Defective RNA molecules associated with citrus tristeza virus

On the Trail of the Longest Plant RNA Virus: Citrus Tristeza Virus

The devastating tristeza epidemic swept through South American citrus groves in the 1930s and subsequently spread to most citrus-growing regions worldwide, causing varying degrees of damage and prompting significant changes in citrus cultivation practices. The causal agent of the disease, citrus tristeza virus (CTV), belongs to the genus Closterovirus in the family Closteroviridae. CTV virions are approximately two microns long and possess the largest known positive-strand RNA genome in plants, spanning 19.3 kb. The history of tristeza disease and CTV's molecular biology and taxonomic relationships have been extensively reviewed in the scientific literature. This paper primarily focuses on the author's personal experiences with tristeza disease and its causal agent over the past six decades. The journey began during a period when biological indexing was the primary diagnostic tool. It later progressed through the isolation of purified CTV particles, which served as a practical diagnostic tool for CTV suppression efforts in Israel during the 1970s. However, biological indexing was first replaced by electron microscopy, followed by ELISA procedures; both were eventually abandoned after it was discovered that many ELISA-positive infections were caused by symptomless CTV isolates, even on trees grafted onto sour orange rootstocks. In retrospect, my work on CTV can be categorized into three main phases. It began with the biological phase, inherited from earlier generations of citrus virologists, followed by the isolation and partial characterization of CTV virions, and culminated in the genomic era. While we live in an age of remarkable biotechnological achievements, my recommendation for future CTV research is to integrate both biological and genomic approaches rather than viewing them as mutually exclusive. This is particularly important for economically significant pathogens such as CTV, which should be studied continuously as both biological agents and molecular pathogens.

Intra-Host Citrus Tristeza Virus Populations during Prolonged Infection Initiated by a Well-Defined Sequence Variant in Nicotiana benthamiana

Due to the error-prone nature of viral RNA-dependent RNA polymerases, the replication of RNA viruses results in a diversity of viral genomes harboring point mutations, deletions, insertions, and genome rearrangements. Citrus tristeza virus (CTV), a causal agent of diseases of economically important citrus species, shows intrinsic genetic stability. While the virus appears to have some mechanism that limits the accumulation of single-nucleotide variants, the production of defective viral genomes (DVGs) during virus infection has been reported for certain variants of CTV. The intra-host diversity generated during plant infection with variant T36 (CTV-T36) remains unclear. To address this, we analyzed the RNA species accumulated in the initially infected and systemic leaves of Nicotiana benthamiana plants inoculated with an infectious cDNA clone of CTV-T36, which warranted that infection was initiated by a known, well-defined sequence variant of the virus. CTV-T36 limited the accumulation of single-nucleotide mutants during infection. With that, four types of DVGs-deletions, insertions, and copy- and snap-backs-were found in all the samples, with deletions and insertions being the most common types. Hot-spots across the genome for DVG recombination and short direct sequence repeats suggest that sequence complementarity could mediate DVG formation. In conclusion, our study illustrates the formation of diverse DVGs during CTV-T36 infection. To the best of our knowledge, this is the first study that has analyzed the genetic variability and recombination of a well-defined sequence variant of CTV in an herbaceous host.

Defective RNA Particles of Plant Viruses-Origin, Structure and Role in Pathogenesis

The genomes of RNA viruses may be monopartite or multipartite, and sub-genomic particles such as defective RNAs (D RNAs) or satellite RNAs (satRNAs) can be associated with some of them. D RNAs are small, deletion mutants of a virus that have lost essential functions for independent replication, encapsidation and/or movement. D RNAs are common elements associated with human and animal viruses, and they have been described for numerous plant viruses so far. Over 30 years of studies on D RNAs allow for some general conclusions to be drawn. First, the essential condition for D RNA formation is prolonged passaging of the virus at a high cellular multiplicity of infection (MOI) in one host. Second, recombination plays crucial roles in D RNA formation. Moreover, during virus propagation, D RNAs evolve, and the composition of the particle depends on, e.g., host plant, virus isolate or number of passages. Defective RNAs are often engaged in transient interactions with full-length viruses-they can modulate accumulation, infection dynamics and virulence, and are widely used, i.e., as a tool for research on cis-acting elements crucial for viral replication. Nevertheless, many questions regarding the generation and role of D RNAs in pathogenesis remain open. In this review, we summarise the knowledge about D RNAs of plant viruses obtained so far.

The Intriguing Conundrum of a Nonconserved Multifunctional Protein of Citrus Tristeza Virus That Interacts with a Viral Long Non-Coding RNA

Citrus tristeza virus (CTV), the largest non-segmented plant RNA virus, has several peculiar features, among which is the production of a 5'-terminal long non-coding RNA (lncRNA) termed low-molecular-weight tristeza 1 (LMT1). In this study, we found that p33, a unique viral protein that performs multiple functions in the virus infection cycle, specifically binds LMT1, both in vivo and in vitro. These results were obtained through the expression of p33 under the context of the wild type virus infection or along with a mutant CTV variant that does not produce LMT1 as well as via ectopic co-expression of p33 with LMT1 in Nicotiana benthamiana leaves followed by RNA immunoprecipitation and rapid amplification of cDNA ends assays. Further experiments in which a recombinant p33 protein and an in vitro transcribed full-length LMT1 RNA or its truncated fragments were subjected to an electrophoretic mobility shift assay demonstrated that p33 binds to at least two distinct regions within LMT1. To the best of our knowledge, this is the first report of a plant virus protein binding to a lncRNA produced by the same virus. The biological significance of the interaction between these two viral factors is discussed.

Walking Together: Cross-Protection, Genome Conservation, and the Replication Machinery of Citrus tristeza virus

"Cross-protection", a nearly 100 years-old virological term, is suggested to be changed to "close protection". Evidence for the need of such change has accumulated over the past six decades from the laboratory experiments and field tests conducted by plant pathologists and plant virologists working with different plant viruses, and, in particular, from research on Citrus tristeza virus (CTV). A direct confirmation of such close protection came with the finding that "pre-immunization" of citrus plants with the variants of the T36 strain of CTV but not with variants of other virus strains was providing protection against a fluorescent protein-tagged T36-based recombinant virus variant. Under natural conditions close protection is functional and is closely associated both with the conservation of the CTV genome sequence and prevention of superinfection by closely similar isolates. It is suggested that the mechanism is primarily directed to prevent the danger of virus population collapse that could be expected to result through quasispecies divergence of large RNA genomes of the CTV variants continuously replicating within long-living and highly voluminous fruit trees. This review article provides an overview of the CTV cross-protection research, along with a discussion of the phenomenon in the context of the CTV biology and genetics.

A Long Non-Coding RNA of Citrus tristeza virus: Role in the Virus Interplay with the Host Immunity

During infection, Citrus tristeza virus (CTV) produces a non-coding subgenomic RNA referred to as low-molecular-weight tristeza 1 (LMT1), which for a long time has been considered as a by-product of the complex CTV replication machinery. In this study, we investigated the role of LMT1 in the virus infection cycle using a CTV variant that does not produce LMT1 (CTV-LMT1d). We showed that lack of LMT1 did not halt virus ability to replicate or form proper virions. However, the mutant virus demonstrated significantly reduced invasiveness and systemic spread in Nicotiana benthamiana as well as an inability to establish infection in citrus. Introduction of CTV-LMT1d into the herbaceous host resulted in elevation of the levels of salicylic acid (SA) and SA-responsive pathogenesis-related genes beyond those upon inoculation with wild-type (WT) virus (CTV-WT). Further analysis showed that the LMT1 RNA produced by CTV-WT or via ectopic expression in the N. benthamiana leaves suppressed SA accumulation and up-regulated an alternative oxidase gene, which appeared to mitigate the accumulation of reactive oxygen species. To the best of our knowledge, this is the first report of a plant viral long non-coding RNA being involved in counter-acting host response by subverting the SA-mediated plant defense.

