Yellow Squash and Zucchini Cultivar Selection for Resistance to Cucurbit Leaf Crumple Virus in the Southeastern United States

Large populations of sweetpotato whiteflies (Bemisia tabaci) have become more regular occurrences during the fall months in parts of the southeastern United States. Large populations of sweetpotato whiteflies have resulted in a significant increase in the incidence of sweetpotato whitefly-transmitted viruses, particularly the cucurbit leaf crumple virus (CuLCrV), which has the potential to cause complete yield loss of fall-planted yellow squash and zucchini (Cucurbita pepo). This study evaluated commercial cultivars of yellow squash and zucchini for resistance against CuLCrV and estimated the yield and fruit quality under environmental conditions during the fall growing season in the southeastern United States. A factorial experimental design was conducted with nine yellow squash and 11 zucchini cultivars during Fall 2017, Fall 2018, and Fall 2019 in Tifton, GA. In situ weather stations monitored the weather conditions during growing seasons, and yellow pest monitor cards monitored the sweetpotato whitefly populations in 2018 and 2019. During all growing seasons, yellow squash and zucchini plants were rated weekly for the severity of CuLCrV. Harvests were conducted 12 times during each season, and fruit were graded as fancy, medium, and culls. Rainfall distribution directly affected the sweetpotato whitefly populations during the production year. In 2018, frequent rainfall events created field conditions that reduced the sweetpotato whitefly populations compared with those during 2017 and 2019. The severity of CuLCrV negatively impacted both the yield and quality of fruit of yellow squash and zucchini, and no resistant commercial cultivars of yellow squash or zucchini were identified. Nonetheless, the yellow squash cultivars Lioness, Gold Prize, and Grand Prize, and the zucchini cultivars SV6009YG and SV0914YG had the highest yields when subjected to the highest sweetpotato whitefly populations during the study.

First report of watermelon crinkle leaf-associated virus 1 (WCLaV-1) and WCLaV-2 in watermelon (Citrullus lanatus L.) plants co-infected with Cucurbit chlorotic yellows virus in Florida

