Sugar beet (Beta vulgaris L. ssp. vulgaris Doell.) was originally selected from white fodder beet in the 1780s and was then specifically bred for sucrose production. The relatively recent inception of the crop has led to a narrow genetic base that has bottlenecked sustainable improvement. To evaluate the potential of publicly available germplasm for sugar beet improvement, genetic diversity analysis with SNPs (singlenucleotide polymorphisms) covering the whole genome of sugar beet was conducted using 1936 publicly available germplasm lines in the United States. The results confirmed the narrow genetic base of sugar beet and identified germplasm accessions with inherently greater diversity that were mostly accessions of wild sea beet (B. vulgaris ssp. maritima (L.) Arcang.), the progenitor species of white fodder beet. These wild accessions displayed a distinct genetic relationship from cultivated sugar beet lines, indicating their high potential for broadening sugar beet genetic diversity. Analysis of historic resistance evaluations also suggested a higher potential of B. vulgaris ssp. maritima accessions to be used as sources of resistance to major diseases and insects of sugar beet. A genome-wide association study using historic evaluation data identified genomic regions significantly associated with disease and insect resistance. However, genomic regions associated with resistance to nematode, insects, or diseases vectored by insects were of low significance, indicating the need for additional research to allow for a more precise evaluation of germplasm responses to insects. The research confirms that accessions of B. vulgaris ssp.
In the fall 2021, red table beet plants (Beta vulgaris L. cv ‘Eagle’) exhibiting stunted growth with shorter petioles were observed at an incidence of 10 to 15 percent in a production field in Payette County, Idaho, United States. In addition to stunting, beet leaves displayed yellowing and mild curling and crumpling, and the roots exhibited hairy root symptoms (sFig.1). To identify potential causal viruses, total RNA was isolated from the leaf and root tissue using RNeasy Plant Mini Kit (Qiagen, Valencia, CA) and subjected to high-throughput sequencing (HTS). Two libraries were prepared, one for the leaf sample and another for the root sample using a ribo-minus TruSeq Stranded Total RNA Library Prep kit (Illumina, San Diego, CA). HTS was performed with 150 bp paired-end sequencing on a NovaSeq 6000 (Novogene, Sacramento, CA). Following adapter trimming and removal of host transcripts, 5.9 and 16.2 million reads were obtained from the leaf and root samples, respectively. These reads were de novo assembled using the SPAdes assembler (Bankevitch et al., 2012; Prjibelski et al., 2020). The assembled leaf sample contigs were aligned to the NCBI non-redundant database to identify contigs matching known viruses. A single contig of 2845 nts that shared 96% coverage and 95.6% sequence identity to the pepper yellow dwarf strain of beet curly top virus (BCTV-PeYD, EU921828; Varsani et al., 2014), and 98% coverage and 98.39% identity with an isolate of BCTV-PeYD (KX529650) from Mexico, was identified in the leaf sample (GenBank Accession OP477336). To validate the HTS detection of BCTV-PeYD, total DNA was isolated from the leaf sample and a 454 bp fragment of the C1 gene (replication-associate protein) was PCR amplified and Sanger sequencing of the amplicon revealed 99.7% identity to the HTS assembled BCTV-PeYD sequence. In addition to the PeYD strain of BCTV, the Worland strain of BCTV (BCTV-Wor) was detected as a single 2930 nt contig with 100% coverage and 97.3% identity to the BCTV-Wor isolate CTS14-015 (KX867045) known to infect sugar beet in Idaho. Of note, there are 11 strains of BCTV and among those, the BCTV-Wor strain induces mild symptoms in sugar beet (Strausbaugh et al., 2017), whereas BCTV-PeYD was found only in pepper from New Mexico. Further, two contigs of 2201 nts and 523 nts were assembled generating a nearly complete genome of spinach curly top Arizona virus (SpCTAV) in the leaf sample with 99% coverage and 99.3% identity (GenBank Accession OQ703946) to the reference genome of SpCTAV (HQ443515; Hernandez-Zepeda et al., 2013). To validate the HTS results, total DNA was isolated from the leaf tissue and PCR amplified a 442 bp fragment that overlaps the V1, V2, and V3 ORFs and its sequence revealed 100% identity with the HTS assembled SpCTAV. The roots sample also showed HTS reads corresponding to BCTV-PeYD and SpCTAV. In addition, beet necrotic yellow vein virus (BNYVV) was detected in the root sample with 30% coverage, but no sequence reads matching to BNYVV was detected in the leaf sample. BNYVV is known to infect sugar beet causing rhizomania (Tamada et al., 1973; Schirmer et al., 2005). To further confirm the BNYVV HTS results, total RNA was extracted separately from the root and leaf tissue, and RT-PCR was performed with primers that were designed to amplify portions of BNYVV RNAs (Weiland et al., 2020). RT-PCR analysis generated the appropriate amplicons with expected sequences corresponding to the RNA-1, RNA-2, RNA-3, and RNA-4 of BNYVV as determined by Sanger sequencing implying BNYVV the causal agent of hairy root symptoms. Similar to observations seen for BNYVV infection in conventional sugar beet varieties, no amplification was detected for BNYVV in the RNA extracted from leaf tissue, indicating that the RT-PCR results are consistent with the HTS analysis. This is the first report of BCTV-PeYD and SpCTAV observed naturally infecting red table beet in Idaho suggesting the geographical expansion of these viruses. The co-existence of BCTV-PeYD and SpCTAV with limited host range needs to be investigated to determine the actual cause of the observed foliar symptoms. This report provides the basis for further research to understand the pathogenic nature of these viruses and their potential threat to red table beet and sugar beet production in Idaho.
