Your search keyword '"Kreuze J"' showing total 44 results

1. Accelerated In Vitro Propagation of Sweetpotato Clones (Ipomoea batatas L.)

Author

Vollmer, R., Espirilla, J., Sánchez, J. C., Arroyo, L., Flores, G., Rojas, A., Anglin, N. L., Kreuze, J., Ellis, D., Kamaluddin, editor, Kiran, Usha, editor, and Abdin, M. Z., editor

Published

2022

2. Viral Diseases in Potato

Author

Kreuze, J. F., Souza-Dias, J. A. C., Jeevalatha, A., Figueira, A. R., Valkonen, J. P. T., Jones, R. A. C., Campos, Hugo, editor, and Ortiz, Oscar, editor

Published

2020

3. A temperature-driven model for potato yellow vein virus transmission efficacy by Trialeurodes vaporariorum (Hemiptera: Aleyrodidae)

Author

Gamarra, H., Carhuapoma, P., Cumapa, L., González, G., Muñoz, J., Sporleder, M., and Kreuze, J.

Published

2020

4. ICTV Virus Taxonomy Profile: Potyviridae 2022

Author

Inoue-Nagata, A.K., Jordan, R., Kreuze, J., Li, F., López-Moya, J.J., Mäkinen, K., Ohshima, K., Wylie, S.J., Inoue-Nagata, A.K., Jordan, R., Kreuze, J., Li, F., López-Moya, J.J., Mäkinen, K., Ohshima, K., and Wylie, S.J.

Abstract

The family Potyviridae includes plant viruses with single-stranded, positive-sense RNA genomes of 8–11 kb and flexuous filamentous particles 650–950 nm long and 11–20 nm wide. Genera in the family are distinguished by the host range, genomic features and phylogeny of the member viruses. Most genomes are monopartite, but those of members of the genus Bymovirus are bipartite. Some members cause serious disease epidemics in cultivated plants. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the family Potyviridae, which is available at ictv.global/report/potyviridae.

Published

2022

5. Degeneration of sweetpotato seed in Tanzania: can cleaned-up, virus-tested seed help?

Author

van der Vlugt, R.A.A., Struik, P.C., Almekinders, C.J.M., Kreuze, J., Ogero, Kwame Okinyi, van der Vlugt, R.A.A., Struik, P.C., Almekinders, C.J.M., Kreuze, J., and Ogero, Kwame Okinyi

Published

2022

6. Translating cropland and trade connectivity for mitigation of emerging pathogens: Priority locations globally and focusing on the Americas

Author

Sula, A. I. Plex, Briseno, R. I. Alcala, Xing, Y., Etherton, B. A., Andersen, K. F., Andrade-Piedra, J. L., Jacques Avelino, Dita Rodriguez, M. A., Gazis, R., Hodson, D., Jarvis, A., Kenyon, L., Kreuze, J. F., Mahabaleswara, S. L., Mosquera Cifuentes, G., Sonder, K., Vallad, G. E., and Garrett, K. A.

Subjects

Terre agricole, Épidémiologie, Pathologie végétale, réduction des risques, Transmission des maladies, H20 - Maladies des plantes

Abstract

Analyses of crop-specific cropland and trade network structures provide a first step for guiding strategies to manage emerging crop pathogens, for iterative improvement as more detailed data become available. We analyzed global to regional cropland and trade networks for the potential spread of emerging pathogens in twelve crops key to food sustainability. We identified which locations have high cropland connectivity globally, and in a more detailed analysis for Central America. A location with high cropland connectivity is more likely to have an important role in epidemics, and so is a candidate for prioritizing mitigation. In epidemic scenario analyses to evaluate relative risk for each crop, we identified countries in the Americas with cropland patterns more likely to result in high levels of pathogen establishment, and so more likely to need focused attention to manage invasions. Country-specific trade networks indicate how invasion risk varies among crops and pathogens, and which components of the network merit particular phytosanitary attention. Using these maps of risk for planning in advance can inform phytosanitary strategies globally, regionally, and within countries, for an efficient response to epidemic invasion. Integrating cropland and trade connectivity with other geographic factors - such as weather conduciveness, management landscapes, regional transportation, local trade, and international phytosanitary networks, will strengthen pest risk assessment and mitigation.

Published

2022

7. Phytosanitary Interventions for Safe Global Germplasm Exchange and the Prevention of Transboundary Pest Spread: The Role of CGIAR Germplasm Health Units

Author

Lava Kumar, P., Maritza, Cuervo, Kreuze, J. F., Giovanna, Muller, Gururaj, Kulkarni, Kumari, Safaa G., Sebastien, Massart, Mezzalama, Monica, Amos, Alakonya, Alice, Muchugi, Ignazio, Graziosi, Marie-Noelle, Ndjiondjop, and Rajan Sharma and Alemayehu Teressa Negawo

Subjects

Seed health

Published

2021

8. Phytosanitary Interventions for Safe Global Germplasm Exchange and the Prevention of Transboundary Pest Spread: The Role of CGIAR Germplasm Health Units

Author

Kumar, P. Lava, primary, Cuervo, Maritza, additional, Kreuze, J. F., additional, Muller, Giovanna, additional, Kulkarni, Gururaj, additional, Kumari, Safaa G., additional, Massart, Sebastien, additional, Mezzalama, Monica, additional, Alakonya, Amos, additional, Muchugi, Alice, additional, Graziosi, Ignazio, additional, Ndjiondjop, Marie-Noelle, additional, Sharma, Rajan, additional, and Negawo, Alemayehu Teressa, additional

Published

2021

9. Interlaboratory test performance studies for identification of Ralstonia solanacearum and molecular confirmation of its virulence : Euphresco Final Report

Author

Tjou-Tam-Sin, N., Vogelaar, M., Li, X., Čermák, V., Forneveld, E., van der Wolf, J.M., Valentini, F., Fraser, K., Cara, M., Yildiz, N., Yuzbasioglu, E., Karahan, A., Ustun, N., and Kreuze, J.

Subjects

Biointeractions and Plant Health, bacteria, food and beverages, Life Science, biochemical phenomena, metabolism, and nutrition, equipment and supplies

Abstract

The EU directive 2006/63/EC describes a detailed protocol for the official testing of Ralstonia solanacearum, that is internationally recognized and has been implemented in many diagnostic laboratories across Europe and beyond. In this protocol, the confirmation of the identity of the bacterium is performed by a laborious, time-consuming and expensive pathogenicity test. Additionally, the described protocols involved in the official testing of Ralstonia solanacearum (for detection and/or identification) require a lot of time, a high level of quarantine measures, and a high degree of expertise. The aim of this project was to develop, and evaluate molecular diagnostic methods for the detection and identification of Ralstonia solanacearum and verification of its virulence that would be faster, more specific and robust. Based on the current taxonomic insights, the high degree of heterogenity present inside the Ralstonia solanacearum species complex (RSSC) has resulted in the clear distinction of three new species inside this complex; the requirement defined in this Euphresco project was that the new molecular tests could be optimally implemented for the detection and identification of Ralstonia solanacearum and Ralstonia pseudosolanacearum, but not of Ralstonia syzygii.The two main objectives of the project were:1) To identify Ralstonia solanacearum virulence genes, and subsequently develop a PCR test on those virulence genes. The development of such a test could substitute the pathogenicity test required by EU directive 2006/63/EC for complete diagnosis of Ralstonia solanacearum.2) To verify other molecular methods to detect or identify Ralstonia solanacearum strains. These methods include the real-time Loop-mediated isothermal amplication test (LAMP) and the recombinase-polymerase amplification assay (RPA).

Published

2020

10. Virus Detection by High-Throughput Sequencing of Small RNAs: Large-Scale Performance Testing of Sequence Analysis Strategies

Author

Massart S., Chiumenti M., De Jonghe K., Glover R., Haegeman A., Koloniuk I., Kominek P., Kreuze J., Kutnjak D., Lotos L., Maclot F., Maliogka V., Maree H.J., Olivier T., Olmos A., Pooggin M.M., Reynard J.-S., Ruiz-Garcia A.B., Safarova D., Schneeberger P. H.H., Sela N., Turco S., Vainio E. J.. Varallyay E., Verdin E., Westenberg M., Brostaux Y., and Candresse T.

