Your search keyword '"Russel, M."' showing total 31 results

1. Assembling filamentous phage occlude pIV channels.

Author

Marciano DK, Russel M, and Simon SM

Subjects

Escherichia coli ultrastructure, Escherichia coli virology, Hydrolysis, Microscopy, Electron, Protein Transport, Viral Nonstructural Proteins metabolism, Coliphages physiology, Viral Nonstructural Proteins antagonists & inhibitors

Abstract

Filamentous phage f1 is exported from its Escherichia coli host without killing the bacterial cell. Phage-encoded protein pIV, which is required for phage assembly and secretion, forms large highly conductive channels in the outer membrane of E. coli. It has been proposed that the phage are extruded across the bacterial outer membrane through pIV channels. To test this prediction, we developed an in vivo assay by using a mutant pIV that functions in phage export but whose channel opens in the absence of phage extrusion. In E. coli lacking its native maltooligosacharride transporter LamB, this pIV variant allowed oligosaccharide transport across the outer membrane. This entry of oligosaccharide was decreased by phage production and still further decreased by production of phage that cannot be released from the cell surface. Thus, exiting phage block the pIV-dependent entry of oligosaccharide, suggesting that phage occupy the lumen of pIV channels. This study provides the first evidence, to our knowledge, for viral exit through a large aqueous channel.

Published

2001

2. An aqueous channel for filamentous phage export.

Author

Marciano DK, Russel M, and Simon SM

Subjects

Anti-Bacterial Agents pharmacology, Biological Transport, Carbohydrate Metabolism, Cell Membrane metabolism, Cell Membrane Permeability, Electric Conductivity, Electrophysiology, Escherichia coli metabolism, Ion Channel Gating, Lipid Bilayers, Mutation, Polysaccharides metabolism, Porins metabolism, Proteolipids, Vancomycin pharmacology, Viral Nonstructural Proteins chemistry, Viral Nonstructural Proteins genetics, Viral Nonstructural Proteins isolation & purification, Coliphages metabolism, Escherichia coli virology, Inovirus metabolism, Ion Channels metabolism, Membrane Proteins metabolism, Viral Nonstructural Proteins metabolism

Abstract

Filamentous phage f1 exits its Escherichia coli host without killing the bacterial cell. It has been proposed that f1 is secreted through the outer membrane via a phage-encoded channel protein, pIV. A functional pIV mutant was isolated that allowed E. coli to grow on large maltodextrins and rendered E. coli sensitive to large hydrophilic antibiotics that normally do not penetrate the outer membrane. In planar lipid bilayers, both mutant and wild-type pIV formed highly conductive channels with similar permeability characteristics but different gating properties: the probability of the wild-type channel being open was much less than that of the mutant channel. The high conductivity of pIV channels suggests a large-diameter pore, thus implicating pIV as the outer membrane phage-conducting channel.

Published

1999

3. The filamentous phage pIV multimer visualized by scanning transmission electron microscopy.

Author

Linderoth NA, Simon MN, and Russel M

Subjects

Biopolymers, Coloring Agents, Dimerization, Methylamines, Microscopy, Electron, Scanning Transmission, Molecular Weight, Protein Conformation, Solubility, Vanadates, Viral Proteins chemistry, Viral Proteins isolation & purification, Coliphages chemistry, Viral Proteins ultrastructure

Abstract

A family of homomultimeric outer-membrane proteins termed secretins mediates the secretion of large macromolecules such as enzymes and filamentous bacteriophages across bacterial outer membranes to the extracellular milieu. The secretin encoded by filamentous phage f1 was purified. Mass determination of individual molecules by scanning transmission electron microscopy revealed two forms, a unit multimer composed of about 14 subunits and a multimer dimer. The secretin is roughly cylindrical and has an internal diameter of about 80 angstroms, which is large enough to accommodate filamentous phage (diameter of 65 angstroms).

