Development of a specific fluorescent phage endolysin for <i>in situ</i> detection of <i>Clostridium</i> species associated with cheese spoilage

Gómez‐Torres, Natalia; Dunne, Matthew; Garde, Sonia; Meijers, Rob; Narbad, Arjan; Ávila, Marta; Mayer, Melinda J.

doi:10.1111/1751-7915.12883

Cited by 29 publications

(14 citation statements)

References 54 publications

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“…As mentioned for tuberculosis, even though there are PCR-based assays faster than the standard method, they cannot differentiate among live and dead cells, which is critical for relevant results, and it is solved with this assay. 43) Similar techniques have been also reported for the detection of Salmonella, 44,45) E. coli, 46) and Clostridium 47,48) in different types of samples.…”

Section: Detection Of Pathogens In Clinical Settings and Food Industrysupporting

confidence: 56%

Engineered Bacteriophages for Practical Applications

Pizarro-Bäuerle

Ando

2020

Biological & Pharmaceutical Bulletin

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The diversity of advanced genetic engineering techniques that have become available in recent years has enabled a more precise manipulation of genes and genomes. Among these, bacteriophage genomes stand out as an interesting target due to their dependence on a host for replication, which previously complicated their manipulation, and due as well to the many possible fields in which they can be used. In this review, we highlight recent applications for which genetically modified bacteriophages are being employed: as phage therapy in medicine, animal industries and agricultural settings; as a source of new antimicrobials; as biosensors for research, health and environmental purposes; and as genetic engineering tools themselves.

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Section: Detection Of Pathogens In Clinical Settings and Food Industrysupporting

confidence: 56%

Engineered Bacteriophages for Practical Applications

Pizarro-Bäuerle

Ando

2020

Biological & Pharmaceutical Bulletin

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“…The natural ability of phages to infect (and kill) a certain bacterial host range has led to their exploitation over the past decades for the development of diagnostic tools and antibacterials for use in medicine [ 25 , 26 ], food production [ 27 , 28 , 29 , 30 , 31 ], and biotechnology [ 32 , 33 , 34 ]. For example, phages can be used to treat Campylobacter [ 35 ] or Salmonella [ 27 ] infections of chicken flocks, or added to feed to kill Clostridium and intestinal coliforms in pigs [ 36 ]; added to ready-to-eat foods to prevent Salmonella [ 37 ] or Listeria [ 38 ] contaminations; or mixed with various food products to act as bio-preservatives [ 39 , 40 , 41 ].…”

Section: Introductionmentioning

confidence: 99%

Molecular Basis of Bacterial Host Interactions by Gram-Positive Targeting Bacteriophages

Dunne

Hupfeld

Klumpp

et al. 2018

Viruses

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The inherent ability of bacteriophages (phages) to infect specific bacterial hosts makes them ideal candidates to develop into antimicrobial agents for pathogen-specific remediation in food processing, biotechnology, and medicine (e.g., phage therapy). Conversely, phage contaminations of fermentation processes are a major concern to dairy and bioprocessing industries. The first stage of any successful phage infection is adsorption to a bacterial host cell, mediated by receptor-binding proteins (RBPs). As the first point of contact, the binding specificity of phage RBPs is the primary determinant of bacterial host range, and thus defines the remediative potential of a phage for a given bacterium. Co-evolution of RBPs and their bacterial receptors has forced endless adaptation cycles of phage-host interactions, which in turn has created a diverse array of phage adsorption mechanisms utilizing an assortment of RBPs. Over the last decade, these intricate mechanisms have been studied intensely using electron microscopy and X-ray crystallography, providing atomic-level details of this fundamental stage in the phage infection cycle. This review summarizes current knowledge surrounding the molecular basis of host interaction for various socioeconomically important Gram-positive targeting phage RBPs to their protein- and saccharide-based receptors. Special attention is paid to the abundant and best-characterized Siphoviridae family of tailed phages. Unravelling these complex phage-host dynamics is essential to harness the full potential of phage-based technologies, or for generating novel strategies to combat industrial phage contaminations.

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“…Alternatively, the localization of LysPBC2 on the developing spores may be evolutionarily beneficial to both phage and host if the endolysin promotes spore germination under favorable environmental conditions. Recently, one study revealed that a Clostridium tyrobutyricum phage endolysin, CTP1L, can bind to clostridial spores (40). Although they did not find an SBD within CTP1L, it is intriguing to identify additional SBDs from phages infecting spore-forming bacteria.…”

Section: Discussionmentioning

confidence: 99%

LysPBC2, a Novel Endolysin Harboring a Bacillus cereus Spore Binding Domain

Kong

et al. 2019

Appl Environ Microbiol

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To control the spore-forming human pathogen Bacillus cereus, we isolated and characterized a novel endolysin, LysPBC2, from a newly isolated B. cereus phage, PBC2. Compared to the narrow host range of phage PBC2, LysPBC2 showed very broad lytic activity against all Bacillus, Listeria, and Clostridium species tested. In addition to a catalytic domain and a cell wall binding domain, LysPBC2 has a spore binding domain (SBD) partially overlapping its catalytic domain, which specifically binds to B. cereus spores but not to vegetative cells of B. cereus. Both immunogold electron microscopy and a binding assay indicated that the SBD binds the external region of the spore cortex layer. Several amino acid residues required for catalytic or spore binding activity of LysPBC2 were determined by mutagenesis studies. Interestingly, LysPBC2 derivatives with impaired spore binding activity showed an increased lytic activity against vegetative cells of B. cereus compared with that of wild-type LysPBC2. Further biochemical studies revealed that these LysPBC2 derivatives have lower thermal stability, suggesting a stabilizing role of SBD in LysPBC2 structure. IMPORTANCE Bacteriophages produce highly evolved lytic enzymes, called endolysins, to lyse peptidoglycan and release their progeny from bacterial cells. Due to their potent lytic activity and specificity, the use of endolysins has gained increasing attention as a natural alternative to antibiotics. Since most endolysins from Gram-positive-bacterium-infecting phages have a modular structure, understanding the function of each domain is crucial to make effective endolysin-based therapeutics. Here, we report the functional and biochemical characterization of a Bacillus cereus phage endolysin, LysPBC2, which has an unusual spore binding domain and a cell wall binding domain. A single point mutation in the spore binding domain greatly enhanced the lytic activity of endolysin at the cost of reduced thermostability. This work contributes to the understanding of the role of each domain in LysPBC2 and will provide insight for the rational design of efficient antimicrobials or diagnostic tools for controlling B. cereus.

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Development of a specific fluorescent phage endolysin for in situ detection of Clostridium species associated with cheese spoilage

Cited by 29 publications

References 54 publications

Engineered Bacteriophages for Practical Applications

Engineered Bacteriophages for Practical Applications

Molecular Basis of Bacterial Host Interactions by Gram-Positive Targeting Bacteriophages

LysPBC2, a Novel Endolysin Harboring a Bacillus cereus Spore Binding Domain

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