi and K. aerogenes). While Nb26lys better attacks Gram-negative than -positive bacteria, LL35lys can only reduce the growth of the Gram-positive ESKAPE strains but does so effectively with a low MIC90 of 2 µg/mL. A higher concentration (≥300 µg/mL) of Nb26lys is needed to inhibit P. putida and K. aerogenes. From 250 putative endolysins, bioinformatic methods were used to select three putative endolysins for cloning and study: LL35lys, Nb26lys, and Tb42lys. All have shown PG-degrading activity, a critical function of endolysin. With a low MIC, LL35lys shows activity for the Gram-positive ESKAPE strains, while Nb26lys and Tb42lys are active against the Gram negatives. Therefore, endolysins from Streptomyces phages have potential as possible antimicrobial agents against ESKAPE bacteria.IMPORTANCEAs antibiotic resistance has become a major global threat, the World Health Organization (WHO) has urgently called for alternative strategies for control of bacterial infections. Endolysin, a phage-encoded protein, can degrade bacterial peptidoglycan in the bacterial cell wall and disrupt bacterial growth. According to the WHO, there are only three endolysin products currently in clinical phase development. In this study we explored novel endolysins from Streptomyces phages as only a few of them have been experimentally characterized. Using several bioinformatics tools, we identified nine different combinations of functional enzymatic domain types from 250 Streptomyces bacteriophages possible endolysins. From these, three potential endolysins were selected for experimental characterization. All three showed positive results in degrading cell wall material and disrupting bacterial growth, indicating their potential as possible antimicrobial agents.

Published
2025
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24. Identification of cell wall binding domains and repeats in Streptococcus pneumoniae phage endolysins: A molecular and diversity analysis

Author

Tahsin Khan, Shakhinur Islam Mondal, Araf Mahmud, Daniyal Karim, Lorraine A. Draper, Colin Hill, Abul Kalam Azad, and Arzuba Akter

Subjects
Endolysin, Alternatives to antibiotics, Streptococcus pneumoniae, Drug resistance, Biology (General), QH301-705.5, Biochemistry, QD415-436
Abstract

Streptococcus pneumoniae (pneumococcus) is a multidrug-resistant pathogen associated with pneumonia, otitis media, meningitis and other severe complications that are currently a global threat to human health. The World Health Organization listed Pneumococcus as the fourth of twelve globally prioritized pathogens. Identifying alternatives to antibiotic therapies is urgently needed to combat Pneumococcus. Bacteriophage-derived endolysins can be used as alternative therapeutics due to their bacterial cell wall hydrolyzing capability. In this study, S. pneumoniae phage genomes were screened to create a database of endolysins for molecular modelling and diversity analysis of these lytic proteins. A total of 89 lytic proteins were curated from 81 phage genomes and categorized into eight groups corresponding to their different enzymatically active (EAD) domains and cell wall binding (CBDs) domains. We then constructed three-dimensional structures that provided insights into these endolysins. Group I, II, III, V, and VI endolysins showed conserved catalytic and ion-binding residues similar to existing endolysins available in the Protein Data Bank. While performing structural and sequence analysis with template lysin, an additional cell wall binding repeat was observed in Group II lysin, which was not previously known. Molecular docking performed with choline confirmed the existence of this additional repeat. Group III endolysins showed 99.16 % similarity to LysME-EF1, a lysin derived from Enterococcus faecalis. Furthermore, the comparative computational analysis revealed the existence of CBDs in Group III lysin. This study provides the first insight into the molecular and diversity analysis of S. pneumoniae phage endolysins that could be valuable for developing novel lysin-based therapeutics.

Published
2024
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25. Phage lysins for intestinal microbiome modulation: current challenges and enabling techniques

Author

Iris Pottie, Roberto Vázquez Fernández, Tom Van de Wiele, and Yves Briers

Subjects
Phage lysin, endolysin, microbiome modulation, antibiotic, dysbiosis, Diseases of the digestive system. Gastroenterology, RC799-869
Abstract

The importance of the microbiota in the intestinal tract for human health has been increasingly recognized. In this perspective, microbiome modulation, a targeted alteration of the microbial composition, has gained interest. Phage lysins, peptidoglycan-degrading enzymes encoded by bacteriophages, are a promising new class of antibiotics currently under clinical development for treating bacterial infections. Due to their high specificity, lysins are considered microbiome-friendly. This review explores the opportunities and challenges of using lysins as microbiome modulators. First, the high specificity of endolysins, which can be further modulated using protein engineering or targeted delivery methods, is discussed. Next, obstacles and possible solutions to assess the microbiome-friendliness of lysins are considered. Finally, lysin delivery to the intestinal tract is discussed, including possible delivery methods such as particle-based and probiotic vehicles. Mapping the hurdles to developing lysins as microbiome modulators and identifying possible ways to overcome these hurdles can help in their development. In this way, the application of these innovative antimicrobial agents can be expanded, thereby taking full advantage of their characteristics.

Published
2024
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28. Genomic analysis of Salmonella bacteriophages revealed multiple endolysin ORFs and importance of ligand-binding site of receptor-binding protein.