Published

1997

4. Essential role of a sodium dodecyl sulfate-resistant protein IV multimer in assembly-export of filamentous phage.

Author

Linderoth NA, Model P, and Russel M

Subjects

Amino Acid Sequence, Base Sequence, Blotting, Western methods, Capsid drug effects, Capsid genetics, Coliphages chemistry, Electrophoresis, Polyacrylamide Gel, Glycerol pharmacology, Heating, Molecular Sequence Data, Mutagenesis, Insertional, Oligodeoxyribonucleotides, Sodium Dodecyl Sulfate pharmacology, Structure-Activity Relationship, Urea pharmacology, Capsid chemistry, Capsid physiology, Coliphages physiology, Virus Assembly physiology

Abstract

Filamentous phage f1 encodes protein IV (pIV), a protein essential for phage morphogenesis that localizes to the outer membrane of Escherichia coli, where it is found as a multimer of 10 to 12 subunits. Introduction of internal His or Strep affinity tags at different sites in pIV interfered with its function to a variable extent. A spontaneous second-site suppressor mutation in gene IV allowed several different insertion mutants to function. The identical mutation was also isolated as a suppressor of a multimerization-defective missense mutation. A high-molecular-mass pIV species is the predominant form of pIV present in cells. This species is stable in 4% sodium dodecyl sulfate at temperatures up to 65 degrees C and is largely preserved at 100 degrees C in Laemmli protein sample buffer containing 4% sodium dodecyl sulfate. The suppressor mutation makes the high-molecular-mass form of wild-type pIV extremely resistant to dissociation, and it stabilizes the high-molecular-mass form of several mutant pIV proteins to extents that correlate with their level of function. Mixed multimers of pIV(f1) and pIV(Ike) also remain associated during heating in sodium dodecyl sulfate-containing buffers. Thus, sodium dodecyl sulfate- and heat-resistant high-molecular-mass pIV is derived from pIV multimer and reflects the physiologically relevant form of the protein essential for assembly-export.

Published

1996

5. Moving through the membrane with filamentous phages.

Author

Russel M

Subjects

Coliphages genetics, DNA Replication, Genome, Viral, Inovirus genetics, Coliphages physiology, Inovirus physiology, Virus Replication

Abstract

Filamentous phages are small, highly evolved parasites that can reproduce and disseminate without killing their host. During assembly, virion proteins are transferred from the host membrane to the single-stranded DNA phase genome and simultaneously secreted from the cell. Filamentous phage assembly shares certain features with bacterial processes responsible for the assembly of cell-surface structures and for extracellular protein secretion.

Published

1995

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

Author

Russel M

Subjects

Amino Acid Sequence, Base Sequence, Coliphages growth & development, Coliphages metabolism, Deoxycholic Acid pharmacology, Escherichia coli drug effects, Gene Expression, Molecular Sequence Data, Mutation, Operon, Phenotype, Sequence Alignment, Viral Proteins chemistry, Coliphages genetics, Escherichia coli genetics, Genes, Viral, Viral Proteins genetics

Abstract

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 pIV+ 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.

Published

1994

7. pIV, a filamentous phage protein that mediates phage export across the bacterial cell envelope, forms a multimer.

Author

Kazmierczak BI, Mielke DL, Russel M, and Model P

Subjects

Bacterial Proteins chemistry, Bacterial Proteins metabolism, Biopolymers, Centrifugation, Density Gradient, Cross-Linking Reagents, Dickeya chrysanthemi chemistry, Escherichia coli metabolism, Inovirus chemistry, Precipitin Tests, Spheroplasts metabolism, Viral Proteins metabolism, Coliphages chemistry, Viral Proteins chemistry

Abstract

Filamentous phage pIV is an outer membrane protein required for phage assembly and secretion. Chemical cross-linking and sedimentation experiments have been used to demonstrate that pIV from f1-infected Escherichia coli exists as a homo-multimer, probably composed of 10 to 12 subunits. pIV secreted from spheroplasts remains soluble and does not form multimers. Synthesis of pIV from distantly related filamentous phages or from a bacterial homolog that participates in a specialized form of extra-cellular protein secretion in the same cell with pIVf1 resulted in the formation of mixed multimers. This suggests that the homologous proteins themselves form homo-multimers. These structures could form gated channels that conduct assembling phage or specific substrate proteins across the outer membrane to the extracellular milieu.

