The N-Terminal Region of the
 Oenococcus oeni
 Bacteriophage fOg44 Lysin Behaves as a Bona Fide Signal Peptide in
 Escherichia coli
 and as a
 cis
 -Inhibitory Element, Preventing Lytic Activity on Oenococcal Cells

São-José, Carlos; Parreira, Ricardo; Vieira, G.; Santos, Mário A.

doi:10.1128/jb.182.20.5823-5831.2000

Cited by 111 publications

(117 citation statements)

References 37 publications

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“…The presence of N-terminal signal sequences in endolysins suggests an alternative to the lambda paradigm and thus provides a mode of action different from that of the great majority of endolysins to access the PG at the end of the lytic phage cycle. Signal sequences may enable transport of the endolysin through the inner membrane to achieve the periplasm in a holin-independent manner by making use of the host Sec machinery (24,27,77).…”

Section: Resultsmentioning

confidence: 99%

“…Subsequently, a small hydrophobic membranespanning protein called holin is expressed at a genetically predetermined time and accumulates in clusters producing homo-oligomeric pores in the inner membrane, thereby exposing the PG layer to the endolysin (17,25,26). Some endolysins, such as the Bacillus cereus phage TP21-L, Oenococcus oeni phage fOg44, and Lactobacillus plantarum phage Øg1e endolysins, present different intrinsic signal sequences that allow them to pass the cytoplasmic membrane and reach the PG in a holin-independent manner (27,28). The referred lytic systems are reported exclusively for Caudovirales phages, and not much is known about lytic systems present in cassettes of phages outside this order.…”

mentioning

confidence: 99%

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Molecular Aspects and Comparative Genomics of Bacteriophage Endolysins

Oliveira

Melo

Santos

et al. 2013

J Virol

239

247

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Phages are recognized as the most abundant and diverse entities on the planet. Their diversity is determined predominantly by their dynamic adaptation capacities when confronted with different selective pressures in an endless cycle of coevolution with a widespread group of bacterial hosts. At the end of the infection cycle, progeny virions are confronted with a rigid cell wall that hinders their release into the environment and the opportunity to start a new infection cycle. Consequently, phages encode hydrolytic enzymes, called endolysins, to digest the peptidoglycan. In this work, we bring to light all phage endolysins found in completely sequenced double-stranded nucleic acid phage genomes and uncover clues that explain the phage-endolysin-host ecology that led phages to recruit unique and specialized endolysins.

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Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

Molecular Aspects and Comparative Genomics of Bacteriophage Endolysins

Oliveira

Melo

Santos

et al. 2013

J Virol

239

247

View full text Add to dashboard Cite

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“…To obtain this recombinant protein, the corresponding sequence of yueB, obtained by PCR with the primer pair yueB-4/yueB-5, was cloned into pIVEX2.3d (Table 1) after digestion of both the product and the vector with the enzymes NcoI and XmaI. The resulting plasmid (pCSJ65) was used to transform E. coli strain CG61, which produces T7 RNA polymerase upon temperature upshift (from 28 to 42°C) (31). This constructed strain was used to overproduce YueB780, which was then purified from E. coli extracts by affinity chromatography (C. São-José and S. Lhuillier, unpublished data).…”

