Abstract
Even though considerable progress has been made in weed ecology, weed molecular biology has been hindered by an inability to genetically manipulate weeds. Genetic manipulation is essential to demonstrate a causative relationship between genotype and phenotype. Herein we demonstrate that virus-mediated transient expression techniques developed for other monocots can be used in black-grass (Alopecurus myosuroides) for loss- and gain-of-function studies. We not only use virus induced gene silencing (VIGS) to create the black-grass exhibiting reduced PHYTOENE DESATURASE expression and virus-mediated overexpression (VOX) to drive GREEN FLUORESCENT PROTEIN, we demonstrate these techniques are applicable to testing hypotheses related to herbicide resistance in black-grass. We use VIGS to demonstrate that AmGSTF1 is necessary for the resistant biotype Peldon to survive fenoxaprop application and show the heterologous expression of the bialaphos resistance gene with VOX is sufficient to confer resistance to an otherwise lethal dose of glufosinate. Black-grass is the most problematic weed for winter-cereal farmers in the UK and Western Europe as it has rapidly evolved adaptions that allow it to effectively avoid current integrated weed management practices. Black-grass also reduces yields and therefore directly threatens food security and productivity. Novel disruptive technologies which mitigate resistance evolution and enable better control over this pernicious weed are therefore required. These virus-mediated protocols offer a step change in our ability to alter genes of interest under controlled laboratory conditions and therefore to gain a molecular-level understanding of how black-grass can survive in the agri-environment.
Highlights
Weeds are arguably among the most economically important groups of plant species
Barley stripe mosaic virus (BSMV) vectors carrying a fragment of black-grass PHYTOENE DESATURASE gene (AmPDS) in antisense orientation induced leaf photobleaching within 5-11 days post inoculation
Glufosinate resistance was not stable when Foxtail mosaic virus (FoMV):bar tillers were separated before spraying (Supplemental Fig. S4). With these data we demonstrate that BSMV Virus-induced gene silencing (VIGS) and FoMV Virus-mediated protein overexpression 13 (VOX) are suitable for loss- and gain-of-function analyses in black-grass relating to herbicide resistance
Summary
Weeds are arguably among the most economically important groups of plant species. They have major agronomic and environmental impacts and affect food security. We used two biotypes that differ in their sensitivity to herbicides (Supplemental Fig. S1): Peldon (multiple herbicide resistant (MHR)) and Rothamsted (sensitive). BSMV vectors carrying a fragment of black-grass PHYTOENE DESATURASE gene (AmPDS) in antisense orientation induced leaf photobleaching within 5-11 days post inoculation (dpi) We assessed suitability of VIGS and VOX for evaluating whether a given gene of interest is necessary or sufficient to confer herbicide resistance in black-grass.
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