Citrus tristeza virus: making an ally from an enemy

Virus diseases of perennial trees and vines have characteristics not amenable to study using small model annual plants. Unique disease symptoms such as graft incompatibilities and stem pitting cause considerable crop losses. Also, viruses in these long-living plants tend to accumulate complex populations of viruses and strains. Considerable progress has been made in understanding the biology and genetics of Citrus tristeza virus (CTV) and in developing it into a tool for crop protection and improvement. The diseases in tree and vine crops have commonalities for which CTV can be used to develop a baseline. The purpose of this review is to provide a necessary background of systems and reagents developed for CTV that can be used for continued progress in this area and to point out the value of the CTV-citrus system in answering important questions on plant-virus interactions and developing new methods for controlling plant diseases.

The Prevalence of the Citrus tristeza virus Trifoliate Resistance Breaking Genotype Among Puerto Rican Isolates

Citrus tristeza virus (CTV) isolates have been grouped into six genotypes: T3, T30, T36, VT, B165, and resistance breaking (RB) based on symptoms, host range, and genomic sequence data. The RB genotype has recently been identified with the novel property of replicating in trifoliate orange trees, a resistant host for the other five genotypes. Puerto Rican CTV isolate B301 caused mild vein clearing symptoms in Mexican lime but did not induce seedling yellows or stem pitting reactions in appropriate indicator Citrus spp., which are typical host reactions of the isolate T30. The isolate B301 was not detected by the genotype specific primer (GSP), which identifies the CTV-T3, -T30, -T36, -VT, and B165 genotypes. A primer pair for reverse transcription polymerase chain reaction (RT-PCR) amplification of the CTV-RB genotype was designed from the heat shock protein (p65) region based on the complete genomic sequences of trifoliate RB isolates from New Zealand available in the GenBank databases. The amplicon sequence from isolate B301 was 98% identical to that of the other trifoliate RB isolates. In addition, B301 was successfully inoculated into 'Carrizo citrange' (a trifoliate hybrid) but did not induce any symptoms. Furthermore, the complete genome sequence of B301 followed by the phylogenetic analysis revealed that the isolate is part of the RB clade with other CTV-RB isolates from New Zealand and Hawaii. Additional CTV isolates obtained from Puerto Rico were tested with the RB-GSP and confirmed the presence of trifoliate RB isolates in mixed infection with known CTV genotypes. Although this is the first report of a CTV trifoliate RB genotype from Puerto Rico, this genotype was present there prior to 1992.

The defective RNAs of Closteroviridae

The family Closteroviridae consists of two genera, Closterovirus and Ampelovirus with monopartite genomes transmitted respectively by aphids and mealybugs and the Crinivirus with bipartite genomes transmitted by whiteflies. The Closteroviridae consists of more than 30 virus species, which differ considerably in their phytopathological significance. Some, like beet yellows virus and citrus tristeza virus (CTV) were associated for many decades with their respective hosts, sugar beets and citrus. Others, like the grapevine leafroll-associated ampeloviruses 1, and 3 were also associated with their grapevine hosts for long periods; however, difficulties in virus isolation hampered their molecular characterization. The majority of the recently identified Closteroviridae were probably associated with their vegetative propagated host plants for long periods and only detected through the considerable advances in dsRNA isolation and sequencing of PCR amplified replicons. Molecular characterization of CTV and several other Closteroviridae revealed that, in addition to genomic and subgenomic RNAs, infected plants contain several different subviral defective RNAs (dRNAs). The roles and biological functions of dRNAs associated with Closteroviridae remain terra incognita.

Citrus tristeza virus: Evolution of Complex and Varied Genotypic Groups

Amongst the Closteroviridae, Citrus tristeza virus (CTV) is almost unique in possessing a number of distinct and characterized strains, isolates of which produce a wide range of phenotype combinations among its different hosts. There is little understanding to connect genotypes to phenotypes, and to complicate matters more, these genotypes are found throughout the world as members of mixed populations within a single host plant. There is essentially no understanding of how combinations of genotypes affect symptom expression and disease severity. We know little about the evolution of the genotypes that have been characterized to date, little about the biological role of their diversity and particularly, about the effects of recombination. Additionally, genotype grouping has not been standardized. In this study we utilized an extensive array of CTV genomic information to classify the major genotypes, and to determine the major evolutionary processes that led to their formation and subsequent retention. Our analyses suggest that three major processes act on these genotypes: (1) ancestral diversification of the major CTV lineages, followed by (2) conservation and co-evolution of the major functional domains within, though not between CTV genotypes, and (3) extensive recombination between lineages that have given rise to new genotypes that have subsequently been retained within the global population. The effects of genotype diversity and host-interaction are discussed, as is a proposal for standardizing the classification of existing and novel CTV genotypes.

Replication of Lettuce chlorosis virus (LCV), a crinivirus in the family Closteroviridae, is accompanied by the production of LCV RNA 1-derived novel RNAs

Cloned infectious complementary DNAs of the bipartite genomic RNAs of Lettuce chlorosis virus (LCV) were constructed. Inoculation of tobacco protoplasts with the in vitro produced RNAs 1 and 2 transcripts, or with RNA 1 transcript alone, resulted in viral replication accompanied by the production of novel LCV RNA 1-derived RNAs. They included the abundantly accumulating LM-LCVR1-1 (~0.38 kb) and LM-LCVR1-2 (~0.3 kb), and the lowly accumulating HM-LCVR1-1 (~8.0 kb) and HM-LCVR1-2 (~6.6 kb), all of which reacted with riboprobes specific to the 5' end of RNA 1 in Northern blot analysis. LM-LCVR1-1 and HM-LCVR1-2 accumulated as positive-stranded RNAs that lacked complementary negative strands, while HM-LCVR1-1 and LM-LCVR1-2 accumulated in both polarities. Additional Northern blot, reverse transcription-polymerase chain reaction, cloning, and sequence analyses revealed LM-LCVR1-2 to be an authentic RNA 1-derived defective (D)RNA, suggesting that its synthesis and maintenance are supported in trans by an RNA 1 encoded replication machinery.

Rapid differentiation and identification of potential severe strains of Citrus tristeza virus by real-time reverse transcription-polymerase chain reaction assays

A multiplex Taqman-based real-time reverse transcription (RT) polymerase chain reaction (PCR) assay was developed to identify potential severe strains of Citrus tristeza virus (CTV) and separate genotypes that react with the monoclonal antibody MCA13. Three strain-specific probes were developed using intergene sequences between the major and minor coat protein genes (CPi) in a multiplex reaction. Probe CPi-VT3 was designed for VT and T3 genotypes; probe CPi-T36 for T36 genotypes; and probe CPi-T36-NS to identify isolates in an outgroup clade of T36-like genotypes mild in California. Total nucleic acids extracted by chromatography on silica particles, sodium dodecyl sulfate-potassium acetate, and CTV virion immunocapture all yielded high quality templates for real-time PCR detection of CTV. These assays successfully differentiated CTV isolates from California, Florida, and a large panel of CTV isolates from an international collection maintained in Beltsville, MD. The utility of the assay was validated using field isolates collected in California and Florida.