Subjects

Virus detection, HTS

Abstract

Recent developments in high-throughput sequencing (HTS), also called next-generation sequencing (NGS), technologies and bioinformatics have drastically changed research on viral pathogens and spurred growing interest in the field of virus diagnostics. However, the reliability of HTS-based virus detection protocols must be evaluated before adopting them for diagnostics. Many different bioinformatics algorithms aimed at detecting viruses in HTS data have been reported but little attention has been paid thus far to their sensitivity and reliability for diagnostic purposes. Therefore, we compared the ability of 21 plant virology laboratories, each employing a different bioinformatics pipeline, to detect 12 plant viruses through a double-blind large-scale performance test using 10 datasets of 21- to 24-nucleotide small RNA (sRNA) sequences from three different infected plants. The sensitivity of virus detection ranged between 35 and 100% among participants, with a marked negative effect when sequence depth decreased. The false-positive detection rate was very low and mainly related to the identification of host genome-integrated viral sequences or misinterpretation of the results. Reproducibility was high(91.6%). This work revealed the key influence of bioinformatics strategies for the sensitive detection of viruses in HTS sRNA datasets and, more specifically (i) the difficulty in detecting viral agents when they are novel or their sRNA abundance is low, (ii) the influence of key parameters at both assembly and annotation steps, (iii) the importance of completeness of reference sequence databases, and (iv) the significant level of scientific expertise needed when interpreting pipeline results. Overall, this work underlines key parameters and proposes recommendations for reliable sRNA-based detection of known and unknown viruses.

Published

2019

11. Efficiency of insect‐proof net tunnels in reducing virus‐related seed degeneration in sweet potato

Author

Ogero, K. O., primary, Kreuze, J. F., additional, McEwan, M. A., additional, Luambano, N. D., additional, Bachwenkizi, H., additional, Garrett, K. A., additional, Andersen, K. F., additional, Thomas‐Sharma, S., additional, and Vlugt, R. A. A., additional

Published

2019

12. Genome sequences of two diploid wild relatives of cultivated sweetpotato reveal targets for genetic improvement

Author

Wu, S, Lau, KH, Cao, Q, Hamilton, JP, Sun, H, Zhou, C, Eserman, L, Gemenet, DC, Olukolu, BA, Wang, H, Crisovan, E, Godden, GT, Jiao, C, Wang, X, Kitavi, M, Manrique-Carpintero, N, Vaillancourt, B, Wiegert-Rininger, K, Yang, X, Bao, K, Schaff, J, Kreuze, J, Gruneberg, W, Khan, A, Ghislain, M, Ma, D, Jiang, J, Mwanga, ROM, Leebens-Mack, J, Coin, LJM, Yencho, GC, Buell, CR, Fei, Z, Wu, S, Lau, KH, Cao, Q, Hamilton, JP, Sun, H, Zhou, C, Eserman, L, Gemenet, DC, Olukolu, BA, Wang, H, Crisovan, E, Godden, GT, Jiao, C, Wang, X, Kitavi, M, Manrique-Carpintero, N, Vaillancourt, B, Wiegert-Rininger, K, Yang, X, Bao, K, Schaff, J, Kreuze, J, Gruneberg, W, Khan, A, Ghislain, M, Ma, D, Jiang, J, Mwanga, ROM, Leebens-Mack, J, Coin, LJM, Yencho, GC, Buell, CR, and Fei, Z

Abstract

Sweetpotato [Ipomoea batatas (L.) Lam.] is a globally important staple food crop, especially for sub-Saharan Africa. Agronomic improvement of sweetpotato has lagged behind other major food crops due to a lack of genomic and genetic resources and inherent challenges in breeding a heterozygous, clonally propagated polyploid. Here, we report the genome sequences of its two diploid relatives, I. trifida and I. triloba, and show that these high-quality genome assemblies are robust references for hexaploid sweetpotato. Comparative and phylogenetic analyses reveal insights into the ancient whole-genome triplication history of Ipomoea and evolutionary relationships within the Batatas complex. Using resequencing data from 16 genotypes widely used in African breeding programs, genes and alleles associated with carotenoid biosynthesis in storage roots are identified, which may enable efficient breeding of varieties with high provitamin A content. These resources will facilitate genome-enabled breeding in this important food security crop.

Published

2018

13. First Report of Potato virus S Naturally Infecting Arracacha (Arracacia xanthorrhiza) in Peru

Author

De Souza, J., primary, Gamarra, H., additional, Müller, G., additional, and Kreuze, J., additional

Published

2018

14. Erratum: ICTV Virus taxonomy profile: Potyviridae

Author

Wylie, S.J., Adams, M., Chalam, C., Kreuze, J., López-Moya, J.J., Ohshima, K., Praveen, S., Rabenstein, F., Stenger, D., Wang, A., Murilo Zerbini, F., Wylie, S.J., Adams, M., Chalam, C., Kreuze, J., López-Moya, J.J., Ohshima, K., Praveen, S., Rabenstein, F., Stenger, D., Wang, A., and Murilo Zerbini, F.

Abstract

No abstract available

Published

2017

15. ICTV Virus Taxonomy Profile: Potyviridae

Author

Wylie, S.J., Adams, M., Chalam, C., Kreuze, J., López-Moya, J.J., Ohshima, K., Praveen, S., Rabenstein, F., Stenger, D., Wang, A., Zerbini, F.M., Wylie, S.J., Adams, M., Chalam, C., Kreuze, J., López-Moya, J.J., Ohshima, K., Praveen, S., Rabenstein, F., Stenger, D., Wang, A., and Zerbini, F.M.

Abstract

The Potyviridae is the largest family of RNA plant viruses, members of which have single-stranded, positive-sense RNA genomes and flexuous filamentous particles 680–900 nm long and 11–20 nm wide. There are eight genera, distinguished by the host range, genomic features and phylogeny of the member viruses. Genomes range from 8.2 to 11.3 kb, with an average size of 9.7 kb. Most genomes are monopartite but those of members of the genus Bymovirus are bipartite. Some members cause serious disease epidemics in cultivated plants. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the taxonomy of the Potyviridae, which is available at www.ictv.global/report/potyviridae.

Published

2017

16. Global Cropland Connectivity: A Risk Factor for Invasion and Saturation by Emerging Pathogens and Pests

Author

Xing, Y., primary, Hernandez Nopsa, J. F., additional, Andersen, K. F., additional, Andrade-Piedra, J., additional, Beed, F. D., additional, Blomme, G., additional, Carvajal-Yepes, M., additional, Coyne, D. L., additional, Cuellar, W. J., additional, Forbes, G. A., additional, Kreuze, J. F., additional, Kroschel, J., additional, Kumar, P. L., additional, Legg, J. P., additional, Parker, M., additional, Schulte-Geldermann, E., additional, Sharma, K., additional, and Garrett, K. A., additional

Published

2017

17. Identification of Nectarine stem pitting‐associated virus infecting Prunus persica in Hungary

Author

Krizbai, L., primary, Kriston, E., additional, Kreuze, J., additional, and Melika, G., additional

Published

2017

18. Next Generation Sequencing and Genetic Analyses Reveal Factors Driving Evolution of Sweetpotato Viruses in Uganda.

Author

Adero J, Wokorach G, Stomeo F, Yao N, Machuka E, Njuguna J, Byarugaba DK, Kreuze J, Yencho GC, Otema MA, Yada B, and Kitavi M

Abstract

Sweetpotato ( Ipomoea batatas L.) is an essential food crop globally, especially for farmers facing resource limitations. Like other crops, sweetpotato cultivation faces significant production challenges due to viral infections. This study aimed to identify and characterize viruses affecting sweetpotato crops in Uganda, mostly those associated with sweetpotato virus disease (SPVD). Infected leaf samples were collected from farmers' fields in multiple districts spanning three regions in Uganda. MiSeq, a next-generation sequencing platform, was used to generate reads from the viral nucleic acid. The results revealed nine viruses infecting sweetpotato crops in Uganda, with most plants infected by multiple viral species. Sweet potato pakakuy and sweet potato symptomless virus_1 are reported in Uganda for the first time. Phylogenetic analyses demonstrated that some viruses have evolved to form new phylogroups, likely due to high mutations and recombination, particularly in the coat protein, P1 protein, cylindrical inclusion, and helper component proteinase regions of the potyvirus. The sweet potato virus C carried more codons under positive diversifying selection than the closely related sweet potato feathery mottle virus, particularly in the P1 gene. This study provides valuable insights into the viral species infecting sweetpotato crops, infection severity, and the evolution of sweet potato viruses in Uganda.

