An artificial positive control for routine detection of rose rosette virus and Phyllocoptes fructiphilus that fit most primers for PCR, LAMP and RPA based assays

Abstract

AbstractRose (Rosa spp.) is a very important ornamental shrub cultivated worldwide and of value for the pharmaceutical industry. The plant is broadly susceptible to pathogens, including viruses. Rose rosette virus (RRV; virus species Emaravirus rosae) causes multiple symptoms typically rosettes, ultimately leading to death. The virus transmission is by grafting and a wind‐dispersed eriophyoid mite, Phyllocoptes fructiphilus, which survives in winter‐dormant plants. Due to extensive globalization RRV is a threat for the European rose, landscape, nursery and tourism industries. The most common and reliable method used for RRV detection is RT‐PCR. Positive control is indispensable for PCR reliability and can be difficult to obtain for emerging or highly contagious pathogens and are subject to BSL‐2 quarantine. A synthetic artificial positive control (APC) using custom DNA inserts of sense and anti‐sense primers was designed de novo and inserted in a circular plasmid vector to create a positive control for use with most RRV reported primers and eriophyoid mites. This study describes a functional demonstration and development of a rapid, consistent, adaptable and cost‐effective alternative to infected true‐tissue positive control for detection of RRV. The inserted RRV primers are for end point and quantitative RT‐PCR, reverse transcription loop‐mediated isothermal amplification (RT‐LAMP), recombinase‐polymerase amplification (RPA), broad detection of emaravirus and the eriophyoid mite vector Phyllocoptes fructiphilus. The APC‐RRV and RRV infected rose (leaf tissue) were tested side to side. Results demonstrated APC‐RRV is a safe, cloneable and reliable approach subjected to quality control with application in quarantine surveillance and routine diagnostics of RRV.