Author

Guzel, Mustafa, Yucefaydali, Aysenur, Yetiskin, Segah, Deniz, Aysu, Yaşar Tel, Osman, Akçelik, Mustafa, and Soyer, Yeşim

Subjects
*GENOMICS, *FOOD pathogens, *POULTRY farms, *DRUG resistance in bacteria, *AMINO acid sequence, *BACTERIOPHAGES
Abstract

Salmonella is a prevalent foodborne pathogen causing millions of global cases annually. Antimicrobial resistance is a growing public health concern, leading to search for alternatives like bacteriophages. A total of 97 bacteriophages, isolated from cattle farms (n = 48), poultry farms (n = 37), and wastewater (n = 5) samples in Türkiye, were subjected to host-range analysis using 36 Salmonella isolates with 18 different serotypes. The broadest host range belonged to an Infantis phage (MET P1-091), lysing 28 hosts. A total of 10 phages with the widest host range underwent further analysis, revealing seven unique genomes (32−243 kb), including a jumbophage (>200 kb). Except for one with lysogenic properties, none of them harbored virulence or antibiotic resistance genes, making them potential Salmonella reducers in different environments. Examining open reading frames (ORFs) of endolysin enzymes revealed surprising findings: five of seven unique genomes contained multiple endolysin ORFs. Despite sharing same endolysin sequences, phages exhibited significant differences in host range. Detailed analysis unveiled diverse receptor-binding protein sequences, with similar structures but distinct ligand-binding sites. These findings emphasize the importance of ligand-binding sites of receptor-binding proteins. Additionally, bacterial reduction curve and virulence index revealed that Enteritidis phages inhibit bacterial growth even at low concentrations, unlike Infantis and Kentucky phages. [ABSTRACT FROM AUTHOR]

Published
2024
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29. Lysins as a powerful alternative to combat Bacillus anthracis.

Author

Nakonieczna, Aleksandra, Abramowicz, Karolina, Kwiatek, Magdalena, and Kowalczyk, Ewelina

Subjects
*LYSINS, *BACILLUS anthracis, *BACTERIOPHAGES, *AMINO acid sequence, *AMIDASES, *ZOONOSES, *BACILLUS cereus
Abstract

This review gathers all, to the best of our current knowledge, known lysins, mainly bacteriophage-derived, that have demonstrated activity against Bacillus anthracis strains. B. anthracis is a spore-forming, toxin-producing bacteria, naturally dwelling in soil. It is best known as a potential biowarfare threat, an etiological agent of anthrax, and a severe zoonotic disease. Anthrax can be treated with antibiotics (ciprofloxacin, penicillin, doxycycline); however, their administration may take up even to 60 days, and different factors can compromise their effectiveness. Bacterial viruses, bacteriophages (phages), are natural enemies of bacteria and use their lytic enzymes, endolysins (lysins), to specifically kill bacterial cells. Harnessing the potential of lysins to combat bacterial infections holds promise for diminishing antibiotic usage and, consequently, addressing the escalating antibiotic resistance in bacteria. In this context, we list the lysins with the activity against B. anthracis, providing a summary of their lytic properties in vitro and the outcomes observed in animal models. Bacillus cereus strain ATCC 4342/RSVF1, a surrogate for B. anthracis, was also included as a target bacteria. Key points: • More than a dozen different B. anthracis lysins have been identified and studied. • They fall into three blocks regarding their amino acid sequence similarity and most of them are amidases. • Lysins could be used in treating B. anthracis infections. [ABSTRACT FROM AUTHOR]

Published
2024
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30. Decoding the Structure–Function Relationship of the Muramidase Domain in E. coli O157.H7 Bacteriophage Endolysin: A Potential Building Block for Chimeric Enzybiotics.

Author

Javid, Mehri, Shahverdi, Ahmad Reza, Ghasemi, Atiyeh, Moosavi-Movahedi, Ali Akbar, Ebrahim-Habibi, Azadeh, and Sepehrizadeh, Zargham

Subjects
*ESCHERICHIA coli, *LYSOZYMES, *GRAM-negative bacterial diseases, *BACTERIAL cell walls, *MOLECULAR dynamics, *BACTERIOPHAGES
Abstract

Bacteriophage endolysins are potential alternatives to conventional antibiotics for treating multidrug-resistant gram-negative bacterial infections. However, their structure–function relationships are poorly understood, hindering their optimization and application. In this study, we focused on the individual functionality of the C-terminal muramidase domain of Gp127, a modular endolysin from E. coli O157:H7 bacteriophage PhaxI. This domain is responsible for the enzymatic activity, whereas the N-terminal domain binds to the bacterial cell wall. Through protein modeling, docking experiments, and molecular dynamics simulations, we investigated the activity, stability, and interactions of the isolated C-terminal domain with its ligand. We also assessed its expression, solubility, toxicity, and lytic activity using the experimental data. Our results revealed that the C-terminal domain exhibits high activity and toxicity when tested individually, and its expression is regulated in different hosts to prevent self-destruction. Furthermore, we validated the muralytic activity of the purified refolded protein by zymography and standardized assays. These findings challenge the need for the N-terminal binding domain to arrange the active site and adjust the gap between crucial residues for peptidoglycan cleavage. Our study shed light on the three-dimensional structure and functionality of muramidase endolysins, thereby enriching the existing knowledge pool and laying a foundation for accurate in silico modeling and the informed design of next-generation enzybiotic treatments. [ABSTRACT FROM AUTHOR]

Published
2024
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31. Biofilm-disrupting effects of phage endolysins LysAm24, LysAp22, LysECD7, and LysSi3: breakdown the matrix.

