Partititioning concurrent influences of nitrogen and phosphorus supply on photosynthetic model parameters of Pinus radiata

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Tree Physiology, 27:335–344

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Partititioning concurrent influences of nitrogen and phosphorus supply on photosynthetic model parameters of Pinus radiata

Horacio E. Bown (1, 2), Michael S. Watt (3), Peter W. Clinton (3), Euan G. Mason (1) and Brian Richardson (3)

1. School of Forestry, University of Canterbury, Private Bag 4800, Christchurch, New Zealand / 2. Corresponding author (heb24@student.canterbury.ac.nz) / 3. Ensis, PO Box 29237, Christchurch, New Zealand / Received March 6, 2006; accepted May 17, 2006; published online December 1, 2006

Summary

Responses of photosynthesis (A) to intercellular CO₂ concentration (C_i) were measured in a fast- and a slow-growing clone of Pinus radiata D. Don cultivated in a greenhouse with a factorial combination of nitrogen and phosphorus supply. Stomatal limitations scaled with nitrogen and phosphorus supply as a fixed proportion of the light-saturated photosynthetic rate (18.5%) independent of clone. Photosynthetic rates at ambient CO₂ concentration were mainly in the V_cmax-limited portion of the CO₂ response curve at low-nitrogen supply and at the transition between V_cmax and J_max at high-nitrogen supply. Nutrient limitations to photosynthesis were partitioned based on the ratio of foliage nitrogen to phosphorus expressed on a leaf area basis (N_a/P_a), by minimizing the mean square error of segmented linear models relating photosynthetic parameters (V_cmax, J_max, T_p) to foliar nitrogen and phosphorus concentrations. A value of N_a/P_a equal to 23 (mole basis) was identified as the threshold separating nitrogen (N_a/P_a ≤ 23) from phosphorus (N_a/P_a > 23) limitations independent of clones. On an area basis, there were significant positive linear relationships between the parameters, V_cmax, J_max, T_p and N_a and P_a, but only the relationships between T_p and N_a and P_a differed significantly between clones. These findings suggest that, in genotypes with contrasting growth, the responses of V_cmax and J_max to nutrient limitation are equivalent. The relationships between the parameters V_cmax, J_max, T_p and foliage nutrient concentration on a mass basis were unaffected by clone, because the slow-growing clone had a significantly greater leaf area to mass ratio than the fast-growing clone. These results may be useful in discriminating nitrogen-limited photosynthesis from phosphorus-limited photosynthesis.

Keywords: electron transport, genotype, nutrient limitation, nutrient ratio, Rubisco carboxylation, stomatal limitation, triose phosphate.