Characterization of subunit-specific interactions in a double-stranded RNA virus: Raman difference spectroscopy of the phi6 procapsid

The icosahedral core of a double-stranded (ds) RNA virus hosts RNA-dependent polymerase activity and provides the molecular machinery for RNA packaging. The stringent requirements of dsRNA metabolism may explain the similarities observed in core architecture among a broad spectrum of dsRNA viruses, from the mammalian rotaviruses to the Pseudomonas bacteriophage phi6. Although the structure of the assembled core has been described in atomic detail for Reoviridae (blue tongue virus and reovirus), the molecular mechanism of assembly has not been characterized in terms of conformational changes and key interactions of protein constituents. In the present study, we address such questions through the application of Raman spectroscopy to an in vitro core assembly system--the procapsid of phi6. The phi6 procapsid, which comprises multiple copies of viral proteins P1 (copy number 120), P2 (12), P4 (72), and P7 (60), represents a precursor of the core that is devoid of RNA. Raman signatures of the procapsid, its purified recombinant core protein components, and purified sub-assemblies lacking either one or two of the protein components have been obtained and interpreted. The major procapsid protein (P1), which forms the skeletal frame of the core, is an elongated and monomeric molecule of high alpha-helical content. The fold of the core RNA polymerase (P2) is also mostly alpha-helical. On the other hand, the folds of both the procapsid accessory protein (P7) and RNA-packaging ATPase (P4) are of the alpha/beta type. Raman difference spectra show that conformational changes occur upon interaction of P1 with either P4 or P7 in the procapsid. These changes involve substantial ordering of the polypeptide backbone. Conversely, conformations of procapsid subunits are not significantly affected by interactions with P2. An assembly model is proposed in which P1 induces alpha-helix in P4 during formation of the nucleation complex. Subsequently, the partially disordered P7 subunit is folded within the context of the procapsid shell.     

Thermodynamic characterization of viral procapsid expansion into a functional capsid shell

The assembly of "complex" DNA viruses such as the herpesviruses and many tailed bacteriophages includes a DNA packaging step where the viral genome is inserted into a preformed procapsid shell. Packaging triggers a remarkable capsid expansion transition that results in thinning of the shell and an increase in capsid volume to accept the full-length genome. This transition is considered irreversible; however, here we demonstrate that the phage λ procapsid can be expanded with urea in vitro and that the transition is fully reversible. This provides an unprecedented opportunity to evaluate the thermodynamic features of this fascinating and essential step in virus assembly. We show that urea-triggered expansion is highly cooperative and strongly temperature dependent. Thermodynamic analysis indicates that the free energy of expansion is influenced by magnesium concentration (3-13?kcal/mol in the presence of 0.2-10?mM Mg(2+)) and that significant hydrophobic surface area is exposed in the expanded shell. Conversely, Mg(2+) drives the expanded shell back to the procapsid conformation in a highly cooperative transition that is also temperature dependent and strongly influenced by urea. We demonstrate that the gpD decoration protein adds to the urea-expanded capsid, presumably at hydrophobic patches exposed at the 3-fold axes of the expanded capsid lattice. The decorated capsid is biologically active and sponsors packaging of the viral genome in vitro. The roles of divalent metal and hydrophobic interactions in controlling packaging-triggered expansion of the procapsid shell are discussed in relation to a general mechanism for DNA-triggered procapsid expansion in the complex double-stranded DNA viruses.     

Assembly of double-stranded RNA viruses: bacteriophage ø6 and yeast virus L-A

Double-stranded RNA viruses have a virion-associated RNA-dependent RNA polymerase activity which is involved in such critical steps of viral assembly as genome packaging and minus strand synthesis. In vitro studies of a bacterial dsRNA virus, ø6, and a yeast virus, L-A, have shed light on capsid formation as well as on the protein/RNA interactions and packaging of the viral genomes. In the ø6 system, an empty dodecahedral polymerase complex (procapsid) composed of four protein species is formed without the help of other viral proteins or RNA. This particle packages positive sense viral RNA genome segments in an ATP dependent reaction. The presence of all rNTPs allows the synthesis of complementary (-) strands within the particle. Self-assembly of an additional protein shell (composed of protein P8) around this particle takes place in the presence of Ca²⁺ ions. In vivo, these nucleocapsids obtain an envelope while still residing in the cell cytoplasm. L-A, in contrast, is not known to make a prohead structure. The Pol domain of L-A's Gag-Pol fusion protein is necessary for packaging of the (+) strand RNA and probably actually binds to the (+) strand packaging site (a stem-loop with a protruding A) insuring its packaging while the Gag domain primes polymerization of the coat protein. N-Acetylation of Gag by the host MAK3 N-acetyltransferase is necessary for proper assembly, and the ratio of Gag-Pol/Gag, determined by the efficiency of - 1 ribosomal frameshifting, is critical for propagation of the M₁ satellite dsRNA.     

