Genetic Dissection of T4 Lysis

t is the holin gene for coliphage T4, encoding a 218-amino-acid (aa) protein essential for the inner membrane hole formation that initiates lysis and terminates the phage infection cycle. T is predicted to be an integral membrane protein that adopts an Nⁱⁿ-C^out topology with a single transmembrane domain (TMD). This holin topology is different from those of the well-studied holins S105 (3 TMDs; N^out-Cⁱⁿ) of the coliphage lambda and S68 (2 TMDs; Nⁱⁿ-Cⁱⁿ) of the lambdoid phage 21. Here, we used random mutagenesis to construct a library of lysis-defective alleles of t to discern residues and domains important for holin function and for the inhibition of lysis by the T4 antiholin, RI. The results show that mutations in all 3 topological domains (N-terminal cytoplasmic, TMD, and C-terminal periplasmic) can abrogate holin function. Additionally, several lysis-defective alleles in the C-terminal domain are no longer competent in binding RI. Taken together, these results shed light on the roles of the previously uncharacterized N-terminal and C-terminal domains in lysis and its real-time regulation.     

Functional Analysis of a Class I Holin,P2 Y

Y is the putative holin gene of the paradigm coliphage P2 and encodes a 93-amino-acid protein. Y is predicted to be an integral membrane protein that adopts an N-out C-in membrane topology with 3 transmembrane domains (TMDs) and a highly charged C-terminal cytoplasmic tail. The same features are observed in the canonical class I lambda holin, the S105 protein of phage lambda, which controls lysis by forming holes in the plasma membrane at a programmed time. S105 has been the subject of intensive genetic, cellular, and biochemical analyses. Although Y is not related to S105 in its primary structure, its characterization might prove useful in discerning the essential traits for holin function. Here, we used physiological and genetic approaches to show that Y exhibits the essential holin functional criteria, namely, allele-specific delayed-onset lethality and sensitivity to the energization of the membrane. Taken together, these results suggest that class I holins share a set of unusual features that are needed for their remarkable ability to program the end of the phage infection cycle with precise timing. However, Y holin function requires the integrity of its short cytoplasmic C-terminal domain, unlike for S105. Finally, instead of encoding a second translational product of Y as an antiholin, as shown for lambda S107, the P2 lysis cassette encodes another predicted membrane protein, LysA, which is shown here to have a Y-specific antiholin character.     

Bacteriophage lysis: mechanism and regulation.

Bacteriophage lysis involves at least two fundamentally different strategies. Most phages elaborate at least two proteins, one of which is a murein hydrolase, or lysin, and the other is a membrane protein, which is given the designation holin in this review. The function of the holin is to create a lesion in the cytoplasmic membrane through which the murein hydrolase passes to gain access to the murein layer. This is necessary because phage-encoded lysins never have secretory signal sequences and are thus incapable of unassisted escape from the cytoplasm. The holins, whose prototype is the lambda S protein, share a common organization in terms of the arrangement of charged and hydrophobic residues, and they may all contain at least two transmembrane helical domains. The available evidence suggests that holins oligomerize to form nonspecific holes and that this hole-forming step is the regulated step in phage lysis. The correct scheduling of the lysis event is as much an essential feature of holin function as is the hole formation itself. In the second strategy of lysis, used by the small single-stranded DNA phage phi X174 and the single-stranded RNA phage MS2, no murein hydrolase activity is synthesized. Instead, there is a single species of small membrane protein, unlike the holins in primary structure, which somehow causes disruption of the envelope. These lysis proteins function by activation of cellular autolysins. A host locus is required for the lytic function of the phi X174 lysis gene E.     

Stable micron‐scale holes are a general feature of canonical holins

At a programmed time in phage infection cycles, canonical holins suddenly trigger to cause lethal damage to the cytoplasmic membrane, resulting in the cessation of respiration and the non‐specific release of pre‐folded, fully active endolysins to the periplasm. For the paradigm holin S105 of lambda, triggering is correlated with the formation of micron‐scale membrane holes, visible as interruptions in the bilayer in cryo‐electron microscopic images and tomographic reconstructions. Here we report that the size distribution of the holes is stable for long periods after triggering. Moreover, early triggering caused by an early lysis allele of S105 formed approximately the same number of holes, but the lesions were significantly smaller. In contrast, early triggering prematurely induced by energy poisons resulted in many fewer visible holes, consistent with previous sizing studies. Importantly, the unrelated canonical holins P2 Y and T4 T were found to cause the formation of holes of approximately the same size and number as for lambda. In contrast, no such lesions were visible after triggering of the pinholin S²¹68. These results generalize the hole formation phenomenon for canonical holins. A model is presented suggesting the unprecedentedly large size of these holes is related to the timing mechanism.     