Published

1994

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

Author

Russel M and Kaźmierczak B

Subjects

Alkaline Phosphatase biosynthesis, Bacterial Proteins biosynthesis, Coliphages genetics, DNA Mutational Analysis, Gene Expression Regulation, Bacterial, Heat-Shock Proteins biosynthesis, Membrane Proteins biosynthesis, Mutation, Operon genetics, Recombinant Fusion Proteins isolation & purification, Recombinant Fusion Proteins metabolism, Sequence Deletion, Sequence Homology, Amino Acid, Spheroplasts metabolism, Subcellular Fractions, Viral Proteins biosynthesis, Virus Replication, Cell Compartmentation, Coliphages growth & development, Genes, Viral genetics, Membrane Proteins genetics, Viral Proteins genetics

Abstract

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.

Published

1993

9. Protein-protein interactions during filamentous phage assembly.

Author

Russel M

Subjects

Alleles, Amino Acid Sequence, Capsid genetics, Capsid metabolism, Coliphages genetics, Escherichia coli, Molecular Sequence Data, Mutation, Protein Binding, Restriction Mapping, Viral Proteins genetics, Coliphages metabolism, Viral Proteins metabolism

Abstract

Filamentous phage proteins pI and pIV are morphogenetic proteins required for phage assembly but not part of the virion. Neither pI nor pIV from the related phages f1 and IKe can substitute for its equivalent in the other phage. When the two proteins are supplied as pairs, however, partial restoration of heterologous phage assembly occurs. This observation strongly suggests that the two proteins interact. A selection for revertants of a temperature sensitive mutant of f1 gene IV resulted in the isolation of a suppressor mutation in gene I. This suppressor is allele specific, and thus supports the hypothesis that pI and pIV interact. A selection for IKe phage that can efficiently utilize paired pI and pIV from from f1 led to the isolation of a phage with a mutation in gene VIII, which encodes the major coat protein of the virus. Analysis of the system suggests that it is pI that interacts with both pIV and pVIII. Thus the process by which filamentous phage are concomitantly assembled and secreted across the cell membranes is likely to involve a series of protein-protein interactions that are accessible to genetic analysis.

Published

1993

10. Construction of a microphage variant of filamentous bacteriophage.

Author

Specthrie L, Bullitt E, Horiuchi K, Model P, Russel M, and Makowski L

Subjects

Bacteriophage M13 ultrastructure, Base Sequence, Coliphages ultrastructure, DNA Replication, DNA, Recombinant, Gene Expression Regulation, Viral, Helper Viruses genetics, Molecular Sequence Data, Morphogenesis, Nucleic Acid Conformation, Particle Size, Plasmids ultrastructure, Bacteriophage M13 genetics, Coliphages genetics, DNA, Viral genetics, Plasmids genetics

Abstract

The intergenic region in the genome of the Ff class of filamentous phage (comprising strains fl, fd and M13) genome constitutes 8% of the viral genome, and has essential functions in DNA replication and phage morphogenesis. The functional domains of this region may be inserted into separate sites of a plasmid to function independently. Here, we demonstrate the construction of a plasmid containing, sequentially, the origin of (+)-strand synthesis, the packaging signal and a terminator of (+)-strand synthesis. When host cells harboring this plasmid (pLS7) are infected with helper phage they produce a microphage particle containing all the structural elements of the mature, native phage. The microphage is 65 A in diameter and about 500 A long. It contains a 221-base single-stranded circle of DNA coated by about 95 copies of the major coat protein (gene 8 protein).

