Page 76 - ACCB 2020
P. 76

Revista de la Asociación Colombiana de Ciencias Biológicas
            issn impreso 0120-4173, issn en línea 2500-7459



                    111. Davies  Jr.,  F.T.,  Olalde-Portugal,  V.,  Aguilera-Gomez,  L.,  Alvarado,  M.J.,  Ferrera-Cerrato,  R.C.,
                       Boutton, T.W. (2002).   Alleviation of drought stress of chile ancho pepper (Capsicum annum L. cv.
                       San Luis) with arbuscular mycorrhiza indigenous to Mexico. Sci Hortic, 92, 347-359.
                    112. Yooyongwech, S., Samphumphuang, T., Tisarum, R., Theerawitaya, C., Chaum, S. (2016). Arbuscular
                       mycorrhizal fungi (AMF) improved water defi cit tolerance in two different sweet potato genotypes
                       involves osmotic adjustments via soluble sugar and free proline. Sci Hort, 198, 107–117.
                    113. Moradtalab, N., Roghieh, H., Nasser, A., Tobias, E. H., Günter, N. (2019). Silicon and the association
                       with an arbuscular-mycorrhizal fungus (Rhizophagusclarus) mitigate the adverse effects of drought
                       stress on strawberry. Agronomy, 9, 41.
                    114. Boutasknit, A., Baslam, M., Ait-El-Mokhtar, M., Anli, M., Ben-Laouane, R., Douira, A. et al (2020).
                       Arbuscular  Mycorrhizal  Fungi  Mediate  Drought Tolerance  and  Recovery  in Two  Contrasting  Ca-
                       rob (Ceratonia siliqua L.) Ecotypes by Regulating Stomatal, Water Relations, and (In)Organic Ad-
                       justments. Plants, 9, 80.
                    115. Hu, D., Baskin, J.M., Baskin, C.C., Wang, Z., Zhang, S., Yang, X. et al (2019). Arbuscular mycorrhizal
                       symbiosis and achene mucilage have independent functions in seedling growth of a desert shrub. J
                       Plant Physiol, 232, 1-11.
                    116. Auge, R.M. (2011).  Water relations, drought and vesicular-arbuscular mycorrhizal symbiosis. Myco-
                       rrhiza, 11, 3-42.
                    117. Mena-Violante, H.G., Ocampo-Jimenez, O., Dendooven, L., Martinez-Soto, G., Gonzalez-Castaneda,
                       J., Davies, F.T. Jr., Olalde-Portugal, V. (2006). Arbuscular-mycorrhizal fungi enhance fruit growth and
                       quality of Chile ancho (Capsicum annum L.cv. San Luis) plants exposed to drought. Mycorrhiza, 16,
                       261-267.
                    118. Amiri, R., Ali, N., Nematollah, E., Mohammad, R. S. (2017). Nutritional status, essential oil changes
                       and water-use effi ciency of rose geranium in response to arbuscular mycorrhizal fungi and water defi -
                       ciency stress. Symbiosis, 73, 15–25.
                    119. Bowles, T.M., Jackson, L.E., Cavagnaro, T.R. (2018).  Mycorrhizal fungi enhance plant nutrient acqui-
                       sition and modulate nitrogen loss with variable water regimes. Glob Chang Biol, 24, 171-182.
                    120. Burrows, R.L. and Ahmed, I. (2007). Fungicide seed treatments minimally affect arbuscular- mycorr-
                       hizal fungal (AMF) colonization of selected vegetable crops. J Biol Sci, 7, 417-420.
                    121. Channabasava, A., Lakshman, H.C., Jorquera, M.A. (2015).  Effect of fungicides on association of ar-
                       buscular mycorrhiza fungus Rhizophagusfasciculatus and growth of Proso millet (Panicum miliaceum
                       L.). J Soil Sci Plant Nutr, 15, 35-45.
                    122. Jin, H., Germida, J.J., Walley, F.L. (2013).  Suppressive effects of seed-applied fungicides on arbus-
                       cular mycorrhizal fungi (AMF) differ with fungicide mode of action and AMF species. Applied Soil
                       Ecol, 72, 22-30.





























            76
                                                                                  Rev. Asoc. Col. Cienc.(Col.), 2020; 32: 63-76
   71   72   73   74   75   76   77   78   79   80   81