Watermelon (Citrullus lanatus L.) and other cucurbits are major crops in Florida. During the 2020 and 2021 seasons, watermelon plants with foliar virus-like symptoms of yellow mottling and chlorosis, mild leaf wrinkling and thickened leaves were observed in commercial fields (40 to 150 ha) in five counties (Desoto, Glades, Osceola, Seminole, and Charlotte) at >50% field incidence. Initial screening of 13 field-collected samples (2 to 4/County) for potyviruses with the Agdia POTY Immunostrip (Agdia, Inc. Elkhart, IN) were negative. Total nucleic acid extracts from each sample (RNeasy Plant Mini Kit, Qiagen, Germantown, MD) were used in one-step RT-PCR (Qiagen OneStep RT-PCR kit) with species-specific primer targeting squash vein yellowing virus (SqVYV), papaya ringspot virus-W (PRSV-W) (Adkins et al., 2008), cucurbit yellow stunting disorder virus (CYSDV) (Polston et al. 2008), cucurbit chlorotic yellows virus (CCYV) (Hernandez et al., 2021a), watermelon crinkle leaf-associated virus 1 (WCLaV-1), and WCLaV-2 (Hernandez et al., 2021b). The samples were also tested for cucurbit leaf crumple virus (CuLCrV) as per Hagen et al. (2008). All 13 samples were negative for SqVYV, PRSV-W, CuLCrV, and CYSDV, but 7 samples (53.8%) from 4 counties tested positive for CCYV, 12 (92.3%) from 5 counties were positive for WCLaV-1, and WCLaV-2 was detected in 8 samples (61.5%) from 5 counties. Three samples were singly infected with WCLaV-1 while the remaining 10 were mixed infected with different combination of 2 or 3 viruses. Notably, symptoms on all 13 plants were visually indistinguishable. To verify the results, two randomly chosen gene-specific fragments per virus, obtained with primers CCYV-v1330/c2369, CCYV-v4881/c5736, WCLaV-1vRP/1cRP, WCLaV-1vMP/1cMP, WCLaV-2vRP/2cRP, and WLaV 2vMP/2cMP, were excised from the gel, cloned, and Sanger-sequenced as described (Hernandez et al., 2021a, 2021b). In pairwise comparisons, the ~1 kb partial ORF1a (GenBank accession nos. MZ325846 to MZ325847) and 753 bp complete coat protein cistron (MZ325848 to MZ325849) of CCYV from Florida shared 98.9-99.5%/98.4-99.6% nucleotide (nt)/amino acid (aa) and 99.4-99.8%/99.6-100% nt/aa identities, respectively with the corresponding sequences of global CCYV isolates. The partial RNA1 (MZ325850 to MZ325851) and RNA2 (MZ325852 to MZ325853) sequences of WCLaV-1 from Florida shared 99.2-99.8%/100% nt/aa and 98.9-100%/99.3-100% nt/aa identities, respectively with the corresponding global sequences of WCLaV-1 isolates. Lastly, the partial RNA1 (MZ325854 to MZ325857) and RNA2 (MZ325858 to MZ325861) sequences of WCLaV-2 from Florida shared 96.4-99.8%/97-100% nt/aa and 96.5-100%/95.9-100% nt/aa identities, respectively with the corresponding global sequences of WCLaV-2 isolates. This is the first report of WCLaV-1 and WCLaV-2 from Florida and the first documentation of the occurrence of CCYV in South Florida. CCYV has been reported previously from California (Wintermantel et al. 2019), Georgia (Kavalappara et al. 2021), and recently from North Florida (M. Paret, pers. comm) but WCLaV-1 and WCLaV-2 have only been reported from Texas (Hernandez et al., 2021b), after their discovery in China (Xin et al. 2017). The results indicate further expansion of the geographical range of these cucurbit-infecting viruses, although their longer but undetected presence in Florida is plausible due to the resemblance of their associated symptoms with those attributed to known viruses. References Adkins, et al., 2008. Plant Dis. 92:1119-1123. https://apsjournals.apsnet.org/doi/10.1094/PDIS-92-7-1119. Hagen, et al. 2008. Plant Dis. 92:781-793. https://apsjournals.apsnet.org/doi/pdfplus/10.1094/PDIS-92-5-0781. Hernandez, et al. 2021a. Plant Dis. https://doi.org/10.1094/PDIS-02-21-0378-PDN. Hernandez, et al., 2021b. Plant Dis. https://doi.org/10.1094/PDIS-02-21-0249-PDN Kavalappara, et al., 2021. Plant Dis. https://doi.org/10.1094/PDIS-11-20-2429-PDN. Polston, et al. 2008. Plant Dis. 92(8):1251. https://apsjournals.apsnet.org/doi/10.1094/PDIS-92-8-1251B. Wintermantel, et al., 2019. Plant Dis. 103(4):778. https://doi.org/10.1094/PDIS-08-18-1390-PDN. Xin, et al., 2017. Front. Microbiol. 8:1514, doi: 10.3389/fmicb.2017.01514.

High Throughput Sequencing-Aided Survey Reveals Widespread Mixed Infections of Whitefly-Transmitted Viruses in Cucurbits in Georgia, USA