Published

2024

19. A Global Assessment of the State of Plant Health.

Author

Acuña I, Andrade-Piedra J, Andrivon D, Armengol J, Arnold AE, Avelino J, Bandyopadhyay R, Bihon Legesse W, Bock CH, Bove F, Brenes-Arguedas T, Calonnec A, Carmona M, Carnegie AJ, Castilla NP, Chen X, Coletta-Filho HD, Coley PD, Cox KD, Davey T, Del Ponte E, Denman S, Desprez-Loustau ML, Dewdney MM, Djurle A, Drenth A, Ducousso A, Esker P, Fiaboe KM, Fourie PH, Frankel SJ, Frey P, Garcia-Figuera S, Garrett KA, Guérin M, Hardy GESJ, Hausladen H, Hu X, Hüberli D, Juzwik J, Kang Z, Kenyon L, Kreuze J, Kromann P, Kubiriba J, Kuhnem P, Kumar J, Kumar PL, Lebrun MH, Legg JP, Leon A, Ma Z, Mahuku G, Makinson RO, Marzachi C, McDonald BA, McRoberts N, Menkir A, Mikaberidze A, Munck IA, Nelson A, Nguyen NTT, O’Gara E, Ojiambo P, Ortega-Beltran A, Paul P, Pethybridge S, Pinon J, Ramsfield T, Rizzo DM, Rossi V, Safni I, Sah S, Santini A, Sautua F, Savary S, Schreinemachers P, Singh M, Spear ER, Srinivasan R, Tripathi L, Vicent A, Viljoen A, Willocquet L, Woods AJ, Wu B, Xia X, Xu X, Yuen J, Zalamea PC, and Zhou C

Subjects

Agriculture, Plants, Soil, Ecosystem, Plant Breeding

Abstract

The Global Plant Health Assessment (GPHA) is a collective, volunteer-based effort to assemble expert opinions on plant health and disease impacts on ecosystem services based on published scientific evidence. The GPHA considers a range of forest, agricultural, and urban systems worldwide. These are referred to as (Ecoregion × Plant System), i.e., selected case examples involving keystone plants in given parts of the world. The GPHA focuses on infectious plant diseases and plant pathogens, but encompasses the abiotic (e.g., temperature, drought, and floods) and other biotic (e.g., animal pests and humans) factors associated with plant health. Among the 33 (Ecoregion × Plant System) considered, 18 are assessed as in fair or poor health, and 20 as in declining health. Much of the observed state of plant health and its trends are driven by a combination of forces, including climate change, species invasions, and human management. Healthy plants ensure (i) provisioning (food, fiber, and material), (ii) regulation (climate, atmosphere, water, and soils), and (iii) cultural (recreation, inspiration, and spiritual) ecosystem services. All these roles that plants play are threatened by plant diseases. Nearly none of these three ecosystem services are assessed as improving. Results indicate that the poor state of plant health in sub-Saharan Africa gravely contributes to food insecurity and environmental degradation. Results further call for the need to improve crop health to ensure food security in the most populated parts of the world, such as in South Asia, where the poorest of the poor, the landless farmers, are at the greatest risk. The overview of results generated from this work identifies directions for future research to be championed by a new generation of scientists and revived public extension services. Breakthroughs from science are needed to (i) gather more data on plant health and its consequences, (ii) identify collective actions to manage plant systems, (iii) exploit the phytobiome diversity in breeding programs, (iv) breed for plant genotypes with resilience to biotic and abiotic stresses, and (v) design and implement plant systems involving the diversity required to ensure their adaptation to current and growing challenges, including climate change and pathogen invasions., Competing Interests: The author(s) declare no conflict of interest.

Published

2023

20. A temperature-dependent phenology model for Bemisia tabaci MEAM1 (Hemiptera: Aleyrodidae).

Author

Sporleder M, Gamarra H, Carhuapoma P, Goicochea L, Kroschel J, and Kreuze J

Abstract

The sweetpotato whitefly, Bemisia tabaci (Gennadius) Middle East-Asia Minor 1 (MEAM1), is widespread across tropical and subtropical regions, affecting hundreds of cultivated and wild plant species. Because the species transmits a variety of viruses, the whitefly has become one of the most economically significant insect pests in the world. Determining a pest's population growth potential as a function of temperature is critical for understanding a species population dynamics, predicting the potential range of the species and its associated diseases, and designing adaptive pest management strategies. The life history of B. tabaci MEAM1 was studied in life-table experiments at 7 constant temperatures ranging from 12 to 35 °C. Nonlinear equations were fitted to development, mortality, and reproduction data and compiled into an overall phenology rate-summation model using Insect Life Cycle Modeling (ILCYM) software, to simulate life-table parameters based on temperature. Life tables of B. tabaci MEAM1 observed at naturally variable temperature in La Molina, Lima, during different seasons, covering the entire temperature range of the species' predicted performance curve, were used to validate the model. Simulations predicted population growth within temperature between 13.9 and 33.4 °C, revealing a maximum finite rate of population increase (λ = 1.163), with a generation time of 33.3 days at 26.4 °C. Predicted species performance agreed well when compared against observed life tables and published data. The process-based physiological model presented here for B. tabaci MEAM1 should prove useful to predict the potential spatial distribution of the species based on temperature and to adjust pest control measures taking different population growth potentials due to prevailing temperature regimes into account., (© The Author(s) 2023. Published by Oxford University Press on behalf of Entomological Society of America. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2023

21. Evidence that an Unnamed Isometric Virus Associated with Potato Rugose Disease in Peru Is a New Species of Genus Torradovirus .

Author

Alvarez-Quinto R, Amao M, Muller G, Fuentes S, Grinstead S, Fuentes-Bueno I, Roenhorst A, Westenberg M, Botermans M, Kreuze J, and Mollov D

Subjects

RNA, Viral genetics, Peru, Genome, Viral, Plant Diseases, Peptide Hydrolases genetics, Polyproteins genetics, Amino Acids genetics, Growth Disorders genetics, Solanum tuberosum genetics

Abstract

A previously uncharacterized torradovirus species infecting potatoes was detected by high-throughput sequencing from field samples from Peru and in customs intercepts in potato tubers that originated from South America in the United States of America and the Netherlands. This new potato torradovirus showed high nucleotide sequence identity to an unidentified isometric virus (SB26/29), which was associated with a disease named potato rugose stunting in southern Peru characterized over two decades ago. Thus, this virus is tentatively named potato rugose stunting virus (PotRSV). The genome of PotRSV isolates sequenced in this study were composed of two polyadenylated RNA segments. RNA1 ranges from 7,086 to 7,089 nt and RNA2 from 5,228 to 5,230 nt. RNA1 encodes a polyprotein containing the replication block (helicase-protease-polymerase), whereas RNA2 encodes a polyprotein cleaved into a movement protein and the three capsid proteins (CPs). Pairwise comparison among PotRSV isolates revealed amino acid identity values greater than 86% in the protease-polymerase (Pro-Pol) region and greater than 82% for the combined CPs. The closest torradovirus species, squash chlorotic leaf spot virus, shares amino acid identities of ∼58 and ∼41% in the Pro-Pol and the combined CPs, respectively. [Formula: see text] Copyright © 2023 The Author(s). This is an open access article distributed under the CC BY 4.0 International license., Competing Interests: The author(s) declare no conflict of interest.

Published

2023

22. Early-Stage Phenotyping of Sweet Potato Virus Disease Caused by Sweet Potato Chlorotic Stunt Virus and Sweet Potato Virus C to Support Breeding.