Bacteriophage ϕ6 nucleocapsid surface protein 8 interacts with virus-specific membrane vesicles containing major envelope protein 9

Enveloped double-stranded RNA (dsRNA) bacterial virus Pseudomonas phage ϕ6 has been developed into an advanced assembly system where purified virion proteins and genome segments self-assemble into infectious viral particles, inferring the assembly pathway. The most intriguing step is the membrane assembly occurring inside the bacterial cell. Here, we demonstrate that the middle virion shell, made of protein 8, associates with the expanded viral core particle and the virus-specific membrane vesicle.     

Dynamics of herpes simplex virus capsid maturation visualized by time-lapse cryo-electron microscopy

The capsid of the herpes simplex virus initially assembles as a procapsid that matures through a massive conformational change of its 182 MDa surface shell. This transition, which stabilizes the fragile procapsid, is facilitated by the viral protease that releases the interaction between the shell and the underlying scaffold; however, protease-deficient procapsids mature slowly in vitro. To study procapsid maturation as a time-resolved process, we monitored this reaction by cryo-electron microscopy (cryo-EM). The resulting images were sorted into 17 distinct classes, and three-dimensional density maps were calculated for each. When arranged in a chronological series, these maps yielded molecular movies of procapsid maturation. A single major switching event takes place at stages 8-9, preceded by relatively subtle adjustments in the pattern of interactions and followed by similarly small 'aftershocks'. The primary mechanism underlying maturation is relative rotations of domains of VP5, the major capsid protein.     

Assembly of the herpes simplex virus procapsid from purified components and identification of small complexes containing the major capsid and scaffolding proteins

An in vitro system is described for the assembly of herpes simplex virus type 1 (HSV-1) procapsids beginning with three purified components, the major capsid protein (VP5), the triplexes (VP19C plus VP23), and a hybrid scaffolding protein. Each component was purified from insect cells expressing the relevant protein(s) from an appropriate recombinant baculovirus vector. Procapsids formed when the three purified components were mixed and incubated for 1 h at 37 degrees C. Procapsids assembled in this way were found to be similar in morphology and in protein composition to procapsids formed in vitro from cell extracts containing HSV-1 proteins. When scaffolding and triplex proteins were present in excess in the purified system, greater than 80% of the major capsid protein was incorporated into procapsids. Sucrose density gradient ultracentrifugation studies were carried out to examine the oligomeric state of the purified assembly components. These analyses showed that (i) VP5 migrated as a monomer at all of the protein concentrations tested (0.1 to 1 mg/ml), (ii) VP19C and VP23 migrated together as a complex with the same heterotrimeric composition (VP19C1-VP232) as virus triplexes, and (iii) the scaffolding protein migrated as a heterogeneous mixture of oligomers (in the range of monomers to approximately 30-mers) whose composition was strongly influenced by protein concentration. Similar sucrose gradient analyses performed with mixtures of VP5 and the scaffolding protein demonstrated the presence of complexes of the two having molecular weights in the range of 200,000 to 600,000. The complexes were interpreted to contain one or two VP5 molecules and up to six scaffolding protein molecules. The results suggest that procapsid assembly may proceed by addition of the latter complexes to regions of growing procapsid shell. They indicate further that procapsids can be formed in vitro from virus-encoded proteins only without any requirement for cell proteins.     

Biological and biochemical properties of the small viral RNA(pRNA) essential for the packaging of the dsDNA of phage ø29

The genome of the lineal double-stranded DNA viruses of both prokaryotes and eukaryotes is packaged into a preformed procapsid during maturation. Common features exist in this step of the viral life cycle. Bacteriophage ø29 is an ideal model in this study because its DNA can be efficiently packaged in vitro with all components overproduced and purified. An exciting aspect is the discovery that a small viral RNA (pRNA) encoded by ø29 has a novel and essential role in viral DNA packaging. This pRNA is not a structural component of the mature virion, nor is it required for the assembly of the procapsid. The discovery of pRNA as a non-protein participant in viral DNA packaging extends previously demonstrated RNA functions.     

