A Simple and Simultaneous Detection Method for Two Different Viroids Infecting Chrysanthemum by Multiplex Direct RT-PCR

Development of a RT-LAMP assay for real-time detection of criniviruses infecting tomato

Yellowing symptoms caused by tomato chlorosis virus (ToCV) and tomato infectious chlorosis virus (TICV), both assigned to the genus Crinivirus, resemble nutrient deficiencies. Therefore, early diagnosis of infections will prevent crop damage and the spread of the viruses. In this study, we established a rapid detection method for ToCV and TICV by reverse transcription-loop-mediated isothermal amplification (RT-LAMP). We first designed primer sets for RT-LAMP specific for ToCV and TICV. Next, by selecting the optimum primer set and determining the optimum conditions for the RT-LAMP reaction, each virus was detected within 50 min by piercing the diseased area of a tomato leaf with a toothpick, immersing the toothpick in the reaction solution, and conducting the RT-LAMP reaction. To verify the accuracy of the procedure, 61 tomato leaf samples showing disease symptoms were collected from five regions of Indonesia, and the RT-LAMP results for the samples were identical to those obtained with the commonly used reverse transcription-polymerase chain reaction.

Duplex RT-PCR assay for simultaneous detection of TSWV and CSVd in chrysanthemum

A novel duplex RT-PCR assay for simultaneous detection of TSWV and CSVd in chrysanthemums was developed. Previous reported primers for amplification of TSWV and CSVd were used and a novel pair of primers for CSVd was designed to improve duplex amplification compatibility. Sensitivity and efficiency of the previous reported and novel primers for CSVd were assessed. Then, the sensitivity of the combined primers to amplify both TSWV and CSVd cDNA were also evaluated. Both TSWV and CSVd were detected in preparations diluted up to 10^-4 and 10^-5 respectively, from total RNA extracts. This duplex RT-PCR method showed an estimated diagnostic sensitivity (DSe) of 97% and diagnostic specificity (DSp) of 99%. For combination of the primers TSWV L1/ L2 and CSVd UCO-1 F/ UCO-1R, the protocol could detect pathogen RNA from naturally infected plants until 0.1 ng and 1 ng respectively. This novel protocol for detection of TSWV/CSVd represents a useful diagnostic tool without the need of expensive probes and less extensive laboratory work. This method could be helpful to assist the selection and further propagation of healthy chrysanthemums on the field as well as to understand the dynamics and the interaction of this virus and viroid within farms.

A current overview of two viroids that infect chrysanthemums: Chrysanthemum stunt viroid and Chrysanthemum chlorotic mottle viroid

The chrysanthemum (Dendranthema X grandiflorum) belongs to the family Asteraceae and it is one of the most popular flowers in the world. Viroids are the smallest known plant pathogens. They consist of a circular, single-stranded RNA, which does not encode a protein. Chrysanthemums are a common host for two different viroids, the Chrysanthemum stunt viroid (CSVd) and the Chrysanthemum chlorotic mottle viroid (CChMVd). These viroids are quite different from each other in structure and function. Here, we reviewed research associated with CSVd and CChMVd that covered disease symptoms, identification, host range, nucleotide sequences, phylogenetic relationships, structures, replication mechanisms, symptom determinants, detection methods, viroid elimination, and development of viroid resistant chrysanthemums, among other studies. We propose that the chrysanthemum and these two viroids represent convenient genetic resources for host-viroid interaction studies.

A single polyprobe for detecting simultaneously eight pospiviroids infecting ornamentals and vegetables

The spread of viroids belonging to the genus Pospiviroid (family Pospiviroidae), recorded recently in ornamentals and vegetables in several European countries, calls for fast, efficient and sensitive detection methods. Based on bioinformatics analyses of sequence identity among all pospiviroids, a digoxigenin-labeled polyprobe (POSPIprobe) was developed that, when tested by dot-blot and Northern-blot hybridization, detected Potato spindle tuber viroid, Citrus exocortis viroid, Columnea latent viroid, Mexican papita viroid, Tomato planta macho viroid, Tomato apical stunt viroid, Pepper chat fruit viroid and Chrysanthemum stunt viroid. The end-point detection limits of the POSPIprobe ranged from 5(-2) to 5(-4), and from 5(-1) to 5(-3) for nucleic acid preparations obtained by phenol extraction and silica-capture, respectively, similar to those of single probes. Based on sequence identity, the POSPIprobe is expected to detect also the two pospiviroid species not tested in this study (Tomato chlorotic dwarf viroid and Iresine viroid-1). Dot-blot assays with the POSPIprobe were validated by testing 68 samples from tomato, chrysanthemum and argyranthemum infected by different pospiviroids as revealed by RT-PCR, thus confirming the potential of this polyprobe for quarantine, certification and survey programs.

Development and validation of a multiplex RT-PCR method for the simultaneous detection of five grapevine viroids

Grapevine yellow speckle viroid 1 (GYSVd-1), Grapevine yellow speckle viroid 2 (GYSVd-2), Australian grapevine viroid (AGVd), Hop stunt viroid (HSVd) and Citrus exocortis viroid (CEVd) are the five viroids known to infect naturally grapevines. We developed a multiplex RT-PCR (mRT-PCR) method for the simultaneous detection of these five viroids and the amplification of the cDNA fragment of a host-derived mRNA (actin mRNA) as an internal positive control. Specific primers for each targeted viroid were designed by taking into account the sequence variability within and between the viroid species and tested in silico. The method was validated by testing 57 grapevine samples from Iran and showed reliability and high sensitivity. The RT-PCR-negative samples were further assayed by Northern-blot hybridization. For this, a method was developed for the simultaneous detection of three different grapevine viroids on a single hybridization membrane. In this survey, HSVd, GYSVd-1, AGVd, and GYSVd-2 were detected in 100, 95, 93, and 65% of the samples tested, respectively, confirming the wide distribution of these viroids in Iran. CEVd was not detected in any of the samples collected. Based on these results, HSVd is proposed as a positive internal control for mRT-PCR in the areas where this viroid is widespread, so as to reduce the time and costs of DNase treatment, which is required when a host-derived internal control is used. The mRT-PCR method has the potential to be used routinely for large-scale surveys and certification programs.