Comparison of two serologically distinct ribonucleic acid bacteriophages. II. Properties of the nucleic acids and coat proteins

Overby, L. R. (University of Illinois, Urbana), G. H. Barlow, R. H. Doi, Monique Jacob, and S. Spiegelman. Comparison of two serologically distinct ribonucleic acid bacteriophages. II. Properties of the nucleic acids and coat proteins. J. Bacteriol. 92:739-745. 1966.-The ribonucleic acid (RNA) molecules and coat proteins of two RNA coliphages, MS-2 and Qbeta, have been characterized. MS-2 RNA shows an S(20,w) of 25.8 and a molecular weight by light scattering of 10(6). The corresponding parameters for Qbeta-RNA were 28.9 and 0.9 x 10(6). A difference in base composition was reflected in the adenine-uracil ratio, which was 0.95 for MS-2 and 0.75 for Qbeta. The two RNA preparations are readily separated by chromatography on columns of methylated albumin. Both gave identical bouyant densities in cesium sulfate of 1.64 g/ml. The coat protein subunits were of similar molecular weights: 15,500 (Qbeta) and 14,000 (MS-2). They differed, however, in that the Qbeta-protein lacked tryptophan and histidine, whereas the MS-2 protein lacked only histidine.     

Irreversible conversion of the physical state of herpes simplex virus preceding inactivation by thermal or antibody treatment.

The buoyant density characteristics of infectious particles of herpes simplex virus types 1 and 2 were studied by centrifugation in sucrose and cesium chloride density gradients with a high resolution and satisfactory infectivity recovery. It was shown that two populations of infectious virions differing in buoyant density coexisted, the difference being slight but definite. The ratio of heavy (H) to light (L) viral particles varied depending upon the solute used, the strains of virus, and the cell origin. Circumstances favoring degradation of viral infectivity tended to increase the H portion. Incubation at 37 degrees C largely converted L to H, and heating at 45 degrees C converted all virions to H without infectivity. The L to H conversion was irreversible, and no populations intermediate between L and H were clearly observed. Inactivation by UV light irradiation did not affect the density pattern. That H was not an artefact due to penetration of solutes, osmotic pressure, viral aggregation, or loss of the envelope was shown experimentally. A difference in the outer shape of particles between negatively stained L and H populations was demonstrated by electron microscopy. Both cell-released and cell-bound herpes simplex virus particles gave essentially the same result with respect to the above characteristics. The effect of limiting dilutions of antiserum was similar to that of mild thermal treatment, in that denser virions increased parallel to a decrease in less dense virions. Sensitization with early immunoglobulin G, composed mainly of complement-requiring neutralizing antibody, caused the density transition, and subsequent addition of complement resulted in a further increase in the buoyant density of the sensitized virions. The DNA in virus particles neutralized with immunoglobulin G plus complement remained resistant to DNase treatment. Possible implications of the phenomena are discussed.     

Infectious process of the parvovirus H-1: correlation of protein content, particle density, and viral infectivity.

The infectious particles of the parvovirus H-1 were characterized with respect to protein content, density in CsCl, and specific infectivity. Heavy-full and light-full particles were purified from infected simian virus 40-transformed newborn human kidney (NB) cells and from simian virus 40-transformed hamster kidney (THK) cells. Analysis of the protein content of these particles demonstrated that the ratio of viral protein VP2' to VP2 was the same in heavy-full and light-full particles derived from the same cell line, but differed significantly between the two hosts. However, the infectivity of the particles from each cell line was the same for all four viral species.. Also, in vitro conversion of VP2' to VP2 did not enhance the particle infectivity of either heavy-full or light-full virus. When the fate of input virus was studied with 125I-labeled H-1, the conversion of VP2' to VP2 occurred in a time-dependent manner up to 24 h postinfection. Simultaneous with the proteolytic cleavage, there was a shift in the density of the heavy-full virus to the light-full density. However, protein analysis of the 125I-labeled light-full virus at various times postinfection indicated that they were not enriched in VP2 when compared with heavy-full virus or the total virus population. Thus, the cleavage of VP2' to VP2 is not responsible for the shift in density from heavy-full to light-full virus, and although these events might be required for infection they appear not to be interdependent.     

