Your search keyword '"Osuna, María Dolores"' showing total 8 results

1. Caracterización de la resistencia herbicida de poblaciones españolas de Chloris truncata frente a glifosato.

Author

Mora, German, Recasens, Jordi, Osuna, María Dolores, Monreal, Miriam Gil, and Torra, Joel

Abstract

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Published

2024

2. Genetic basis and origin of resistance to acetolactate synthase inhibitors in Amaranthus palmeri from Spain and Italy.

Author

Manicardi, Alfredo, Scarabel, Laura, Llenes, Josep María, Montull, José María, Osuna, María Dolores, Torra Farré, Joel, and Milani, Andrea

Subjects

ACETOLACTATE synthase, GENETIC variation, SEED dispersal, HAPLOTYPES, AMARANTHUS palmeri, PEST control, AMARANTHS, BIOLOGICAL weed control

Abstract

BACKGROUND: Amaranthus palmeri is an aggressive annual weed native to the United States, which has become invasive in some European countries. Populations resistant to acetolactate synthase (ALS) inhibitors have been recorded in Spain and Italy, but the evolutionary origin of the resistance traits remains unknown. Bioassays were conducted to identify cross‐resistance to ALS inhibitors and a haplotype‐based genetic approach was used to elucidate the origin and distribution of resistance in both countries. RESULTS: Amaranthus palmeri populations were resistant to thifensulfuron‐methyl and imazamox, and the 574‐Leu mutant ALS allele was found to be the main cause of resistance among them. In two Spanish populations, 376‐Glu and 197‐Thr mutant ALS alleles were also found. The haplotype analyses revealed the presence of two and four distinct 574‐Leu mutant haplotypes in the Italian and Spanish populations, respectively. None was common to both countries, but some mutant haplotypes were shared between geographically close populations or between populations more than 100 km apart. Wide genetic diversity was found in two very close Spanish populations. CONCLUSION: ALS‐resistant A. palmeri populations were introduced to Italy and Spain from outside Europe. Populations from both countries have different evolutionary histories and originate from independent introduction events. ALS resistance then spread over short and long distances by seed dispersal. The higher number and genetic diversity among mutant haplotypes from the Spanish populations indicated recurrent invasions. The implementation of control tactics to limit seed dispersal and the establishment of A. palmeri is recommended in both countries. © 2023 The Authors. Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2023

3. Various Population Structures of Cryphonectria parasitica in Cáceres (Spain) Determine the Feasibility of the Biological Control of Chestnut Blight with Hypovirulent Strains.

Author

Rodríguez-Molina, María del Carmen, García-García, María Blanca, Osuna, María Dolores, Gouveia, Eugénia, and Serrano-Pérez, Paula

Subjects

PARASITIC wasps, CHESTNUT, CASTANEA, DIAGNOSTIC use of polymerase chain reaction, BARRAGES

Abstract

Chestnut blight, caused by Cryphonectria parasitica, is a severe disease that may be biologically controlled by the use of hypovirulent strains, but the diversity of the pathogen population affects biocontrol feasibility. Villuercas–Ibores–Jara, the Jerte Valley and La Vera are the main chestnut production districts in Cáceres (central-western Spain). The purpose of this study is to determine the Vegetative Compatibility Groups (VCGs) and mating types in these districts and to identify hypovirulent isolates to be used in biological control. The VCGs were determined by the merging/barrage response; PCR tests were used for the mating type determination and CHV-1 hypovirus detection. In total, 40 sites were surveyed and 269 isolates were obtained, most of them (227) from the Villuercas–Ibores–Jara district, where EU11 was the predominant VCG (88.1%) with EU1 (6.6%) and EU12 (4.4%) being also present. In the Jerte Valley and La Vera, EU1 (61.9%), EU11 (11.9%) and EU12 (11.9%) were the predominant VCGs. Both mating types were detected (48% MAT-1; 50% MAT-2) and in general, only one mating type was found in each site. The presence of Cryphonectria hypovirus 1 (CHV-1), subtype I, was identified in only one isolate (VCG EU11) from Villuercas–Ibores–Jara. The characteristics of the C. parasitica population in this district and the occurrence of CHV-1 hypovirus support the potential of successful biological control in Villuercas–Ibores–Jara using hypovirulent strains, while in the Jerte Valley and La Vera only preventive measures are recommended. [ABSTRACT FROM AUTHOR]

Published

2023

4. Physiological Fitness Associated to ACCase Target-Site Resistance Enhances Growth and Reproduction in Phalaris brachystachys.

