Virus taxonomy--1997

Serological Methods for Detection of Polymyxa graminis, an Obligate Root Parasite and Vector of Plant Viruses

A purification procedure was developed to separate Polymyxa graminisresting spores from sorghum root materials. The spores were used as im-munogen to produce a polyclonal antiserum. In a direct antigen coating enzyme-linked immunosorbent assay (DAC ELISA), the antiserum could detect one sporosorus per well of the ELISA plate. In spiked root samples, the procedure detected one sporosorus per mg of dried sorghum roots. The majority of isolates of P. graminis from Europe, North America, and India reacted strongly with the antiserum. Interestingly, P. graminis isolates from the state of Rajasthan (northern India), from Pakistan, and an isolate from Senegal (West Africa) reacted weakly with the antiserum. The cross-reactivity of the serum with P. betae isolates from Belgium and Turkey was about 40% of that observed for the homologous isolate. There was no reaction with common fungi infecting roots or with the obligate parasite Olpidium brassicae. However, two isolates of Spongospora sub-terranea gave an absorbance similar to that observed with the homologous antigen. The DAC ELISA procedure was successfully used to detect various stages in the life cycle of P. graminis and to detect infection that occurred under natural and controlled environments. A simple procedure to conjugate antibodies to fluorescein 5-isothiocyanate (FITC) is described. Resting spores could be detected in root sections by using FITC-labeled antibodies. The potential for application of the two serological techniques for studying the epidemiology of peanut clump disease and for the characterization of Polymyxa isolates from various geographical origins is discussed.

Transcriptional activation of the rice tungro bacilliform virus gene is critically dependent on an activator element located immediately upstream of the TATA box

To investigate the transcriptional mechanisms of rice tungro bacilliform virus, we have systematically analyzed an activator element located immediately upstream of the TATA box in the rice tungro bacilliform virus promoter and its cognate trans-acting factors. Using electrophoretic mobility shift assays, we showed that rice nuclear proteins bind to the activator element, forming multiple specific DNA-protein complexes via protein-protein interactions. Copper-phenanthroline footprinting and DNA methylation interference analysis indicated that multiple DNA-protein complexes share a common binding site located between positions -60 to -39, and the proteins contact the activator element in the major groove. DNA UV cross-linking assays further showed that two nuclear proteins (36 and 33 kDa), found in rice cell suspension and shoot nuclear extracts, and one (27 kDa), present in root nuclear extracts, bind to this activator element. In protoplasts derived from a rice (Oryza sativa) suspension culture, the activator element is a prerequisite for promoter activity and its function is critically dependent on its position relative to the TATA box. Thus, transcriptional activation may function via interactions with the basal transcriptional machinery, and we propose that this activation is mediated by protein-protein interactions in a position-dependent mechanism.

Molecular Characterization of Potato virus V Genomes from Europe Indicates Limited Spatiotemporal Strain Differentiation

ABSTRACT Because there were no previous reports on the molecular characterization of Potato virus V (PVV, genus Potyvirus, family Potyviridae), the complete genomic sequence of PVV isolate Dv42 was determined. The length of the single-stranded messenger-polarity RNA genome was 9,851 nt (nucleotides), followed by a poly(A) tail. The genome contained a 5'-terminal nontranslated region (5'-NTR; 204 nt), a single open reading frame (nucleotides 205-9406; 3,067 amino acids), and a 3'-NTR that was unusually long (446 nt) compared with that of Potato virus Y (PVY; 331-nt 3'-NTR), Potato virus A (PVA; 207-nt 3'-NTR), and other potyviruses that naturally infect Solanaceae species. Phylogenetic analysis with the cylindrical inclusion protein-encoding and coat protein (CP)-encoding regions indicated that PVV Dv42 was most closely related to Pepper mottle virus and PVY, respectively. Seven PVV isolates (including Dv42) collected from cultivated potatoes in the Netherlands, the United Kingdom, and Norway from 1964 to 1997 were uniform in serological properties and symptomatology in indicator hosts that could distinguish strains of PVY and PVA. The nucleotide sequences of the 5'-NTR, P1, CP, and 3'-NTR regions of the PVV isolates were determined and were 94.6 to 99.5, 96.3 to 98.8, 96.4 to 98.7, and 96.3 to 99.6% identical, respectively. The amino acid similarities for the P1 and CP were 95.8 to 98.6 and 96.0 to 97.8%, respectively. Phylogenetic analysis of the CP sequences of PVV revealed no significant grouping, in contrast to PVY and PVA, which were grouped largely according to the previously recognized strains based on host responses. However, the relatively few differences in the P1 sequences of PVV were correlated with the different countries of origin. Hence, the PVV isolates infecting potatoes in Europe seem to vary little genetically and may belong to a single strain.

