The adsorption protein of phage IKe. Localization by deletion mutagenesis of domains involved in infectivity

We constructed a set of plasmid-encoded internal deletion mutants within the gene for the adsorption protein (g3p) of phage IKe. All mutant proteins still contain the signal and membrane anchor sequence, as those are known to be indispensable for proper localization and hence assembly of the g3p into phage. These various deletions comprise all internal parts of the protein and are properly incorporated into phage, which remarkably shows that signal and anchor sequence are sufficient for incorporation of g3p. The data furthermore reveal that two separate sections within the IKe g3p are essential for infection: one amino-terminal, preceding the glycine-rich stretch, and the other carboxy-terminal. We conclude that this latter domain is involved in penetration because mutants lacking it are not infectious, but still bind to the receptor. The amino-terminal region, essential for infection, bears the receptor-recognizing domain and a sequence homologous to the penetration domain of the evolutionary related Ff phages, which is probably also involved in penetration of phage IKe. The prominent glycine-rich stretch of the IKe g3p is not essential for infection but significantly promotes it.     

Host range mutants of bacteriophage Ox2 can use two different outer membrane proteins of Escherichia coli K-12 as receptors.

The Escherichia coli K-12 outer membrane protein OmpA functions as the receptor for bacteriophage Ox2. We isolated a host range mutant of this phage which was able to grow on an Ox2-resistant ompA mutant producing an altered OmpA protein. From this mutant, Ox2h5, a second-step host range mutant was recovered which formed turbid plaques on a strain completely lacking the OmpA protein. From one of these mutants, Ox2h10, a third-step host range mutant, Ox2h12, was isolated which formed clear plaques on a strain missing the OmpA protein. Ox2h10 and Ox2h12 apparently were able to use both outer membrane proteins OmpA and OmpC as receptors. Whereas there two proteins are very different with respect to primary structures and functions, the OmpC protein is very closely related to another outer membrane protein, OmpF, which was not recognized by Ox2h10 or Ox2h12. An examination of the OmpC amino acid sequence, in the regions where it differs from that of OmpF, revealed that one region shares considerable homology with a region of the OmpA protein which most likely is required for phage Ox2 receptor activity.     

A 70-kd protein of the yeast mitochondrial outer membrane is targeted and anchored via its extreme amino terminus

The major 70-kd protein of the yeast mitochondrial outer membrane is made on cytosolic ribosomes and imported into the outer membrane without proteolytic cleavage. We have attempted to identify the sequences which target the protein to the mitochondria and which permanently anchor it to the lipid bilayer of the outer membrane. By manipulating the cloned gene we have deleted 13 different regions throughout the polypeptide; in addition, we have fused amino-terminal regions of different length to beta-galactosidase. Each altered gene was introduced into yeast and the intracellular fate of the corresponding polypeptide product was determined by subcellular fractionation. All the information for targeting and anchoring the 70-kd protein (617 amino acids) was contained within the amino-terminal 41 amino acids. When this entire region was deleted, the protein was recovered with the cytosol fraction. However, several restricted deletions within this amino-terminal region appeared to affect targeting and anchoring differentially: most of the altered protein remained in the cytosol but a small fraction was misrouted into the mitochondrial matrix space. We suggest that targeting is mediated by a region which includes the 11 amino-terminal amino acids whereas the permanent membrane anchor is provided by a typical transmembrane sequence between residues 9 and 38.     

DNA sequence of genes 38 encoding a receptor-recognizing protein of bacteriophages T2, K3 and of K3 host range mutants