Published

1992

11. Interchangeability of related proteins and autonomy of function. The morphogenetic proteins of filamentous phage f1 and IKe cannot replace one another.

Author

Russel M

Subjects

Cloning, Molecular, Coliphages genetics, DNA, Single-Stranded metabolism, Genetic Complementation Test, Morphogenesis, Protein Binding, Species Specificity, Viral Proteins genetics, Viral Proteins metabolism, Coliphages physiology, Viral Proteins physiology

Abstract

The filamentous phage f1 and IKe infect a common host, are structurally highly similar and exhibit 55% identity at the DNA sequence level. Based on the idea that proteins that function autonomously will be more tolerant of multiple amino acid differences than proteins that must interact with other proteins to function, the ability of four individual proteins from f1 to substitute for their IKe equivalents to promote virus assembly in vivo has been examined. The reciprocal replacements were also examined. Only the single-strand DNA binding proteins (pV) were fully interchangeable. A minor capsid protein, pIX, was unable to substitute in assembly of the heterologous phage. Two proteins required for particle assembly that are not part of the phage particle, pI and pIV, were not interchangeable, although pIVf1 stimulated formation of a very small number of IKe particles in the absence of pIVIKe. The lack of interchangeability suggests that these morphogenetic proteins do not function autonomously, but rather interact with one or more phage proteins. The ability of certain overproduced proteins to interfere with assembly of wild-type f1 or IKe forms the basis for a model that suggests that phage assembly requires an interaction between pI and pIV.

Published

1992

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

Author

Brissette JL and Russel M

Subjects

Amino Acid Sequence, Biological Transport, Cloning, Molecular, DNA Mutational Analysis, DNA, Single-Stranded, Escherichia coli ultrastructure, Molecular Sequence Data, Morphogenesis, Protein Precursors, Protein Processing, Post-Translational, Protein Sorting Signals genetics, Subcellular Fractions metabolism, Trypsin pharmacology, Virus Replication, Coliphages genetics, Genes, Viral, Membrane Proteins genetics, Viral Structural Proteins genetics

Abstract

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.

Published

1990

13. Phage shock protein, a stress protein of Escherichia coli.

Author

Brissette JL, Russel M, Weiner L, and Model P

Subjects

Bacterial Proteins genetics, Bacterial Proteins isolation & purification, Cloning, Molecular, Coliphages genetics, Electrophoresis, Polyacrylamide Gel, Escherichia coli drug effects, Ethanol pharmacology, Genes, Bacterial, Heat-Shock Proteins genetics, Heat-Shock Proteins isolation & purification, Hot Temperature, Kinetics, Mitomycin, Mitomycins pharmacology, Nalidixic Acid pharmacology, Novobiocin pharmacology, Osmolar Concentration, Bacterial Proteins biosynthesis, Coliphages metabolism, Escherichia coli metabolism, Heat-Shock Proteins biosynthesis

Abstract

Filamentous phage infection induces the synthesis of large amounts of an Escherichia coli protein, phage shock protein (Psp), the product of a previously undescribed gene. This induction is due to the phage gene IV protein, pIV, an integral membrane protein. The uninduced level of Psp is undetectable, but when induced by prolonged synthesis of pIV, it can become one of the most abundant proteins in the cell. Psp is also synthesized transiently in response to several stresses (heat, ethanol, and osmotic shock). High-level synthesis occurs only after extreme treatment. Unlike the members of the heat shock regulon, Psp induction does not require the heat shock sigma factor, sigma 32; some stimuli that elicit sigma 32-dependent heat shock proteins do not induce Psp synthesis. The level of Psp induction after extreme stress is even higher in sigma 32 mutant cells, which are unable to mount a normal heat shock response, suggesting that these parallel stress responses are interrelated.

