The holin of bacteriophage lambda forms rings with large diameter

Holins control the length of the infection cycle of tailed phages (the Caudovirales) by oligomerizing to form lethal holes in the cytoplasmic membrane at a time dictated by their primary structure. Nothing is currently known about the physical basis of their oligomerization or the structure of the oligomers formed by any known holin. Here we use electron microscopy and single-particle analysis to characterize structures formed by the bacteriophage λ holin (S105) in vitro . In non-ionic or mild zwitterionic detergents, purified S105, but not the lysis-defective variant S105_A52V, forms rings of at least two size classes, the most common having inner and outer diameters of 8.5 and 23 nm respectively, and containing approximately 72 S105 monomers. The height of these rings, 4 nm, closely matches the thickness of the lipid bilayer. The central channel is of unprecedented size for channels formed by integral membrane proteins, consistent with the non-specific nature of holin-mediated membrane permeabilization. S105 present in detergent-solubilized rings and in inverted membrane vesicles showed similar sensitivities to proteolysis and cysteine-specific modification, suggesting that the rings are representative of the lethal holes formed by S105 to terminate the infection cycle and initiate lysis.     

Dimerization between the holin and holin inhibitor of phage lambda

Holins are integral membrane proteins that control the access of phage-encoded muralytic enzymes, or endolysins, to the cell wall by the sudden formation of an uncharacterized homo-oligomeric lesion, or hole, in the membrane, at a precisely defined time. The timing of lambda-infected cell lysis depends solely on the 107 codon S gene, which encodes two proteins, S105 and S107, which are the holin and holin inhibitor, respectively. Here we report the results of biochemical and genetic studies on the interaction between the holin and the holin inhibitor. A unique cysteine at position 51, in the middle of the second transmembrane domain, is shown to cause the formation of disulfide-linked dimers during detergent membrane extraction. Forced oxidation of membranes containing S molecules also results in the formation of covalently linked dimers. This technique is used to demonstrate efficient dimeric interactions between S105 and S107. These results, coupled with the previous finding that the timing of lysis depends on the excess of the amount of S105 over S107, suggest a model in which the inhibitor functions by titrating out the effector in a stoichiometric fashion. This provides a basis for understanding two evolutionary advantages provided by the inhibitor system, in which the production of the inhibitor not only causes a delay in the timing of lysis, allowing the assembly of more virions, but also increases effective hole formation after triggering.     

Genetic and biochemical analysis of dimer and oligomer interactions of the lambda S holin

Bacteriophage lambda uses a holin-endolysin system for host cell lysis. R, the endolysin, has muralytic activity. S, the holin, is a small membrane protein that permeabilizes the inner membrane at a precisely scheduled time after infection and allows the endolysin access to its substrate, resulting in host cell lysis. lambda S has a single cysteine at position 51 that can be replaced by a serine without loss of the holin function. A collection of 27 single-cysteine products of alleles created from lambda S(C51S) were tested for holin function. Most of the single-cysteine variants retained the ability to support lysis. Mutations with the most defective phenotype clustered in the first two hydrophobic transmembrane domains. Several lines of evidence indicate that S forms an oligomeric structure in the inner membrane. Here we show that oligomerization does not depend on disulfide bridge formation, since the cysteineless S(C51S) (i) is functional as a holin and (ii) shows the same oligomerization pattern as the parental S protein. In contrast, the lysis-defective S(A52V) mutant dimerizes but does not form cross-linkable oligomers. Again, dimerization does not depend on the natural cysteine, since the cysteineless lysis-defective S(A52V/C51S) is found in dimers after treatment of the membrane with a cross-linking agent. Furthermore, under oxidative conditions, dimerization via the natural cysteine is very efficient for S(A52V). Both S(A52V) (dominant negative) and S(A48V) (antidominant) interact with the parental S protein, as judged by oxidative disulfide bridge formation. Thus, productive and unproductive heterodimer formation between the parental protein and the mutants S(A52V) and S(A48V), respectively, may account for the dominant and antidominant lysis phenotypes. Examination of oxidative dimer formation between S variants with single cysteines in the hydrophobic core of the second membrane-spanning domain revealed that positions 48 and 51 are on a dimer interface. These results are discussed in terms of a three-step model leading to S-dependent hole formation in the inner membrane.     