Clocking out: modeling phage-induced lysis of Escherichia coli

Phage lambda lyses the host Escherichia coli at a precisely scheduled time after induction. Lysis timing is determined by the action of phage holins, which are small proteins that induce hole formation in the bacterium's cytoplasmic membrane. We present a two-stage nucleation model of lysis timing, with the nucleation of condensed holin rafts on the inner membrane followed by the nucleation of a hole within those rafts. The nucleation of holin rafts accounts for most of the delay of lysis after induction. Our simulations of this model recover the accurate lysis timing seen experimentally and show that the timing accuracy is optimal. An enhanced holin-holin interaction is needed in our model to recover experimental lysis delays after the application of membrane poison, and such early triggering of lysis is possible only after the inner membrane is supersaturated with holin. Antiholin reduces the delay between membrane depolarization and lysis and leads to an earlier time after which triggered lysis is possible.     

Probing the Structure of the S105 Hole

For most phages, holins control the timing of host lysis. During the morphogenesis period of the infection cycle, canonical holins accumulate harmlessly in the cytoplasmic membrane until they suddenly trigger to form lethal lesions called holes. The holes can be visualized by cryo-electron microscopy and tomography as micrometer-scale interruptions in the membrane. To explore the fine structure of the holes formed by the lambda holin, S105, a cysteine-scanning accessibility study was performed. A collection of S105 alleles encoding holins with a single Cys residue in different positions was developed and characterized for lytic function. Based on the ability of 4-acetamido-4′-((iodoacetyl) amino) stilbene-2,2′-disulfonic acid, disodium salt (IASD), to modify these Cys residues, one face of transmembrane domain 1 (TMD1) and TMD3 was judged to face the lumen of the S105 hole. In both cases, the lumen-accessible face was found to correspond to the more hydrophilic face of the two TMDs. Judging by the efficiency of IASD modification, it was concluded that the bulk of the S105 protein molecules were involved in facing the lumen. These results are consistent with a model in which the perimeters of the S105 holes are lined by the holin molecules present at the time of lysis. Moreover, the findings that TMD1 and TMD3 face the lumen, coupled with previous results showing TMD2-TMD2 contacts in the S105 dimer, support a model in which membrane depolarization drives the transition of S105 from homotypic to heterotypic oligomeric interactions.     

The hydrophilic C-terminal part of the lambda S holin is non-essential for intermolecular interactions

Available evidence indicates that oligomerization of the bacteriophage lambda S holin leads to a non-specific lesion in the cytoplasmic membrane which permits transit of the phage encoded transglycosylase to the periplasm. In an attempt to locate an intermolecular interaction domain in S a chimeric protein comprising the N-terminal 32 aa of phage PhiX174 lysis protein E and the last 75 aa of lambda S has been constructed. We report that the EΦS fusion protein is stable, membrane bound, and inhibits S-mediated lysis in trans. C-terminal truncations of the EΦS fusion protein indicated that the hydrophilic C-terminal end of S (i.e. the last 15 aa) is non-essential for oligomerization.     

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.     

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.     

Genetic analysis of the T4 holin: timing and topology

The t protein of bacteriophage T4 shares with other holins the ability to cause the formation of a lethal membrane lesion which allows the phage endolysin to attack the peptidoglycan. Moreover, T, like other holins, acts in a saltatory manner at a precisely programmed time in the vegetative cycle. Unlike other holins, however, T has the unique ability to postpone its lethal function in response to a secondary infection by a T-even phage during the vegetative cycle. A signal transduction system that responds to the secondary infection is thought to be encoded by some of the numerous r genes, defined by mutations that abolish this lysis-inhibition (LIN) response. The primary structure of T differs from two main structural patterns found in more than 30 orthologous groups of holins. Genetic approaches were taken to probe the t sequence for features involved in membrane localization, functional timing and LIN regulation. Gene fusion analysis indicates that T has a single TMD near the N-terminus, with the bulk of the protein residing in the periplasm. Mapping and phenotypic analysis of deletion and point mutations in t indicates that the periplasmic domain of T is the major determinant of the timing mechanism and is involved in the LIN response.     