Author

Lendel, Anastasiya M., Antonova, Nataliia P., Grigoriev, Igor V., Usachev, Evgeny V., Gushchin, Vladimir A., and Vasina, Daria V.

Subjects
*KLEBSIELLA pneumoniae, *LYSINS, *GRAM-negative bacteria, *ACINETOBACTER baumannii, *BIOFILMS, *DRUG resistance in microorganisms, *BACTERIOPHAGES
Abstract

The ability of most opportunistic bacteria to form biofilms, coupled with antimicrobial resistance, hinder the efforts to control widespread infections, resulting in high risks of negative outcomes and economic costs. Endolysins are promising compounds that efficiently combat bacteria, including multidrug-resistant strains and biofilms, without a low probability of subsequent emergence of stable endolysin-resistant phenotypes. However, the details of antibiofilm effects of these enzymes are poorly understood. To elucidate the interactions of bacteriophage endolysins LysAm24, LysAp22, LysECD7, and LysSi3 with bacterial films formed by Gram-negative species, we estimated their composition and assessed the endolysins' effects on the most abundant exopolymers in vitro. The obtained data suggests a pronounced efficiency of these lysins against biofilms with high (Klebsiella pneumoniae) and low (Acinetobacter baumannii) matrix contents, or dual-species biofilms, resulting in at least a twofold loss of the biomass. These peptidoglycan hydrolases interacted diversely with protective compounds of biofilms such as extracellular DNA and polyanionic carbohydrates, indicating a spectrum of biofilm-disrupting effects for bacteriolytic phage enzymes. Specifically, we detected disruption of acid exopolysaccharides by LysAp22, strong DNA-binding capacity of LysAm24, both of these interactions for LysECD7, and neither of them for LysSi3. [ABSTRACT FROM AUTHOR]

Published
2024
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32. Yeast Expressing a Phage Endolysin Reduces Endogenous Clostridium perfringens Ex Vivo in 21-Day-Old Broiler Chicken Intestinal Fluids.

Author

Barnas, Michael R., Attuquayefio, Wendy D., Donovan, David M., Skory, Christopher D., Hammond, Rosemarie W., Siragusa, Gregory R., and Timmons, Jennifer R.

Subjects
BROILER chickens, YEAST, SACCHAROMYCES cerevisiae, INTESTINES, ESCHERICHIA coli, BACTERIOPHAGES, CLOSTRIDIUM perfringens
Abstract

SUMMARY The phage endolysin PlyCP41 when purified from Escherichia coli exhibits lytic activity against Clostridium perfringens (CP) in vitro. The anti-clostridial activity of PlyCP41 endolysin expressed in transgenic yeast (Saccharomyces cerevisiae) was verified in phosphate buffered saline via mixing experiments with cultured CP and transgenic yeast slurries followed by serial dilution plating and colony counts on tryptose sulfite cycloserine (CP indicator) plates. The transgenic yeast containing PlyCP41 resulted in a log10 4.5 reduction (99.997%; P < 0.01) of the cultured CP. In addition, this serial dilution plating assay was used to demonstrate that transgenic yeast slurries could reduce the endogenous CP content in fluids from three different gastrointestinal regions (proximal, medial, and distal) from 21-day-old broiler chickens. The transgenic yeast treatment of gut slurries resulted in a log 10 1.19, 4.53, and 1.28 reduction in proximal, medial, and distal gut slurries (90% to 99.99% of the endogenous CP; P < 0.01), respectively, compared to nontreatment controls. These results indicate that the phage endolysin PlyCP41 expressed in S. cerevisiae is effective at reducing the endogenous CP in gastrointestinal fluids of broiler chickens. Future studies will measure the anti-CP effect in vivo by administering transgenic yeast to broiler chickens in the feed. RESUMEN Levadura que expresa una fago-endolisina reduce la presencia endógena de Clostridium perfringens Ex vivo en fluidos intestinales de pollos de engorde de 21 días. La fago endolisina PlyCP41, cuando se purifica a partir de Escherichia coli, exhibe actividad lítica contra Clostridium perfringens (Cp) in vitro. La actividad anticlostridial de la endolisina PlyCP41 expresada en levadura transgénica (Saccharomyces cerevisiae) se verificó en solución salina amortiguada con fosfato mediante experimentos de mezclas con cultivos de C. perfringens y suspensiones de levadura transgénica, seguido de cultivos de diluciones en serie y recuentos de colonias en placas de triptosa sulfito cicloserina (TSC; indicador para C. perfringens). La levadura transgénica que contenía PlyCP41 dio como resultado una reducción de log10 4.5 (99.997%; P <0.01) en el cultivo de C. perfringens. Además, este ensayo de dilución en serie en placas se utilizó para demostrar que las suspensiones de levadura transgénica podrían reducir el contenido de C. perfringens endógeno en fluidos de tres regiones gastrointestinales diferentes (proximal, medial y distal) de pollos de engorde de 21 días de edad. El tratamiento con levadura transgénica de las suspensiones intestinales dio como resultado una reducción de log10 de 1.19, 4.53 y 1.28 en las suspensiones intestinales proximal, medial y distal (90% a 99.99 % de C. perfringens endógena; P < 0.01), respectivamente, en comparación con los controles no tratados. Estos resultados indican que la fago-endolisina PlyCP41 expresada en S. cerevisiae es eficaz para reducir el contenido endógeno de C. perfringens en los fluidos gastrointestinales de pollos de engorde. Los estudios futuros medirán el efecto contra C. perfringens in vivo mediante la administración de levadura transgénica a pollos de engorde en el alimento. [ABSTRACT FROM AUTHOR]