Author

David M, Kante M, Fuentes S, Eyzaguirre R, Diaz F, De Boeck B, Mwanga ROM, Kreuze J, and Grüneberg WJ

Subjects

Disease Resistance, Tanzania, Crinivirus, Virus Diseases classification, Ipomoea batatas virology, Potyvirus classification, Potyvirus genetics

Abstract

Sweet potato virus disease (SPVD) is a global constraint to sweetpotato ( Ipomoea batatas ) production, especially under intensive cultivation in the humid tropics such as East Africa. The objectives of this study were to develop a precision SPVD phenotyping protocol, to find new SPVD-resistant genotypes, and to standardize the first stages of screening for SPVD resistance. The first part of the protocol was based on enzyme-linked immunosorbent assay results for sweet potato chlorotic stunt virus (SPCSV) and sweet potato virus C (SPVC) with adjustments to a negative control (uninfected clone Tanzania) and was performed on a prebreeding population (VZ08) comprising 455 clones and 27 check clones graft inoculated under screenhouse conditions. The second part included field studies with 52 selected clones for SPCSV resistance from VZ08 and 8 checks. In screenhouse conditions, the resistant and susceptible check clones performed as expected; 63 clones from VZ08 exhibited lower relative absorbance values for SPCSV and SPVC than inoculated check Tanzania. Field experiments confirmed SPVD resistance of several clones selected by relative absorbance values (nine resistant clones in two locations; that is, 17.3% of the screenhouse selection), supporting the reliability of our method for SPVD-resistance selection. Two clones were promising, exhibiting high storage root yields of 28.7 to 34.9 t ha -1 and SPVD resistance, based on the proposed selection procedure. This modified serological analysis for SPVD-resistance phenotyping might lead to more efficient development of resistant varieties by reducing costs and time at early stages, and provide solid data for marker-assisted selection with a quantitative tool for classifying resistance.[Formula: see text] Copyright © 2023 The Author(s). This is an open access article distributed under the CC BY 4.0 International license., Competing Interests: The author(s) declare no conflict of interest.

Published

2023

23. Ralstonia Strains from Potato-Growing Regions of Kenya Reveal Two Phylotypes and Epidemic Clonality of Phylotype II Sequevar 1 Strains.

Author

Sharma K, Iruegas-Bocardo F, Abdurahman A, Alcalá-Briseño RI, Garrett KA, Goss EM, Ngundo G, Kreuze J, Atieno E, and Munguti F

Subjects

Kenya epidemiology, Phylogeny, Plant Diseases microbiology, Ralstonia, Ralstonia solanacearum genetics, Solanum tuberosum microbiology

Abstract

Bacterial wilt, caused by the Ralstonia solanacearum species complex (RSSC), is the most destructive potato disease in Kenya. Studies were conducted to (i) determine the molecular diversity of RSSC strains associated with bacterial wilt of potato in Kenya, (ii) generate an RSSC distribution map for epidemiological inference, and (iii) determine whether phylotype II sequevar 1 strains exhibit epidemic clonality. Surveys were conducted in 2018 and 2019, in which tubers from wilting potato plants and stem samples of potential alternative hosts were collected for pathogen isolation. The pathogen was phylotyped by multiplex PCR and 536 RSSC strains typed at a sequevar level. Two RSSC phylotypes were identified, phylotype II (98.4%, n = 506 [sequevar 1 ( n = 505) and sequevar 2 ( n = 1)]) and phylotype I (1.6%, n = 30 [sequevar 13 ( n = 9) and a new sequevar ( n = 21)]). The phylotype II sequevar 1 strains were haplotyped using multilocus tandem repeat sequence typing (TRST) schemes. The TRST scheme identified 51 TRST profiles within the phylotype II sequevar 1 strains with a modest diversity index (HGDI = 0.87), confirming the epidemic clonality of RSSC phylotype II sequevar 1 strains in Kenya. A minimum spanning tree and mapping of the TRST profiles revealed that TRST27 '8-5-12-7-5' is the primary founder of the clonal complex of RSSC phylotype II sequevar 1 and is widely distributed via latently infected seed tubers. [Formula: see text] Copyright © 2022 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license.

Published

2022

24. ICTV Virus Taxonomy Profile: Potyviridae 2022.

Author

Inoue-Nagata AK, Jordan R, Kreuze J, Li F, López-Moya JJ, Mäkinen K, Ohshima K, Wylie SJ, and Ictv Report Consortium

Subjects

Host Specificity, Plant Viruses classification, Plant Viruses genetics, Plants, RNA, Viral genetics, Virion genetics, Virion ultrastructure, Virus Replication, Genome, Viral, Phylogeny, Plant Diseases virology, Potyviridae classification, Potyviridae genetics

Abstract

The family Potyviridae includes plant viruses with single-stranded, positive-sense RNA genomes of 8-11 kb and flexuous filamentous particles 650-950 nm long and 11-20 nm wide. Genera in the family are distinguished by the host range, genomic features and phylogeny of the member viruses. Most genomes are monopartite, but those of members of the genus Bymovirus are bipartite. Some members cause serious disease epidemics in cultivated plants. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the family Potyviridae , which is available at ictv.global/report/potyviridae.

Published

2022

25. Phylogenetics and Evolution of Potato Virus V: Another Potyvirus that Originated in the Andes.

Author

Fuentes S, Gibbs AJ, Adams IP, Hajizadeh M, Kreuze J, Fox A, Blouin AG, and Jones RAC

Subjects

Biological Evolution, Plant Diseases virology, South America, Phylogeny, Potyvirus classification, Solanum tuberosum virology

Abstract

Potato virus V (PVV) causes a disease of potato ( Solanum tubersosum ) in South and Central America, Europe, and the Middle East. We report here the complete genomic sequences of 42 new PVV isolates from the potato's Andean domestication center in Peru and of eight historical or recent isolates from Europe. When the principal open reading frames of these genomic sequences together with those of nine previously published genomic sequences were analyzed, only two from Peru and one from Iran were found to be recombinant. The phylogeny of the 56 nonrecombinant open reading frame sequences showed that the PVV population had two major phylogroups, one of which formed three minor phylogroups (A1 to A3) of isolates, all of which are found only in the Andean region of South America (Peru and Colombia), and the other formed two minor phylogroups, a basal one of Andean isolates (A4) that is paraphyletic to a crown cluster containing all the isolates found outside South America (World). This suggests that PVV originated in the Andean region, with only one minor phylogroup spreading elsewhere in the world. In minor phylogroups A1 and A3, there were two subclades on long branches containing isolates from S. phureja evolving more rapidly than the others, and these interfered with dating calculations. Although no temporal signal was directly detected among the dated nonrecombinant sequences, PVV and potato virus Y (PVY) are from the same potyvirus lineage and are ecologically similar, so "subtree dating" was done via a single maximum likelihood phylogeny of PVV and PVY sequences, and PVY's well-supported 157 ce "time to most common recent ancestor" was extrapolated to date that of PVV as 29 bce. Thus the independent historical coincidences supporting the datings of the PVV and PVY phylogenies are the same; PVV arose ≥2,000 years ago in the Andes and was taken to Europe during the Columbian Exchange, where it diversified around 1853 ce, soon after the European potato late blight pandemic. PVV is likely to be more widespread than currently realized and is of biosecurity relevance for world regions that have not yet recorded its presence.[Formula: see text] Copyright © 2022 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license.

Published

2022

26. Interlaboratory Comparison Study on Ribodepleted Total RNA High-Throughput Sequencing for Plant Virus Diagnostics and Bioinformatic Competence.

Author

Gaafar YZA, Westenberg M, Botermans M, László K, De Jonghe K, Foucart Y, Ferretti L, Kutnjak D, Pecman A, Mehle N, Kreuze J, Muller G, Vakirlis N, Beris D, Varveri C, and Ziebell H

Abstract

High-throughput sequencing (HTS) technologies and bioinformatic analyses are of growing interest to be used as a routine diagnostic tool in the field of plant viruses. The reliability of HTS workflows from sample preparation to data analysis and results interpretation for plant virus detection and identification must be evaluated (verified and validated) to approve this tool for diagnostics. Many different extraction methods, library preparation protocols, and sequence and bioinformatic pipelines are available for virus sequence detection. To assess the performance of plant virology diagnostic laboratories in using the HTS of ribosomal RNA depleted total RNA (ribodepleted totRNA) as a diagnostic tool, we carried out an interlaboratory comparison study in which eight participants were required to use the same samples, (RNA) extraction kit, ribosomal RNA depletion kit, and commercial sequencing provider, but also their own bioinformatics pipeline, for analysis. The accuracy of virus detection ranged from 65% to 100%. The false-positive detection rate was very low and was related to the misinterpretation of results as well as to possible cross-contaminations in the lab or sequencing provider. The bioinformatic pipeline used by each laboratory influenced the correct detection of the viruses of this study. The main difficulty was the detection of a novel virus as its sequence was not available in a publicly accessible database at the time. The raw data were reanalysed using Virtool to assess its ability for virus detection. All virus sequences were detected using Virtool in the different pools. This study revealed that the ribodepletion target enrichment for sample preparation is a reliable approach for the detection of plant viruses with different genomes. A significant level of virology expertise is needed to correctly interpret the results. It is also important to improve and complete the reference data.

