Efecto alelopático de Capsicum chinense, Dianthus caryophyllusy Sorghum bicoloren semillas

• Alisa Clementina Barroso-Ake ^[1] ; Roberto Arredondo-Valdés ^[1] ; Leslie Carnero-Avilés ^[2] ; Anna Ilina ^[1] ; Rodolfo Ramos-González ^[1]
  1. [1] Universidad Autónoma de Coahuila

     Universidad Autónoma de Coahuila

     México

     
  2. [2] Instituto Nacional de Investigaciones Forestales, Agrícolas y Pecuarias
• Localización: Ecosistemas y Recursos Agropecuarios, ISSN-e 2007-901X, ISSN 2007-9028, Vol. 12, Nº. 1 (Enero-Abril 2025), 2025
• Idioma: español
• Títulos paralelos:
  • Allelopathic effect of Capsicum chinense, Dianthus caryophyllus, and Sorghum bicoloron seeds
• Enlaces
  • Texto completo (pdf)
• Resumen
  • español

    Las malezas representan una amenaza para la producción agrícola, causando pérdidas significativas en los cultivos. Los herbicidas químicos han sido ampliamente utilizados para su control, sin embargo, su empleo conlleva problemas ambientales y de resistencia que plantean desafíos importantes. Por lo que se ha buscado desarrollar alternativas más sostenibles, en el marco de la agricultura sustentable, los extractos vegetales ofrecen características prometedoras, como degradabilidad, bajo costo y efectividad.En este contexto, el presente trabajo tiene como objetivo desarrollar una alternativa basada en extractos vegetales de Capsicum chinenseL., Dianthus caryophyllusL. y Sorghum bicolorL. Se llevaron a cabo los análisis de identificación de compuestos antioxidantes (DPPH), cuantificación de fenoles totales, así como la determinación de compuestos volátiles mediante análisis HPLC/MS y GC-MS/MS. Además, se realizaron pruebas de inhibiciónde la germinación de semillas de Phaseolus vulgarisL. y Avena sativaL. utilizando los diferentes extractos evaluados. Los resultados revelaron la presencia de diversas familias de compuestos que contribuyen a la actividad alelopática de los extractos. Se observó inhibición de germinación en las semillas, lo que sugiere un potencial efecto herbicida pre-emergente de los tratamientos seleccionados. Los extractos vegetales analizados exhiben una amplia variedad de bioactivos y una actividad herbicida significativa. Por lo tanto, se postula su uso como una alternativa viable y sostenible para el control de la germinación de malezas en sistemas agrícolas, lo que podría contribuir a la promoción de prácticas agrícolas más respetuosas con el ambiente.

  • English

    Weedsrepresent a threat toagricultural production, causing significant losses in various crops. Chemically synthesized herbicides havebeen widely usedfor their control; however, their use entails environmental and resistance problems that poseimportant challenges. Aware of this problem, we have sought to develop more sustainable alternatives within the framework of sustainable agriculture. Plant extracts offer promising characteristics, such as their degradability,low cost, and effectiveness. In this context, the main objective of this work is to develop an alternative based on plant extracts from Capsicum chinenseL., Dianthus caryophyllusL., and Sorghum bicolorL. With HPLC/MS and GC-MS/MS analysis, we were able to find antioxidant compounds (DPPH), measure total phenols, and find volatile compounds. Additionally, we conducted germination inhibition tests on model seeds of Phaseolus vulgarisL. and Avena sativa L., utilizing the various extracts under evaluation. The results revealed the presence of various families of compounds, which contributed to the allelopathic activity of the extracts. The model seeds showed inhibition of germination, indicating a potential pre-emergence herbicidal effect of the selected treatments. The plant extracts analyzed exhibit a wide variety of bioactive and significant herbicidal activities. Therefore, we postulate its use as a viable and sustainable alternative for controlling weed germination in agricultural systems, potentially promoting more environmentally friendly agricultural practices.

