Processing of filamentous phage pre-coat protein. Effect of sequence variations near the signal peptidase cleavage site

Continuous microfluidic assortment of interactive ligands (CMAIL)

Finding an interactive ligand-receptor pair is crucial to many applications, including the development of monoclonal antibodies. Biopanning, a commonly used technique for affinity screening, involves a series of washing steps and is lengthy and tedious. Here we present an approach termed continuous microfluidic assortment of interactive ligands, or CMAIL, for the screening and sorting of antigen-binding single-chain variable antibody fragments (scFv) displayed on bacteriophages (phages). Phages carrying native negative charges on their coat proteins were electrophoresed through a hydrogel matrix functionalized with target antigens under two alternating orthogonal electric fields. During the weak horizontal electric field phase, phages were differentially swept laterally depending on their affinity for the antigen, and all phages were electrophoresed down to be collected during the strong vertical electric field phase. Phages of different affinity were spatially separated, allowing the continuous operation. More than 10⁵ CFU (colony forming unit) antigen-interacting phages were isolated with ~100% specificity from a phage library containing 3 × 10⁹ individual members within 40 minutes of sorting using CMAIL. CMAIL is rapid, sensitive, specific, and does not employ washing, elution or magnetic beads. In conclusion, we have developed an efficient and cost-effective method for isolating and sorting affinity reagents involving phage display.

Membrane integration of E. coli model membrane proteins

The molecular events of membrane translocation and insertion have been investigated using a number of different model proteins. Each of these proteins has specific features that allow interaction with the membrane components which ensure that the proteins reach their specific local destination and final conformation. This review will give an overview on the best-characterized proteins studied in the bacterial system and emphasize the distinct aspects of the pathways.

Direct interaction of YidC with the Sec-independent Pf3 coat protein during its membrane protein insertion

YidC is a newly defined translocase component that mediates the insertion of proteins into the membrane bilayer. How YidC functions in the insertion process is not known. In this study, we report that the Sec-independent Pf3 coat protein requires the YidC protein specifically for the membrane translocation step. Using photocrosslinking techniques and ribosome-bound Pf3 coat derivatives with an extended carboxyl-terminal region, we found that the transmembrane region of the Pf3 coat protein physically interacts with YidC and the bacterial signal recognition particle Ffh component. We also find that in the insertion pathway, Pf3 coat interacts strongly with YidC only after its transmembrane segment is fully exposed outside the ribosome tunnel. Interaction between Pf3 coat and YidC occurs even in the absence of the proton motive force and with a Pf3 coat mutant that is defective in transmembrane insertion. Our study demonstrates that YidC can directly interact with a Sec-independent membrane protein, and the role of YidC is at the stage of folding the Pf3 protein into a transmembrane configuration.

Phage display: applications, innovations, and issues in phage and host biology

In the 7 years since the first publications describing phage-displayed peptide libraries, phage display has been successfully employed in a variety of research. Innovations in vector design and methods to identify target clones account for much of this success. At the same time, not all ventures have been entirely successful and it appears that phage and host biology play important roles in this. A key issue concerns the role played by a displayed peptide or protein in its successful expression and incorporation into virions. While few studies have examined these issues specifically in context of phage display, the literature as a whole provides insight. Accordingly, we review phage biology, relevant aspects of host biology, and phage display applications with the goals of illustrating (i) relevant aspects of the interplay between phage-host biology and successful phage display and (ii) the limitations and considerable potential of this important technology.Key words: bacteriophage M13, phage display, pIII, pVIII, expression libraries.

Phage presentation and affinity selection of a deletion mutant of human interleukin-3

A deletion derivative of the cytokine human interleukin-3 (hIL-3(15-125), comprising amino acids 15-125 of the native protein) was produced as a fusion to the filamentous phage surface protein pIII. The cytokine was detected in association with phage particles by protein immunoblotting. Compared to an equivalent quantity of soluble-cytokine, phage-presented hIL-3(15-125) exhibited reduced biological activity in a hIL-3-dependent cell proliferation assay. The reduction in activity was attributable to presence of phage particles in the assay, rather than directly owing to physical incorporation of the cytokine into the phage particle. Owing to the position of the amber codon in the phagemid vector, the phagemid-produced free hIL-3(15-125) species (designated hIL-3(15-125) epsilon) had 20 amino acids appended to its C-terminus; hIL-3(15-125) epsilon did not exhibit reduced bioactivity. hIL-3(15-125)-presenting phage were affinity-selected with either a hIL-3-reactive polyclonal antibody or with cells expressing the heterodimeric hIL-3 receptor. These data are consistent with the use of phage-display technology for the affinity selection of hIL-3 variants with modified biological properties.

