Interchangeability of the adsorption proteins of bacteriophages Ff and IKe.

The wild-type adsorption protein (g3p) of filamentous phage IKe cannot be exchanged with its analogous protein in the related Ff (M13, fd, and f1) phage particles. Deletion mutants of the protein, however, are assembled into Ff phage particles. These hybrid Ff phage particles bearing deleted IKe g3p attach to N pili, thus conserving the host attachment property of the protein but not its infection-initiating function. This means that the attachment specificity is determined by IKe g3p independently of other phage components in contact with it. Infection initiation function, the process in which phage DNA is released into the host, in contrast seems to require either more complex structural features of the protein (for example, a certain oligomeric structure) provided only in the original particle, or a concerted action of g3p with another particle component, not replaceable by its homologous counterpart in the related phage.     

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.     

Nucleotide sequence and genetic organization of the genome of the N-specific filamentous bacteriophage IKe. Comparison with the genome of the F-specific filamentous phages M13, fd and f1

The nucleotide sequence and genetic organization of the genome of the N-specific filamentous single-stranded DNA phage IKe has been established and compared with that of the F-specific filamentous phages M13, fd and f1 (Ff). The IKe DNA sequence comprises 6883 nucleotides, which is 476 (475) nucleotides more than the nucleotide sequence of the Ff genome. The data indicate that IKe and Ff have evolved from a common ancestor (overall homology approx. 55%) and that their genomes contain ten homologous genes, the order of which is identical. Similar to Ff, the major coat protein and the gene III-encoded pilot protein of IKe are synthesized via precursor molecules. The extent of homology between the genes of IKe and Ff differs significantly from one gene to another. Genes that code for viral capsid proteins are less homologous than genes whose products are involved in the processes of DNA replication and phage morphogenesis. During evolution, large nucleotide sequence rearrangements have occurred in the gene (gene III) whose product is needed for the attachment of the virion to the conjugative pili of the host cell, suggesting that these rearrangements have led to phages with different host specificities. Extensive nucleotide sequence homology was noted between the structural elements involved in DNA replication and phage morphogenesis, indicating that the mechanisms involved in DNA replication and morphogenesis are highly conserved.     

Nucleotide sequence of the genome of the filamentous bacteriophage I2-2: Module evolution of the filamentous phage genome

Summary The nucleotide sequence of the circular single-stranded genome of the filamentous Escherichia coli phage I2-2 has been determined and compared with those of the filamentous E. coli phages Ff(M13, fl, or fd) and IKe. The I2-2 DNA sequence comprises 6744 nucleotides; 139 nucleotides less than that of the N- and I2-plasmid-specific phage IKe, and 337 (336) nucleotides more than that of the F-plasmid-specific phage Ff. Nucleotide sequence comparisons have indicated that I2-2, IKe, and Ff have a similar genetic organization, and that the genomes of I2-2 and IKe are evolutionarily more closely related than those of I2-2 and Ff. The studies have further demonstrated that the I2-2 genome is a composite replicon, composed of only two-thirds of the ancestral genome of IKe. Only a contiguous I2-2 DNA sequence of 4615 nucleotides encompassing not only the coat protein and phage assembly genes, but also the signal required for efficient phage morphogenesis, was found to be significantly homologous to sequences in the genomes of IKe and Ff. No homology was observed between the consecutive DNA sequence that contains the origins for viral and complementary strand replication and the replication genes. Although other explanations cannot be ruled out, our data strongly suggest that the ancestor filamentous phage genome of phages I2-2 and IKe has exchanged its replication module during evolution with that of another replicon, e.g., a plasmid that also replicates via the so-called rolling circle mechanism. Offprint requests to: R.N.H. Konings     

Escherichia coli TolA tolerates multiple amino-acid substitutions as revealed by screening randomized variants for membrane integrity and phage receptor function

Escherichia coli TolA is a cytoplasmic membrane protein required for outer membrane integrity and the translocation of F-specific filamentous (Ff) bacteriophage DNA. Both phage infection and membrane integrity depend on several TolA interactions, e.g. those of the TolA C-terminal domain (TolAIII). Membrane integrity involves interaction with two host proteins and phage translocation requires direct interaction with the N-terminal domain (N1) of Ff phage protein g3p. Although cocrystallization of TolAIII and N1g3p has identified several contact points, it is still uncertain which residues are selectively involved in the different TolA functions. Thus, four different limited substitution libraries of TolA were created, targeting contacts at positions 415-420. These libraries were introduced into the tolA strain K17DE3tolA/F(+) and several variants, containing complementing, multiple amino-acid substitutions, were identified. However, most randomized variants did not complement the tolA strain K17DE3tolA/F(+). The TolA variants that restored sensitivity to phage infection displayed a considerable sequence variation, while the few variants that restored tolerance to detergent were from the same library. A comparison of the generated residue variation and natural variation, suggests that structural dependence overrides contact residue dependence. Thus, library screening can be efficient in identifying TolA variants with different functionally associated characteristics.     

