Effects of n(2) deficiency on transport and partitioning of C and N in a nodulated legume.

Nodulated root systems of white lupin (Lupinus albus L. cv Ultra: Rhizobium strain WU425) were exposed to Ar:O(2) (80:20, v/v) or Ar:N(2):O(2) (70:10:20, v/v/v) and C and N partitioning were examined over a 9- or 10-day period in comparison with control plants with nodulated roots retained in air. Accumulation of N ceased in plants exposed to Ar:O(2) or was much reduced in plants exposed to Ar:N(2):O(2), but net C assimilation rates and profiles of C utilization remained similar to those of control N(2)-fixing plants. There was, however, a proportional reduction in CO(2) evolution from nodulated roots of the Ar:O(2) treatment. Xylem N levels fell rapidly after application of Ar:O(2). C:N ratios of phloem sap of petioles and of stem base rose during the first day of Ar:O(2) treatment and then fell progressively back to levels close to that of control plants as leaf reserves of N became available for loading of phloem. Stem top phloem sap increased progressively in C:N ratio throughout Ar:O(2) treatment, presumably due to increasing shortage of xylem derived N for xylem to phloem exchange. Reexposure of Ar:O(2)-treated nodulated root systems to air prompted a rapid recovery of N(2) fixation and restoration of plant N status. Rates of N(2) fixation in plants whose roots were exposed to a range of N(2) concentrations indicated an apparent K(m) of 10% N(2) for the attached intact white lupin nodule.