Abstract
Soybean vein necrosis-associated virus (SVNaV) is a newly isolated tospovirus from field-grown soybeans in the United States. Polyclonal antibodies generated against the recombinant Escherichia coli-expressed nucleocapsid protein (NP) of the virus, reacted specifically with SVNaV and exhibited low, if any, cross-reactivity with other species within the genus Tospovirus. The serological results are in agreement with low sequence homology of the SVNaV-NP gene when compared with those of other tospovirus species, some of which are capable of infecting soybean naturally. Phylogenetic analysis utilizing NP sequences from several SVNaV isolates collected from different geographical regions and various soybean genotypes over 4 years showed close relationships, but distinct from the representatives of all the established serogroups or distinct serotypes within the genus of Tospovirus. All SVNaV isolates examined reacted strongly with the generated polyclonal antibodies. Collectively, our serological analyses suggest that SVNaV represents a new and distinct soybean-infecting tospovirus serotype. Furthermore, our data demonstrate that antiserum against NP has the potential to serve as a reliable probe for SVNaV detection in field-grown soybeans.
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Tospoviruses are responsible for considerable losses in a large number of agriculturally important crops worldwide (Pappu et al. 2009; Plyusnin et al. 2011). Several tospovirus species have been reported from field-grown soybeans in different parts of the world. These include Tomato spotted wilt virus (TSWV) (Golnaraghi et al. 2004; Nischwitz et al. 2006), Tomato yellow ring virus (TYRV) (Hassani-Mehraban et al. 2007), Groundnut ringspot virus (GRSV) (Pietersen and Morris 2002), and Groundnut bud necrosis virus (GBNV) (Bhat et al. 2002).
Soybean vein necrosis-associated virus (SVNaV) is a newly identified tospovirus originally isolated from field-grown soybeans in Tennessee (TN), USA, in 2008 (Tzanetakis et al. 2009). Soybean is a major legume crop in the United States with approximately 78.1 million acres under plantation in 2010. Symptomatic soybeans exhibited vein clearing and chlorosis of leaf tissues adjacent to veins (Fig. 1a), which eventually progressed to necrosis (Fig. 1b and c). Since observation of these symptoms in TN, the presence of similar symptoms in soybean fields in other soybean growing areas of the United States, including Kentucky (KY), and isolation of the virus have been reported (Zhou et al. 2011). In KY where the seasonal timing of appearance of symptoms was followed for 3 years, time of appearance of the symptoms varied from late June to early August of each year and symptomatic plants remained sporadic within soybean fields. Zhou et al. (2011) have noted that first symptoms appeared in Arkansas and Illinois in early June.
Organization of SVNaV genome is similar to other members of the genus Tospovirus within the family Bunyaviridae (Zhou et al. 2011). Tospovirus is the only genus in the family Bunyaviridae for which its members are capable of infecting plants. Member species are defined based on vector specificity, host range, serological properties and nucleoprotein (NP) gene characteristics (Chen et al. 2010; Plyusnin et al. 2011). According to the 9th report of the International Committee on Taxonomy of Viruses, the genus Tospovirus contains a total of eight definitive species with an additional 15 tentative species (Plyusnin et al. 2011).
Tospoviral virions, in general, consist of a core nucleocapsid protein (NP) encapsulating viral genome surrounded by a host-derived lipid membrane with two virally encoded glycoproteins (Plyusnin et al. 2011). NP is the most abundant structural protein of tospoviruses, and as such it has served well as a candidate for generation of antibodies. Indeed the majority of tospoviral monoclonal and polyclonal antibodies are directed against this structural protein of the virus (Chen et al. 2005; Jain et al. 2005; Wu et al. 2009). Current classification of tospoviruses based on serological relationship of NPs, has divided them into three related serogroups including Iris yellow spot virus (IYSV), Tomato spotted wilt virus (TSWV) and Watermelon silver mottle virus (WSMoV) (Chen et al. 2010). In addition, there are three distinct serotypes with no clear serological relationship with the established serogroups. These serotypes include Impatiens necrotic spot virus (INSV), Peanut yellow spot virus (PYCS), and Peanut chlorotic fan-spot virus (PCFV) (Chen et al. 2010; Chu et al. 2001; de Avila et al. 1993; Jain et al. 2005; Pappu et al. 2009). Another tospovirus species, Melon yellow spot virus (MYSV), was originally identified as a distinct serotype (Cortez et al. 2001; Kato et al. 2000); however, in a subsequent study by Chen et al. (2010), serological relationships based on NP between MYSV and WSMoV were demonstrated. More recently, a few additional serologically-distinct tospovirus species have also been identified (Bag et al. 2010; Dong et al. 2008; Hassani-Mehraban et al. 2005, 2010; Seepiban et al. 2011).