Viruses transmitted by the sweet potato whitefly (Bemisia tabaci) have been detrimental to the sustainable production of cucurbits in the southeastern USA. Surveys were conducted in the fall of 2019 and 2020 in Georgia, a major cucurbit-producing state of the USA, to identify the viruses infecting cucurbits and their distribution. Symptomatic samples were collected and small RNA libraries were prepared and sequenced from three cantaloupes, four cucumbers, and two yellow squash samples. An analysis of the sequences revealed the presence of the criniviruses cucurbit chlorotic yellows virus (CCYV), cucurbit yellow stunting disorder virus (CYSDV), and the begomovirus cucurbit leaf crumple virus (CuLCrV). CuLCrV was detected in 76%, CCYV in 60%, and CYSDV in 43% of the total samples (n = 820) tested. The level of mixed infections was high in all the cucurbits, with most plants tested being infected with at least two of these viruses. Near-complete genome sequences of two criniviruses, CCYV and CYSDV, were assembled from the small RNA sequences. An analysis of the coding regions showed low genetic variability among isolates from different hosts. In phylogenetic analysis, the CCYV isolates from Georgia clustered with Asian isolates, while CYSDV isolates clustered with European and USA isolates. This work enhances our understanding of the distribution of viruses on cucurbits in South Georgia and will be useful to develop strategies for managing the complex of whitefly-transmitted viruses in the region.

Cucurbit leaf crumple virus (CuLCrV) associated to watermelon disease in Campeche state, Mexico

An annual recurrent disease causing yield reduction in cultivated watermelon (Citrullus lanatus) was documented by the growers in different farms of Campeche state, Mexico. In April 2019 and March 2020 open field grown watermelon plants showed symptoms such as leaf curling, crumpling, and leaf basal or apical necrosis (Figure S1), with an incidence ranging from 30 up to 80%. These plants also presented high populations of whitefly, especially in the most affected fields. In order to identify the causal agent of the disease, a total of 22 symptomatic watermelon plants were collected in four locations from Campeche state. Total nucleic acids (DNA and RNA) were extracted from these leaf samples. Initially, RT-PCR analysis was performed with specific primers (Table S1) for cucurbit-infecting Crinivirus transmitted by whitefly but the expected size PCR product for those viruses was not amplified in any of these samples. To investigate the presence of cucurbit-infecting begomoviruses, PCR was performed by using specific primers for those begomoviruses reported in Mexico and north/central America including Squash leaf curl virus (SLCV), Watermelon chlorotic stunt virus (WmCSV), Melon chlorotic leaf curl virus (MCLCuV), and Cucurbit leaf crumple virus (CuLCrV) (Table S1). Only the expected amplicon size of ~1089 bp for CuLCrV was amplified from DNA extracts from all 22 watermelon samples, suggesting a single cucurbit-associated virus. The putative complete genome of the CuLCrV Campeche isolate was amplified by circular DNA enrichment using a Rolling Circle Amplification (RCA) procedure from two representative samples, followed by enzymatic digestion using BamHI, EcoRI, KpnI, and SacI enzymes (Inoue-Nagata et al., 2004). Expected linearized full-length viral components (~2.7 kb) were obtained with EcoRI and SacI, and both products, from one selected sample, were cloned in to pGreen0029 vector and were fully sequenced. Sequence analysis of the EcoRI clone, designated as LV2019Camp_A (deposited in GenBank accession no. MW273384) revealed the highest identity of 97.52% to CuLCrV DNA-A isolate Baja California Sur isolate (GeneBank accession no. MN625831.1), whereas the KpnI clone, designated as LV2019Camp_B (deposited in GenBank accession no. MW273385), shared 94.87% identity with DNA B of CuLCrV isolate Arizona (GeneBank accession no. AF327559.1). Subsequently, CuLCrV isolate Campeche-derived agroinfectious clone, was obtained by constructing a partial dimeric tandem repeat of both DNA-A and DNA-B components (Bang et al., 2014). Twelve watermelon plants were agroinfiltrated with the infectious clone at the fourth true leaf stage, resulting in symptomatic plants (11/12) exhibiting leaf yellowing, curling, and crumpling 15 days after agroinfiltrated (Figure S1), and CuLCrV infection was confirmed by PCR specific detection using DNA extract from non-inoculated leaves. Previously CuLCrV has been detected in the USA (Arizona, Texas, California, Florida, South Carolina, and Georgia), and north Mexico (Coahuila) infecting cucurbits including squash, cucumber, cantaloupe, pumpkin, and watermelon (Brown et al., 2000., Keinath et al., 2018), in both single and mixed infection with other whitefly transmitted RNA viruses (CYSDV, genera Crinivirus), and DNA viruses (SLCV, genera Begomovirus) (Kuo et al., 2007). To our knowledge, this is the first report of CuLCrV infecting a cucurbit crop in the Campeche state from the Yucatán peninsula, in Mexico.

