Phage lysis: Three steps,three choices,one outcome

The lysis of bacterial hosts by double-strand DNA bacteriophages, once thought to reflect merely the accumulation of sufficient lysozyme activity during the infection cycle, has been revealed to recently been revealed to be a carefully regulated and temporally scheduled process. For phages of Gramnegative hosts, there are three steps, corresponding to subversion of each of the three layers of the cell envelope: inner membrane, peptidoglycan, and outer membrane. The pathway is controlled at the level of the cytoplasmic membrane. In canonical lysis, a phage encoded protein, the holin, accumulates harmlessly in the cytoplasmic membrane until triggering at an allele-specific time to form micron-scale holes. This allows the soluble endolysin to escape from the cytoplasm to degrade the peptidoglycan. Recently a parallel pathway has been elucidated in which a different type of holin, the pinholin, which, instead of triggering to form large holes, triggers to form small, heptameric channels that serve to depolarize the membrane. Pinholins are associated with SAR endolysins, which accumulate in the periplasm as inactive, membrane-tethered enzymes. Pinholin triggering collapses the proton motive force, allowing the SAR endolysins to refold to an active form and attack the peptidoglycan. Surprisingly, a third step, the disruption of the outer membrane is also required. This is usually achieved by a spanin complex, consisting of a small outer membrane lipoprotein and an integral cytoplasmic membrane protein, designated as o-spanin and i-spanin, respectively. Without spanin function, lysis is blocked and progeny virions are trapped in dead spherical cells, suggesting that the outer membrane has considerable tensile strength. In addition to two-component spanins, there are some single-component spanins, or u-spanins, that have an N-terminal outer-membrane lipoprotein signal and a C-terminal transmembrane domain. A possible mechanism for spanin function to disrupt the outer membrane is to catalyze fusion of the inner and outer membranes.     

Rz/Rz1 lysis gene equivalents in phages of Gram-negative hosts

Under usual laboratory conditions, lysis by bacteriophage lambda requires only the holin and endolysin genes, but not the Rz and Rz1 genes, of the lysis cassette. Defects in Rz or Rz1 block lysis only in the presence of high concentrations of divalent cations. The lambda Rz and Rz1 lysis genes are remarkable in that Rz1, encoding an outer membrane lipoprotein, is completely embedded in the +1 register within Rz, which itself encodes an integral inner membrane protein. While Rz and Rz1 equivalents have been identified in T7 and P2, most phages, including such well-studied classic phages as T4, P1, T1, Mu and SP6, lack annotated Rz/Rz1 equivalents. Here we report that a search strategy based primarily on gene arrangement and membrane localization signals rather than sequence similarity has revealed that Rz/Rz1 equivalents are nearly ubiquitous among phages of Gram-negative hosts, with 120 of 137 phages possessing genes that fit the search criteria. In the case of T4, a deletion of a non-overlapping gene pair pseT.2 and pseT.3 identified as Rz/Rz1 equivalents resulted in the same divalent cation-dependent lysis phenotype. Remarkably, in T1 and six other phages, Rz/Rz1 pairs were not found but a single gene encoding an outer membrane lipoprotein with a C-terminal transmembrane domain capable of integration into the inner membrane was identified. These proteins were named "spanins," since their protein products are predicted to span the periplasm providing a physical connection between the inner and outer membranes. The T1 spanin gene was shown to complement the lambda Rz-Rz1- lysis defect, indicating that spanins function as Rz/Rz1 equivalents. The widespread presence of Rz/Rz1 or their spanin equivalents in phages of Gram-negative hosts suggests a strong selective advantage and that their role in the ecology of these phages is greater than that inferred from the mild laboratory phenotype.     

The lambda spanin components Rz and Rz1 undergo tertiary and quaternary rearrangements upon complex formation

Phage holins and endolysins have long been known to play key roles in lysis of the host cell, disrupting the cytoplasmic membrane and peptidoglycan (PG) layer, respectively. For phages of Gram‐negative hosts, a third class of proteins, the spanins, are involved in disrupting the outer membrane (OM). Rz and Rz1, the components of the lambda spanin, are, respectively, a class II inner membrane protein and an OM lipoprotein, are thought to span the entire periplasm by virtue of C‐terminal interactions of their soluble domains. Here, the periplasmic domains of Rz and Rz1 have been purified and shown to form dimeric and monomeric species, respectively, in solution. Circular dichroism analysis indicates that Rz has significant alpha‐helical character, but much less than predicted, whereas Rz1, which is 25% proline, is unstructured. Mixture of the two proteins leads to complex formation and an increase in secondary structure, especially alpha‐helical content. Moreover, transmission electron‐microscopy reveals that Rz–Rz1 complexes form large rod‐shaped structures which, although heterogeneous, exhibit periodicities that may reflect coiled‐coil bundling as well as a long dimension that matches the width of the periplasm. A model is proposed suggesting that the formation of such bundles depends on the removal of the PG and underlies the Rz–Rz1 dependent disruption of the OM.     

