Crystallization of the membrane-containing bacteriophage PRD1 in quartz capillaries by vapour diffusion.

Crystals of bacteriophage PRD1, a virus containing an internal lipid bilayer, have been grown in thin-walled quartz capillary tubes by vapour diffusion as a means of eliminating mechanical handling of the crystals during data collection. It has been found that the addition of polyethylene glycol 20 000 (PEG 20K) to the mother liquor that bathes the crystals allows far higher resolution diffraction intensities to be observed. Growing and treating the crystals in this way has produced a small number of crystals which are particularly amenable to X-ray diffraction analysis.

A minor capsid protein P30 is essential for bacteriophage PRD1 capsid assembly.

Bacteriophage PRD1 is a double-stranded DNA virus infecting Gram-negative hosts. It has a membrane component located in the interior of the isometric capsid. In addition to the major capsid protein P3, the capsid contains a 9 kDa protein P30. Protein P30 is proposed to be located between the adjacent facets of the icosahedral capsid and is required for stable capsid assembly. In its absence, an empty phage-specific membrane vesicle is formed. The major protein component of this vesicle is a phage-encoded assembly factor, protein P10, that is not present in the final structure.

A new mutant class, made by targeted mutagenesis, of phage PRD1 reveals that protein P5 connects the receptor binding protein to the vertex.

Phage PRD1 and adenovirus share a number of structural and functional similarities, one of which is the vertex organization at the fivefold-symmetry positions. We developed an in vitro mutagenesis system for the linear PRD1 genome in order to make targeted mutations. The role of protein P5 in the vertex structure was examined by this method. Mutation in gene V revealed that protein P5 is essential. The absence of P5 did not compromise the particle assembly or DNA packaging but led to a deficient vertex structure where the receptor binding protein P2, in addition to protein P5, was missing. P5(-) particles also lost their DNA upon purification. Based on this and previously published information we propose a spatial model for the spike structure at the vertices. This resembles to the corresponding structure in adenovirus.

Assembly dynamics of the nucleocapsid shell subunit (P8) of bacteriophage phi6.

Phi6 is an enveloped dsRNA bacteriophage of Pseudomonas syringae. The viral envelope encloses a nucleocapsid, consisting of an RNA-dependent RNA polymerase complex within an icosahedral shell assembled from approximately 800 copies of a 16 kDa subunit (protein P8, encoded by viral gene 8). During infection, the nucleocapsid penetrates the host plasma membrane and enters the cytosol, whereupon the P8 shell disassembles and the polymerase complex is activated. To understand the molecular mechanisms of shell assembly and disassembly-processes that have counterparts in most viral infections-we have investigated the structure, stability, and dynamics of P8 in different assembly states using time-resolved Raman spectroscopy and hydrogen-isotope exchange. In the presence of Ca(2+), which promotes shell assembly, the highly alpha-helical conformation of the P8 subunit is stabilized by rapid assembly into shell-like structures. However, in the absence of Ca(2+), the P8 subunit is thermolabile and unstable, manifested by a slow alpha-helix --> beta-strand conformational change and the accumulation of aberrant aggregates. In both properly assembled shells and aberrant aggregates, the P8 subunit retains an alpha-helical core that is protected against deuterium exchange of amide NH groups. Surprisingly, no additional protection against amide exchange is conferred by the shell lattice. Time-resolved assembly and disassembly experiments in deuterated buffers indicate that the regions of P8 involved in subunit/subunit interactions in the intact shell undergo rapid exchanges, presumably due to local unfolding events that are characterized by low activation barriers. Such localized dynamics of P8 within the shell lattice may mediate the nucleocapsid/host membrane interactions that are required in the cytosol for particle assembly during maturation and disassembly during infection.

Stable packaging of phage PRD1 DNA requires adsorption protein P2, which binds to the IncP plasmid-encoded conjugative transfer complex.