Module swaps between related translocator proteins pIV(f1), pIV(IKe) and PulD: identification of a specificity domain

In Gram-negative bacteria, type II and type III secretion and filamentous phage assembly systems use related outer membrane proteins for substrate-specific transport across the outer membrane. We show here that the specificity domain of the phage f1 outer membrane protein pIV is contained within the 149 N-terminal amino acid residues. When the pIV(f1) specificity domain is fused to the translocator domain of the related pIV of phage IKe, the chimeric construct supports f1 but not IKe assembly. Functional coupling between the two domains in this chimeric construct is poor and is improved by a single amino acid change in the translocator domain of the pIV(IKe). In native pIV(IKe), two amino acid changes within its specificity domain are both necessary and sufficient to change the specificity from IKe to f1 assembly. Analysis of 39 chimeric constructs between pIV(f1) and the outer membrane protein PulD of the pullulanase secretion system failed to identify a comparable exchangeable specificity domain. These results indicate that the two domains may not function autonomously, and suggest that tertiary and quarternary changes of the entire translocator component rather than of an autonomous functional domain are required for specific translocation across the outer membrane.

Molecular models and structural comparisons of native and mutant class I filamentous bacteriophages Ff (fd, f1, M13), If1 and IKe

The filamentous bacteriophages are flexible rods about 1 to 2 microns long and 6 nm in diameter, with a helical shell of protein subunits surrounding a DNA core. The approximately 50-residue coat protein subunit is largely alpha-helix and the axis of the alpha-helix makes a small angle with the axis of the virion. The protein shell can be considered in three sections: the outer surface, occupied by the N-terminal region of the subunit, rich in acidic residues that interact with the surrounding solvent and give the virion a low isoelectric point; the interior of the shell, including a 19-residue stretch of apolar side-chains, where protein subunits interact mainly with each other; and the inner surface, occupied by the C-terminal region of the subunit, rich in basic residues that interact with the DNA core. The fact that virtually all protein side-chain interactions are between different subunits in the coat protein array, rather than within subunits, makes this a useful model system for studies of interactions between alpha-helix subunits in a macromolecular assembly. We describe molecular models of the class I filamentous bacteriophages. This class includes strains fd, f1, M13 (these 3 very similar strains are members of the Ff group), If1 and IKe. Our model of fd has been refined to fit quantitative X-ray fibre diffraction data to 30 A resolution in the meridional direction and 7 A resolution in the equatorial direction. A simulated 3.3 A resolution diffraction pattern from this model has the same general distribution of intensity as the experimental diffraction pattern. The observed diffraction data at 7 A resolution are fitted much better by the calculated diffraction pattern of our molecular model than by that of a model in which the alpha-helix subunit is represented by a rod of uniform density. The fact that our fd model explains the fd diffraction data is only part of our structure analysis. The atomic details of the model are supported by non-diffraction data, in part previously published and in part newly reported here. These data include information about permitted or forbidden side-chain replacements, about the effect of chemical modification, and about spectroscopic experiments.(ABSTRACT TRUNCATED AT 400 WORDS)

Inserting foreign peptides into the major coat protein of bacteriophage M13

Foreign DNA fragments were inserted into filamentous phage gene VIII to create hybrid B-proteins with foreign sequences in the amino terminus. The hybrid proteins are incorporated into the virions which retain viability and infectivity. Virions with hybrid B-proteins have the same contour length and the same number of B-protein molecules as virions with natural B-proteins. It was shown that for one of hybrid B-proteins the position of the processing site had changed.