Properties and origins of infectious rhinovirus type 14 particles of different buoyant densities.

Isopycnic centrifugation of rhinovirus type 14 (RV14), purified from infected HeLa or KB cell cultures, into CsCl gradients resolved two bands of infectious virus particles with buoyant density values of 1.409 +/- 0.007 (H virus) and 1.386 +/- 0.004 (L virus) g/ml. Only H virus was detected by incorporation of radiolabeled uridine into viral RNA, and H virus accounted for the majority of infectivity in gradients. H and L virus could not be differentiated by plaque morphology, extent of neutralization by RV14-specific antiserum, or particle size. Electron microscope studies showed that most L-virus particles were associated with an amorphous material. Treatment of L virus with proteolytic enzymes or rebanding L virus in CsCl gradients resulted in recovery of the majority of infectivity as H virus. Virus purified from cell-free fluids from infected HeLa or KB cell cultures banded only as H virus. HeLa cell cultures challenged with purified H virus and harvested at 3 h postinoculation for virus purification yielded only infectious H virus. Both H and L viruses were detected in cell cultures that had been challenged with purified H virus and harvested at 12 h postinoculation. The data suggest that H virus represents progeny virus, whereas L virus represents sequestered infectious virus particles which become associated with an amorphous material and do not enter into viral replicative processes.     

Specific Encapsidation of Nodavirus RNAs Is Mediated through the C Terminus of Capsid Precursor Protein Alpha

Flock house virus (FHV) is a small icosahedral insect virus with a bipartite, messenger-sense RNA genome. Its T=3 icosahedral capsid is initially assembled from 180 subunits of a single type of coat protein, capsid precursor protein alpha (407 amino acids). Following assembly, the precursor particles undergo a maturation step in which the alpha subunits autocatalytically cleave between Asn363 and Ala364. This cleavage generates mature coat proteins beta (363 residues) and gamma (44 residues) and is required for acquisition of virion infectivity. The X-ray structure of mature FHV shows that gamma peptides located at the fivefold axes of the virion form a pentameric helical bundle, and it has been suggested that this bundle plays a role in release of viral RNA during FHV uncoating. To provide experimental support for this hypothesis, we generated mutant coat proteins that carried deletions in the gamma region of precursor protein alpha. Surprisingly, we found that these mutations interfered with specific recognition and packaging of viral RNA during assembly. The resulting particles contained large amounts of cellular RNAs and varying amounts of the viral RNAs. Single-site amino acid substitution mutants showed that three phenylalanines located at positions 402, 405, and 407 of coat precursor protein alpha were critically important for specific recognition of the FHV genome. Thus, in addition to its hypothesized role in uncoating and RNA delivery, the C-terminal region of coat protein alpha plays a significant role in recognition of FHV RNA during assembly. A possible link between these two functions is discussed.     

Complete genome sequence of garlic latent virus,a member of the carlavirus family

The complete genome sequence of the garlic latent virus (GLV) has been determined. The whole GLV genome consists of 8,353 nucleotides, excluding the 3'-end poly(A)+ tail, and contains six open-reading frames (ORFs). Putative proteins that were encoded by the reading frames contain the motifs that were conserved in carlavirus-specific RNA replicases, NTP-dependent DNA helicases, two viral membrane-bound proteins, a viral coat protein, and a zinc-finger. Overall, the GLV genome shows structural features that are common in carlaviruses. An in vitro translation analysis revealed that the zinc-finger protein is not produced as a transframe protein with the coat protein by ribosomal frameshifting. A Northern blot analysis showed that GLV-specific probes hybridized to garlic leaf RNA fragments of about 2.6 and 1.5 kb long, in addition to the 8.5 kb whole genome. The two subgenomic RNAs might be encapsidated into smaller viral particles. In garlic plants, 700 nm long flexuous rod-shaped virus particles were observed in the immunoelectron microscopy using polyclonal antibodies against the GLV coat proteins.     