Purification and Biochemical Characterization of the Lambda Holin

Holins are small phage-encoded cytoplasmic membrane proteins, remarkable for their ability to make membranes permeable in a temporally regulated manner. The purification of S105, the λ holin, and one of the two products of gene S is described. Because the wild-type S105 holin could be only partially purified from membrane extracts by ion-exchange chromatography, an oligohistidine tag was added internally to the S105 sequence for use in immobilized metal affinity chromatography. An acceptable site for the tag was found between residues 94 and 95 in the highly charged C-terminal domain of S. This allele, designated S105H94, had normal lysis timing under physiological expression conditions. The S105H94 protein was overproduced, purified, and characterized by circular dichroism spectroscopy, which revealed approximately 40% alpha-helix conformation, consistent with the presence of two transmembrane helices. The purified protein was then used to achieve release of fluorescent dye loaded in liposomes in vitro, whereas protein from an isogenic construct carrying an S mutation known to abolish hole formation was inactive in this assay. These results suggest that S is a bitopic membrane protein capable of forming aqueous holes in bilayers.     

Functional analysis of the phage T4 holin in a λ context

Phage lambda hybrids were constructed by inserting the t gene of phage T4 in place of the lambda holin gene, S. Induction of the hybrid phage resulted in lysis that was just as abrupt as, but occurred much earlier in the vegetative cycle than, that obtained with lambda, indicating that t is indeed a holin gene. Moreover, it was possible to impose lysis inhibition (LIN) on induction of the hybrid phage, but not of the parental lambda phage, by superinfection with LIN-competent T4. The imposition of the LIN state was found to depend on the allelic state of the rI and t genes of the superinfecting T4 phage, indicating that the LIN-sensitive state of the T holin is transient. Finally, induction of lysogens carrying both holin genes was shown to result in earlier triggering of lysis than with either holin gene alone. This result suggests that the two very dissimilar holins contribute additively to the physiology of the timing mechanism, or, less likely, that they interact to form one mass-action pool. In either case, these results imply a common pathway for holin timing and function.     

Periplasmic domains define holin-antiholin interactions in t4 lysis inhibition

Bacteriophage T4 effects host lysis with a holin, T, and an endolysin, E. T and E accumulate in the membrane and cytoplasm, respectively, throughout the period of late gene expression. At an allele-specific time, T triggers to disrupt the membrane, allowing E to enter the periplasm and attack the peptidoglycan. T triggering can be blocked by secondary infections, leading to the state of lysis inhibition (LIN). LIN requires the T4 antiholin, RI, and is sensitive to the addition of energy poisons. T is unusual among holins in having a large C-terminal periplasmic domain. The rI gene encodes a polypeptide of 97 residues, of which 72 are predicted to be a periplasmic domain. Here, we show that the periplasmic domain of RI is necessary and sufficient to block T-mediated lysis. Moreover, when overexpressed, the periplasmic domain of T (T(CTD)) was found to abolish LIN in T4 infections and to convert wild-type (wt) T4 plaques from small and fuzzy edged to the classic "r" large, sharp-edged plaque morphology. Although RI could be detected in whole cells, attempts to monitor it during subcellular fractionation were unsuccessful, presumably because RI is a highly unstable protein. However, fusing green fluorescence protein (GFP) to the N terminus of RI created a more stable chimera that could be demonstrated to form complexes with wild-type T(CTD) and also with its LIN-defective T75I variant. These results suggest that the function of the unusual periplasmic domain of T is to transduce environmental information for the real-time control of lysis timing.     

Evidence for a holin-like protein gene fully embedded out of frame in the endolysin gene of Staphylococcus aureus bacteriophage 187.

