Rapid detection of peach latent mosaic viroid by reverse transcription recombinase polymerase amplification

Rapid and specific detection of Pentastiridius leporinus by recombinase polymerase amplification assay

Pentastiridius leporinus (Hemiptera: Cixiidae) is the main vector of an emerging and fast spreading sugar beet disease, the syndrome 'basses richesses' (SBR), in different European countries. The disease is caused by the γ-3-proteobacterium 'Candidatus Arsenophonus phytopathogenicus' and the phytoplasma 'Candidatus Phytoplasma solani' which are exclusively transmitted by planthoppers and can lead to a significant loss of sugar content and yield. Monitoring of this insect vector is important for disease management. However, the morphological identification is time consuming and challenging as two additional cixiid species Reptalus quinquecostatus and Hyalesthes obsoletus with a very close morphology have been reported in sugar beet fields. Further, identification of females and nymphs of P. leporinus at species level based on taxonomic key is not possible. In this study, an isothermal nucleic acid amplification based on recombinase polymerase amplification (RPA) was developed to specifically detect P. leporinus. In addition, real-time RPA was developed to detect both adults (male and female) and nymph stages using pure or crude nucleic acid extracts. The sensitivity of the real-time RPA for detection of P. leporinus was comparable to real-time PCR, but a shorter time (< 7 min) was required. This is a first report for real-time RPA application for P. leporinus detection using crude nucleic acid templates which can be applied for fast and specific detection of this vector in the field.

Rapid and Visual Detection of Actinidia Chlorotic Ringspot-Associated Virus Using One-Step Reverse-Transcription Recombinase Polymerase Amplification Combined with Lateral Flow Dipstick Assay

Actinidia chlorotic ringspot-associated virus (AcCRaV) occurs widely in major kiwifruit producing areas of China and is often accompanied by coinfecting viruses, affecting the growth, yield, and quality of kiwifruit. Therefore, a rapid and sensitive detection method is crucial for diagnosing and developing effective AcCRaV management strategies. In this study, a one-step reverse-transcription recombinase polymerase amplification combined with a lateral flow dipstick (RT-RPA-LFD) assay was developed for rapid detection of AcCRaV. Specific primers and a probe were designed based on the conserved region of the coat protein gene sequence of AcCRaV. The one-step RT-RPA reaction can be performed at 35 and 40°C within 10 to 30 min, and the amplification results can be read directly on the LFD within 5 min. The detection limit of the one-step RT-RPA-LFD assay was 10-8 ng (about 20 viral copies), which was equal with one-step RT-qPCR and 100 times more sensitive than one-step RT-PCR. Moreover, the one-step RT-RPA-LFD assay was successfully applied to detect AcCRaV from crude extracts, and the entire detection process can be completed within 40 min. These results indicate that the RT-RPA-LFD assay is a simple, rapid, and sensitive strategy that can be used for accurate diagnosis of AcCRaV-infected kiwifruit plants in the field. To our knowledge, this is the first study applying the one-step RT-RPA-LFD assay to detect a kiwifruit virus.

Application of Rapid and Reliable Detection of Cymbidium Mosaic Virus by Reverse Transcription Recombinase Polymerase Amplification Combined with Lateral Flow Immunoassay

Cymbidium mosaic virus (CymMV) is one of economically important viruses that cause significant losses of orchids in the world. In the present study, a reverse transcription recombinase polymerase amplification (RT-RPA) assay combined with a lateral flow immunostrip (LFI) assay was developed for the detection of CymMV in orchid plants. A pair of primers containing fluorescent probes at each terminus that amplifies highly specifically a part of the coat protein gene of CymMV was determined for RT-RPA assay. The RT-RPA assay involved incubation at an isothermal temperature (39°C) and could be performed rapidly within 30 min. In addition, no cross-reactivity was observed to occur with odontoglossum ringspot virus and cymbidium chlorotic mosaic virus. The RT-RPA with LFI assay (RT-RPA-LFI) for CymMV showed 100 times more sensitivity than conventional reverse transcription polymerase chain reaction (RT-PCR). Furthermore, the RT-PCR-LFI assay demonstrated the simplicity and the rapidity of CymMV detection since the assay did not require any equipment, by comparing results with those of conventional RT-PCR. On-site application of the RT-RPA-LFI assay was validated for the detection of CymMV in field-collected orchids, indicating a simple, rapid, sensitive, and reliable method for detecting CymMV in orchids.