Secretion of Hepatitis C Virus Envelope Glycoproteins Depends on Assembly of Apolipoprotein B Positive Lipoproteins

The density of circulating hepatitis C virus (HCV) particles in the blood of chronically infected patients is very heterogeneous. The very low density of some particles has been attributed to an association of the virus with apolipoprotein B (apoB) positive and triglyceride rich lipoproteins (TRL) likely resulting in hybrid lipoproteins known as lipo-viro-particles (LVP) containing the viral envelope glycoproteins E1 and E2, capsid and viral RNA. The specific infectivity of these particles has been shown to be higher than the infectivity of particles of higher density. The nature of the association of HCV particles with lipoproteins remains elusive and the role of apolipoproteins in the synthesis and assembly of the viral particles is unknown. The human intestinal Caco-2 cell line differentiates in vitro into polarized and apoB secreting cells during asymmetric culture on porous filters. By using this cell culture system, cells stably expressing E1 and E2 secreted the glycoproteins into the basal culture medium after one week of differentiation concomitantly with TRL secretion. Secreted glycoproteins were only detected in apoB containing density fractions. The E1–E2 and apoB containing particles were unique complexes bearing the envelope glycoproteins at their surface since apoB could be co-immunoprecipitated with E2-specific antibodies. Envelope protein secretion was reduced by inhibiting the lipidation of apoB with an inhibitor of the microsomal triglyceride transfer protein. HCV glycoproteins were similarly secreted in association with TRL from the human liver cell line HepG2 but not by Huh-7 and Huh-7.5 hepatoma cells that proved deficient for lipoprotein assembly. These data indicate that HCV envelope glycoproteins have the intrinsic capacity to utilize apoB synthesis and lipoprotein assembly machinery even in the absence of the other HCV proteins. A model for LVP assembly is proposed.     

Assembly of two independent populations of flock house virus particles with distinct RNA packaging characteristics in the same cell

Flock House virus (FHV; Nodaviridae) is a positive-strand RNA virus that encapsidates a bipartite genome consisting of RNA1 and RNA2. We recently showed that specific recognition of these RNAs for packaging into progeny particles requires coat protein translated from replicating viral RNA. In the present study, we investigated whether the entire assembly pathway, i.e., the formation of the initial nucleating complex and the subsequent completion of the capsid, is restricted to the same pool of coat protein subunits. To test this, coat proteins carrying either FLAG or hemagglutinin epitopes were synthesized from replicating or nonreplicating RNA in the same cell, and the resulting particle population and its RNA packaging phenotype were analyzed. Results from immunoprecipitation analysis and ion-exchange chromatography showed that the differentially tagged proteins segregated into two distinct populations of virus particles with distinct RNA packaging phenotypes. Particles assembled from coat protein that was translated from replicating RNA contained the FHV genome, whereas particles assembled from coat protein that was translated from nonreplicating mRNA contained random cellular RNA. These data demonstrate that only coat proteins synthesized from replicating RNA partake in the assembly of virions that package the viral genome and that RNA replication, coat protein translation, and virion assembly are processes that are tightly coupled during the life cycle of FHV.     

Mechanism of Ozone Inactivation of Bacteriophage f2

The inactivation kinetics of bacteriophage f2 were studied by using ozone under controlled laboratory conditions. The phage were rapidly inactivated during the first 5 s of the reaction by 5 and 7 logs at ozone concentrations of 0.09 and 0.8 mg/liter, respectively. During the next 10 min, the phage were further inactivated at a slower rate in both treatments. The [³H]uridine-labeled f2 phage and its ribonucleic acid (RNA) were examined to elucidate the mechanism of ozone inactivation, utilizing adsorption to host bacteria, sucrose density gradient analysis, and electron microscopy. The specific adsorption of the phage was reduced by ozonation in the same pattern as plaque-forming unit reduction. RNA was released from the phage particles during ozonation, although it had reduced infectivity for spheroplasts. Electron microscopic examination showed that the phage coat was broken by ozonation into many protein subunit pieces and that the specific adsorption of the phage to host pili was inversely related to the extent of phage breakage. The RNA enclosed in the phage coat was inactivated less by ozonation than were whole phage, but inactivated more than naked RNA. These findings suggest that ozone breaks the protein capsid into subunits, liberating RNA and disrupting adsorption to the host pili, and that the RNA may be secondarily sheared by a reduction with and/or without the coat protein molecules, which have been modified by ozonation.     