Genes 38, which code for a receptor-recognizing protein present at the tip of the long tail fibers, have been sequenced from phages T2, the T-even-type phage K3 and its host range mutants K3hx, K3h1 and K3h1h. The genes from phages T2 and K3 code for proteins consisting of 262 and 260 amino acid residues, respectively. Fifty amino-terminal and 25 carboxy-terminal residues are highly conserved. The amino-terminal amino acids are most likely involved in binding to the neighboring protein 37. Between residues 116 and 226 of the T2 protein and residues 116 and 223 of the K3 protein, sequences exist that are similar to sequences present in Escherichia coli outer membrane proteins and which serve as phage receptors. Most likely, all of these regions in the latter proteins are exposed on the cell surface and are part of their phage receptor areas. In the phage proteins, these sequences are flanked by stretches rich in glycine, perhaps providing an increased flexibility for the polypeptide at these sites; some "wobble" may be required during the protein 38-receptor interaction. The mutational alterations in the host range mutants were found in gene 38. In the K3hx protein, a duplication of six base-pairs caused the wild-type sequence -Gly163-Lys-Leu-Ile- to be changed to -Gly163-Lys-Leu-Lys-Leu-Ile-. In the K3h1 protein, a glutamic acid residue at position 203 was substituted by a lysine. Both alterations occurred within areas similar to outer membrane proteins. Mutant K3h1h, derived from K3h1, exhibits an extended host range as compared to K3h1. No mutational alteration, in addition to that found in K3h1, was found in g38 nor was the part of gene 37 that encodes the carboxy-terminal moiety of the protein altered. K3h1h may represent a "trigger-happy" phage. The results of this and other work show that the phage-phage receptor systems under study represent a primitive immune system.     

Bacteriophage receptor area of outer membrane protein OmpA of Escherichia coli K-12.

A number of T-even-like bacteriophages use the outer membrane protein OmpA of Escherichia coli as a receptor. We had previously analyzed a series of ompA mutants which are resistant to such phages and which still produce the OmpA protein (R. Morona, M. Klose, and U. Henning, J. Bacteriol. 159:570-578, 1984). Mutational alterations were found near or at residues 70, 110 and 154. Based on these and other results a model was proposed showing the amino-terminal half of the 325-residue protein crossing the outer membrane repeatedly and being cell surface exposed near residues 25, 70, 110, and 154. We characterized, by DNA sequence analysis, an additional 14 independently isolated phage-resistant ompA mutants which still synthesize the protein. Six of the mutants had alterations identical to the ones described before. The other eight mutants possessed seven new alterations: Ile-24----Asn, Gly-28----Val, deletion of Glu-68, Gly-70----Cys, Ser-108----Phe, Ser-108----Pro, and Gly-154----Asp (two isolates). Only the latter alteration resulted in a conjugation-deficient phenotype. The substitutions at Ile-24 and Gly-28 confirmed the expectation that this area of the protein also participates in its phage receptor region. It is unlikely that still other such sites of the protein are involved in the binding of phage, and it appears that the phage receptor area of the protein has now been characterized completely.     

Analysis of the sorting signals directing NADH-cytochrome b5 reductase to two locations within yeast mitochondria.

Mitochondrial NADH-cytochrome b5 reductase (Mcr1p) is encoded by a single nuclear gene and imported into two different submitochondrial compartments: the outer membrane and the intermembrane space. We now show that the amino-terminal 47 amino acids suffice to target the Mcr1 protein to both destinations. The first 12 residues of this sequence function as a weak matrix-targeting signal; the remaining residues are mostly hydrophobic and serve as an intramitochondrial sorting signal for the outer membrane and the intermembrane space. A double point mutation within the hydrophobic region of the targeting sequence virtually abolishes the ability of the precursor to be inserted into the outer membrane but increases the efficiency of transport into the intermembrane space. Import of Mcr1p into the intermembrane space requires an electrochemical potential across the inner membrane, as well as ATP in the matrix, and is strongly impaired in mitochondria lacking Tom7p or Tim11p, two components of the translocation machineries in the outer and inner mitochondrial membranes, respectively. These results indicate that intramitochondrial sorting of the Mcr1 protein is mediated by specific interactions between the bipartite targeting sequence and components of both mitochondrial translocation systems.     

The receptor specificity of bacteriophages can be determined by a tail fiber modifying protein.

T-Even type bacteriophages recognize their cellular receptors with the distal ends of their long tail fibers. The distal part of these fibers consists of a dimer of gene product (gp) 37. The assembly of this gp to a functional dimer requires the action of two other proteins, gp57 and gp38. Genes (g) 38 have been cloned from five T-even type phages which use the Escherichia coli outer membrane protein OmpA as a receptor. The phages used differ in their ability to infect a series of ompA mutants producing altered OmpA proteins, i.e., each phage has a specific host range for these mutants. The cloned genes 38 complemented g38 amber mutants of phage T2, which uses the outer membrane protein OmpF as a receptor. The complemented phages had become phenotypically OmpA-dependent and, with one exception, OmpF-independent, but regained the host range of T2 upon growth in a host lacking the cloned g38. The host range of the complemented phages, as determined on the ompA mutants, was identical to, similar to, or different from that of the phage, from which the cloned g38 originated. The results presented show that gp38 from one phage can phenotypically 'imprint', in a finely-tuned manner, a host range onto gp37 of another phage with a different host specificity. In view of the extreme diversity of host ranges observed, it is suggested that gp38 of T2 and of the OmpA-specific phages may remain attached to gp37 in the phage particle and in cooperation with gp37 determine the host range.     