Published

1990

14. Some acridine-resistant mutations of bacteriophage T4D.

Author

Rappaport H, Russel M, and Susman M

Subjects

Chromosome Mapping, Coliphages growth & development, DNA Viruses drug effects, DNA Viruses growth & development, DNA, Viral biosynthesis, Escherichia coli growth & development, Recombination, Genetic, Time Factors, Acridines pharmacology, Coliphages drug effects, Drug Resistance, Microbial, Mutation

Abstract

Three new 9-aminoacridine (9AA) resistant mutations of bacteriophage T4D have been isolated and characterized. Two of the mutations, rs and rc, have identical patterns of acridine resistance, but they map on opposite sides of the rII region. In addition, rs has an effect on the plaque morphology of r mutations, whereas rc does not. The third mutation, ama, maps very close to rs but exhibits a different pattern of resistance to 9AA. None of the three is resistant to acridines by virtue of reduced permeability. Taken together with other mutations that have been previously characterized, these new mutations permit us to set the minimum number of acridine-sensitive processes in T4 development at four.

Published

1974

15. Translational, autogenous regulation of gene 32 expression during bacteriophage T4 infection.

Author

Russel M, Gold L, Morrissett H, and O'Farrell PZ

Subjects

Drug Stability, Half-Life, Kinetics, Models, Biological, Viral Proteins metabolism, Virus Replication, Coliphages metabolism, DNA, Viral metabolism, Escherichia coli metabolism, Genes, Protein Biosynthesis, RNA, Messenger metabolism

Abstract

Functional half-life measurements of the bacteriophage T4 gene 32 messenger RNA indicate that this mRNA is extremely stable. Regulation of gene 32 expression at the transcriptional level cannot account for the rapidity with which P32 synthesis can be repressed. Furthermore, derepression of P32 synthesis occurs in the presence of rifampicin, a drug which inhibits transcriptional initiation. In addition, T4-infected cultures in which P32 expression is repressed possess almost as much gene 32 mRNA as derepressed cultures. We conclude that expression of the T4 gene 32 protein is regulated at the level of translation.

Published

1976

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

Author

Russel M and Model P

Subjects

Chromosome Mapping, Chromosomes, Bacterial, Genes, Dominant, Morphogenesis, Mutation, Temperature, Viral Plaque Assay, Viral Proteins biosynthesis, Coliphages growth & development, Escherichia coli genetics, Genes, Bacterial

Abstract

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.

Published

1983

17. Aspects of the growth and regulation of the filamentous phages.

Author

Fulford W, Russel M, and Model P

Subjects

Coliphages growth & development, Escherichia coli growth & development, Viral Proteins genetics, Coliphages genetics, Escherichia coli genetics, Genes, Genes, Viral

Published

1986

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

Author

Russel M and Model P

Subjects

Kinetics, Molecular Weight, Virus Replication, Coliphages metabolism, Escherichia coli metabolism, Membrane Proteins biosynthesis, Mutation, Peptide Hydrolases metabolism, Viral Proteins metabolism

Abstract

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.

Published

1981

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

Author

Boeke JD, Russel M, and Model P

Subjects

Amino Acid Sequence, Amino Acids metabolism, Base Sequence, Codon, Deoxyribonucleotides analysis, Electrophoresis, Polyacrylamide Gel, Genes, Viral, Mutation, Suppression, Genetic, Coliphages metabolism, DNA, Viral, Viral Proteins biosynthesis

Published

1980

20. Cassettes of the f1 intergenic region.

Author

Heitman J, Treisman J, Davis NG, and Russel M

Subjects

Cloning, Molecular methods, Plasmids, Templates, Genetic, Coliphages genetics, Genes, Viral

Published

1989

21. Filamentous phage assembly: membrane insertion of the major coat protein.

Author

Model P, Russel M, and Boeke JD

Subjects

Coliphages genetics, Escherichia coli genetics, Morphogenesis, Mutation, Protein Precursors metabolism, Coliphages ultrastructure, Membrane Proteins metabolism, Viral Proteins metabolism, Virus Replication

Abstract

The assembly of filamentous bacteriophages has been studied in cells infected by wild-type and mutant phage; host mutants defective in bacteriophage assembly have also been isolated. Phage assembly takes place at the membrane, and requires insertion of the viral major coat protein. We present data on the physiology of this process and on the effects of amino acid sequence variations near to the coat protein amino terminus on membrane insertion, processing, and phage assembly.

