Multiple target site resistance to glyphosate in junglerice (<scp><i>Echinochloa colona</i></scp>) lines from California orchards

Morran, Sarah; Moretti, Marcelo L.; Brunharo, Caio Augusto de Castro Grossi; Fischer, Albert J.; Hanson, Bradley D.

doi:10.1002/ps.5061

Cited by 13 publications

(19 citation statements)

References 33 publications

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“…A number of engineered and natural bacterial and plant EPSPS variants have been shown to prevent glyphosate binding and thus endow glyphosate resistance (Healy‐Fried et al ., ; Alibhai et al ., ; Sammons & Gaines, ; Yi et al ., ; Sammons et al ., ). Since the first identification of a naturally evolved glyphosate resistance EPSPS gene mutation, resulting in a Pro‐106‐Ser substitution in Eleusine indica (Baerson et al ., ), other single amino acid substitutions (Thr, Ala, Leu) at the same Pro‐106 residue have been reported to endow glyphosate resistance in weed species (Ng et al ., ; Yu et al ., ; Kaundun et al ., ; Sammons & Gaines, ; Morran et al ., ). Artificial and naturally evolved double EPSPS gene mutations have also been reported to confer glyphosate resistance in bacteria and plants (Padgette et al ., ; Kahrizi et al ., ; Funke et al ., ; Sammons & Gaines, ; Chen et al ., , ; Yu et al ., ).…”

Section: Do Epsps Target‐site Glyphosate Resistance Mutations Lead Tomentioning

confidence: 97%

“…As outlined earlier, glyphosate resistance‐endowing amino acid substitutions at Pro‐106 lead only to low‐level glyphosate resistance and a lack of significant changes in EPSPS functionality (Table ). Not surprisingly, Pro‐106 substitutions are the most common form of target‐site glyphosate resistance (Powles & Yu, ; Sammons & Gaines, ; Morran et al ., ), and resistant individuals show no fitness cost at the plant level, and persist in populations in the absence of glyphosate selection (Yu et al ., ; Fernández‐Moreno et al ., ; Han et al ., ; Wu et al ., ).…”

Section: Do Epsps Target‐site Glyphosate Resistance Mutations Lead Tomentioning

confidence: 99%

“…Additionally, a recently reported novel resistance mechanism involves rapid tissue necrosis by as‐yet‐unknown mechanisms that limit glyphosate transport in resistant Ambrosia trifida (Moretti et al ., ). It is important to realize that both target‐ and nontarget‐site glyphosate resistance mechanisms can coexist within an individual plant and within plant populations (Bostamam et al ., ; Morran et al ., ). Thus, individual plants and/or populations can express both different target‐site (e.g.…”

Section: Introductionmentioning

confidence: 97%

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Do plants pay a fitness cost to be resistant to glyphosate?

Vila‐Aiub

Powles

2019

New Phytologist

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Summary We reviewed the literature to understand the effects of glyphosate resistance on plant fitness at the molecular, biochemical and physiological levels. A number of correlations between enzyme characteristics and glyphosate resistance imply the existence of a plant fitness cost associated with resistance‐conferring mutations in the glyphosate target enzyme, 5‐enolpyruvylshikimate‐3‐phosphate synthase (EPSPS). These biochemical changes result in a tradeoff between the glyphosate resistance of the EPSPS enzyme and its catalytic activity. Mutations that endow the highest resistance are more likely to decrease catalytic activity by reducing the affinity of EPSPS for its natural substrate, and/or slowing the velocity of the enzyme reaction, and are thus very likely to endow a substantial plant fitness cost. Prediction of fitness costs associated with EPSPS gene amplification and overexpression can be more problematic. The validity of cost prediction based on the theory of evolution of gene expression and resource allocation has been cast into doubt by contradictory experimental evidence. Further research providing insights into the role of the EPSPS cassette in weed adaptation, and estimations of the energy budget involved in EPSPS amplification and overexpression are required to understand and predict the biochemical and physiological bases of the fitness cost of glyphosate resistance.

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Section: Do Epsps Target‐site Glyphosate Resistance Mutations Lead Tomentioning

confidence: 97%

Section: Do Epsps Target‐site Glyphosate Resistance Mutations Lead Tomentioning

confidence: 99%

Section: Introductionmentioning

confidence: 97%

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Do plants pay a fitness cost to be resistant to glyphosate?

Vila‐Aiub

Powles

2019

New Phytologist

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“…Because glyphosate inhibits EPSPS, an enzyme of the shikimic acid pathway involved in the catalysis of the reaction between shikimate-3-phosphate and P-enolpyruvate, shikimic acid accumulates as a result of this inhibition and may be used as a biomarker to quantify glyphosate activity in plants. The accumulation of shikimic acid in response to glyphosate was measured as described by Morran et al 16 and based on methods by Shaner 26 with modifications. Briefly, seedlings were treated at the threeto four-leaf stage with 0, 435 and 870 g a.e ha −1 of glyphosate (Roundup PowerMAX ® ) as previously described.…”

Section: Shikimic Acid Accumulation Assaymentioning

confidence: 99%

“…Single nucleotide substitutions (SNPs) in EPSPS, identified in several weed species, result in a wide range of glyphosate resistance levels depending on the species. 15,16 SNPs that are commonly involved in glyphosate resistance are reported to occur at position 106 of the EPSPS, where a proline (wild-type) may be substituted by an alanine, leucine, serine or threonine. 17 Double mutations in the EPSPS (at coding positions 102 and 106) have been described in transgenic crops and weeds, increasing even further the level of glyphosate resistance.…”

Section: Introductionmentioning

confidence: 99%

EPSPS duplication and mutation involved in glyphosate resistance in the allotetraploid weed species Poa annua L.

Brunharo

Morran

Martin

et al. 2019

Pest Management Science

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BACKGROUND Poa annua is a widespread winter annual weed species in California. Recently, poor control of this species with glyphosate was reported by growers in an almond orchard in California with a history of repetitive glyphosate use. The objectives of this research were to evaluate the level of glyphosate resistance in a developed S4 P. annua line (R) and identify the mechanisms of resistance involved. RESULTS Whole‐plant dose–response experiments confirmed glyphosate resistance in R, which required 18‐fold more glyphosate to achieve a 50% growth reduction compared with a susceptible line (S), results that were supported by the lower shikimate accumulation observed in R compared with S. No differences in glyphosate absorption, translocation, or metabolism were observed, suggesting that non‐target‐site mechanisms of resistance are not involved in the resistance phenotype. A missense single nucleotide polymorphism was observed in EPSPS coding position 106 in R, resulting in a leucine to proline substitution. This polymorphism was observed exclusively in P. supina EPSPS homeologs. A seven‐fold increase in the number of copies of EPSPS alleles was observed in R compared with S. CONCLUSIONS We report the first case of glyphosate resistance associated with both EPSPS duplication and target‐site mutation at position 106, leading to high levels of glyphosate resistance in the allotetraploid weed species Poa annua L. Data obtained in this research will be useful for the development of diagnostic tools for rapid glyphosate resistance identification, monitoring and containment. © 2018 Society of Chemical Industry

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