Whole-genome sequencing and phenotyping revealed structural variants and varied level of resistance against leaf crumple disease in diverse lines of snap bean (Phaseolus vulgaris)

The production and quality of Phaseolus vulgaris (snap bean) have been negatively impacted by leaf crumple disease caused by two whitefly-transmitted begomoviruses; cucurbit leaf crumple virus (CuLCrV) and sida golden mosaic Florida virus (SiGMFV), which often appear as a mixed infection in Georgia. Host resistance is the most economical management strategy against whitefly-transmitted viruses. Currently, information is not available with respect to resistance to these two viruses in commercial cultivars. In two field seasons (2018 and 2019), we screened Phaseolus sp. genotypes (n = 84 in 2018; n = 80 in 2019; most of the genotypes were common in both years with a few exceptions) for resistance against CuLCrV and/or SiGMFV. Twenty genotypes with high- to moderate-levels of resistance (disease severity ranging from 5-50%) to CuLCrV and/or SiGMFV were identified. Twenty-one genotypes were found to be highly susceptible with a disease severity of ≥66%. Adult whitefly counts differed significantly among snap bean genotypes for both years. The whole genome of these Phaseolus sp. (n=82) genotypes was sequenced and genetic variability among them was identified. Over 900 giga-base (Gb) of filtered data were generated and >88% of the resulting data were mapped to the reference genome, and SNP and Indel variants in Phaseolus genotypes were obtained. A total of 645,729 SNPs and 68,713 Indels including 30,169 insertions and 38,543 deletions were identified, which were distributed in 11 chromosomes with chromosome 02 harboring the maximum number of variants. These phenotypic and genotypic information will be helpful in genome-wide association studies that will aid in identifying genetic basis of resistance to these begomoviruses in Phaseolus sp.

Low Frequency of Horizontal and Vertical Transmission of Cucurbit Leaf Crumple Virus in Whitefly Bemisia tabaci Gennadius

Cucurbit leaf crumple virus (CuLCrV), a bipartite begomovirus, is transmitted by whiteflies in a persistent and circulative manner. Like other begomoviruses, CuLCrV transmission via feeding is well understood; however, whether and how CuLCrV is transmitted by horizontal and vertical modes in its vector, Bemisia tabaci, remains unexplored. We studied transovarial and mating transmission of CuLCrV, and comparatively analyzed virus accumulation in whiteflies through feeding and nonfeeding modes. Furthermore, we quantified CuLCrV DNA A accumulation at different time points to determine whether this virus propagates in whiteflies. CuLCrV DNA A was transmitted vertically and horizontally by B. tabaci, with low frequency in each case. Transovarial transmission of CuLCrV DNA A was only 3.93% in nymphs and 3.09% in adults. Similarly, only a single viruliferous male was able to transmit CuLCrV DNA A to its nonviruliferous female counterparts via mating. In contrast, viruliferous females were unable to transmit CuLCrV DNA A to nonviruliferous males. Additionally, the recipient adults that presumably acquired CuLCrV transovarially and via mating were not able to transmit the virus to squash plants. We further report that the CuLCrV DNA A viral copy numbers were significantly lower in nonfeeding modes of transmission than in feeding ones. The viral copy numbers significantly decreased at succeeding time points throughout adulthood, suggesting no CuLCrV propagation in B. tabaci. Altogether, the low frequency of nonfeeding transmission, reduced virus accumulation in whiteflies, and absence of plant infectivity through nonfeeding transmission suggest that transovarial and mating CuLCrV transmission might not substantially contribute to CuLCrV epidemics.

