Sap-direct RT-PCR for the rapid detection of coleus blumei viroids of the genus Coleviroid from natural host plants

Coleus blumei viroid 7: a novel viroid resulting from genome recombination between Coleus blumei viroids 1 and 5

The genus Coleviroid, family Pospiviroidae, comprises six known viroids, all infecting Plectranthus scutellarioides (Coleus blumei; coleus). In 2017, a novel viroid-like RNA sequence that shares ca. 65% identity with Coleus blumei viroid 1 (CbVd-1) was identified in a coleus cultivar infected by multiple coleviroids. Further sequence and secondary structure analyses are consistent with the discovery of a seventh viroid in the genus Coleviroid: tentatively named "Coleus blumei viroid 7" (CbVd-7). The viroid appears to be the product of a natural recombination event between CbVd-1 and Coleus blumei viroid 5. We prove CbVd-7 to be infectious and in turn demonstrate the ability of all known coleviroid left- and right-arm segments to recombine. With a length of 234 nucleotides, this is the smallest viroid described to date.

First report of Coleus blumei viroid 1 in commercial Coleus blumei in the United States

Coleus scutellarioides (syn. Coleus blumei) is a widely grown evergreen ornamental plant valued for its highly decorative variegated leaves. Six viroids, named Coleus blumei viroid 1 to 6 (CbVd-1 to -6) have been identified in coleus plants in many countries of the world (Nie and Singh 2017), including Canada (Smith et al. 2018). However there have been no reports of Coleus blumei viroids occurring in the U.S.A. (Nie and Singh 2017). In April 2021, leaf tissue samples from 27 cultivars of C. blumei, one plant of each, were submitted to the University of Idaho laboratory from a commercial nursery located in Oregon to screen for the presence of viroids. The sampled plants were selected randomly and no symptoms were apparent in any of the samples. Total nucleic acids were extracted from each sample (Dellaporta et al. 1983) and used in reverse-transcription (RT)-PCR tests (Jiang et al. 2011) for the CbVd-1 and CbVd-5 with the universal primer pair CbVds-P1/P2, which amplifies the complete genome of all members in the genus Coleviroid (Jiang et al. 2011), and two additional primer pairs, CbVd1-F1/R1 and CbVd5-F1/R1, specific for CbVd-1 and CbVd-5, respectively (Smith et al. 2018). Five C. blumei plants (cvs Fire Mountain, Lovebird, Smokey Rose, Marrakesh, and Nutmeg) were positive for a coleviroid based on the observation of the single 250-nt band in the RT-PCR test with CbVds-P1/P2 primers. Two of these CbVd-1 positive plants (cvs Lovebird and Nutmeg) were also positive for CbVd-1 based on the presence of a single 150-nt band in the RT-PCR assay with CbVd1-F1/R1 primers. One plant (cv Jigsaw) was positive for CbVd-1, i.e. showing the 150-nt band in RT-PCR with CbVd1-F1/R1 primers, but did not show the ca. 250-bp band in RT-PCR with primers CbVds-P1/P2. None of the tested plants were positive for CbVd-5, either with the specific, or universal primers. All coleviroid- and CbVd-1-specific PCR products were sequenced directly using the Sanger methodology, and revealed whole genomes for five isolates of CbVd-1 from Oregon, U.S.A. The genomes of the five CbVd-1 isolates displayed 96.9-100% identity among each other and 96.0-100% identity to the CbVd-1 sequences available in GenBank. Because the sequences from cvs Lovebird, Marrakesh, and Nutmeg, were found 100% identical, one sequence was deposited in GenBank (MZ326145). Two other sequences, from cvs Fire Mountain and Smokey Rose, were deposited in the GenBank under accession numbers MZ326144 and MZ326146, respectively. To the best of our knowledge, this is the first report of CbVd-1 in the United States.

A rapid sap-direct reverse transcription-polymerase chain reaction method for detection of dendrobium viroid in Dendrobium plants

Dendrobium viroid (DVd) was first reported in China in 2020, and it is the only viroid known to infect Orchidaceae family plants. In this study, we developed a simple reverse transcription-polymerase chain reaction (RT-PCR) method for the rapid detection of DVd in Dendrobium plants. When extracting the sap template from the leaves, they are first clamped between two layers of plastic film, and the sap is pressed out and collected with a pipette. Using this sap, DVd was detected by dot-blot and RT-PCR methods and, the expected amplicons were confirmed by sequencing analysis. The batch analysis of field samples revealed that this method can be used to detect DVd rapidly. The detection method also reduces cross-contamination between different samples and minimizes false positives. Thus, this sap-direct RT-PCR method allows effective and rapid DVd detection in the study of Orchidaceae plants.

