Abstract
The induction by ambient NO3- and NO2- of the NO3- and NO2- uptake and reduction systems in roots of 8-d-old intact barley (Hordeum vulgare L.) seedlings was studied. Seedlings were induced with concentrations of NaNO3 or NaNO2 ranging from 0.25 to 1000 [mu]M. Uptake was determined by measuring the depletion of either NO3- or NO2- from uptake solutions. Enzyme activities were assayed in vitro using cell-free extracts. Uptake and reduction systems for both NO3- and NO2- were induced by either ion. The Km values for NO3- and NO2- uptake induced by NO2- were similar to those for uptake induced by NO3-. Induction of both the uptake and reduction systems was detected well before any NO3- or NO2- was found in the roots. At lower substrate concentrations of both NO3- and NO2- (5-10 [mu]M), the durations of the lag periods preceding induction were similar. Induction of uptake, as a function of concentration, proceeded linearly and similarly for both ions up to about 10 [mu]M. Then, while induction by NO3- continued to increase more slowly, induction by NO2- sharply decreased between 10 and 1000 [mu]M, apparently due to NO2- toxicity. In contrast, induction of NO3- reductase (NR) and NO2- reductase (NiR) by NO2- did not decrease above 10 [mu]M but rather continued to increase up to a substrate concentration of 1000 [mu]M. NO3- was a more effective inducer of NR than was NO2-; however, both ions equally induced NiR. Cycloheximide inhibited the induction of both uptake systems as well as NR and NiR activities whether induced by NO3- or NO2-. The results indicate that in situ NO3- and NO2- induce both uptake and reduction systems, and the accumulation of the substrates per se is not obligatory.
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Selected References
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