Published
2024
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33. Endolysins: a new antimicrobial agent against antimicrobial resistance. Strategies and opportunities in overcoming the challenges of endolysins against Gram-negative bacteria.

Author

Khan, Fazal Mehmood, Rasheed, Fazal, Yunlan Yang, Bin Liu, and Rui Zhang

Subjects
GRAM-negative bacteria, DRUG resistance in microorganisms, ENZYME stability, ACINETOBACTER baumannii, DRUG resistance in bacteria, PROTEIN engineering
Abstract

Antibiotic-resistant bacteria are rapidly emerging, and the increasing prevalence of multidrug-resistant (MDR) Acinetobacter baumannii poses a severe threat to humans and healthcare organizations, due to the lack of innovative antibacterial drugs. Endolysins, which are peptidoglycan hydrolases encoded by a bacteriophage, are a promising new family of antimicrobials. Endolysins have been demonstrated as an effective therapeutic agent against bacterial infections of A. baumannii and many other Gram-positive and Gram-negative bacteria. Endolysin research has progressed from basic in vitro characterization to sophisticated protein engineering methodologies, including advanced preclinical and clinical testing. Endolysin are therapeutic agent that shows antimicrobial properties against bacterial infections caused by drug-resistant Gram-negative bacteria, there are still barriers to their implementation in clinical settings, such as safety concerns with outer membrane permeabilizers (OMP) use, low efficiency against stationary phase bacteria, and stability issues. The application of protein engineering and formulation techniques to improve enzyme stability, as well as combination therapy with other types of antibacterial drugs to optimize their medicinal value, have been reviewed as well. In this review, we summarize the clinical development of endolysin and its challenges and approaches for bringing endolysin therapies to the clinic. This review also discusses the different applications of endolysins. [ABSTRACT FROM AUTHOR]

Published
2024
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34. Bacteriophage Endolysins Mouth Wash Effect for Treatment of Dental Caries Caused by Streptococcus mutans: An In Vivo Study.

Author

Ali, Huda Mohammad Hasan, Al-Zubaidy, Adeeb Ahmed Kadhim, and Abdulamir, Ahmed Sahib

Abstract

The current work aimed to evaluate the in vivo effectiveness of bacteriophage endolysins as oral antibiotic (mouth wash) for treatment of dental caries caused by S. mutans in rats by induction of S. mutans infection and treatment with endolysins, then culture to demonstrate the effectiveness of endolysins on the bacterial growth, and to determine the desired antibacterial concentration of bacteriophage endolysins for treatment of dental caries caused by S. mutans with the desired effects. From patients with dental caries that were attainted to Al-Imamain Al-Kadhimain (Peace Being Upon Them) Medical City Hospital, AL-Ameen Health Center and different individuals from various places having caries from December 2021 to May 2022, twenty-five S. mutans isolates were collected. These isolates were determined by morphology, Gram staining, growing them on their selective media (MS-SBT agar), biochemical tests and VITEK2 compact system. Eight of these S. mutans isolates were used for the in vivo study. The results showed that the endolysin enzyme that was extracted from the corresponding bacteriophage which was specific for the corresponding S. mutans isolate was effective as an antibacterial agent for the treatment of dental caries as mouth wash in this in vivo study, giving minimum inhibitory concentrations (MIC) and minimum bactericidal concentrations (MBC) ranging between 16.78–18.87 and 20.97–23.6 μg/mL respectively. The findings showed that endolysin is effective as antibacterial agent against S. mutans as mouth wash and by injection between teeth and gum. [ABSTRACT FROM AUTHOR]

Published
2024
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35. Engineered endolysin of Klebsiella pneumoniae phage is a potent and broad-spectrum bactericidal agent against "ESKAPEE" pathogens.