Selection of antibody ligands from a large library of oligopeptides expressed on a multivalent exposition vector

Practically any oligopeptide can be exposed on the surface of the bacteriophage capsid by fusion to the major coat protein of filamentous bacteriophages. A phage expressing a particular peptide tag can be selected from a mixture of tens of millions of clones, exposing oligopeptides of random sequence, by affinity purification with a protein ligand. In this respect, pVIII can be used as an alternative and complement to the exposition vectors based on the product of gene III (pIII). We have constructed a phagemid vector that contains gene VIII under the control of the pLac promoter. This vector can be conveniently used to construct libraries of oligopeptides with a random amino acid sequence. An antipeptide monoclonal antibody was used to affinity-purify phagemids exposing oligopeptides which can interact with the monoclonal antibody. DNA sequencing of the amino terminus of gene VIII of the recovered clones predicts the synthesis of hybrid proteins whose aminoterminal amino acid sequence is related to that of the oligopeptide used to raise the antibody. In other words, only oligopeptides that bind a very small portion of the immunoglobulin G surface are affinity-purified by this method, implying that the antigen binding site possesses molecular properties that renders it much stickier than the remainder of the molecule.

Signal peptidase I overproduction results in increased efficiencies of export and maturation of hybrid secretory proteins in Escherichia coli

The effects of 25-fold overproduction of Escherichia coli signal peptidase I (SPase I) on the processing kinetics of various (hybrid) secretory proteins, comprising fusions between signal sequence functions selected from the Bacillus subtilis chromosome and the mature part of TEM-beta-lactamase, were studied in E. coli. One precursor (pre[A2d]-beta-lactamase) showed an enhanced processing rate, and consequently, a highly improved release of the mature enzyme into the periplasm. A minor fraction of a second hybrid precursor (pre[A13i]-beta-lactamase), which was not processed under standard conditions of SPase I synthesis, was shown to be processed under conditions of SPase I overproduction. However, this did not result in efficient release of the mature beta-lactamase into the periplasm. In contrast, the processing rates of wild-type pre-beta-lactamase and pre(A2)-beta-lactamase, already high under standard conditions, were not detectably altered by SPase I overproduction. These results demonstrate that the availability of SPase I can be a limiting factor in protein export in E. coli, in particular with respect to (hybrid) precursor proteins showing low (SPase I) processing efficiencies.

Regulation of filamentous bacteriophage length by modification of electrostatic interactions between coat protein and DNA

Bacteriophage fd gene VIII, which encodes the major capsid protein, was mutated to convert the serine residue at position 47 to a lysine residue (S47K), thereby increasing the number of positively charged residues in the C-terminal region of the protein from four to five. The S47K coat protein underwent correct membrane insertion and processing but could not encapsidate the viral DNA, nor was it incorporated detectably with wild-type coat proteins into hybrid bacteriophage particles. However, hybrid virions could be constructed from the S47K coat protein and a second mutant coat protein, K48Q, the latter containing only three lysine residues in its C-terminal region. K48Q phage particles are approximately 35% longer than wild-type. Introducing the S47K protein shortened these particles, the S47K/K48Q hybrids exhibiting a range of lengths between those of K48Q and wild-type. These results indicate that filamentous bacteriophage length (and the DNA packaging underlying it) are regulated by unusually flexible electrostatic interactions between the C-terminal domain of the coat protein and the DNA. They strongly suggest that wild-type bacteriophage fd makes optimal use of the minimum number of coat protein subunits to package the DNA compactly.

Dual importance of positive charge in the C-terminal region of filamentous bacteriophage coat protein for membrane insertion and DNA-protein interaction in virus assembly

Gene VIII encoding the procoat protein of the Class II filamentous bacteriophage Pf1 (infecting Pseudomonas aeruginosa) has been cloned and expressed in Escherichia coli and subjected to site-directed mutagenesis. The two positively charged residues clustered near the C-terminus, arginine-44 and lysine-45, were systematically converted to uncharged residues and serine-41 was converted to an arginine residue. Removal of positive charge in the C-terminal region of the molecule seriously impaired the ability of the procoat molecule to undergo insertion at the E. coli cell inner membrane, as manifested by the diminished processing of the N-terminal leader peptide. The basic amino acids near the C-terminus of the coat protein are also involved in neutralizing the negatively charged viral DNA during virus assembly. However, despite its additional positive charge, the S41R mutant protein was unable to participate in the assembly of Class I bacteriophage fd in E. coli. This dual requirement of positively charged residues in the C-terminal region of the coat protein for membrane processing and insertion and for electrostatic neutralization of the encapsidated DNA poses important constraints on the evolution of filamentous bacteriophages with two different helical symmetries.