Published

2021

27. Serological survey and metagenomic discovery of potato viruses in Rwanda and Burundi reveals absence of PVY in Burundi and first report of TRV in potatoes in sub-Saharan Africa.

Author

Okonya JS, Gamarra H, Nduwayezu A, Bararyenya A, Kroschel J, and Kreuze J

Subjects

Burundi epidemiology, Phylogeny, Plant Diseases, Rwanda, Potyvirus genetics, Solanum tuberosum, Viruses

Abstract

Worldwide, potato (Solanum tuberosum L.) is the third most important food crop after rice and wheat. Its production is however constrained by several virus diseases. The occurrence and distribution of the economically important viruses and associated insect vectors is however not known for Rwanda and Burundi, where potato is an important food security and income crop. We surveyed 194 potato fields for viruses and insect vectors. Aphids were commonly found infesting farmers' potato fields in contrast to whiteflies. Testing by Enzyme Linked Immunosorbent Assay (ELISA) for six potato viruses identified five viruses: potato leafroll virus (PLRV), potato virus X, S, M and Y (PVX, PVS, PVM, PVY) in Rwanda and two viruses (PLRV and PVS) in Burundi. A subset of samples were analyzed using small RNA sequencing and assembly (sRSA) and additionally revealed presence of PVX and for the first time, tobacco rattle virus (TRV) in Burundi. PLRV and PVS were most common while PVY was rare and not found in Burundi, which is highly unusual. To our knowledge, this is the first report of TRV infecting potatoes in sub-Saharan Africa. Phylogenetic analysis of 14 complete viral genomes determined by sRSA suggested multiple introductions of viruses into the region., (Copyright © 2021. Published by Elsevier B.V.)

Published

2021

28. The Phylogeography of Potato Virus X Shows the Fingerprints of Its Human Vector.

Author

Fuentes S, Gibbs AJ, Hajizadeh M, Perez A, Adams IP, Fribourg CE, Kreuze J, Fox A, Boonham N, and Jones RAC

Subjects

Animals, Genome, Viral, Genomics, Humans, Open Reading Frames, Phylogeny, Phylogeography, Plant Diseases virology, Potexvirus classification, RNA Virus Infections transmission, RNA, Viral genetics, Disease Vectors, Potexvirus genetics, Solanum tuberosum virology

Abstract

Potato virus X (PVX) occurs worldwide and causes an important potato disease. Complete PVX genomes were obtained from 326 new isolates from Peru, which is within the potato crop's main domestication center, 10 from historical PVX isolates from the Andes (Bolivia, Peru) or Europe (UK), and three from Africa (Burundi). Concatenated open reading frames (ORFs) from these genomes plus 49 published genomic sequences were analyzed. Only 18 of them were recombinants, 17 of them Peruvian. A phylogeny of the non-recombinant sequences found two major (I, II) and five minor (I-1, I-2, II-1, II-2, II-3) phylogroups, which included 12 statistically supported clusters. Analysis of 488 coat protein (CP) gene sequences, including 128 published previously, gave a completely congruent phylogeny. Among the minor phylogroups, I-2 and II-3 only contained Andean isolates, I-1 and II-2 were of both Andean and other isolates, but all of the three II-1 isolates were European. I-1, I-2, II-1 and II-2 all contained biologically typed isolates. Population genetic and dating analyses indicated that PVX emerged after potato's domestication 9000 years ago and was transported to Europe after the 15th century. Major clusters A-D probably resulted from expansions that occurred soon after the potato late-blight pandemic of the mid-19th century. Genetic comparisons of the PVX populations of different Peruvian Departments found similarities between those linked by local transport of seed potato tubers for summer rain-watered highland crops, and those linked to winter-irrigated crops in nearby coastal Departments. Comparisons also showed that, although the Andean PVX population was diverse and evolving neutrally, its spread to Europe and then elsewhere involved population expansion. PVX forms a basal Potexvirus genus lineage but its immediate progenitor is unknown. Establishing whether PVX's entirely Andean phylogroups I-2 and II-3 and its Andean recombinants threaten potato production elsewhere requires future biological studies.

Published

2021

29. Transcriptome analysis provides insights into the responses of sweet potato to sweet potato virus disease (SPVD).

Author

Bednarek R, David M, Fuentes S, Kreuze J, and Fei Z

Subjects

Gene Expression Profiling, Plant Diseases genetics, Potyvirus, Coinfection, Ipomoea batatas genetics, RNA, Small Untranslated, Virus Diseases

Abstract

Sweet potato (Ipomoea batatas) ranks among the most important crops in the world and provides nutritional and economic sustainability for subsistence farmers in sub-Saharan Africa. Its production is mainly constrained by sweet potato virus disease (SPVD) caused by the coinfection of two positive-sense single-stranded RNA viruses, sweet potato chlorotic stunt virus (SPCSV) and sweet potato feathery mottle virus (SPFMV). Current understanding of sweet potato responses to SPCSV and SPFMV at the molecular level remains very limited. In this study, we performed deep sequencing of both messenger RNA (mRNA) and small RNA (sRNA) populations in an SPVD-susceptible cultivar 'Beauregard' upon viral infection, to identify biological pathways that contribute to both general and specific host responses to these important viral pathogens. We found that pathways related to stress response and signaling were significantly affected by viral infection. sRNA components of these pathways were predominantly affected in late stages of the coinfection by SPCSV and SPFMV. We identified several novel microRNAs that were responsive to viral infection, some of which were predicted to target nucleotide-binding site leucine-rich repeat (NBS-LRR) disease resistance genes. The downregulation of the salicylic acid-mediated defense response pathway in particular seems to be a result of the viral infection process, and can in part explain the susceptible nature of the 'Beauregard' cultivar., (Copyright © 2021 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2021

30. Molecular Diversity and Pathogenicity of Ralstonia solanacearum Species Complex Associated With Bacterial Wilt of Potato in Rwanda.

Author

Sharma K, Kreuze J, Abdurahman A, Parker M, Nduwayezu A, and Rukundo P

Subjects

Phylogeny, Plant Diseases, Rwanda, Virulence genetics, Ralstonia solanacearum genetics, Solanum tuberosum

Abstract

Bacterial wilt (BW), caused by Ralstonia solanacearum species complex (RSSC), leads to substantial potato yield losses in Rwanda. Studies were conducted to (i) determine the molecular diversity of RSSC strains associated with BW of potato, (ii) generate an RSSC distribution map for epidemiological inferences, and (iii) test the pathogenicity of predominant RSSC phylotypes on six commercial potato cultivars. In surveys conducted in 2018 and 2019, tubers from wilting potato plants were collected for pathogen isolation. DNA was extracted from 95 presumptive RSSC strain colonies. The pathogen was phylotyped by multiplex PCR and typed at sequevar level. Phylotype II sequevar 1 strains were then haplotyped using multilocus tandem repeat sequence typing (TRST) schemes. Pathogenicity of one phylotype II strain and two phylotype III strains were tested on cultivars Kinigi, Kirundo, Victoria, Kazeneza, Twihaze, and Cruza. Two RSSC phylotypes were identified, phylotype II (95.79%, n = 91) and phylotype III (4.21%, n = 4). This is the first report of phylotype III strains from Rwanda. Phylotype II strains were identified as sequevar 1 and distributed across potato growing regions in the country. The TRST scheme identified 14 TRST haplotypes within the phylotype II sequevar 1 strains with moderate diversity index (HGDI = 0.55). Mapping of TRST haplotypes revealed that a single TRST '8-5-12-7-5' haplotype plays an important epidemiological role in BW of potato in Rwanda. None of the cultivars had complete resistance to the tested phylotypes; the level of susceptibility varied among cultivars. Cultivar Cruza, which is less susceptible to phylotype II and III strains, is recommended when planting potatoes in the fields with history of BW.[Formula: see text] Copyright © 2021 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license.