Population dynamics of a Florida Citrus tristeza virus isolate and aphid-transmitted subisolates: identification of three genotypic groups and recombinants after aphid transmission

Tristeza is an important citrus disease affecting the viability and productivity of citrus worldwide. The causal agent, Citrus tristeza virus (CTV), usually occurs as a mixture of genotypes in nature, with one of the genotypes often dominating the population. CTV has a monopartite, positive-sense RNA genome of approximately 19.3 kb and exhibits over 30% diversity in the 5' half and less than 10% in the 3' half among different genotypes. A Florida CTV isolate, FS627, was selected for this study. Isolate FS627 was analyzed by reverse-transcription polymerase chain reaction (RT-PCR) using primers to three regions: 788-bp region in the 5' (697 to 1,484 nucleotides), open reading frame (ORF)1a, 696 or 718 bp from the overlapping region of the RdRp (ORF1b) and p33 (ORF2) gene, and a 672-bp major coat protein gene (ORF7) in the 3' end of the CTV genome. The presence of T36, T30, and VT genotypes in isolate FS627 was confirmed utilizing the genotype specific overlapping region of RdRp primer pairs for RT-PCR amplification followed by cloning and sequence analysis. Analysis of single-strand conformational polymorphisms and sequences of RT-PCR-amplified products of the above regions were used to determine the presence of genotypes in both the parent and aphid-transmitted (AT) subisolates. Although the parent isolate had T36 as the major genotype, T30 was the major genotype in most of the AT subisolates. Some intermediate genotypes were detected that differed from the parental or AT subisolates. These intermediate genotypes were considered to be recombinants of the T30 and T36 genotypes and also were observed in the second level of AT subisolates generated from the of first-level AT subisolates of CTV-FS627. This work provides advance information on the population dynamics in CTV mixtures and the generation of virus recombinants after aphid transmission.

Discrimination between mild and severe Citrus tristeza virus isolates with a rapid and highly specific real-time reverse transcription-polymerase chain reaction method using TaqMan LNA probes

Severe isolates of Citrus tristeza virus (CTV) inducing seedling yellows (SY) and/or stem pitting (SP) in grapefruit or sweet orange are a major threat for the citrus industry worldwide. Identification of these CTV variants was achieved by quantitative real-time reverse transcription-polymerase chain reaction (RT-PCR) using a general primer set and three TaqMan locked nucleic acids (LNA) probes targeting sequences characteristic of severe, mild (non-SY, non-SP), and T36-like isolates. Successful amplification was achieved from fresh or silica-desiccated CTV-infected samples and all isolates but one reacted with one or more probes. Standard curves using RNA transcripts homologous to the three probes allowed a reproducible quantitative assay, with a wide dynamic range of detection starting with 10(2) copies. RT-PCR assays with homologous and heterologous transcript RNA mixes demonstrated that each probe reacted only with its cognate sequence which was detected even at ratios below 2.5%. Analysis of 56 pathogenically distinct CTV isolates from 20 countries showed that mild isolates reacted only with the mild probe, whereas severe SP and SY isolates reacted with the severe-SP or the T36-like probes, respectively, and often with a second probe. This procedure can be useful to identify and control potentially dangerous CTV isolates in areas affected only by mild isolates.

Citrus tristeza virus: a pathogen that changed the course of the citrus industry

Citrus tristeza virus (CTV) (genus Closterovirus, family Closteroviridae) is the causal agent of devastating epidemics that changed the course of the citrus industry. Adapted to replicate in phloem cells of a few species within the family Rutaceae and to transmission by a few aphid species, CTV and citrus probably coevolved for centuries at the site of origin of citrus plants. CTV dispersal to other regions and its interaction with new scion varieties and rootstock combinations resulted in three distinct syndromes named tristeza, stem pitting and seedling yellows. The first, inciting decline of varieties propagated on sour orange, has forced the rebuilding of many citrus industries using tristeza-tolerant rootstocks. The second, inducing stunting, stem pitting and low bearing of some varieties, causes economic losses in an increasing number of countries. The third is usually observed by biological indexing, but rarely in the field. CTV polar virions are composed of two capsid proteins and a single-stranded, positive-sense genomic RNA (gRNA) of approximately 20 kb, containing 12 open reading frames (ORFs) and two untranslated regions (UTRs). ORFs 1a and 1b, encoding proteins of the replicase complex, are directly translated from the gRNA, and together with the 5' and 3'UTRs are the only regions required for RNA replication. The remaining ORFs, expressed via 3'-coterminal subgenomic RNAs, encode proteins required for virion assembly and movement (p6, p65, p61, p27 and p25), asymmetrical accumulation of positive and negative strands during RNA replication (p23), or suppression of post-transcriptional gene silencing (p25, p20 and p23), with the role of proteins p33, p18 and p13 as yet unknown. Analysis of genetic variation in CTV isolates revealed (1) conservation of genomes in distant geographical regions, with a limited repertoire of genotypes, (2) uneven distribution of variation along the gRNA, (3) frequent recombination events and (4) different selection pressures shaping CTV populations. Measures to control CTV damage include quarantine and budwood certification programmes, elimination of infected trees, use of tristeza-tolerant rootstocks, or cross protection with mild isolates, depending on CTV incidence and on the virus strains and host varieties predominant in each region. Incorporating resistance genes into commercial varieties by conventional breeding is presently unfeasible, whereas incorporation of pathogen-derived resistance by plant transformation has yielded variable results, indicating that the CTV-citrus interaction may be more specific and complex than initially thought. A deep understanding of the interactions between viral proteins and host and vector factors will be necessary to develop reliable and sound control measures.

Improved Efficiency for Quantitative and Qualitative Indexing for Citrus tristeza virus and Citrus psorosis virus

Reverse transcription-polymerase chain reaction (RT-PCR) assays were developed for the detection of Citrus tristeza virus (CTV; genus Closterovirus) and Citrus psorosis virus (CPsV; genus Ophiovirus) in citrus trees. Real-time TaqMan RT-PCR was also developed for the detection of CTV. Three different sample preparation methods were compared. The total RNA extraction method by Qiagen was found to be more reliable than the other two methods consisting of crude plant sap extraction and total nucleic acid trapping on a silica bed. Of 287 samples tested for CTV, 210 samples tested positive by RT-PCR and 198 samples by enzyme-linked immunosorbent assay (ELISA). Furthermore, the results from monthly tests of a selected number of field-grown CTV-infected trees showed that RT-PCR detected the virus in 100% of the infected trees in winter and summer, whereas ELISA did not. The one-tube RT-PCR detection was developed for CPsV and was more sensitive than ELISA. Notably, three of 10 CPsV isolates were not detected by ELISA. As demonstrated here, our approach allows the efficacious detection of different viruses in citrus plants using a minimal amount of tissue during all seasons. The molecular methods described could be used in citrus certification programs and to test trees in nurseries and commercial orchards.

