Acioli–Santos, B., Vieira, H.E.E., Lima, C.E.P. & Maia, L.C. 2011. The Molecular Ectomycorrhizal Fungus Essence in Association: A Review of Differentially Expressed Fungal Genes During Symbiosis Formation. In: Rai, M. & Varma, A. (Editors). Diversity and Biotechnology of Ectomycorrhizae. Vol 25, Soil Biology, Springer, Berlin, 87–121.
Agerer, R. 1987–2012. Colour atlas of ectomycorrhizae. 1st–15th delivery, Einhorn, Schwäbisch Gmünd.
Ahmed, I.M., Cao, F., Han, Y., Nadira, U.A., Zhang, G. & Wu, F. 2013. Differential changes in grain ultra structure, amylase, protein and amino acid profiles between Tibetan wild and cultivated barleys under drought and salinity alone and combined stress. Food Chemistry, 141: 2743–2750.
Allan, C.D., Macalady, A.K., Chenchouni, H., Bachelet, D., McDowell, N., Vennetier, M., Kizberger, T., Rigling, A., Breshears, D.D., Hogg, E.H., Gonzalez, P., Fensham, R., Zhang, Z., Castro, J., Demidova, N., Lim, J.H., Allard, G., Running, S.W., Semerci, A., & Cobb, N. 2010. A global overview of drought and heat–induced tree mortality reveals emerging climate change risks for forests. Forest Ecology and Management, 259:660–684.
Alvarez, M., Huygens, D., Fernandez, C., Gacitua, Y., Olivares, E., Saavedra, I., Alberdi, M. & Valenzuela, E. 2009a. Effect of ectomycorrhizal colonization and drought on reactive oxygen species metabolism of Nothofagus dombeyi roots. Tree Physiology, 29:1047–1057.
Alvarez, M., Huygens, D., Olivares, E., Saavedra, I., Alberdi, M. & Valenzuela, E. 2009b. Ectomycorrhizal fungi enhance nitrogen and phosphorus nutrition of Nothofagus dombeyi under drought conditions by regulating assimilative enzyme activities. Physiologia Plantarum,136: 426–436.
Asadi, F., Mirzaei–Nadushan, H., Modirrahmati, E. & Naderi–shaahab, M.E. 2005. Identification of poplar clones using morphological markers. Iranian Journal of Forest and Poplar Research, 12: 267–300.
Augé, R.M, & Moore, J.L. 2005. Arbuscular mycorrhizal symbiosis and plant drought resistance. In: Mehrotra, VS (Editor) Mycorrhiza: Role and Applications. Allied Publishers Limited, New Dehli.
Azevedo, R.A., Arruda, P., Turner, W.L. & Lea, P.J. 1997. The biosynthesis and metabolism of the aspartate derived amino acids in higher plants. Phytochemistry, 46(3):395–419.
Azevedo, R.A., Lancien, M. & Lea, P.J. 2006. The aspartic acid metabolic pathway, an exciting and essential pathway in plants. Amino Acids, 30: 143–62.
Barrs, H.D., & Weatherley, P.E. 1962. A re–examination of the relative turgidity technique for estimating water deficits in leaves. Australian Journal of Biological Sciences, 15:413–428.
Bestel–Corre, G., Dumas–Gaudot, E.·& Gianinazzi, S. 2004. Proteomics as a tool to monitor plant–microbe endosymbioses in the rhizosphere. Mycorrhiza, 14:1–10.
Blaudez, D., Botton, B., Dizengremel, P. & Chalot, M. 2001. The fate of [14C] glutamate and [14C] malate in birch roots is strongly modified under inoculation with Paxillus involutus. Plant, Cell and Environment, 24:449–457.
Blaudez, D., Chalot, M., Dizengremel, P. & Botton, B. 1998. Structure and function of the ectomycorrhizal association between Paxillus involutus and Betula pendula. II. Metabolic changes during mycorrhiza formation. New Phytologist, 138: 543–552.
Breda, N., Huc, R., Granier, A. & Dreyer, E. 2006. Temperate forest trees and stands under severe drought: a review of ecophysiological responses, adaptation processes and long–term consequences. Annals of Forest Science, 63: 625–644.
Chalot, M., Blaudez, D. & Brun, A. 2006. Ammonia: a candidate for nitrogen transfer at the mycorrhizal interface. Trends in Plant Science, 11: 263–266.