Comparative serological analyses of the NP of SVNaV with other tospovirus species, especially those infecting soybean, were the aim of this study. Due to the instability of virions of tospoviruses (Best 1968), the recombinant Escherichia coli-expressed NP of SVNaV was utilized as an immunogen to produce polyclonal antibodies. Subsequently, the generated antibodies were utilized for comparative serological analysis and development of an immunoassay for detection of SVNaV in soybean.
Soybean plants with typical SVNaV symptoms were collected from fields in TN and KY, USA, during growing seasons 2008 to 2011. Isolates TN1 and TN2 were collected in 2008 from TN. Isolates KY1 to KY3 were collected in 2009, KY4 to KY7 in 2010, and KY8 to KY10 in 2011. Soybean cultivars from which these isolates were collected included Asgrow 4630, Asgrow 4703, Asgrow 4707, Asgrow 5304, Southern States RT4996N, Southern States LL511N, Pioneer 94B73, Pioneer 94Y30, and Steyer 4430. The infected leaf tissues were stored at −80°C.
Inoculum for sap-inoculation was prepared by grinding the symptomatic leaf tissues in the presence of ice-cold 0.1 M phosphate buffer, pH 7.0 containing 0.2% sodium sulphite (w/v) and 1% (v/v) 2-mercaptoethanol (Mandal et al. 2008) and rub-inoculated onto carborundum-dusted (600 mesh) leaves of Nicotiana glutinosa L., N. benthamiana as well as various soybean genotypes including Williams, Lee68, and Asgrow 5304. The inoculated plants were kept in a growth chamber operating at 22°C with a photoperiod of 16 h and monitored for the appearance of symptoms up to 4 weeks postinoculation and screened for the presence of SVNaV by either RT-PCR or ELISA.
For cloning of the NP gene, total RNA from naturally infected soybean leaf tissues was isolated using the QIAGEN RNeasy Mini Kit (QIAGEN, Santa Clara, CA, USA). The first-strand cDNA was generated using 10-mer random primers in the presence of SuperScript II reverse transcriptase (Invitrogen, Carlsbad, CA, USA). Specific PCR primers utilized to detect SVNaV in the suspected leaf tissues were SVNaV-f1 (5′-AGATATAAAGTTGAGACACTATC-3′) and SVNaV-r1 (5′- TGCAACACATCCGGAACTCTG-3′) corresponding to nucleotide sequences 2553–2575 and 1636–1657 of small RNA from TN isolate, respectively (Zhou et al. 2011; GenBank accession no. HQ728387). The PCR program consisted of a cycle of 2 min at 95°C; 30 s at 94°C, 30 s at 56°C, 1 min at 72°C, 32 cycles; followed by final extension for 10 min at 72°C. In order to express NP, while cDNA generated with random primers served as a template, the entire NP gene of KY1 isolate was amplified in the presence of primers SVNaV-f2 (5′-CCT GAATTCATGCCACAAACAGCAGG-3′) and SVNaV-r2 (5′-TTA GCGGCCGCTAAACAGAAAACTCC-3′) (EcoRI and NotI sites are underlined whereas non-SVNaV sequences are bold-faced) corresponding to nucleotide sequences 2516–2533 and 1688–1703 of small RNA from TN isolate, respectively (Zhou et al. 2011; GenBank accession no. HQ728387). Subsequently, the amplicons were digested with EcoRI and NotI restriction enzymes (New England BioLabs, Beverly, MA, USA), and ligated in-frame with 6 × His-tag in the bacterial expression vector pET-28a (+) (Novagen, Madison, WI, USA). Following verification of the sequences by sequencing, the construct was transferred into E. coli strain BL21 (DE3) (Stratagene, La Jolla, CA, USA). Expression of the recombinant protein was induced in the presence of 1 mM isopropyl-β-d-thiogalactopyranoside (IPTG) (Promega, Madison, WI, USA). The recombinant poly-histidine tagged expressed protein was purified using Ni-NTA affinity column chromatography under native condition according to the QIAexpress protocol (Qiagen). Subsequently, the purified protein was subjected to SDS-PAGE analysis followed by amino acid sequencing using MALDI-TOF-MS/MS at the Iowa State University-Protein Facility (Ames, IA, USA).