We have cloned, sequenced, and characterized the genes encoding the lytic system of the unique Staphylococcus aureus phage 187. The endolysin gene ply187 encodes a large cell wall-lytic enzyme (71.6 kDa). The catalytic site, responsible for the hydrolysis of staphylococcal peptidoglycan, was mapped to the N-terminal domain of the protein by the expression of defined ply187 domains. This enzymatically active N terminus showed convincing amino acid sequence homology to an N-acetylmuramoyl-L-alanine amidase, whereas the C-terminal part, whose function is unknown, revealed striking relatedness to major staphylococcal autolysins. An additional reading frame was identified entirely embedded out of frame (+1) within the 5' region of ply187 and was shown to encode a small, hydrophobic protein of holin-like function. The hol187 gene features a dual-start motif, possibly enabling the synthesis of two products of different lengths (57 and 55 amino acids, respectively). Overproduction of Hol187 in Escherichia coli resulted in growth retardation, leakiness of the cytoplasmic membrane, and loss of de novo ATP synthesis. Compared to other holins identified to date, Hol187 completely lacks the highly charged C terminus. The secondary structure of the polypeptide is predicted to consist of two small, antiparallel, hydrophobic, transmembrane helices. These are supposed to be essential for integration into the membrane, since site-specific introduction of negatively charged amino acids into the first transmembrane domain (V7D G8D) completely abolished the function of the Hol187 polypeptide. With antibodies raised against a synthetic 18-mer peptide representing a central part of the protein, it was possible to detect Hol187 in the cytoplasmic membrane of phage-infected S. aureus cells. An important indication that the protein actually functions as a holin in vivo was that the gene (but not the V7D G8D mutation) was able to complement a phage lambda Sam mutation in a nonsuppressing E. coli HB101 background. Plaque formation by lambdagt11::hol187 indicated that both phage genes have analogous functions. The data presented here indicate that a putative holin is encoded on a different reading frame within the enzymatically active domain of ply187 and that the holin is synthesized during the late stage of phage infection and found in the cytoplasmic membrane, where it causes membrane lesions which are thought to enable access of Ply187 to the peptidoglycan of phage-infected Staphylococcus cells.     

Export of maltose-binding protein species with altered charge distribution surrounding the signal peptide hydrophobic core in Escherichia coli cells harboring prl suppressor mutations.

It is believed that one or more basic residues at the extreme amino terminus of precursor proteins and the lack of a net positive charge immediately following the signal peptide act as topological determinants that promote the insertion of the signal peptide hydrophobic core into the cytoplasmic membrane of Escherichia coli cells with the correct orientation required to initiate the protein export process. The export efficiency of precursor maltose-binding protein (pre-MBP) was found to decrease progressively as the net charge in the early mature region was increased systematically from 0 to +4. This inhibitory effect could be further exacerbated by reducing the net charge in the signal peptide to below 0. One such MBP species, designated MBP-3/+3 and having a net charge of -3 in the signal peptide and +3 in the early mature region, was totally export defective. Revertants in which MBP-3/+3 export was restored were found to harbor mutations in the prlA (secY) gene, encoding a key component of the E. coli protein export machinery. One such mutation, prlA666, was extensively characterized and shown to be a particularly strong suppressor of a variety of MBP export defects. Export of MBP-3/+3 and other MBP species with charge alterations in the early mature region also was substantially improved in E. coli cells harboring certain other prlA mutations originally selected as extragenic suppressors of signal sequence mutations altering the hydrophobic core of the LamB or MBP signal peptide. In addition, the enzymatic activity of alkaline phosphatase (PhoA) fused to a predicted cytoplasmic domain of an integral membrane protein (UhpT) increased significantly in cells harboring prlA666. These results suggest a role for PrlA/SecY in determining the orientation of signal peptides and possibly other membrane-spanning protein domains in the cytoplasmic membrane.     

To flip or not to flip: lipid-protein charge interactions are a determinant of final membrane protein topology

The molecular details of how lipids influence final topological organization of membrane proteins are not well understood. Here, we present evidence that final topology is influenced by lipid–protein interactions most likely outside of the translocon. The N-terminal half of Escherichia coli lactose permease (LacY) is inverted with respect to the C-terminal half and the membrane bilayer when assembled in mutants lacking phosphatidylethanolamine and containing only negatively charged phospholipids. We demonstrate that inversion is dependent on interactions between the net charge of the cytoplasmic surface of the N-terminal bundle and the negative charge density of the membrane bilayer surface. A transmembrane domain, acting as a molecular hinge between the two halves of the protein, must also exit from the membrane for inversion to occur. Phosphatidylethanolamine dampens the translocation potential of negative residues in favor of the cytoplasmic retention potential of positive residues, thus explaining the dominance of positive over negative amino acids as co- or post-translational topological determinants.     