Variable electrostatic interaction between DNA and coat protein in filamentous bacteriophage assembly

A restriction fragment carrying the major coat protein gene (gene VIII) was excised from the DNA of the class I filamentous bacteriophage fd, which infects Escherichia coli. This fragment was cloned into the expression plasmid pKK223-3, where it came under the control of the tac promoter, generating plasmid pKf8P. Bacteriophage fd gene VIII was similarly cloned into the plasmid pEMBL9+, enabling it to be subjected to site-directed mutagenesis. By this means the positively charged lysine residue at position 48, one of four positively charged residues near the C terminus of the protein, was turned into a negatively charged glutamic acid residue. The mutated fd gene VIII was cloned back from the pEMBL plasmid into the expression plasmid pKK223-3, creating plasmid pKE48. In the presence of the inducer isopropyl-beta-D-thiogalactoside, the wild-type and mutated coat protein genes were strongly expressed in E. coli TG1 cells transformed with plasmids pKf8P and pKE48, respectively, and the product procoat proteins underwent processing and insertion into the E. coli cell inner membrane. A net positive charge of only 2 on the side-chains in the C-terminal region is evidently sufficient for this initial stage of the virus assembly process. However, the mutated coat protein could not encapsidate the DNA of bacteriophage R252, an fd bacteriophage carrying an amber mutation in its own gene VIII, when tested on non-suppressor strains of E. coli. On the other hand, elongated hybrid bacteriophage particles could be generated whose capsids contained mixtures of wild-type (K48) and mutant (E48) subunits. This suggests that the defect in assembly may occur at the initiation rather than the elongation step(s) in virus assembly. Other mutations of lysine-48 that removed or reversed the positive charge at this position in the C-terminal region of the coat protein were also found to lead to the production of commensurately longer bacteriophage particles. Taken together, these results indicate direct electrostatic interaction between the DNA and the coat protein in the capsid and support a model of non-specific binding between DNA and coat protein subunits with a stoicheiometry that can be varied during assembly.

Topogenic signals in integral membrane proteins

Integral membrane proteins are characterized by long apolar segments that cross the lipid bilayer. Polar domains flanking these apolar segments have a more balanced amino acid composition, typical for soluble proteins. We show that the apolar segments from three different kinds of membrane-assembly signals do not differ significantly in amino acid content, but that the inside/outside location of the polar domains correlates strongly with their content of arginyl and lysyl residues, not only for bacterial inner-membrane proteins, but also for eukaryotic.proteins from the endoplasmic reticulum, the plasma membrane, the inner mitochondrial membrane, and the chloroplast thylakoid membrane. A positive-inside rule thus seems to apply universally to all integral membrane proteins, with apolar regions targeting for membrane integration and charged residues providing the topological information.

Transcending the impenetrable: how proteins come to terms with membranes

In the living cell, proteins are efficiently sorted to a whole range of subcellular compartments. In many cases, sorting specificity is mediated by short 'sorting signals' attached either permanently or transiently to the protein. At long last, a fairly coherent picture of the design and function of many such sorting signals is beginning to emerge.

Cloning and expression of the filamentous bacteriophage Pf1 major coat protein gene in Escherichia coli. Membrane protein processing and virus assembly