Evolutionary analysis of genetic variation observed in citrus tristeza virus (CTV) after host passage

We have studied the genetic variability in two genes (p18 and p20) from two groups of Citrus tristeza virus (CTV) isolates. One group (isolates T385, T317, T318, and T305) was derived from a Spanish source by successive host passages while the other (isolates T388 and T390) was obtained after aphid transmission from a Japanese source. A total of 274 sequences were obtained for gene p18 and 451 for p20. In the corresponding phylogenetic trees, sequences derived from the severe isolates (T318, T305, and T388) clustered together and separately from those derived from mild or moderate isolates (T385, T317, and T390), regardless of their geographic origin. Hierarchical analyses of molecular variance showed that up to 53% of the total genetic variability in p18 and up to 87% of the variation in p20 could be explained by differences in the pathogenicity features of the isolates. Neutrality tests revealed that different selection forces had been acting between isolates and between genes, with purifying selection being suggested for p18 from isolates T385 and T390 and for p20 from isolates T385, T317, and T388, and balancing selection for p18 from isolates T318, T305, and T388 and for p20 from isolates T318 and T390. Furthermore, several models of codon selection were observed, with purifying selection being the most notable one, compatible with low effective population size of the virus populations resulting from transmission bottlenecks. We found no evidence of recombination playing a significant role during p18 and p20 evolution in these isolates. These results suggest that hosts can be an important evolutionary factor for CTV isolates.

Assessment of sequence diversity in the 5'-terminal region of Citrus tristeza virus from India

Twenty-one Citrus tristeza virus (CTV) isolates from India were characterized, using genotype-specific multiple molecular markers (MMM) from the 54'-terminal region and two other overlapping primer pairs (CN487/489 and CN488/491) from ORF1a (697-1484 nucleotides (nt)). The 5'-terminal genotype-specific primer pairs amplified about 500 bases from the 5'-end of the CTV genomic RNA (gRNA). With the three different MMM, the VT genotype-specific primers amplified 19 Indian CTV isolates. The T30-specific primers amplified five isolates, and the T36 primer amplified only one isolate T36. All isolates were amplified with CN488/491 primers; however, only 20 isolates were amplified with CN487/489 pair. A phylogenetic tree, derived from the sequences of the different MMM primer-amplified products, placed all the isolates into four distinct genogroups. Three of these four groups were typified by the reference isolates T30, T36, and VT. The fourth group, represented by the isolate BAN-2, was considered as a new genogroup. A phylogenetic tree based on sequences of the CN487/491 amplified products and other published sequences placed all of the isolates in eight genogroups. Phylogenetic correlation over the three different regions sequences of these CTV isolates showed more sequence variability between 1082 and 1484nt than between 1 and 500 or 697-1105 nt of the CTV gRNA. Based on three different 5' regions sequences and phylogenetic analysis, it is hypothesized that isolates BAN-1, BAN-2, and B165 are three naturally occurring variants that add to the complexity of the CTV populations in India.

Genetic Marker Analysis of a Global Collection of Isolates of Citrus tristeza virus: Characterization and Distribution of CTV Genotypes and Association with Symptoms

ABSTRACT Genetic markers amplified from three noncontiguous regions by sequence specific primers designed from the partial or complete genome sequences of Citrus tristeza virus (CTV) isolates T3, T30, T36, and VT were used to assess genetic relatedness of 372 isolates in an international collection. Eighty-five isolates were judged similar to the T3 isolate, 81 to T30, 11 to T36, and 89 to VT. Fifty-one isolates were mixed infections by two or more identifiable viral genotypes, and 55 isolates could not be assigned unequivocally to a group defined by marker patterns. Maximum parsimony analysis of aligned marker sequences supported the grouping of isolates on the basis of marker patterns only. Specific disease symptoms induced in select citrus host plants were shared across molecular groups, although symptoms were least severe among isolates grouped by markers with the T30 isolate and were most severe among isolates grouped by markers with the T3 isolate. Isolates assigned the same genotype showed variable symptoms and symptom severity. A classification strategy for CTV isolates is proposed that combines genetic marker patterns and nucleotide sequence data.

Evidence of multiple recombination events between two RNA sequence variants within a Citrus tristeza virus isolate

Analysis of sequence variants of a natural Citrus tristeza virus (CTV) isolate (SY568) revealed that its population was composed of three sequence types: (I) the most frequent type had > or =97.9% nucleotide identity with the sequence predominant in severe CTV isolates from different origins; (II) a second variant, genetically close to the major component of several mild isolates, had < or =85% identity with the first; and (III) several variants (less than 4%) resulted from homologous recombination at one or more sites between sequences I and II. Recombination sites had an AU-rich stretch of 8-89 nucleotides shared by both parental sequences, flanked by GC- and AU-rich regions upstream and downstream, respectively. This context has been suggested as a hot-spot for homologous recombination in other RNA viruses.

Quantitative parameters determining whitefly (Bemisia tabaci) transmission of Lettuce infectious yellows virus and an engineered defective RNA

In this study, quantitative parameters affecting in vitro acquisition and whitefly (Bemisia tabaci) transmission of Lettuce infectious yellows virus (LIYV) were examined and B. tabaci transmission of an engineered defective RNA (D-RNA) was demonstrated. Virions purified from virus- and virion RNA-inoculated Chenopodium murale plants and protoplasts of Nicotiana tabacum, respectively, were consistently transmitted to plants by B. tabaci when virion concentrations were 0.1 ng microl(-1) or greater. Transmission efficiency increased with increasing virion concentration and number of whiteflies used for inoculation. When in vitro-derived transcripts of the M5gfp D-RNA (engineered to express the green fluorescent protein, GFP) were co-inoculated to protoplasts with wild-type LIYV virion RNAs, the resulting virions were transmissible to plants. LIYV and the M5gfp D-RNA systemically invaded inoculated plants; however, GFP expression was not detected in these plants. Unlike LIYV, the M5gfp D-RNA was not subsequently transmitted by B. tabaci from the initially infected plants, but, when high concentrations of virions from plants infected by LIYV and the M5gfp D-RNA were used for in vitro acquisition by whiteflies, both were transmitted to plants. Quantitative and qualitative analyses showed that, although the M5gfp D-RNA replicated within and systemically invaded plants along with LIYV, compared with LIYV RNA 2 it was not as abundant in plants or in the resulting virions, and concentration of encapsidated RNAs is an important factor affecting transmission efficiency.

Defective RNAs of Citrus tristeza virus analogous to Crinivirus genomic RNAs

The family Closteroviridae includes the genera Closterovirus and Ampelovirus with monopartite genomes and the genus Crinivirus with bipartite genomes. Plants infected with the Closterovirus, Citrus tristeza virus (CTV), often contain one or more populations of defective RNAs (dRNAs). Although most dRNAs are comparatively small (2-5 kb) consisting of the genomic RNA termini with large internal deletions, we recently characterized large dRNAs of approximately 12 kb that retained the open reading frames (ORFs) 1a plus 1b. These were self-replicating RNAs and appeared to be analogous to the genomic RNA 1 of the bipartite criniviruses. The present report describes the finding of an additional group of large dRNAs (LdRNAs) that retained all or most of the 10 3' ORFs and appeared to be analogous to genomic RNA 2 of criniviruses. Isolates associated with LdRNAs were found associated with double-recombinant dRNAs (DR-dRNAs) of various sizes (1.7 to 5.1 kb) that comprised the two termini and a noncontiguous internal sequence from ORF2. The genetic and epidemiological implications of the architectural identities of LdRNAs and DR dRNAs and their apparent analogy with the genomic RNA 2 of criniviruses are discussed.