Ciais, P.H., Reichstein, M., Viovy, N., Granier, A., Allard, V., et al. 2005. Europe–wide reduction in primary productivity caused by the heat and drought in 2003. Nature, 437: 529–533.
Cicatelli, A., Ferrol, N., Rozpadek, P. & Castiglione, S. 2019. Editorial: Effects of Plant–Microbiome Interactions on Phyto– and Bio–Remediation Capacity. Frontiers in Plant Science, 10: 533.
Correa, A. & Martins–Loucao, M.A. 2011. C:N Interactions and the cost:benefit balance in ectomycorrhizae: 387–403. In: Rai, M. & Varma, A. (Editors). Diversity and Biotechnology of Ectomycorrhizae, Soil Biology. Springer–Verlag, Berlin, Heidelberg.
Cortleven, A., Leuendorf, J.E., Frank, M., Pezzetta, D., Bolt, S. & Schmulling, T. 2019. Cytokinin action in response to abiotic and biotic stresses in plants. Plant, Cell and Environment, 42: 998–1018.
Dominguez Nunez, J.A., Gonzalez, R.P., Rodriguez Barreal, J.A. & de Omenaca Gonzalez, J.A.S. 2008. The effect of Tuber melanosporum Vitt. mycorrhization on growth, nutrition, and water relations of Quercus petraea Liebl., Quercus faginea Lamk., and Pinus halepensis Mill. seedlings. New Forests, 35(2): 159–171.
Drossopoulos, J.B., Karamanos, A.J. & Niavis, C.A. 1985. Changes in free amino compounds during the development of two wheat cultivars subjected to different degrees of water stress. Annals of Botany, 56: 291–305.
Duponnois, R. & Garbaye, J. 1991. Techniques for controlled synthesis of Douglas–fir – Laccaria laccata ectomycorrhizal symbiosis. Annals of Forest Science, 48: 641–650.
Finlay, R.D. & Soderstrom, B. 1992. Mycorrhiza and carbon flow to the soil. In: Allen, M.F. (Editor). Mycorrhizal Functioning. New York, Chapmaan & Hall. 134–160.
Galston, A.W. & Kaur–Sawhney, R. 1990. Polyamines in plant physiology. Plant Physiology, 94: 406–410.
Good, A.G. & Zaplachinski, S.T. 1994. The effects of drought stress on free amino acid accumulation and protein synthesis in Brassica napus. Physiologia Plantarum, 90: 9–14.
Guescini, M., Pierleoni, R., Palma, F., Zeppa, S., Vallorani, L., Potenza, L., Sacconi, C., Giomaro, G. & Stocchi, V. 2003. Characterization of the Tuber borchii nitrate reductase gene and its role in ectomycorrhizae. Molecular Genetics and Genomics, 269(6): 807–16.
Henriques, A.B., Cambraia, J., Pacheco, S. & Muchovej, R.M.C. 1992. Nitrogen partitioning in Pinus caribaea var. hondurensis colonized with Pisolithus tinctorius. Revista Brasileira de Fisiologia Vegetal, 4(2): 91–94.
Hirayama, T. & Shinozaki, K. 2010. Research on plant abiotic stress responses in the post–genome era: past, present and future. Plant Journal, 61: 1041–1052.
Hogg, E.H., Brandt, J.P. & Michaelian, M. 2008. Impacts of a regional drought on the productivity, dieback and biomass of western Canadian aspen forests. Canadian Journal of Forest Research, 38: 1373–1384.
Juvany, M., Müller, M. & Munné–Bosch, S. 2013. Photo–oxidative stress in emerging and senescing leaves: a mirror image? Journal of Experimental Botany, 64, 3087–3098.
Kudoyarova, G., Veselova, S., Hartung, W., et al. 2011. Involvement of root ABA and hydraulic conductivity in the control of water relations in wheat plants exposed to increased evaporative demand. Planta, 233(1):87–94.
Lambilliotte, R., Cooke, R., Samson, D., Fizames, C., Gaymard, F., Plassard, C., Tatry, M.V., Berger, C., Laudie, M., Legeai, F., Karsenty, E., Delseny, M., Zimmermann, S. & Sentenac, H. 2004. Large–scale identification of genes in the fungus Hebeloma cylindrosporumpaves the way to molecular analyses of ectomycorrhizal symbiosis. New Phytologist, 164: 505–513.