Author

Golmohammadzadeh, Sajedeh, Gherekhloo, Javid, Osuna, María Dolores, Ghaderi-Far, Farshid, Kamkar, Behnam, Alcántara-de la Cruz, Ricardo, and De Prado, Rafael

Subjects

LEAF area index, BIOLOGICAL fitness, PLANT growth

Abstract

Short-spike canarygrass (Phalaris brachystachys (Link.)) from Iranian wheat fields has developed resistance to acetyl-coenzyme A carboxylase (ACCase) inhibitors due to a target-site mutation (Ile-1781-Thr). Target-site resistance mutations may confer pleiotropic effects in weeds. In this paper, the possible effect of the Ile-1781-Thr mutation on the ecological fitness during life cycles in P. brachystachys plants was investigated. ACCase genes of P. brachystachys populations resistant (R) and susceptible (S) to ACCase inhibitors were sequenced and the vegetative growth and reproductive characteristics of the plants were assessed. In the final growth stage (217 days after planting—DAP), R sub-population plants were 30 cm taller than the S plants. Additionally, the R sub-population produced up to 12 leaves and 2.8 tillers more per plant, and accumulated double the dry weight (2850 g m−2) compared to the S sub-population. The leaf area index (LAI) of the R sub-population was 1.1 times higher than that of the S sub-population. In addition, the net assimilation rate (NAR) and plant growth rate (PGR) between 114 and 182 DAP of the R sub-population were 0.11 and 13 g m−2 d−1 higher than the S sub-population, but the relative growth rate (RGR) was similar between R and S sub-populations. The number of spikes (6 vs. 3.8), the spike length (8.4 vs. 5.5), and number of seeds per plant (1276 vs. 751 seed plant−1) of the R sub-population were higher than the S ones, but the weight (3.25 g) and size (11.6 mm2) of 1000 seeds were similar between populations. The R sub-population of P. brachystachys exhibited higher plant growth and reproductive parameters than the S one, which may increase the frequency of resistance in the population in the absence of adequate weed-control methods. [ABSTRACT FROM AUTHOR]

Published

2022

5. Editorial: Multiple Herbicide-Resistant Weeds and Non-target Site Resistance Mechanisms: A Global Challenge for Food Production.

Author

Torra, Joel, Osuna, María Dolores, Merotto, Aldo, and Vila-Aiub, Martin

Subjects

HERBICIDE resistance, WEEDS, SUSTAINABLE agriculture, PESTICIDE resistance, BOTANY, WEED control, FOOD production, WEED competition

Abstract

In both 2,4-D and glyphosate cases, a potential reduced herbicide translocation resistance mechanism could be related to ABC transporters (Pan et al., [42]), however, alterations in translocation and cell exclusion resulting in 2,4-D and glyphosate resistance were not identified with the RN phenotype. Although reduced glyphosate translocation was described as a resistance mechanism long ago, only recently the first glyphosate cell membrane carrier has been identified (ABCC-type transporter) conferring glyphosate resistance in I E. colona i (Pan et al., [42]). Resistance to ALS, ACCase, and EPSPS inhibiting herbicides are the most reported cases in this Research Topic, with 8, 7, and 5 contributions, respectively, which agrees with the SoA herbicides most related to herbicide resistance worldwide (Heap, [31]). Keywords: cross-resistance; cytochrome P450 monooxygenase (CYP450); enhanced herbicide metabolism; glutathione-S-transferase (GST); glyphosate; rapid necrosis EN cross-resistance cytochrome P450 monooxygenase (CYP450) enhanced herbicide metabolism glutathione-S-transferase (GST) glyphosate rapid necrosis 1 5 5 11/01/21 20211028 NES 211028 Evolution of Multiple Survival Mechanisms The acquired inheritable trait of plants to survive and reproduce under herbicide exposure is defined as resistance. [Extracted from the article]

Published

2021

6. Erratum: Torra et al. Amaranthus palmeri a New Invasive Weed in Spain with Herbicide Resistant Biotypes. Agronomy 2020 , 10 , 993.

Author

Torra, Joel, Royo-Esnal, Aritz, Romano, Yolanda, Osuna, María Dolores, León, Ramón G., and Recasens, Jordi

Subjects

AMARANTHUS palmeri, NOXIOUS weeds, AGRONOMY, HERBICIDES

Abstract

Conflicts of Interest The authors declare no conflict of interest. Reference 1 Torra J., Royo-Esnal A., Romano Y., Osuna M.D., León R.G., Recasens J. Amaranthus palmeri a New Invasive Weed in Spain with Herbicide Resistant Biotypes. The authors would like to make the following correction to the published paper [[1]]: Revise the content in Section 2.4 from "All mutations conferring ALS resistance in I A. palmeri i in positions Ser653, Trp574, Pro197, Pro197, Ala122 and Ala122 of CAD and BE domains" to "All mutations conferring ALS resistance in I A. palmeri i in positions Gly654, Ser653, Trp574, Ala205, Pro197 and Ala122 of CAD and BE domains". [Extracted from the article]

Published

2021

7. Different Mutations Providing Target Site Resistance to ALS- and ACCase-Inhibiting Herbicides in Echinochloa spp. from Rice Fields.