Published

1981

22. Thioredoxin is required for filamentous phage assembly.

Author

Russel M and Model P

Subjects

Amino Acid Sequence, Base Sequence, Escherichia coli genetics, Genes, Bacterial, Morphogenesis, Mutation, Thioredoxins genetics, Bacterial Proteins physiology, Coliphages growth & development, Thioredoxins physiology, Virus Replication

Abstract

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.

Published

1985

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

Author

Russel M and Model P

Subjects

Bacterial Proteins metabolism, Carbonyl Cyanide m-Chlorophenyl Hydrazone pharmacology, Coliphages metabolism, Protein Precursors metabolism, Sodium Hydroxide pharmacology, Coliphages ultrastructure, Membrane Proteins metabolism, Viral Proteins metabolism

Abstract

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.

Published

1982

24. An improved filamentous helper phage for generating single-stranded plasmid DNA.

Author

Russel M, Kidd S, and Kelley MR

Subjects

Base Sequence, DNA Transposable Elements, Genetic Vectors, Nucleic Acid Conformation, Coliphages genetics, DNA, Single-Stranded genetics, DNA, Viral genetics, Escherichia coli genetics, Plasmids

Abstract

Gene cloning in plasmid vectors that contain a filamentous phage intergenic region presents several advantages. However, technical difficulties have been a problem, primarily low yields of packaged single stranded (ss) plasmid DNA from the rapid, small scale procedures usually employed, and ambiguities in sequencing reactions attributed to the contamination by helper phage ss DNA. We report here the construction and some properties of a new f1 helper phage. Using this phage, R408, plasmid ss DNA is packaged and exported preferentially over phage ss DNA, and the absolute yield of plasmid ss DNA is usually increased.

Published

1986

25. Regulation of gene 32 expression during bacteriophage T4 infection of Escherichia coli.

Author

Gold L, O'Farrell PZ, and Russel M

Subjects

Feedback, Genes, Kinetics, Models, Biological, Mutation, Species Specificity, Virus Replication, Coliphages metabolism, DNA Replication, DNA, Viral metabolism, Escherichia coli metabolism, Viral Proteins metabolism

Abstract

The gene 32 protein of the bacteriophage T4 plays an important role in genetic recombination, DNA repair, and DNA replication; the protein functions in these processes by virtue of a strong binding capacity for single-stranded DNA. During infections of Escherichia coli by bacteriophage carrying amber of temperature-sensitive mutations in gene 32, the altered gene 32 protein (that is, the amber fragment of the missense polypeptide) is synthesized at greatly elevated rates. During infections by phages that are mutant in other genes (and wild type in gene 32), gene 32 expression is coupled to the quantity of single-stranded DNA produced during the infection. The data are consistent with a model in which the gene 32 protein binds preferentially to all available single-stranded DNA. When all available single-stranded DNA is complexed with gene 32 protein, free gene 32 protein represses its own synthesis. The high level expression of altered gene 32 proteins (amber fragments or missense polypeptides) is a direct consequence of the proposed autoregulation.

Published

1976

26. Low-frequency infection of F- bacteria by transducing particles of filamentous bacteriophages.

Author

Russel M, Whirlow H, Sun TP, and Webster RE

Subjects

Genotype, Plasmids, Coliphages genetics, DNA, Viral genetics, Escherichia coli genetics, Genes, Bacterial, Transduction, Genetic

Abstract

Filamentous particles containing single-stranded plasmid and bacteriophage DNA are able to infect F- Escherichia coli at frequencies of approximately 10(-6). This infection is dependent on an intact particle and requires the products of the tolQ, tolR, and tolA genes of the bacteria. The addition of CaCl2 can increase the frequency about 100-fold, presumably by increasing the concentration of particles at the bacterial surface.