• Referencias bibliográficas
  • Al-Snafi AE (2017) Chemical contents and medical importance of Dianthus caryophyllus- A review. IOSR Journal of Pharmacy 07(03): 61-71. https://doi.org/10.9790/3013-0703016171
  • Balbi V, Devoto A (2008) Jasmonate signalling network in Arabidopsis thaliana: Crucial regulatory nodes and new physiological scenarios. New...
  • Bastidas DA, Guerrero JA, Wyckhuys K (2013) Residuos de plaguicidas en cultivos de pasifloras en regiones de alta producción en Colombia....
  • Bo AB, Kim JD, Kim YS, Sin HT, Kim HJ, Khaitov B, Choi JS (2019) Isolation, identification and characterization of Streptomyces metabolites...
  • Castillo F, Hernández D, Gallegos G, Mendez M, Rodríguez R, Reyes A, Aguilar CN (2010) In vitro antifungal activity of plant extracts obtained...
  • Cerda-Cejudo ND, Buenrostro-Figueroa JJ, Sepúlveda L, Torres-Leon C, Chávez-González ML, Ascacio-Valdés JA, Aguilar CN (2022) Recovery of...
  • Cordeau S, Triolet M, Wayman S, Steinberg C, Guillemin JP (2016) Bioherbicides: Dead in the water? A review of the existing products for integrated...
  • Ding J, Liu J, Zhang Z, Guo J, Cheng M, Wan Y, Xie SS (2020). Design, synthesis and biological evaluation of coumarin-based N-hydroxycinnamamide...
  • De-Mastro G, El-Mahdi J, Ruta C (2021). Bioherbicidal potential of the essential oils from Mediterranean Lamiaceae for weed control in organic...
  • Dos Santos FE, Carvalho MSS, Silveira GL, Correa FF, Cardoso MDG, Andrade-Vieira LF, Vilela LR (2019) Phytotoxicity and cytogenotoxicity of...
  • Espinosa-García FJ, Villaseñor JL (2017) Biodiversity, distribution, ecology and management of non-native weeds in Mexico: A review. Revista...
  • Fisher AJ (2013) Resistencia a herbicidas: Mecanismos y mitigación. Revista Especial de Malezas 29: 13-19.
  • Fu Y, Zhang SQ, Liu YX, Wang JY, Gao S, Zhao LX, Ye F (2019) Design, synthesis, SAR and molecular docking of novel green niacin-triketone...
  • González XA, Ronquillo-Cedillo I, Ávila-Nájera DM, Rodríguez-Hernández C, Pedraza-Mandujano J, Martínez-Jiménez DL (2022) Riesgos a la salud...
  • Guevara-González J, Narváez-Flies C, Marín-Navarrete A, Gutiérrez-López J, Troncoso-Troncoso C (2019) Bioherbicida a partir de extracto fenólico...
  • Hoagland RE (2001) Microbial allelochemicals and pathogens as bioherbicidal agents. Weed Technology 15(4): 835-857. https://doi.org/10.1614/0890-037X(2001)015[0835:MAAPAB]2.0.CO;2
  • Islam AM, Kato-Noguchi H (2014) Phytotoxic activity of Ocimum tenuiflorum extracts on germination and seedling growth of different plant species....
  • Kothari SL, Joshi A, Kachhwaha S, Ochoa-Alejo N (2010) Chilli peppers a review on tissue culture and transgenesis. Biotechnology Advances...
  • Liu X, Tian F, Tian Y, Wu Y, Dong F, Xu J, Zheng Y (2016) Isolation and identification of potential allelochemicals from aerial parts of Avena...
  • Lo CM, Han J, Wong ES (2020) Chemistry in aromatherapy–extraction and analysis of essential oils from plants of Chamomilla recutita, Cymbopogon...
  • Loake G, Grant M (2007) Salicylic acid in plant defense the players and protagonists. Current Opinion in Plant Biology 10(5): 466-472. https://doi.org/10.1016/j.pbi.2007.08.008
  • Martínez-Ávila GC, Aguilera-Carbó AF, Rodríguez-Herrera R, Aguilar CN (2012) Fungal enhancement of the antioxidant properties of grape waste....
  • Montull JM, Torra J (2023) Herbicide resistance is increasing in Spain: Concomitant management and prevention. Plants 12(3): 469. https://doi.org/10.3390/plants12030469
  • Morra MJ, Popova IE, Boydston RA (2018) Bioherbicidal activity of Sinapis alba seed meal extracts. Industrial Crops and Products 115: 174-181....
  • Nazemi AH, Asadi GA, Ghorbani R (2018) Allelopathic potential of lavender’s Extract and coumarin applied as pre-plant incorporated into soil...
  • Nielsen SS (2003) Food analysis laboratory manual. 3 edición. Kluwer Academic/Plenum Publishers, New York, NY, USA. 557p.
  • Palau H, Senesi S, Mogni L, Ordoñez I (2015) Impacto económico macro y micro de malezas resistentes en el agro argentino. ADAMAFAUBA 43(1):...
  • Qiao L, Hao S (2018) Novel trifluoromethylcoumarinyl urea derivatives: Synthesis, characterization, fluorescence, and bioactivity. Molecules...
  • Ratnayaka HH, Molin WT, Sterling TM (2003) Physiological and antioxidant responses of cotton and spurred anoda under interference and mild...
  • Razavi SM (2011) Plant coumarins as allelopathic agents. International Journal of Biological Chemistry 5(1): 86-90.
  • Reyes-Escogido ML, Gonzalez-Mondragon EG, Vazquez-Tzompantzi E (2011) Chemical and pharmacological aspects of capsaicin. Molecules 16(2):...
  • Roberts J, Florentine S, Fernando WD, Tennakoon KU (2022) Achievements, developments and future challenges in the field of bioherbicides for...
  • Shajib MTI, Pedersen HA, Mortensen AG, Kudsk P, Fomsgaard IS (2012) Phytotoxic effect, uptake, and transformation of biochanin A in selected...
  • Sora GTS, Haminiuk CWI, da Silva MV, Zielinski AAF, Gonçalves GA, Bracht A, Peralta RM (2015) A comparative study of the capsaicinoid and...
  • Steel RG, Torrie JH (1981) Principles and procedures of statistics, a biometrical approach. McGraw-Hill Kogakusha, Ltd. Japan. 633p.
  • Tucuch-Pérez MA, Mendo-González EI, Ledezma-Pérez A, Iliná A, Hernández-Castillo FD, Barrera-Martinez CL, Arredondo-Valdés R (2023) The herbicidal...
  • Vlot AC, Dempsey DMA, Klessig DF (2009) Salicylic acid, a multifaceted hormone to combat disease. Annual Review of Phytopathology 47: 177-206....
  • Waliszewski SM, Szymczynski GA, Serafin Z, Infanzón RM, Siliceo J (2002) Ésteres de ftalatos-factor orquidotóxico. Revista Internacional de...
  • Zenil-Lugo N, Colinas-León MT, Bautista-Bañuelos C, Vázquez-Rojas TR, Lozoya-Saldaña H, Martínez-Damián MT (2014) Fenoles totales y capacidad...