Polyclonal antibodies against the recombinant SVNaV-NP were raised in a rabbit through a contract with Covance Inc. (Denver, PA, USA). Rabbit received a total of 1.75 mg of purified SVNaV-NP via 10 injections over a period of 6 months. Initially, 250 μg of the purified recombinant protein emulsified with Freund’s complete adjuvant (1:1 v/v) was administered. Subsequent injections (seven times with 125 μg protein per injection) were administered at 21-day intervals in the presence of incomplete Freund’s adjuvant. Finally, two booster injections with a total of 625 μg of SVNaV-NP were given each with a rest period of 1 month in between. Blood samples were taken at various intervals and the antisera were evaluated by antigen coated indirect-ELISA (AC-IELISA) (Malapi-Nelson et al. 2009) using bacterially expressed purified SVNaV-NP (0.1 μg/well) or sap from naturally infected soybean leaf tissues (1:10 w/v in carbonate buffer, pH 9.6) as antigens. For antiserum titration, serial dilutions were prepared in phosphate buffer saline (PBS; 3.2 mM Na2HPO4, 0.5 mM KH2PO4, 1.3 mM KCl, 135 mM NaCl, pH 7.4) containing 0.05% (v/v) Tween 20 and 5% (w/v) non-fat dry milk. To evaluate sensitivity of anti-SVNaV serum in detecting the virus in infected soybean tissues, serial dilutions of sap extracts in carbonate buffer, pH 9.6 was probed with a constant dilution of the antiserum (1:2000). Absorbance values exceeding mean value of background (i.e. reaction with sap extract from healthy soybean) + 3X standard deviation were considered positive for ELISA. The ability of anti-SVNaV serum to detect the virus in soybean infected tissues by western-immunoblotting was also evaluated where five leaf discs (~1 cm each) were collected from the symptomatic areas of leaves of field-grown soybean plants, pulverized in the presence of liquid nitrogen and homogenized in 1 ml of extraction buffer [0.625 M Tris–HCl pH 8, 2% (w/v) SDS, 10% (v/v) 2-mercaptoethanol, 10% (v/v) glycerol] (Harlow and Lane 1988). The homogenate was briefly vortexed, boiled for 5 min and centrifuged at 10,000 rpm for 10 min. The supernatant recovered, mixed with equal volume of loading buffer [0.25 M Tris–HCl pH 6.8, 8% (w/v) SDS, 30% (v/v) Glycerol, 0.02% (w/v) bromophenol blue and 5% (v/v) 2-mercaptoethanol)], boiled for 10 min and 10 μl of each sample loaded per lane. Western-immunoblotting was done essentially as described by Towbin et al. (1979).
Serological relationship between SVNaV and other tospovirus species infecting soybean or representatives of distinct serotypes or serogroups were evaluated by AC-IELISA. These included GRSV, INSV, Tomato chlorotic spot virus (TCSV), TSWV and TYRV. Polyclonal antibodies against these tospoviruses, as well as their homologous antigens, were all supplied by AC Diagnostics (AC Diagnostics Inc., Fayetteville, AR, USA). Positive samples consisted of plant extracts from tospoviruses infected plant tissues were used as supplied.
Calculation of amino acid sequence identity was done by GeneDoc version 2.6.2002 (http://www.psc.edu/biomed/genedoc/). Multiple sequence alignment was performed using Clustal X Version 2.0 (Larkin et al. 2007). Phylogenetic tree was constructed by MEGA software version 4.0 based on the neighbour joining (NJ) method and the interior reliability of each branch by the bootstrap value with 1,000 replicates (Tamura et al. 2007).