Section: Methodsmentioning

confidence: 99%

Bacillus subtilisOperon Encoding a Membrane Receptor for Bacteriophage SPP1

2004

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The results reported here have identified yueB as the essential gene involved in irreversible binding of bacteriophage SPP1 to Bacillus subtilis. First, a deletion in an SPP1-resistant (pha-2) strain, covering most of the yueB gene, could be complemented by a xylose-inducible copy of yueB inserted at amyE. Second, disruption of yueB by insertion of a pMutin4 derivative resulted in a phage resistance phenotype regardless of the presence or absence of IPTG (isopropyl-␤-D-thiogalactopyranoside). YueB homologues are widely distributed in grampositive bacteria. The protein Pip, which also serves as a phage receptor in Lactococcus lactis, belongs to the same family. yueB encodes a membrane protein of ϳ120 kDa, detected in immunoblots together with smaller forms that may be processed products arising from cleavage of its long extracellular domain. Insertional inactivation of yueB and the surrounding genes indicated that yueB is part of an operon which includes at least the upstream genes yukE, yukD, yukC, and yukBA. Disruption of each of the genes in the operon allowed efficient irreversible adsorption, provided that yueB expression was retained. Under these conditions, however, smaller plaques were produced, a phenotype which was particularly noticeable in yukE mutant strains. Interestingly, such reduction in plaque size was not correlated with a decreased adsorption rate. Overall, these results provide the first demonstration of a membrane-bound protein acting as a phage receptor in B. subtilis and suggest an additional involvement of the yukE operon in a step subsequent to irreversible adsorption.The interaction of a bacteriophage with the bacterial surface (adsorption) is the first step in the infection process. This step involves recognition of and binding to one or more cell envelope constituents and leads to ejection of the phage DNA from the capsid. It has long been appreciated that adsorption can proceed in two steps, one reversible step followed by irreversible commitment (1). Irreversible adsorption and ejection of DNA are possibly different descriptions of the same phenomenon, but this has not really been clarified. Similarly, DNA ejection from the capsid and injection into the cytoplasm are at best difficult to separate in vivo, except in those cases where injection itself proceeds in distinct phases, as in T5 (13).In the gram-negative world, several phage receptors have been identified, and in a number of cases (e.g., T4, T5, and T7 of Escherichia coli), the adsorption and injection processes are now beginning to be understood at a detailed molecular level (14,18,26). Much less is known about the first steps of infection for phages preying on gram-positive bacteria. Early work has established that glucosylated polyglycerol phosphate, the major and essential teichoic acid in Bacillus subtilis, serves as a receptor for several phages, including 29, 25, and SP01 (24,29,34,36). Mutations leading to a lack of glucosylation of this polymer block the phage adsorption process and plaque-forming ability. More rece...

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“…Holin and endolysin genes can be identified by analysis of the genomic sequences of most dsDNA phages, although only a few have been characterized in terms of in vivo function. For phages tested to date, the endolysin requires the holin to achieve access to the peptidoglycan, except in some phages of gram-positive bacteria, where the endolysins use the sec system (20). The best-characterized example of holin-endolysin systems is that of phage , where the S gene encodes the holin and R encodes the endolysin, a transglycosylase.…”

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confidence: 99%

Sizing the Holin Lesion with an Endolysin-β-Galactosidase Fusion

2003

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Double-stranded DNA phages require two proteins for efficient host lysis: the endolysin, a muralytic enzyme, and the holin, a small membrane protein. In an event that defines the end of the vegetative cycle, the holin S acts suddenly to permeabilize the membrane. This permeabilization enables the R endolysin to attack the cell wall, after which cell lysis occurs within seconds. A C-terminal fusion of the R endolysin with full-length ␤-galactosidase (␤-Gal) was tested for lytic competence in the context of the late-gene expression system of an induced lysogen. Under these conditions, the hybrid R-␤-Gal product, an active tetrameric ␤-Gal greater than 480 kDa in mass, was fully functional in lysis mediated by the S holin. Western blot analysis demonstrated that the lytic competence was not due to the proteolytic release of the endolysin domain of the R-␤-Gal fusion protein. The ability of this massive complex to be released by the S holin suggests that S causes a generalized membrane disruption rather than a regular oligomeric membrane pore. Similar results were obtained with an early lysis variant of the S holin and also in parallel experiments with the T4 holin, T, in an identical lambda context. However, premature holin lesions triggered by depolarization of the membrane were nonpermissive for the hybrid endolysin, indicating that these premature lesions constituted less-profound damage to the membrane. Finally, a truncated T holin functional in lysis with the endolysin is completely incompetent for lysis with the hybrid endolysin. A model for the formation of the membrane lesion within homo-oligomeric rafts of holin proteins is discussed.

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The N-Terminal Region of the Oenococcus oeni Bacteriophage fOg44 Lysin Behaves as a Bona Fide Signal Peptide in Escherichia coli and as a cis -Inhibitory Element, Preventing Lytic Activity on Oenococcal Cells

Cited by 111 publications

References 37 publications

Molecular Aspects and Comparative Genomics of Bacteriophage Endolysins

Molecular Aspects and Comparative Genomics of Bacteriophage Endolysins

Bacillus subtilisOperon Encoding a Membrane Receptor for Bacteriophage SPP1

Sizing the Holin Lesion with an Endolysin-β-Galactosidase Fusion

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