Landhausser, S.M., Muhsin, T.M., & Zwiazek, J.J. 2002. The effect of ectomycorrhizae on water relations in aspen (Populus tremuloides) and white spruce (Picea glauca) at low soil temperatures. Canadian Journal of Botany, 80: 684–689.
Lehto, T. & Zwiazek, J.J. 2011. Ectomycorrhizas and water relations of trees: a review. Mycorrhiza, 2: 71–90.
Luo, Z.B., Janz, D., Jiang, X., Gobel, C., Wildhagen, H., Tan, Y., Rennenberg, H., Feussner, I. & Polle, A. 2009a. Upgrading Root Physiology for Stress Tolerance by Ectomycorrhizas: Insights from Metabolite and Transcriptional Profiling into Reprogramming for Stress Anticipation. Plant Physiology, 151(4): 1902–1917.
Luo, Z.B., Li, K., Jiang, X. & Polle, A. 2009b. The ectomycorrhizal fungus (Paxillus involutus) and hydrogels affect drought tolerance of Populus euphratica. Annals of Forest Science, 66: 106.
Maksup, S, Roytrakul, S & Supaibulwatana, K. 2014. Physiological and comparative proteomic analyses of Thai jasmine rice and two check cultivars in response to drought stress. Journal of Plant Interactions, 9: 43–55.
Marvi Mohajer, M. 2005. Silviculture. Tehran University Presss, Tehran, 387 p.
Marx, D.H. & Bryan, W.C. 1975. Growth and ectomycorrhizal development of loblolly pine seedlings in fumigated soil infested with the fungal symbiont Pisolithus tinctorius. Forest Science, 21: 245–254.
Masclaux–Daubresse, C., Daniel–Vedele, F., Dechorgnat, J., Chardon, F., Gaufichon, L. & Suzuki, A. 2010. Nitrogen uptake, assimilation and remobilization in plants: challenges for sustainable and productive agriculture. Annals of Botany, 105: 1141–1157.
Matsubara, Y.I., Ishigaki, T. & Koshikawa, K. 2009. Changes in free amino acid concentrations in mycorrhizal strawberry plants. Scientia Horticulturae, 119(4):392–396.
Minamisawa, K., Arima, Y. & Kumazawa, K. 1983. Transport of fixed nitrogen from soybean nodules inoculated with Rhizobium japonicum strains. Soil Science and Plant Nutrition, 29(1): 85–92.
Morel, M., Jacob, C., Kohler, A., Johansson, T., Martin, F., Chalot, M. & Brun, A. 2005. Identification of genes differentially expressed in extraradical mycelium and ectomycorrhizal roots during Paxillus involutus–Betula pendula ectomycorrhizal symbiosis. Applied and Environmental Microbiology, 71: 382–391.
Murashige, T. & Skoog, F. 1962. A revised medium for rapid growth and bioassays with tobaco tissue culture. Physiology of Plants, 15: 437–442.
Nehls, U., Gohringer, F., Wittulsky, S. & Dietz, S. 2010. Fungal carbohydrate support in the ectomycorrhizal symbiosis: a review. Plant Biology, 12: 292–301.
Obata, T., Witt, S., Lisec, J., Palacios–Rojas, N., Florez–Sarasa I., Yousfi, S., Araus, J.L., Cairns, J.E., Fernie, A.R. 2015. Metabolite profiles of maize leaves in drought, heat, and combined stress field trials reveal the relationship between metabolism and grain yield. Plant Physiology, 169: 2665–2683.
Osuagwu, G.G.E.‚ Edeoga, H.O. & Osuagwu, A.N. 2010. The influence of water stress (drought) on the mineral and vitamin potential of the leaves Ocimum gratissimum L. Recent Research in Science and Technology, 2: 27–33.
Pinheiro, C. & Chaves, M.M. 2011. Photosynthesis and Drought: Can We Make Metabolic Connections from Available Data? Journal of Experimental Botany, 62: 869–882.
Qu, L., Quoreshi, A.M., Iwase, K., Tamai, Y., Funada, R. & Koike, T. 2003. In vitro ectomycorrhiza formation on two larch species of seedling with six different fungal species. Eurasian Journal of Forest Research, 6(1): 65–73.
Quoreshi, A.M. & Khasa, D.P. 2008. Effectiveness of mycorrhizal inoculation in the nursery on root colonization, growth, and nutrient uptake of aspen and balsam poplar. Biomass Bioenergy, 32: 381–391.