Assembly and Maturation of the Bacteriophage Lambda Procapsid: gpC Is the Viral Protease

Viral capsids are robust structures designed to protect the genome from environmental insults and deliver it to the host cell. The developmental pathway for complex double-stranded DNA viruses is generally conserved in the prokaryotic and eukaryotic groups and includes a genome packaging step where viral DNA is inserted into a pre-formed procapsid shell. The procapsids self-assemble from monomeric precursors to afford a mature icosahedron that contains a single “portal” structure at a unique vertex; the portal serves as the hole through which DNA enters the procapsid during particle assembly and exits during infection. Bacteriophage λ has served as an ideal model system to study the development of the large double-stranded DNA viruses. Within this context, the λ procapsid assembly pathway has been reported to be uniquely complex involving protein cross-linking and proteolytic maturation events. In this work, we identify and characterize the protease responsible for λ procapsid maturation and present a structural model for a procapsid-bound protease dimer. The procapsid protease possesses autoproteolytic activity, it is required for degradation of the internal “scaffold” protein required for procapsid self-assembly, and it is responsible for proteolysis of the portal complex. Our data demonstrate that these proteolytic maturation events are not required for procapsid assembly or for DNA packaging into the structure, but that proteolysis is essential to late steps in particle assembly and/or in subsequent infection of a host cell. The data suggest that the λ-like proteases and the herpesvirus-like proteases define two distinct viral protease folds that exhibit little sequence or structural homology but that provide identical functions in virus development. The data further indicate that procapsid assembly and maturation are strongly conserved in the prokaryotic and eukaryotic virus groups.     

The bacteriophage lambda gpNu3 scaffolding protein is an intrinsically disordered and biologically functional procapsid assembly catalyst

Procapsid assembly is a process whereby hundreds of copies of a major capsid protein assemble into an icosahedral protein shell into which the viral genome is packaged. The essential features of procapsid assembly are conserved in both eukaryotic and prokaryotic complex double-stranded DNA viruses. Typically, a portal protein nucleates the co-polymerization of an internal scaffolding protein and the major capsid protein into an icosahedral capsid shell. The scaffolding proteins are essential to procapsid assembly. Here, we describe the solution-based biophysical and functional characterization of the bacteriophage lambda (λ) scaffolding protein gpNu3. The purified protein possesses significant α-helical structure and appears to be partially disordered. Thermally induced denaturation studies indicate that secondary structures are lost in a cooperative, apparent two-state transition (T_m = 40.6 ± 0.3 °C) and that unfolding is, at least in part, reversible. Analysis of the purified protein by size-exclusion chromatography suggests that gpNu3 is highly asymmetric, which contributes to an abnormally large Stokes radius. The size-exclusion chromatography data further indicate that the protein self-associates in a concentration-dependent manner. This was confirmed by analytical ultracentrifugation studies, which reveal a monomer-dimer equilibrium (K_d,app ~ 50 μM) and an asymmetric protein structure at biologically relevant concentrations. Purified gpNu3 promotes the polymerization of gpE, the λ major capsid protein, into virus-like particles that possess a native-like procapsid morphology. The relevance of this work with respect to procapsid assembly in the complex double-stranded DNA viruses is discussed.     

Purification and organization of the gene 1 portal protein required for phage P22 DNA packaging

The gene 1 protein of Salmonella bacteriophage P22 is located at the DNA packaging vertex of the mature particle. The protein is incorporated into the procapsid shell during shell assembly and is required for DNA packaging. The unassembled precursor form of the gene 1 protein has been purified from cells infected with mutants blocked in procapsid assembly. The purified 90,000-dalton protein was dimeric or monomeric; upon storage in the cold it formed 20S cyclic dodecamers. Computer filtering of negatively stained electron micrographs revealed 12 arms and knobs projecting from a central ring, with a 30-A channel at the center. Similar dodecameric rings were released from disrupted procapsid shells. These results indicate that the gene 1 protein is organized as a cyclic dodecamer within the procapsid shell and serves as the portal through which P22 DNA is threaded during DNA packaging. The presence of a 12-fold ring located at a 5-fold portal vertex appears to be a conserved structural theme of the DNA packaging apparatus of double-stranded DNA phages.     

Approaches to determine stoichiometry of viral assembly components.

