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Department of Agricultural Biology

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https://hdl.handle.net/10217/100336
These digital collections include theses, dissertations, faculty publications, and datasets from the Department of Agricultural Biology. Also present is a video documentary titled Complete Harvest: The Future of Rice as Bioenergy. Due to departmental name changes, materials from the following historical departments are also included here: Bioagricultural Sciences and Pest Management; Botany; Botany and Plant Pathology; Entomology; Plant Pathology and Weed Science; Zoology; Zoology and Entomology.

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Browsing Department of Agricultural Biology by Subject "Amaranthus palmeri"

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    Dataset associated with “Investigating the origins and evolution of a glyphosate-resistant weed invasion in South America”
    (Colorado State University. Libraries, 2021) Gaines, T.; Slavov, G.; Hughes, D.; Kuepper, A.; Sparks, C.; Oliva, J.; Vila-Aiub, M.; Garcia, M. A.; Merotto, A.; Neve, P.
    The global invasion, and subsequent spread and evolution of weeds provides unique opportunities to address fundamental questions in evolutionary and invasion ecology. Amaranthus palmeri is a widespread glyphosate-resistant (GR) weed in the USA. Since 2015, GR populations of A. palmeri have been confirmed in South America, raising questions about introduction pathways and the importance of pre- versus post-invasion evolution of GR traits. We used RAD-Seq genotyping to characterize genetic structure of populations from Brazil, Argentina, Uruguay and the USA. We also quantified gene copy number of the glyphosate target, 5-enolpyruvyl-3-shikimate phosphate synthase (EPSPS) and the presence of an extra-chromosomal circular DNA (eccDNA) replicon known to confer GR in USA populations. Populations in Brazil, Argentina, and Uruguay were only weakly differentiated (pairwise FST  0.043) in comparison to USA populations (mean pairwise FST = 0.161, range = 0.068-0.258), suggesting a single major invasion event. However, elevated EPSPS copy number and the EPSPS replicon were identified in all populations from Brazil and Uruguay, but only in a single Argentinean population. These observations are consistent with independent in situ evolution of glyphosate resistance in Argentina, followed by some limited recent migration of the eccDNA based mechanism from Brazil to Argentina. Taken together, our results are consistent with an initial introduction of A. palmeri into South America sometime before the 1980s, and local evolution of GR in Argentina, followed by a secondary invasion of GR A. palmeri with the unique eccDNA based mechanism from the USA into Brazil and Uruguay during the 2010’s.
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    Molecular genetics of glyphosate resistance in Palmer amaranth (Amaranthus palmeri L.)
    (Colorado State University. Libraries, 2009) Gaines, Todd A., author; Westra, Philip, advisor; Leach, Jan, advisor
    Glyphosate resistant Palmer amaranth populations were identified in Georgia in 2004. Studies were undertaken to characterize inheritance, the molecular basis of resistance, and the potential for gene transfer to related Amaranthus species. Dose response results support rejecting a monogenic inheritance hypothesis in favor of an alternative polygenic, additive inheritance model. Apomixis in genetic populations used for inheritance studies is probably occurring and makes interpretation of inheritance difficult. Glyphosate resistance in Palmer amaranth appears to be incompletely dominant and may be polygenic. No target site mutations known to confer resistance were identified in resistant alleles of the 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) gene, the target of glyphosate. Estimation of gene copy numbers of EPSPS relative to acetolactate synthase (ALS) in gDNA by quantitative PCR (qPCR) suggested that resistant plant genomes contain 64 to 128 times more copies of EPSPS than susceptible plants. qPCR on cDNA revealed that EPSPS was expressed approximately 35 times higher in resistant plants. Elevated EPSPS copy number is heritable and correlates with expression level and resistance in F2 populations. The molecular basis of resistance is likely due to increased production of EPSPS due to gene amplification. This is the first documented occurrence of EPSPS gene amplification in a weed population under glyphosate selection pressure. The risk of resistance gene transfer was measured with field studies and hand crosses with A. hybridus, A. retroflexus, A. powellii, A. spinosus, and A. tuberculatus. Glyphosate application (0.4 kg ha-1) was used to screen for resistant progeny from the crosses. Hybridization with A. spinosus occurred in both years of the field study and in hand crosses, with average frequency ranging from <0.01% to 1.4%. Hybrids with A. spinosus were either monoecious or dioecious. Monoecious plants produced seed through self-pollination, and the F2 progeny were segregating for resistance. Hybridization occurred in the 2007 field study with A. hybridus (<0.01%) and A. tuberculatus (0.08% and 0.19% for two accessions), all of the hybrid plants were dioecious, and none produced seed. The highest risk for glyphosate resistance gene transfer from A. palmeri is to A. spinosus.
