Survival of MS2 and Φ6 viruses in droplets as a function of relative humidity, pH, and salt, protein, and surfactant concentrations.

The survival of viruses in droplets is known to depend on droplets' chemical composition, which may vary in respiratory fluid between individuals and over the course of disease. This relationship is also important for understanding the persistence of viruses in droplets generated from wastewater, freshwater, and seawater. We investigated the effects of salt (0, 1, and 35 g/L), protein (0, 100, and 1000 µg/mL), surfactant (0, 1, and 10 µg/mL), and droplet pH (4.0, 7.0, and 10.0) on the viability of viruses in 1-µL droplets pipetted onto polystyrene surfaces and exposed to 20%, 50%, and 80% relative humidity (RH) using a culture-based approach. Results showed that viability of MS2, a non-enveloped virus, was generally higher than that of Φ6, an enveloped virus, in droplets after 1 hour. The chemical composition of droplets greatly influenced virus viability. Specifically, the survival of MS2 was similar in droplets at different pH values, but the viability of Φ6 was significantly reduced in acidic and basic droplets compared to neutral ones. The presence of bovine serum albumin protected both MS2 and Φ6 from inactivation in droplets. The effects of sodium chloride and the surfactant sodium dodecyl sulfate varied by virus type and RH. Meanwhile, RH affected the viability of viruses as shown previously: viability was lowest at intermediate to high RH. The results demonstrate that the viability of viruses is determined by the chemical composition of carrier droplets, especially pH and protein content, and environmental factors. These findings emphasize the importance of understanding the chemical composition of carrier droplets in order to predict the persistence of viruses contained in them.

Genome packaging in multi-segmented dsRNA viruses: distinct mechanisms with similar outcomes.

Segmented double-stranded (ds)RNA viruses share remarkable similarities in their replication strategy and capsid structure. During virus replication, positive-sense single-stranded (+)RNAs are packaged into procapsids, where they serve as templates for dsRNA synthesis, forming progeny particles containing a complete equimolar set of genome segments. How the +RNAs are recognized and stoichiometrically packaged remains uncertain. Whereas bacteriophages of the Cystoviridae family rely on specific RNA-protein interactions to select appropriate +RNAs for packaging, viruses of the Reoviridae instead rely on specific inter-molecular interactions between +RNAs that guide multi-segmented genome assembly. While these families use distinct mechanisms to direct +RNA packaging, both yield progeny particles with a complete set of genomic dsRNAs.

ICTV Virus Taxonomy Profile: Cystoviridae.

The family Cystoviridae includes enveloped viruses with a tri-segmented dsRNA genome and a double-layered protein capsid. The innermost protein shell is a polymerase complex responsible for genome packaging, replication and transcription. Cystoviruses infect Gram-negative bacteria, primarily plant-pathogenic Pseudomonas syringae strains. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the taxonomy of the Cystoviridae, which is available at http://www.ictv.global/report/cystoviridae.

Cystoviral RNA-directed RNA polymerases: Regulation of RNA synthesis on multiple time and length scales.

P2, an RNA-directed RNA polymerase (RdRP), is encoded on the largest of the three segments of the double-stranded RNA genome of cystoviruses. P2 performs the dual tasks of replication and transcription de novo on single-stranded RNA templates, and plays a critical role in the viral life-cycle. Work over the last few decades has yielded a wealth of biochemical and structural information on the functional regulation of P2, on its role in the spatiotemporal regulation of RNA synthesis and its variability across the Cystoviridae family. These range from atomic resolution snapshots of P2 trapped in functionally significant states, in complex with catalytic/structural metal ions, polynucleotide templates and substrate nucleoside triphosphates, to P2 in the context of viral capsids providing structural insight into the assembly of supramolecular complexes and regulatory interactions therein. They include in vitro biochemical studies using P2 purified to homogeneity and in vivo studies utilizing infectious core particles. Recent advances in experimental techniques have also allowed access to the temporal dimension and enabled the characterization of dynamics of P2 on the sub-nanosecond to millisecond timescale through measurements of nuclear spin relaxation in solution and single molecule studies of transcription from seconds to minutes. Below we summarize the most significant results that provide critical insight into the role of P2 in regulating RNA synthesis in cystoviruses.

Reassortment in segmented RNA viruses: mechanisms and outcomes.

