Purification, crystallization and preliminary X-ray diffraction analysis of the phage T4 vertex protein gp24 and its mutant forms

The study of bacteriophage T4 assembly has revealed regulatory mechanisms pertinent not only to viruses but also to macromolecular complexes. The capsid of bacteriophage T4 is composed of the major capsid protein gp23, and a minor capsid protein gp24, which is arranged as pentamers at the vertices of the capsid. In this study the T4 capsid protein gp24 and its mutant forms were overexpressed and purified to homogeneity. The overexpression from plasmid vectors of all the constructs in Escherichia coli yields biologically active protein in vivo as determined by assembly of active virus following infection with inactivated gene 24 mutant viruses. The gp24 mutant was subjected to surface entropy reduction by mutagenesis and reductive alkylation in order to improve its crystallization properties and diffraction quality. To determine if surface mutagenesis targeting would result in diffractable crystals, two glutamate to alanine mutations (E89A,E90A) were introduced. We report here the biochemical observations and consequent mutagenesis experiment that resulted in improvements in the stability, crystallizability and crystal quality of gp24 without affecting the overall folding. Rational modification of the protein surface to achieve crystallization appears promising for improving crystallization behavior and crystal diffracting qualities. The crystal of gp24(E89A,E90A) diffracted to 2.6A resolution compared to wild-type gp24 at 3.80A resolution under the same experimental conditions. Surface mutation proved to be a better method than reductive methylation for improving diffraction quality of the gp24 crystals.     

Frameshift and double-amber mutations in the bacteriophage T4 uvsX gene: analysis of mutant UvsX proteins from infected cells

Summary The bacteriophage T4 uvsX gene encodes a 43 kDa, single-stranded DNA-dependent ATPase, double-stranded DNA-binding protein involved in DNA recombination, repair and mutagenesis. Mutants of uvsX have a DNA-arrest phenotype and reduced burst size. Western blot immunoassay of UvsX peptides made by a number of amber mutants revealed amber peptides ranging from 25–32 kDa. Wild-type UvsX protein was also detected in lysates of cells infected with uvsX amber mutants, suggesting that their mutations are suppressed by translational ambiguity. We investigated the effects of mutations near the 5 end of uvsX. A frameshift mutation was engineered at codon 33. Western immunoblots for UvsX protein demonstrated that the frameshift mutant expresses no detectable wild-type UvsX; instead, a 37 kDa reactive peptide was detected. In order to determine if this peptide represents truncated UvsX protein, the mutation was regenerated in the cloned uvsX gene and expressed in transformed Escherichia coli. Endopeptidase digestion of the 37 kDa protein from the cloned gene generated peptide fragments indistinguishable from those obtained from wild-type UvsX. A double-amber mutant of uvsX was also generated by oligonucleotide site-directed mutagenesis. No UvsX protein was detected in lysates of cells infected with the uvsX-am64am67 double mutant. Plaque size and sensitivity to UV inactivation for both the double-amber and the frame-shift mutants were indistinguishable from those of other uvsX mutants. Mutations in uvsY had no demonstrable effect on efficiency of plating or UV sensitivity of uvsX mutants. Thus, null mutants of uvsX are viable.     

Nonsense suppression context effects in Escherichia coli bacteriophage T4

Summary Nonsense suppression by supE44 has been examined in a collection of 14 T4 gene 22 and gene 23 UAG mutants, for which the precise gene location is known. In concordance with previous studies, UAG followed by a pyrimidine was inefficiently suppressed. However, among positions with similar 3 nucleotides, there was considerable variation in suppression efficiency. The competition between supE44 and Release Factor 1 (RF1) was also investigated following the introduction of a multicopy RF1 plasmid. An inverse relationship between the efficiency of suppression and RF1 competition was observed.     

Hoc protein regulates the biological effects of T4 phage in mammals

We previously investigated the biological, non-antibacterial effects of bacteriophage T4 in mammals (binding to cancer cells in vitro and attenuating tumour growth and metastases in vivo); we selected the phage mutant HAP1 that was significantly more effective than T4. In this study we describe a non-sense mutation in the hoc gene that differentiates bacteriophage HAP1 and its parental strain T4. We found no substantial effects of the mutation on the mutant morphology, and its effects on electrophoretic mobility and hydrodynamic size were moderate. Only the high ionic strength of the environment resulted in a size difference of about 10 nm between T4 and HAP1. We compared the antimetastatic activity of the T2 phage, which does not express protein Hoc, with those of T4 and HAP1 (B16 melanoma lung colonies). We found that HAP1 and T2 decreased metastases with equal effect, more strongly than did T4. We also investigated concentrations of T4 and HAP1 in the murine blood, tumour (B16), spleen, liver, or muscle. We found that HAP1 was rapidly cleared from the organism, most probably by the liver. Although HAP1 was previously defined to bind cancer cells more effectively (than T4), its rapid elimination precluded its higher concentration in tumours. Maria Zembala and Janusz Boratynski contributed equally to this work.     