Use of recombinant baculoviruses in synthesis of morphologically distinct viruslike particles of flock house virus, a nodavirus.

Flock house virus (FHV) is a small icosahedral insect virus of the family Nodaviridae. Its genome consists of two messenger-sense RNA molecules, both of which are encapsidated in the same particle. RNA1 (3.1 kb) encodes proteins required for viral RNA replication; RNA2 (1.4 kb) encodes protein alpha (43 kDa), the precursor of the coat protein. When Spodoptera frugiperda cells were infected with a recombinant baculovirus containing a cDNA copy of RNA2, coat protein alpha assembled into viruslike precursor particles (provirions) that matured normally by autocatalytic cleavage of protein alpha into polypeptide chains beta (38 kDa) and gamma (5 kDa). The particles were morphologically indistinguishable from authentic FHV and contained RNA derived from the coat protein message. These results showed that RNA1 was required neither for virion assembly nor for maturation of provirions. Expression of mutants in which Asn-363 at the beta-gamma cleavage site of protein alpha was replaced by either aspartate, threonine, or alanine resulted in assembly of particles that were cleavage defective. For two of the mutants, unusual structural features were observed after preparation for electron microscopy. Particles containing Asp at position 363 were labile and showed a strong tendency to break into half-shells. Particles in which Asn-363 was replaced by Ala displayed a distinct hole in an otherwise complete shell. The third mutant, containing Thr at position 363, was indistinguishable in morphology from authentic FHV.     

Comparison of two serologically distinct ribonucleic acid bacteriophages. I. Properties of the viral particles

Overby, L. R. (University of Illinois, Urbana), G. H. Barlow, R. H. Doi, Monique Jacob, and S. Spiegelman. Comparison of two serologically distinct ribonucleic acid bacteriophages. I. Properties of the viral particle. J. Bacteriol. 91:442-448. 1966.-Two ribonucleic acid (RNA) coliphages, MS-2 and Qbeta, have been characterized physically and serologically. MS-2 has an S(20, w) value of 79, a molecular weight of 3.6 x 10(6), a density of 1.422, and pH 3.9 as its isoelectric point. Qbeta has an S(20, w) of 84, a molecular weight of 4.2 x 10(6), a density of 1.439, and an isoelectric point at pH 5.3. One host (Escherichia coli A-19) permits a distinction between the two on the basis of a marked difference in plaque size. They are distinct immunochemically, no serological cross-reaction being detectable.     

The double-stranded RNA genome of yeast virus L-A encodes its own putative RNA polymerase by fusing two open reading frames

The L-A double-stranded RNA virus of Saccharomyces cerevisiae encodes its major coat protein (80 kDa) and a minor single-stranded RNA binding protein (180 kDa) that has immunological cross-reactivity with the major coat protein. The sequence of L-A cDNA clones revealed two open reading frames (ORF), ORF1 and ORF2. These two reading frames overlap by 130 base pairs and ORF2 is in the -1 reading frame with respect to ORF1. Although the major coat protein of the viral particles is encoded by ORF1, the 180-kDa protein is derived from the entire double-stranded RNA genome by fusing ORF1 and ORF2, probably by a -1 translational frameshift. Within the overlapping region is a sequence similar to that producing a -1 frameshift by "simultaneous slippage" in retroviruses. The coding sequence of ORF2 shows a pattern characteristic of viral RNA-dependent RNA polymerases of icosahedral (+)-strand RNA viruses. Thus, the 180-kDa protein is analogous to gag-pol fusion proteins.     

Serological Relatedness of the Ribonucleic Acid-Containing Coliphages

The serological relationship of the ribonucleic acid (RNA)-containing coliphages MS-2, M-12, R-17, f₂, β, fr, f₄, and Qβ was determined. Antisera against MS-2, R-17, f₂, fr, and Qβ neutralized the infectivity of all of these RNA phages to varying degrees. Although each phage was serologically distinct, the antisera cross-reacted with certain phages to approximately the same degree, indicating the antigenic relationship of the coat proteins of these phages. Adsorption of anti-MS-2 sera with varying concentrations of all of the phages demonstrated that these viruses contain similar yet unique antigenic determinants. It is suggested that these RNA phages are mutants of two related phages rather than of the same phage.     