A restriction fragment carrying the major coat protein gene (gene VIII) was excised from the replicative form (RF) DNA of the class II filamentous bacteriophage Pf1, which infects Pseudomonas aeruginosa. This fragment was cloned into the expression plasmid pKK223-3, where it came under the control of the tac promoter. In transformed Escherichia coli JM101 cells, in the presence of the inducer isopropyl-beta-D-thiogalactoside, the bacteriophage Pf1 gene was strongly expressed. The bacteriophage Pf1 coat protein displays the same pattern of negatively charged N-terminal region, hydrophobic middle region and positively charged C-terminal region as that of its counterpart in the class I bacteriophage fd, which infects E. coli, but otherwise the two proteins have no sequence homology. However, the Pf1 procoat protein was found to undergo processing and insertion into the E. coli cell inner membrane, like its fd counterpart, demonstrating that this part of the assembly process is the same for these different bacteriophages. The complete transcriptional unit, incorporating the tac promoter and rrnB transcription terminators flanking the Pf1 coat protein gene, was excised from the expression plasmid and cloned into the intergenic space of bacteriophage R252, an fd bacteriophage that carries an amber mutation in its own major coat protein gene. The Pf1 coat protein gene was again well expressed in infected E. coli cells but the chimeric bacteriophage had growth properties identical to those of the parent bacteriophage R252 on suppressor and non-suppressor strains of E. coli. The class I bacteriophage Pf1 coat protein evidently cannot be recognized by the class I bacteriophage assembly complex at or in the E. coli cell inner membrane, either at the point of initiation of assembly or during the elongation process.

Amino-terminal deletion mutants of the Rous sarcoma virus glycoprotein do not block signal peptide cleavage but can block intracellular transport

Protein sequence requirements for cleavage of the signal peptide from the Rous sarcoma virus glycoprotein have been investigated through the use of deletion mutagenesis. The phenotypes of these mutants have been characterized by expression of the cloned, mutated env genes in CV-1 cells using a late replacement SV40 vector. The deletion mutations were generated by Ba131 digestion at the XhoI site located near the 5' end of the coding sequence for the structural protein gp85, which is found at the amino terminus of the precursor glycoprotein, Pr95. The results of experiments with three mutants (X1, X2, and X3) are presented. Mutant X1 has a 14 amino acid deletion encompassing amino acids 4-17 of gp85, which results in the loss of one potential glycosylation site. In mutants X2 and X3 the amino terminal nine and six amino acids, respectively, of gp85 are deleted. During the biosynthesis of all three mutant polypeptides, the signal peptide is efficiently and accurately cleaved from the nascent protein, even though in mutants X2 and X3 the cleavage site itself has been altered. In these mutants the alanine/aspartic acid cleavage site has been mutated to alanine/asparagine and alanine/glutamine, respectively. These results are consistent with the concept that sequences C-terminal to the signal peptidase site are unimportant in defining the site of cleavage in eucaryotes. Mutants X2 and X3 behave like wild-type with respect to protein glycosylation, palmitic acid addition, cleavage to gp85 and gp37, and expression on the cell surface. Mutant X1, on the other hand, is defective in intracellular transport. Although it is translocated across the rough endoplasmic reticulum and core-glycosylated, its transport appears to be blocked at an early Golgi compartment. No terminal glycosylation of the protein, cleavage of the precursor protein to the mature products, or expression on the cell surface is observed. The deletion in X1 thus appears to destroy signals required for export to the cell surface.

Thioredoxin is required for filamentous phage assembly

Sequence comparisons show that the fip gene product of Escherichia coli, which is required for filamentous phage assembly, is thioredoxin. Thioredoxin serves as a cofactor for reductive processes in many cell types and is a constituent of phage T7 DNA polymerase. The fip-1 mutation makes filamentous phage and T7 growth temperature sensitive in cells that carry it. The lesion lies within a highly conserved thioredoxin active site. Thioredoxin reductase (NADPH), as well as thioredoxin, is required for efficient filamentous phage production. Mutant phages defective in phage gene I are particularly sensitive to perturbations in the fip-thioredoxin system. A speculative model is presented in which thioredoxin reductase, thioredoxin, and the gene I protein interact to drive an engine for filamentous phage assembly.

Increased intracellular concentration of an initiator protein markedly reduces the minimal sequence required for initiation of DNA synthesis

One of the most common sites used for cloning in the filamentous phages f1, fd, and M13 lies within the phage "functional origin," a sequence of 140 nucleotides that is required for phage replication. Even small insertions (four nucleotides) at this location severely reduce origin function. Secondary trans-acting mutations in the phage genome are necessary to restore efficient replication. One of these mutations, present in one of our cloning vectors, R218, has been fully characterized. It consists of a regulatory mutation within gene V that leads to a marked increase in the intracellular level of the phage gene II protein, the "initiator" of viral replication. Increased gene II protein production is sufficient to reduce the minimal sequence required for a functional origin to only 40 nucleotides, while the remaining 100 (containing the cloning site) become entirely dispensable. The general implications of these findings are discussed.