Segmented RNA viruses are widespread in nature and include important human, animal and plant pathogens, such as influenza viruses and rotaviruses. Although the origin of RNA virus genome segmentation remains elusive, a major consequence of this genome structure is the capacity for reassortment to occur during co-infection, whereby segments are exchanged among different viral strains. Therefore, reassortment can create viral progeny that contain genes that are derived from more than one parent, potentially conferring important fitness advantages or disadvantages to the progeny virus. However, for segmented RNA viruses that package their multiple genome segments into a single virion particle, reassortment also requires genetic compatibility between parental strains, which occurs in the form of conserved packaging signals, and the maintenance of RNA and protein interactions. In this Review, we discuss recent studies that examined the mechanisms and outcomes of reassortment for three well-studied viral families - Cystoviridae, Orthomyxoviridae and Reoviridae - and discuss how these findings provide new perspectives on the replication and evolution of segmented RNA viruses.

Electrophoretic mobility confirms reassortment bias among geographic isolates of segmented RNA phages.

BACKGROUND: Sex presents evolutionary costs and benefits, leading to the expectation that the amount of genetic exchange should vary in conditions with contrasting cost-benefit equations. Like eukaryotes, viruses also engage in sex, but the rate of genetic exchange is often assumed to be a relatively invariant property of a particular virus. However, the rates of genetic exchange can vary within one type of virus according to geography, as highlighted by phylogeographic studies of cystoviruses. Here we merge environmental microbiology with experimental evolution to examine sex in a diverse set of cystoviruses, consisting of the bacteriophage ϕ6 and its relatives. To quantify reassortment we manipulated - by experimental evolution - electrophoretic mobility of intact virus particles for use as a phenotypic marker to estimate genetic exchange. RESULTS: We generated descendants of ϕ6 that exhibited fast and slow mobility during gel electrophoresis. We identified mutations associated with slow and fast phenotypes using whole genome sequencing and used crosses to establish the production of hybrids of intermediate mobility. We documented natural variation in electrophoretic mobility among environmental isolates of cystoviruses and used crosses against a common fast mobility ϕ6 strain to monitor the production of hybrids with intermediate mobility, thus estimating the amount of genetic exchange. Cystoviruses from different geographic locations have very different reassortment rates when measured against ϕ6, with viruses isolated from California showing higher reassortment rates than those from the Northeastern US. CONCLUSIONS: The results confirm that cystoviruses from different geographic locations have remarkably different reassortment rates -despite similar genome structure and replication mechanisms- and that these differences are in large part due to sexual reproduction. This suggests that particular viruses may indeed exhibit diverse sexual behavior, but wide geographic sampling, across varying environmental conditions may be necessary to characterize the full repertoire. Variation in reassortment rates can assist in the delineation of viral populations and is likely to provide insight into important viral evolutionary dynamics including the rate of coinfection, virulence, and host range shifts. Electrophoretic mobility may be an indicator of important determinants of fitness and the techniques herein can be applied to the study of other viruses.

Plate tectonics of virus shell assembly and reorganization in phage φ8, a distant relative of mammalian reoviruses.

The hallmark of a virus is its capsid, which harbors the viral genome and is formed from protein subunits, which assemble following precise geometric rules. dsRNA viruses use an unusual protein multiplicity (120 copies) to form their closed capsids. We have determined the atomic structure of the capsid protein (P1) from the dsRNA cystovirus Φ8. In the crystal P1 forms pentamers, very similar in shape to facets of empty procapsids, suggesting an unexpected assembly pathway that proceeds via a pentameric intermediate. Unlike the elongated proteins used by dsRNA mammalian reoviruses, P1 has a compact trapezoid-like shape and a distinct arrangement in the shell, with two near-identical conformers in nonequivalent structural environments. Nevertheless, structural similarity with the analogous protein from the mammalian viruses suggests a common ancestor. The unusual shape of the molecule may facilitate dramatic capsid expansion during phage maturation, allowing P1 to switch interaction interfaces to provide capsid plasticity.

Role of host protein glutaredoxin 3 in the control of transcription during bacteriophage Phi2954 infection.