Author

Amaro-Blanco, Ignacio, Romano, Yolanda, Palmerin, Jose Antonio, Gordo, Raquel, Palma-Bautista, Candelario, De Prado, Rafael, Osuna, María Dolores, and Andolfi, Anna

Subjects

ECHINOCHLOA, HERBICIDES, RICE, ACETOLACTATE synthase, ACETYL-CoA carboxylase, HERBICIDE-resistant crops, HERBICIDE resistance, GLYPHOSATE

Abstract

Echinochloa spp. is one of the most invasive weeds in rice fields worldwide. Acetolactate synthase (ALS) and acetyl-CoA carboxylase (ACCase) inhibiting herbicides are two of the most widely used rice herbicides. However, overuse has led to the resistance evolution of Echinochloa spp. to penoxsulam (ALS-inhibitor) and cyhalofop-methyl (ACCase-inhibitor). In this work, 137 different Echinochloa spp. populations were collected in different rice fields in Extremadura (western Spain) where lack of control was detected. Target-site based resistance (by sequencing ALS and ACCase gene) and characterization of Echinochloa species at the molecular level (based on PCR-RFLP analyses) were carried out in those populations. Most of the populations studied (111 of 137) belong to the E. oryzicola/E. oryzoides group. Three-point mutations were identified in ALS genes: Pro197Ser, Pro197Thr, and Ser653Asn, the first being the most frequent substitution in resistant plants. In the ACCase gene, the Ile1781Leu substitution was found. In both ALS and ACCase sequencing, evidence of heterozygosity was also observed. To assess whether cross-resistance patterns differed between mutations, two populations belonging to the E. oryzicola/E. oryzoides group had its most frequent mutations (Pro197Ser, population ech3-14 and Ile1781Leu, population ech114-10) chosen to be carried out in a dose-response assay. It was confirmed that Pro197Ser conferred resistance to triazolopyrimidine, imidazolinone, sulfonylurea, and pyrimidinyl benzoate families. On the other hand, the Ile1781Leu change gave resistance to aryloxyphenoxypropionate and cyclohexanedione families. Of the authorized herbicides in rice in Spain, more that 80% belong to these families. It is therefore important that farmers carry out an integrated control system that combines both chemical and non-chemical tools. [ABSTRACT FROM AUTHOR]

Published

2021

8. Amaranthus palmeri a New Invasive Weed in Spain with Herbicide Resistant Biotypes.

Author

Torra, Joel, Royo-Esnal, Aritz, Romano, Yolanda, Osuna, María Dolores, León, Ramón G., and Recasens, Jordi

Subjects

AMARANTHUS palmeri, HERBICIDE resistance, NOXIOUS weeds, HERBICIDES, MICROSATELLITE repeats, DNA fingerprinting

Abstract

Amaranthus palmeri is the most prominent invasive weed in agricultural land from North America, partly due to its propensity to evolve resistance to multiple herbicide sites of action. In the last two decades, reports of this species have increased throughout the American continent and occasionally in other continents. In 2007, A. palmeri populations were found in three localities in northeastern Spain, and they are still present today. To determine whether these three populations resulted from a common or independent introduction events—and when and from where they could have occurred—research was carried out aiming to characterize the resistance profile and mechanisms to 5-enolpyruvylshikimate-3-phosphate synthase-and acetolactate synthase (ALS)-inhibiting herbicides and to analyze the relationship between these three populations using inter simple sequence repeat DNA fingerprinting. Dose–response trials confirmed that the three populations were susceptible to glyphosate but resistant to nicosulfuron-methyl. Resistance to ALS inhibitors was due to several amino acid substitutions in positions Pro197, Trp574 and Ser653. Moreover, the substitutions Ser653Ile and Pro197Thr are described for the first time in this species. At field-labeled rates, all populations were fully controlled with alternative herbicides with other sites of action. Amaranthus palmeri individuals were clustered in three groups based on unweighted pair group method with arithmetic mean analysis, which corresponded to the three sampled populations, with a 67% of genetic relationship among them. Considering this high genetic variability and the different positions and amino acid substations found between populations, it was hypothesized that different colonization events occurred from the American continent probably prior to the introduction of glyphosate resistant crops. Prevention from new introductions is warranted because new herbicide resistance traits could arrive, complicating the management of this invasive weed species, while managing or eradicating the already established populations. [ABSTRACT FROM AUTHOR]

Published

2020