The double-stranded DNA bacteriophage PRD1 uses an IncP plasmid-encoded conjugal transfer complex as a receptor. Plasmid functions in the PRD1 life cycle are restricted to phage adsorption and DNA entry. A single phage structural protein, P2, located at the fivefold capsid vertices, is responsible for PRD1 attachment to its host. The purified recombinant adsorption protein was judged to be monomeric by gel filtration, rate zonal centrifugation, analytical ultracentrifugation, and chemical cross-linking. It binds to its receptor with an apparent K(d) of 0.20 nM, and this binding prevents phage adsorption. P2-deficient particles are unstable and spontaneously release the DNA with concomitant formation of the tail-like structure originating from the phage membrane. We envisage the DNA to be packaged through one vertex, but the presence of P2 on the other vertices suggests a mechanism whereby the injection vertex is determined by P2 binding to the receptor.

The complete genome sequence of PM2, the first lipid-containing bacterial virus To Be isolated.

Bacteriophage PM2 was isolated from the Pacific Ocean off the coast of Chile in the late 1960s. It was a new virus type, later classified as Corticoviridae, and also the first bacterial virus for which it was demonstrated that lipids are part of the virion structure. Here we report the determination and analysis of the 10, 079-bp circular dsDNA genome sequence. Noteworthy discoveries are the replication initiation system, which is related to the rolling circle mechanism described for phages such as φX174 and P2, and a 1.2-kb sequence that is similar to the maintenance region of a plasmid found in a marine Pseudoalteromonas sp. strain A28.

Viral evolution revealed by bacteriophage PRD1 and human adenovirus coat protein structures.

The unusual bacteriophage PRD1 features a membrane beneath its icosahedral protein coat. The crystal structure of the major coat protein, P3, at 1.85 A resolution reveals a molecule with three interlocking subunits, each with two eight-stranded viral jelly rolls normal to the viral capsid, and putative membrane-interacting regions. Surprisingly, the P3 molecule closely resembles hexon, the equivalent protein in human adenovirus. Both viruses also have similar overall architecture, with identical capsid lattices and attachment proteins at their vertices. Although these two dsDNA viruses infect hosts from very different kingdoms, their striking similarities, from major coat protein through capsid architecture, strongly suggest their evolutionary relationship.

Purification and characterization of the assembly factor P17 of the lipid-containing bacteriophage PRD1.

Assembly factors, proteins assisting the formation of viral structures, have been found in many viral systems. The gene encoding the assembly factor P17 of bacteriophage PRD1 has been cloned and expressed in Escherichia coli. P17 acts late in phage assembly, after capsid protein folding and multimerization, and sorting of membrane proteins has occurred. P17 has been purified to near homogeneity. It is a tetrameric protein displaying a rather high heat stability. The protein is largely in an alpha-helical conformation and possesses a putative leucine zipper which is not essential for protein function, as judged by in vitro mutagenesis and complementation analysis. Although heating does not cause structural changes in the conformation of the protein, the dissociation of the tetramer into smaller units is evident as diminished self-quenching of the fluorescently labeled P17. Similarly, dissociation of the tetramer is also obtained by dialysis of the protein against 6-M guanidine hydrochloride (GdnHCl) or 1% SDS. The reassembly of these smaller units upon cooling is evident from resonance energy transfer.

The IncP plasmid-encoded cell envelope-associated DNA transfer complex increases cell permeability.

IncP-type plasmids are broad-host-range conjugative plasmids. DNA translocation requires DNA transfer-replication functions and additional factors required for mating pair formation (Mpf). The Mpf system is located in the cell membranes and is responsible for DNA transport from the donor to the recipient. The Mpf complex acts as a receptor for IncP-specific phages such as PRD1. In this investigation, we quantify the Mpf complexes on the cell surface by a phage receptor saturation technique. Electrochemical measurements are used to show that the Mpf complex increases cell envelope permeability to lipophilic compounds and ATP. In addition it reduces the ability of the cells to accumulate K+. However, the Mpf complex does not dissipate the membrane voltage. The Mpf complex is rapidly disassembled when intracellular ATP concentration is decreased, as measured by a PRD1 adsorption assay.

Changes in host cell energetics in response to bacteriophage PRD1 DNA entry.