Published

2021

31. Potato Virus A Isolates from Three Continents: Their Biological Properties, Phylogenetics, and Prehistory.

Author

Fuentes S, Gibbs AJ, Adams IP, Wilson C, Botermans M, Fox A, Kreuze J, Boonham N, Kehoe MA, and Jones RAC

Subjects

Argentina, Australia, Europe, New Zealand, Phylogeny, Plant Breeding, Plant Diseases, Potyvirus genetics, Solanum tuberosum

Abstract

Forty-seven potato virus A (PVA) isolates from Europe, Australia, and South America's Andean region were subjected to high-throughput sequencing, and 46 complete genomes from Europe ( n = 9), Australia ( n = 2), and the Andes ( n = 35) obtained. These and 17 other genomes gave alignments of 63 open reading frames 9,180 nucleotides long; 9 were recombinants. The nonrecombinants formed three tightly clustered, almost equidistant phylogroups; A comprised 14 Peruvian potato isolates; W comprised 37 from potato in Peru, Argentina, and elsewhere in the world; and T contained three from tamarillo in New Zealand. When five isolates were inoculated to a potato cultivar differential, three strain groups (= pathotypes) unrelated to phylogenetic groupings were recognized. No temporal signal was detected among the dated nonrecombinant sequences, but PVA and potato virus Y (PVY) are from related lineages and ecologically similar; therefore, "relative dating" was obtained using a single maximum-likelihood phylogeny of PVA and PVY sequences and PVY's well-supported 157 CE "time to most common recent ancestor". The PVA datings obtained were supported by several independent historical coincidences. The PVA and PVY populations apparently arose in the Andes approximately 18 centuries ago, and were taken to Europe during the Columbian Exchange, radiating there after the mid-19th century potato late blight pandemic. PVA's phylogroup A population diverged more recently in the Andean region, probably after new cultivars were bred locally using newly introduced Solanum tuberosum subsp. tuberosum as a parent. Such cultivars became widely grown, and apparently generated the A × W phylogroup recombinants. Phylogroup A, and its interphylogroup recombinants, might pose a biosecurity risk.[Formula: see text] Copyright © 2021 The Author(s). This is an open access article distributed under the CC BY 4.0 International license.

Published

2021

32. A temperature-dependent phenology model for the greenhouse whitefly Trialeurodes vaporariorum (Hemiptera: Aleyrodidae).

Author

Gamarra H, Sporleder M, Carhuapoma P, Kroschel J, and Kreuze J

Subjects

Animals, Crinivirus, Plant Diseases, Population Dynamics, Temperature, Disease Vectors, Hemiptera physiology

Abstract

The greenhouse whitefly Trialeurodes vaporariorum Westwood (Hemiptera: Aleyrodidae) is a serious pest of many fruits, vegetables and ornamental crops in sub-tropical regions and in greenhouses worldwide. Potato is a secondary host of the species but the major threat from this insect in the Andean region for potato is the transmission by this insect of a crinivirus causing Potato yellow vein disease. Determination of the pest's temperature-dependent population growth potential is crucial knowledge for understanding the population dynamics and spread potential of the species and the diseases it can transmit, as well as for designing effective pest management strategies. Trialeurodes vaporariorum development, mortality and reproduction were studied at seven constant temperatures ranging from 10 to 32 °C. The Insect Life Cycle Modeling (ILCYM) software was used to fit nonlinear equations to the data and establish an overall phenology model to simulate life-table parameters based on temperature. In addition, life tables of T. vaporariorium were established at daily fluctuating temperature in two different environments: Cusco (5 °C-35 °C) and La Molina, Lima (13.7 °C-24.9 °C), and used to adjust and validate the model. The insect only completed its life cycle at constant temperatures above 15 °C and below 32 °C although the cycle was completed at daily fluctuating temperatures between 5 °C and 35 °C. The overall model portrayed population development within the temperature range of 14° to 32 °C with a maximum finite rate of population increase (= 1.14) at 23 °C. However, the model revealed poor convergence with life tables established at fluctuating temperatures indicating an influential effect of temperature fluctuations on the whitefly life history parameters, particularly on adult survival time and reproduction. Therefore, we adjusted the model for convergence with a single life table observed at fluctuating temperature. The adjusted model gave good predictions when compared with remaining observed life tables and published data. The adjusted model predicted population development within the temperature range of 11.5 °C-35.5 °C, and maximum population growth at around 24 °C with a finite rate of increase, λ, of 1.137 and a population doubling time of 5 days. The established process-based physiological model presented here for T. vaporariorum can be used for predicting the species distribution potential based on temperature worldwide and should prove helpful in adjusting pest management measures. Moreover, the information obtained will be used to predict the spread potential of potato yellow vein disease., (Copyright © 2020. Published by Elsevier B.V.)

Published

2020

33. Characterization of distinct strains of an aphid-transmitted ilarvirus (Fam. Bromoviridae) infecting different hosts from South America.

Author

Silvestre R, Fuentes S, Risco R, Berrocal A, Adams I, Fox A, Cuellar WJ, and Kreuze J

Subjects

Animals, Ilarvirus classification, Ilarvirus isolation & purification, Phylogeny, Plant Leaves virology, Recombination, Genetic, Solanum tuberosum virology, South America, United Kingdom, Aphids virology, Genome, Viral, High-Throughput Nucleotide Sequencing, Host Specificity, Ilarvirus genetics, Plant Diseases virology

Abstract

Potato yellowing virus (PYV, original code SB-22), an unassigned member of the Genus Ilarvirus Family Bromoviridae, has been reported infecting potatoes in Peru, Ecuador and Chile. It is associated with symptomless infections, however yellowing of young leaves has been observed in some potato cultivars. Thirteen potato and yacon isolates were selected after routine screening of CIP-germplasm and twenty-four were identified from 994 potato plants collected in Peru whereas one was intercepted from yacon in the UK. These isolates were identified using high throughput sequencing, ELISA, host range and RT-PCR. Here we report the sequence characterization of the complete genomes of nine PYV isolates found infecting Solanum tuberosum, four complete genome isolates infecting Smallanthus sonchifolius (yacon), and in addition 15 complete RNA3 sequences from potato and partial sequences of RNA1, 2 and 3 of isolates infecting potato and yacon from Ecuador, Peru and Bolivia. Results of phylogenetic and recombination analysis showed RNA3 to be the most variable among the virus isolates and suggest potato infecting isolates have resulted through acquisition of a movement protein variant through recombination with an unknown but related ilarvirus, whereas one yacon isolate from Bolivia also had resulted from a recombination event with another related viruses in the same region. Yacon isolates could be distinguished from potato isolates by their inability to infect Physalis floridana, and potato isolates from Ecuador and Peru could be distinguished by their symptomatology in this host as well as phylogenetically. The non-recombinant yacon isolates were closely related to a recently described isolate from Solanum muricatum (pepino dulce), and all isolates were related to Fragaria chiloensis latent virus (FCiLV) reported in strawberry from Chile, and probably should be considered the same species. Although PYV is not serologically related to Alfalfa mosaic virus (AMV), they are both transmitted by aphids and share several other characteristics that support the previous suggestion to reclassify AMV as a member in the genus Ilarvirus., (Copyright © 2020 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2020

34. Molecular Epidemiology of Ralstonia solanacearum Species Complex Strains Causing Bacterial Wilt of Potato in Uganda.

Author

Abdurahman A, Parker ML, Kreuze J, Elphinstone JG, Struik PC, Kigundu A, Arengo E, and Sharma K

Subjects

Molecular Typing, Phylogeny, Plant Diseases microbiology, Uganda, Molecular Epidemiology, Ralstonia solanacearum classification, Ralstonia solanacearum genetics, Solanum tuberosum microbiology

Abstract

Bacterial wilt (BW) caused by the Ralstonia solanacearum species complex (RSSC) is a serious threat to potato production in Uganda. However, little is known about the extent of the disease and the type of the pathogen strains involved. A nationwide survey was conducted to study BW prevalence and incidence in potato, and potato tuber and stem samples of potential alternative hosts were collected for pathogen isolation. DNA was extracted from pure cultures for genetic diversity studies. The pathogen was phylotyped by multiplex PCR; then, a subset of isolates was typed at sequevar level. Isolates of the same sequevar were then haplotyped using multilocus tandem repeat sequence typing (TRST) schemes. BW prevalence and incidence in potato farms were 81.4 and 1.7%, respectively. Three RSSC phylotypes were identified, with the majority of the strains belonging to Phylotype II (80%) followed by Phylotype I (18.5%) and III (1.5%). Phylotype I strains belonged to Sequevar 31, and Phylotype II strains belonged to Sequevar 1. Potato-associated Phylotype II Sequevar 1 strains were more diverse (27 TRST haplotypes) than nonpotato Phylotype I (5 TRST haplotypes). Mapping of TRST haplotypes revealed that three TRST haplotypes of Phylotype II Sequevar 1 strains play an important epidemiological role in BW of potato in Uganda being disseminated via latently infected seed.[Formula: see text]Copyright © 2019 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license.