Functional Interaction of the tonA/tonB Receptor System in Escherichia coli

Host range mutants of phage T1 (T1h), which productively infected tonB mutants of Escherichia coli, were isolated. The phage mutants were inactivated by isolated outer membranes of E. coli in contrast to the wild-type phage, which only adsorbed reversibly. For the infection process, the tonB function is apparently only required for the irreversible adsorption of the phage T1, but not for the transfer of the phage DNA through the outer membrane and the cytoplasmic membrane of the cell. Mutants of the tonA gene expressing normal amounts of outer membrane receptor proteins were isolated and found to be partially sensitive to phage T5 and resistant to the phages T1 and T1h, colicin M, and albomycin and unable to take up iron as a ferrichrome complex. One tonA mutant remained partially sensitive to T5, colicin M, and albomycin and supported growth of T1h (not of T1) with the same plating efficiency as the parent strain. Only a small region of the tonA receptor protein seems to function for all the very different substrates. A newly isolated host range mutant of T5 (T5h) adsorbed faster to tonA(+) cells than did wild-type T5 and infected tonA missense mutants resistant to wild-type T5. The interplay of the tonA with the tonB function was observed with phage T5 infection, although T5 required only the tonA receptor. Ferrichrome inhibited plaque formation of T5 only when plated on tonB mutants. Adsorption of T5 to cells in liquid medium was influenced by ferrichrome as follows: complete inhibition by 0.1 muM ferrichrome with tonB mutants, not more than 35% inhibition by 1 to 100 muM ferrichrome with the tonB(+) parent strain in the presence of glucose as energy source, and 90% inhibition by 1 muM ferrichrome with partially starved parent cells. We conclude that there exist different functional states of the receptor protein that depend on the energy state of the cell and the tonB function. The latter seems to be required only for translocation processes with outer membrane proteins involved.     

Mutants at conserved positions in gene IV, a gene required for assembly and secretion of filamentous phages

The filamentous phage protein pIV is required for assembly and secretion of the virus and possesses regions homologous to those found in a number of Gram-negative bacterial proteins that are essential components of a widely distributed extracellular protein-export system. These proteins form multimers that may constitute an outer membrane channel that allows phage/protein egress. Three sets of f1 gene IV mutants were isolated at positions that are absolutely (G355 and P375) or largely (F381) conserved amongst the 16 currently known family members. The G355 mutants were non-functional, interfered with assembly of plV⁺ phage, and made Escherichia coli highly sensitive to deoxycholate. The P375 mutants were non-functional and defective in multimerization. Many of the F381 mutants retained substantial function, and even those in which charged residues had been introduced supported some phage assembly. Some inferences about the roles of these conserved amino acids are made from the mutant phenotypes.     

Precise determination of the mitochondrial import signal contained in a 70 kDa protein of yeast mitochondrial outer membrane

A major 70 kDa protein of the yeast mitochondrial outer membrane is coded by a nuclear gene, synthesized on cytoplasmic ribosomes, and transported to the mitochondrial outer membrane. In order to investigate in detail the information necessary for localizing the 70 kDa protein at the outer membrane, we have examined the intracellular and intramitochondrial location of fusion proteins which consist of various lengths of the amino-terminal region of the 70 kDa protein with an enzymatically active beta-galactosidase. The results indicate that the extreme amino-terminal 12 amino acids of the 70 kDa protein function as a targeting sequence, whereas the subsequent uncharged region (up to residue 29) is necessary for "stop-transfer" and "anchoring" functions. Moreover, we have found that a fusion protein which contained the amino-terminal 19 amino acids of the 70 kDa protein is localized on the outer membrane as well as in the matrix space. Changes in the dual localization of this fusion protein accompanied its overproduction or expression in a respiration-deficient yeast mutant.     