The N terminus of the head protein of T4 bacteriophage directs proteins to the GroEL chaperonin

The head protein of T4 bacteriophage requires the GroEL chaperonin for its insertion into a growing T4 head. Hundreds of thousands of copies of this protein must pass through the chaperonin in a limited time later in infection, indicating that the protein must use GroEL very efficiently and may contain sequences that bind tightly to GroEL. We show that green fluorescent protein (GFP) fused to the N terminus of the head protein can fold at temperatures higher than those at which the GFP protein can fold well by itself. We present evidence that this folding is promoted by the strong binding of N-terminal head protein sequences to GroEL. This binding is so strong that some fusion proteins can apparently deplete the cell of the GroEL needed for other cellular functions, altering the cellular membranes and slowing growth.     

Primary structure of the tail sheath protein of bacteriophage T4 and its gene

Complete sequence determination of gene 18 encoding the tail sheath protein was carried out mainly by the Maxam-Gilbert method. Approximately 40 peptides contained in a tryptic digest and a lysyl endopeptidase digest of gp 18 were isolated by reversed-phase high-performance liquid chromatography. All the peptides were identified along the nucleotide sequence of gene 18 based on the amino acid compositions. These peptides cover 88% of the total primary structure. Furthermore, the amino acid sequences of 9 of the 40 peptides were determined by a gas-phase protein sequencer; one of them turned to be the N-terminal one. The C-terminal peptide in the tryptic digest was isolated from the unadsorbed fraction of affinity chromatography on immobilized anhydrotrypsin and the amino acid sequence was also determined. Thus, the complete primary structure of gp 18 was determined; it has 658 amino acid residues and a molecular weight of 71,160.This article was presented during the proceedings of the International Conference on Macromolecular Structure and Function, held at the National Defence Medical College, Tokorozawa, Japan, December 1985.     

Lysis protein T of bacteriophage T4

Summary Lysis protein T of phage T4 is required to allow the phage's lysozyme to reach the murein layer of the cell envelope and cause lysis. Using fusions of the cloned gene t with that of the Escherichia coli alkaline phosphatase or a fragment of the gene for the outer membrane protein OmpA, it was possible to identify T as an integral protein of the plasma membrane. The protein was present in the membrane as a homooligomer and was active at very low cellular concentrations. Expression of the cloned gene t was lethal without causing gross leakiness of the membrane. The functional equivalent of T in phage is protein S. An amber mutant of gene S can be complemented by gene t, although neither protein R of (the functional equivalent of T4 lysozyme) nor S possess any sequence similarity with their T4 counterparts. The murein-degrading enzymes (including that of phage P22) have in common a relatively small size (molecular masses of ca. 18 000) and a rather basic nature not exhibited by other E. coli cystosolic proteins. The results suggest that T acts as a pore that is specific for this type of enzyme.     

Molecular evolution of bacteriophages: Discrete patterns of codon usage in T4 genes are related to the time of gene expression

Summary Patterns of codon usage in certain coliphages are adapted to expression inEscherichia coli. Bacteriophage T4 may be an exception to test the rule, as it produces eight tRNAs with specificities that are otherwise rare inE. coli. A database of all known T4 DNA sequences has been compiled, comprising 174 genes and a total of 115 kb (approximately 70% of the T4 genome). Codon usage has been examined in all T4 genes; some of these are known to be expressed before, and some after, the production of phage tRNAs. The results show two different patterns of codon usage: by comparison with the early genes, the late genes exhibit a shift in preference toward those codons recognized by the phage-encoded tRNAs. The T4 tRNAs translate A-ending codons, and it is possible that the phage acquired the tRNA genes because the mutation bias of the T4 DNA polymerase forces the T4 genome toward A+T-richness.Presented at the NATO Advanced Workshop on Genome Organization and Evolution, held in Spetses, Greece, September 1990     