Effect of Ultraviolet Light on Mengovirus: Formation of Uracil Dimers, Instability and Degradation of Capsid, and Covalent Linkage of Protein to Viral RNA

UV irradiation of purified mengovirus resulted in a very rapid inactivation of the infectivity of the virions (D(37) [37% survival dose] = 700 ergs/mm(2)) which correlated in time with the formation of uracil dimers in the viral RNA. During the first 2 min of irradiation, an average of 1.7 uracil dimers were formed per PFU of virus inactivated. Hemagglutination activity of the virions began to decrease only after a lag period of about 5 min and at a much lower rate (D(37) = 84,000 ergs/mm(2)). This decrease coincided in time with the appearance of altered proteins in the capsid and a structural change in the capsid. Although 10- to 20-min irradiated virions appeared intact in the electron microscope and sedimented at 150S in sucrose density gradients, the RNA of the virions became accessible to RNase and extractable by low concentrations of sodium dodecyl sulfate, and the virions broke down upon equilibrium centrifugation in CsCl gradients. During longer periods of irradiation (30 to 60 min), a progressively greater proportion of the virions were converted to 14S protein particles and 80S ribonucleoprotein particles composed of intact viral RNA and about 30% of the capsid proteins, alpha, beta, and gamma. Empty capsids were not detectable at any time during 60 min of irradiation, by which time disruption of the virions was complete. Irradiation of complete virions also resulted in an increased sedimentation rate of the viral RNA and in the covalent linkage to the viral RNA of about 1% of the total capsid protein in the form of heterogeneous low-molecular-weight polypeptides. The two observations seem to be causally related, since irradiation of isolated viral RNA did not result in an increase in sedimentation rate of the RNA, even though uracil dimer formation in viral RNA occurred at about the same rate and to the same extent whether intact virions or viral RNA were irradiated.     

The effect of proteolytic cleavage of potato virus X coat protein on its ability to self-assemble with RNA and viral infectivity

The process of proteolytic cleavage of potato virus X coat protein molecules inside the virions and in the dissociated state in the course of their purification and storage has been studied. In agreement with the previous reports, the intact form (Ps) of the coat protein in the viral particles was found to be gradually cleaved to three discrete lower molecular forms (Pi, Pf, Pu). During the storage of the dissociated coat protein preparations further cleavage was observed with formation of at least three additional lower molecular weight forms (Ppa, Ppb, Ppc). The location of proteolytic cleavage sites leading to formation of Ppa form was determined. The shortened forms Pi, Pf, Pu and Ppa (and possibly Ppc) were found to be incorporated into the viral particles in the course of reconstitution in vitro with the viral RNA. Infectivity of the virus containing only intact (Ps) form of the protein was found to be two to three folds higher than that of the virus containing only Pf form of the coat protein.     

Monitoring of S Protein Maturation in the Endoplasmic Reticulum by Calnexin Is Important for the Infectivity of Severe Acute Respiratory Syndrome Coronavirus

Severe acute respiratory syndrome coronavirus (SARS-CoV) is the etiological agent of SARS, a fatal pulmonary disorder with no effective treatment. We found that SARS-CoV spike glycoprotein (S protein), a key molecule for viral entry, binds to calnexin, a molecular chaperone in the endoplasmic reticulum (ER), but not to calreticulin, a homolog of calnexin. Calnexin bound to most truncated mutants of S protein, and S protein bound to all mutants of calnexin. Pseudotyped virus carrying S protein (S-pseudovirus) produced by human cells that were treated with small interfering RNA (siRNA) for calnexin expression (calnexin siRNA-treated cells) showed significantly lower infectivity than S-pseudoviruses produced by untreated and control siRNA-treated cells. S-pseudovirus produced by calnexin siRNA-treated cells contained S protein modified with N-glycan side chains differently from other two S proteins and consisted of two kinds of viral particles: those of normal density with little S protein and those of high density with abundant S protein. Treatment with peptide-N-glycosidase F (PNGase F), which removes all types of N-glycan side chains from glycoproteins, eliminated the infectivity of S-pseudovirus. S-pseudovirus and SARS-CoV produced in the presence of α-glucosidase inhibitors, which disrupt the interaction between calnexin and its substrates, showed significantly lower infectivity than each virus produced in the absence of those compounds. In S-pseudovirus, the incorporation of S protein into viral particles was obviously inhibited. In SARS-CoV, viral production was obviously inhibited. These findings demonstrated that calnexin strictly monitors the maturation of S protein by its direct binding, resulting in conferring infectivity on SARS-CoV.     