Author

Wei Chen, Li-Mei Han, Xiu-Zhen Chen, Peng-Cheng Yi, Hui Li, Yun-Yao Ren, Jing-Han Gao, Cai-Yun Zhang, Jing Huang, Wei-Xiao Wang, Zhi-Liang Hu, and Chun-Mei Hu

Subjects
KLEBSIELLA pneumoniae, ENTEROBACTER cloacae, CHIMERIC proteins, BACTERIOPHAGES, PATHOGENIC microorganisms, SCANNING electron microscopy, DRUG resistance in microorganisms
Abstract

The rise of antimicrobial resistance in ESKAPEE pathogens poses significant clinical challenges, especially in polymicrobial infections. Bacteriophage-derived endolysins offer promise in combating this crisis, but face practical hurdles. Our study focuses on engineering endolysins from a Klebsiella pneumoniae phage, fusing them with ApoE23 and COG133 peptides. We assessed the resulting chimeric proteins' bactericidal activity against ESKAPEE pathogens in vitro. ApoE23-Kp84B (CHU-1) reduced over 3 log units of CFU for A. baumannii, E. faecalis, K. pneumoniae within 1 h, while COG133-Kp84B (CHU-2) showed significant efficacy against S. aureus. COG133-L1-Kp84B, with a GS linker insertion in CHU-2, exhibited outstanding bactericidal activity against E. cloacae and P. aeruginosa. Scanning electron microscopy revealed alterations in bacterial morphology after treatment with engineered endolysins. Notably, CHU-1 demonstrated promising anti-biofilm and anti-persister cell activity against A. baumannii and E. faecalis but had limited efficacy in a bacteremia mouse model of their coinfection. Our findings advance the field of endolysin engineering, facilitating the customization of these proteins to target specific bacterial pathogens. This approach holds promise for the development of personalized therapies tailored to combat ESKAPEE infections effectively. [ABSTRACT FROM AUTHOR]

Published
2024
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36. Influence of Lipopolysaccharide-Interacting Peptides Fusion with Endolysin LysECD7 and Fatty Acid Derivatization on the Efficacy against Acinetobacter baumannii Infection In Vitro and In Vivo.

Author

Li, Xiaowan, Shangguan, Wenwen, Yang, Xiaoqian, Hu, Xiaoyue, Li, Yanan, Zhao, Wenjie, Feng, Meiqing, and Feng, Jun

Subjects
*ACINETOBACTER baumannii, *ACINETOBACTER infections, *FATTY acids, *DERIVATIZATION, *MULTIDRUG resistance, *PEPTIDES
Abstract

Acinetobacter baumannii has developed multiple drug resistances, posing a significant threat to antibiotic efficacy. LysECD7, an endolysin derived from phages, could be a promising therapeutic agent against multi-drug resistance A. baumannii. In this study, in order to further enhance the antibacterial efficiency of the engineered LysECD7, a few lipopolysaccharide-interacting peptides (Li5, MSI594 and Li5-MSI) were genetically fused with LysECD7. Based on in vitro antibacterial activity, the fusion protein Lys-Li5-MSI was selected for further modifications aimed at extending its half-life. A cysteine residue was introduced into Lys-Li5-MSI through mutation (Lys-Li5-MSIV12C), followed by conjugation with a C16 fatty acid chain via a protonation substitution reaction(V12C-C16). The pharmacokinetic profile of V12C-C16 exhibited a more favorable characteristic in comparison to Lys-Li5-MSI, thereby resulting in enhanced therapeutic efficacy against lethal A. baumannii infection in mice. The study provides valuable insights for the development of novel endolysin therapeutics and proposes an alternative therapeutic strategy for combating A. baumannii infections. [ABSTRACT FROM AUTHOR]

Published
2024
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37. Bacteriophage Endolysins Antibacterial Effect against S. mutans Isolated from Dental Caries: An In-Vitro Study.

Author

Hasan Ali, Huda Mohammad, Kadhim Al-Zubaidy, Adeeb Ahmed, and Abdulamir, Ahmed Sahib

Subjects
*BACTERIOPHAGES, *ANTIBACTERIAL agents, *STREPTOCOCCUS mutans, *ANTIBIOTICS, *BACTERIAL cultures
Abstract

Background: Many bacterial infections including dental caries that caused by Streptococcus mutans (S. mutans) were difficult to be treated due to the unavailability of effective antibiotics. Therefore, it requires to focus the attention on endolysin as an antibacterial agent. This study was designed to evaluate the In-vitro effectiveness of specific bacteriophage endolysins against S. mutans isolated from dental caries. Methods: Twenty-five isolates of S. mutans were collected from patients with dental caries attended to Al-Imamain Al-Kadhimain, Medical City Hospital, and AL-Ameen Health Center, during the period from December 2021 to May 2022. The S. mutans isolates were identified by culturing them on their specific mitis salivarius sucrose bacitracin tellurite media (MS-SBT agar), morphological characteristics, gram staining, biochemical tests and VITEK 2 compact system. Seven of these S. mutans isolates were used for the in-vitro study. Results: The bacteriophage endolysin enzyme extracted from the corresponding S. mutans isolate was effective as In-vitro antibacterial agent with minimum inhibitory concentration (MIC) and minimum bactericidal concentration (MBC) ranging between (13.63 - 17.83) µg/ml and (17.04-22.28) µg/ml respectively. Conclusion: The endolysin was effective as antibacterial agent against multi-drug resistant (MDR) S. mutans upon growing and testing on culture media. [ABSTRACT FROM AUTHOR]

Published
2024
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38. Lysin and Lytic Phages Reduce Vibrio Counts in Live Feed and Fish Larvae.