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    Molecular genetics of herbicide resistance in Palmer amaranth (Amaranthus palmeri): metabolic tembotrione resistance and geographic origin of glyphosate resistance
    (Colorado State University. Libraries, 2018) Küpper, Anita, author; Gaines, Todd A., advisor; Dayan, Franck E., committee member; Nissen, Scott J., committee member; Reddy, Anireddy S. N., committee member
    Palmer amaranth (Amaranthus palmeri) is a major weed in U.S. cotton and soybean production systems, partly because it evolved resistance to five different herbicide modes of action. Resistance to the 4-hydroxyphenylpyruvate dioxygenase (HPPD)-inhibitor tembotrione in a population from Nebraska (NER) is due to enhanced metabolism. This type of non-target-site resistance is especially troublesome because of its potential for cross-resistance. Tembotrione-susceptible (NES) and NER formed the same tembotrione metabolites but NER exhibited faster 4-hydroxylation followed by glycosylation. The T 50 value (time for 50% production of the maximum 4-hydroxylation product) was 4.9 and 11.9 h for NER and NES, respectively. Hydroxylation is typically catalyzed by cytochrome P450 monooxygenases (CYPs). Metabolism differences between NER and NES were most prominent under 28°C conditions and herbicide application at the four-leaf stage. An RNA-Seq transcriptome analysis was conducted with Pseudo-F 2 tembotrione-resistant and -susceptible individuals originating from three separate NER x NES crosses that were sampled before, six, and twelve h after treatment (HAT). Differential gene expression analysis identified CYP72A219 and CYP81E8 as strong candidates for metabolic resistance. The contigs were constitutively expressed in resistant plants, as were the contigs for several glycosyltransferases (GTs), oxidase, and glutathione-S-transferase (GST). Exposure to tembotrione further increased their expression in both resistant and susceptible plants. Originally native to the Southwest, A. palmeri has spread throughout the country. In 2004 a population was identified with resistance to glyphosate, a herbicide heavily relied on in modern no-tillage and transgenic glyphosate-resistant crop systems. Glyphosate resistance in the species is now highly prevalent in USA and was also discovered in Brazil in 2015. This was confirmed by species identification with a genetic marker, dose-response studies, shikimate accumulation assay, and EPSPS copy number assay. The Brazilian population was also resistant to sulfonylurea and imidazolinone ALS inhibitor herbicides conferred by two different alleles for target-site mutations in the ALS gene (W574L and S653N). The degree of genetic relatedness among eight different populations of glyphosate-resistant (GR) and –susceptible (GS) A. palmeri from various geographic regions in USA was investigated by analyzing patterns of phylogeography and diversity to ascertain whether resistance evolved independently or spread from outside to an Arizona locality (AZ-R). Shikimate accumulation and EPSPS genomic copy assays confirmed resistance or susceptibility. With a set of 1,351 single nucleotide polymorphisms (SNPs), discovered by genotyping-by-sequencing (GBS), UPGMA phylogenetic analysis, principal component analysis, Bayesian model-based clustering, and pairwise comparisons of genetic distances were conducted. A GR population from Tennessee and two GS populations from Georgia and Arizona were identified as genetically distinct while the remaining GS populations from Kansas, Arizona, and Nebraska clustered together with two GR populations from Arizona and Georgia. Within the latter group, AZ-R was most closely related to the GS populations from Kansas and Arizona followed by the GR population from Georgia. GR populations from Georgia and Tennessee were genetically distinct from each other. The data suggest the following two possible scenarios: either glyphosate resistance was introduced to the Arizona locality from the east, or resistance evolved independently in Arizona. Glyphosate resistance in the Georgia and Tennessee localities most likely evolved separately. Thus, modern farmers need to continue to diversify weed management practices and prevent seed dispersal to mitigate herbicide resistance evolution in A. palmeri.