Membrane fusion during phage lysis

Rajaure, Manoj; Berry, Joel D.; Kongari, Rohit; Cahill, Jesse; Young, Ry

doi:10.1073/pnas.1420588112

Cited by 67 publications

(73 citation statements)

References 43 publications

(54 reference statements)

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“…The PG meshwork acts as a negative inhibitor of gp11 function. Previously, we showed that PG depletion in the presence of physiological levels of Rz-Rz1 resulted in lysis, independent of holin or endolysin function (8). This implied the intact PG network acts a negative regulator of two-component spanin function, preventing IM-OM fusion until the lytic pathway is initiated by holin triggering (8).…”

Section: Resultsmentioning

confidence: 88%

“…Proposed structural models of these complexes rely heavily on detailed genetic and biochemical analysis (4-7), focused on the predominantly alpha-helical, coiled-coil structure of the i-spanin. Moreover, there is compelling evidence that the spanin complexes disrupt the OM by causing IM-OM fusion and that this topological function is blocked as long as the PG is intact (8).…”

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confidence: 99%

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Localization and Regulation of the T1 Unimolecular Spanin

Kongari

Snowden

Berry

et al. 2018

J Virol

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Spanins are bacteriophage lysis proteins responsible for disruption of the outer membrane, the final step of Gram-negative host lysis. The absence of spanins results in a terminal phenotype of fragile spherical cells. The phage T1 employs a unimolecular spanin gp that has an N-terminal lipoylation signal and a C-terminal transmembrane domain. Upon maturation and localization, gp ends up as an outer membrane lipoprotein with a C-terminal transmembrane domain embedded in the inner membrane, thus connecting both membranes as a covalent polypeptide chain. Unlike the two-component spanins encoded by most of the other phages, including lambda, the unimolecular spanins have not been studied extensively. In this work, we show that the gp mutants lacking either membrane localization signal were nonfunctional and conferred a partially dominant phenotype. Translation from internal start sites within the gp coding sequence generated a shorter product which exhibited a negative regulatory effect on gp function. Fluorescence spectroscopy time-lapse videos of gp-GFP expression showed gp accumulated in distinct punctate foci, suggesting localized clusters assembled within the peptidoglycan meshwork. In addition, gp was shown to mediate lysis in the absence of holin and endolysin function when peptidoglycan density was depleted by starvation for murein precursors. This result indicates that the peptidoglycan is a negative regulator of gp function. This supports a model in which gp acts by fusing the inner and outer membranes, a mode of action analogous to but mechanistically distinct from that proposed for the two-component spanin systems. Spanins have been proposed to fuse the cytoplasmic and outer membranes during phage lysis. Recent work with the lambda spanins Rz-Rz1, which are similar to class I viral fusion proteins, has shed light on the functional domains and requirements for two-component spanin function. Here we report, for the first time, a genetic and biochemical approach to characterize unimolecular spanins, which are structurally and mechanistically different from two-component spanins. Considering similar predicted secondary structures within the ectodomains, unimolecular spanins can be regarded as a prokaryotic version of type II viral membrane fusion proteins. This study not only adds to our understanding of regulation of phage lysis at various levels but also provides a prokaryotic genetically tractable platform for interrogating class II-like membrane fusion proteins.

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Section: Resultsmentioning

confidence: 88%

mentioning

confidence: 99%

Localization and Regulation of the T1 Unimolecular Spanin

Kongari

Snowden

Berry

et al. 2018

J Virol

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“…Phages infecting Gram-negative bacteria harbour an additional lytic tool; the spanins. Two-component spanins are integral membrane proteins (i-spanins and o-spanins for inner and outer membranes, respectively) that form a complex spanning the periplasm, and recently also unimolecular spanins (u-spanins) have been described (Summer et al, 2007;Rajaure et al, 2015). At the time of lysis, spanins change their conformation to fuse the outer and inner membranes.…”

Section: Proteins Diversity and Domain Architecturesmentioning

confidence: 99%

Diversity, specificity and molecular evolution of the lytic arsenal of Pseudomonas phages: in silico perspective

Valero-Rello¹

2019

Environmental Microbiology

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Summary Bacteriophages encode an arsenal of proteins to lyse bacteria by breaking their surface structures, constituting a promising alternative to antibiotics. However, the selection and bioengineering of endolysins and other phage lytic proteins need to be assisted by a previous knowledge of their molecular characteristics. In this study, all putative lytic proteins encoded in Pseudomonas phages were in silico examined to describe their diversity, host association and molecular evolution. A total of 491 proteins were identified among 223 phages, including endolysins, holins, pinholins, spanins, lipases and peptidases. Protein families and combination of functional domains were characteristic of phages belonging to the same genus, and these tended to infect a single host species. Clustering and phylogenetic analysis showed a protein grouping associated with bacterial host, and some functional domains being specific. Interestingly, most putative lytic proteins from phages infecting P. fluorescens and P. putida had negative net charges, opposed to most endolysins. Phage lifestyle also had an impact on protein variability, with transglycosylases, glucosaminidases, holins and spanins from lysogenic phages clustering into monophyletic nodes, suggesting the effect of a different selection pressure as a result of the co‐option of a new function in the lysogenized bacteria.

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“…Although the lysis event has been well-studied operationally through the use of video-microscopic as well as molecular and physiological methods 9–11 , there is little information on the impact of the lytic pathway on biomechanics and physical structure of the infected cell. During the last decade, several researchers have used atomic force microscopes (AFM) to characterize the infection cycle of E. coli by different phages.…”

Section: Introductionmentioning

confidence: 99%

Bursting out: linking changes in nano-topography and biomechanical properties of biofilm-forming Escherichia coli to T4 lytic cycle

Abraham

Kaufman

Perreault

et al. 2020

Preprint

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ABSTRACTBacteriophage infection cycle has been extensively studied, yet little is known on the structural and mechanical changes that lead to bacterial lysis. Here, bio-atomic force microscopy was used to study in real-time and in-situ the impact of the canonical phage T4 on the nano-topography and biomechanics of irreversibly attached, biofilm-forming E. coli cells. The results show that in contrast to the lytic cycle in planktonic cells, which ends explosively, anchored cells that are in the process of forming biofilms undergo gradual lysis, developing distinct sub-micron lesions (∼300 nm in diameter) within the cell envelope. Furthermore, it is shown that the envelope rigidity and cell elasticity decrease (>50% and >40%, respectively) following T4 infection. These new insights show that the well-established lytic pathway of planktonic cells may be significantly different from that of biofilm-forming cells. Elucidating the lysis paradigm of these cells may advance biofilm removal and phage therapeutic.There is no conflict of interest and all co-authors have seen and approved the current version for submission.

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Membrane fusion during phage lysis

Cited by 67 publications

References 43 publications

Localization and Regulation of the T1 Unimolecular Spanin

Localization and Regulation of the T1 Unimolecular Spanin

Diversity, specificity and molecular evolution of the lytic arsenal of Pseudomonas phages: in silico perspective

Bursting out: linking changes in nano-topography and biomechanical properties of biofilm-forming Escherichia coli to T4 lytic cycle

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