The gene II proteins of the filamentous phages IKe and Ff (M13, fd and f1) are not functionally interchangeable during viral strand replication.

Gene II protein is the only phage-encoded protein required for the double-stranded DNA replication of the distantly related filamentous phages IKe and Ff (M13, fd and f1). Complementation studies have demonstrated that, despite a significant degree of homology between the nucleotide sequences of the gene II's of IKe and Ff and the core's (domains A) of their viral strand replication origins, the biological functions of the gene II proteins are not interchangeable. The specificity of these proteins is not determined by the nucleotide sequence (domain B) which is required for efficient initiation of viral strand replication of Ff. In fact, our data indicate that a sequence with a similar function as domain B in Ff does not form part of the viral strand replication origin of IKe.     

Two-dimensional 1H nuclear magnetic resonance studies on the gene V-encoded single-stranded DNA-binding protein of the filamentous bacteriophage IKe. I. Structure elucidation of the DNA-binding wing

Two-dimensional nuclear magnetic resonance techniques were used to obtain residue- and sequence-specific assignments in the 1H spectrum of the single-stranded DNA-binding protein encoded by gene V of the filamentous phage IKe (IKe GVP). The residue-specific assignments are based on the analysis of J-correlated spectra, i.e. correlated spectroscopy and homonuclear-Hartmann-Hahn total correlated spectroscopy. Complete assignments of side-chain spin systems, e.g. long side-chains, were, to a major part, derived from two-dimensional spectra obtained by means of the latter technique. Sequence-specific residue assignments were obtained for the two neighbouring residues V41 and Y42, and the amino acid sequence segment encompassing residues S17 through I29. The structure of this segment, a beta-loop, was deduced from the interresidue nuclear Overhauser effect pattern. Residues S17 through V19 and P26 through I29 form an anti-parallel beta-ladder segment, whereas residues Q21 to K25 constitute the loop region. The beta-loop is expected to project into the solution and is intimately involved in binding to single-stranded DNA; it is therefore designated the "DNA-binding wing". By analogy with the structure of the DNA-binding wing deduced from IKe GVP, a similar structure is proposed for the corresponding domain of the gene V protein encoded by the filamentous phage Ff for which, from X-ray diffraction studies, a three-dimensional structure has been deduced. Essential differences appear to exist between the DNA-binding domain in the X-ray structure and that proposed in this paper. Possible reasons for these differences are discussed.     

Mike, a chimeric filamentous phage designed for the separate production of either DNA strand of pKUN vector plasmids by F+ cells

To enable the separate production of either DNA strand of recombinant pKUN plasmids [Peeters et al., Gene 41 (1986) 39-46] by conjugation-deficient F+ cells a chimeric Ff/IKe filamentous phage, Mike, has been constructed. Its genome contains the functions required for asymmetric DNA replication from the N-plasmid specific filamentous phage IKe, and the functions required for host cell penetration, single-stranded DNA accumulation, phage assembly, and secretion from the F-plasmid specific filamentous phage Ff (i.e. M13, fl, or fd).     

Characterization of the DNA binding protein encoded by the N-specific filamentous Escherichia coli phage IKe. Binding properties of the protein and nucleotide sequence of the gene

A DNA binding protein encoded by the filamentous single-stranded DNA phage IKe has been isolated from IKe-infected Escherichia coli cells. Fluorescence and in vitro binding studies have shown that the protein binds co-operatively and with a high specificity to single-stranded but not to double-stranded DNA. From titration of the protein to poly(dA) it has been calculated that approximately four bases of the DNA are covered by one monomer of protein. These binding characteristics closely resemble those of gene V protein encoded by the F-specific filamentous phages M13 and fd. The nucleotide sequence of the gene specifying the IKe DNA binding protein has been established. When compared to the nucleotide sequence of gene V of phage M13 it shows an homology of 58%, indicating that these two phages are evolutionarily related. The IKe DNA binding protein is 88 amino acids long which is one amino acid residue larger than the gene V protein sequence. When the IKe DNA binding protein sequence is compared with that of gene V protein it was found that 39 amino acid residues have identical positions in both proteins. The positions of all five tyrosine residues, a number of which are known to be involved in DNA binding, are conserved. Secondary structure predictions indicate that the two proteins contain similar structural domains. It is proposed that the tyrosine residues which are involved in DNA binding are the ones in or next to a beta-turn, at positions 26, 41 and 56 in gene V protein and at positions 27, 42 and 57 in the IKe DNA binding protein.     