Models for the binary complex of bacteriophage T4 gp59 helicase loading protein: gp32 single-stranded DNA-BINDING protein and ternary complex with pseudo-Y junction DNA

Bacteriophage T4 gp59 helicase assembly protein (gp59) is required for loading of gp41 replicative helicase onto DNA protected by gp32 single-stranded DNA-binding protein. The gp59 protein recognizes branched DNA structures found at replication and recombination sites. Binding of gp32 protein (full-length and deletion constructs) to gp59 protein measured by isothermal titration calorimetry demonstrates that the gp32 protein C-terminal A-domain is essential for protein-protein interaction in the absence of DNA. Sedimentation velocity experiments with gp59 protein and gp32ΔB protein (an N-terminal B-domain deletion) show that these proteins are monomers but form a 1:1 complex with a dissociation constant comparable with that determined by isothermal titration calorimetry. Small angle x-ray scattering (SAXS) studies indicate that the gp59 protein is a prolate monomer, consistent with the crystal structure and hydrodynamic properties determined from sedimentation velocity experiments. SAXS experiments also demonstrate that gp32ΔB protein is a prolate monomer with an elongated A-domain protruding from the core. Fitting structures of gp59 protein and the gp32 core into the SAXS-derived molecular envelope supports a model for the gp59 protein-gp32ΔB protein complex. Our earlier work demonstrated that gp59 protein attracts full-length gp32 protein to pseudo-Y junctions. A model of the gp59 protein-DNA complex, modified to accommodate new SAXS data for the binary complex together with mutational analysis of gp59 protein, is presented in the accompanying article (Dolezal, D., Jones, C. E., Lai, X., Brister, J. R., Mueser, T. C., Nossal, N. G., and Hinton, D. M. (2012) J. Biol. Chem. 287, 18596-18607).     

Mutational specificity of a bacteriophage T4 DNA polymerase mutant, mel88

Summary Several bacteriophage T4 DNA polymerase mutants have been shown to increase the frequency of spontaneous mutations (Speyer et al. 1966; Freese and Freese 1967; de Vries et al. 1972; Reha-Krantz et al. 1986). In order to determine the molecular basis of the mutator phenotype, it is necessary to characterize the types of mutations produced by the mutator DNA polymerases. We show here that at least one DNA polymerase mutator mutant, mel88, induces an increased number of base substitution mutations compared with wild-type.     

A novel method for selective isolation of C-terminal peptides from tryptic digests of proteins by immobilized anhydrotrypsin: application to structural analyses of the tail sheath and tube proteins from bacteriophage T4

A novel method useful for selective isolation of the C-terminal peptide from a tryptic digestion mixture of a protein has been developed by taking advantage of a unique property of anhydrotrypsin, which has a strong specific affinity for the peptides containing arginine or lysine at their C-termini. Briefly, peptides produced by tryptic digestion of a protein are fractionated by affinity chromatography on a column of immobilized anhydrotrypsin. The C-terminal peptide is recovered in a breakthrough fraction, while the remainders are adsorbed on the column (unless the protein ends in arginine or lysine). The breakthrough fraction is then subjected to reversed-phase high-performance liquid chromatography in order to purify the C-terminal peptide. Using this method, we have successfully isolated the C-terminal peptides from tryptic digests of the sheath protein (gp 18) and the tube protein (gp 19) of bacteriophage T4. The analytical results on these peptides, together with the information on the N-terminal structures of the original proteins and on the nucleotide sequences of genes 18 and 19, allowed us to establish the complete primary structures of the two proteins.     

Isolation and genetic characterization of new uvsW alleles of bacteriophage T4

Summary TheuvsW gene of bacteriophage T4 is required for wild-type levels of recombination, for normal survival and mutagenesis after UV irradiation, and for wild-type resistance to hydroxyurea. Additionally,uvsW mutations restore the arrested DNA synthesis caused by mutations in any of several genes that block secondary initiation (recombination-primed replication, the major mode of initiation at late times), but only partially restore the reduced burst size. AuvsW deletion mutation was constructed to establish the null-allele phenotype, which is similar but not identical to the phenotype of the canonicaluvsW mutation, and to demonstrate convincingly that theuvsW gene is non-essential (althoughuvsW mutations severely compromise phage production). In an attempt to uncouple the diverse effects ofuvsW mutations, temperature-sensitiveuvsWts mutants were isolated. Recombination and replication effects were partially uncoupled in these mutants, suggesting distinct and separable roles foruvsW in the two processes. Furthermore, the restoration of DNA synthesis but not recombination in the double mutantsuvsW uvsX anduvsW uvsY prompts the hypothesis that the restored DNA synthesis is not recombinationally initiated.     