A genetic approach for analysing surface-exposed regions of the OmpC protein of Escherichia coli K-12

Phage attachment sites on bacterial cell surfaces are provided by the exposed regions of outer membrane proteins and lipopolysaccharide (LPS). We have identified surface exposed residues of OmpC that are important for phage binding. This was accomplished by employing a genetic scheme in which two simultaneous selections enriched for ompC mutants defective in phage attachment, but retained functional channels. Mutational alterations were clustered in three regions of the OmpC protein. These regions also showed the greatest divergence from the analogous regions of the highly related OmpF and PhoE proteins. The majority of alterations (8 out of 11) occurred in a region of OmpC that is predicted to form a large exterior loop (loop 4). Interestingly, while the removal of this loop prevented phage binding, the deletion conferred enhanced channel activities.   Another type of phage-resistant mutants synthesized defective LPS molecules. Biochemical analysis of mutant LPS revealed it to be of the Re-type LPS, lacking the heptose moieties from the LPS inner core. As a result of this LPS defect, many outer membrane proteins were present in somewhat reduced levels. The phage resistance seen in these mutants could be a result of both the presence of defective LPS and reduced OmpC levels.     

Analysis of the structure and subcellular location of filamentous phage pIV.

The gene IV protein of filamentous bacteriophages is an integral membrane protein required for phage assembly and export. A series of gene IV::phoA fusion, gene IV deletion, and gene IV missense mutations have been isolated and characterized. The alkaline phosphatase activity of the fusion proteins suggests that pIV lacks a cytoplasmic domain. Cell fractionation studies indicate that the carboxy-terminal half of pIV mediates its assembly into the membrane, although there is no single, discrete membrane localization domain. The properties of gene IV missense and deletion mutants, combined with an analysis of the similarities between pIVs from various filamentous phage and related bacterial export-mediating proteins, suggest that the amino-terminal half of pIV consists of a periplasmic substrate-binding domain that confers specificity to the assembly-export system.     

Characterization of a T5-like coliphage, SPC35, and differential development of resistance to SPC35 in Salmonella enterica serovar typhimurium and Escherichia coli

The potential of bacteriophage as an alternative biocontrol agent has recently been revisited due to the widespread occurrence of antibiotic-resistant bacteria. We isolated a virulent bacteriophage, SPC35, that can infect both Salmonella enterica serovar Typhimurium and Escherichia coli. Morphological analysis by transmission electron microscopy and analysis of its 118,351-bp genome revealed that SPC35 is a T5 group phage belonging to the family Siphoviridae. BtuB, the outer membrane protein for vitamin B(12) uptake, was found to be a host receptor for SPC35. Interestingly, resistant mutants of both E. coli and S. Typhimurium developed faster than our expectation when the cultures were infected with SPC35. Investigation of the btuB gene revealed that it was disrupted by the IS2 insertion sequence element in most of the resistant E. coli isolates. In contrast, we could not detect any btuB gene mutations in the resistant S. Typhimurium isolates; these isolates easily regained sensitivity to SPC35 in its absence, suggesting phase-variable phage resistance/sensitivity. These results indicate that a cocktail of phages that target different receptors on the pathogen should be more effective for successful biocontrol.     

New locus (ttr) in Escherichia coli K-12 affecting sensitivity to bacteriophage T2 and growth on oleate as the sole carbon source.

The nature of resistance to phage T2 in Escherichia coli K-12 was investigated by analyzing a known phage T2-resistant mutant and by isolating new T2-resistant mutants. It was found that mutational alterations at two loci, ompF (encoding the outer membrane protein OmpF) and ttr (T-two resistance), are needed to give full resistance to phage T2. A ttr::Tn10 mutation was isolated and was mapped between aroC and dsdA, where the fadL gene (required for long-chain fatty acid transport) is located. The receptor affected by ttr was the major receptor used by phage T2 and was located in the outer membrane. Phage T2 was thus able to use two outer membrane proteins as receptors. All strains having a ttr::Tn10 allele and most of the independently isolated phage T2-resistant mutants were unable to grow on oleate as the sole carbon and energy source, i.e., they had the phenotype of fadL mutants. The gene fadL is known to encode an inner membrane protein. The most likely explanation is that fadL and ttr are in an operon and that ttr encodes an outer membrane protein which functions in translocating long-chain fatty acids across the outer membrane and also as a receptor for phage T2.     