Sorting signals within the Saccharomyces cerevisiae sporulation-specific dityrosine transporter, Dtr1p, C terminus promote Golgi-to-prospore membrane transport

During sporulation in Saccharomyces cerevisiae, the dityrosine transporter Dtr1p, which is required for formation of the outermost layer of the spore wall, is specifically expressed and transported to the prospore membrane, a novel double-lipid-bilayer membrane. Dtr1p consists of 572 amino acids with predicted N- and C-terminal cytoplasmic extensions and 12 transmembrane domains. Dtr1p missing the largest internal cytoplasmic loop was trapped in the endoplasmic reticulum in both mitotically dividing cells and cells induced to sporulate. Deletion of the carboxyl 15 amino acids, but not the N-terminal extension of Dtr1p, resulted in a protein that failed to localize to the prospore membrane and was instead observed in cytoplasmic puncta. The puncta colocalized with a cis-Golgi marker, suggesting that Dtr1p missing the last 15 amino acids was trapped in an early Golgi compartment. Deletion of the C-terminal 10 amino acids resulted in a protein that localized to the prospore membrane with a delay and accumulated in cytoplasmic puncta that partially colocalized with a trans-Golgi marker. Both full-length Dtr1p and Dtr1p missing the last 10 amino acids expressed in vegetative cells localized to the plasma membrane and vacuoles, while Dtr1p deleted for the carboxyl-terminal 15 amino acids was observed only at vacuoles, suggesting that transport to the prospore membrane is mediated by distinct signals from those that specify plasma membrane localization. Transfer-of-function experiments revealed that both the carboxyl transmembrane domain and the C-terminal tail are important for Golgi complex-to-prospore membrane transport.     

Tol-dependent macromolecule import through the Escherichia coli cell envelope requires the presence of an exposed TolA binding motif

The Tol-Pal proteins of the cell envelope of Escherichia coli are required for maintaining outer membrane integrity. This system forms protein complexes in which TolA plays a central role by providing a bridge between the inner and outer membranes via its interaction with the Pal lipoprotein. The Tol proteins are parasitized by filamentous bacteriophages and group A colicins. The N-terminal domain of the Ff phage g3p protein and the translocation domains of colicins interact directly with TolA during the processes of import through the cell envelope. Recently, a four-amino-acid sequence in Pal has been shown to be involved in Pal's interaction with TolA. A similar motif is also present in the sequence of two TolA partners, g3p and colicin A. Here, a mutational study was conducted to define the function of these motifs in the binding activity and import process of TolA. The various domains were produced and exported to the bacterial periplasm, and their cellular effects were analyzed. Cells producing the g3p domain were tolerant to colicins and filamentous phages and had destabilized outer membranes, while g3p deleted of three residues in the motif was affected in TolA binding and had no effect on cell integrity or colicin or phage import. A conserved Tyr residue in the colicin A translocation domain was involved in TolA binding and colicin A import. Furthermore, in vivo and in vitro coprecipitation analyses demonstrated that colicin A and g3p N-terminal domains compete for binding to TolA.     

Identification and mutational analysis of bacteriophage PRD1 holin protein P35

Holin proteins are phage-induced integral membrane proteins which regulate the access of lytic enzymes to host cell peptidoglycan at the time of release of progeny viruses by host cell lysis. We describe the identification of the membrane-containing phage PRD1 holin gene (gene XXXV). The PRD1 holin protein (P35, 12.8 kDa) acts similarly to its functional counterpart from phage lambda (gene S), and the defect in PRD1 gene XXXV can be corrected by the presence of gene S of lambda. Several nonsense, missense, and insertion mutations in PRD1 gene XXXV were analyzed. These studies support the overall conclusion that the charged amino acids at the protein C terminus are involved in the timing of host cell lysis.     

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.     

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.     

