First Report of Pitaya Virus X Infecting Lophocereus schottii f. mieckleyanus (Thin-Stemmed Totem Pole Cactus) in the United States

Lophocereus is a genus of three species of columnar cacti native to Arizona and Mexico (Lodi, 2015). These cacti produce several tall, ascending, columnar stems that branch at the base in a candelabra-like arrangement. The most common species, L. schottii is known as the senita cactus. Several unusual knobby-stemmed spineless forms of senita cactus have been found in nature in Baja California, Mexico, which are collectively known as totem pole cacti. The thin-stemmed totem pole cactus, L. schottii f. mieckleyanus is an important part of landscapes in southern Arizona. Cacti are clonally propagated which makes viral infections of economic importance in the ornamental/nursery industry. In February 2023, virus-like symptoms, such as mosaic and chlorotic spots were observed on the stems of L. schottii f. mieckleyanus grown in a nursery in Phoenix, AZ, USA. Total RNA was extracted from two symptomatic cacti (YPHC-61 A & B) following the protocol by Tzanetakis et al. (2007), and cDNA was synthesized using the Superscript IV Reverse Transcriptase (Invitrogen, Vilnius, Lithuania). Reverse transcription polymerase chain reaction (RT-PCR) performed with cactus virus X specific primers (Kim et al. 2016) targeting the coat protein (CP) gene failed to generate any amplicon, while potexvirus-replicase primers, Potex 2RC and Potex 5 (van der Vlugt and Berendsen 2002) targeting RNA-dependent RNA polymerase (RdRp) gene amplified an expected amplicon of ~580 bp from both the samples. One of the amplicons was Sanger sequenced and showed 90.7% nucleotide (nt) identity with pitaya virus X (PiVX) in the GenBank (MN982522). Sequence was submitted in the GenBank under the accession number OR425049. PiVX is a new species of the genus Potexvirus and is named after its origin from pitaya (Hylocereus spp.). Further, RT-PCR was conducted with PiVX-specific primers, CP 110F/CP 604R targeting CP gene (Bae and Park 2022) and RdRp gene (RdRp F 5' GCGTGGGCCCTGGAAAA-3'/RdRp R 5' CTAAGATTCATCAATTCACCTCTCC-3') (this study). Amplicons of ~500 and 1100 bp were obtained using primers, CP 110F/CP 604R and RdRp F/RdRp R, respectively. A BLAST search revealed 90.5% nt identity to PiVX CP sequences (OM802135 and OM802134) and 87.3% nt identity to RdRp sequences (MN982523 and LC654699) in the GenBank. Sequences of isolates YPHC-61A and YPHC-61B were submitted in the GenBank under accession numbers, OQ915350 and PP182358 (CP gene) and OQ915351 and PP209539 (RdRp gene). Phylogenetic analysis based on the combined sequence datasets of CP and RdRp genes also grouped YPHC-61A and YPHC-61B with PiVX isolates and separated from other potexviruses species. For a bioassay of the virus, sap extract from symptomatic cactus was mechanically inoculated onto indicator plant species, i.e., beans, alfalfa, and melon. Ten days post- inoculation, chlorotic lesions were observed on beans and alfalfa plants, while melon and mock-inoculated plants did not show any symptoms. Similarly, L. schottii f. mieckleyanus plants grafted with infected cactus showed chlorotic spots after 30 days post grafting. Mechanically inoculated beans, alfalfa, and cactus plants were found to be positive for PiVX based on RT-PCR and Sanger sequencing. PiVX has earlier been detected on Notocactus leninghausii f. cristatus (Park et al. 2018) and dragon fruit (Selenicereus undatus) plants in South Korea (Bae and Park 2022). To our knowledge, this is the first report of PiVX on L. schottii f. mieckleyanus in the United States and worldwide.

