M. R. Hajimorad

Loss and Gain of Elicitor Function of Soybean Mosaic Virus G7 Provoking Rsv1-Mediated Lethal Systemic Hypersensitive Response Maps to P3

ABSTRACT Rsv1, a single dominant resistance gene in soybean PI 96983 (Rsv1), confers extreme resistance against all known American strains of Soybean mosaic virus (SMV), except G7 and G7d. SMV-G7 provokes a lethal systemic hypersensitive response (LSHR), whereas SMV-G7d, an experimentally evolved variant of SMV-G7, induces systemic mosaic. To identify the elicitor of Rsv1-mediated LSHR, chimeras were constructed by exchanging fragments between the molecularly cloned SMV-G7 (pSMV-G7) and SMV-G7d (pSMV-G7d), and their elicitor functions were assessed on PI 96983 (Rsv1). pSMV-G7-derived chimeras containing only P3 of SMV-G7d lost the elicitor function, while the reciprocal chimera of pSMV-G7d gained the function. The P3 regions of the two viruses differ by six nucleotides, of which two are translationally silent. The four amino acid differences are located at positions 823, 915, 953, and 1112 of the precursor polypeptide. Analyses of the site-directed point mutants of both the viruses revealed that nucleotide substitutions leading to translationally silent mutations as well as reciprocal amino acid substitution at position 915 did not influence the loss or gain of the elicitor function. pSMV-G7-derived mutants with amino acid substitutions at any of the other three positions lost the ability to provoke LSHR but induced SHR instead. Two concomitant amino acid substitutions at positions 823 (V to M) and 953 (K to E) abolished pSMV-G7 elicitor function, provoking Rsv1-mediated SHR. Conversely, pSMV-G7d gained the elicitor function of Rsv1-mediated LSHR by a single amino acid substitution at position 823 (M to V), and mutants with amino acid substitutions at position 953 or 1112 induced SHR instead of mosaic. Taken together, the data suggest that strain-specific P3 of SMV is the elicitor of Rsv1-mediated LSHR.

Cytoplasmic inclusion cistron of Soybean mosaic virus serves as a virulence determinant on Rsv3-genotype soybean and a symptom determinant

Soybean mosaic virus (SMV; Potyvirus, Potyviridae) is one of the most widespread viruses of soybean globally. Three dominant resistance genes (Rsv1, Rsv3 and Rsv4) differentially confer resistance against SMV. Rsv1 confers extreme resistance and the resistance mechanism of Rsv4 is associated with late susceptibility. Here, we show that Rsv3 restricts the accumulation of SMV strain G7 to the inoculated leaves, whereas, SMV-N, an isolate of SMV strain G2, establishes systemic infection. This observation suggests that the resistance mechanism of Rsv3 differs phenotypically from those of Rsv1 and Rsv4. To identify virulence determinant(s) of SMV on an Rsv3-genotype soybean, chimeras were constructed by exchanging fragments between avirulent SMV-G7 and the virulent SMV-N. Analyses of the chimeras showed that both the N- and C-terminal regions of the cytoplasmic inclusion (CI) cistron are required for Rsv3-mediated resistance. Interestingly, the N-terminal region of CI is also involved in severe symptom induction in soybean.

Adaptation of Soybean mosaic virus Avirulent Chimeras Containing P3 Sequences from Virulent Strains to Rsv1-Genotype Soybeans Is Mediated by Mutations in HC-Pro

In Rsv1-genotype soybean, Soybean mosaic virus (SMV)-N (an avirulent isolate of strain G2) elicits extreme resistance (ER) whereas strain SMV-G7 provokes a lethal systemic hypersensitive response (LSHR). SMV-G7d, an experimentally evolved variant of SMV-G7, induces systemic mosaic. Thus, for Rsv1-genotype soybean, SMV-N is avirulent whereas SMV-G7 and SMV-G7d are both virulent. Exploiting these differential interactions, we recently mapped the elicitor functions of SMV provoking Rsv1-mediated ER and LSHR to the N-terminal 271 amino acids of P3 from SMV-N and SMV-G7, respectively. The phenotype of both SMV-G7 and SMV-G7d were rendered avirulent on Rsv1-genotype soybean when the part of the genome encoding the N-terminus or the entire P3 cistron was replaced with that from SMV-N; however, reciprocal exchanges did not confer virulence to SMV-N-derived P3 chimeras. Here, we describe virulent SMV-N-derived P3 chimeras containing the full-length or the N-terminal P3 from SMV-G7 or SMV-G7d, with or without additional mutations in P3, that were selected on Rsv1-genotype soybean by sequential transfers on rsv1 and Rsv1-genotype soybean. Sequence analyses of the P3 and helper-component proteinase (HC-Pro) cistrons of progeny recovered from Rsv1-genotype soybean consistently revealed the presence of mutations in HC-Pro. Interestingly, the precise mutations in HC-Pro required for the adaptation varied among the chimeras. No mutation was detected in the HC-Pro of progeny passaged continuously in rsv1-genotype soybean, suggesting that selection is a consequence of pressure imposed by Rsv1. Mutations in HC-Pro alone failed to confer virulence to SMV-N; however, reconstruction of mutations in HC-Pro of the SMV-N-derived P3 chimeras resulted in virulence. Taken together, the data suggest that HC-Pro complementation of P3 is essential for SMV virulence on Rsv1-genotype soybean.

