FRD3 controls iron localization in Arabidopsis.

The frd3 mutant of Arabidopsis exhibits constitutive expression of its iron uptake responses and is chlorotic. These phenotypes are consistent with defects either in iron deficiency signaling or in iron translocation and localization. Here we present several experiments demonstrating that a functional FRD3 gene is necessary for correct iron localization in both the root and shoot of Arabidopsis plants. Reciprocal grafting experiments with frd3 and wild-type Arabidopsis plants reveal that the phenotype of a grafted plant is determined by the genotype of the root, not by the genotype of the shoot. This indicates that FRD3 function is root-specific and points to a role for FRD3 in delivering iron to the shoot in a usable form. When grown under certain conditions, frd3 mutant plants overaccumulate iron in their shoot tissues. However, we demonstrate by direct measurement of iron levels in shoot protoplasts that intracellular iron levels in frd3 are only about one-half the levels in wild type. Histochemical staining for iron reveals that frd3 mutants accumulate high levels of ferric iron in their root vascular cylinder, the same tissues in which the FRD3 gene is expressed. Taken together, these results clearly indicate a role for FRD3 in iron localization in Arabidopsis. Specifically, FRD3 is likely to function in root xylem loading of an iron chelator or other factor necessary for efficient iron uptake out of the xylem or apoplastic space and into leaf cells.

Supply of O2 regulates demand for O2 and uptake of malate by N2-fixing bacteroids from soybean nodules.

Bacteroids, prepared anaerobically from soybean root nodules by fractional centrifugation or by sucrose or Percoll density-gradient methods, were retained within a stirred, flow-through reaction chamber and used to determine rates of respiration and N2 fixation at various rates of O2 supply. Liquid reaction solutions containing malate, oxyleghaemoglobin, dissolved N2 and various levels of dissolved O2 were passed through the reaction chamber at measured rates of flow. The relative oxygenation of leghaemoglobin in the chamber was determined automatically by spectrophotometry of the effluent solution, and the concentrations of free, dissolved O2 ([O2(free)]) and the rates of O2 consumption were calculated. N2 fixation was measured by analysis of fractions of effluent. The principal finding was that stepwise increases in the flow rate (increasing the supply of O2 and malate) induced an increase in O2 demand (respiration) resulting in a decrease in [O2(free)] and increased N2 fixation. In some experiments, samples of bacteroids were withdrawn from the flow chamber during steady states and the rates of malate uptake were measured in standard, microaerobic assays. Progressive taking of samples from the flow chamber whilst maintaining constant flow rates (increasing the supply of O2 and malate per bacteroid) also resulted in increased O2 demand and declines in [O2(free)]. With increased bacteroid respiration, transport of malate into bacteroids (linear with time between 1 and 5 min after starting each assay) increased proportionally. This suggests that the rate of malate transport is tightly coupled with bacteroid respiration. Thus, bacteroid respiration, coupled with malate uptake, must be regulated by the rate of O2 supply, rather than by the [O2(free)] prevailing in the stirred chamber as found or assumed in previous work. These features are discussed in relation to N2 fixation by anaerobically isolated bacteroids.

Comparative analysis of the Bradyrhizobium japonicum sucA region.

To study the adjustments made to the tricarboxylic acid cycle during symbiosis of nitrogen-fixing rhizobia with their host legumes, we have characterized the genes encoding the alpha-ketoglutarate dehydrogenase enzyme complex in Bradyrhizobium japonicum. The genes were arranged in the order sucA-sucB-scdA-lpdA, where scdArepresents a short-chain dehydrogenase gene (GenBank accession No. AY049030). All four genes appeared to be co-transcribed, an arrangement that is so far unique to B. japonicum. The mdh gene, encoding malate dehydrogenase, was located upstream of the sucA operon, and its primary transcript appeared to be monocistronic. Primer extension indicated that the sucA operon and mdh were transcribed from typical housekeeping promoters.