Complete genome sequence of a novel secovirid infecting cassava in the Americas.

We report the complete genome sequence of a field isolate of a novel bipartite secovirid infecting cassava in Colombia, provisionally named "cassava torrado-like virus" (CsTLV). The genome sequence was obtained using Oxford Nanopore Technology, and the 5' ends were confirmed by RACE. The RNA1 is 7252 nucleotides (nt) long, encoding a polyprotein of 2336 amino acids (aa) containing the typical "replication block", conserved torradovirus motifs, and a Maf/Ham1 domain, which is not commonly found in viral genomes. The RNA2 is 4469 nt long and contains two overlapping ORFs encoding proteins of 226 and 1179 aa, showing the characteristic genome arrangement of members of the genus Torradovirus.

Genome Analysis and Pathobiology of Cassava-Infecting Torradoviruses Containing a Putative Maf/HAM1 Pyrophosphatase Domain.

Next generation sequencing has been used to identify and characterize the full genome sequence of a cassava-infecting torradovirus, revealing the presence of a Maf/HAM1 domain downstream of the RNA-dependent RNA-polymerase (RdRp) domain in RNA1 in all isolates sequenced. A similar domain is also found in unrelated potyvirids infecting Euphorbiaceae hosts in the Americas and cassava in Africa. Even though cassava torrado-like virus (CsTLV) could not be mechanically transmitted to a series of herbaceous hosts, it can be efficiently transmitted by bud graft-inoculation to different cassava landraces. Our bioassays show that CsTLV has a narrow host range. Crystal-like structures of isometric virus-like particles were observed in cells of plants with single infection by CsTLV, and consistently induced chlorotic leaf spots and affected root yields significantly. Moreover, CsTLV infection induces changes in the accumulation of total sugars in storage roots. Field surveys indicated the presence of CsTLV in the main cassava growing regions of Colombia, and the occurrence of two different cassava-infecting torradovirus species. Profiles of small RNAs of 21 to 24 nucleotides in length, derived from CsTLV RNAs targeted by cassava RNA silencing defense mechanisms, are also reported.

First report of Sri Lankan cassava mosaic virus and Cassava Mosaic Disease in Laos.

Cassava (Manihot esculenta Crantz) has been traditionally grown as a subsistence crop in Laos, but in recent years cassava cultivation in this country has expanded and is becoming a 'cash crop' for farmers (Malik et al., 2020). This also means that cassava vegetative seed (stakes) is rapidly multiplied and distributed. One of the most important diseases affecting cassava in the world is the Cassava Mosaic Disease (CMD), caused by several species of begomoviruses and disseminated by infected stakes or vectored by the whitefly Bemisia tabaci (Legg et al., 2014). Sri Lankan cassava mosaic virus (SLCMV), a bipartite begomovirus, is the virus species causing CMD in Southeast Asia (SEA) and is widespread in Cambodia, Vietnam, Thailand and south China (Siriwan et al., 2020). During field surveys on July 12 to 14, 2020, the team in south Laos, surveyed 8 fields along the border with Cambodia, in the southern provinces of Attapeu and Champassack and identified CMD symptoms (Supplementary Figure 1A) in only one of the fields, located at Kong District of the Champassack province (GPS coordinates 13.94325, 105.99102). From these 8 fields, samples were collected from every third plant in an X pattern. Photographs from each sampled plant were taken and uploaded into CIAT's PestDisPlace platform (https://pestdisplace.org), for CMD symptom confirmation (Supplementary Figure 1B). Leaf samples were sent to the laboratory for PCR using primers SLCMV-F 5'-ATGTCGAAGCGACCAGCAGATATAAT-3' and SLCMV-R 5'-TTAATTGCTGACCGAATCGTAGAAG-3' targeting the AV1 gene (Dutt et al., 2005), following the protocol described in Siriwan et al. (2020) and primers SLCMV-B-F1 5'-ACCGGATGGCCGCGCCCCCCTCT-3' and SLCMV-B-606R 5'-CACCTACCCTGTTATCGCTAAG-3' targeting part of the BV1 gene. Out of 60 samples collected for the field in Kong district, eleven (18.3%) resulted PCR positive to SLCMV (to DNA-A and DNA-B) but only four plants (6.7%) showed symptoms of CMD (see Supplementary Figure 1B and 1C). None of the samples in the other seven fields had CMD symptoms nor was SLCMV detected in any of these plants. Furthermore, the presence of CMD symptoms in the old leaves of the plants in the affected field suggests that the virus was introduced with contaminated stakes. The complete bipartite genome of one isolate (Champ1), was amplified by Rolling Circle Amplification and sequenced with the nanopore MinION technology as described by Leiva et al. (2020). The sequences were submitted to GenBank under accession nos MT946533 (DNA-A) and MT946534 (DNA-B). A phylogenetic tree for SLCMV and a link to the open SLCMV Nextstrain map (Hadfield et al., 2018) is included in Supplementary Figure 2. The sequences of the DNA-A and DNA-B components of the Champ1 isolate were nearly identical to those of anisolate of SLCMV from Ratanakiri, Cambodia (99.72% for DNA-A and 99.82 for DNA-B; Wang et al., 2016). Phylogenetic analysis (Supplementary Figure 2), grouped isolate Champ1 with those that form the cluster of SEA isolates that contain the shorter version of the rep gene (Siriwan et al., 2020). This short version of rep present a deletion of 7 amino acids at the C-terminus, which is involved in host responses to SLCMV (Wang et al., 2020). The confirmation of CMD and SLCMV in the border between Laos and Cambodia should be followed by disease containment and management strategies, particularly given that the majority cassava varieties grown in Laos are from neighbor countries, most of which have already reported the presence of CMD. Acknowledgements We thank all staff from the CIAT's Cassava Program and the Plant Protection Center of Laos in Vientiane. We acknowledge financial support from the Australian Centre for International Agricultural Research (ACIAR) and the CGIAR Research Program on Roots, Tubers and Bananas (RTB) (https://www.cgiar.org/funders/).