Experimental adaptation of an RNA virus mimics natural evolution.

ABSTRACT Identification of virulence determinants of viruses is of critical importance in virology. In search of such determinants, virologists traditionally utilize comparative genomics between a virulent and an avirulent virus strain and construct chimeras to map their locations. Subsequent comparison reveals sequence differences, and through analyses of site-directed mutants, key residues are identified. In the absence of a naturally occurring virulent strain, an avirulent strain can be functionally converted to a virulent variant via an experimental evolutionary approach. However, the concern remains whether experimentally evolved virulence determinants mimic those that have evolved naturally. To provide a direct comparison, we exploited a plant RNA virus, soybean mosaic virus (SMV), and its natural host, soybean. Through a serial in vivo passage experiment, the molecularly cloned genome of an avirulent SMV strain was converted to virulent variants on functionally immune soybean genotypes harboring resistance factor(s) from the complex Rsv1 locus. Several of the experimentally evolved virulence determinants were identical to those discovered through a comparative genomic approach with a naturally evolved virulent strain. Thus, our observations validate an experimental evolutionary approach to identify relevant virulence determinants of an RNA virus.

Evaluation of North American isolates of Soybean mosaic virus for gain of virulence on Rsv‐genotype soybeans with special emphasis on resistance‐breaking determinants on Rsv4

Resistance to Soybean mosaic virus (SMV) in soybean is conferred by three dominant genes: Rsv1, Rsv3 and Rsv4. Over the years, scientists in the USA have utilized a set of standard pathotypes, SMV-G1 to SMV-G7, to study interaction with Rsv-genotype soybeans. However, these pathotypes were isolated from a collection of imported soybean germplasm over 30 years ago. In this study, 35 SMV field isolates collected in recent years from 11 states were evaluated for gain of virulence on soybean genotypes containing individual Rsv genes. All isolates were avirulent on L78-379 (Rsv1), whereas 19 were virulent on L29 (Rsv3). On PI88788 (Rsv4), 14 of 15 isolates tested were virulent; however, only one was capable of systemically infecting all of the inoculated V94-5152 (Rsv4). Nevertheless, virulent variants from 11 other field isolates were rapidly selected on initial inoculation onto V94-5152 (Rsv4). The P3 cistrons of the original isolates and their variants on Rsv4-genotype soybeans were sequenced. Analysis showed that virulence on PI88788 (Rsv4) was not associated, in general, with selection of any new amino acid, whereas Q1033K and G1054R substitutions were consistently selected on V94-5152 (Rsv4). The role of Q1033K and G1054R substitutions, individually or in combination, in virulence on V94-5152 (Rsv4) was confirmed on reconstruction in the P3 cistron of avirulent SMV-N, followed by biolistic inoculation. Collectively, our data demonstrate that SMV has evolved virulence towards Rsv3 and Rsv4, but not Rsv1, in the USA. Furthermore, they confirm that SMV virulence determinants on V94-5152 (Rsv4) reside on P3.

Diagnostic Potential of Polyclonal Antibodies Against Bacterially Expressed Recombinant Coat Protein of Alfalfa mosaic virus

Alfalfa mosaic virus (AMV), a pathogen of a wide range of plant species, including Glycine max (soybean), is poorly immunogenic. Polyclonal antibodies were generated against bacterially expressed recombinant coat proteins (rCPs) of two biologically distinct AMV strains in rabbits and compared with those raised against native and glutaraldehyde-treated virions of the same strains. Analyses showed that sera against rCPs had comparable antibody titers in indirect enzyme-linked immunosorbent assay with those raised against virions when soybean sap containing homologous viruses served as antigens. Polyclonal antibodies against rCPs were specific, sensitive, and detected all AMV isolates that originated from soybean fields from geographically different regions of the United States. Comparison of CP genes of these isolates showed 96 to 99 and 96 to 100% nucleotide and amino acid sequence identities, respectively, suggesting that they are all closely related. This was further confirmed by phylogenetic analysis where they were all clustered together along with representative AMV strains belonging to group I. Collectively, our data demonstrate that, despite poor immunogenicity of AMV, polyclonal antibodies against rCP are effective probes for detection and diagnosis of the virus.