Due to the rapidity of biological reactions, it is difficult to isolate intermediates or to determine the stoichiometry of participants in intermediate reactions. Instead of determining the absolute amount of each component, this study involved the use of relative parameters, such as dilution factors, percentages probabilities, and slopes of titration curves, that can be more accurately quantified to determine the stoichiometry of components involved in bacteriophage phi29 assembly. This work takes advantage of the sensitive in vitro phage phi29 assembly system, in which 10(8) infectious virions per ml without background can be assembled from eight purified components. It provides a convenient assay for quantification of the stoichiometry of packaging components, including the viral procapsid, genomic DNA, DNA-packaging pRNA, and other structural proteins and enzymes. The presence of a procapsid binding domain and another essential functional domain within the pRNA makes it an ideal component for constructing lethal mutants for competitive procapsid binding. Two methods were used for stoichiometry determination. Method 1 was to determine the combination probability of mutant and wild-type pRNAs bound to procapsids. The probability of procapsids that possess a certain amount of mutant and a certain amount of wild-type pRNA, both with an equal binding affinity, was predicted with the binomial equation [EQUATION IN TEXT] where Z is the total number of pRNAs per procapsid, M is the number of mutant pRNAs bound to one procapsid, and (ZM) is equal to [FORMULA IN TEXT]. With various ratios of mutant to wild-type pRNA in in vitro viral assembly, the percent mutant pRNA versus the yield of virions was plotted and compared to a series of predicted curves to find a best fit. It was determined that five or six copies of pRNA were required for one DNA-packaging event, while only one mutant pRNA per procapsid was sufficient to block packaging. Method 2 involved the comparison of slopes of curves of dilution factors versus the yield of virions. Components with known stoichiometries served as standard controls. The larger the stoichiometry of the component, the more dramatic the influence of the dilution factor on the reaction. A slope of 1 indicates that one copy of the component is involved in the assembly of one virion. A slope larger than 1 would indicate multiple-copy involvement. By this method, the stoichiometry of gp11 in phi29 particles was determined to be approximately 12. These approaches are useful for the determination of the stoichiometry of functional units involved in viral assembly, be they single molecules or oligomers. However, these approaches are not suitable for the determination of exact copy numbers of individual molecules involved if the functional unit is composed of multiple subunits prior to assembly.     

A conformational switch in bacteriophage p22 portal protein primes genome injection

Double-stranded DNA (dsDNA) viruses such as herpesviruses and bacteriophages infect by delivering their genetic material into cells, a task mediated by a DNA channel called "portal protein." We have used electron cryomicroscopy to determine the structure of bacteriophage P22 portal protein in both the procapsid and mature capsid conformations. We find that, just as the viral capsid undergoes major conformational changes during virus maturation, the portal protein switches conformation from a procapsid to a mature phage state upon binding of gp4, the factor that initiates tail assembly. This dramatic conformational change traverses the entire length of the DNA channel, from the outside of the virus to the inner shell, and erects a large dome domain directly above the DNA channel that binds dsDNA inside the capsid. We hypothesize that this conformational change primes dsDNA for injection and directly couples completion of virus morphogenesis to a new cycle of infection.     

A Pseudo-Atomic Model for the Capsid Shell of Bacteriophage Lambda Using Chemical Cross-Linking/Mass Spectrometry and Molecular Modeling

Bacteriophage lambda is one of the most exhaustively studied of the double-stranded DNA viruses. Its assembly pathway is highly conserved among the herpesviruses and many of the bacteriophages, making it an excellent model system. Despite extensive genetic and biophysical characterization of many of the lambda proteins and the assembly pathways in which they are implicated, there is a relative dearth of structural information on many of the most critical proteins involved in lambda assembly and maturation, including that of the lambda major capsid protein. Toward this end, we have utilized a combination of chemical cross-linking/mass spectrometry and computational modeling to construct a pseudo-atomic model of the lambda major capsid protein as a monomer, as well as in the context of the assembled procapsid shell. The approach described here is generalizable and can be used to provide structural models for any biological complex of interest. The procapsid structural model is in good agreement with published biochemical data indicating that procapsid expansion exposes hydrophobic surface area and that this serves to nucleate assembly of capsid decoration protein, gpD. The model further implicates additional molecular interactions that may be critical to the assembly of the capsid shell and for the stabilization of the structure by the gpD decoration protein.     

Regulation of coat protein polymerization by the scaffolding protein of bacteriophage P22.

