Page 75 - ACCB 2020
P. 75

Arbuscular Mycorrhizae Fungi: A Tool For Sustainable Agriculture. Varaprasad Kolla  et al




                       reaction and direct isolations on selective media. Phytopathology. 93, 229-235.
                   90.  Graham, J.H. (1982).  Effect of citrus root exudates on germination of chlamydospores of vesicular-
                       arbuscular mycorrhizal fungus Glomus epigaeum. Mycologia, 74, 831-835.
                   91.  Sharma, M.P., Gaur, A., Mukerji, K.G. (2007).  Arbuscular mycorrhiza mediated plant pathogen inte-
                       ractions and the mechanisms involved in: Biological control of plant diseases, Sharma, M.P., Gaur A.,
                       and Mukerji K.G. (Eds.). Haworth Press, Binghamton, USA., pp 47-63.
                   92.  Heinemeyer, A. and Fitter, A.H. (2004).  Impact of temperature on the arbuscular mycorrhizal (AM)
                       symbiosis: growth response of the host plant & its AM fungal partner. J Exp Bot, 55, 525-534.
                   93.  Furlan, V. and Fortin, J.A. (1973).  Formation of endomycorrhizae by Endogonecalospora on Allium
                       cepa under three temperature regimes. Nat Can, 100, 467-477.
                   94.  Graham, J.H., Leonard, R.T., Menge, J.A. (1982).  Interaction of light and soil temperature with phos-
                       phorus inhibition of vesicular-arbuscular mycorrhiza formation. New Phytol, 91, 683-690.
                   95.  Fitter, A.H., Heinemeyer, A., Staddon, P.L. (2000).  The impact of elevated CO2& global climate chan-
                       ge on arbuscular mycorrhizas: a mycocentric approach. New Phytol, 147, 179-187.
                   96.  Auge, R.M., Toler, H.D., Saxton, A.M. (2015).  Arbuscular mycorrhizal symbiosis alters stomatal
                       conductance of host plants more under drought than under amply watered conditions: meta-analysis.
                       Mycorrhiza,  25, 13-24.
                   97.  Addy, H.D., Schaffer, G. F., Miller, M. H., Peterson, R. L. (1994). Survival of the external mycelium
                       of a VAM fungus in frozen soil over winter. Mycorrhiza, 5, 1-5.
                   98.  Mohan, J.E., Cowden, C.C., Baas, P., Dawadi, A., Frankson, P.T., Helmick, K. et al (2014).  Mycorr-
                       hizal fungi mediation of terrestrial ecosystem responses to global change: mini-review. Fungal Ecol,
                       10, 3-19.
                   99.  Hawkes, C.V., Hartley, I.P., Ineson P., Fitter, A.H. (2008).  Soil temperature affects carbon allocation
                       within arbuscular mycorrhizal networks and carbon transport from plant to fungus. Glob Change Biol,
                       14, 1181-1190.
                   100. Heinemeyer, A., Ineson, P., Ostle, N., Fitter, A.H. (2006).   Respiration of the external mycelium in the
                       arbuscular mycorrhizal symbiosis shows strong dependence on recent photosynthates and acclimation
                       to temperature. New Phytol, 171, 159-170.
                   101. Ahmad, A., Bashir, Z., Akram, W. (2011). Effect of sunlight on the mycorrhizal associations in rhizo-
                       matic plant Colocasia esculenta L. Mycopath, 9, 57-60.
                   102. Rodriguez, A. and Sanders, I.R. (2015).  The role of community and population ecology in applying
                       mycorrhizal fungi for improved food security. ISME J, 9, 1053-1061.
                   103. Azul, A.M., Nunes, J., Ferreira, I., Coelho, A. S., Verissiomo, P., Trovao, J. (2014).Valuing native ec-
                       tomycorrhizal fungi as a Mediterranean forestry component for sustainable and innovative solutions1.
                       Botany, 92, 161-171.
                   104. Poorter, H. and Navas, M.L. (2003).  Plant growth and competition at elevated CO2 on winners, losers
                       and functional groups. New Phytol, 157, 175-198.
                   105. Monz, C.A., Kunt, H.W., Reeves, F.B., Elliot, E.T. (1994).  The response of mycorrhizal colonization
                       to elevated CO2 & climate change in Pascopyrumsmithii and Boutelouagracilis. Plant Soil, 165, 75-
                       80.
                   106. Tang, J., Xu, L., Chen, X., Hu, S. (2009).   Interaction between C4 barnyard grass and C3 upland rice
                       under elevated CO2: impact of mycorrhizae. Acta Oecologia, 35, 227-235.
                   107. Rilling, M.C. and Allen, M.F. (1999).  What is the role of arbuscular mycorrhizal fungi in plant-to-
                       ecosystem responses to elevated atmospheric CO ? Mycorrhiza, 9,1-8.
                                                              2
                   108. Sanders, I.R., Streitwolf-Engel, R., Vander Heijden, M.G.A., Boller, T., Wiemken, A. (1998). Increased
                       allocation to external hyphae of arbuscular mycorrhizal fungi under CO  enrichment. Oecologia, 117,
                                                                                2
                       496-503.
                   109. Baslam, M., Antolin, M.C., Gogorcena, Y., Munoz, F., Goicoechea, N. (2014). Changes in alfalfa fo-
                       rage quality & stem carbohydrates induced by arbuscular mycorrhizal fungi and elevated atmospheric
                       CO .  Ann Appl Biol, 164, 190-199.
                         2
                   110. Todeschini, V., Aitlahmidi, N., Mazzucco, E., Marsano, F., Gosetti, F., Robotti, E. et al (2018). Impact
                       of benefi cial microorganisms on Strawberry growth, fruit production, nutritional quality and volatilo-
                       me. Front Plant Sci, 9, 1611.



                                                                                                             75
            Rev. Asoc. Col. Cienc.(Col.), 2020; 32: 63-76.
   70   71   72   73   74   75   76   77   78   79   80