Author

Romero, Jaime, Blas-Chumacero, Sergueia, Urzúa, Victoria, Villasante, Alejandro, Opazo, Rafael, Gajardo, Felipe, Miranda, Claudio D., and Rojas, Rodrigo

Subjects
FISH larvae, VIBRIO anguillarum, VIBRIO alginolyticus, VIBRIO, FISH feeds, BACTERIOPHAGES, STOCK prices, AQUACULTURE
Abstract

Vibrio species are naturally found in estuarine and marine ecosystems, but are also recognized as significant human enteropathogens, often linked to seafood-related illnesses. In aquaculture settings, Vibrio poses a substantial risk of infectious diseases, resulting in considerable stock losses and prompting the use of antimicrobials. However, this practice contributes to the proliferation of antimicrobial-resistant (AMR) bacteria and resistance genes. Our investigation aimed to explore the potential of biological agents such as bacteriophage CH20 and endolysin LysVPp1 in reducing Vibrio bacterial loads in both rotifer and fish larvae. LysVPp1's lytic activity was assessed by measuring absorbance reduction against various pathogenic Vibrio strains. Phage CH20 exhibited a limited host range, affecting only Vibrio alginolyticus GV09, a highly pathogenic strain. Both CH20 and LysVPp1 were evaluated for their effectiveness in reducing Vibrio load in rotifers or fish larvae through short-setting bioassays. Our results demonstrated the significant lytic effect of endolysin LysVPp1 on strains of Vibrio alginolyticus, Vibrio parahaemolyticus, and Vibrio splendidus. Furthermore, we have showcased the feasibility of reducing the load of pathogenic Vibrio in live feed and fish larvae by using a non-antibiotic-based approach, such as lytic phage and endolysin LysVPp1, thus contributing to the progress of a sustainable aquaculture from a One Health perspective. [ABSTRACT FROM AUTHOR]

Published
2024
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39. Role of hypothetical protein PA1-LRP in antibacterial activity of endolysin from a new Pantoea phage PA1

Author

Ye Tian, Xinyan Xu, Munazza Ijaz, Ying Shen, Muhammad Shafiq Shahid, Temoor Ahmed, Hayssam M. Ali, Chengqi Yan, Chunyan Gu, Jianfei Lu, Yanli Wang, Gabrijel Ondrasek, and Bin Li

Subjects
phage, endolysin, lysis, novel lysed protein, fusion expression, Microbiology, QR1-502
Abstract

IntroductionPantoea ananatis has emerged as a significant plant pathogen affecting various crops worldwide, causing substantial economic losses. Bacteriophages and their endolysins offer promising alternatives for controlling bacterial infections, addressing the growing concerns of antibiotic resistance.MethodsThis study isolated and characterized the Pantoea phage PA1 and investigated the role of PA1-LRP in directly damaging bacteria and assisting endolysin PA1-Lys in cell lysis, comparing its effect to exogenous transmembrane domains following the identification and analysis of the PA1-Lys and the PA1-LRP based on whole genome analysis of phage PA1. Additionally, this study also explored how hydrophobic region of PA1-LRP (HPP) contributes to bacterial killing when combined with PA1-Lys and examined the stability and lytic spectrum of PA1-Lys under various conditions.Results and discussionPhage PA1 belonging to the Chaseviridae family exhibited a broad host range against P. ananatis strains, with a latent period of 40 minutes and a burst size of 17.17 phages per infected cell. PA1-Lys remained stable at pH 6-10 and temperatures of 20-50°C and showed lytic activity against various Gram-negative bacteria, while PA1-Lys alone could not directly lyse bacteria, its lytic activity was enhanced in the presence of EDTA. Surprisingly, PA1-LRP inhibited bacterial growth when expressed alone. After 24 h of incubation, the OD600 value of pET28a-LRP decreased by 0.164 compared to pET28a. Furthermore, the lytic effect of co-expressed PA1-LRP and PA1-Lys was significantly stronger than each separately. After 24 h of incubation, compared to pET28a-LRP, the OD600 value of pET28a-Lys-LRP decreased by 0.444, while the OD420 value increased by 3.121. Live/dead cell staining, and flow cytometry experiments showed that the fusion expression of PA1-LRP and PA1-Lys resulted in 41.29% cell death, with bacterial morphology changing from rod-shaped to filamentous. Notably, PA1-LRP provided stronger support for endolysin-mediated cell lysis than exogenous transmembrane domains. Additionally, our results demonstrated that the HPP fused with PA1-Lys, led to 40.60% cell death, with bacteria changing from rod-shaped to spherical and exhibiting vacuolation. Taken together, this study provides insights into the lysis mechanisms of Pantoea phages and identifies a novel lysis-related protein, PA1-LRP, which could have potential applications in phage therapy and bacterial disease control.