An optimized nucleic acid isolation protocol for virus diagnostics in cassava (Manihot esculenta Crantz.).

Our group works on the detection and characterization of cassava viruses, supporting projects that involve large scale pathogen surveillance activities and resistance screening assays in multiple and remote locations. In order to comply with these applications, nucleic acid isolation protocols need to be cost effective, adjusted for samples that will stand long distance transport and harsh storage conditions, while maximizing the yield and quality of the nucleic acid extracts obtained. The method we describe here has been widely used and validated using different downstream tests (including, but not limited to, Rolling Circle Amplification and Illumina and Nanopore sequencing), but is currently unpublished. The protocol begins with milligram amounts of dry leaf samples stored in silica gel, does not require liquid Nitrogen nor phenol extraction and produces an average of 2.11 µg of nucleic acids per mg of dry tissue.•DNA purity estimations reveal OD260/280 ratios above 2.0 and OD260/230 ratios above 1.7, even for samples stored in silica gel for several months.•The high quality of the extracts is suitable for detection of DNA and RNA viruses, with high efficiency.•We suggest this method could be used as part of a gold standard kit for virus detection in cassava.

A simple PCR-based method for the rapid and accurate identification of spider mites (Tetranychidae) on cassava.

The morphological identification of mites entails great challenges. Characteristics such as dorsal setae and aedeagus are widely used, but they show variations between populations, and the technique is time consuming and demands specialized taxonomic expertise that is difficult to access. A successful alternative has been to exploit a region of the mitochondrial cytochrome oxidase I (COI) gene to classify specimens to the species level. We analyzed the COI sequences of four mite species associated with cassava and classified them definitively by detailed morphological examinations. We then developed an identification kit based on the restriction fragment length polymorphism-polymerase chain reaction of subunit I of the COI gene focused on the three restriction enzymes AseI, MboII, and ApoI. This set of enzymes permitted the simple, accurate identification of Mononychellus caribbeanae, M. tanajoa, M. mcgregori, and Tetranychus urticae, rapidly and with few resources. This kit could be a vital tool for the surveillance and monitoring of mite pests in cassava crop protection programs in Africa, Asia, and Latin America.

Surveillance and diagnostics of the emergent Sri Lankan cassava mosaic virus (Fam. Geminiviridae) in Southeast Asia.

Emergent agricultural pathogens cause severe damage worldwide and their invasive potential is significantly increased by global trade, crop intensification and climate change. Standard surveillance and diagnostic protocols need to be evaluated and implemented, particularly with diseases caused by a wide range of pathogens that induce similar symptoms. Such is the case with Cassava Mosaic Disease (CMD) present in Africa and Asia, and associated with mixed virus infections and recombinant and re-assorted virus strains. CMD has been recently reported in Southeast Asia (SEA) and is already widely spread throughout this region. This communication offers an update on protocols and tools used to track the distribution of CMD and to characterize the pathogen associated with it in SEA.

Complete Genome Sequence of Rice hoja blanca tenuivirus Isolated from a Susceptible Rice Cultivar in Colombia.

We describe here the complete genome of Rice hoja blanca tenuivirus The sequenced isolate was obtained by insect vector transmission from a symptomatic rice sample grown in Colombia. Sequence data from the four RNA components were obtained by deep sequencing (Illumina), and infections were confirmed by enzyme-linked immunosorbent assay and Sanger sequencing.

Resolution of cassava-infecting alphaflexiviruses: Molecular and biological characterization of a novel group of potexviruses lacking the TGB3 gene.

Several potexviruses (Family Alphaflexiviridae) have been reported infecting cassava (Manihot esculenta Crantz) in the Americas. They were isolated from severely diseased plants during the last 30-40 years and include: Cassava common mosaic virus (CsCMV), Cassava Caribbean mosaic virus (CsCaMV), Cassava Colombian symptomless virus (CsCSV) and Cassava virus X (CsVX). However, their definitive classification as distinct species remains unresolved for several reasons, including the lack of sequence data and unavailability of samples from original isolates. This complicates disease diagnostics, cassava germplasm exchange certification, evaluation of virus cleaning protocols and epidemiological studies. Furthermore, a recently detected novel alphaflexivirus, indicates that cassava-infecting potexviruses may be more diverse. To solve the identity of these viruses, we started indexing samples from different parts of Colombia using different sets of PCR primers, antisera available and inoculation to indicator plants. Results show that there are three major phylogenetic groups of potexviruses infecting cassava, and they correspond to CsCMV, CsVX and the newly identified Cassava new alphaflexivirus (CsNAV). Bioassays and sequence analysis established that isolates of CsNAV and CsVX cause latent infections in different cassava landraces, they are not efficiently transmitted to the indicator plant Nicotiana benthamiana and they lack the gene 3 of the conserved potexviral 'triple gene block' (TGB). In contrast, all isolates of CsCMV (which have a characteristic potexvirus genome arrangement) caused Cassava Common Mosaic Disease (CCMD) in single infections and were efficiently transmitted to N. benthamiana. Although phylogenetic analysis of the replicase sequence placed CsNAV and CsVX as members of the Potexvirus genus, their distinct genome arrangement and biological characteristics suggest they can be considered as members of a separate taxonomic group.