Variation of haplotype distributions of two genomic regions of Citrus tristeza virus populations from eastern Spain

Genetic variation in natural populations of Citrus tristeza virus (CTV) was studied using haplotypes detected by single-strand conformation polymorphism (SSCP) analysis of two genomic regions (p20 gene and segment A, located in ORF1a). Analysis of 254 samples from 125 trees, collected at 12 different sites, yielded 8 different haplotypes for p20 and 5 for segment A. The most frequent haplotype of p20 was predominant at all sites, but several sites differed in the predominance of segment A haplotypes. At most sites, the homozygosity observed for the p20 gene tended to be higher than expected in a neutral evolution, whereas the opposite was true for segment A. Comparison of the populations at different sites showed that 44 of the 66 possible population pairs were genetically distinct for segment A, but only six pairs differed for the p20 gene. Analysis of molecular variance grouping trees by site, scion variety, rootstock or age, showed that variation in segment A was significantly affected by site, tree age and rootstock, and that variation between trees in each group and within trees was even more important. In contrast, variation in p20 was affected only by site and rootstock, each factor contributing to < 2% of the variation. The data suggest that sequence variations in segment A must be functionally less important and that it has less evolutionary constraints than p20. Detection of different haplotypes in neighbour trees or in samples from the same tree may help explain part of the variability observed in CTV symptom expression.

A novel class of large and infectious defective RNAs of Citrus tristeza virus

Citrus tristeza virus (CTV)-infected plants contain one or more populations of defective RNAs (dRNAs), mostly with a size range of ca. 2.0 to 5.0 kb. Several CTV dRNAs have been characterized and found to consist mainly of the two termini of the genomic RNA, with extensive internal deletions. The present paper describes a new class of large ( approximately 12.0 kb) dRNAs from three different CTV isolates with two unusual features. First is their composition with intact replicase genes. These dRNAs contained a large 5' portion of the genomic RNA terminus, which apparently corresponded to the recently described 5' large single-stranded subgenomic RNA (sgRNA) of ORF1a+1b (Che et al., 2001). The 3' portion of the large dRNAs varied among the 10 different cDNA clones examined in this work. In 2 dRNAs this portion consisted of truncated ORF10 (p20), and in 5 dRNAs it contained truncated ORF11 (p23). Two dRNA molecules were found with a 3' portion that started in the exact 5' position of the intergenic region between the p20 and p23 ORFs. In one dRNA, this portion coincided with the full-length sgRNA corresponding to ORF10. The second unusual feature was their ability to be readily transmitted mechanically to citrus plants by stem slashing and also to Nicotiana benthamiana protoplasts. The possibility that these dRNAs may be encapsidated and be capable of self-replication is discussed.

Green fluorescent protein expression from recombinant lettuce infectious yellows virus-defective RNAs originating from RNA 2

Lettuce infectious yellows virus (LIYV) RNA 2 defective RNAs (D RNAs) were compared in protoplasts for their ability to replicate and to express the green fluorescent protein (GFP) from recombinant D RNA constructs. Initially four LIYV D RNAs of different genetic composition were compared, but only two (LIYV D RNA M5 and M18) replicated to high levels. Both of these contained at least two complete ORFs, one being the 3'-terminal ORF encoding P26. Northern hybridization analysis using probes corresponding to 3' regions of LIYV RNA 2 detected the P26 subgenomic RNA from protoplasts infected with LIYV RNAs 1 and 2 or protoplasts inoculated only with RNA 1 plus either the LIYV D RNA M5 or M18, suggesting that these LIYV D RNAs served as templates to generate the P26 subgenomic RNA. The GFP coding region was inserted as an in-frame insertion into the P26 coding region of the LIYV M5 and M18 D RNAs, yielding M5gfp and M18gfp. When transcripts of M5gfp and M18gfp were used to inoculate protoplasts, bright fluorescence was seen only when they were co-inoculated with LIYV RNA 1. The percentage of fluorescent protoplasts ranged from experiment to experiment, but was as high as 5.8%. Time course analyses showed that fluorescence was not detected before 48 h pi, and this correlated with the timing of LIYV RNA 2 and RNA 2 D RNA accumulation, but not with that of LIYV RNA 1.

Genetic variation of Citrus tristeza virus isolates from California and Spain: evidence for mixed infections and recombination

We examined the population structure and genetic variation of four genomic regions within and between 30 Citrus tristeza virus (CTV) isolates from Spain and California. Our analyses showed that most isolates contained a population of sequence variants, with one being predominant. Four isolates showed two major sequence variants in some genomic regions. The two major variants of three of these isolates showed very low nucleotide identity to each other but were very similar to those of other isolates, suggesting the possibility of mixed infections with two divergent isolates. Incongruencies of phylogenetic relationships in the different genomic regions and statistical analyses suggested that the genomes of some CTV sequence variants originated by recombination events between diverged sequence variants. No correlation was observed between geographic origin and nucleotide distance, and thus from a genetic view, the Spanish and Californian isolates analyzed here could be considered members of the same population.

5'-coterminal subgenomic RNAs in citrus tristeza virus-infected cells

Three unusual 5' coterminal positive-stranded subgenomic (sg) RNAs, two of about 0.8 kb and one of 10 kb (designated LMT1, LMT2, and LaMT, respectively), from Citrus spp. plants and Nicotiana benthamiana protoplasts infected with Citrus tristeza virus (CTV) were characterized. The 5' termini of the LMT RNAs were mapped by runoff reverse transcription and found to correspond with the 5' terminus of the genomic RNA. The LMT 5'-coterminal sgRNAs consisted of two modal lengths of 744--746 and 842--854 nts. The 3' of the LaMT RNAs terminated near the junction of ORF 1b and ORF 2 (p33). None of the 5' sgRNAs had detectable amounts of corresponding negative-sense RNAs, as occurs with the genomic and 3' coterminal subgenomic RNAs of CTV. The abundance of the short and long 5' sgRNAs differed considerably in infected cells. The LMT RNAs were considerably more abundant than the genomic RNAs, while the larger LaMT RNA accumulated to much lower levels. The kinetics of accumulation of LMT1 and LMT2 in synchronously infected protoplasts differed. The larger RNA, LMT1, accumulated earlier with a strong hybridization signal at 2 days postinfection, a time when only traces of genomic and 3' sgRNAs were detected. The lack of corresponding RNAs, that could be 3' cleavage products corresponding to the 5' coterminal sgRNAs and the lack of complementary negative strands, suggest that these sgRNAs were produced by termination during the synthesis of the genomic positive strands.