The final step in the phage infection cycle: the Rz and Rz1 lysis proteins link the inner and outer membranes

Bacteriophage lambda has four adjacent genes -S, R, Rz and Rz1- dedicated to host cell lysis. While S, encoding the holin and antiholin, and R, encoding the endolysin, have been intensively studied, the products of Rz and Rz1 have not been characterized at either the structural or functional levels. Rz1 is an outer membrane lipoprotein and our results indicate that Rz is a type II signal anchor protein. Here we present evidence that an Rz-Rz1 complex that spans the periplasm carries out the final step in the process of host lysis. These results are discussed in terms of a model where endolysin-mediated degradation of the cell wall is a prerequisite for conformational changes in the Rz-Rz1 complex leading to the juxtaposition and fusion of the IM and OM. Fusion of the two membranes removes the last physical barrier to efficient release of progeny virions.     

Mycobacteriophage endolysins: diverse and modular enzymes with multiple catalytic activities

The mycobacterial cell wall presents significant challenges to mycobacteriophages--viruses that infect mycobacterial hosts--because of its unusual structure containing a mycolic acid-rich mycobacterial outer membrane attached to an arabinogalactan layer that is in turn linked to the peptidoglycan. Although little is known about how mycobacteriophages circumvent these barriers during the process of infection, destroying it for lysis at the end of their lytic cycles requires an unusual set of functions. These include Lysin B proteins that cleave the linkage of mycolic acids to the arabinogalactan layer, chaperones required for endolysin delivery to peptidoglycan, holins that regulate lysis timing, and the endolysins (Lysin As) that hydrolyze peptidoglycan. Because mycobacterial peptidoglycan contains atypical features including 3→3 interpeptide linkages, it is not surprising that the mycobacteriophage endolysins also have non-canonical features. We present here a bioinformatic dissection of these lysins and show that they are highly diverse and extensively modular, with an impressive number of domain organizations. Most contain three domains with a novel N-terminal predicted peptidase, a centrally located amidase, muramidase, or transglycosylase, and a C-terminal putative cell wall binding domain.     

Studies on the deoxyribonucleic acid-bearing portion of the cell envelope of Escherichia coli.

The envelope components of nuclear bodies which were obtained from Escherichia coli W7 by a mild lysis method were investigated. By using 2,6-diaminopimelic acid (DAP) as precursor which is incorporated only into peptidoglycan in this strain it was found that the particles contained about 14% of the murein layer of the cell. The percentage of phosphatidylethanolamine was enriched at the cost of the other phospholipids in the nuclear bodies compared to whole cells. If lipids were labelled with 3H-palmitic acid the cytoplasmic and the outer membrane could be found after isopycnic centrifugation; however, when the cells were incubated with chloramphenicol, only the outer membrane was seen. The peptidoglycan and the proteins could be assigned only to the outer membrane. The DNA is also bound to the outer membrane. From these results it was concluded that (1) in all lysis methods the cytoplasmic membrane is more easily dissolved than the outer layers of the envelope, and (2) that there is a firm binding between DNA and the outer membrane in vivo.     

The influence of cationic dendrimers on antibacterial activity of phage endolysin against P. aeruginosa cells

Nowadays, the researchers make a big effort to find new alternatives to overcome bacterial drug resistance. One option is the application of bacteriophage endolysins enable to degrade peptidoglycan (PG) what in consequence leads to bacterial cell lysis. In this study we examine phage KP27 endolysin mixed with poly(propyleneimine) dendrimers to evaluate an antimicrobial effect against Pseudomonas aeruginosa. Polycationic compounds destabilize bacterial outer membrane (OM) helping endolysins to gain access to PG. We found out that not only bacterial lipopolysaccharide (LPS) is the main hindrance for highly charged cationic dendrimers to disrupt OM and make endolysin reaching the target but also the dendrimer surface modification. The reduction of a positive charge and concentration in maltose poly(propyleneimine) dendrimers significantly increased an antibacterial effect of endolysin. The application of recombinant lysins against Gram-negative bacteria is one of the future therapy options, thus OM permeabilizers such as cationic dendrimers may be of high interest to be combined with PG-degrading enzymes.     

