The formation of ectomycorrhizal (ECM) root tissue is characterized by distinct morphological and developmental stages, such as preinfection and adhesion, mantle, and Hartig net formation. The global pattern of gene expression during these stages in the birch (Betula pendula)-Paxillus involutus ECM association was analyzed using cDNA microarrays. In comparison with nonsymbiotic conditions, 251 fungal (from a total of 1,075) and 138 plant (1,074 in total) genes were found to be differentially regulated during the ECM development. For instance, during mantle and Hartig net development, there were several plant genes upregulated that are normally involved in defense responses during pathogenic fungal challenges. These responses were, at later stages of ECM development, found to be repressed. Other birch genes that showed differential regulation involved several homologs that usually are implicated in water permeability (aquaporins) and water stress tolerance (dehydrins). Among fungal genes differentially upregulated during stages of mantle and Hartig net formation were homologs putatively involved in mitochondrial respiration. In fully developed ECM tissue, there was an upregulation of fungal genes related to protein synthesis and the cytoskeleton assembly machinery. This study highlights complex molecular interactions between two symbionts during the development of an ECM association.
Comparative analyses of aspects of the carbon (C) physiology and the expression of C transporter genes in birch (Betula pendula Roth.) colonized by the ectomycorrhizal fungus Paxillus involutus (Batsch) Fr. were performed using mycorrhizal (M) and non‐mycorrhizal (NM) plants of similar foliar nutrient status. After six months of growth, the biomass of M plants was significantly lower than that of NM plants. Diurnal C budgets of both sets of plants revealed that M plants exhibited higher rates of photosynthesis and root respiration expressed per unit dry weight. However, the diurnal net C gain of M and NM plants remained similar. Ectomycorrhizal roots contained higher soluble carbohydrate pools and increased activity of cell wall invertase, suggesting that additional C was allocated to these roots and their ectomycorrhizal fungi consistent with an increased sink demand for C due to the presence of the mycobiont. In M roots, the expression of two hexose and one sucrose transporter genes of birch were reduced to less than one‐third of the expression level observed in NM roots. Analysis using a probe against the birch ribosomal internal transcribed spacer region revealed that M roots contained 22% less plant RNA than NM roots. As the expression of birch hexose and sucrose transporter genes was reduced to a much greater extent, this suggests that these specific genes were down‐regulated in response to alterations in C metabolism within M roots.
Summary• Physiological and molecular responses to phosphorus (P) supply and mycorrhizal infection by Glomus intraradices were compared in European (River) and African (H511) maize ( Zea mays ) cultivars to examine the extent to which these responses differed between plants developed for use in high-and low-nutrient-input agricultural systems.• Biomass, photosynthetic rates, nutrient and carbohydrate contents, mycorrhizal colonization and nutrient-responsive phosphate transporter gene expression were measured in nonmycorrhizal and mycorrhizal plants grown at different inorganic phosphorus (P i ) supply rates.• Nonmycorrhizal River plants grew poorly at low P i but were highly responsive to mycorrhizal infection; there were large increases in biomass, tissue P content and the rate of photosynthesis and a decline in the expression of phosphate transporter genes. Nonmycorrhizal H511 plants grew better than River plants at low P i , and had a higher root : shoot ratio. However, the responses of H511 plants to higher P i supplies and mycorrhizal infection were much more limited than those of River plants.• The adaptations that allowed nonmycorrhizal H511 plants to perform well in low-P soils limited their ability to respond to higher nutrient supply rates and mycorrhizal infection. The European variety had not lost the ability to respond to mycorrhizas and may have traits useful for low-nutrient agriculture where mycorrhizal symbioses are established.
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