ABSTRACT
Raspberry plants, valued for their fruits, are vulnerable to a range of viruses that adversely affect their yield and quality. Utilizing high-throughput sequencing (HTS), we identified a novel virus, tentatively named raspberry enamovirus 1 (RaEV1), in three distinct raspberry plants. This study provides a comprehensive characterization of RaEV1, focusing on its genomic structure, phylogeny, and possible transmission routes. Analysis of nearly complete genomes from 14 RaEV1 isolates highlighted regions of variance, particularly marked by indel events. The evidence from phylogenetic and sequence analyses supports the classification of RaEV1 as a distinct species within the Enamovirus genus. Among the 289 plant and 168 invertebrate samples analyzed, RaEV1 was detected in 10.4% and 0.4%, respectively. Most detections occurred in plants that were also infected with other common raspberry viruses. The virus was present in both commercial and wild raspberries, indicating the potential of wild plants to act as viral reservoirs. Experiments involving aphids as potential vectors demonstrated their ability to acquire RaEV1 but not to successfully transmit it to plants.
Subject(s)
Aphids , Luteoviridae , Rubus , Viruses , Animals , Luteoviridae/genetics , Phylogeny , Plant DiseasesABSTRACT
Though apple genotyping is mainly used for scientific and breeding purposes, it can also be adopted by national authorities to control the authenticity of apple cultivars. To facilitate the introduction of routine apple genotyping into practice, a new apple simple sequence repeat (SSR) genotyping kit was developed (called the Ap17â¯in. SSR Genotyping Kit). The kit combines 17 SSR markers including those recommended by the Working Group of the European Cooperative Programme for Plant Genetic Resources (ECPGR), covering all apple linkage groups in a one-tube reaction format, using a fragment analysis method to simplify the genotyping procedure. The kit was successfully tested using 880 unique diploid apple germplasm accessions; the kit can also readily discriminate triploid and tetraploid samples. The total probability of identity for the kit and the sample collection used was calculated to be 1.73â¯×â¯10-22. Tables for converting results to enable genotype comparisons between currently-used genotyping systems and the Ap17â¯in. kit are provided. The kit is ideally suited for validation in laboratories genotyping a large number of apple samples, saving time, costs, and labor, while minimizing technical and human errors.