Double-stranded DNA bacteriophage PRD1 infects a variety of gram-negative bacteria harboring an IncP-type conjugative plasmid. The plasmid codes for the DNA transfer phage receptor complex in the cell envelope. Our goal was, by using a collection of mutant phage particles for which the variables are the DNA content and/or the presence of the receptor-binding protein, to obtain information on the energy requirements for DNA entry as well as on alterations in the cellular energetics taking place during the first stages of infection. We studied the fluxes of tetraphenylphosphonium (TPP+), phenyldicarbaundecaborane (PCB-), and K+ ions as well as ATP through the envelope of Salmonella typhimurium cells. The final level of the membrane voltage (delta psi) indicator TPP+ accumulated by the infected cells exceeds the initial level before the infection. Besides the effects on TPP+ accumulation, PRD1 induces the leakage of ATP and K+ from the cytosol. All these events were induced only by DNA-containing infectious particles and were cellular ATP and delta psi dependent. PRD1-caused changes in delta psi and in PCB- binding differ considerably from those observed in other bacteriophage infections studied. These results are in accordance with the presence of a specific channel engaged in phage PRD1 DNA transport.

Polarized Raman spectroscopy of double-stranded RNA from bacteriophage phi6: local Raman tensors of base and backbone vibrations.

Raman tensors for localized vibrations of base (A, U, G, and C), ribose and phosphate groups of double-stranded RNA have been determined from polarized Raman measurements on oriented fibers of the genomic RNA of bacteriophage phi6. Polarized Raman intensities for which electric vectors of both the incident and scattered light are polarized either perpendicular (I[bb]) or parallel (I[cc]) to the RNA fiber axis have been obtained by Raman microspectroscopy using 514.5-nm excitation. Similarly, the polarized Raman components, I(bc) and I(cb), for which incident and scattered vectors are mutually perpendicular, have been obtained. Spectra collected from fibers maintained at constant relative humidity in both H2O and D2O environments indicate the effects of hydrogen-isotopic shifts on the Raman polarizations and tensors. Novel findings are the following: 1) the intense Raman band at 813 cm(-1), which is assigned to phosphodiester (OPO) symmetrical stretching and represents the key marker of the A conformation of double-stranded RNA, is characterized by a moderately anisotropic Raman tensor; 2) the prominent RNA band at 1101 cm(-1), which is assigned to phosphodioxy (PO2-) symmetrical stretching, also exhibits a moderately anisotropic Raman tensor. Comparison with results obtained previously on A, B, and Z DNA suggests that tensors for localized vibrations of backbone phosphodiester and phosphodioxy groups are sensitive to helix secondary structure and local phosphate group environment; and 3) highly anisotropic Raman tensors have been found for prominent and well-resolved Raman markers of all four bases of the RNA duplex. These enable the use of polarized Raman spectroscopy for the determination of purine and pyrimidine base residue orientations in ribonucleoprotein assemblies. The present determination of Raman tensors for dsRNA is comprehensive and accurate. Unambiguous tensors have been deduced for virtually all local vibrational modes of the 300-1800 cm(-1) spectral interval. The results provide a reliable basis for future evaluations of the effects of base pairing, base stacking, and sequence context on the polarized Raman spectra of nucleic acids.

Assembly of membrane-containing bacteriophage PRD1 is dependent on GroEL and GroES.

Assembly of the broad-host-range bacteriophage PRD1 involves translocation of the virus-specific membrane to the inside of the icosahedral protein shell formed of trimeric coat proteins. The formation of PRD1 particles is, in addition to the virus-encoded assembly factors P10 and P17, dependent on GroEL/GroES chaperonins. The chaperonins assist in the folding of the capsid proteins P3 and P5 and in the assembly of viral membrane proteins.

Probing phage PRD1-specific proteins with monoclonal and polyclonal antibodies.

Four new specificity class MAbs against PRD1 proteins (P6, P7/14, P11, P18) and polyclonal antiserum against the minor capsid protein P5 were produced. The antibodies were used to analyze the phage protein distribution inside the host cell during infection as well as in the virion. The minor component of the capsid, P5, was shown to be located on the surface of the virion. The proteins responsible for particle infectivity were localized to the membrane fraction of the host cells. In addition, by detection with MAbs, genes encoding proteins P14 and P18 were positively localized on the PRD1 genome.

