Project description:Resistance to synthetic auxin herbicides was recently confirmed in a population of Amaranthus powellii. Following field studies, an RNA-seq experiment was devised to determine the mechanism of resistance to MCPA (a synthetic auxin herbicide) by comparing the level of gene expression of genes in the auxin pathway between the resistant and a susceptible population of Amaranthus powellii. The results identified several differentially expressed genes (DEGs) in the auxin pathway that were significantly downregulated in the resistant samples indicating that the resistance mechanism may be linked to a target site modification.

Project description:Background: The continuous use of the herbicides contributes to the emergence of the resistant populations of numerous weed species that are tolerant to multiple herbicides with different modes of action (multiple resistance) which is provided by non-target-site resistance mechanisms. In this study, we addressed the question of rapid acquisition of herbicide resistance to pinoxaden (acetyl CoA carboxylase inhibitor) in Apera spica-venti, which endangers winter cereal crops and has high adaptation capabilities to inhabit many rural locations. To this end, de novo transcriptome of Apera spica-venti was assembled and RNA-sequencing analysis of plants resistant and susceptible to pinoxaden treated with this herbicide was performed. Results: The obtained data showed that the prime candidate genes responsible for herbicide resistance were those encoding 3-ketoacyl-CoA synthase 12-like, UDP-glycosyltransferases (UGT) including UGT75K6, UGT75E2, UGT83A1-like, and glutathione S-transferases (GSTs) such as GSTU1 and GSTU6. Also, such highly accelerated herbicide resistance emergence may result from the enhanced constitutive expression of a wide range of genes involved in detoxification already before herbicide treatment and may also influence response to biotic stresses, which was assumed by the detection of expression changes in genes encoding defence-related proteins, including receptor kinase-like Xa21. Moreover, alterations in the expression of genes associated with methylation in non-treated herbicide-resistant populations were identified. Conclusion: The obtained results indicated genes that may be involved in herbicide resistance. Moreover, they provide valuable insight into the possible effect of resistance on the weed interaction with the other stresses by indicating pathways associated with both abiotic and biotic stresses.

Project description:Background: The continuous use of the herbicides contributes to the emergence of the resistant populations of numerous weed species that are tolerant to multiple herbicides with different modes of action (multiple resistance) which is provided by non-target-site resistance mechanisms. In this study, we addressed the question of rapid acquisition of herbicide resistance to pinoxaden (acetyl CoA carboxylase inhibitor) in Apera spica-venti, which endangers winter cereal crops and has high adaptation capabilities to inhabit many rural locations. To this end, de novo transcriptome of Apera spica-venti was assembled and RNA-sequencing analysis of plants resistant and susceptible to pinoxaden treated with this herbicide was performed. Results: The obtained data showed that the prime candidate genes responsible for herbicide resistance were those encoding 3-ketoacyl-CoA synthase 12-like, UDP-glycosyltransferases (UGT) including UGT75K6, UGT75E2, UGT83A1-like, and glutathione S-transferases (GSTs) such as GSTU1 and GSTU6. Also, such highly accelerated herbicide resistance emergence may result from the enhanced constitutive expression of a wide range of genes involved in detoxification already before herbicide treatment and may also influence response to biotic stresses, which was assumed by the detection of expression changes in genes encoding defence-related proteins, including receptor kinase-like Xa21. Moreover, alterations in the expression of genes associated with methylation in non-treated herbicide-resistant populations were identified. Conclusion: The obtained results indicated genes that may be involved in herbicide resistance. Moreover, they provide valuable insight into the possible effect of resistance on the weed interaction with the other stresses by indicating pathways associated with both abiotic and biotic stresses.

Project description:Effective weed management tools are crucial for maintaining the profitable production of snap bean (Phaseolus vulgaris [L.]). Preemergence herbicides help the crop to gain a size advantage over the weeds, but the few preemergence herbicides registered in snap bean have poor waterhemp (Amaranthus tuberculatus) control, a major pest in snap bean production. Waterhemp and other difficult-to-control weeds can be managed by flumioxazin, an herbicide that inhibits protoporphyrinogen oxidase (PPO). However, there is limited knowledge about crop tolerance to this herbicide. We aimed to quantify the degree of snap bean tolerance to flumioxazin and explore the underlying mechanisms. A genome-wide association mapping approach was employed, utilizing field-collected data from a snap bean diversity panel. The response to a preemergence application of flumioxazin was measured by assessing plant population density and shoot biomass variables. Snap bean tolerance to flumioxazin is associated with a single genomic location in chromosome 02. Tolerance is influenced by several factors, including those that are indirectly affected by seed size/weight and those that directly impact the herbicide's metabolism and protect the cell from reactive oxygen species induced damage. Transcriptional profiling and co-expression network analysis identified biological pathways likely involved in flumioxazin tolerance, including oxidoreductase processes. Upregulation of genes involved in those processes is possibly orchestrated by a transcription regulator located in the region identified in the GWAS analysis. Several entries belonging to the Romano class, including Bush Romano 350, Roma II, and Romano Purpiat presented high levels of tolerance in this study. The alleles identified in the diversity panel that condition snap bean tolerance to flumioxazin shed light on a novel mechanism of herbicide tolerance and can be used in crop improvement.

Project description:Resistance to the synthetic auxin herbicide fluroxypyr has an unconfirmed non-target site resistance mechanism. An RNA-Seq experiment was used to align to a reference transcriptome for the weed species Bassia scoparia to quantify gene expression and to identify sequence variants in the alignments. High gene expression was found in several genes related to metabolic degredation of the parent fluroxypyr compound.

Project description:Microalgae, particularly Chlamydomonas, produce valuable pigments like chlorophylls and carotenoids for industrial applications while demonstrating potential in bioremediation. This study employs proteomics to analyze protein expression patterns between norflurazon-resistant and non-resistant Chlamydomonas strains. The investigation aims to understand the molecular mechanisms underlying herbicide resistance, focusing on differential protein expression when exposed to norflurazon, a commonly used herbicide in weed control. This research could provide insights into both bioremediation capabilities and herbicide resistance mechanisms in microalgae.

Project description:Resistance to a non-selective HPPD-inhibiting herbicide syncarpic acid-3 (SA3) in populations of waterhemp (Amaranthus tuberculatus) (whole-plant assay) revealed using untargeted metabolomics via LC-MS.

Project description:Resistance to a non-selective HPPD-inhibiting herbicide syncarpic acid-3 (SA3) in populations of waterhemp (Amaranthus tuberculatus) (excised leaf assay) revealed using untargeted metabolomics via LC-MS.

Project description:Resistance to the phenoxy synthetic auxin herbicide 2,4-D is conferred by a deletion mutation in the degron tail of IAA2. An RNA-Seq experiment was used to assemble a reference transcriptome for the weed species Sisymbrium orientale, to quantify gene expression, and to identify sequence variants in the alignments. A 27 bp deletion was identified in the IAA2 gene. Forward genetics supported the role of this deletion mutation in resistance. The IAA2 deletion allele was transformed into Arabidopsis thaliana to confirm that it conferred 2,4-D resistance.

Project description:Loose silky bentgrass (Apera spica-venti) is an important weed in Europe. It can cause up to 30% yield loses. There is little molecular information available about this species. The lack of genetic information limits the biological understanding of this important noxious weed species such as growth, genetic variation, reproduction, biosynthesis of metabolites and metabolic mechanisms of herbicide resistance. This study produced a reference transcriptome for A. spica-venti from different tissues (leaf, root, stem) and various growth stages (seed at phenological stages 05, 07, 08, 09).