Bacteriophage Phi2954 contains three dsRNA genomic segments, designated L, M, and S. The RNA is located inside a core particle composed of multiple copies of a major structural protein, an RNA-dependent RNA polymerase, a hexameric NTPase, and an auxiliary protein. The core particle is covered by a shell of protein P8, and this structure is enclosed within a lipid-containing membrane. We have found that normal infection of the host Pseudomonas syringae is dependent on the action of a host protein, glutaredoxin 3 (GrxC). GrxC removes the P8 shell from the infecting particle and binds to the inner core. Removal of P8 activates the transcription of segments S and M, whereas binding of GrxC to the core particle activates the transcription of segment L. The differences in transcription behavior are due to the preference of the polymerase for G as the first base of the transcript. Transcripts of segments S and M begin with GCAA, whereas those of segment L begin with ACAA. The binding of GrxC to the particle results in changes in polymerase activity. Mutations resulting in independence of GrxC are found in the gene for protein P1, the major structural protein of the inner core particle.

Temporal control of message stability in the life cycle of double-stranded RNA bacteriophage phi8.

The cystoviruses have genomes of three double-stranded RNA segments. The genes of the L transcript are expressed early in infection, while those of M and S are expressed late. In all cystovirus groups but one, the quantity of the L transcript late in infection is lower than those of the other two because of transcriptional control. In bacteriophage Phi8 and its close relatives, transcription of L is not controlled; instead, the L transcript is turned over rapidly late in infection. The three messages are produced in approximately equal amounts early in infection, but the amount of L is less than 10% of the amounts of the others late in infection. The decay of the Phi8 L message depends upon the production of protein Hb, which is encoded in segment L. It also depends upon a target site within the H gene region. Phage mutants lacking either the Hb gene or the target region do not show the late control of L message quantity. In addition to having a role as a negative regulator, Hb functions to neutralize the activity of protein J, encoded by segment S, which causes the degradation of all viral transcripts.

Structure of a hexameric RNA packaging motor in a viral polymerase complex.

Packaging of the Cystovirus varphi8 genome into the polymerase complex is catalysed by the hexameric P4 packaging motor. The motor is located at the fivefold vertices of the icosahedrally symmetric polymerase complex, and the symmetry mismatch between them may be critical for function. We have developed a novel image-processing approach for the analysis of symmetry-mismatched structures and applied it to cryo-electron microscopy images of P4 bound to the polymerase complex. This approach allowed us to solve the three-dimensional structure of the P4 in situ to 15-A resolution. The C-terminal face of P4 was observed to interact with the polymerase complex, supporting the current view on RNA translocation. We suggest that the symmetry mismatch between the two components may facilitate the ring opening required for RNA loading prior to its translocation.

Hexameric molecular motors: P4 packaging ATPase unravels the mechanism.

Genome packaging into an empty capsid is an essential step in the assembly of many complex viruses. In double-stranded RNA (dsRNA) bacteriophages of the Cystoviridae family this step is performed by a hexameric helicase P4 which is one of the simplest packaging motors found in nature. Biochemical and structural studies of P4 proteins have led to a surprising finding that these proteins bear mechanistic and structural similarities to a variety of the pervasive RecA/F1-ATPase-like motors that are involved in diverse biological functions. This review describes the role of P4 proteins in assembly, transcription and replication of dsRNA bacteriophages as it has emerged over the past decade while focusing on the most recent structural studies. The P4 mechanism is compared with the models proposed for the related hexameric motors.

Virus particles monitored by fluorescence spectroscopy: a potential detection assay for macromolecular assembly.

Native fluorescence spectroscopy was used for in situ investigations of two lipid-containing bacteriophages from the cystovirus family as well as their Pseudomonad host cells. Both the viruses phi6 and phi12 and their bacterial host proteins contain the amino acid tryptophan (trp), which is the predominant fluorophore in UV. Within proteins, trp's structural environment differs, and the differences are reflected in their spectroscopic signatures. It was observed that the peak of the trp emission from both viruses was at 330 nm, a significantly shorter wavelength than trp in either the Pseudomonad host cells or the amino acid's chemical form. This allowed us to monitor the viral attachment process and subsequent lytic release of progeny virus particles by measurement of the trp emission spectra during the infection process. This work demonstrates that fluorescence may offer a novel tool to detect viruses and monitor viral infection of cells and may be part of a biodefense application.

Packaging, replication and recombination of the segmented genome of bacteriophage Phi6 and its relatives.