First Report of Narcissus late season yellows virus, Narcissus latent virus, and Narcissus mosaic virus in daffodil (Narcissus pseudonarcissus) in the United States

Daffodils (family Amaryllidaceae, genus Narcissus) are important ornamental plants produced primarily for cut flowers. In 2019, daffodils sales in the US were $6.26 M (USDA-NASS, 2019). In May 2021, four symptomatic daffodil plants (Narcissus pseudonarcissus) were sampled from a flowerbed (<10% disease incidence) on the Utah State University campus, Logan, Utah. The plants had foliar mosaic and yellow striping symptoms like those caused by the infections of Narcissus degeneration virus (NDV, a potyvirus) and Narcissus mosaic virus (NMV, a potexvirus) (Hanks and Chastagner 2017), and tested positive for potyviruses by ELISA Potyvirus group test (Agdia, Elkhart, IN). A sample of two leaves from the only surviving plant was sent to the USDA Plant Pathogen Confirmatory Diagnostics Laboratory (PPCDL) for testing. Total RNA extracted from 0.2 g pooled tissues (0.1g per leaf) using RNeasy Plant Mini kit (Qiagen) was tested for potyvirus in RT-PCR using Nib2F & Nib3R primers (Zheng et al. 2010). Later, the sample was tested for Narcissus latent virus (NLV) and NMV by RT-PCR (He et al. 2018) after the viruses were detected by high throughput sequencing (HTS) described below. A second primer pair was designed in-house targeting NMV TGB1 protein (NMV-2F: CCTTACACCACCGATCCTAAAG & NMV-2R: GGAGCTGCAGTGATGACATATAG. Amplicon size =555bp). The nucleotide (nt) sequence of the potyvirus RT-PCR product obtained (281 bp; GenBank accession no. ON653017) shared 99.29% identity with Narcissus late season yellows virus (NLSYV) BC 37 isolate (MH886515). The nt sequence of NLV-specific primer amplified product (542 bp; ON653018) showed 97.60% identity with NLV NL isolate (KX979913), a maculavirus. The amplicons obtained using two NMV-specific primer pairs were 348 bp (ON653019) and 524 bp (ON653020) long and shared 89.37% and 91.98% nt sequence identities with NMV SW13-Iris isolate (KF752593) at two genomic regions (5613-6860 nt and 5477-6000 nt), respectively. To obtain full genome sequences of the viruses in the sample, HTS was done. A cDNA library was prepared from 500 ng total RNA using the Direct cDNA sequencing kit (SQK-DCS109). The library was loaded onto an R9.4.1 MinION flow cell and sequenced for 48 hours. A total of 372,000 raw reads were obtained with a N50 of 2,754 bp and mean read length of 1,890 bp with 8,085 reads mapped to the viral database. Reads were assembled using canu v 2.1.1 (Koren et al. 2017). Three full-length viral contigs, ON677368 (6955 nt), ON677369 (9624 nt), and ON677370 (8180 nt), were assembled from 4616, 301, and 699 reads, respectively. BLASTn search showed that the three contigs (ON677368, ON677369, and ON677370) shared 94.42% nt identity with NMV SW13-Iris (KF752593), 98.56% with NLSYV BC 37 (MH886515.1), and 98.60% with NLV NL (KX979913.1) isolates, respectively. The potexvirus group, which NMV is a member, has species demarcation of < 72% nt identity (or 80% aa identity) between their coat protein or replicase genes (ICTV 2021). The predicted replicase protein sequence (1643 aa) of the detected NMV (ON677368) showed 95% identity with a published NMV genome (P15059), confirming its identity. NDV was not detected in the sample by RT-PCR and HTS. This is the first report of NLMV, NLSYV, and NMV in daffodil plants in the United States. Daffodils are an important ornamental crop in United States and Europe. A reduction in flower quality, bulb size, and number has been observed in plants infected with these viruses (Ward et al. 2009) that can affect their marketability.