Published

2019

35. Potato virus Y; the Andean connection.

Author

Fuentes S, Jones RAC, Matsuoka H, Ohshima K, Kreuze J, and Gibbs AJ

Abstract

Potato virus Y (PVY) causes disease in potatoes and other solanaceous crops. The appearance of its necrogenic strains in the 1980s made it the most economically important virus of potatoes. We report the isolation and genomic sequences of 32 Peruvian isolates of PVY which, together with 428 published PVY genomic sequences, gave an alignment of 460 sequences. Of these 190 (41%) were non-recombinant, and 162 of these provided a dated phylogeny, that corresponds well with the likely history of PVY, and show that PVY originated in South America which is where potatoes were first domesticated. The most basal divergences of the PVY population produced the N and C: O phylogroups; the origin of the N phylogroup is clearly Andean, but that of the O and C phylogroups is unknown, although they may have been first to establish in European crops. The current PVY population originated around 156 CE. PVY was probably first taken from South America to Europe in the 16th century in tubers. Most of the present PVY diversity emerged in the second half of the 19th century, after the Phytophthora infestans epidemics of the mid-19th century destroyed the European crop and stimulated potato breeding. Imported breeding lines were shared, and there was no quarantine. The early O population was joined later by N phylogroup isolates and their recombinants generated the R1 and R2 populations of damaging necrogenic strains. Our dating study has confirmed that human activity has dominated the phylodynamics of PVY for the last two millennia.

Published

2019

36. Genome sequences of two diploid wild relatives of cultivated sweetpotato reveal targets for genetic improvement.

Author

Wu S, Lau KH, Cao Q, Hamilton JP, Sun H, Zhou C, Eserman L, Gemenet DC, Olukolu BA, Wang H, Crisovan E, Godden GT, Jiao C, Wang X, Kitavi M, Manrique-Carpintero N, Vaillancourt B, Wiegert-Rininger K, Yang X, Bao K, Schaff J, Kreuze J, Gruneberg W, Khan A, Ghislain M, Ma D, Jiang J, Mwanga ROM, Leebens-Mack J, Coin LJM, Yencho GC, Buell CR, and Fei Z

Subjects

Base Sequence, Carotenoids metabolism, Ecotype, Genetic Variation, Genomics, Molecular Sequence Annotation, Multigene Family, Phylogeny, Polyploidy, Repetitive Sequences, Nucleic Acid genetics, Diploidy, Genome, Plant, Ipomoea batatas genetics, Plant Breeding

Abstract

Sweetpotato [Ipomoea batatas (L.) Lam.] is a globally important staple food crop, especially for sub-Saharan Africa. Agronomic improvement of sweetpotato has lagged behind other major food crops due to a lack of genomic and genetic resources and inherent challenges in breeding a heterozygous, clonally propagated polyploid. Here, we report the genome sequences of its two diploid relatives, I. trifida and I. triloba, and show that these high-quality genome assemblies are robust references for hexaploid sweetpotato. Comparative and phylogenetic analyses reveal insights into the ancient whole-genome triplication history of Ipomoea and evolutionary relationships within the Batatas complex. Using resequencing data from 16 genotypes widely used in African breeding programs, genes and alleles associated with carotenoid biosynthesis in storage roots are identified, which may enable efficient breeding of varieties with high provitamin A content. These resources will facilitate genome-enabled breeding in this important food security crop.

Published

2018

37. Erratum: ICTV Virus Taxonomy Profile: Potyviridae.

Author

Wylie SJ, Adams M, Chalam C, Kreuze J, López-Moya JJ, Ohshima K, Praveen S, Rabenstein F, Stenger D, Wang A, Murilo Zerbini F, and Ictv Report Consortium

Published

2017

38. Molecular and pathobiological characterization of 61 Potato mop-top virus full-length cDNAs reveals great variability of the virus in the centre of potato domestication, novel genotypes and evidence for recombination.

Author

Kalyandurg P, Gil JF, Lukhovitskaya NI, Flores B, Müller G, Chuquillanqui C, Palomino L, Monjane A, Barker I, Kreuze J, and Savenkov EI

Subjects

DNA, Complementary genetics, Evolution, Molecular, Genome, Viral genetics, Genotype, Plant Viruses pathogenicity, RNA Viruses genetics, RNA Viruses pathogenicity, Recombination, Genetic genetics, Plant Viruses genetics, Solanum tuberosum virology

Abstract

The evolutionary divergence of Potato mop-top virus (PMTV), a tri-partite, single-stranded RNA virus, is exceptionally low, based on the analysis of sequences obtained from isolates from Europe, Asia and North America. In general, RNA viruses exist as dynamic populations of closely related and recombinant genomes that are subjected to continuous genetic variation. The reason behind the low genetic variation of PMTV remains unclear. The question remains as to whether the low variability is a shared property of all PMTV isolates or is a result of the limited number of isolates characterized so far. We hypothesized that higher divergence of the virus might exist in the Andean regions of South America, the centre of potato domestication. Here, we report high variability of PMTV isolates collected from 12 fields in three locations in the Andean region of Peru. To evaluate PMTV genetic variation in Peru, we generated full-length cDNA clones, which allowed reliable comparative molecular and pathobiological characterization of individual isolates. We found significant divergence of the CP-RT and 8K sequences. The 8K cistron, which encodes a viral suppressor of RNA silencing, was found to be under diversifying selection. Phylogenetic analysis determined that, based on the CP-RT sequence, all PMTV isolates could be categorized into three separate lineages (clades). Moreover, we found evidence for recombination between two clades. Using infectious cDNA clones of the representatives of these two clades, as well as reassortants for the RNA-CP genomic component, we determined the pathobiological differences between the lineages, which we coined as S (for severe) and M (for mild) types. Interestingly, all isolates characterized previously (from Europe, Asia and North America) fall into the S-type clade, whereas most of the Peruvian isolates belong to the M-type. Taken together, our results support the notion of the single introduction of PMTV from the centre of potato origin to Europe, and subsequent spread of the S-type into Asia and USA. This is also supported by the suggested novel classification of isolates based on genetic constellations., (© 2017 THE AUTHORS. MOLECULAR PLANT PATHOLOGY PUBLISHED BY BRITISH SOCIETY FOR PLANT PATHOLOGY AND JOHN WILEY & SONS LTD.)

Published

2017

39. Diversity, Pathogenicity, and Current Occurrence of Bacterial Wilt Bacterium Ralstonia solanacearum in Peru.

Author

Gutarra L, Herrera J, Fernandez E, Kreuze J, and Lindqvist-Kreuze H

Abstract

The current bacterial wilt infestation level in the potato fields in the Peruvian Andes was investigated by collecting stem samples from wilted plants and detecting Ralstonia solanacearum . In total 39 farmers' fields located in the central and northern Peru between the altitudes 2111 and 3742 m above sea level were sampled. R. solanacearum was detected in 19 fields, and in 153 out of the 358 samples analyzed. Phylogenetic analysis using the partial sequence of the endoglucanase gene on strains collected in Peru between 1966 and 2016 from potato, pepper, tomato, plantain or soil, divided the strains in phylotypes I, IIA, and IIB. The Phylotype IIB isolates formed seven sequevar groups including the previously identified sequevars 1, 2, 3, 4, and 25. In addition to this, three new sequevars of phylotype IIB were identified. Phylotype IIA isolates from Peru clustered together with reference strains previously assigned to sequevars 5, 39, 41, and 50, and additionally one new sequevar was identified. The Phylotype I strain was similar to the sequevar 18. Most of the Peruvian R. solanacearum isolates were IIB-1 strains. In the old collection sampled between 1966 and 2013, 72% were IIB-1 and in the new collection at 2016 no other strains were found. The pathogenicity of 25 isolates representing the IIA and IIB sequevar groups was tested on potato, tomato, eggplant and tobacco. All were highly aggressive on potato, but differed in pathogenicity on the other hosts, especially on tobacco. All IIA strains caused latent infection on tobacco and some strains also caused wilting, while IIB strains caused only few latent infections on this species. In conclusion, high molecular diversity was found among the R. solanacearum strains in Peru. Most of the variability was found in areas that are no longer used for potato cultivation and thus these strains do not pose a real threat for potato production in the country. Compared to the previous data from the 1990s, the incidence of bacterial wilt has decreased in Peru. The epidemics are likely caused by infected seed tubers carrying the clonal brown rot strain IIB-1.

