An Overview of Rice Cultivation in Spain and the Management of Herbicide-Resistant Weeds

July 12, 2021

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Publicated to:Agronomy-Basel. 11 (6): 1095- - 2021-01-01 11(6), DOI: 10.3390/agronomy11061095

Authors: Gomez de Barreda, Diego; Pardo, Gabriel; Osca, Jose Maria; Catala-Forner, Mar; Consola, Silvia; Garnica, Irache; Lopez-Martinez, Nuria; Palmerin, Jose Antonio; Osuna, Maria Dolores;

Affiliations

Cultius Extensius Sostenibles. Producció Vegetal - Author

Extremadura Sci & Technol Res Ctr CICYTEX, Ctra AV,Km 372, Badajoz 06187, Guadajira, Spain - Author

Govt Extremadura, Plant Hlth Serv, Km 2,5, Badajoz 06400, Spain - Author

Inst Agrifood Res & Technol IRTA, Estacio Expt Ebre, Km 1, Amposta 43870, Spain - Author

Inst Agrifood Technol & Infrastruct Navarra INTIA, Edificio Peritos,Avda Serapio Huici 22, Navarra 31610, Villava, Spain - Author

Plant Hlth Serv DARP, Generalitat Catalunya, Ctra Valencia 108, Roquetes 43520, Spain - Author

Univ Politecn Valencia, Plant Protect Dept, Camino Vera S-N, Valencia 46022, Spain - Author

Univ Seville, High Tech Sch Agron Engn ETSIA, Agron Dept, Seville 41013, Spain - Author

Univ Zaragoza, Agrifood Res & Technol Ctr Aragon CITA, AgriFood Inst Aragon IA2, CITA,Plant Protect Dept, Ave Montanana 930, Zaragoza 50059, Spain - Author

Abstract

Spain is the second highest rice-producing country in the European Union, with approximately 105,000 ha used to grow this crop. The major rice-producing regions in Spain are Andalusia, Extremadura, Catalonia, and Valencia, followed by Aragon and Navarre. The main soil texture throughout Spanish rice areas is silty clay loam, with alkaline soils (pH > 7.5)-except in the Extremadura area (pH = 5.5-6)-and a low organic matter content. Water quality in terms of salinity is acceptable, although in some coastal rice areas salinity issues occasionally appear to be a determining factor for high yield achievement. According to a survey carried out on farmers and technicians, the most problematic weeds found in rice crops today in Spain are Echinochloa spp., Leptochloa spp., and Cyperus difformis. Most of the currently authorized herbicides can be classified according to two modes of action: ALS-inhibiting and ACCase-inhibiting. Repeated field applications of herbicides with the same mode of action have resulted in the selection of herbicide-resistant weeds. At present, resistance has been confirmed in different regions of Spain to ALS inhibitors in Echinochloa spp., Leptochloa spp., and Cyperus difformis, and to ACCase inhibitors in Echinochloa spp. and Leptochloa spp. The mechanism of resistance in these species is a mutation in the target site of these herbicides. Several mutations have been found in the ALS gene, both in Echinochloa spp. and Cyperus difformis, distributed in the different rice-growing regions considered in this work. ACCase gene mutations have been mainly found in Leptochloa spp. individuals from Extremadura and Valencia. These different mutations have resulted in different patterns of cross-resistance to ALS- and ACCase-inhibiting herbicides. It is likely that the repeated use of these two modes of action in rice will result in the evolution of more resistant weed populations. The possible availability of new herbicides with alternative modes of action in a short space of time seems very limited, suggesting the need for a more appropriate use of the available alternative strategies (crop rotation, dry sowing, manual weeding, etc.). This work presents a review of the main characteristics of rice cultivation in Spain, emphasizing the current problems in this crop and the management of herbicide-resistant weeds.

Keywords

Als inhibitorsBarnyard grassCrop protectionCross-resistanceDirect-seeded riceEchinochloa-crus-galliHerbicideInhibiting herbicidesL.PenoxsulamPhotosynthesisRiceSpp.Target-site resistanceWeed managementWeed science

Quality index

Bibliometric impact. Analysis of the contribution and dissemination channel

The work has been published in the journal Agronomy-Basel due to its progression and the good impact it has achieved in recent years, according to the agency WoS (JCR), it has become a reference in its field. In the year of publication of the work, 2021, it was in position 18/90, thus managing to position itself as a Q1 (Primer Cuartil), in the category Agronomy.

From a relative perspective, and based on the normalized impact indicator calculated from World Citations provided by WoS (ESI, Clarivate), it yields a value for the citation normalization relative to the expected citation rate of: 1.44. This indicates that, compared to works in the same discipline and in the same year of publication, it ranks as a work cited above average. (source consulted: ESI Nov 14, 2024)

This information is reinforced by other indicators of the same type, which, although dynamic over time and dependent on the set of average global citations at the time of their calculation, consistently position the work at some point among the top 50% most cited in its field:

Weighted Average of Normalized Impact by the Scopus agency: 2.32 (source consulted: FECYT Feb 2024)
Field Citation Ratio (FCR) from Dimensions: 7.03 (source consulted: Dimensions Jul 2025)

Specifically, and according to different indexing agencies, this work has accumulated citations as of 2025-07-05, the following number of citations:

WoS: 16
Scopus: 29

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