Also, there are cultivar, species a

Also, there are cultivar, species and genotypic differences in response to iron and micronutrient deficiencies (Römheld and Marschner, 1990), in terms of rates of exudation, chemical nature of phytosiderophores produced, and the size of microbial populations at the apical root zone (Von Wirén et al., 1993). Ac- cording to Römheld (1991), Fe or Zn deficiency in soil induces de novo synthesis of phytosiderophore in the cytoplasm, followed by enhanced release across the plasma membrane into the rhizosphere, where the phytosiderophore forms a complex with the insoluble ferric compound and the entire complex transported into the cytoplasm via a specific translocator in the membrane. H+ extrusion into the rhizosphere pro- motes ferric reductase enzyme activity in the plasma membrane, leading to increased reduction of ferric to ferrous ion, which is preferentially absorbed by roots (Römheld, 1987). Apparently, microbial siderophores
are also capable of solubilizing ferric compounds in the rhizosphere (Jurkevitch et al., 1986), although they are the least preferred in uptake. Iron is toxic when in excess inside cells. However, unlike in microbes, its regulation in plants still remains unknown. Microbial uptake of Fe is regulated by a chromosomal repressor, which shuts down expression of all components of the siderophore biosynthetic pathway, thus restricting further uptake of Fe into the cell (Neilands, 1987). Given that mainly grasses and cereal crops exude phytosiderophores, different plant species must have different ways of regulating internal Fe concentration than that observed in microbes.