First Report of the Association of Zygocactus virus X with Dragon Fruit (Hylocereus spp.) plants from Telangana, India

Dragon fruit (Hylocereus spp.) a member of the family Cactaceae, is widely cultivated throughout the world, includingspan style="font-family:'Times New Roman'; letter-spacing:0.05pt; color:#333333"> India. During 2020-2021 crop growing season, mosaic symptoms were observed on the cladodes of dragon fruit plants (Purple Pink cultivar: 1-2% disease incidence) grown at a farmer's field of Telangana, India (Fig. S1 a). The symptomatic cladodes (n= 4), observed under leaf-dip electron microscopy (Zuchmaan and Zellnig, 2009) at Indian Agricultural Research Institute, New Delhi, revealed the presence of flexuous rod- shaped virus-like particles (Fig S1 b). Virus particles were of 580 x 13 nm size, corresponding to the genus Potexvirus. For further confirmation, the total RNA isolated from symptomatic cladodes using a NucleoSpin RNA Plant Mini kit (Macherey-Nagel). Subsequently, a reverse transcription polymerase chain reaction (RT-PCR) was performed using the PrimeScript 1st strand cDNA Synthesis Kit (Takara Bio). The cDNA was further amplified with the primers specific to coat protein (CP) gene of four different species of the genus Potexvirus known to infect members of Cactaceae family. Four sets of primers were used for detection, viz., Cactus virus X (CVX) (F, 5'-ATGTCTACTACTGGAGTCCA-3'; R, 5'-CTACTCAGGGCCTGGGAGAA-3'); Pitaya virus X (PiVX) (F, 5'-ATGGCTACTCAAACAGCACAA-3'; R, 5'-CTACTCTGGGGAGGGAAG-3'); Schlumbergera virus X (SchVX) (F, 5'-ATGTCGACCACTCCATCTTC-3'; R, 5'-TTATTCAGGGGATGGTAGTA-3') and Zygocactus virus X (ZyVX) (F, 5'-ATGTCTAACACTGCAGGAGT-3'; R, TCATTC GGGACCCGGTAGGA-3') (Duarte et al., 2008; Janssen et al., 2021; Parameswari et al., 2021), by following the PCR profile (Park et al., 2018). The species-specific primers of CVX, PiVX and SchVX did not amplify any amplicon, whereas the primers specific to ZyVX at nucleotide position 5841-6521 from complete CP gene have resulted in amplification of expected size (~680 base pairs) from all the samples. The gel-purified RT-PCR products were cloned into a pDrive cloning vector (Qiagen, Germany) and sequenced bi-directionally using Sanger sequencing. The resultant sequences (681 nt) of the CP gene showed 98% (nucleotide) and 100% (amino acid) sequence similarity with the CP gene sequence (Accession No: KY581590) of ZyVX. Hence, one representative sequence was deposited to the NCBI GenBank database as ZyVX-DPC isolate (Accession number- OK415019). The Neighbour Joining Phylogenetic Tree constructed using MEGA6 software (Tamura et al. 2013) showed grouping of Indian ZyVX-DPC isolate with the previously reported ZyVX isolates from Korea, Taiwan, China and Germany (Fig. S1c). These results confirmed the association of ZyVX with the symptomatic cladodes of dragon fruit plants collected from Telangana, India. Earlier studies revealed that ZyVX is a member of the genus Potexvirus known to infect dragon fruit plants from Brazil and China (Duarte et al., 2008). In India until now, anthracnose disease (Colletotrichum siamense) and CVX from Hylocereus spp. were reported (Abirami et al., 2019; Parameswari et al., 2021). To the best of our knowledge, this is the first report of ZyVX infection on dragon fruit in India. The draon fruit, being vegetatively propagated and with increasing cultivable area in India (Abirami et al, 2019), the present study gains significance. Further studies on mode of virus transmission, estimation of crop yield losses, host range studies and finding out source of resistance are essential.

First Report of Distinct Bamboo mosaic virus (BaMV) Isolates Infecting Bambusa funghomii in Vietnam and the Identification of a Highly Variable Region in the BaMV Genome

New isolates of the Bamboo mosaic virus (BaMV) were identified in Bambusa funghomii bamboo in Vietnam. Sequence analyses revealed that the Vietnam isolates are distinct from all known BaMV strains, sharing the highest sequence identities (about 77%) with the Yoshi isolates reported in California, USA. Unique satellite RNAs were also found to be associated with the BaMV Vietnam isolates. A possible recombination event was detected in the genome of BaMV-VN2. A highly variable region was identified in the ORF1 gene, in between the methyl transferase domain and helicase domain. These results revealed the presence of unique BaMV isolates in an additional bamboo species in one more country, Vietnam, and provided evidence in support of the possible involvement of environmental or host factors in the diversification and evolution of BaMV.