Onsite detection of plant viruses using isothermal amplification assays

Plant diseases caused by viruses limit crop production and quality, resulting in significant losses. However, options for managing viruses are limited; for example, as systemic obligate parasites, they cannot be killed by chemicals. Sensitive, robust, affordable diagnostic assays are needed to detect the presence of viruses in plant materials such as seeds, vegetative parts, insect vectors, or alternative hosts and then prevent or limit their introduction into the field by destroying infected plant materials or controlling insect hosts. Diagnostics based on biological and physical properties are not very sensitive and are time-consuming, but assays based on viral proteins and nucleic acids are more specific, sensitive, and rapid. However, most such assays require laboratories with sophisticated equipment and technical skills. By contrast, isothermal-based assays such as loop-mediated isothermal amplification (LAMP) and recombinase polymerase amplification (RPA) are simple, easy to perform, reliable, specific, and rapid and do not require specialized equipment or skills. Isothermal amplification assays can be performed using lateral flow devices, making them suitable for onsite detection or testing in the field. To overcome non-specific amplification and cross-contamination issues, isothermal amplification assays can be coupled with CRISPR/Cas technology. Indeed, the collateral activity associated with some CRISPR/Cas systems has been successfully harnessed for visual detection of plant viruses. Here, we briefly describe traditional methods for detecting viruses and then examine the various isothermal assays that are being harnessed to detect viruses.

Rapid diagnostic detection of tomato apical stunt viroid based on isothermal reverse transcription-recombinase polymerase amplification

Tomato apical stunt viroid (TASVd) is a serious threat to tomato plants that can cause a considerable yield loss. In the present study, two isothermal molecular diagnostic assays based on reverse transcription-recombinase polymerase amplification (RT-RPA) utilizing the AmplifyRP® platform for plant pathogen detection were developed. The results of this research demonstrated distinct specificity of both developed assays, AmplifyRP® Acceler8™ and AmplifyRP® XRT, expressed in the absence of any cross-reaction activity to all total RNA extracts obtained from plants infected with other pospiviroids. The RT-RPA assays detected viroid RNA in 81- and 27-fold dilutions of the original TASVd-infected crude extract for AmplifyRP® Acceler8™ and AmplifyRP® XRT, respectively. The sensitivity tests in serial water dilutions showed the ability of AmplifyRP® Acceler8™ and AmplifyRP® XRT to detect 8 and 80 fg of pure TASVd RNA transcript, respectively. The influence of crude extract on viroid RNA transcript detection was also examined and a decrease of sensitivity of approximately 100-fold for both RT-RPA assays was revealed. To our knowledge, this is the first report describing development of RT-RPA assays to detect TASVd in plants using the AmplifyRP® platform that can be further employed both in laboratory conditions and in the field for on-site diagnosis.

Development of a reverse transcription droplet digital PCR assay for sensitive detection of peach latent mosaic viroid

Peach latent mosaic viroid (PLMVd) represents a continuing threat to peach tree production worldwide. In this study, a sensitive and accurate quantification of PLMVd in peach leaves was established using a reverse transcription droplet digital polymerase chain reaction (RT-ddPCR) assay. The quantitative linearity, accuracy, and sensitivity of RT-ddPCR for the detection of PLMVd were comparatively assessed to those of reverse-transcription real-time quantitative polymerase chain reaction (RT-qPCR) assay. The specificity assay shows no amplification in major peach viruses, apple chlorotic leaf spot virus and prunus necrotic ring spot virus and negative control. Furthermore, the levels of PLMVd transcripts determined using RT-ddPCR and RT-qPCR showed a high degree of linearity and quantitative correlation. Our results also indicated that the RT-ddPCR assay is at least two-fold more sensitive than qPCR and could therefore, be used to detect PLMVd in field samples. Moreover, optimization of RT-ddPCR was found to enhance the sensitivity of PLMVd detection in the peach leaf samples with low viral loads. In summary, the established RT-ddPCR assay represents a promising alternative method for the precise quantitative detection of PLMVd; it would be particularly applicable for diagnosing PLMVd infections in plant quarantine inspection and PLMVd-free certification program.

Rapid and visual detection of tomato spotted wilt virus using recombinase polymerase amplification combined with lateral flow strips

Tomato spotted wilt virus (TSWV) is economically important in Korea as it causes significant losses to a wide range of important ornamental and vegetable crops. Therefore, a rapid detection method is imperative for TSWV diagnosis. Specific primers and probes were designed based on the conserved sequences of the TSWV coat protein gene. In this study, an isothermal reverse transcription recombinase polymerase amplification (RT-RPA) assay, combined with lateral flow strips (LFS), was established for rapid detection of TSWV in pepper infected leaves. The RT-RPA reaction was performed at an optimal condition of 38 °C for 10 min and an LFS incubation time of approximately 5 min. There was no cross-reactivity with other viruses infecting pepper such as cucumber mosaic virus, pepper mottle virus, pepper mild mottle virus, and broad bean wilt virus 2, thus confirming the specificity of RT-RPA-LFS. The sensitivity of the RT-RPA assay was similar to that of RT-PCR, and RT-RPA-LFS was successfully applied to detect TSWV in the pepper samples collected from the field. Thus, RT-RPA-LFS assay might be a promising candidate for quick diagnosis of TSWV-infected pepper plants.