Summary
Sodium nitrate applications ranging from 0.36 to 22.84 mM N were shown to depress rates of nodule formation and reduce total nitrogen fixation (acetylene reduction) in white clover plants grown in aseptic test tube culture.
Low nitrate levels gave an initial depression in symbiotic activity but the reduction was of short duration and these treatments were subsequently associated with enhanced rates of nodule formation and nitrogen fixation. As a result, phenotypic variation appeared to be strongly differentially affected by the amount of nitrate present. A subsequent experiment suggested that much of the variation was a consequence of early enhancement of plant growth rates by low levels of nitrate followed by rapid depletion thus giving a transitory inhibitory effect. This was confirmed in a third experiment in which the range of nitrate concentration was held constant. Differential effects on variability in nodule formation and nitrogen fixation were then greatly reduced but there was still a residual level of plant-to-plant variation. The results have clear implications for selecting genetic variants capable of fixing di-nitrogen in the presence of combined N. The provision of a single limiting dose of combined nitrogen to a population containing individuals with inherently different growth rates can bring about variations in the phenotypic expression of symbiotic characters. These variations are unlikely to be based on genetic factors which have a direct and stable effect on nodule development and nitrogenase activity. The implications of the results for plant breeding are discussed.
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Rys, G.J., Mytton, L.R. The potential for breeding white clover (Trifolium repens L.) with improved nodulation and nitrogen fixation when grown with combined nitrogen. Plant Soil 88, 181–195 (1985). https://doi.org/10.1007/BF02182445
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DOI: https://doi.org/10.1007/BF02182445