An optimized nucleic acid isolation protocol for virus diagnostics in cassava (Manihot esculenta Crantz.)

Our group works on the detection and characterization of cassava viruses, supporting projects that involve large scale pathogen surveillance activities and resistance screening assays in multiple and remote locations. In order to comply with these applications, nucleic acid isolation protocols need to be cost effective, adjusted for samples that will stand long distance transport and harsh storage conditions, while maximizing the yield and quality of the nucleic acid extracts obtained. The method we describe here has been widely used and validated using different downstream tests (including, but not limited to, Rolling Circle Amplification and Illumina and Nanopore sequencing), but is currently unpublished. The protocol begins with milligram amounts of dry leaf samples stored in silica gel, does not require liquid Nitrogen nor phenol extraction and produces an average of 2.11 µg of nucleic acids per mg of dry tissue.•DNA purity estimations reveal OD260/280 ratios above 2.0 and OD260/230 ratios above 1.7, even for samples stored in silica gel for several months.•The high quality of the extracts is suitable for detection of DNA and RNA viruses, with high efficiency.•We suggest this method could be used as part of a gold standard kit for virus detection in cassava.

A Replicating Viral Vector Greatly Enhances Accumulation of Helical Virus-Like Particles in Plants

The production of plant helical virus-like particles (VLPs) via plant-based expression has been problematic with previous studies suggesting that an RNA scaffold may be necessary for their efficient production. To examine this, we compared the accumulation of VLPs from two potexviruses, papaya mosaic virus and alternanthera mosaic virus (AltMV), when the coat proteins were expressed from a replicating potato virus X- based vector (pEff) and a non-replicating vector (pEAQ-HT). Significantly greater quantities of VLPs could be purified when pEff was used. The pEff system was also very efficient at producing VLPs of helical viruses from different virus families. Examination of the RNA content of AltMV and tobacco mosaic virus VLPs produced from pEff revealed the presence of vector-derived RNA sequences, suggesting that the replicating RNA acts as a scaffold for VLP assembly. Cryo-EM analysis of the AltMV VLPs showed they had a structure very similar to that of authentic potexvirus particles. Thus, we conclude that vectors generating replicating forms of RNA, such as pEff, are very efficient for producing helical VLPs.

Development and optimization of a pepino mosaic virus-based vector for rapid expression of heterologous proteins in plants

Plant-virus-derived vectors are versatile tools with multiple applications in agricultural and medical biotechnology. In this study, we developed pepino mosaic virus (PepMV) (family Alphaflexiviridae; genus Potexvirus) into a vector for heterologous protein expression in plants. PepMV was initially cloned in a step-wise manner, fully sequenced and the full-length infectious clone was tested for infectivity in Nicotiana benthamiana. Initial infectious clones resulted in poor replication of PepMV and lack of systemic movement. Mutations in the viral sequence affected systemic infection. Two suspected mutations were altered to restore systemic infectivity. PepMV infection was apparent as early as 4 days post agroinfiltration (dpa) inoculation in N. benthamiana. A multiple cloning site was inserted into the PepMV genome for introduction and expression of foreign genes. Several modifications to the wild-type vector were made, such as a replacing the native subgenomic promoter (SGP) with a heterologous SGP, and introduction of translational enhancers and terminators, to improve heterologous expression of the foreign gene-of-interest. GFP was used as a reporter for monitoring virus infection and protein production. Strong GFP expression was observed as early as 4 dpa with a translational enhancer. The PepMV-based vector produces rapid expression of the foreign gene in comparison to two other potexvirus-based vectors. GFP production was monitored over time and optimal protein production was recorded between 5 and 7 dpa. GFP protein levels reached up to 4% and decreased to 0.5% total soluble protein at 7 and 14 dpa, respectively. Future studies will evaluate this virus-based vector for large-scale production of pharmaceutical compounds. KEY POINTS: • A pepino mosaic virus isolate was developed into a plant-based expression vector. • Expression levels of the heterologous protein were comparable or exceeded previously developed viral vectors. • Protein levels in plants were highest between 5 and 7 days and decreased gradually.