High-Throughput Sequencing Analysis of Small RNAs Derived from Coleus Blumei Viroids

Characterization of viroid-derived small RNAs (vd-sRNAs) is important to understand viroid–host interactions; however, vd-sRNAs belonging to the genus Coleviroid are yet to be identified and characterized. Herein, we used coleus plants singly infected with coleus blumei viroid (CbVd)-1, -5, or -6 and doubly infected with CbVd-1 and -5 to identify and analyze their vd-sRNAs. We found sense and antisense vd-sRNAs for CbVd-1, -5 and -6, and 22-nt vd-sRNAs were the most abundant; moreover, the 5′-terminal nucleotides (nts) of CbVd-1, -5, and -6 were biased toward U and C, and sRNAs derived from these three viroids were unevenly distributed along their genomes. We also noted that CbVd-5 and -6 share a fragment that forms the right half of the rod-like secondary structure of these viroids, which implied that they generated almost the same type of vd-sRNAs. This finding indicated that vd-sRNA biogenesis is mainly determined by the primary sequence of their substrates. More importantly, we found two complementary vd-sRNAs (22 nt) that were generated from the central conserved region (CCR) of these three viroids, suggesting an important role of CCR in vd-sRNA biogenesis. In conclusion, our results provide novel insight into the biogenesis of vd-sRNAs and the biological roles of CCR.

Comprehensive secondary structure elucidation of four genera of the family Pospiviroidae

Viroids are small, circular, single stranded RNA molecules that infect plants. Since they are non-coding, their structures play a critical role in their life cycles. To date, little effort has been spend on elucidating viroid structures in solution due to both the experimental difficulties and the time-consuming nature of the methodologies implicated. Recently, the technique of high-throughput selective 2'-hydroxyl acylation analyzed by primer extension (SHAPE) was adapted for the probing of the members of family Avsunviroidae, all of whom replicate in the chloroplast and demonstrate ribozyme activity. In the present work, twelve viroid species belonging to four different genera of the family Pospiviroidae, whose members are characterized by the presence of a central conserved region (CCR) and who replicate in nucleus of the host, were probed. Given that the structures of five distinct viroid species from the family Pospiviroidae have been previously reported, an overview of the different structural characteristics for all genera and the beginning of a manual classification of the different viroids based on their structural features are presented here.

Infectious cDNA clones of four viroids in Coleus blumei and molecular characterization of their progeny

Four viroid species infecting Coleus blumei, named Coleus blumei viroid 1-4 (CbVd-1-CbVd-4), and two tentative new viroid species, named CbVd-5 and CbVd-6, have been characterized, for two of which (CbVd-5 and CbVd-6, first reported in 2009), there is no established bioassay. Here, infectious clones were used as inoculums sources and the biological properties of CbVd-1, -3, -5 and -6 were assessed. When dimeric CbVd (+) RNAs synthesized in vitro were bioassayed, the first detection time for the four CbVds was different, ranging from 45 to 300 days. In addition, we confirmed that CbVd-5 and CbVd-6 can be transmitted via seeds. Molecular characterization of their progeny from slash-inoculated plants one year after inoculation demonstrated that the genetic diversity of CbVd populations may depend on the infected coleus plants and on the viroid genotype.

A universal oligonucleotide microarray with a minimal number of probes for the detection and identification of viroids at the genus level

A major challenge in the agricultural industry is the development of techniques that can screen plant samples for viroid infection. Microarrays are promising in this regard, as their high throughput nature can potentially allow for the detection of a range of viroids in a single test. In this paper we present a microarray that can detect a wide spectrum of all 8 reported viroid genera including 37 known plant viroid species. The array was constructed using an automated probe design protocol which generated a minimal number of probes to detect viroids at the genus level. The designed microarray showed a high specificity and sensitivity when tested with a set of standard virus samples. Finally, the microarray was applied to screen infected field samples, with Hop stunt viroid infection identified as the major disease causing pathogen for an infected citrus sample.

Rapid detection and identification of viroids in the genus Coleviroid using a universal probe

A simple, low-cost hybridization assay using a universal DIG-labeled riboprobe for the rapid detection and identification of coleus viroids is presented. An octamer of 32-nucleotide sequence derived from the central conserved region (CCR) of viroids in the genus Coleviroid was used to develop a universal cRNA probe (8-central-conserved-region probe, 8CCR probe) for coleus viroids. Dot-blot hybridization assays demonstrated that the sensitivity of this probe was similar to specific probes for each CbVd, and Northern hybridization results revealed that at least four coleus viroids could be distinguished readily and simultaneously using the 8CCR probe. Batch detection assay showed that hybridization using the 8CCR probe can identify coleus viroids rapidly and effectively. This rapid and low-cost molecular hybridization technique is an effective way to survey the occurrence of coleus viroids, and has reference for the detection of other viroids and possibly viruses.