Rapid effects of nitrogen form on leaf morphogenesis in tobacco

Abstract

Ammonium (NH⁺₄) instead of nitrate (NO⁻₃) as the nitrogen (N) source for tobacco (Nicotiana tabacum L.) cultivated in a pH‐buffered nutrient solution resulted in decreased shoot and root biomass. Reduction of shoot fresh weight was mainly related to inhibition of leaf growth, which was already detectable after short‐term NH⁺₄ treatments of 24 h, and even at a moderate concentration level of 2 mM. Microscopic analysis of the epidermis of fully expanded leaves revealed a decrease in cell number (50%) and in cell size (30%) indicating that both cell division and cell elongation were affected by NH⁺₄ application. Changes in various physiological parameters known to be associated with NH⁺₄‐induced growth depression were examined both in long‐term and short‐term experiments: the concentrations of total N, soluble sugars and starch as well as the osmotic potential, the apparent hydraulic conductivity and the rate of water uptake were not reduced by NH⁺₄ treatments (duration 1–12 d), suggesting that leaf growth was neither limited by the availability of N and carbohydrates, nor by a lack of osmotica or water supply. Although the concentration of K⁺ in leaf press sap declined in expanding leaves by approximately 15% in response to NH⁺₄ nutrition, limitation of mineral nutrients seems to be unlikely in view of the fast response of leaf growth at 24 h after the start of the NH⁺₄ treatment. No inhibitory effects were observed when NH⁺₄ and NO⁻₃ were applied simultaneously (each 1 mM) resulting in a NO⁻₃/NH⁺₄ net uptake ratio of 6 : 4. These findings suggest that the rapid inhibition of leaf growth was not primarily related to NH⁺₄ toxicity, but to the lack of NO⁻₃‐supply. Growth inhibition of plants fed solely with NH⁺₄ was associated with a 60% reduction of the zeatine+zeatine riboside (Z+ZR) cytokinin fraction in the xylem sap after 24 h. Furthermore Z+ZR levels declined to almost zero within the next 4 d after start of the NH⁺₄ treatment. In contrast, the concentrations of the putative Z+ZR precursors isopentenyl‐adenine and isopentenyl‐adenosine (i‐Ade+i‐Ado) were not affected by NH⁺₄ application. Since cytokinins are involved in the regulation of both cell division and cell elongation, it seems likely that the presence of NO⁻₃ is required to maintain biosynthesis and/or root to shoot transfer of cytokinins at a level that is sufficient to mediate normal leaf morphogenesis.