The use of functionally deficient viral vectors as visualization tools to reveal complementation patterns between plant viruses and the silencing suppressor p19

Plant virus transport complementation is classically observed as a helper virus allowing another virus to regain cell-to-cell or systemic movement through a restrictive host plant (Malyshenko et al., 1989). The complementation effect is usually studied by observing virus infection after co-infection or super-inoculation of the helper virus. We herein demonstrate the utility of functionally deficient viral vectors as tools to determine the contribution of individual viral genes to plant viral transport complementation. Two functionally deficient viral vectors were engineered that derive from foxtail mosaic potexvirus and sunn-hemp mosaic tobamovirus, namely FECT (FoMV Eliminate CP and TGB, (Liu and Kearney, 2010)) and SHEC (SHMV Eliminate CP gene, (Liu and Kearney, 2010)), respectively. FECT had all the ORFs removed except for the replicase and thus is defective for both long-distance and cell-to-cell movement. SHEC lacked only the coat protein ORF and retained the movement protein (MP) and is functional for cell-to-cell movement. When FECT and SHEC vectors were inoculated with the silencing suppressor p19 in different zones of the same leaf, FECT was enabled to express its reporter gene beyond the original inoculation zone. When FECT, SHEC, and p19 were individually inoculated in separate zones, both FECT and SHEC reporter gene expression was observed within the p19 zone, distant from the original virus inoculation points. These observations indicate that SHEC movement protein could create a trafficking network to allow viral RNAs of FECT and SHEC and p19/p19 transcript to move from cell to cell. This system provides a tool to visually monitor the movement of viruses and silencing suppressors as well as to identify the effects of individual viral components on virus movement.

Second generation of pepino mosaic virus vectors: improved stability in tomato and a wide range of reporter genes

BACKGROUND

Vectors based on plant viruses are important tools for functional genomics, cellular biology, plant genome engineering and molecular farming. We previously reported on the construction of PepGFP2a, a viral vector based on pepino mosaic virus (PepMV) which expressed GFP efficiently and stably in plants of its experimental host Nicotiana benthamiana, but not in its natural host tomato. We have prepared a new set of PepMV-based vectors with improved stability that are able to express a wide range of reporter genes, useful for both N. benthamiana and tomato.

RESULTS

We first tested PepGFPm1 and PepGFPm2, two variants of PepGFP2a in which we progressively reduced a duplication of nucleotides encoding the N-terminal region of the coat protein. The new vectors had improved GFP expression levels and stability in N. benthamiana but not in tomato plants. Next, we replaced GFP by DsRed or mCherry in the new vectors PepDsRed and PepmCherry, respectively; while PepmCherry behaved similarly to PepGFPm2, PepDsRed expressed the reporter gene efficiently also in tomato plants. We then used PepGFPm2 and PepDsRed to study the PepMV localization in both N. benthamiana and tomato cells. Using confocal laser scanning microscopy (CLSM), we observed characteristic fluorescent bodies in PepMV-infected cells; these bodies had a cytoplasmic localization and appeared in close proximity to the cell nucleus. Already at 3 days post-agroinoculation there were fluorescent bodies in almost every cell of agroinoculated tissues of both hosts, and always one body per cell. When markers for the endoplasmic reticulum or the Golgi apparatus were co-expressed with PepGFPm2 or PepDsRed, a reorganisation of these organelles was observed, with images suggesting that both are intimately related but not the main constituents of the PepMV bodies. Altogether, this set of data suggested that the PepMV bodies are similar to the potato virus X (PVX) "X-bodies", which have been described as the PVX viral replication complexes (VRCs). To complete the set of PepMV-based vectors, we constructed a vector expressing the BAR herbicide resistance gene, useful for massive susceptibility screenings.

CONCLUSIONS

We have significantly expanded the PepMV tool box by producing a set of new vectors with improved stability and efficiency in both N. benthamiana and tomato plants. By using two of these vectors, we have described characteristic cellular bodies induced by PepMV infection; these bodies are likely the PepMV VRCs.