Genetic variability and phylogenetic analysis of hosta virus X

Triple gene block 1 (TGB1) and coat protein (CP) sequences of 30 hosta virus X (HVX) isolates from Tennessee (TN), USA, were determined and compared with available sequences in GenBank. The CPs of all known HVX isolates, including those from TN, shared 98.3–100% and 98.2–100% nucleotide and amino acid sequence identity, respectively, whereas TGB1 shared 97.4–100% nucleotide and 97–100% amino acid sequence identity. TGB1 of TN isolates were all longer by one codon from that of a Korean isolate, which is the only sequence publicly available. Phylogenetic analysis of nucleotide and amino acid sequences of TGB1 and CP of all known HVX isolates, separately or combined, revealed a close relationship, suggesting that all of them are derived from a common ancestor. Phylogenetic analysis with the type member of each genus of the family Flexiviridae confirmed that HVX is a member of a distinct species of the genus Potexvirus.

Amino acid substitution in P3 of Soybean mosaic virus to convert avirulence to virulence on Rsv4‐genotype soybean is influenced by the genetic composition of P3

The modification of avirulence factors of plant viruses by one or more amino acid substitutions converts avirulence to virulence on hosts containing resistance genes. Limited experimental studies have been conducted on avirulence/virulence factors of plant viruses, in particular those of potyviruses, to determine whether avirulence/virulence sites are conserved among strains. In this study, the Soybean mosaic virus (SMV)-Rsv4 pathosystem was exploited to determine whether: (i) avirulence/virulence determinants of SMV reside exclusively on P3 regardless of virus strain; and (ii) the sites residing on P3 and crucial for avirulence/virulence of isolates belonging to strain G2 are also involved in virulence of avirulent isolates belonging to strain G7. The results confirm that avirulence/virulence determinants of SMV on Rsv4-genotype soybean reside exclusively on P3. Furthermore, the data show that sites involved in the virulence of SMV on Rsv4-genotype soybean vary among strains, with the genetic composition of P3 playing a crucial role.

Plant Genetic Resistance to Viruses

Plants have evolved a variety of active and passive mechanisms to defend themselves against viral pathogens, and disease resistance genes have been incorporated into crop plants to protect against diseases caused by viruses. The specificity of resistance genes is usually limited to a virus species or group of highly related species, and there is not natural resistance available to all viruses of economic importance. For these reasons, there has also been great interest in developing or engineering novel virus resistance traits based on our knowledge of plant antiviral immune systems such as RNA silencing. With the recent emergence of technologies based on site-specific nucleases that can be used to manipulate the sequence of genes within crop plant genomes, there are now opportunities to further exploit our knowledge of plant-virus interactions to develop plants with novel forms of resistance. However, viruses have the potential to rapidly evolve to overcome resistance whether it is natural or engineered. Therefore, it is essential that we understand factors that influence the durability of resistance traits to maximize their longevity. In this chapter, we briefly highlight different forms of natural and engineered virus resistance mechanisms, discuss approaches to use genome editing for developing virus resistant plants, and explore the issue of durability as it relates to both natural and engineered resistance traits. Finally, we consider future research prospects that will continue to expand our knowledge of host-virus interactions and provide a solid foundation for understanding and possibly predicting resistance durability.

Development of an RT-PCR/RFLP assay to detect Hosta virus X in hosta (Hosta spp.)

Summary Hosta virus X (HVX) is the most damaging virus of hosta (Hosta spp.). By taking advantage of the conserved coat protein (CP) sequences of characterised isolates of HVX, a reliable and sensitive diagnostic assay, based on RT-PCR, was developed. The conserved, single Hind II recognition site within the CP sequences was also exploited for restriction fragment length polymorphism (RFLP)-based verification of the amplicons. The reliability of the assay was demonstrated by successful amplification of 30 HVX isolates from 20 cultivars of hosta. The effectiveness of the assay was demonstrated by detecting several distinct isolates of HVX in a mechanically-inoculated hosta cultivar containing a low virus titre. The assay was capable of detecting HVX in composite samples consisting of a single HVX-infected leaf disc, approx. 1 cm in diameter, combined with up to 200 virus-free leaf discs of similar size, which demonstrated its potential for large-scale screening. The sensitivity of the assay was not affected by genetic variation in the hosta cultivars or in the virus isolates. We conclude that RT-PCR/RFLP is reliable, sensitive, and efficient for large-scale screening of hosta for HVX infection.