The PCR amplicons harbouring the entire NP gene from SVNaV with an expected size of 834 nucleotides encoding 277 amino acids was obtained from the field-grown symptomatic soybean leaf tissues (data not shown). The recombinant E. coli-expressed NP was obtained and purified under native conditions. Based on SDS-PAGE analysis, the purified expressed protein was a single polypeptide with a molecular mass of 33 kDa (Fig. 2). This was slightly larger than the predicted size of the NP based on the deduced amino acid sequences of the gene (30.8 kDa). This anomaly in size is likely due to fusion to His-tag and being expressed as a recombinant protein. The observation that bacterially expressed NP was recognized by monoclonal antibody against histidine-tag in western-immunoblotting (data not shown) provided supports for the recombinant nature of the purified protein. Nevertheless, amino acid sequencing using MALDI-TOF/TOF MS/MS unequivocally confirmed the identity of the purified recombinant protein as SVNaV-NP (data not shown). Therefore, it was subsequently utilized as an immunogen for generation of polyclonal antibodies.
The antiserum obtained in the last bleeding was utilized for polyclonal antibody characterization, serological analyses and immunoassay development. The dilution end point of the antiserum to detect 0.1 μg purified recombinant SVNaV-NP in AC-IELISA was 1:64,000. However, when the antiserum was titrated against sap extract derived from naturally infected soybean leaf tissues, its dilution end point was 1:8,000. The antiserum at a dilution of 1:2000 was sensitive enough to detect as low as 0.1 ng of bacterially expressed purified NP in AC-IELISA and could detect SVNaV in sap extract from naturally infected soybean leaf tissues diluted up to 1:512. The antiserum reacted weakly (O. D. 405 nm 0.21 ± 0.07) with sap extract from healthy soybean leaf tissues at various sap dilutions up to 1:512 tested. The antiserum showed broad specificity against SVNaV as it detected all virus isolates in AC-IELISA (data not shown) demonstrating close serological relationships among geographically distinct isolates from various soybean genotypes. Furthermore, the antiserum was efficient in detecting SVNaV in the infected leaf tissues by western-immunoblotting (Fig. 3).
The NP genes of all 12 ELISA-positive SVNaV isolates collected in this study were RT-PCR amplified and directly sequenced. Comparative analysis showed high levels of sequence identity (98–100%) among all the isolates at both nucleotide and amino acid levels (data not shown), including isolate TN that its entire genome sequence is published (Zhou et al. 2011; GenBank accession no. HQ728387). On the other hand, the NP of SVNaV isolates shared low degree of amino acid sequence identity with those of other soybean infecting tospovirus species or representative of serogroups or distinct serotypes. These included TYRV (31%); TSWV (30%); GRSV (30%); GBNV (30%); WSMoV (28–29%); INSV (28%); and PCFV (17–18%). In general, the threshold value of NP amino acid sequence identity for a distinct tospovirus is less than 90% (Plyusnin et al. 2011). Thus, any tospovirus with the NP amino acid sequence identity less than 90% with those of other known tospoviruses should be considered as a distinct species (Plyusnin et al. 2011; Jones 2005). Hence, these data confirm that SVNaV is a distinct tospovirus species (Zhou et al. 2011). A phylogenetic tree based on amino acid sequence of NP from all SVNaV isolates collected in this study as well as TN isolate (Zhou et al. 2011) revealed that all were grouped together and occupied the same position distinct from the other species examined (Fig. 4). Hence, this further confirms that SVNaV is a phylogenetically distinct species from all the other tospovirus species studied here and elsewhere (Zhou et al. 2011). Our phylogenetic data also demonstrate that all the SVNaV isolates, regardless of the geographical origin, soybean genetic background and time of collection, occupied the same position.