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.     

Lysogenization by bacteriophage lambda

Summary An easy and sensitive way of measuring the proportion of E. coli cells which are lysogenized by lambda phage or lambda mutants has been devised. With this assay it was possible to analyse the lysogenic response as a function of the average phage input per cell. The results indicate that lysogenization of exponentially growing cells requires that the cells are infected by at least two phages able to replicate, or three or four phages unable to replicate.     

Solubilization and delivery by GroEL of megadalton complexes of the lambda holin

GroEL can solubilize membrane proteins by binding them in its hydrophobic cavity when detergent is removed by dialysis. The best-studied example is bacteriorhodopsin, which can bind in the GroEL chaperonin at two molecules per tetradecamer. Applying this approach to the holin and antiholin proteins of phage lambda, we find that both proteins are solubilized by GroEL, in an ATP-sensitive mode, but to vastly different extents. The antiholin product, S107, saturates the chaperonin at six molecules per tetradecameric complex, whereas the holin, S105, which is missing the two N-terminal residues of S107, forms a hyper-solubilization complex with up to 350 holin molecules per GroEL, or approximately 4 MDa of protein per 0.8 MDa tetradecamer. Gel filtration chromatography and immunoprecipitation experiments confirmed the existence of complexes of the predicted masses for both S105 and S107 solubilization. For S105, negatively stained electron microscopic images show structures consistent with protein shells of the holin assembled around the chaperonin tetradecamer. Importantly, S105 can be delivered rapidly and efficiently to artificial liposomes from these complexes. In these delivery experiments, the holin exhibits efficient membrane-permeabilizing activity. The S107 antiholin can block formation of the hypersolubilization complexes, suggesting that their formation is related to an oligomerization step intrinsic to holin function.     

Lethal action of bacteriophage lambda S gene.

The functions of the bacteriophage lambda lysis genes S, R, and Rz were investigated. Different combinations of wild-type and inactive alleles of all three lysis genes were cloned into the plasmid pBH20 and were expressed under the control of a lac operator-promoter. The involvement of the Rz gene in lysis was proposed in our previous work and was confirmed by the Mg2+-dependent lysis defect of clones in which part of the Rz gene is deleted. Membrane vesicles prepared from induced S+ cells were shown to have a severely reduced capacity for active transport of glucose; this defect was detectable at least 20 min before lysis. Cell viability was also shown to decrease very soon after induction, long before physiological death and lysis; this decrease in viability is absolutely dependent on S expression and independent of R and Rz. The nonviable fraction of cells at any time after induction was demonstrated to be equal to the fraction committed to eventual lysis. Induction of an Sts clone showed that the S gene product is stable and capable of inducing lysis long after the cessation of synthesis of S gene product. A model for S action is proposed.     

Mutational analysis of bacteriophage lambda lysis gene S

A plasmid carrying the bacteriophage lambda lysis genes under lac control was subjected to hydroxylamine mutagenesis, and mutations eliminating the host lethality of the S gene were selected. DNA sequence analysis revealed 48 single-base mutations which resulted in alterations within the coding sequence of the S gene. Thirty-three different missense alleles were generated. Most of the missense changes clustered in the first two-thirds of the molecule from the N terminus. A simple model for the disposition of the S protein within the inner membrane can be derived from inspection of the primary sequence. In the first 60 residues, there are two distinct stretches of predominantly hydrophobic amino acids, each region having a net neutral charge and extending for at least 20 residues. These regions resemble canonical membrane-spanning domains. In the model, the two domains span the bilayer as a pair of net neutral charge helices, and the N-terminal 10 to 12 residues extend into the periplasm. The mutational pattern is largely consistent with the model. Charge changes within the putative imbedded regions render the protein nonfunctional. Loss of glycine residues at crucial reverse-turn domains which would be required to reorient the molecule to reenter the membrane also inactivate the molecule. Finally, a number of neutral and rather subtle mutations such as Ala to Val and Met to Ile are found, mostly within the putative spanning regions. Although no obvious explanation exists for this subtle and heterogeneous class of mutations, it is noted that all of the changes result in a loss of alpha-helical character as predicted by Chou-Fasman theoretical analysis. Alternative explanations for some of these changes are also possible, including a reduction in net translation rate due to substitution of a rare codon for a common one. The model and the pattern of mutations have implications for the probable oligomerization of the S protein at the time of endolysin release at the end of the vegetative growth period.     