Resolution of cassava-infecting alphaflexiviruses: Molecular and biological characterization of a novel group of potexviruses lacking the TGB3 gene

Several potexviruses (Family Alphaflexiviridae) have been reported infecting cassava (Manihot esculenta Crantz) in the Americas. They were isolated from severely diseased plants during the last 30-40 years and include: Cassava common mosaic virus (CsCMV), Cassava Caribbean mosaic virus (CsCaMV), Cassava Colombian symptomless virus (CsCSV) and Cassava virus X (CsVX). However, their definitive classification as distinct species remains unresolved for several reasons, including the lack of sequence data and unavailability of samples from original isolates. This complicates disease diagnostics, cassava germplasm exchange certification, evaluation of virus cleaning protocols and epidemiological studies. Furthermore, a recently detected novel alphaflexivirus, indicates that cassava-infecting potexviruses may be more diverse. To solve the identity of these viruses, we started indexing samples from different parts of Colombia using different sets of PCR primers, antisera available and inoculation to indicator plants. Results show that there are three major phylogenetic groups of potexviruses infecting cassava, and they correspond to CsCMV, CsVX and the newly identified Cassava new alphaflexivirus (CsNAV). Bioassays and sequence analysis established that isolates of CsNAV and CsVX cause latent infections in different cassava landraces, they are not efficiently transmitted to the indicator plant Nicotiana benthamiana and they lack the gene 3 of the conserved potexviral 'triple gene block' (TGB). In contrast, all isolates of CsCMV (which have a characteristic potexvirus genome arrangement) caused Cassava Common Mosaic Disease (CCMD) in single infections and were efficiently transmitted to N. benthamiana. Although phylogenetic analysis of the replicase sequence placed CsNAV and CsVX as members of the Potexvirus genus, their distinct genome arrangement and biological characteristics suggest they can be considered as members of a separate taxonomic group.

Transmission of Bamboo mosaic virus in Bamboos Mediated by Insects in the Order Diptera

Bamboo mosaic virus (BaMV), a member of the genus Potexvirus, is the major threat to bamboo cultivation. Similar to most potexviruses, the transmission of BaMV by insect vectors has not been documented previously. However, field observations of BaMV disease incidences suggested that insect vectors might be involved. In this study, we aimed to investigate the possibility of insect-mediated transmission of BaMV among bamboo clumps, in order to provide further insights into the infection cycles of BaMV for the development of effective disease management measures. From the major insects collected from infected bamboo plantations, BaMV genomic RNAs were detected inside the bodies of two dipteran insects, Gastrozona fasciventris and Atherigona orientalis, but not in thrips (Scirtothrips dorsalis). Artificial feeding assays using green fluorescent protein-tagged BaMV virions revealed that BaMV could enter the digestive systems and survive in the regurgitant and excretion of the dipterans. BaMV RNA could be retained in the dipterans for up to 4 weeks. Insect-mediated transmission assays indicated that both dipterans could transmit BaMV to bamboo seedlings through artificially created wounds with low infection efficiency (14 - 41%), suggesting that the dipterans may mediate the transmission in a mechanical-like manner. These results demonstrated that dipterans with sponge-like mouthparts may also serve as vectors for at least one potexvirus, BaMV, among bamboo plants. The finding suggested that dipteran insect control should be integrated into the disease management measures against BaMV infections.

Function and Structural Organization of the Replication Protein of Bamboo mosaic virus

The genus Potexvirus is one of the eight genera belonging to the family Alphaflexiviridae according to the Virus Taxonomy 2015 released by International Committee on Taxonomy of Viruses (www.ictvonline.org/index.asp). Currently, the genus contains 35 known species including many agricultural important viruses, e.g., Potato virus X (PVX). Members of this genus are characterized by flexuous, filamentous virions of 13 nm in diameter and 470-580 nm in length. A potexvirus has a monopartite positive-strand RNA genome, encoding five open-reading frames (ORFs), with a cap structure at the 5' end and a poly(A) tail at the 3' end. Besides PVX, Bamboo mosaic virus (BaMV) is another potexvirus that has received intensive attention due to the wealth of knowledge on the molecular biology of the virus. In this review, we discuss the enzymatic activities associated with each of the functional domains of the BaMV replication protein, a 155-kDa polypeptide encoded by ORF1. The unique cap formation mechanism, which may be conserved across the alphavirus superfamily, is particularly addressed. The recently identified interactions between the replication protein and the plant host factors are also described.

