Determination of the virus diversity associated with Grapevine leafroll disease

Molenaar, Nicholas

04 1900

Thesis (MSc)--Stellenbosch University, 2015. / ENGLISH ABSTRACT: Vitis vinifera is the woody crop most susceptible to intracellular pathogens. Currently 70 pathogens infect grapevine, of which 63 are of viral origin. Grapevine leafroll-associated virus 3 (GLRaV-3) is the type species of the genus Ampelovirus, family Closteroviridae. It is considered to be the primary causative agent of Grapevine leafroll disease (GLD) globally; however, the etiology of GLD is not completely understood. Here we report on the viral populations present in GLD symptomatic grapevines across the Western Cape province, South Africa. A widespread survey was performed to screen 315 grapevines for 11 grapevine-infecting viruses using RT-PCR. Additionally, GLRaV-3 variant groups were distinguished with high-resolution melt (HRM) curve analysis used in conjunction with real-time RT-PCR. Members of the family Closteroviridae were detected with the highest frequency, particularly GLRaV-3 that was detected in 87% of tested plants. Nextgeneration sequencing (NGS) is capable of detecting known and novel viruses without prior knowledge of viral sequences and when used in a metagenomic approach is able to detected viral populations within diseased vines. A total of 17 grapevine samples were subjected to NGS using either an Illumina MiSeq or HiSeq 2500 instrument to determine the virome within GLD vines. Collectively, more than 190 million reads were generated through NGS. Read datasets were trimmed and filtered for quality and subjected to both read-mapping and de novo assembly. Contigs assembled de novo were analyzed with BLAST (Basic Local Alignment Search Tool) against the NCBI (National Centre for Biotechnology Information) database and it was determined that GLRaV-3 was the best-represented virus, comprising 97.5% of the assembled contigs. Grapevine virus F (GVF) was detected for the first time in South African vineyards through de novo assemblies and the complete genome sequence validated through direct Sanger sequencing. The complete genome of GVF isolate V5 spans 7 539 nucleotides and shares 89.11% nucleotide identity to existing GVF genomes. The data generated through this study will assist in further understanding the etiology of GLD, support the current hypothesis of GLRaV-3 as the primary contributor to GLD, aid in understanding virus associations in diseased vines and potentially develop systems in which to control disease spread and symptom severity. / AFRIKAANSE OPSOMMING: Vitis vinifera is die houtagtige oes wat die mees vatbaarste is vir intrasellulêre patogene. Tans word wingerde deur 70 patogene geïnfekteer, waarvan 63 van virale oorsprong is. Grapevine leafrollassociated virus 3 (GLRaV-3) is die tipe spesie van die genus Ampelovirus, familie Closteroviridae. Dit word globaal beskou as die primêre oorsaak van Wingerd krulblaar-siekte (GLD), alhoewel die etiologie van GLD nie heeltemal begryp word nie. In hierdie verslag word die virale populasies teenwoordig in GLD simptomatiese wingerde oor die Wes-Kaap provinsie in Suid-Afrika gerapporteer. ‘n Wydverspreide opname was uitgevoer om 315 wingerde met 11 wingerdinfekterende virusse te ondersoek, deur gebruik te maak van tru-transkripsie polimerase ketting reaksie (PKR). Verder is variantgroepe van GLRaV-3 onderskei met hoë-resolusie smeltingskurweanalise, tesame met die gebruik van in-tyd tru-transkripsie PKR. Die hoogste frekwensie was van die lede van die familie Closteroviridae, veral GLRaV-3 wat in 87% van die ondersoekte plante gevind is. Nuwe-generasie volgorderbepaling (NGS) beskik oor die vermoë om bekende en nuwe virusse te herken in virale populasies in geaffekteerde wingerde sonder vorige kennis van virale volgorderbepalings en wanneer dit in ‘n metagenomiese benadering gebruik word kan die virale bevolkings binne siek wingerde ontdek. ‘n Totaal van 17 wingerd-steekproewe was blootgestel aan NGS deur die gebruik van of ‘n Illumina MiSeq of ‘n HiSeq 2500 instrument om die virome te bepaal van GLD wingerde. In totaal is meer 190 miljoen lesings gegenereer deur NGS. Hierdie data lesings was verwerk en gefilter vir kwaliteit om onderwerp te word vir beide kartering en de novo samestellings. Contigs verkry deur de novo samestellings was geanaliseer met BLAST (Basic Local Alignment Search Tool) teenoor die NCBI (National Centre for Biotechnology Information) databasis en dit was vasgestel dat GLRaV-3 was die mees-verteenwoordigende virus, bestaande uit 97.5% van die saamgestelde contigs. Grapevine virus F (GVF) was vir die eerste keer in Suid- Afrikaanse wingerde waargeneem deur de novo samestellings en die volledige genoom volgordger is geverifieer deur middel van direkte Sanger volgorderbepaling. Die volledige genoom van GVF isoleer V5 spanwydte van 7539 nukleotiedes en deel 89.11% nukleotied identiteite van bestaande GVF genome. Die gegenereerde data van hierdie studie sal bykomende begrip van die etiologie van GLD bystaan, die huidige hipotese van GLRaV-3 as die primêre bydraer tot GLD ondersteun, verhoogde begrip van virus-assosiasies in wingerdsiektes verseker en potensiële sisteme ontwikkel om siektes en simptome te beheer.