Charged residues in the transmembrane domains of hepatitis C virus glycoproteins play a major role in the processing, subcellular localization, and assembly of these envelope proteins

For most membrane proteins, the transmembrane domain (TMD) is more than just an anchor to the membrane. The TMDs of hepatitis C virus (HCV) envelope proteins E1 and E2 are extreme examples of the multifunctionality of such membrane-spanning sequences. Indeed, they possess a signal sequence function in their C-terminal half, play a major role in endoplasmic reticulum localization of E1 and E2, and are potentially involved in the assembly of these envelope proteins. These multiple functions are supposed to be essential for the formation of the viral envelope. As for the other viruses of the family Flaviviridae, these anchor domains are composed of two stretches of hydrophobic residues separated by a short segment containing at least one fully conserved charged residue. Replacement of these charged residues by an alanine in HCV envelope proteins led to an alteration of all of the functions performed by their TMDs, indicating that these functions are tightly linked together. These data suggest that the charged residues of the TMDs of HCV glycoproteins play a key role in the formation of the viral envelope.

Sugarcane yellow leaf virus: an emerging virus that has evolved by recombination between luteoviral and poleroviral ancestors

We have derived the genomic nucleotide sequence of an emerging virus, the Sugarcane yellow leaf virus (ScYLV), and shown that it produces one to two subgenomic RNAs. The family Luteoviridae currently includes the Luteovirus, Polerovirus, and Enamovirus genera. With the new ScYLV nucleotide sequence and existing Luteoviridae sequence information, we have utilized new phylogenetic and evolutionary methodologies to identify homologous regions of Luteoviridae genomes, which have statistically significant altered nucleotide substitution ratios and have produced a reconstructed phylogeny of the Luteoviridae. The data indicate that Pea enation mosaic virus-1 (PEMV-1), Soybean dwarf virus (SbDV), and ScYLV exhibit spatial phylogenetic variation (SPV) consistent with recombination events that have occurred between poleroviral and luteoviral ancestors, after the divergence of these two progenitor groups. The reconstructed phylogeny confirms a contention that a continuum in the derived sequence evolution of the Luteoviridae has been established by intrafamilial as well as extrafamilial RNA recombination and expands the database of recombinant Luteoviridae genomes that are currently needed to resolve better defined means for generic discrimination in the Luteoviridae (D'Arcy, C. J. and Mayo, M. 1997. Arch. Virol. 142, 1285-1287). The analyses of the nucleotide substitution ratios from a nucleotide alignment of Luteoviridae genomes substantiates the hypothesis that hot spots for RNA recombination in this virus family are associated with the known sites for the transcription of subgenomic RNAs (Miller et al. 1995. Crit. Rev. Plant Sci. 14, 179-211), and provides new information that might be utilized to better design more effective means to generate transgene-mediated host resistance.

Rescue of synthetic RNAs into thogoto and influenza A virus particles using core proteins purified from Thogoto virus

The ribonucleoprotein (RNP) complexes of Thogoto virus (THOV), a tick-borne orthomyxovirus, have been purified from detergent-lysed virions. The purified RNPs were then disrupted by centrifugation through a CsCl-glycerol gradient to obtain fractions highly enriched in nucleoprotein (NP) and virtually devoid of viral genomic RNA. When these NP-enriched fractions were incubated with a synthetic THOV-like RNA, and the mixtures were transfected into THOV-infected cells, the synthetic RNA was expressed and packaged into THOV particles. Similarly, hybrid mixtures containing purified THOV NP and influenza A virus synthetic RNAs (either a model CAT RNA or a gene encoding the viral neuraminidase), were prepared and transfected into influenza A virus-infected cells. The synthetic CAT RNA, was shown to be expressed and packaged into virus particles, and the neuraminidase gene was rescued into influenza virions. These data are discussed in terms of the similarities observed between THOV and influenza A virus and the potential application of the THOV purified proteins for rescuing synthetic genes into infectious viruses.