The coat protein of Alternanthera mosaic virus is the elicitor of a temperature-sensitive systemic necrosis in Nicotiana benthamiana, and interacts with a host boron transporter protein

Different isolates of Alternanthera mosaic virus (AltMV; Potexvirus), including four infectious clones derived from AltMV-SP, induce distinct systemic symptoms in Nicotiana benthamiana. Virus accumulation was enhanced at 15 °C compared to 25 °C; severe clone AltMV 3-7 induced systemic necrosis (SN) and plant death at 15 °C. No interaction with potexvirus resistance gene Rx was detected, although SN was ablated by silencing of SGT1, as for other cases of potexvirus-induced necrosis. Substitution of AltMV 3-7 coat protein (CPSP) with that from AltMV-Po (CP(Po)) eliminated SN at 15 °C, and ameliorated symptoms in Alternanthera dentata and soybean. Substitution of only two residues from CP(Po) [either MN(13,14)ID or LA(76,77)IS] efficiently ablated SN in N. benthamiana. CPSP but not CP(Po) interacted with Arabidopsis boron transporter protein AtBOR1 by yeast two-hybrid assay; N. benthamiana homolog NbBOR1 interacted more strongly with CPSP than CP(Po) in bimolecular fluorescence complementation, and may affect recognition of CP as an elicitor of SN.

P3N-PIPO of Clover yellow vein virus exacerbates symptoms in pea infected with white clover mosaic virus and is implicated in viral synergism

Mixed infection of pea (Pisum sativum) with Clover yellow vein virus (ClYVV) and White clover mosaic virus (WClMV) led to more severe disease symptoms (a phenomenon called viral synergism). Similar to the mixed ClYVV/WClMV infection, a WClMV-based vector encoding P3N-PIPO of ClYVV exacerbated the disease symptoms. Infection with the WClMV vector encoding ClYVV HC-Pro (a suppressor of RNA silencing involved in potyviral synergisms), also resulted in more severe symptoms, although to a lesser extent than infection with the vector encoding P3N-PIPO. Viral genomic RNA accumulated soon after inoculation (at 2 and 4 days) at higher levels in leaves inoculated with WClMV encoding HC-Pro but at lower levels in leaves inoculated with WClMV encoding P3N-PIPO than in peas infected with WClMV encoding GFP. Our results suggest that ClYVV P3N-PIPO is involved in the synergism between ClYVV and WClMV during pea infection through an unknown mechanism different from suppression of RNA silencing.

Genetic Composition of Pepino mosaic virus Population in North American Greenhouse Tomatoes

In just a few short years, pepino mosaic disease has quickly become endemic in greenhouse tomatoes around the world. Although three genotypes of Pepino mosaic virus (PepMV) were identified in the United States, genetic composition of PepMV in greenhouse tomato crops in North America has not been determined. In this study, genetic variability and population structure of PepMV were evaluated through nucleotide sequence comparison and phylogenetic analysis of two genomic regions (helicase domain and TGB2-3) derived from 91 cDNA clones that were derived from 31 field-collected samples. These samples were collected from several major greenhouse tomato facilities in five states in the United States and two provinces in Canada. All four major genotypes of PepMV (EU, US1, US2, and CH2) were found in North America. Three distinct genotypes (EU, US1, and US2) were found in mixed infection in samples collected from Arizona and Colorado, two genotypes (EU and CH2) in Texas, and a single genotype (EU) in Alabama and California and the provinces of British Columbia and Ontario in Canada. The complexity of population genetics of PepMV in the United States poses an additional challenge to the greenhouse tomato industry because a tomato cultivar with durable resistance to multiple genotypes of PepMV may be harder to develop.