Published

2017

40. Complete sequence and variability of a new subgroup B nepovirus infecting potato in central Peru.

Author

De Souza J, Müller G, Perez W, Cuellar W, and Kreuze J

Subjects

Base Sequence, Genome, Viral, Molecular Sequence Data, Nepovirus classification, Peru, Phylogeny, RNA, Viral genetics, Sequence Analysis, DNA, Viral Proteins genetics, Genetic Variation, Nepovirus genetics, Nepovirus isolation & purification, Plant Diseases virology, Solanum tuberosum virology

Abstract

The complete bipartite genome (RNA1 and RNA2) of a new nepovirus infecting potato was obtained using small RNA sequencing and assembly complemented by Sanger sequencing. Each RNA encodes a single polyprotein, flanked by 5' and 3' untranslate regions (UTR) and followed by a poly (A) tail. The putative polyproteins encoded by RNA1 and RNA2 had sets of motifs which are characteristic of viruses in the genus Nepovirus. Sequence comparisons using the Pro-Pol region and the coat protein, including phylogenetic analysis of these regions, showed closest relationships with nepoviruses. The data obtained support the taxonomical status of this new virus (putative named Potato virus B, PVB) as a member of the genus Nepovirus, subgroup B.

Published

2017

41. ICTV Virus Taxonomy Profile: Potyviridae.

Author

Wylie SJ, Adams M, Chalam C, Kreuze J, López-Moya JJ, Ohshima K, Praveen S, Rabenstein F, Stenger D, Wang A, Zerbini FM, and Ictv Report Consortium

Subjects

Gene Order, Genome, Viral, Phylogeny, Plant Viruses physiology, Potyviridae physiology, RNA, Viral genetics, Virus Replication, Plant Diseases virology, Plant Viruses classification, Plant Viruses genetics, Potyviridae classification, Potyviridae genetics

Abstract

The Potyviridae is the largest family of RNA plant viruses, members of which have single-stranded, positive-sense RNA genomes and flexuous filamentous particles 680-900 nm long and 11-20 nm wide. There are eight genera, distinguished by the host range, genomic features and phylogeny of the member viruses. Genomes range from 8.2 to 11.3 kb, with an average size of 9.7 kb. Most genomes are monopartite but those of members of the genus Bymovirus are bipartite. Some members cause serious disease epidemics in cultivated plants. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the taxonomy of the Potyviridae, which is available at www.ictv.global/report/potyviridae.

Published

2017

42. VirusDetect: An automated pipeline for efficient virus discovery using deep sequencing of small RNAs.

Author

Zheng Y, Gao S, Padmanabhan C, Li R, Galvez M, Gutierrez D, Fuentes S, Ling KS, Kreuze J, and Fei Z

Subjects

Animals, Automation instrumentation, Computational Biology instrumentation, High-Throughput Nucleotide Sequencing instrumentation, Humans, Viruses classification, Viruses genetics, Automation methods, Computational Biology methods, High-Throughput Nucleotide Sequencing methods, RNA, Small Untranslated genetics, RNA, Viral genetics, Viruses isolation & purification

Abstract

Accurate detection of viruses in plants and animals is critical for agriculture production and human health. Deep sequencing and assembly of virus-derived small interfering RNAs has proven to be a highly efficient approach for virus discovery. Here we present VirusDetect, a bioinformatics pipeline that can efficiently analyze large-scale small RNA (sRNA) datasets for both known and novel virus identification. VirusDetect performs both reference-guided assemblies through aligning sRNA sequences to a curated virus reference database and de novo assemblies of sRNA sequences with automated parameter optimization and the option of host sRNA subtraction. The assembled contigs are compared to a curated and classified reference virus database for known and novel virus identification, and evaluated for their sRNA size profiles to identify novel viruses. Extensive evaluations using plant and insect sRNA datasets suggest that VirusDetect is highly sensitive and efficient in identifying known and novel viruses. VirusDetect is freely available at http://bioinfo.bti.cornell.edu/tool/VirusDetect/., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2017

43. Marker-free PLRV resistant potato mediated by Cre-loxP excision and RNAi.

Author

Orbegozo J, Solorzano D, Cuellar WJ, Bartolini I, Roman ML, Ghislain M, and Kreuze J

Subjects

DNA, Bacterial genetics, Genetic Vectors genetics, Integrases genetics, Luteoviridae genetics, Luteoviridae pathogenicity, Plants, Genetically Modified growth & development, Plants, Genetically Modified virology, RNA Interference, Solanum tuberosum growth & development, Solanum tuberosum virology, Inverted Repeat Sequences genetics, Plants, Genetically Modified genetics, Solanum tuberosum genetics, Viral Envelope Proteins genetics

Abstract

An inverted repeat construct corresponding to a segment of the potato leaf roll virus coat protein gene was created under control of a constitutive promoter and transferred into a transformation vector with a heat inducible Cre-loxP system to excise the nptII antibiotic resistance marker gene. Fifty-eight transgenic events were evaluated for resistance to PLRV by greenhouse inoculations, which lead to the identification of 7 highly resistant events, of which 4 were extremely resistant. This resistance was also highly effective against accumulation in subsequent tuber generations from inoculated plants, which has not been reported before. Northern blot analysis showed correlation of PLRV specific siRNA accumulation with the level of PLRV resistance. Heat mediated excision of the nptII antibiotic resistance gene in PLRV resistant events was highly efficient in one event with full excision in 71 % of treated explants. On the other hand 8 out of 10 analyzed events showed truncated T-DNA insertions lacking one of the two loxP sites as determined by PCR and confirmed by sequencing flanking regions in 2 events, suggesting cryptic LB sites in the non-coding region between the nptII gene and the flanking loxP site. Accordingly, it is proposed to modify the Cre-loxP vector by reducing the 1 kb size of the region between nptII, loxP, and the LB.

Published

2016

44. Synergistic interactions of begomoviruses with Sweet potato chlorotic stunt virus (genus Crinivirus) in sweet potato (Ipomoea batatas L.).

Author

Cuellar WJ, Galvez M, Fuentes S, Tugume J, and Kreuze J

Subjects

Base Sequence, Crinivirus isolation & purification, Eosinophil Cationic Protein metabolism, Genome, Viral, Ipomoea batatas genetics, Likelihood Functions, Phylogeny, Plant Diseases virology, Plants, Genetically Modified, RNA, Small Interfering metabolism, Begomovirus physiology, Crinivirus physiology, Host-Pathogen Interactions, Ipomoea batatas virology

Abstract

Three hundred and ninety-four sweet potato accessions from Latin America and East Africa were screened by polymerase chain reaction (PCR) for the presence of begomoviruses, and 46 were found to be positive. All were symptomless in sweet potato and generated leaf curling and/or chlorosis in Ipomoea setosa. The five most divergent isolates, based on complete genome sequences, were used to study interactions with Sweet potato chlorotic stunt virus (SPCSV), known to cause synergistic diseases with other viruses. Co-infections led to increased titres of begomoviruses and decreased titres of SPCSV in all cases, although the extent of the changes varied notably between begomovirus isolates. Symptoms of leaf curling only developed temporarily in combination with isolate StV1 and coincided with the presence of the highest begomovirus concentrations in the plant. Small interfering RNA (siRNA) sequence analysis revealed that co-infection of SPCSV with isolate StV1 led to relatively increased siRNA targeting of the central part of the SPCSV genome and a reduction in targeting of the genomic ends, but no changes to the targeting of StV1 relative to single infection of either virus. These changes were not observed in the interaction between SPCSV and the RNA virus Sweet potato feathery mottle virus (genus Potyvirus), implying specific effects of begomoviruses on RNA silencing of SPCSV in dually infected plants. Infection in RNase3-expressing transgenic plants showed that this protein was sufficient to mediate this synergistic interaction with DNA viruses, similar to RNA viruses, but exposed distinct effects on RNA silencing when RNase3 was expressed from its native virus, or constitutively from a transgene, despite a similar pathogenic outcome., (© 2014 BSPP AND JOHN WILEY & SONS LTD.)

Published

2015