The rice tungro bacilliform virus gene II product interacts with the coat protein domain of the viral gene III polyprotein

Rice tungro bacilliform virus (RTBV) is a plant pararetrovirus whose DNA genome contains four genes encoding three proteins and a large polyprotein. The function of most of the viral proteins is still unknown. To investigate the role of the gene II product (P2), we searched for interactions between this protein and other RTBV proteins. P2 was shown to interact with the coat protein (CP) domain of the viral gene III polyprotein (P3) both in the yeast two-hybrid system and in vitro. Domains involved in the P2-CP association have been identified and mapped on both proteins. To determine the importance of this interaction for viral multiplication, the infectivity of RTBV gene II mutants was investigated by agroinoculation of rice plants. The results showed that virus viability correlates with the ability of P2 to interact with the CP domain of P3. This study suggests that P2 could participate in RTBV capsid assembly.

Comparison of classic and molecular approaches for the identification of untypeable enteroviruses

Members of the family Picornaviridae are the most common viruses infecting humans, and species in several genera also infect a wide variety of other mammals. Picornaviruses have traditionally been classified by antigenic type, based on a serum neutralization assay. However, this method is time-consuming and labor-intensive, is sensitive to virus aggregation and antigenic variation, and requires a large number of antisera to identify all serotypes, even when antiserum pools are used. We developed generic reverse transcription (RT)-PCR primers that will amplify all human enterovirus serotypes, as well as many rhinoviruses and other picornaviruses, and used RT-PCR amplification of the VP1 gene and amplicon sequencing to identify enteroviruses that were refractory to typing by neutralization with pooled antisera. Enterovirus serotypes determined by sequencing were confirmed by neutralization with monospecific antisera. Of 55 isolates tested, 49 were of known enterovirus serotypes, two were rhinoviruses, and four were clearly picornaviruses but did not match any known picornavirus sequence. All four untyped picornaviruses were closely related to one another in sequence, suggesting that they are of the same serotype. RT-PCR, coupled with amplicon sequencing, is a simple and rapid method for the typing and classification of picornaviruses and may lead to the identification of many new picornavirus serotypes.

Pea embryonic tissues show common responses to the replication of a wide range of viruses

The response of pea embryonic tissues to the replication of a range of different viruses was investigated using in situ hybridization to analyze changes in the expression of two host genes, heat shock protein 70 (hsp70) and lipoxygenase (lox1). Excised pea embryos were infected using microprojectile bombardment with a nonseed transmissible strain of Pea seed-borne mosaic potyvirus, or with Pea early browning tobravirus (PEBV), White Clover mosaic potexvirus, or Beet curly top geminivirus. Collectively, these examples represent families of viruses with differing genomic features, differing numbers of genomic components and differing replication strategies. In all cases, there was an induction of hsp70 associated with virus replication and, in most cases, a downregulation of lox1. Hence, either each virus has a direct inducer of these common responses or the induction is indirectly the result of a generic feature of virus infection. By exploiting the bipartite nature of the PEBV genome, the coat protein gene and genes involved in vector transmission were excluded as potential inducers.

Molecular characterization of the cucurbit yellow stunting disorder virus coat protein gene

ABSTRACT Cucurbit yellow stunting disorder virus (CYSDV) is a partially characterized bipartite closterovirus transmitted by the tobacco whitefly (Bemisia tabaci). CYSDV has emerged as a serious pathogen in southeastern Spain and the Mediterranean Region, causing yellowing disease of cucumber and melon crops. Using a modified reverse-transcription polymerase chain reaction protocol with gel-extracted dsRNA templates, fragments of CYSDV RNA2 were amplified and cloned. Sequence analysis of the cloned fragments revealed open reading frames encoding the heat shock protein 70 homolog, two proteins of unknown function (p58 and p9), and the coat protein (CP) of the virus in a contiguous gene arrangement similar to that of lettuce infectious yellows virus (LIYV) RNA2. The complete CYSDV CP gene is 756 nt long and encodes a protein with a molecular mass of 28.5 kDa. A comparison of the amino acid sequence of the CYSDV CP gene with those of other closteroviruses revealed significant levels of similarity with sweet potato chlorotic stunt virus and LIYV (36 and 27%, respectively), both of which are members of the recently proposed Crinivirus genus of closteroviruses. The complete CYSDV CP gene was cloned into a bacterial expression vector, and the resulting fusion protein was purified and used to produce antiserum. Purified immunoglobulins specifically detected CYSDV in infected plant extracts, both in immunoblot and indirect enzyme-linked immunosorbent assays with a titer exceeding 2,000 times for both assays.