A second function of the S gene of bacteriophage lambda

Infection of Escherichia coli by bacteriophage lambda caused an immediate inhibition of uptake by members of all three classes of E. coli active transport systems and made the inner membrane permeable to sucrose and glycine; however, infection stimulated alpha-methyl glucoside uptake. Phage infection caused a dramatic drop in the ATP pool of the cell, but the membrane did not become permeable to nucleotides. Infection by only one phage per cell was sufficient to cause transport inhibition. However, adsorption of phage to the lambda receptor did not cause transport inhibition; DNA injection was required. The inhibition of transport caused by lambda phage infection was transient, and by 20 min after infection, transport had returned to its initial level. The recovery of transport activity appeared to require a lambda structural protein with a molecular weight of 5,500. This protein was present in wild-type phage and at a reduced level in S7 mutant phage but was missing in S2 and S4 mutant phage. Cells infected with S7 phage had a partial recovery of active transport, whereas cells infected with S2 or S4 phage did not recover active transport. Neither the inhibition of transport caused by phage infection nor its recovery were affected by the protein synthesis inhibitors chloramphenicol and rifampin.     

Biochemical and genetic evidence for three transmembrane domains in the class I holin, lambda S

lambda S, the prototype class I holin gene, encodes three potential transmembrane domains in its 107 codons, whereas 21 S, the class II prototype spans only 71 codons and encodes two transmembrane domains. Many holin genes, including lambda S and 21 S, have the "dual-start" regulatory motif at the N terminus, suggesting that class I and II holins have the same topology. The primary structure of 21 S strongly suggests a bitopic "helical-hairpin" topology, with N and C termini on the cytoplasmic side of the membrane. However, lambda S chimeras with an N-terminal signal sequence show Lep-dependent function, indicating that the N-terminal domain of S requires export. Here the signal sequence chimera is shown to be sensitive to the missense change A52V, which blocks normal S function. Moreover, cysteine-modification studies in isolated membranes using a collection of S variants with single-cysteine substitutions show that the positions in the core of the 3 putative transmembrane domains of lambda S are protected. Also, S proteins with single-cysteine substitutions in the predicted cytoplasmic and periplasmic loops are more efficiently labeled in inverted membrane vesicles and whole cells, respectively. These data constitute direct evidence that the holin S(lambda) has three transmembrane domains and indicate that class I and class II holins have different topologies, despite regulatory and functional homology.     

Transduction of bacteriophage lambda by bacteriophage T1.

When bacteriophage T1 was grown on bacteriophage lambda-lysogenic cells, phenotypically mixed particles were formed which had the serum sensitivity, host range, and density of T1 but which gave rise to lambda phage. T1 packaged lambda genomes more efficiently both when the length of the prophage was less than that of wild-type lambda and when the host cell was polylysogenic. Expression of the red genes of lambda or the recE system of Escherichia coli during T1 growth enhanced pickup of lambda by T1, whereas packaging was reduced in recB cells. If donors were singly lysogenic, the expression of transduced lambda genomes as a PFU required lambda-specified excisive recombination, whereas lambda genomes transduced from polylysogens required only lambda- or E. coli-specified general recombination to give a productive infection.     

On inactivation of bacteriophage lambda by hydroxylamine

Hydroxylamine is a mutagen which is much more active on single-stranded DNA than on double-stranded DNA. It is shown here that the cohesive ends of lambda DNA, with 10 cytidine residues, constitute a hydroxylamine target roughly equal in magnitude to the entire duplex part of the molecule, which contains ca. 25 000 cytidine residues.     