Development of Loop-Mediated Isothermal Amplification Assay for Rapid Detection of Cucurbit Leaf Crumple Virus

A loop-mediated isothermal amplification (LAMP) assay was developed for simple, rapid and efficient detection of Cucurbit leaf crumple virus (CuLCrV), one of the most important begomoviruses that infects cucurbits worldwide. A set of six specific primers targeting a total 240 nt sequence regions in the DNA A of CuLCrV were designed and synthesized for detection of CuLCrV from infected leaf tissues using real-time LAMP amplification with the Genie® III system, which was further confirmed by gel electrophoresis and SYBR™ Green I DNA staining for visual observation. The optimum reaction temperature and time were determined, and no cross-reactivity was seen with other begomoviruses. The LAMP assay could amplify CuLCrV from a mixed virus assay. The sensitivity assay demonstrated that the LAMP reaction was more sensitive than conventional PCR, but less sensitive than qPCR. However, it was simpler and faster than the other assays evaluated. The LAMP assay also amplified CuLCrV-infected symptomatic and asymptomatic samples more efficiently than PCR. Successful LAMP amplification was observed in mixed virus-infected field samples. This simple, rapid, and sensitive method has the capacity to detect CuLCrV in samples collected in the field and is therefore suitable for early detection of the disease to reduce the risk of epidemics.

Detection of Cucurbit Yellow Stunting Disorder Virus Infecting Watermelon in South Carolina

Watermelon is an important cucurbit crop grown in 44 states in the United States of America (USA). South Carolina (SC) had the seventh largest watermelon production area in USA with 4,500 acres in 2018 valued at approximately $17 million. In June 2019, four watermelon plants displaying symptoms of virus infection including stunting, leaf crumpling, interveinal chlorosis, and necrosis of leaf margins were observed in a research trial in Charleston, SC. Whiteflies were observed on the abaxial surface of the leaves. One plant was tested for the presence of whitefly-transmitted cucurbit leaf crumple virus (CuLCrV), cucurbit yellow stunting disorder virus (CYSDV), and squash vein yellowing virus and aphid-transmitted papaya ringspot virus by RT-PCR. Amplicons of the expected size were only observed for CuLCrV (∼1 kb) and CYSDV (∼0.7 kb). Because CYSDV was not previously reported from SC, we continued to monitor the field for virus symptoms during the summer season. By mid-August 2019, 15 additional plants (1.9% incidence) were observed with similar symptoms of virus infection. Two virus identification methods (CP and Hsp70h) confirmed that CYSDV was indeed present in watermelon samples in SC. The geographic range of CYSDV and other whitefly-transmitted viruses continues to expand into and within major cucurbit-producing regions with each production season, especially in the southeastern USA. This is the first report of CYSDV infecting watermelon or any other plant in SC. These three whitefly-transmitted viruses now need to be considered in management plans by SC growers. Knowledge of the presence of CYSDV, an additional virus, infecting cucurbits, in SC is also important from a regulatory perspective.

First Report of Cucurbit Leaf Crumple Virus Infecting Three Cucurbit Crops in South Carolina

Virus-like symptoms of curled and crumpled leaves, bright yellow chlorosis, and marginal leaf necrosis typical of begomovirus infection were observed on watermelon, summer squash, and muskmelon in three counties in South Carolina in August 2017. Genus-specific primers for begomovirus-A and begomovirus-B components produced amplicons of the expected sizes. Sanger sequencing of amplicons from both A and B components and BLASTn analysis revealed a high nucleotide sequence identity in seven watermelon samples from Beaufort and Charleston counties and five muskmelon samples from Charleston County with cucurbit leaf crumple virus.