Complete sequence of RNA 1 and the presence of tRNA-like structures in all RNAs of Potato mop-top virus, genus Pomovirus

The complete nucleotide sequence (6043 nt) of RNA 1 from Potato mop-top virus (PMTV-Sw), the type member of the genus Pomovirus, was determined. The first (5'-terminal) open reading frame (ORF 1) encodes a predicted protein of 148 kDa. ORF 2 extends through the opal stop codon of ORF 1 producing a predicted readthrough protein of 206 kDa which resembles the RNA-dependent RNA polymerases (RdRp) of other fungal-transmitted viruses. It includes a methyltransferase, a helicase and a GDD RdRp motif, respectively. Phylogenetic analyses of RdRps indicated that PMTV is most closely related to Beet soil-borne virus (genus Pomovirus), Broad bean necrosis virus (genus Pomovirus) and Soil-borne wheat mosaic virus (genus Furovirus), and is more distantly related to the other viruses of the former furovirus group. The 5' and 3' termini of RNA 1 in PMTV contained untranslated regions (UTR) of 114 nt and 489 nt, respectively. The 3'-UTR of RNA 1 contained a tRNA-like structure, which has previously been reported in the 3'-UTR of RNA 2 but not RNA 3. However, in this study, the tRNA-like structure was also found in the 3'-UTR of RNA 3, which confirms its presence in the 3'-UTRs of all three RNAs of PMTV.

The nucleopolyhedroviruses of Rachiplusia ou and Anagrapha falcifera are isolates of the same virus

The 7.8 kb EcoRI-G fragment of Rachiplusia ou multicapsid nucleopolyhedrovirus (RoMNPV), containing the polyhedrin gene, was cloned and sequenced. The sequence of the fragment was 92.3% identical to the sequence of the corresponding region in the Autographa californica (Ac)MNPV genome. A comparison of the EcoRI-G sequence with other MNPV sequences revealed that RoMNPV was most closely related to AcMNPV. However, the predicted amino acid sequence of RoMNPV polyhedrin shared more sequence identity with the polyhedrin of Orygia pseudotsugata MNPV. In addition, the RoMNPV sequence was almost completely identical (99.9%) to a previously published 6.3 kb sequence of Anagrapha falcifera MNPV (AfMNPV). The EcoRI and HindIII restriction fragment profiles of RoMNPV and AfMNPV also were nearly identical, with an additional EcoRI band detected in RoMNPV DNA. Bioassays of these viruses with three different hosts (the European corn borer, Ostrinia nubilalis Hubner, the corn earworm, Helicoverpa zea Boddie, and the tobacco budworm, Heliothis virescens Fabricius) failed to detect any differences in the biological activities of RoMNPV and AfMNPV. These results indicate that RoMNPV and AfMNPV are different isolates of the same virus. The taxonomic relationship of Ro/AfMNPV and AcMNPV is discussed.

Molecular detection and typing of human picornaviruses

Picornaviruses include several important clinical pathogens which cause diseases varying from common cold to poliomyelitis and hepatitis. Introduction of RT-PCR methods for the detection of these viruses has significantly facilitated the diagnosis of picornavirus infections and elucidated their etiological role in clinical illnesses. Partial sequence analysis of the genomes has been used for typing of the viruses and in studies of molecular epidemiology of picornaviruses. These molecular approaches are likely to become the most predominant techniques for the diagnosis and epidemiological analysis, particularly in the enterovirus infections.

Sequence of the genomic RNA of nudaurelia beta virus (Tetraviridae) defines a novel virus genome organization