The fitness of citrus tristeza virus defective RNAs is affected by the lengths of their 5'- and 3'-termini and by the coding capacity

Populations of the Closterovirus Citrus tristeza virus (CTV) generally contain defective RNAs (dRNAs) that vary in size, abundance, and sequence. The variation in abundance of the different dRNAs in a population suggests selection for those of higher fitness. To examine factors affecting fitness of dRNAs, we investigated a series of in vitro constructed dRNAs for their ability to be amplified in protoplasts by an efficiently replicated CTV deletion mutant. The minimal sequences required for accumulation of the dRNAs were within the genomic 5' proximal approximately 1 kb and the 3' 270 nucleotides. However, other factors were involved, because a dRNA with only the minimal sequences failed to be replicated. Rescue of a nonviable dRNA by insertion of nonviral sequences between the termini suggested that "spacing" between terminal cis-acting signals influenced fitness. A continuous open reading frame (ORF) through most of the sequences derived from the 5' of the genome was a requirement for dRNA amplification. In general, insertions, deletions, or nucleotide substitutions were tolerated in the dRNAs as long as an ORF was retained, whereas dRNAs with mutations that prematurely terminated the ORF were not viable. To discriminate between a requirement for an essential protein and ribosomal travel, perhaps to present replication signals to the replicase complex, mutations were made to modify the potential protein but still maintain an ORF. Deletions, insertions of nonviral sequences, or switching of reading frames that altered the amino acid sequence of the protein, except the N-terminal 161 amino acids, did not destroy the fitness of the dRNAs. Yet termination of the ORF in the middle of nonviral sequences did destroy the ability of the dRNAs to be amplified. These results suggest that even though a continuous ORF was needed for fitness, its protein product did not affect the amplification of the dRNAs.

Genetic Diversity and Evolution of Closteroviruses

The family Closteroviridae comprises more than 30 plant viruses with flexuous, filamentous virions and includes representatives with either mono- or bipartite positive-strand ssRNA genomes. Closteroviruses are transmitted semipersistently by insects from three families of Homoptera, in infected plants are associated with phloem tissue, and demonstrate an astonishing genetic diversity that suggests extensive, on-going evolution. Phylogenetic analyses of their replicative genes as well as the conserved HSP70 demonstrate that closteroviruses co-evolved with their insect vectors, resulting in three major lineages, i.e. aphid-, mealybug-, and whitefly-transmitted viruses. Closteroviruses apparently represent an ancient and diverse virus family that may pose threats to agriculture and needs serious attention.

Sequences of Citrus tristeza virus separated in time and space are essentially identical

The first Citrus tristeza virus (CTV) genomes completely sequenced (19.3-kb positive-sense RNA), from four biologically distinct isolates, are unexpectedly divergent in nucleotide sequence (up to 60% divergence). Understanding of whether these large sequence differences resulted from recent evolution is important for the design of disease management strategies, particularly the use of genetically engineered mild (essentially symptomless)-strain cross protection and RNA-mediated transgenic resistance. The complete sequence of a mild isolate (T30) which has been endemic in Florida for about a century was found to be nearly identical to the genomic sequence of a mild isolate (T385) from Spain. Moreover, samples of sequences of other isolates from distinct geographic locations, maintained in different citrus hosts and also separated in time (B252 from Taiwan, B272 from Colombia, and B354 from California), were nearly identical to the T30 sequence. The sequence differences between these isolates were within or near the range of variability of the T30 population. A possible explanation for these results is that the parents of isolates T30, T385, B252, B272, and B354 have a common origin, probably Asia, and have changed little since they were dispersed throughout the world by the movement of citrus. Considering that the nucleotide divergence among the other known CTV genomes is much greater than those expected for strains of the same virus, the remarkable similarity of these five isolates indicates a high degree of evolutionary stasis in some CTV populations.

Nucleotide sequence and organization of ten open reading frames in the genome of grapevine leafroll-associated virus 1 and identification of three subgenomic RNAs

The genome of Grapevine leafroll-associated virus 1 (GLRaV-1) was cloned and the sequence of 12394 nts determined. It contains 10 major open reading frames (ORFs) and a 3'-non-coding region lacking a poly(A) tract. The first ORF (ORF 1a) encodes a putative RNA helicase at the C-terminal portion of an apparently larger protein. The downstream ORF, 1b, overlaps ORF 1a and lacks an initiation codon. This ORF encodes an RNA-dependent RNA polymerase of M(r) 59276. ORF 2 encodes a small hydrophobic protein of M(r) 6736, and ORF 3 encodes a homologue of the HSP70 family of heat shock proteins and has an M(r) of 59500. ORF 4 encodes a protein with an M(r) of 54648 that shows similarity to the corresponding proteins of other closteroviruses. ORF 5 encodes the viral coat protein (CP) with an M(r) of 35416. The identity of this ORF as the CP gene was confirmed by expression in Escherichia coli and testing with the viral antibody. ORFs 6 and 7 code for two CP-related products with M(r) of 55805 and 50164, respectively. ORFs 8 and 9 encode proteins of M(r) 21558 and 23771 with unknown functions. Using DNA probes to different regions of the GLRaV-1 sequence, three major 3'-coterminal subgenomic RNA species were identified and mapped on the GLRaV-1 genome. Phylogenetic analyses of the individual genes of GLRaV-1 demonstrated a closer relationship between GLRaV-1 and GLRaV-3 than with other closteroviruses.

Replication of heterologous combinations of helper and defective RNA of citrus tristeza virus

Citrus tristeza virus (CTV) populations are among the more complex of plant RNA viruses with unusual mixtures of strains and defective RNAs (dRNAs). Citrus plants infected with different CTV isolates contain multiple dRNA molecules that differ in size and relative abundance within and between isolates. Additionally, we found mixtures of heterologous dRNAs in populations. To examine the replication of CTV dRNAs, the protoplast system had to be extended to support helper-assisted amplification of input dRNAs. The use of freshly extracted sap of CTV-infected tissue as inoculum increased the infection of Nicotiana benthamiana protoplasts sufficiently to result in accumulation of high levels of CTV RNAs as well as dRNAs within 2 or 3 days postinoculation. A series of dRNA-like molecules, each with a single large internal deletion, were created from an infectious cDNA clone of the CTV T36 isolate and examined for amplification in N. benthamiana protoplasts using a CTV deletion mutant as the helper virus. Of 12 synthetic dRNAs, only three with sizes of 3650, 3819, and 4460 nucleotides were efficiently replicated. CTV dRNA replication did not appreciably affect levels of accumulation of the genomic or the subgenomic RNAs of the helper virus. To investigate the maintenance of dRNAs in CTV populations, we examined heterologous interactions between dRNAs and helper viruses. Wild-type populations of heterologous strains T68 and T3, as well as the homologous T36, supported replication of synthetic T36 dRNAs. Replacement in the T36 dRNA of the 5' region, which is most variable among CTV strains, with the corresponding sequences from VT, T68, T3, or T30 resulted in chimeric dRNAs that failed to be replicated by the T36 helpers but were replicated to detectable levels by the T68 helper. The differential specificities of different CTV replicase complexes with dRNA replication signals is one possible factor that affects the maintenance of dRNA population structures.

Aphid Transmission Alters the Genomic and Defective RNA Populations of Citrus tristeza virus Isolates

ABSTRACT A total of 14 Spanish isolates of Citrus tristeza virus (CTV) and 1 isolate from Japan were transmitted by Aphis gossypii, and the subisolates obtained were compared with the source isolates for symptom expression and double-stranded RNA (dsRNA) pattern. Of the 14 Spanish isolates, 9 showed altered dsRNA patterns after aphid transmission but only minor variations in the intensity of symptoms induced on Mexican lime. Northern blot hybridization with complementary DNA (cDNA) probes corresponding to both the 5' and the 3' termini of the CTV genomic RNA (gRNA) showed that the dsRNA bands that could be used to discriminate between the dsRNA pattern of the source and the aphid-transmitted isolates were the replicative forms of defective RNAs (D-RNAs). Conversely, the Japanese isolate and two subisolates obtained from it by aphid transmission had the same dsRNA pattern, but one of the subisolates induced milder symptoms in several hosts. Dot-blot hybridization with cDNA probes representing several regions of the gRNA showed that most of the aphid-transmitted isolates differed from the corresponding source isolate by their hybridization pattern. Our results indicate that aphid transmission often sorts the populations of gRNA variants and D-RNAs present in CTV isolates.