Macromolecular import into Escherichia coli: the TolA C-terminal domain changes conformation when interacting with the colicin A toxin

Various macromolecules such as bacteriotoxins and phage DNA parasitize some envelope proteins of Escherichia coli to infect the bacteria. A two-step import mechanism involves the primary interaction with an outer membrane receptor or with a pilus followed by the translocation across the outer membrane. However, this second step is poorly understood. It was shown that the TolA, TolQ, and TolR proteins play a critical role in the translocation of group A colicins and filamentous bacteriophage minor coat proteins (g3p). Translocation of these proteins requires the interaction of their N-terminal domain with the C-terminal domain of TolA (TolAIII). In this work, short soluble TolAIII domains were overproduced in the cytoplasm and in the periplasm of E. coli. In TolAIII, the two cysteine residues were found to be reduced in the cytoplasmic form and oxidized in the periplasmic form. The interaction of TolAIII with the N-terminal domain of colicin A (ATh) is observed in the presence and in the absence of the disulfide bridge. The complex formation of TolAIII and ATh was found to be independent of the ionic strength. An NMR study of TolAIII, both free and bound, shows a significant structural change when interacting with ATh, in the presence or absence of the disulfide bridge. In contrast, such a structural modification was not observed when TolAIII interacts with g3p N1. These results suggest that bacteriotoxins and Ff bacteriophages parasitize E. coli using different interactions between TolA and the translocation domain of the colicin and g3p protein, respectively.     

Plasmid mediated alterations in composition and structure of envelopes of Escherichia coli B/r

Seven transmissible (Tra⁺), antibiotic resistance (r) plasmids, which confer sensitivity to the filamentous bacteriophage IKe on an Escherichia coli B/r strain harboring them, have been examined for the changes they evoke in the host cell membranes. The plasmids rR48and rR269, like rRM98 [1], cause a significant reduction in the density of the outer membrane and the virtual elimination of its 36 500 dalton protein. These 2 properties do not appear to be altered when rR45, rR199 or rR205 are the resident plasmids. No changes in the inner membrane proteins are seen in any of these strains. In the case of the rR46-bearing strain, the density of the outer membrane is increased and the level of the 36 500 dalton protein is unaltered; in addition, several changes in both inner and outer membrane proteins are seen. Spontaneous IKe resistant mutants isolated from strains lacking the 36 500 dalton protein are either Tra⁺ or Tra^?. Since most of them also lack this protein, the latter is not important to the expression of inter-bacterial gene transfer and IKe sensitivity.On freeze fracture, strains lacking the 36 500 dalton protein cleave almost exclusively within the outer membrane. The plasmidless host and the remaining plasmid-bearing strains show a strong fracture plane within the cytoplasmic membrane. Despite the fact that most of the plasmid-bearing strains used are proficient in effecting interbacterial plasmid transfer, no morphological differences which can be correlated with this function have been observed between their etched cell surfaces and that of the plasmidless host.     

Characterization of a Dual-Function Domain That Mediates Membrane Insertion and Excision of Ff Filamentous Bacteriophage

The filamentous phage Ff (f1, fd, or M13) of Escherichia coli is assembled at the cell membranes by a process that is morphologically similar to that of pilus assembly. The release of the filament virion is mediated by excision from the membrane; conversely, entry into a host cell is mediated by insertion of the virion coat proteins into the membrane. The N-terminal domains of the minor virion protein pIII have the sole role of binding to host receptors during infection. In contrast, the C domain of pIII is required for two opposite functions: insertion of the virion into the membrane during infection and excision at the termination step of assembly/secretion. We identified a 28-residue-long segment in the pIII C domain, which is required for phage entry but dispensable for release from the membrane at the end of assembly. This segment, which we named the infection-competence segment (ICS), works only in cis with the N-terminal receptor-binding domains and does not require the equivalent ICS sequences in other subunits within the virion cap. The ICS contains a predicted amphipathic α-helix and is rich in small amino acids, Gly, Ala, and Ser, which are arranged as a [small]XXX[small]XX[small]XXX[small]XXX[small] motif. Scanning Ala/Gly mutagenesis of ICS showed that small residues are compatible with infection. Overall, organization of the C domain is reminiscent of α-helical pore-forming toxins' membrane insertion domains. The unique ability of pIII to mediate both membrane insertion and excision allowed us to compare these two fundamental membrane transactions and to show that receptor-triggered insertion is a more complex process than excision from membranes.