Rampino, P., Pataleo, S., Gerardi, C., Mita, G., & Perrotta, C. 2006. Drought stress response in wheat: Physiological and molecular analysis of resistant and sensitive genotypes. Plant Cell Environ, 29(12): 2143–52.
Rennenberg, H., Loreto, F., Polle, A., Brilli, F., Fares, S., Beniwal, R.S. & Gessler, A. 2006. Physiological responses of forest trees to heat and drought. Plant Biology, 8: 556–571.
Rincon, A., Priha, O., Lelu–Walter, M.A., Bonnet, M., Sotta, B. & Tacon, F.L. 2005. Shoot water status and ABA responses of transgenic hybrid larch Larix kaempferi x L. decidua to ectomycorrhizal fungi and osmotic stress. Tree Physiology, 25: 1101–1108.
Sannigrahi, P., Ragauskas, A.J., & Tuskan, G.A. 2010. Poplar as a feedstock for biofuels: a review of compositional characteristics. Biofuels, Bioproducts and Biorefining, 4: 209–226.
Showler, A.T., Cavazos, J.O. & Moran, P.J., 2007. Dynamics of free amino acid accumulations in cotton leaves measured on different timelines after irrigation. Subtropical Plant Science, 59: 38–55.
Sixto, H., Aranda, I. & Grau, J.M., 2006. Assessment of salt tolerance in Populus alba clones using chlorophyll fluorescence. Photosynthetica, 44: 169–173.
Skokut, T.A., Varner, J.E., Schaefer, J., Stejskal, E.O. & McKay, R.A. 1982. [N]NMR determination of asparagine and glutamine nitrogen utilization for synthesis of storage protein in developing cotyledons of soybean in culture. Plant Physiology, 69(2): 308–13.
Smith, S.E. & Read, D.J. 2008. Mycorrhizal Symbiosis, third ed. Academic Press, San Diego, CA.
Szuba, A. 2015. Ectomycorrhiza of Populus. Forest Ecology and Management, 347: 156–169.
Tarkka, M. 2000. Developmentally regulated proteins in Pinus sylvestris roots and ectomycorrhiza. University of Helsinki, Finland.
Turgeman, T., Asher, J.B., Roth–Bejerano, N., Kagan–Zur, V., Kapulnik, Y. & Sitrit, Y. 2011. Mycorrhizal association between the desert truffle Terfezia boudieri and Helianthemum sessiliflorum alters plant physiology and fitness to arid conditions. Mycorrhiza, 21: 623–630.
Ugalde, T.D., Maher, S.E., Nardell, N.E. & Wallgrove, R.M. 1995. Amino acid metabolisin and protein deposition in the endosperm of wheat; synthesis of proline via ornithine. In: Wallgrove, R.M. (Editor). Amino Acids and Their Derivatives in Higher Plants. Cambridge University Press, 7–86.
Vance, C.P. 2008. Carbon and Nitrogen Metabolism in Legume Nodules. In: Nitrogen–fixing Leguminous Symbioses. Dilworth, M.J., James, E.K., Sprent, J.I. & Newton, W.E. (Editors). Springer Verlag, Berlin, Heidelberg, New York, ISBN 978–1–4020–3548–7, 293–315.
Wilkinson, S., Kudoyarova, G.R., Veselov, D.S., Arkhipova, T.N. & Davies, W.J. 2012. Plant hormone interactions: innovative targets for crop breeding and management. Journal of Experimental Botany 63: 3499–3509.
Wolters, H. & Jurgens, G. 2009. Survival of the flexible: hormonal growth control and adaptation in plant development. Nature Reviews Genetics, 10: 305–317.
Wu, Q.S., Zou, Y.N., Xia, R.X.‚ & Wangi, M.Y. 2009. Mycorrhiza has a direct effect on reactive oxygen metabolism of drought–stressed citrus. Soil, Environmental and Atmospheric Sciences, 55(10): 436–442.
Wu, Q.S., Zou, Y.N., Xia, R.X.‚ & Wangi, M.Y. 2007. Osmotic solute responses of mycorrhizal citrus (Poncitrus trifoliate) seedling to drought stress. Acta Physiologica Plantarum, 29: 543–549.
Zeid, F.A., El Shihy, O., Ghallab, A.E.M. & Ibrahim, F.E.A. 2009. Effect of exogenous ascorbic acid on wheat tolerance to salinity stress conditions. Arab Journal of Biotechnology, 12: 149–174.