Published
2024
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41. Bacteriophage as a potential biotherapeutics to combat present-day crisis of multi-drug resistant pathogens

Author

Ananya Pattnaik, Sanghamitra Pati, and Sangram Keshari Samal

Subjects
Multi-drug resistant, Pathogens, Endolysin, Phage-therapy, Clinical products, Science (General), Q1-390, Social sciences (General), H1-99
Abstract

The rise of Multi-Drug Resistant (MDR) bacterial pathogens to most, if not all, currently available antibacterial agents has become a global threat. As a consequence of the antibiotic resistance epidemic, phage therapy has emerged as a potential alternative to conventional antibiotics. Despite the high therapeutic advantages of phage therapy, they have not yet been successfully used in the clinic due to various limitations of narrow host specificity compared to antibiotics, poor adhesion on biofilm surface, and susceptibility to both human and bacterial defences. This review focuses on the antibacterial effect of bacteriophage and their recent clinical trials with a special emphasis on the underlying mechanism of lytic phage action with the help of endolysin and holin. Furthermore, recent clinical trials of natural and modified endolysins and some marketed products have also been emphasized with future prospective.

Published
2024
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42. Antimicrobial peptide thanatin fused endolysin PA90 (Tha-PA90) for the control of Acinetobacter baumannii infection in mouse model

Author

Jeonghyun Lim, Heejoon Myung, Daejin Lim, and Miryoung Song

Subjects
Endolysin, Thanatin, Tha-PA90, Designed endolysin, A. baumannii infection, Drug-resistant gram-negative pathogen, Medicine
Abstract

Abstract Background This study addresses the urgent need for infection control agents driven by the rise of drug-resistant pathogens such as Acinetobacter baumannii. Our primary aim was to develop and assess a novel endolysin, Tha-PA90, designed to combat these challenges. Methods Tha-PA90 incorporates an antimicrobial peptide (AMP) called thanatin at its N-terminus, enhancing bacterial outer membrane permeability and reducing host immune responses. PA90 was selected as the endolysin component. The antibacterial activity of the purified Tha-PA90 was evaluated using an in vitro colony-forming unit (CFU) reduction assay and a membrane permeability test. A549 cells were utilized to measure the penetration into the cytosol and the cytotoxicity of Tha-PA90. Finally, infection control was monitored in A. baumannii infected mice following the intraperitoneal administration of Tha-PA90. Results Tha-PA90 demonstrated remarkable in vitro efficacy, completely eradicating A. baumannii strains, even drug-resistant variants, at a low concentration of 0.5 μM. Notably, it outperformed thanatin, achieving only a

Published
2024
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43. LysSYL: a broad-spectrum phage endolysin targeting Staphylococcus species and eradicating S. aureus biofilms

Author

He Liu, Xuemei Wei, Zhefen Wang, Xiaonan Huang, Mengyang Li, Zhen Hu, Kexin Zhang, Qiwen Hu, Huagang Peng, Weilong Shang, Yi Yang, Yuting Wang, Shuguang Lu, and Xiancai Rao

Subjects
Phage, Endolysin, Staphylococcus aureus, Biofilms, Persisters, Microbiology, QR1-502
Abstract

Abstract Background Staphylococcus aureus and its single or mixed biofilm infections seriously threaten global public health. Phage therapy, which uses active phage particles or phage-derived endolysins, has emerged as a promising alternative strategy to antibiotic treatment. However, high-efficient phage therapeutic regimens have yet to be established. Results In this study, we used an enrichment procedure to isolate phages against methicillin-resistant S. aureus (MRSA) XN108. We characterized phage SYL, a new member of the Kayvirus genus, Herelleviridae family. The phage endolysin LysSYL was expressed. LysSYL demonstrated stability under various conditions and exhibited a broader range of efficacy against staphylococcal strains than its parent phage (100% vs. 41.7%). Moreover, dynamic live/dead bacterial observation demonstrated that LysSYL could completely lyse MRSA USA300 within 10 min. Scan and transmission electron microscopy revealed evident bacterial cell perforation and deformation. In addition, LysSYL displayed strong eradication activity against single- and mixed-species biofilms associated with S. aureus. It also had the ability to kill bacterial persisters, and proved highly effective in eliminating persistent S. aureus when combined with vancomycin. Furthermore, LysSYL protected BALB/c mice from lethal S. aureus infections. A single-dose treatment with 50 mg/kg of LysSYL resulted in a dramatic reduction in bacterial loads in the blood, liver, spleen, lungs, and kidneys of a peritonitis mouse model, which resulted in rescuing 100% of mice challenged with 108 colony forming units of S. aureus USA300. Conclusions Overall, the data provided in this study highlight the strong therapeutic potential of endolysin LysSYL in combating staphylococcal infections, including mono- and mixed-species biofilms related to S. aureus.

