Relationships between leaf nitrogen and limitations of photosynthesis in canopies of Solidago altissima

Vertical distribution patterns of light, leaf nitrogen, and leaf gas exchange through canopies of the clonal perennial Solidago altissima were studied in response to mowing and fertilizer application in a field experiment. Consistent with the distribution of light, average leaf nitrogen content followed a 'smooth' exponential decline along the fertilized stands both in control and mown plots. The nitrogen profile along the unfertilzed stands in mown plots, however, was 'disrupted' by high-nitrogen leaves at the top of shorter ramets that only reached intermediate strata of the canopies. Hence, in these stands leaf nitrogen was significantly increased in shea ramets compared with tall ramets for a given light environment, suggesting suboptimal stand structure but not necessarily suboptimal single-ramet architecture. However, at least under the climatic conditions observed during measurements, such disrupture had no substantial effect on stand productivity: model calculations showed that vertical distribution patterns of leaf nitrogen along ramets only marginally influenced the photosynthetic performance of ramets and stands. This is explained by the observed photosynthesis-nitrogen relationship: the rate of photosynthesis per unit amount of leaf nitrogen did not increase with leaf nitrogen content even under saturating light levels indicating that leaf photosynthesis was not nitrogen limited during the measurement periods. Nevertheless, our study indicates that consideration of how architecture(s) of adjacent individual plants interact could be essential for a better understanding of the trade-offs between individual and canopy characteristics for maximizing carbon gain. Such trade-offs may end up in a suboptimal canopy structure, which could not be predicted and understood by classical canopy optimization models. (C) 1999 Editions scientifiques et medicales Elsevier SAS.