Sodium and potassium relations of Spergularia marina following N and P deprivation: results of short‐term growth studies

Abstract

In this, we consider the coordination of plant growth and ion acquisition, reporting the short‐term adjustments of growth and K+ and Na+ relations which follow when plants are subject to a sudden deprivation of N and P. The plant used for the experiments, Spergularia marina (L.) Grieseb., is a small coastal halophyte, and the growth medium was 0.2 × modified seawater. By considering nutrients whose availability has not been changed, we report on an aspect of organismal integration which has received little attention either experimentally or in mathematical models. The studies are limited to the first 60 h after N and P deprivation in order to consider changes that, if they are not primary responses, are not temporally remote, passive adjustments.For growth analyses, plants were used approximately 30 days after germination and 16 days after transfer to solution culture. Random harvests were made at hourly invervals, and after 12 h, one‐half of the plants were transferred to cultures without N or P. Tissue analyses were used to calculate relative growth rates, relative accumulation rates and net uptake rates. For comparison, isotope uptake studies using 42K+ and 22Na+ were conducted at 12, 36 and 60 h after deprivation.The effects on growth and biomass allocation were very rapid, detectable within 13 h. K+ transport also responded quickly, and from the beginning of the study, there was essentially no net translocation of K+ to the shoot. Isotope studies confirmed the responsiveness, with translocation reduced 33 and 90% after 12 and 36 h, respectively. Though Na+ adjustments were slower, they were coordinated with growth such that tissue concentrations in the N and P‐deprived plants were comparable to those in the controls. We conclude that N and C are insufficient elements on which to build mathematical models useful to environmental physiologists. At a minimum, the incorporation of K+ relations in growth models would both allow the development of the osmotic potential needed to drive cell expansion, and provide a means to probe –experimentally as well as mathematically – the coordinating mechanisms of plant growth and resource management.