Cytoplasmic phosphorylating domain of the mannitol-specific transport protein of the phosphoenolpyruvate-dependent phosphotransferase system in Escherichia coli: overexpression, purification, and functional complementation with the mannitol binding domain

The cytoplasmic C-terminal domain, residues 348-637, and the membrane-bound N-terminal domain, residues 1-347, of EIImtl have been subcloned and expressed in Escherichia coli. The N-terminal domain, IICmtl, contains the mannitol binding site, and the C-terminal domain, IIBAmtl, contains the activity-linked phosphorylation sites, His-554 and Cys-384. Overexpression of the BA domain was achieved by a translational in-frame fusion of the gene with the cro ATG start codon, downstream of the strong PR promoter of phage lambda. The domain has been purified and characterized in in vitro complementation assays. It possessed no mannitol phosphorylation activity itself but was able to restore the phosphoenolpyruvate-dependent phosphorylation activity of two EIImtl phosphorylation site mutants, lacking His-554 or Cys-384. The complementary N-terminal domain was also expressed. Membranes possessing IICmtl were unable to phosphorylate mannitol at the expense of phosphoenolpyruvate. However, when the membranes were combined with the purified C-terminal domain, mannitol phosphorylation activity was restored. Mannitol transport and phosphorylation were also restored in vivo when the two plasmids encoding the N- and C-terminal domains were expressed in the same cell. These data demonstrate the existence of structurally and functionally distinct domains in EIImtl: a cytoplasmic domain with phosphorylating activity and a membrane-bound N-terminal domain which, in the presence of the cytoplasmic domain, is able to actively transport and phosphorylate mannitol. The ability to separate, overproduce, and purify structurally stable, enzymatically active domains opens the way for 3D structural studies as well as complete kinetic analysis of the activities of the individual domains and their interactions.     

Membrane topology of the H+-pyrophosphatase of Streptomyces coelicolor determined by cysteine-scanning mutagenesis

The H+-translocating pyrophosphatase (H+-PPase) is a proton pump that is found in a wide variety of organisms. It consists of a single polypeptide chain that is thought to possess between 14 and 17 transmembrane domains. To determine the topological arrangement of its conserved motifs and transmembrane domains, we carried out a cysteine-scanning analysis by determining the membrane topology of cysteine substitution mutants of Streptomyces coelicolor H+-PPase expressed in Escherichia coli using chemical reagents. First, we prepared a synthetic DNA that encoded the enzyme and constructed a functional cysteine-less mutant by substituting the four cysteine residues. We then introduced cysteine residues individually into 42 sites in its hydrophilic regions and N- and C-terminal segments. Thirty-six of the mutant enzymes retained both pyrophosphatase and H+-translocating activities. Analysis of 29 of these mutant forms using membrane-permeable and -impermeable sulfhydryl reagents revealed that S. coelicolor H+-PPase contains 17 transmembrane domains and that several conserved segments, such as the substrate-binding domains, are exposed to the cytoplasm. Four essential serine residues that were located on the cytoplasmic side were also identified. A marked characteristic of the S. coelicolor enzyme is a long additional sequence that includes a transmembrane domain at the C terminus. We propose that the basic structure of H+-PPases has 16 transmembrane domains with several large cytoplasmic loops containing functional motifs.     

Mutational analysis of the S21 pinholin

Lambdoid phage 21 has the prototype pinholin‐SAR endolysin lysis system, which is widely distributed among phages. Its prototype pinholin, S²¹68, triggers at an allele‐specific time to form small, heptameric lesions, or pinholes, in the cytoplasmic membrane, thus initiating lysis. S²¹68 has two transmembrane domains, TMD1 and TMD2. Only TMD2 is required for the formation of pinholes, whereas TMD1 acts as an inhibitor of TMD2 and must be externalized to the periplasm in the lytic pathway. Previously we provided evidence that S²¹68 first accumulates as inactive dimers with both transmembrane domains embedded in the bilayer. Here we analyse an extensive collection of S²¹ mutants to identify residues and domains critical to the function and regulation of the pinholin. Evidence is presented indicating that, within the inactive dimer, TMD1 acts in trans as an inhibitor of the lethal function of TMD2. A wide range of phenotypes, from absolute lysis defectives to accelerated lysis triggering, are observed for mutations mapping to each topological domain. The pattern of phenotypes allows the generation of a model for the structure of the inactive dimer. The model identifies the faces of the two transmembrane domains involved in intramolecular and intermolecular interactions, as well as interaction with the lipid.