Functional organization of the bacteriophage PRD1 genome.

PRD1 is a broad-host-range virus that infects Escherichia coli cells. It has a linear double-stranded DNA genome that replicates by a protein-primed mechanism. The virus particle is composed of a protein coat enclosing a lipid membrane. On the basis of this structure, PRD1 is being used as a membrane biosynthesis and structure model. In this investigation, we constructed the transcription map of the 15-kb-long phage genome. This was achieved by a computer search of putative promoters, which were then tested for activity by primer extension and for the capability to promote the synthesis of chloramphenicol acetyltransferase.

Topology of the major capsid protein P3 of bacteriophage PRD1: analysis using monoclonal antibodies and C-terminally truncated proteins.

Trimeric capsomeres of protein P3 (395 aa) are the main component of the phage PRD1 capsid, which encloses a lipid-protein vesicle containing the viral dsDNA genome. In this study we characterize a panel of monoclonal antibodies (MAb) against P3. The epitopes recognized by the MAbs are analyzed by immunoprecipitation of intact virions or of released P3 trimers, and by Western blotting using a series of C-terminally truncated P3 molecules. Nine of the MAbs recognize epitopes on the virion surface, whereas five require unmasking of epitopes by disruption of the virions. Several of the MAbs are capable of neutralizing the virus; this is most probably due to virus aggregation by the antibodies. Analysis of the C-terminal truncations (the 6 Western blot-positive MAbs were used) delineates three major antigenic regions of the protein. The epitope of MAb 3T74 is included in the 66 N-terminal amino acids, and is not accessible on the virion surface, suggesting that the N-terminus is internally located in the capsid. MAbs 3N81 and 3R2 recognize epitopes in the region of amino acids 159-168, which is part of the first predicted beta-barrel structure of P3. The third antigenic region is in the second predicted beta-barrel, between amino acids 217-242, where the epitopes of 3N180, 3P4, and 3T5 map. The trimerization of P3 was found to be independent of the non-structural assembly factor proteins P10 and P17. Functional studies of the truncated proteins reveal that molecules comprising of 294 or more residues from the P3 N-terminus are capable of trimer formation.

Binding of an Escherichia coli double-stranded DNA virus PRD1 to a receptor coded by an IncP-type plasmid.

IncP plasmid RP1 Tra regions are needed to assemble the receptor for lipid-containing double-stranded DNA bacteriophage PRD1 on the cell surface. Using radioactively labeled phage and electron microscopic techniques, we showed that the surfaces of Salmonella typhimurium(RP1) and Escherichia coli(RP1) cells contained approximately 50 and 20 PRD1 binding sites, respectively. Expression of the receptor was growth phase dependent and was highest at late logarithmic or early stationary phase. The PRD1-resistant RP1 transposon mutants isolated were all Tra-, and the transposons were located in both the Tra1 and Tra2 regions.

Structural studies of the enveloped dsRNA bacteriophage phi 6 of Pseudomonas syringae by Raman spectroscopy. I. The virion and its membrane envelope.