The Lysis System of the <Emphasis Type="Italic">Streptomyces aureofaciens</Emphasis> Phage μ1/6

Previously, two genes, designated as lyt and hol, were identified in the lysis module of phage μ1/6. They were cloned and expressed in Escherichia coli. An additional candidate holin gene, hol2, was found downstream from the hol gene based on one predicted transmembrane domain and a highly charged C-terminal sequence of the encoded protein. Expression of hol or hol2 in E. coli was shown to cause cell death. The concomitant expression of λ endolysin (R) and μ1/6 holin resulted in cell lysis. Similarly, the coexpression of the endolysin and holin of phage μ1/6 led to lysis, apparently due to the ability of μ1/6 endolysin to hydrolyze the peptidoglycan layer of this bacterium. In contrast, the simultaneous expression of μ1/6 hol2 and the endolysin gene (λR or μ1/6 lyt) did not cause detectable lysis of the host cells. Demonstration of the holin function in streptomycetes was achieved by providing for the release of μ1/6 endolysin to the periplasm and subsequent cleavage of the peptidoglycan, which strongly suggested that the holin produces lesions in the streptomycete membrane.     

Effect of the lambda S gene product on properties of the Escherichia coli inner membrane

The S gene of bacteriophage lambda is a late gene required for cell lysis, but unlike the other two lysis genes, R and Rz, it does not code for an endolysin. Earlier studies have shown that the S gene product inhibits respiration and macromolecular synthesis and makes the inner membrane permeable to sucrose. In this study, the effect of the S gene product on a number of Escherichia coli membrane functions (active transport, permeability, respiration, and transhydrogenase and ATPase activity) were measured, and a product of the lambda S gene was identified in the inner membrane fraction by two-dimensional polyacrylamide gel electrophoresis. The results of these experiments indicate that the lambda S product is present in the inner membrane, that it increased the permeability of the membrane for all of the small molecules that were tested, and that its action is reversible. The simplest explanation of these results is that the S gene product forms a hydrophilic pore through the inner membrane, allowing small molecules and lambda lysozyme to pass through.     

Export of the pneumococcal phage SV1 lysin requires choline‐containing teichoic acids and is holin‐independent

Streptococcus pneumoniae bacteriophages (phages) rely on a holin–lysin system to accomplish host lysis. Due to the lack of lysin export signals, it is assumed that holin disruption of the cytoplasmic membrane allows endolysin access to the peptidoglycan. We investigated the lysis mechanism of pneumococcal phage SV1, by using lysogens without holin activity. Upon phage induction in a holin deficient background, phage lysin was gradually targeted to the cell wall, in spite of lacking any obvious signal sequence. Our data indicate that export of the phage lysin requires the presence of choline in the teichoic acids, an unusual characteristic of pneumococci. At the bacterial surface, the exolysin remains bound to choline residues without inducing lysis, but is readily activated by the collapse of the membrane potential. Additionally, the activation of the major autolysin LytA, which also participates in phage‐mediated lysis, is equally related to perturbations of the membrane proton motive force. These results indicate that collapse of the membrane potential by holins is sufficient to trigger bacterial lysis. We found that the lysin of phage SV1 reaches the peptidoglycan through a novel holin‐independent pathway and propose that the same mechanism could be used by other pneumococcal phages.     

Structure of bacteriophage SPN1S endolysin reveals an unusual two‐module fold for the peptidoglycan lytic and binding activity

Bacteriophage SPN1S infects the pathogenic Gram‐negative bacterium Salmonella typhimurium and expresses endolysin for the release of phage progeny by degrading peptidoglycan of the host cell walls. Bacteriophage SPN1S endolysin exhibits high glycosidase activity against peptidoglycans, resulting in antimicrobial activity against a broad range of outer membrane‐permeabilized Gram‐negative bacteria. Here, we report a crystal structure of SPN1S endolysin, indicating that unlike most endolysins from Gram‐negative bacteria background, the α‐helical protein consists of two modular domains, a large and a small domain, with a concave groove between them. Comparison with other structurally homologous glycoside hydrolases indicated a possible peptidoglycan binding site in the groove, and the presence of a catalytic dyad in the vicinity of the groove, one residue in a large domain and the other in a junction between the two domains. The catalytic dyad was further validated by antimicrobial activity assay against outer membrane‐permeabilized Escherichia coli. The three‐helix bundle in the small domain containing a novel class of sequence motif exhibited binding affinity against outer membrane‐permeabilized E. coli and was therefore proposed as the peptidoglycan‐binding domain. These structural and functional features suggest that endolysin from a Gram‐negative bacterial background has peptidoglycan‐binding activity and performs glycoside hydrolase activity through the catalytic dyad.     