Secretion and membrane integration of a filamentous phage-encoded morphogenetic protein

The filamentous phage-encoded gene IV protein is required at high levels for virus assembly, although it is not a constituent of the virion. It is an integral membrane protein that does not contain an extended hydrophobic region of the kind often required for stable integration in the inner membrane. Rather, like a number of Escherichia coli outer membrane proteins, pIV is rich in charged amino acid residues and is predicted to consist of extensive beta-sheet structures. In phage-producing cells, pIV is primarily detected in the outer membrane, while in cells that produce it from the cloned gene, pIV is found in both the inner and outer membranes. The protein is synthesized as a precursor. Following cleavage of the signal sequence and translocation into the periplasm, the mature form is initially found as a soluble species. Soluble pIV then integrates into the membrane with a half-time of one to two minutes. Neither phage assembly nor other phage proteins are needed for this membrane integration, and phage assembly does not require the presence of the soluble form. The gene IV protein may be part of the structure through which the assembling phage is extruded.     

Effect of Long Generation Times on Growth of Bacteroides thetaiotaomicron in Carbohydrate-Limited Continuous Culture

lamB is the structural gene for the bacteriophage lambda receptor, a multifunctional protein located in the outer membrane of Escherichia coli K-12. We present a method for deletion mapping of any lamB mutations with a recognizable pheno-type. This method involves a transducing phage constructed by in vitro recombination which can also be used for complementation, deoxyribonucleic acid sequence, and in vitro protein synthesis studies with the mutated lamB gene. Using this method, we mapped 18 lamB missense mutations which confer resistance to phage lambda h+ (wild-type host range). The main results were the following. (i) None of the 18 mutations was located in the first 4 deletion intervals out of the 11 of the genetic map. (ii) These mutations were clustered according to their phenotype as follows. (a) Class I mutations, which allow growth of lambda h and lambda hh* (one-step and two-step host range mutants of lambda, respectively), were located in three regions--three in interval V, four in interval VIII-IX, and three in interval X-XI. Only the last three mutations still allowed growth of phage K10 which also uses the lambda receptor, and two of them still allowed reversible binding of lambda h+. (b) All seven class II mutations allowed only growth of lambda hh* and mapped in interval V. These results are discussed in the frame of a genetic approach to the functional topology of the lambda receptor.     

Further sequence analysis of the phage lambda receptor site. Possible implications for the organization of the lamB protein in Escherichia coli K12

We present the DNA sequence alterations due to seven lamB missense mutations yielding resistance to phages lambda and K10. They reveal five different amino acid positions in the LamB protein. Three positions (245, 247 and 249) define a new region required for phage adsorption. The two other positions (148 and 152) belong to a region where mutations to phage resistance has already been detected. These two regions are hydrophilic and could belong to turns of the protein located at the surface of the cell. All the missense mutational alterations to phage resistance sequenced in the LamB protein correspond to 10 sites located in four different segments of the polypeptide chain. We discuss their location in terms of the notion of phage receptor site and of a working model for the organization of this protein in the outer membrane of Escherichia coli.     

Identification of Yersinia enterocolitica genes affecting survival in an animal host using signature-tagged transposon mutagenesis

Pathogenic Yersinia species are associated with both localized and systemic infections in mammalian hosts. In this study, signature-tagged transposon mutagenesis was used to identify Yersinia enterocolitica genes required for survival in a mouse model of infection. Approximately 2000 transposon insertion mutants were screened for attenuation. This led to the identification of 55 mutants defective for survival in the animal host, as judged by their ability to compete with the wild-type strain in mixed infections. A total of 28 mutants had transposon insertions in the virulence plasmid, validating the screen. Two of the plasmid mutants with severe virulence defects had insertions in an uncharacterized region. Several of the chromosomal insertions were in a gene cluster involved in O-antigen biosynthesis. Other chromosomal insertions identified genes not previously demonstrated as being required for in vivo survival of Y. enterocolitica. These include genes involved in the synthesis of outer membrane components, stress response and nutrient acquisition. One severely attenuated mutant had an insertion in a homologue of the pspC gene (phage shock protein C) of Escherichia coli. The phage shock protein operon has no known biochemical or physiological function in E. coli, but is apparently essential for the survival of Y. enterocolitica during infection.     