λ噬菌体穿孔素(holin) 蛋白触发裂菌的分子机制

穿孔素-裂解酶二元裂解系统是双链DNA噬菌体普遍采用的裂菌模式,以λ噬菌体为例,系统地揭示了噬菌体穿孔素的结构与功能。λ噬菌体的S基因的特征是呈双起始基序(dual-start motif),编码穿孔素(holin)S105和抗穿孔素(antiholin)S107,通过二者不同水平的表达及相互作用,触发裂菌过程。作者综述了λ噬菌体穿孔素的膜拓扑结构和成孔机制的最新研究进展,并展望了穿孔素的研究热点和应用前景。     

Control of bacteriophage lambda CII activity by bacteriophage and host functions

We have studied the regulation of the lambda cII gene in vivo using cloned lambda fragments. Lambda N protein stimulated cII expression. Surprisingly, although very high cII protein levels were detected by gel electrophoresis, little cII protein activity, measured as stimulation of the lambda pI and pE promoters, was observed. The half-life of cII protein depended critically on its initial level. At low concentrations its half-life was as short as 1.5 min, whereas at high cII protein levels, it could be as long as 22 min. The Escherichia coli mutant ER437 directs lambda towards lysogeny; cII protein was more stable in this strain than in the wild type. On the other hand, although cyclic AMP is required for efficient lysogeny, it did not appear to influence the synthesis, stability, or activity of cII protein.     

Topological and phylogenetic analyses of bacterial holin families and superfamilies

Holins are small “hole-forming” transmembrane proteins that mediate bacterial cell lysis during programmed cell death or following phage infection. We have identified fifty two families of established or putative holins and have included representative members of these proteins in the Transporter Classification Database (TCDB; www.tcdb.org). We have identified the organismal sources of members of these families, calculated their average protein sizes, estimated their topologies and determined their relative family sizes. Topological analyses suggest that these proteins can have 1, 2, 3 or 4 transmembrane α-helical segments (TMSs), and members of a single family are frequently, but not always, of a single topology. In one case, proteins of a family proved to have either 2 or 4 TMSs, and the latter arose by intragenic duplication of a primordial 2 TMS protein-encoding gene resembling the former. Using established statistical approaches, some of these families have been shown to be related by common descent. Seven superfamilies, including 21 of the 52 recognized families were identified. Conserved motif and Pfam analyses confirmed most superfamily assignments. These results serve to expand upon the scope of channel-forming bacterial holins.     

The C-terminal sequence of the lambda holin constitutes a cytoplasmic regulatory domain

The C-terminal domains of holins are highly hydrophilic and contain clusters of consecutive basic and acidic residues, with the overall net charge predicted to be positive. The C-terminal domain of lambda S was found to be cytoplasmic, as defined by protease accessibility in spheroplasts and inverted membrane vesicles. C-terminal nonsense mutations were constructed in S and found to be lysis proficient, as long as at least one basic residue is retained at the C terminus. In general, the normal intrinsic scheduling of S function is deranged, resulting in early lysis. However, the capacity of each truncated lytic allele for inhibition by the S107 inhibitor product of S is retained. The K97am allele, when incorporated into the phage context, confers a plaque-forming defect because its early lysis significantly reduces the burst size. Finally, a C-terminal frameshift mutation was isolated as a suppressor of the even more severe early lysis defect of the mutant SA52G, which causes lysis at or before the time when the first phage particle is assembled in the cell. This mutation scrambles the C-terminal sequence of S, resulting in a predicted net charge increase of +4, and retards lysis by about 30 min, thus permitting a viable quantity of progeny to accumulate. Thus, the C-terminal domain is not involved in the formation of the lethal membrane lesion nor in the "dual-start" regulation conserved in lambdoid holins. Instead, the C-terminal sequence defines a cytoplasmic regulatory domain which affects the timing of lysis. Comparison of the C-terminal sequences of within holin families suggests that these domains have little or no structure but act as reservoirs of charged residues that interact with the membrane to effect proper lysis timing.     

Recombination of bacteriophage phi X174 by the red function of bacteriophage lambda.

Recombination of bacteriophage phi X174 was effectively promoted when the Red function of lambda was supplied by either co-infection with lambda or induction of lambda lysogens. Mutations in red alpha and red beta genes of lambda abolished recombination nearly completely, whereas a mutation in gam gene reduced it only slightly. The Red-promoted recombination of phi X174 occurred in recA, recB, and polA mutants as well as in wild-type strains of Escherichia coli. It was further stimulated when phi X174 mutants were irradiated with UV light before infection.