Published

1988

27. The role of thioredoxin in filamentous phage assembly. Construction, isolation, and characterization of mutant thioredoxins.

Author

Russel M and Model P

Subjects

Base Sequence, Binding Sites, Coliphages metabolism, Genotype, Models, Molecular, Plasmids, Protein Conformation, Species Specificity, Thioredoxins isolation & purification, Bacterial Proteins genetics, Coliphages genetics, Escherichia coli genetics, Mutation, Thioredoxins genetics

Abstract

Filamentous phage assembly in vivo shows an absolute requirement for thioredoxin and a partial requirement for thioredoxin reductase. Mutants in which one or both of the active site cysteine residues of thioredoxin were changed to alanine or serine were constructed and shown to support filamentous phage assembly. Some of the mutants were almost as effective as wild-type thioredoxin, while others supported phage assembly only when high levels of the mutant protein were present in the infected cell. The mutant proteins were all inactive in an assay which couples oxidation of NADPH to reduction of 5,5'-dithiobis-2-nitrobenzoic acid) via thioredoxin reductase and thioredoxin. These active site mutants make phage assembly completely independent of thioredoxin reductase, which suggests that the phage needs, and the active site mutants provide, the proteins in the reduced conformation. Other mutants were isolated on the basis of their failure to support filamentous phage growth. These specified mutant thioredoxin proteins with varying levels of redox activity in vivo and in vitro. The locations of these mutations suggest that the surface of thioredoxin thought to interact with thioredoxin reductase also interacts with the filamentous phage assembly machinery. An in vivo assay for thioredoxin redox function, based on the ability of cells to utilize methionine sulfoxide, was developed. Met- cells containing mutant thioredoxins that are inactive in vitro do not form colonies on plates containing methionine sulfoxide as the sole methionine source.

Published

1986

28. Replacement of the fip gene of Escherichia coli by an inactive gene cloned on a plasmid.

Author

Russel M and Model P

Subjects

Genotype, Mutation, Temperature, Transduction, Genetic, Alleles, Cloning, Molecular, Coliphages genetics, Escherichia coli genetics, Genes, Bacterial, Plasmids

Abstract

To determine whether the fip gene of Escherichia coli, which is required for filamentous phage assembly, is required for cell viability, we replaced the chromosomal copy of the gene with an inactive copy introduced on a plasmid. We found that the fip gene is dispensable. The method we devised, which should be generally useful, was also tested with an inactivated rho gene. As expected, the rho gene is essential.

Published

1984

29. The time of synthesis and function of the rII + product of bacteriophage T4.

Author

Mattson T and Russel M

Subjects

Adenine metabolism, Carbon Isotopes, Chloramphenicol pharmacology, Coliphages growth & development, Coliphages isolation & purification, DNA Replication, DNA, Viral biosynthesis, Escherichia coli, Floxuridine pharmacology, Genes, Genetic Code, Leucine metabolism, Mutation, RNA, Messenger biosynthesis, Temperature, Thymidine metabolism, Time Factors, Tritium, Virus Replication, Coliphages metabolism, Lysogeny, Viral Proteins biosynthesis

Published

1972

30. Control of bacteriophage T4 DNA polymerase synthesis.

Author

Russel M

Subjects

Autoradiography, Carbon Isotopes, DNA Replication, DNA, Viral, Electrophoresis, Polyacrylamide Gel, Escherichia coli, Genes, Regulator, Genetic Code, Kinetics, Molecular Biology, Mutation, Temperature, Viral Proteins biosynthesis, Coliphages enzymology, DNA Nucleotidyltransferases biosynthesis

Published

1973

31. Cassettes of the f1 intergenic region

Author

Heitman, J, Treisman, J, Davis, N G, and Russel, M

Subjects

Genes, Viral, Templates, Genetic, Cloning, Molecular, Coliphages, Plasmids

Published

1989