How signal sequences maintain cleavage specificity

The specificity of the signal sequence cleavage reaction has been postulated to reside in a signal peptidase active site that can bind only to particular (i, i + 2) pairs of amino acids. In this paper, we present further patterns of non-random amino acid utilization in a region around in vivo cleavage sites, and show that they can be interpreted in terms of selection acting to reduce the number of potential competing sites in the vicinity of the correct one.

A bacterial gene, fip, required for filamentous bacteriophage fl assembly

An Escherichia coli mutant which does not support the growth of filamentous bacteriophage fl allows phage fl DNA synthesis and gene expression in mutant cells, but progeny particles are not assembled. The mutant cells have no other obvious phenotype. On the basis of experiments with phage containing nonlethal gene I mutations and with mutant fl selected for the ability to grow on mutant bacteria, we propose an interaction between the morphogenetic function encoded by gene I of the phage and the bacterial function altered in this mutant. The bacterial mutation defines a new gene, fip (for filamentous phage production), located near 84.2 min on the E coli chromosome.

Construction of a synthetic messenger RNA encoding a membrane protein

We have synthesized microgram quantities of a functional eucaryotic mRNA by in vitro transcription. For this purpose, we constructed a plasmid in which the Escherichia coli lactose promoter was 5' to the vesicular stomatitis virus (VSV) G protein gene (Rose, J. K., and C. J. Gallione, 1981, J. Virol., 39:519-528). This DNA served as the template in an in vitro transcription reaction utilizing E. coli RNA polymerase. The RNA product was capped using the vaccinia guanylyltransferase. A typical preparation of the synthetic G mRNA was equivalent to the amount of G mRNA that can be isolated from approximately 10(8) VSV-infected cells. This synthetic mRNA was translated by a wheat germ extract in the presence of microsomes, producing a polypeptide that was indistinguishable from G protein in its size, antigenicity, degree of glycosylation, and its membrane insertion. This technique should aid in identifying features needed by proteins for insertion into membranes.

Demonstration by a novel genetic technique that leader peptidase is an essential enzyme of Escherichia coli

It was previously shown that two separate regions of DNA are required for expression of the cloned leader peptidase gene on plasmid pTD101 (T. Date and W. Wickner, Proc. Natl. Acad. Sci. U.S.A. 78:6106-6110, 1981). Both loci have been mapped in detail, and their roles have been established. A 1.3-kilobase region, termed the L region, encodes the 37,000-dalton leader peptidase protein. Another region, termed the P region, is about 1.5 kilobases away from the L region and is less than 350 base pairs long. The P region acts in cis to the L region, suggesting that it plays a role as a promoter. A technique for inactivation of the leader peptidase gene on the Escherichia coli chromosome has been developed to examine whether the leader peptidase which we had cloned is essential for cell growth. A specific plasmid (P(-) L(-)) which deletes both the P region and a substantial portion of the L region was constructed and transformed into a polA mutant strain. The plasmid cannot replicate in this strain; thus, the plasmid-borne ampicillin resistance is lost unless the plasmid DNA recombines into the chromosome. Integration of the P(-) L(-) plasmid did not yield any viable ampicillin-resistant cells, whereas the three control plasmids, P(+) L(+), P(+) L(-), and P(-) L(+), did. When the P(-) L(-) plasmid was transformed into the polA(Ts) strain, the strain could only grow in the presence of ampicillin at a permissive temperature, suggesting that integration of the plasmid into the host chromosome leads to inactivation of the chromosomal leader peptidase gene. Southern hybridization analysis demonstrated that the integration of plasmids into the chromosome occurred at the homologous site. This study demonstrates that expression of the leader peptidase gene is critical for cell growth.