The monopartite genome of Nudaurelia beta virus, the type species of the Betatetravirus genus of the family Tetraviridae, consists of a single-stranded positive-sense RNA (ss+RNA) of 6625 nucleotides containing two open reading frames (ORFs). The 5' proximal ORF of 5778 nucleotides encodes a protein of 215 kDa containing three functional domains characteristic of RNA-dependent RNA polymerases of ss+RNA viruses. The 3' proximal ORF of 1836 nucleotides, which encodes the 66-kDa capsid precursor protein, overlaps the replicase gene by more than 99% (1827 nucleotides) and is in the +1 reading frame relative to the replicase reading frame. This capsid precursor is expressed via a 2656-nucleotide subgenomic RNA. The 3' terminus of the genome can be folded into a tRNA-like secondary structure that has a valine anticodon; the tRNA-like structure lacks a pseudoknot in the aminoacyl stem, a feature common to both genera of tetraviruses. Comparison of the sequences of Nudaurelia beta virus and another member of the Tetraviridae, Helicoverpa armigera stunt virus, which is in the genus Omegatetravirus, shows identities of 31.6% for the replicase and 24.5% for the capsid protein. The viruses in the genera Betatetravirus and Omegatetravirus of the Tetraviridae are clearly related but show significant differences in their genome organization. It is concluded that the ancestral virus with a bipartite genome, as found in the genus Omegatetravirus, likely evolved from a virus with an unsegmented genome, as found in the genus Betatetravirus, through evolution of the subgenomic RNA into a separate genomic component, with the accompanying loss of the capsid gene from the longer genomic RNA.

Typing of human enteroviruses by partial sequencing of VP1

Human enteroviruses (family Picornaviridae) are the major cause of aseptic meningitis and also cause a wide range of other acute illnesses, including neonatal sepsis-like disease, acute flaccid paralysis, and acute hemorrhagic conjunctivitis. The neutralization assay is usually used for enterovirus typing, but it is labor-intensive and time-consuming and standardized antisera are in limited supply. We have developed a molecular typing system based on reverse transcription-PCR and nucleotide sequencing of the 3' half of the genomic region encoding VP1. The standard PCR primers amplify approximately 450 bp of VP1 for most known human enterovirus serotypes. The serotype of an "unknown" may be inferred by comparison of the partial VP1 sequence to those in a database containing VP1 sequences for the prototype strains of all 66 human enterovirus serotypes. Fifty-one clinical isolates of known serotypes from the years 1991 to 1998 were amplified and sequenced, and the antigenic and molecular typing results agreed for all isolates. With one exception, the nucleotide sequences of homologous strains were at least 75% identical to one another (>88% amino acid identity). Strains with homologous serotypes were easily discriminated from those with heterologous serotypes by using these criteria for identification. This method can greatly reduce the time required to type an enterovirus isolate and can be used to type isolates that are difficult or impossible to type with standard immunological reagents. The technique may also be useful for the rapid determination of whether viruses isolated during an outbreak are epidemiologically related.

Biotic, molecular, and phylogenetic characterization of bean calico mosaic virus, a distinct begomovirus species with affiliation in the squash leaf curl virus cluster

ABSTRACT Bean calico mosaic virus (BCMoV), a whitefly-transmitted geminivirus from Sonora, Mexico, was purified, and the genome components were cloned and sequenced. Purified viral fractions and cloned genome components were infectious by biolistic inoculation to bean, completing Koch's postulates for both. The B biotype of the whitefly Bemisia tabaci efficiently transmitted both native virus and progeny virus derived from cloned DNA inoculum. Host ranges of native virus and of progeny virus derived from cloned DNA were identical based upon whitefly and biolistic mediated transmission, respectively. BCMoV has a relatively wide experimental host range among begomoviruses known to infect bean, encompassing genera and species within the Fabaceae, Malvaceae, and Solanaceae. BCMoV has a bipartite genome, as do other New World begomoviruses. BCMoV DNA-A shared highest nucleotide sequence identities with squash leaf curl virus-E strain (SLCV-E) and cabbage leaf curl virus (CaLCV) at 80.1 and 80.7%, respectively. BCMoV DNA-B shared highest nucleotide sequence identity with SLCV-E at 70.7%. The common region (CR) sequences of BCMoV and SLCV-E are 73 to 76% identical; however, modular cis-acting elements within the CR involved in replication origin function and recognition are 100% conserved. Phy-logenetic analysis indicated that BCMoV DNA-A shares a most recent common ancestor with the DNA-A of two viruses that also occur in the Sonoran Desert, SLCV-E and Texas pepper virus (TPV-TAM), and CaLCV from Florida. In contrast, a phylogenetic analysis indicated that BCMoV DNA-B shares a most recent common ancestor with SLCV-E; whereas DNA-B of CaLCV clustered in a separate clade with pepper hausteco virus. Collectively, biological and molecular characteristics indicate that BCMoV is a distinct begomovirus species with the northernmost distribution of any begomovirus isolated from bean in the Americas. Furthermore, the phylogenetic relationships of begomovirus cognate components are not necessarily identical, suggesting that DNA-A and DNA-B of some begomoviruses may have different evolutionary histories.