The Holin protein of bacteriophage PRD1 forms a pore for small-molecule and endolysin translocation

PRD1 is a bacteriophage with an icosahedral outer protein layer surrounding the viral membrane, which encloses the linear double-stranded DNA genome. PRD1 infects gram-negative cells harboring a conjugative IncP plasmid. Here we studied the lytic functions of PRD1. Using infected cells and plasmid-borne lysis genes, we demonstrated that a two-component lysis system (holin-endolysin) operates to release progeny phage particles from the host cell. Monitoring of ion fluxes and the ATP content of the infected cells allowed us to build a model of the sequence of lysis-related physiological changes. A decrease in the intracellular level of ATP is the earliest indicator of cell lysis, followed by the leakage of K+ from the cytosol approximately 20 min prior to the decrease in culture turbidity. However, the K+ efflux does not immediately lead to the depolarization of the cytoplasmic membrane or leakage of the intracellular ATP. These effects are observed only approximately 5 to 10 min prior to cell lysis. Similar results were obtained using cells expressing the holin and endolysin genes from plasmids.     

Lysis Inhibition in Escherichia coli Infected with Bacteriophage T4

A technique of continuous filtration of T4-infected Escherichia coli has been devised to study the phenomenon of lysis inhibition. Studies using this technique revealed that the length of the lysis delay caused by superinfection can attain only certain discrete values, which for low average multiplicity of superinfection is thought to be a reflection of the actual number of superinfecting particles per cell. The time interval between primary and superinfection had little effect on the length of lysis delay. With increasing rate of superinfection, the length of lysis delay decreased. In superinfected cells, the concentration of endolysin exceeded the final concentration in nonsuperinfected cells. Superinfection of a lysing culture induced lysis inhibition immediately. Temperature-shift experiments, with cells primarily infected by a temperature-sensitive endolysin mutant, revealed that after the normal latent period superinfection was unable to induce lysis inhibition. Amber-restrictive cells, which were primarily infected by an endolysin negative amber mutant, released adenosine triphosphate (ATP) at the end of the normal latent period although lysis did not occur. Superinfection reduced the loss of ATP markedly. The hypothetical role of the cytoplasmic membrane in lysis inhibition is discussed.     

Two beginnings for a single purpose: the dual-start holins in the regulation of phage lysis

For most large phages of both Gram-positive and Gram-negative bacteria, there appears to be a single pathway for achieving disruption of the host envelope, requiring at least two phage-encoded lysis functions (a holin and an endolysin). The holin is a small membrane protein which causes a non-specific lesion in the cytoplasmic membrane, which allows the endolysin to gain access to its substrate, the peptidoglycan. The scheduling of host lysis is effected by regulatory mechanisms which govern the synthesis and activity of the holin protein accumulating in the membrane. Accordingly, aspects of expression and function of holin genes are considered here, focusing mainly on the lambdoid S genes. This group of genes, of which lambda S is the prototype, are characterized by a dual-start motif consisting of two Met start codons separated by one or two codons, at least one of which specifies Arg or Lys. Two protein products are elaborated, differing only by two or three N-terminal residues but apparently possessing opposing functions: the shorter polypeptide is the active holin, or lysis-effector, whereas the longer polypeptide apparently acts as an inhibitor of holin function. Models will be considered which may account for the ability of the holin to form a 'hole' in the cytoplasmic membrane at a programmed time, as well as for the inhibitory properties of the longer product. Finally, we discuss recent results suggesting that the dual-start motif can be viewed as a level of regulation superimposed on a timing function intrinsic to the canonical holin structure.     