The genomes of bacteriophage Phi6 and its relatives are packaged through a mechanism that involves the recognition and translocation of the three different plus strand transcripts of the segmented dsRNA genomes into preformed polyhedral structures called procapsids or inner cores. The packaging requires hydrolysis of NTPs and takes place in the order S:M:L. Minus strand synthesis begins after the completion of the plus strand packaging. The packaging and replication reactions can be studied in vitro with purified components. A model has been presented that proposes that the program of serially dependent packaging is determined by the conformational changes at the surface of the procapsid due to the amount of RNA packaged at each step. The in vitro packaging and replication system has facilitated the application of reverse genetics and the study of recombination in the family of Cystoviridae.

Self-assembly of double-stranded RNA bacteriophages.

Double-stranded RNA viruses infecting bacterial hosts belong to the Cystoviridae family. Bacteriophage phi6 is one of the best characterized dsRNA viruses and shares structural as well as functional similarities with other well-studied eukaryotic dsRNA viruses (e.g. L-A, rotavirus, bluetongue virus, and reovirus). The assembly pathway of the enveloped, triple-layered phi6 virion has been well documented and can be divided into four distinct steps which are (1) procapsid formation, (2) genome encapsidation and replication, (3) nucleocapsid surface shell assembly, and (4) envelope formation. In this review, we focus primarily on the procapsid and nucleocapsid assembly for which in vitro systems have been established. The in vitro assembly systems have been instrumental in revealing assembly intermediates and conformational changes that are common to phi6 and phi8, two cystoviruses with negligible sequence homology. Two viral enzymes, the packaging NTPase (P4) and the RNA-dependent RNA polymerase (P2), were found essential for the nucleation step. The nucleation complex contains one or more tetramers of the major procapsid protein (P1) and is further stabilized by protein P4. Interaction of P1 and P4 during assembly is accompanied by an additional folding of their respective polypeptide chains. The in vitro assembled procapsids were shown to selectively package and replicate the genomic ssRNA. Furthermore, in vitro assembly of infectious nucleocapsids has been achieved in the case of phi6. The in vitro studies indicate that the nucleocapsid coat protein (P8) assembles around the polymerase complex in a template-assisted manner. Implications for the assembly of other dsRNA viruses are also presented.

Construction of carrier state viruses with partial genomes of the segmented dsRNA bacteriophages.

The cystoviridae are bacteriophages with genomes of three segments of dsRNA enclosed within a polyhedral capsid. Two members of this family, Phi6 and Phi8, have been shown to form carrier states in which the virus replicates as a stable episome in the host bacterium while expressing reporter genes such as kanamycin resistance or lacalpha. The carrier state does not require the activity of all the genes necessary for phage production. It is possible to generate carrier states by infecting cells with virus or by electroporating nonreplicating plasmids containing cDNA copies of the viral genomes into the host cells. We have found that carrier states in both Phi6 and Phi8 can be formed at high frequency with all three genomic segments or with only the large and small segments. The large genomic segment codes for the proteins that constitute the inner core of the virus, which is the structure responsible for the packaging and replication of the genome. In Phi6, a carrier state can be formed with the large and middle segment if mutations occur in the gene for the major structural protein of the inner core. In Phi8, carrier state formation requires the activity of genes 8 and 12 of segment S.

Unique properties of the inner core of bacteriophage phi8, a virus with a segmented dsRNA genome.

The inner core of bacteriophage phi8 is capable of packaging and replicating the plus strands of the RNA genomic segments of the virus in vitro. The particles composed of proteins P1, P2, P4, and P7 can be assembled in cells of E. coli that carry plasmids with cDNA copies of genomic segment L. The gene arrangement on segment L was found to differ from that of other cystoviruses in that the gene for the ortholog of protein P7 is located at the 3' end of the plus strand rather than near the 5' end. In place of the normal location of gene 7 is gene H, whose product is necessary for normal phage development, but not necessary for in vitro genomic packaging and replication. Genomic packaging is dependent upon the activity of an NTPase motor protein, P4. P4 was purified from cell extracts and was found to form hexamers with little NTPase activity until associated with inner core particles. Labeling studies of in vitro packaging of phi8 RNA do not show serial dependence; however, studies involving in vitro packaging for the formation of live virus indicate that packaging is stringent. Studies with the acquisition of chimeric segments in live virus indicate that phi8 does package RNA in the order s/m/l. The inner core of bacteriophage phi8 differs from that of its relatives in the Cystoviridae in that the major structural protein P1 is able to interact with the host cell membrane to effect penetration of the inner core into the cell.