Comprehensive Mutational Analysis of the Moloney Murine Leukemia Virus Envelope Protein

The envelope (Env) protein of Moloney murine leukemia virus is the primary mediator of viral entry. We constructed a large pool of insertion mutations in the env gene and analyzed the fitness of each mutant in completing two critical steps in the virus life cycle: (i) the expression and delivery of the Env protein to the cell surface during virion assembly and (ii) the infectivity of virions displaying the mutant proteins. The majority of the mutants were poorly expressed at the producer cell surface, suggesting folding defects due to the presence of the inserted residues. The mutants with residual infectivity had insertions either in the amino-terminal signal sequence region, two disulfide-bonded loops in the receptor binding domain, discrete regions of the carboxy-terminal region of the surface subunit (SU), or the cytoplasmic tail. Insertions that allowed the mutants to reach the cell surface but not to mediate detectable infection were located within the amino-terminal sequence of the mature Env, within the SU carboxy-terminal region, near putative receptor binding residues, and throughout the fusion peptide. Independent analysis of select mutants in this group allowed more precise identification of the defect in Env function. Mapping of mutant phenotypes to a structural model of the receptor-binding domain provides insights into the protein's functional organization. The high-resolution functional map reported here will be valuable for the engineering of the Env protein for a variety of uses, including gene therapy.     

Fuctional organization of the outer membrane of escherichia coli: Phage and colicin receptors as components of iron uptake systems

The functional interaction of outer memberane proteins of E. coli can be studied using phage and colicin receptors which are essential components of penetration systems. The uptake of ferric iron in the form of the ferrichrome complex requires the ton A and ton B functions in the outer membrane of E. coli. The ton A gene product is the receptor protein for phage T5 and is required together with the ton B function by the phages T1 anf ?80 to infect cells and by colicin M and the antibiotic albomycin, a structural analogue of ferrichrome, to kill cells. The ton B function is necessary for the uptake of ferric iron complexed by citrate. Iron complexed by enterochelin is only transported in the presence of the ton B and feu functions. Cells which have lost the feu function are resistant to the colicins B, I or V while ton B mutants are resistant to all colicins. The interaction of the ton A, Ton B, and feu functions apparently permits quite different “substrates” to overcome the permeablility barrier of the outer membrane. It was shown for ferrichrome dependent iron uptake that the complexing agent was not altered and could be used repeatedly. Only very low amounts of ³H-labeled ferrichrome were found in the cell. It is possible that the iron is mobilized in the membrane and that desferriferrichrome is released into the medium without having entered the cytoplasm. Growth on ferrichrome as the sole iron source waw used to select revertants of T5 resistant ton A mutants. All revertants exhibited wild-type properties with the exception of partial revertants. In these 4 strains, as in the ton A mutants, the ton A protein was not detectable by SDS polyacrylamide gel electrophoreses of outer membranes. Albomycin resistant mutants were selected and shown to fall into 5 categories: (1) ton A; (2) ton B mutants; (3) mutants with no iron transport defects and normal ton A/ton B functions, which might be target site mutants; (4) mutants which were deficient in ferrichrome-mediated iron uptake but had normal ton A/ton B functions. We tentatively consider that the defect might be located in the active transport system of the cytoplasmic membrane; (5) a variety of mutants with the following general properties: most of them were resistant to colicin M, transported iron poorly, and, like ton B mutants, contained additional proteins in the outer membrane. The outer membrane protein patterns of wild-type and ton B mutant strains were compared by slab gel electrophoresis in an attempt to identify a ton B protein. It was observed that under most growth conditions, ton B mutants overproduced 3 proteins of molecular weights 74,000–83,000. In extracted, iron-deficient medium, both the wild-type and ton B mutant strains had similar large amounts of these proteins in their outer membranes. The appearance of these proteins was suppressed by excess iron in both wild-type and mutant. From this evidence it is apparent that the proteins appear as a response to low intracellular iron rather than being controlled by the ton B gene. The nature of these proteins and their possible role in iron transport is disussed.