Grapevine leafroll disease

Virus genetic diversity

Virome sequencing

UCTD

Anomalous PCR results to Grapevine leafroll associated closterovirus type 3 in South Africa

Kotze, Aletta Christina

27 June 2008

Grapevine leafroll-associated virus type 3 (GLRaV-3) is the major causative agent of grapevine leafroll disease. The disease has a major negative impact on grape production for wineries, and can cause up to 62.8% loss in production. Despite the negative impact of GLRaV-3 on the grapevine industry worldwide, knowledge on the variability of the virus, which is essential for developing effective control measure of the virus in vineyards, is surprisingly scarce. To test this, six primers sets used in a one tube, one step polymerase chain reaction (PCR) protocol, together with ELISA were used to detect GLRaV-3 virus in 135 plant samples collected from a single vineyard. As expected the more sensitive PCR detected more infected samples than ELISA. However, some samples yielded positive results with the ELISA, but negative results using PCR. This might suggest that strain variants exist. Amongst PCR results of the different primer sets, anomalous results occurred, as often a plant will yield an amplicon with one primer set, but not with another primer set. Using the entire set of 7 PCR results per sample, each plant was assigned a PCR ‘fingerprint’. This yielded 24 different fingerprints in the vineyard. Mapping the spatial distribution of given fingerprints supported the possibility that strain variants exist. However, sequencing areas incorporating the primer binding sites showed no nucleotide sequence differences, indicating that the anomalous PCR results were not due to variants, but rather to protocol error. The PCR protocol used initially was adapted to obtain more optimal detection of virus. Different extraction methods and PCR protocols were tested. It was found that using the two step RT-PCR and using a less dilute plant macerate in ELISA extraction buffer (1:5), yielded amplicon of the expected size from all known infected plant samples. The protocol was further optimized with regards the RT step and subsequent PCR. Since the modified protocol did detect all known infected plant samples it can be concluded that in the 135 plant samples tested no significant sequence variation in strains at the primer binding sites occurred and that the anomalous PCR results initially obtained were due to a sub-optimal extraction method. / Dissertation (MSc (Microbiology))--University of Pretoria, 2008. / Microbiology and Plant Pathology / unrestricted

Grapevine leafroll disease

Closterovirus type 3

South africa

UCTD

Rapid Detection of Grapevine Leafroll-associated virus Type 3 using the reverse transcription loop-mediated amplification method

Walsh, Helen Ann

January 2013

Grapevine Leafroll disease (GLD), one of the most destructive diseases of grapevines, has been found in every country where grapevines are grown. Grapevine Leafroll associated virus type 3 (GLRaV-3), one of several viruses associated with GLD globally, is the most prevalent virus in South African grapevines and therefore control of GLRaV-3 takes high priority in any strategy aimed at control of GLD. GLD can be controlled through the use of an integrated strategy which includes using certified plant material, controlling insect vectors through use of systemic insecticides and the removal of infected vines by roguing. Infected individuals are identified each autumn, using either symptom display (in red cultivars, where infected individuals display interveinal reddening and downward rolling of leaves) or ELISA (in symptomless white cultivars). ELISA is laborious, time consuming and relatively insensitivity compared to molecular techniques and a simpler, more rapid and more sensitive means of indentifying GLRaV-3 infected vines is required. A simple RNA extraction procedure combined with a single-tube reverse transcriptase loop-mediated amplification (RT-LAMP) has been developed which allows for the rapid, simple detection of GLRaV-3. Using RT-LAMP, a viral target can be amplified in 2 hours under isothermal conditions. This GLRaV-3 specific RTLAMP uses hydroxy napthol blue (HNB), a colourimetric indicator that changes from violet to sky blue only where a positive RT-LAMP reaction has occurred, making results quick and easy to interpret. The sensitivity of this technique was compared to ELISA and nested PCR by pooling samples at varying ratios of healthy to infected plants. Using nested PCR and RT-LAMP 1 infected sample could be detected amongst 50 healthy individuals while ELISA could only detect 1 amongst 30 infected making RT-LAMP more sensitive than ELISA. Further RT-LAMP could be performed in 2 hours compared to nested PCR and ELISA’s 8 and 48 hours respectively. Based on these results, RT-LAMP is viable alternative for ELISA for the detection of GLRaV-3 in the field. RT-LAMP was also tested for its ability to detect GLRaV-3 in grapevine rootstocks where, due to low viral titres and erratic distribution, it is notoriously difficult to detect. The rootstocks which were used for testing of GLRaV-3 had been tested in a previous study and it was found that only 28% of samples tested positive after 33 months (post inoculation). Using RT-LAMP, 78% of samples tested positive for GLRaV-3. Although further testing must be done, RT-LAMP may also be a viable alternative for testing grapevine rootstocks for GLRaV-3 infection. / Dissertation (MSc)--University of Pretoria, 2013. / gm2014 / Microbiology and Plant Pathology / unrestricted

