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W3199595295 abstract "Cover crops and mulches have become an alternative for soil management in vineyards due to the agronomic, environmental, and economic advantages, especially the possibility of weed control. Implicitly to this objective lies the idea of assessing the potential herbicide effect of the allelochemicals released by different cover crops and mulch species. With this objective, the present work evaluated the phytotoxic effects of 12 aqueous extracts of selected species with potential use as a cover crop or mulch: a Bromus species mixture (B. hordeaceus L. and B. rubens L.), Festuca arundinacea Schreb., Hordeum murinum L., H. vulgare L., Vulpia ciliata Dumort., Medicago rugosa Desr., M. sativa L., Trifolium subterraneum L., T. incarnatum L., Phacelia tanacetifolia Benth., Sinapis alba L., and Pinus sylvestris L., on the germination and early growth of three troublesome weeds (Conyza bonariensis (L.) Cronquist, Aster squamatus (Spreng.) Hieron, and Bassia scoparia (L.) A. J.). The different in vitro bioassays showed that aqueous extracts of some species significantly inhibited or reduced germination and root and shoot growth of the target weed species in a dose-response manner. Germination of A. squamatus and C. bonariensis was reduced by 100-80% by the different extracts applied at 50% concentration and completely blocked at 100% concentration, except for M. rugosa extract, to which both species showed less sensitivity. Root elongation of A. squamatus was inhibited under every extract and concentration, whereas C. bonariensis root growth showed only some tolerance to the crude extracts of F. arundinacea and P. sylvestris. Bassia scoparia was relatively tolerant to the aqueous plant extracts, except for T. subterraneum crude extract, which reduced total germination by 80%; otherwise, B. scoparia showed higher general sensitivity of shoot growth than the other two weed species. The chemical profiles of phenolic compounds of the aqueous extracts were obtained and identified by HPLC-DAD, the phenolic profiles of H. murinum, V. ciliata, and M. rugosa being reported in this work for the first time. Using stepwise regression, the influence of certain phenolic compounds from the aqueous extracts on the germination and early growth of weeds was predicted. Among other significant compounds, the flavonoid naringenin identified in T. subterraneum aqueous extract at 8.09 μg·mL–1 was predicted to underlie its specific phytotoxicity on B. scoparia germination. These results support the use of cover crops and mulches in weed management and can help to select the most suitable species to adopt according to the target weed species. Highlights- The phytotoxic nature of the aqueous extracts of twelve conventional and novel cover crops and mulch species was demonstrated in vineyards’ three troublesome weed species. - Phenolic acids and flavonoids of the twelve aqueous extracts were identified and quantified by HPLC-DAD, and, by regression analysis, some allelochemicals were postulated as responsible for the phytotoxic effects. - The water-soluble phenolic profiles of three potential cover crops, namely Hordeum murinum, Vulpia ciliata, and Medicago rugosa, are reported for the first time. - In vitro germination and early root growth of Conyza bonariensis and Aster squamatus were almost entirely restricted by any of the twelve plants’ aqueous extracts and presumably by the joint action of their particular allelopathic compounds. - Bassia scoparia germination was relatively much less sensitive to the extracts, except for Trifolium subterraneum, for which the flavonoid naringenin was predicted to underlie its specific phytotoxicity." @default.
W3199595295 created "2021-09-27" @default.
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W3199595295 creator A5078339107 @default.
W3199595295 date "2021-09-13" @default.
W3199595295 modified "2023-10-16" @default.
W3199595295 title "Predictive phytotoxic value of water-soluble allelochemicals in plant extracts for choosing a cover crop or mulch for specific weed control" @default.
W3199595295 cites W138200024 @default.
W3199595295 cites W1520777070 @default.
W3199595295 cites W1556454050 @default.
W3199595295 cites W160231869 @default.
W3199595295 cites W1752127576 @default.
W3199595295 cites W1822839629 @default.
W3199595295 cites W1925640196 @default.
W3199595295 cites W1969100508 @default.
W3199595295 cites W1971670601 @default.
W3199595295 cites W1985400568 @default.
W3199595295 cites W1985715974 @default.
W3199595295 cites W1987512688 @default.
W3199595295 cites W1989190156 @default.
W3199595295 cites W1993593427 @default.
W3199595295 cites W1996426333 @default.
W3199595295 cites W2013577856 @default.
W3199595295 cites W2018334144 @default.
W3199595295 cites W2020144634 @default.
W3199595295 cites W2021155162 @default.
W3199595295 cites W2025306064 @default.
W3199595295 cites W2030224824 @default.
W3199595295 cites W2035759078 @default.
W3199595295 cites W2038930717 @default.
W3199595295 cites W2042191025 @default.
W3199595295 cites W2042521185 @default.
W3199595295 cites W2045559194 @default.
W3199595295 cites W2050099332 @default.
W3199595295 cites W2061060260 @default.
W3199595295 cites W2063168365 @default.
W3199595295 cites W2064575506 @default.
W3199595295 cites W2065657447 @default.
W3199595295 cites W2075666754 @default.
W3199595295 cites W2084367132 @default.
W3199595295 cites W2093552524 @default.
W3199595295 cites W2097975533 @default.
W3199595295 cites W2104725167 @default.
W3199595295 cites W2110319189 @default.
W3199595295 cites W2114185006 @default.
W3199595295 cites W2117491464 @default.
W3199595295 cites W2164800387 @default.
W3199595295 cites W2168491855 @default.
W3199595295 cites W2277439455 @default.
W3199595295 cites W2313473084 @default.
W3199595295 cites W2410667349 @default.
W3199595295 cites W2428527978 @default.
W3199595295 cites W2493075868 @default.
W3199595295 cites W2528865760 @default.
W3199595295 cites W2543685669 @default.
W3199595295 cites W2746502071 @default.
W3199595295 cites W2762576521 @default.
W3199595295 cites W2763234966 @default.
W3199595295 cites W2786447064 @default.
W3199595295 cites W2808131895 @default.
W3199595295 cites W2886211288 @default.
W3199595295 cites W2886855549 @default.
W3199595295 cites W2897197166 @default.
W3199595295 cites W2910625816 @default.
W3199595295 cites W2913586504 @default.
W3199595295 cites W2927727306 @default.
W3199595295 cites W2948158164 @default.
W3199595295 cites W2953200376 @default.
W3199595295 cites W3005780337 @default.
W3199595295 cites W3022400724 @default.
W3199595295 cites W3028038251 @default.
W3199595295 cites W3034552197 @default.
W3199595295 cites W3046497583 @default.
W3199595295 cites W3048856357 @default.
W3199595295 cites W3095030055 @default.
W3199595295 cites W3096625454 @default.
W3199595295 cites W3097482024 @default.
W3199595295 cites W3111253717 @default.
W3199595295 cites W3156047661 @default.
W3199595295 cites W32288979 @default.
W3199595295 cites W49099830 @default.
W3199595295 doi "https://doi.org/10.4081/ija.2021.1872" @default.
W3199595295 hasPublicationYear "2021" @default.
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