Sugar beet (Beta vulgaris L.) is an important crop grown for its sucrose content used in sugar production around the world. Tomato bushy stunt virus (TBSV) is an RNA virus that belongs to the Tombusvirus genus of the family Tombusviridae (Hearne et al., 1990). The virus was first isolated from tomato, and it is known to infect a wide range of plants (Smith, 1935; Martelli et al., 1988; Hafez et al., 2010). In 1980, a natural infection of TBSV was reported in sugar beet leaves with chlorotic and necrotic ring spots and line pattern symptoms based on serological affinity to TBSV anti-sera in Czechoslovakia (Novak and Lanzova, 1980). In March 2021, sugarbeet plants showing stunted and bushy growth with yellowing and necrotic leaves were observed in a production field in the Imperial Valley of California. Harvested roots exhibited stunted and abnormal growth compared to roots from healthy plants (sFig. 1A). These symptoms prompted a screen for potential infection by TBSV. Root-tissue harvested from the symptomatic sugar beet was initially screened using a TBSV double antibody sandwich enzyme-linked immunosorbent assay (DAS-ELISA; Agdia, Inc., Elkhart, IN), which reacted positive for TBSV. To obtain the full-length sequence of TBSV and potentially other viruses in the sample, total RNA isolated using the RNeasy Plant Mini Kit (Qiagen, Valencia, CA) from the root-tissue was subjected to high-throughput sequencing (HTS). Libraries were prepared using the TruSeq Stranded Total RNA Library Prep kit (Illumina, San Diego, CA) and sequenced using Illumina NovoSeq 6000 paired-end platform (Novogene, Sacramento, CA). A total of 52 million reads were obtained after removing the adapters and reads mapping to the host genome. These high-quality reads were de novo assembled into 75,891 contigs that are larger than 500 base pairs using the SPAdes assembler (Bankevitch et al., 2012; Prjibelski et al., 2020). The resulting contigs were searched for matching sequences to known viruses using the NCBI non-redundant database. A single contig of 4770 nts representing the full-length genome of TBSV was generated (Accession number OP477335), which showed 100% coverage to previously reported TBSV isolates ‘statice’ (AJ249740.1) and ‘nipplefruit’ (AY579432.1) with 92.19% and 91.25% nucleotide sequence identities, respectively, and thus confirming the presence of TBSV in sugar beet root-tissue. However, it showed 74% coverage with only 87% nucleotide identity to a previously reported Lettuce necrotic stunt virus (LNSV) from sugar beet, a tombusvirus that was re-classified as Moroccan pepper virus (MPV) due to high degree (>97%) of sequence identity (Obermeier et al., 2001; Wintermantel and Anchieta, 2012; Wintermantel and Hladky, 2013). The coat protein is conserved within species in tombusvirus, and it plays a significant role by providing serological relationships to tombusvirus taxonomy. The coat protein of TBSV-isolate of this study shared 98.45% and 96.91% identities at amino acid level with TBSV ‘nipplefruit’ (AY579432.1) and TBSV ‘statice’ (AJ249740.1) isolates, respectively. In contrast, it showed only 61.56% identity with the coat protein of MPV as shown in the phylogenetic tree indicating that the TBSV-isolate reported here is different from MPV (sFig. 2). To confirm the presence of TBSV, reverse-transcription (RT)-PCR was performed using the total RNA isolated from the root-tissue with primers (VR306: 5’-CGCTCACGAGCCCAGCATCCTTGA-3’ and VR297: 5’-ACACCGCCACAGGAGCCATGATTG-3’) designed based on the HTS data to amplify a portion of the TBSV genome. Sequencing of the RT-PCR product confirmed the presence of TBSV sequence with 99.1% identity to the TBSV-isolate identified in this study. Further, mechanical inoculation of total RNA isolated from the symptomatic sugar beet roots produced local lesions and systemic necrosis symptoms on the leaves of Chenopodium quinoa (sFig. 1B). Sequencing of the amplicon obtained using RT-PCR with primers VR306 and VR297 confirmed the presence of TBSV in C. quinoa. In addition to TBSV, several viral contigs representing Beet necrotic yellow vein virus were identified in the root-tissue indicating mixed infection in the field. To our knowledge, this is the first report that documents the occurrence of TBSV in sugar beet in the United States. Since TBSV is a soil-borne virus, our findings indicate the need for further studies focused on the frequency and coexistence of the TBSV with BNYVV in sugar beet production fields to understand the disease complexity resulting from potential mixed infections.
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