Alterations in the cell envelope of Escherichia coli late in bacteriophage T4 infection

The cell envelope of Escherichia coli was examined for changes during late stages of bacteriophage T4 infection. Late events in T4 infection are shown to result in (i) a reduction in the effectiveness of membrane separation procedures employing either isopycnic sucrose gradient centrifugation or selective solubilization of inner membrane by detergent (Sarkosyl or Triton X-100), (ii) the appearance of a 54 000 dalton host protein in membrane preparations, (iii) the adventitious presence of detergent-resistant phage morphogenetic structures in membrane preparations, and (iv) a decrease in the activity of NADH oxidase and an apparent alteration in its association with inner membrane. These modifications occur regardless of the state of the $\text{e}$ and $\text{t}$ genes of T4.     

Engineering of bacteriophage T4 tail sheath protein

Gene product 18 (gp18, 659 amino acids) forms bacteriophage T4 contractile tail sheath. Recombinant protein assembles into different length polysheaths during expression in the cell, which complicates the preparation of protein crystals for its spatial structure determination. To design soluble monomeric gp18 mutants unable to form polysheaths and useful for crystallization, we have used Bal31 nuclease for generation deletions inside gene 18 encoding the Ile507-Gly530 region. Small deletions in the region of Ile507-Ile522 do not affect the protein assembly into polysheaths. Protein synthesis termination occurs because of reading frame failure in the location of deletions. Some fragments of gp18 containing short pseudoaccidental sequence in the C-terminal, while being soluble, have lost the ability for polysheath assembly. For the first time we succeeded in obtaining crystals of a soluble gp18 fragment containing 510 amino acids which, according to trypsin resistance, is similar to native protein monomer.     

Design and crystal structure of bacteriophage T4 mini-fibritin NCCF

Fibritin is a fibrous protein that forms "whiskers" attached to the neck of bacteriophage T4. Whiskers interact with the long tail fibers regulating the assembly and infectivity of the virus. The fibritin trimer includes the N-terminal domain responsible for attachment to the phage particle and for the collar formation, the central domain forming a 500 A long segmented coiled-coil structure, and the C-terminal "foldon" domain. We have designed a "mini" fibritin with most of the coiled-coil domain deleted, and solved its crystal structure. The non-helical N-terminal part represents a new protein fold that tightly interacts with the coiled-coil segment forming a single domain, as revealed by calorimetry. The analysis of the crystal structure and earlier electron microscopy data on the collar-whisker complex suggests the necessity of other proteins to participate in the collar formation. Crystal structure determination of the N-terminal domain of fibritin is the first step towards elucidating the detailed structure and assembly mechanism of the collar-whisker complex.     

Regulation of translation of the head protein of T4 bacteriophage by specific binding of EF-Tu to a leader sequence

Recent evidence indicates that translation elongation factor Tu (EF-Tu) has a role in the cell in addition to its well established role in translation. The translation factor binds to a specific region called the Gol region close to the N terminus of the T4 bacteriophage major head protein as the head protein emerges from the ribosome. This binding was discovered because EF-Tu bound to Gol peptide is the specific substrate of the Lit protease that cleaves the EF-Tu between amino acid residues Gly59 and lle60, blocking phage development. These experiments raised the question of why the Gol region of the incipient head protein binds to EF-Tu, as binding to incipient proteins is not expected from the canonical role of EF-Tu. Here, we use gol-lacZ translational fusions to show that cleavage of EF-Tu in the complex with Gol peptide can block translation of a lacZ reporter gene fused translationally downstream of the Gol peptide that activated the cleavage. We propose a model to explain how binding of EF-Tu to the emerging Gol peptide could cause translation to pause temporarily and allow time for the leader polypeptide to bind to the GroEL chaperonin before translation continues, allowing cotranslation of the head protein with its insertion into the GroEL chaperonin chamber, and preventing premature synthesis and precipitation of the head protein. Cleavage of EF-Tu in the complex would block translation of the head protein and therefore development of the infecting phage. Experiments are presented that confirm two predictions of this model. Considering the evolutionary conservation of the components of this system, this novel regulatory mechanism could be used in other situations, both in bacteria and eukaryotes, where proteins are cotranslated with their insertion into cellular structures.