Minicell formation by Campylobacter jejuni

Campylobacter jejuni sheds its flagella and varying proportions of the poles of the cell late in the growth cycle, resulting in the production of very small flagellated structures 0.1 to 0.3 microM in diameter. Electron microscopy revealed that these structures were minicells possessing outer membrane, cytoplasmic membrane, flagellar basal complex, and polar membrane; nucleoplasms were not seen. The initial event in the formation of these minicells involved a constriction of the cytoplasmic membrane, segregating the polar regions of the cell. The peptidoglycan layer of the cell wall was not visible, but was presumed to lyse at the separation site of minicell formation, and to reform or remain intact along the main length of the cell because the rods did not spheroplast. Finally, rupture and resealing of the outer membrane component of the wall resulted in the release of fully enclosed minicells and nonflagellated rods.     

Sizing the holin lesion with an endolysin-beta-galactosidase fusion

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 lambda 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 beta-galactosidase (beta-Gal) was tested for lytic competence in the context of the late-gene expression system of an induced lambda lysogen. Under these conditions, the hybrid R-beta-Gal product, an active tetrameric beta-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-beta-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.     

Spanin function requires subunit homodimerization through intermolecular disulfide bonds

The λ Rz and Rz1 proteins are the subunits of the spanin complex, required for the disruption of the outer membrane during host lysis. Rz, the inner membrane or i‐spanin, has a largely alpha‐helical periplasmic domain, whereas Rz1, the outer membrane or o‐spanin, has a 25% proline content with no predicted secondary structure. We report that both Rz and Rz1 accumulate as homodimers covalently linked by intermolecular disulfide bonds involving all three Cys residues, two in Rz and one in Rz1. Moreover, of these three intermolecular disulfides, spanin function requires the presence of at least one of the two linkages nearest the Rz–Rz1 C‐terminal interaction domains; i.e. either the Rz1–Rz1 disulfide or the distal Rz–Rz disulfide link. In a dsbC host, but not in dsbA or dsbA dsbC hosts, formation of the covalent homodimers of Rz is severely reduced and outer membrane disruption is significantly delayed, suggesting that the spanin pathway normally proceeds through DsbA‐mediated formation of an intramolecular disulfide in Rz. In contrast, efficient formation of the Rz1–Rz1 disulfide requires DsbA. Finally, Dsb‐independent formation of the covalent homodimer of either subunit requires the presence of the other, presumably as a template for close apposition of the thiols.     

A second endolysin gene is fully embedded in-frame with the lysA gene of mycobacteriophage Ms6

Mycobacteriophages are dsDNA viruses that infect mycobacterial hosts. The mycobacteriophage Ms6 accomplishes lysis by producing two cell wall hydrolytic enzymes, Lysin A (LysA) that possesses a central peptidoglycan recognition protein (PGRP) super-family conserved domain with the amidase catalytic site, that cleaves the amide bond between the N-acetylmuramic acid and L-alanine residues in the oligopeptide crosslinking chains of the peptidoglycan and Lysin B (LysB) a mycolylarabinogalactan esterase that hydrolyzes the mycolic acids from the mycolyl-arabinogalactan-peptidoglycan complex. Examination of the endolysin (lysA) DNA sequence revealed the existence of an embedded gene (lysA(241)) encoded in the same reading frame and preceded by a consensus ribosome-binding site. In the present work we show that, even though lysA is essential for Ms6 viability, phage mutants that express only the longer (Lysin(384)) or the shorter (Lysin(241)) endolysin are viable, but defective in the normal timing, progression and completion of host cell lysis. In addition, both endolysins have peptidoglycan hydrolase activity and demonstrated broad growth inhibition activity against various gram-positive bacteria and mycobacteria.     

Mycobacteriophage Lysin B is a novel mycolylarabinogalactan esterase

Mycobacteriophages encounter a unique problem among phages of Gram-positive bacteria, in that lysis must not only degrade the peptidoglycan layer but also circumvent a mycolic acid-rich outer membrane covalently attached to the arabinogalactan–peptidoglycan complex. Mycobacteriophages accomplish this by producing two lysis enzymes, Lysin A (LysA) that hydrolyses peptidoglycan, and Lysin B (LysB), a novel mycolylarabinogalactan esterase, that cleaves the mycolylarabinogalactan bond to release free mycolic acids. The D29 LysB structure shows an α/β hydrolase organization with a catalytic triad common to cutinases, but which contains an additional four-helix domain implicated in the binding of lipid substrates. Whereas LysA is essential for mycobacterial lysis, a Giles Δ lysB mutant mycobacteriophage is viable, but defective in the normal timing, progression and completion of host cell lysis. We propose that LysB facilitates lysis by compromising the integrity of the mycobacterial outer membrane linkage to the arabinogalactan–peptidoglycan layer.