A prokaryotic membrane anchor sequence: carboxyl terminus of bacteriophage f1 gene III protein retains it in the membrane

Gene III protein of bacteriophage f1 is inserted into the host cell membrane where it is assembled into phage particles. A truncated form of gene III protein, encoded by a recombinant plasmid and lacking the carboxyl terminus, does not remain in the membrane but instead appears to slip through it. Fusion of a hydrophobic "membrane anchor" from another membrane protein, the gene VIII protein, to the truncated gene III protein (by manipulation of the recombinant plasmid) restores membrane anchoring. A model for the relationship of gene III protein with the Escherichia coli membrane is discussed.

Effects of bacteriophage f1 gene III protein on the host cell membrane

Plasmids which encode bacteriophage f1 coat protein genes VIII and III are responsible for a number of unusual properties suggesting that they have a drastic effect on the bacterial outer membrane. Analysis of several such recombinant plasmids and selection of mutant plasmids unable to cause this effect established that the properties were caused by gene III protein or its amino-terminal fragment.

Filamentous phage pre-coat is an integral membrane protein: analysis by a new method of membrane preparation

We show, using a simple, rapid fractionation method, that the precursor to the filamentous phage major coat protein is an integral membrane protein. The method, which consists of treatment of Escherichia coli with 0.1 N NaOH followed by centrifugation, leaves a subset of inner and outer membrane proteins in the NaOH pellet. Most proteins partition into the NaOH pellet (membrane) or supernatant (cytoplasm and periplasm) in a manner consistent with their subcellular location as determined by more conventional techniques. We find no evidence for cytoplasmic filamentous phage pre-coat protein in either wild-type of mutant-infected cells. Our evidence suggests that a protein identified as "soluble procoat" by K. Ito, G. Mandell and W. Wickner may be the amber fragment of a different phage protein.

Isolation of the Escherichia coli leader peptidase gene and effects of leader peptidase overproduction in vivo

The only covalent modifications known to accompany protein insertion into membranes or protein secretion are glycosylation and the proteolytic removal of an NH2-terminal leader (signal) sequence. This latter reaction is catalyzed by leader peptidase, a constitutive, membrane-bound proteinase. We now report the identification of a plasmid-bearing strain of Escherichia coli that overproduces leader peptidase 4- to 6-fold. This strain grows normally and shows an unaltered polypeptide composition of inner ad outer membranes. The leader peptidase gene has been subcloned and transferred from this plasmid to the multicopy plasmid pBR322, yielding a new plasmid (pTD101). Strains transformed by pTD101 have a 30-fold increase in leader peptidase. We have studied the effect of leader peptidase overproduction on the insertion of newlymade M13 phage coat protein into the plasma membrane of infected cells. The overproducer strain, when infected by M13 phage, shows a dramatic acceleration in the conversion of procoat (a cytoplasmic precursor form) to coat (an integral, transmembrane protein). Thus the leader peptidase that converts M13 procoat to coat in vitro can catalyze this reaction in vivo as well.

Gene II of phage f1: its functions and its products

Plasmids harboring the amino-terminal part of bacteriophage f1 gene II confer to bacterial cells partial resistance to infection with the male-specific bacteriophages f1 and f2. This effect (IP-2 phenotype) is due to the production of large amounts of an approximately 20,000-dalton polypeptide corresponding to the amino-terminal part of gene II protein. These results have allowed the isolation of clones producing functional gene II protein in large amounts. An in vitro assay has been developed to test the enzymatic activity of the gene II protein produced.

A mutation downstream from the signal peptidase cleavage site affects cleavage but not membrane insertion of phage coat protein

Morphogenesis of filamentous phage includes synthesis of the phage major coat protein in precursor form, its insertion into the host cell plasma membrane, its cleavage to the mature form of the protein, and its assembly there into virions. The M13 mutant am8H1R6 encodes a coat protein in which leucine replaces glutamic acid as residue 2 of the mature protein [Boeke, J. D., Russel, M. & Model, P. (1980) J. Mol. Biol. 144, 103-116]. The coat protein precursor produced by this variant is a poor substrate for the Escherichia coli signal peptidase both in vivo and in vitro. This pre-coat protein, which is eventually processed and assembled into viable phage particles, is associated with the membrane fraction of the infected cell. We conclude that the domain recognized by the signal peptidase extends beyond the signal peptide itself. Furthermore, membrane association and signal peptide cleavage can be separated temporally under conditions that permit membrane insertion, cleavage, and phage assembly.