Molecular characterization of an isolate of citrus tristeza virus that causes severe symptoms in sweet orange

The complete sequence (19,249 nucleotides) of the genome of citrus tristeza virus (CTV) isolate SY568 was determined. The genome organization is identical to that of the previously determined CTV-T36 and CTV-VT isolates. Sequence comparisons revealed that CTV-SY568, a severe stem-pitting isolate from California, has more than 87% overall sequence identity with CTV-VT, a seedling yellows isolate from Israel. Although SY568 has an overall sequence identity of 81% with CTV-T36, a quick decline isolate from Florida, the sequence identity in the 3' half of the genome is over 90% while the sequence identity in the 5' half of the genome is as low as 56%. Based on the sequence alignments of these three isolates, sequences in the 3' half of the genome are generally well conserved, while the sequences in the 5' half are relatively divergent. Sequence data of independent overlapping clones from the CTV-SY568 genome revealed two regions with highly divergent sequences. In open reading frame 1b (RNA dependent RNA polymerase), there were 118 nucleotide differences that lead to 16 amino acid changes. In the open reading frame of the divergent coat protein gene, 5 amino acid changes result from 48 nucleotide differences. Most differences occurred in the third position of the codons, and resulted in silent amino acid substitutions. RNase protection assays demonstrated that most of the clones obtained are representative of the major RNA species of this isolate. Northern analysis indicated that CTV-SY568 accumulated more viral RNA including genomic and certain subgenomic RNAs than isolates VT or T36 in sweet orange.

An engineered closterovirus RNA replicon and analysis of heterologous terminal sequences for replication

Citrus tristeza virus (CTV) populations in citrus trees are unusually complex mixtures of viral genotypes and defective RNAs developed during the long-term vegetative propagation of the virus and by additional mixing by aphid transmission. The viral replication process allows the maintenance of minor amounts of disparate genotypes and defective RNAs in these populations. CTV is a member of the Closteroviridae possessing a positive-stranded RNA genome of approximately 20 kilobases that expresses the replicase-associated genes as an approximately 400-kDa polyprotein and the remaining 10 3' genes through subgenomic mRNAs. A full-length cDNA clone of CTV was generated from which RNA transcripts capable of replication in protoplasts were derived. The large size of cDNA hampered its use as a genetic system. Deletion of 10 3' genes resulted in an efficient RNA replicon that was easy to manipulate. To investigate the origin and maintenance of the genotypes in CTV populations, we tested the CTV replicase for its acceptance of divergent sequences by creating chimeric replicons with heterologous termini and examining their ability to replicate. Exchange of the similar 3' termini resulted in efficient replication whereas substitution of the divergent (up to 58% difference in sequence) 5' termini resulted in reduced but significant replication, generally in proportion to the extent of sequence divergence.

Two paths of sequence divergence in the citrus tristeza virus complex

ABSTRACT Comparison of a sampling of complementary DNA (cDNA) sequences from the Florida citrus tristeza virus (CTV) isolates T3 and T30 to the sequence of the genome of the Israeli isolate VT showed a relatively consistent or symmetrical distribution of nucleotide sequence identity in both the 5' and 3' regions of the 19.2-kb genome. In contrast, comparison of these sequences to the sequence of isolate T36 showed a dramatic decrease in sequence identity in the 5' proximal 11 kb of the genome. A cDNA probe derived from this region of the T36 genome hybridized to double-stranded RNA (dsRNA) of only 3 of 10 different Florida CTV isolates. In contrast, analogous probes from T3 and T30 hybridized differentially to the seven isolates not selected by the T36 probe. Primers designed from cDNA sequence for polymerase chain reaction (PCR) selectively amplified these 10 isolates, allowing them to be classified as similar to T3, T30, or T36. In contrast, individual cDNA probes derived from the 3' terminal open reading frames of the T3, T30, and T36 genomes all hybridized to dsRNA from all Florida CTV isolates tested, and PCR primers designed from the T36 capsid protein gene sequence amplified successfully from all isolates. Based on these data, we propose the creation of two groups of CTV, exemplified by the VT and T36 isolates, respectively. Isolates in the VT group, which include isolates VT, T3, and T30, have genomic sequence divergence that is relatively constant in proportion and distribution throughout the genome, and candidate isolates for that group could be considered strains of the same virus. The T36 group is differentiated from the VT group by the highly divergent 5' genomic sequence. This 5' region of the CTV genome, thus, can serve as a measure of the extent of sequence divergence and can be used to define new groups and group members in the CTV complex.

D-RNA molecules associated with subisolates of the VT strain of citrus tristeza virus which induce different seedling-yellows reactions

Citrus tristeza virus (CTV) strains were previously catalogued as seedling-yellows (SY) and non-SY (nSY) types, according to their yellowing and stunting effects on indicator seedlings. Among subisolates of the VT strain, which were selected from chronically infected Alemow plants, there was a correlation between the presence of 2.4-, 2.7- and 4.5-kb D-RNAs, and SY and nSY reactions, respectively. Similarly, plants infected with Mor-T subisolates, which cause SY, contained D-RNAs of 2.6 to 2.8 kb, while nSY subisolates from recovered sour orange tissue contained a major D-RNA of 5.1 kb. Plants harboring the 2.7-kb D-RNA were protected against challenge inoculation with a subisolate harboring the 4.5-kb D-RNA. This study suggests that the nSY reaction results either from the absence of SY gene(s) in the genomes of certain CTV strains or through the suppression of the effects of SY gene(s) by D-RNAs with 5' parts larger than 4000nt.

Molecular variability of the 5'- and 3'-terminal regions of citrus tristeza virus RNA

ABSTRACT Isolates of citrus tristeza virus (CTV) differ widely in their biological properties. These properties may depend on the structure of viral RNA populations comprising the different isolates. As a first approach to study the molecular basis of the biological variability, we have compared the sequences of multiple cDNA clones of the two terminal regions of the RNA from different CTV isolates. The polymorphism of the 5' untranslated region (UTR) allowed the classification of the sequences into three groups, with intragroup sequence identity higher than 88% and intergroup sequence identity as low as 44%. The variability of an open reading frame (ORF) 1a segment adjacent to the 5' UTR supports the same grouping. Some CTV isolates contained sequences of more than one group. Most sequences from Spanish isolates belonged to group III, whereas a Japanese isolate was composed mostly of sequences of groups I and II. The mildest isolates contained only sequences of group III, whereas the most severe isolates also contained sequences of groups I, II, or both. The most stable secondary structure predicted for the 5' UTR was composed of two stem-loops and remained essentially unchanged as a result of compensatory mutations in the stems and accommodation of most of the variability in the loops. In contrast to the 5'-terminal region, the variability of the 3'-terminal region of CTV RNA was very much restricted, with nucleotide identity values higher than 90%. The presence of a conserved putative "zinc-finger" domain adjacent to a basic region in p23, the predicted product of ORF 11, suggests that this protein might act as a regulatory factor during virus replication.

