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Economy of Carbon and Nitrogen in a Nodulated and Nonnodulated (NO₃-grown) Legume ¹

^a Department of Botany, University of Western Australia, Nedlands, 6009

Partitioning and utilization of assimilated C and N were compared in nonnodulated, NO₃-fed and nodulated, N₂-fed plants of white lupin (Lupinus albus L.). The NO₃ regime used (5 millimolar NO₃) promoted closely similar rates of growth and N assimilation as in the symbiotic plants. Over 90% of the N absorbed by the NO₃-fed plants was judged to be reduced in roots. Empirically based models of C and N flow demonstrated that patterns of incorporation of C and N into dry matter and exchange of C and N among plant parts were essentially similar in the two forms of nutrition. NO₃-fed and N₂-fed plants transported similar types and proportions of organic solutes in xylem and phloem. Withdrawal of NO₃ supply from NO₃-fed plants led to substantial changes in assimilate partitioning, particularly in increased translocation of N from shoot to root. Nodulated plants showed a lower (57%) conversion of C or net photosynthate to dry matter than did NO₃-fed plants (69%), and their stems were only half as effective as those of NO₃-fed plants in xylem to phloem transfer of N supplied from the root. Below-ground parts of symbiotic plants consumed a larger share (58%) of the plants' net photosynthate than did NO₃-fed roots (50%), thus reflecting a higher CO₂ loss per unit of N assimilated (10.2 milligrams C/milligram N) by the nodulated root than by the root of the NO₃-fed plant (8.1 milligrams C/milligram N). Theoretical considerations indicated that the greater CO₂ output of the nodulated root involved a slightly greater expenditure for N₂ than for NO₃ assimilation, a small extra cost due to growth and maintenance of nodule tissue, and a considerably greater nonassimilatory component of respiration in root tissue of the symbiotic plant than in the root of the NO₃-fed plant.

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