The serological relationships between SVNaV and GRSV, INSV, TCSV, TSWV and TYRV were examined in AC-IELISA (Fig. 5). As expected, each of the antisera exhibited the strongest reaction with its homologous antigen (Fig. 5). There was low, if any, serological cross-reactivity between SVNaV antiserum and the other tospovirus species examined. Likewise, antisera to other tospoviruses cross-reacted poorly or not at all with two SVNaV isolates tested (Fig. 5). These observations indicate that SVNaV is a distinct serotype. Furthermore, they are in complete agreement with the low amino acid sequence identity observed between SVNaV-NP and other tospoviruses (Fig. 4; Zhou et al. 2011). As expected and shown in Fig. 5, cross-reactivity was observed among GRSV, TCSV, and TSWV, which are all members of TSWV serogroup (Feldhoff et al. 1997; Jain et al. 2005; Lovato et al. 2004). INSV is a distinct serotype belonging to INSV serogroup (Chen et al. 2010). Antiserum to TYRV did not cross-react with any of the other tospoviruses tested (Fig. 5). TYRV is considered as a distinct tospovirus species as well (Hassani-Mehraban et al. 2005, 2010). The antigenic uniqueness of SVNaV among tospoviruses capable of infecting soybean naturally offers an opportunity to detect the virus reliably in the infected field-grown soybeans immunologically even though the plants may be co-infected by other tospoviral species (Bhat et al. 2002; Golnaraghi et al. 2004; Hassani-Mehraban et al. 2007; Nischwitz et al. 2006; Pietersen and Morris 2002).
There are currently two different assays available for detection of SVNaV in the infected soybean tissues; RT-PCR (Zhou et al. 2011) and AC-IELISA (present study). Our AC-IELISA is capable of detecting the virus only in the symptomatic tissues and our attempts to detect the virus in non-symptomatic tissues of the same infected soybean leaves failed (data not shown). It is interesting to note that RT-PCR also amplified SVNaV sequences only from the symptomatic areas of the infected leaves (data not shown). These observations suggest that possibly SVNaV is not capable of moving efficiently in the infected soybean leaves and likely the virus is not well-adapted to soybean. Despite a number of attempts, we did not succeed in transmitting SVNaV by sap-inoculation to any of the inoculated plants including to the same soybean genotype (Asgrow 4630) from which one of the isolate was collected. Under the same inoculation conditions, an isolate of TSWV consistently infected two tobacco species inoculated (data not shown) suggesting our inoculation method was optimal for transmission of tospoviruses that are known to be mechanically transmissible (Plyusnin et al. 2011). This observation further supports the possibility that SVNaV is not a well-adapted virus to soybean and may have been introduced to soybean recently from another host. The observation that SVNaV isolates collected from different soybean genotypes and from different geographical regions over a period of 4 years have a high level of NP sequence identity also supports the likelihood that soybean is a recent host of SVNaV.
Due to difficulty in sap-inoculation of SVNaV, we have not been able to reproduce the symptoms observed under the field conditions experimentally. Hence, the fulfillment of Koch’s postulate that SVNaV is indeed the sole causal agent of soybean vein necrosis disease requires a breakthrough in experimental transmission of the virus. Nevertheless, we have consistently detected SVNaV in symptomatic leaf tissues from field-grown soybean exhibiting typical disease symptoms. This has been noted by Zhou et al. (2011) as well.
Our serological data presented in this paper are in complete agreement with a recent report that SVNaV was defined as a new and distinct tospovirus species based on nucleotide sequences (Zhou et al. 2011). Our phylogenetic analysis of SVNaV isolates from KY and TN demonstrate little variation among NP of these isolates regardless of the geographical origin or the genetic background of soybean cultivars and year of collection. This observation supports our conclusion that polyclonal antibodies against the NP of SVNaV coupled with AC-IELISA has the potential to serve as a quick, reliable and economical assay for large scale surveys of soybean fields for the presence of the virus, provided symptomatic tissues with typical disease symptoms are screened. This immunoassay also has the potential to play an essential role for screening of soybean germplasm for finding sources of resistance to SVNaV once an optimal method for the experimental transmission of the virus is in place.
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Acknowledgements
We wish to thank AC Diagnostics (AC Diagnostics Inc., Fayetteville, AR, USA) for providing antisera against tospoviruses and their homologous antigens and two anonymous reviewers for their constructive comments. This research was supported by a grant from Tennessee soybean promotion board.
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The nucleotide sequence data reported in this article have been deposited in the GenBank under accession numbers JF808207-JF808215 and JQ277450-JQ277452.
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Khatabi, B., Wen, RH., Hershman, D.E. et al. Generation of polyclonal antibodies and serological analyses of nucleocapsid protein of Soybean vein necrosis-associated virus: A distinct soybean infecting tospovirus serotype. Eur J Plant Pathol 133, 783–790 (2012). https://doi.org/10.1007/s10658-012-9969-5
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DOI: https://doi.org/10.1007/s10658-012-9969-5