New satellite RNAs, but no DI RNAs, are found in natural populations of tomato bushy stunt tombusvirus

A collection of 57 field isolates of the tombusvirus tomato bushy stunt virus was obtained from eggplant and tomato during 1994-1997 and was examined for the presence of defective interfering (DI) RNA species by Northern blot hybridization and RT-PCR. No DI RNA species were detected associated with any of the field TBSV isolates. However, serial passaging of two field isolates in Nicotiana clevelandii at high multiplicity of infection resulted in the rapid generation of DI-like RNA species, indicating that the absence of DI RNAs in natural populations of the virus was not due to the inability of the TBSV field isolates to generate them in a suitable host. The results indicate that DI RNAs may not play a role in modulating natural TBSV infections in the hosts examined. In 4 of 57 isolates analyzed we have detected less than full-length RNAs and we show here that they are true satellite RNAs. Two different satellite RNA species were detected, named TBSV sat RNAs B1 (822 nt) and B10 (612 nt). TBSV sat RNAs lack significant open reading frames and do not present sequence homology except in a central box that is also conserved in TBSV-Ch genomic RNA and in all the DI RNAs derived from it. TBSV sat RNA B10 attenuated the symptoms induced by the helper virus in N. clevelandii while sat RNA B1 did not modify the symptoms. This is the first report of sat RNAs associated with TBSV and the first time that sat RNAs are associated with natural tombusvirus infections.

Involvement of a subgenomic mRNA in the generation of a variable population of defective citrus tristeza virus molecules

The fusion sites between the termini of naturally occurring defective RNAs (D-RNAs) from three citrus tristeza virus (CTV) isolates were sequenced. Seven of eight clones showed a common 3' terminus of 940 nucleotides (nt) fused to 5' termini with different sizes. An extra cytosine nucleotide was found at the junction site of the majority of the common 3' D-RNAs. Molecular analysis of the plus and minus strands of the 0.9-kbp double-stranded RNA, corresponding to the CTV open reading frame 11 subgenomic RNA (sgRNA), showed that they were identical in length and sequence to the common 3' sequence of the D-RNAs. These results imply that viral sgRNA messengers also function as building components for genomic rearrangement and exchange of complete viral genes.

Transcriptional strategy of closteroviruses: mapping the 5' termini of the citrus tristeza virus subgenomic RNAs

Citrus tristeza virus (CTV) induces formation of a nested set of at least nine 3' coterminal subgenomic RNAs (sgRNAs) in infected tissue. The organization and expression of the 19,296-nucleotide (nt) CTV genome resembles that of coronaviruses, with polyprotein processing, translational frameshifting, and multiple sgRNA formation, but phylogenetically the CTV polymerase, like polymerases of other closteroviruses, belongs to the Sindbis virus-like lineage of RNA virus polymerases. Both positive-strand RNA virus supergroups, coronaviruses and Sindbis-like viruses, utilize different mechanisms of transcription. To address the mechanism of CTV transcription, 5' termini for the two most abundant sgRNAs, 1.5 and 0.9 kb, respectively, were mapped by runoff reverse transcription. The two sgRNAs were demonstrated to have 48- and 38-nt 5' untranslated regions (5'-UTRs), respectively. The 5'-UTR for the 1.5-kb RNA was cloned, sequenced, and demonstrated to be colinear with the 48-nt genomic sequence upstream of the initiator codon of the respective open reading frame 10, i.e., to be of continuous template origin. The data obtained suggest that the sgRNA transcription of CTV is dissimilar from the coronavirus transcription and consistent with the transcriptional mechanism of other Sindbis-like viruses. Thus, the Sindbis virus-like mechanism of transcription of the positive-strand RNA genomes might be successfully utilized by the closterovirus genome of up to 19.3 kb with multiple sgRNAs.

Characterization of Beet Yellows Closterovirus-Specific RNAs in Infected Plants and Protoplasts

ABSTRACT Tetragonia expansa plants infected with a California isolate of beet yellows virus (BYV-60) contained multiple BYV-specific RNAs identified by Northern blot hybridization. These RNAs were identified by cDNA probes specific to six open reading frames (ORFs). One genomic RNA and five subgenomic (sg) RNAs representing the p65/p6.4, p64, p24, p22, and p21 ORFs were identified. A probe derived from the 3'-terminal ORF (p21) hybridized to each of the sgRNAs, indicating the RNAs are 3' coterminal. Hybridization with 5'- and 3'-end probes indicated that preparations of BYV particles contained the genomic RNA as well as two additional RNA molecules corresponding in size to the coat protein (CP) sgRNA and an unidentified RNA. A Chenopodium quinoa protoplast system also was used to study BYV replication. The temporal accumulation of BYV-specific RNAs and CP was investigated in protoplasts transfected with purified virion RNA. Accumulation of genomic plus-strand RNA was evident as early as 15 h postinoculation. The development of this protoplast system is significant for studies of closterovirus replication.

Natural Field Spread of Mild and Severe Isolates of Citrus Tristeza Virus in Florida

The effectiveness of five different aphid control regimes in delaying movement of mild and severe isolates of citrus tristeza virus (CTV) into a CTV-free sweet orange scion on sour orange rootstock block was monitored annually for 5 years, using severe isolate-specific and isolate-nonspecific monoclonal antibodies. The average percentage of trees infected with a severe isolate of CTV was 32, 32, 20, 25, and 28 for trees treated with Temik, Temik + Meta-Systox R (MSR), MSR, stylet oil, or no aphid control, respectively, at the conclusion of the experiment (5 years). These percentages were not significantly different (P ≤ 0.05). The average percentage of trees infected only with mild isolates was 13, 10, 7, 7, and 17 for the above treatments, respectively. The infection with mild isolates was significantly greater (P ≤ 0.05) with no aphid control than with stylet oil or MSR treatments.

Serial passage of tobacco rattle virus under different selection conditions results in deletion of structural and nonstructural genes in RNA 2

The RNA genome of tobacco rattle virus (TRV) is bipartite. RNA 2 of the nematode-transmissible TRV isolate PPK20 encodes the viral coat protein (cp) and proteins with molecular weights of 29,400 and 32,800 (29.4K and 32.8K proteins). When this isolate was serially passaged in tobacco by using phenol-extracted RNA as the inoculum in each transfer, defective interfering (DI) RNAs rapidly accumulated. A number of these DI RNAs were cloned. Six DI RNAs had single internal deletions in RNA 2 that removed most of the cp gene, the 29.4K gene, and the 5' half of the 32.8K gene. The borders of the deletions in these DI RNAs were found to be flanked in the genomic RNA 2 by short nucleotide repeats or sequences resembling the 5' end of TRV genomic and subgenomic RNAs. Two DI RNAs were found to be recombinants containing a 5' sequence derived from RNA 2 and a 3' sequence derived from RNA 1. When serial passage of TRV isolate PPK20 was carried out by using leaf homogenates as inocula in each transfer, accumulation of a DI RNA (designated D7) with a functional cp gene was observed. The deletion in D7 covered the 3' end of the cp gene, the 29.4K gene, and the 5' half of the 32.8K gene. An infectious cDNA clone of D7 RNA was made. In mixed infections, D7 RNA rapidly outcompeted RNA 2 but did not compete with RNA 1. The deletion in D7 RNA abolished the nematode transmissibility of the PPK20 isolate. These results may explain the observation that many laboratory isolates of tobraviruses have lost their nematode transmissibility and contain RNA 2 molecules of widely different lengths.