We report and interpret the first Raman spectrum of a double-stranded RNA virus containing a membrane envelope. Spectra of the native bacteriophage phi 6 and of its isolated host-attachment (spike) protein and phospholipid-free core assembly were collected from aqueous solutions over a wide range of temperature. Comparison of the vibrational spectra by digital difference methods permits the following structural conclusions regarding molecular constituents of the fully assembled virion. (1) The double-stranded RNA, phospholipid and protein components of the phage exhibit Raman amplitudes in accordance with their biochemically determined compositions in the native virion (10, 20 and 70%, respectively). (2) alpha-Helix and irregular conformations are the dominant secondary structures in proteins of both the viral membrane and nucleocapsid. This represents a departure from previously examined icosahedral phage and plant viruses, which are dominated by beta-sheet structures. (3) The phospholipids of the viral membrane are liquid crystalline throughout the determined range of virus thermostability (0 to 40 degrees C). (4) The P3 spike protein of phi 6, which is anchored to, but not sequestered within the viral membrane, is largely alpha-helical (approximately 35%) and highly thermolabile. Denaturation of P3 at temperatures above 30 degrees C leads to appreciable loss (approximately 20%) of alpha-helix in favor of beta-strand structure, and alters significantly the environments of many aromatic side-chains. (5) The secondary structures of integral membrane proteins of phi 6 are overwhelmingly alpha-helical (approximately 70 to 80%) and also thermolabile. In contrast to P3, which exhibits aspartate and glutamate carboxyls in the ionized form (CO2-), the integral membrane proteins exhibit only protonated carboxyl groups (COOH). Treatment of phi 6 with butylated hydroxytoluene (BHT), which has been shown to remove the P3 spike protein, does not significantly perturb phospholipids and associated integral proteins of the viral membrane or structural proteins and packaged double-stranded RNA of the nucleocapsid. However, P3 subunits, which are recovered after BHT treatment, exhibit radically altered secondary and tertiary structures, including the loss of most subunit alpha-helices. Among the P3 side-chains affected by BHT treatment, we note a general trend toward greater hydrophilicity and greater solvent exposure of the aromatic residues Trp and Tyr. On the other hand, the cysteine sulfhydryl groups of the BHT-isolated P3 monomer are not solvent exposed and function as strong hydrogen-bond donors in the protein core.(ABSTRACT TRUNCATED AT 400 WORDS)

Structural studies of the enveloped dsRNA bacteriophage phi 6 of Pseudomonas syringae by Raman spectroscopy. II. Nucleocapsid structure and thermostability of the virion, nucleocapsid and polymerase complex.

Structures and thermostabilities of the double-stranded (ds) RNA bacteriophage phi 6 and of its isolated nucleocapsid-polymerase complex (nucleocapsid core) and dsRNA components have been investigated by Raman spectroscopy. The spectra show that proteins of the phi 6 virion are collectively deficient in beta-sheet secondary structure. In particular, the major protein (P8) of the outer spherical shell of the phi 6 nucleocapsid exhibits a secondary structure dominated largely by alpha-helix and irregular conformations. The absence of appreciable beta-structure in the P8 subunit suggests a tertiary conformation lacking the beta-barrel motif common to subunits of most other spherical viral capsids. In addition, the Raman spectra show that subunits of the dodecahedral nucleocapsid core are also predominantly alpha-helical. The results thus indicate a largely alpha-helical secondary structure for the major subunit (P1) of the phi 6 nucleocapsid core, as well as for the P8 subunit of the outer spherical shell. Using Raman difference spectroscopy, we demonstrate that proteins of the nucleocapsid core (P1, P2, P4 and P7) interact extensively with the packaged phi 6 RNA genome, and further, that conformational stability of the packaged RNA is reduced upon removal from the core. Also, we find that proteins of the phi 6 nucleocapsid are significantly more thermostable than proteins of the viral membrane envelope, which are reported in the accompanying paper (Li et al., 1993). The present results suggest that both the architectural principles and modes of protein-RNA interaction in the phi 6 virion differ fundamentally from those of icosahedral single-stranded RNA viruses. Both Raman and circular dichroism spectra indicate that the dsRNA genome of phi 6 is an A-form structure. The Raman marker bands signify the presence only of C3'-endo/anti nucleoside conformers. The Raman signature of dsRNA, revealed in the spectrum of the phi 6 genome, is discussed here as a model for assessing base-pairing and base-stacking interactions in other ribonucleoprotein assemblies.

Genome organization of membrane-containing bacteriophage PRD1.

We have determined the nucleotide sequence of the late region (11 kbp) of the lipid-containing bacteriophage PRD1. Gene localization was carried out by complementing nonsense phage mutants with genomic clones containing specific reading frames. The localization was confirmed by sequencing the N-termini of isolated gene products as well as sequencing the N-termini of tryptic fragments of the phage membrane-associated proteins. This, with the previously obtained sequence of the early regions, allowed us to organize most of the phage genes in the phage genome.