In the morphogenesis of double stranded DNA phages, a precursor protein shell empty of DNA is first assembled and then filled with DNA. The assembly of the correctly dimensioned precursor shell (procapsid) of Salmonella bacteriophage P22 requires the interaction of some 420 coat protein subunits with approximately 200 scaffolding protein subunits to form a double shelled particle with the scaffolding protein on the inside. In the course of DNA packaging, all of the scaffolding protein subunits exit from the procapsid and participate in further rounds of procapsid assembly (King and Casjens. 1974. Nature (Lond.). 251:112-119). To study the mechanism of shell assembly we have purified the coat and scaffolding protein subunits by selective dissociation of isolated procapsids. Both proteins can be obtained as soluble subunits in Tris buffer at near neutral pH. The coat protein sedimented in sucrose gradients as a roughly spherical monomer, while the scaffolding protein sedimented as if it were an elongated monomer. When the two proteins were mixed together in 1.5 M guanidine hydrochloride and dialyzed back to buffer at room temperature, procapsids formed which were very similar in morphology, sedimentation behavior, and protein composition to procapsids formed in vivo. Incubation of either protein alone under the same conditions did not yield any large structures. We interpret these results to mean that the assembly of the shell involves a switching of both proteins from their nonaggregating to their aggregating forms through their mutual interaction. The results are discussed in terms of the general problem of self-regulated assembly and the control of protein polymerization in morphogenesis.     

Scaffolding protein regulates the polymerization of P22 coat subunits into icosahedral shells in vitro

Coat and scaffolding subunits derived from P22 procapsids have been purified in forms that co-assemble rapidly and efficiently into icosahedral shells in vitro under native conditions. The half-time for this reaction is approximately five minutes at 21 degrees C. The in vitro reaction exhibits the regulated features observed in vivo. Neither coat nor scaffolding subunits alone self-assemble into large structures. Upon mixing the subunits together they polymerize into procapsid-like shells with the in vivo coat and scaffolding protein composition. The subunits in the purified coat protein preparations are monomeric. The scaffolding subunits appear to be monomeric or dimeric. These results confirm that P22 procapsid formation does not proceed through the assembly of a core of scaffolding, which then organizes the coat, but requires copolymerization of coat and scaffolding. To explore the mechanisms of the control of polymerization, shell assembly was examined as a function of the input ratio of scaffolding to coat subunits. The results indicated that scaffolding protein was required for both initiation of shell assembly and continued polymerization. Though procapsids produced in vivo contain about 300 molecules of scaffolding, shells with fewer subunits could be assembled down to a lower limit of about 140 scaffolding subunits per shell. The overall results of these experiments indicate that coat and scaffolding subunits must interact in both the initiation and the growth phases of shell assembly. However, it remains unclear whether during growth the coat and scaffolding subunits form a mixed oligomer prior to adding to the shell or whether this occurs at the growing edge.     

Characterization of subunit structural changes accompanying assembly of the bacteriophage P22 procapsid

P22 serves as a model for the assembly and maturation of icosahedral double-stranded DNA viruses. The viral capsid precursor, or procapsid, is assembled from 420 copies of a 47 kDa coat protein subunit (gp5) that is rich in beta-strand secondary structure. Maturation to the capsid, which occurs in vivo upon DNA packaging, is accompanied by shell expansion and a large increase in the level of protection against deuterium exchange of amide NH groups. Accordingly, shell maturation resembles the final step in protein folding, wherein domain packing and an exchange-protected core become more fully developed [Tuma, R., Prevelige, P. E., Jr., and Thomas, G. J., Jr. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 9885-9890]. Here, we exploit recent advances in Raman spectroscopy to investigate the P22 coat protein subunit under conditions which stabilize the monomeric state, viz., in solution at very low concentrations. Under these conditions, the monomer exhibits an elongated shape, as demonstrated by small-angle X-ray scattering. Raman spectra allow the identification of conformation-sensitive marker bands of the monomer, as well as the characterization of NH exchange dynamics for comparison with procapsid and capsid shell assemblies. We show that procapsid assembly involves significant ordering of the predominantly beta-strand backbone. We propose that such ordering may mediate formation of the distinct subunit conformations required for assembly of a T = 7 icosahedral lattice. However, the monomer, like the subunit within the procapsid lattice, exhibits a moderate level of protection against low-temperature NH exchange, indicative of a nascent folding core. The environments and exchange characteristics of key side chains are also similar for the monomeric and procapsid subunits, and distinct from corresponding characteristics of the capsid subunit. The monomer thus represents a compact but metastable folding intermediate along the pathway to assembly of the procapsid and capsid.