Diseases of grapevines

Grapevine Leafroll disease (GLD)

South African grapevines

UCTD

Grapevine Viruses and Associated Vectors in Virginia: Survey, Vector Management, and Development of Efficient Grapevine Virus Testing Methods

Jones, Taylor J.

07 July 2016

In order to aid the booming wine industry in the state of Virginia, U.S.A., we developed a series of studies to provide a deeper understanding of the viruses and vectors for management of virus diseases and development of better tools for grapevine virus diagnostics. A statewide survey for 14 different grapevine viruses between 2009 and 2014 was conducted: 721 samples were collected from 116 vineyards in the period. Among the 12 viruses identified, Grapevine leafroll associated virus-3 (GLRaV-3), Grapevine rupestris stem-pitting associated virus (GRSPaV), and Grapevine red blotch-associated virus (GRBaV) were most commonly present. A new real-time PCR method for the detection of the V2 gene of GRBaV was developed. The resulting method takes less time for more accurate diagnostics than conventional PCR. Evaluation of insecticide effectiveness on GLRaV-3 vectors (mealybugs) and the spread of GLRaV-3 were examined: Four trials conducted from 2012 to 2014 revealed that despite successful control of mealybugs, GLRaV-3 is spread at a very rapid rate. A new sampling technique for efficient nucleic acid storage and testing was developed: the nitrocellulose membrane-based method allows simpler extraction of nucleic acid and provides a storage medium that can hold viable RNA/DNA at room temperature for up to 18 months. An investigation of multiple virus-infected vines and the impact of these co-infections on grapevine fruit chemistry was conducted. GLRaV-3, GRBaV, GRSPaV, and co-infections of the 3 all negatively impacted Brix, pH, titratable acidity, and anthocyanin levels. / Ph. D.

Grapevine leafroll disease

Grapevine red blotch associated virus

Nitrocellulose Membranes

real-time PCR

Mealybugs

Grapevines

Virginia

Documentation of grapevine leafroll-associated viruses in wine grape varieties and native grape species in Virginia, and examination of the movement of grapevine leafroll disease to develop management strategies

Jones, Taylor J.

21 December 2012

Grapevine leafroll-associated virus-2 (GLRaV-2), GLRaV-3, and grapevine fleck virus (GFkV) are widespread in grapes around the world. These viruses can cause significant crop loss and affect wine quality by reducing sugar accumulation and compromising skin color. Mealybugs are vectors of grapevine leafroll-associated viruses (GLRaVs). A statewide survey of commercial and wild grapevines in Virginia was conducted during 2009 through 2011. Also, vector management options were tested in two field studies. GLRaV-2, GLRaV-3, and GFkV were detected in 8%, 25%, and 1%, respectively, of over 1,200 vine samples (41 wine grape varieties) from 77 locations, and 64% of vineyards were positive for at least one of the tested viruses. All 100 wild grapevines tested were free of these three viruses, indicating that they are not alternative hosts. The majority of infected vines from commercial vineyards were planted prior to the 1990\'s; however, some new plantings were also found to be positive, indicating movement of the viruses among vineyards and also potential infection prior to planting. The high frequency of virus-infected vines emphasizes the importance of clean plant materials, as well as management of vector insects. The insecticide trials resulted in promising vector control with dinotefuran and spirotetramat; however, acetamiprid and pryrethroid resulted in an increase in mealybug population. This study is the first to examine multiple grape viruses in VA. It will aid in developing better strategies aimed at controlling mealybugs to restrict the movement of viral diseases. / Master of Science in Life Sciences

Grapevine leafroll disease

GLRaV-2

GLRaV-3

Grapevine Fleck Virus

Mealybugs

Grapevines

Virginia