Published
2024
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44. Unveiling Hidden Allies: In Silico Discovery of Prophages in Tenacibaculum Species

Author

Carolina Ramírez and Jaime Romero

Subjects
Tenacibaculosis, phage therapy, Tenacibaculum, endolysin, aquaculture, Therapeutics. Pharmacology, RM1-950
Abstract

Tenacibaculosis, caused by Tenacibaculum species, is a significant disease in aquaculture, leading to high mortality and economic losses. Antibiotic treatment raises concerns about resistance, making phage therapy an interesting alternative. Analyzing phage traces in Tenacibaculum genomes is crucial for developing these bacteriophage-based strategies. Methods: We assessed the presence of prophages in 212 Tenacibaculum genomes/assemblies available in the NCBI repository, comprising several species and global locations, using the PHASTEST program. Then, we focused on those regions classified as intact, evaluating the most common phages found using VICTOR. The protein of interest discovered in the prophages was evaluated using the ProtParam, DeepTMHMM, InterPro, and Phyre2 tools. In addition, we evaluated the presence of antiphage defense systems in those genomes with intact prophages using the DefenseFinder tool. Results: We identified 25 phage elements in 24 out of the 212 Tenacibaculum genomes/assemblies analyzed, with 11% of the assemblies containing phage elements. These were concentrated in T. maritimum and T. mesophilum, which harbored 10 and 7 prophage regions, respectively. Of the identified elements, six were classified as intact, including four in T. maritimum, with the most common phages belonging to the Pippivirus and Siphoviridae families. Bioinformatic analysis showed that the putative endolysin is a stable protein of 432 amino acids and 49.8 kDa, with three transmembrane helices and a CHAP domain, structurally similar to the CHAP lytic domain of S. aureus bacteriophage K. Conclusions: Key prophage elements in Tenacibaculum, especially in T. maritimum, show promise for phage therapy against tenacibaculosis, supporting sustainable, antibiotic-free treatments in aquaculture.

Published
2024
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45. Diversity of Endolysin Domain Architectures in Bacteriophages Infecting Bacilli

Author

Olga N. Koposova, Olesya A. Kazantseva, and Andrey M. Shadrin

Subjects
bacteriophage, endolysin, Bacillus, antibiotic resistance, antibacterial compounds, domain architectures, Microbiology, QR1-502
Abstract

The increasing number of antibiotic-resistant bacterial pathogens is a serious problem in medicine. Endolysins are bacteriolytic enzymes of bacteriophages, and a promising group of enzymes with antibacterial properties. Endolysins of bacteriophages infecting Gram-positive bacteria have a modular domain organization. This feature can be used to design enzymes with new or improved properties by modifying or shuffling individual domains. This work is a detailed analysis 1of the diversity of endolysin domains found in bacteriophages infecting bacilli. During the course of the work, a database of endolysins of such bacteriophages was created, and their domain structures were analyzed using the NCBI database, RASTtk, BLASTp, HHpred, and InterPro programs. A phylogenetic analysis of endolysins was performed using MEGA X. In 438 phage genomes, 454 genes of endolysins were found. In the endolysin sequences found, eight different types of catalytic domains and seven types of cell wall binding domains were identified. The analysis showed that many types of endolysin domains have not yet been characterized experimentally. Studies of the properties of such domains will help to reveal the potential of endolysins for the creation of new antibacterial agents.

Published
2024
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46. Molecular Docking of Endolysins for Studying Peptidoglycan Binding Mechanism

Author

Arina G. Arakelian, Gennady N. Chuev, and Timur V. Mamedov

Subjects
endolysin, peptidoglycan, cell wall, molecular docking, Autodock Vina, 3D-RISM, Organic chemistry, QD241-441
Abstract

Endolysins of bacteriophages, which degrade the bacterial cell wall peptidoglycan, are applicable in many industries to deal with biofilms and bacterial infections. While multi-domain endolysins have both enzymatically active and cell wall-binding domains, single-domain endolysins consist only of an enzymatically active domain, and their mechanism of peptidoglycan binding remains unexplored, for this is a challenging task experimentally. This research aimed to explore the binding mechanism of endolysins using computational approaches, namely molecular docking and bioinformatical tools, and analyze the performance of these approaches. The docking engine Autodock Vina 1.1.2 and the 3D-RISM module of AmberTools 24 were studied in the current work and used for receptor–ligand affinity and binding energy calculations, respectively. Two possible mechanisms of single-domain endolysin–ligand binding were predicted by Autodock Vina and verified by the 3D-RISM. As a result, the previously obtained experimental results on peptidoglycan binding of the isolated gamma phage endolysin PlyG enzymatically active domain were supported by molecular docking. Both methods predicted that single-domain endolysins are able to bind peptidoglycan, with Autodock Vina being able to give accurate numerical estimates of protein–ligand affinities and 3D-RISM providing comparative values.

Published
2024
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