Virus-like particles of potato leafroll virus as potential carrier system for nucleic acids

Potato leafroll virus is a member of the polerovirus genus. The isometric virion is formed by a coat protein encapsidating single-stranded, positive-sense, mono-partite genomic RNA with covalently attached viral protein at the 5' end. The coat protein of the virus exists in two forms: i) a 23 kDa protein, the product of the coat protein gene, and ii) a 78 kDa protein, the product of the coat protein gene and an additional open reading frame expressed by read-through of the coat protein gene stop codon. The aim of this work was the expression of potato leafroll virus coat protein-based proteins that would be able to assemble into virus-like particles in insect cells. These modified particles were tested for their ability to encapsidate nucleic acids. Two types of N-terminally His-tagged coat protein constructs were used for the expression in insect cells: one, encoding a 23 kDa protein with the C-terminal amino-acid sequence corresponding to the wild type coat protein and the second with additional clathrin binding domain at the C-terminus. The expression of these two proteins by a recombinant baculovirus was characterized by Western immunoblotting with antibodies directed against potato leafroll virus. The protection or putative encapsidation of nucleic acids by these two coat protein derivatives was shown by DNase I and RNase A protection assays.     

Mutations in Rous sarcoma virus nucleocapsid protein p12 (NC): deletions of Cys-His boxes.

Rous sarcoma virus nucleocapsid protein p12 (NC) contains two conserved amino acid motifs, the Cys-His boxes, which constitute potential metal-binding domains. To try to understand the function of NC and of each of its Cys-His boxes during the viral life cycle, particularly in viral RNA packaging, we have used synthetic oligonucleotides to delete precisely either the proximal or the distal box, or both Cys-His boxes. The mutant DNAs were transfected into chicken embryo fibroblasts, and the virions produced in a transient assay were characterized biochemically for production of viral proteins and particles, RNA packaging, and infectivity. The results indicated the following. (i) The deletion of either the proximal or the distal box decreases the amount of viral RNA packaged in the particles and results in incomplete 70S dimer formation. (ii) The deletion of both boxes inhibits viral RNA packaging. (iii) The deletion of the proximal, but not the distal, box suppresses any detectable infectivity, while the deletion of the distal, but not the proximal, box lowers infectivity 100 to 200 times.     

Defective bacteriophage MS2 particles containing specific RNA FRAGMENTS]

Two types of MS2 particle are revealed when phage lysates are banded in CsCl density gradient. The lower band contain normal phage particles with a density of 1.46 g/cm3. The upper band with a density of 1.44 g/cm3 containes uninfective incomplete MS2 particles. Both phage types reveal no abnormalities in the content of the coat protein and A-protein. They are nearly identical in RNA content. RNA in the normal buoyant density phage particles is native. RNA in the defective particles consists of three specific fragments with molecular weights 6.5-10(5), 5.5-10(5) and 4.4-10(5) and molar ratios 5:4:9 respectively. THE 5'-TERMINAL ANALYSIS OF RNA from defective MS2 particles reveals the presence of native pppGp. THE 3'-TERMINAL ANALYSIS OF THE INDIVIDUAL RNA fragments reveals the presence of adenosine only in the shortest fragment. RNA fragmentation in defective particles can be explained by the action of intracellular RNAses on the unprotected regions on RNA chain in structurally incomplete virions.