Nitrogen-13 Studies of Nitrate Fluxes in Barley Roots: II. EFFECT OF PLANT N-STATUS ON THE KINETIC PARAMETERS OF NITRATE INFLUX

Influx of nitrate into the roots of intact barley plants wasfollowed over periods of 1–15 min using nitrogen-13 asa tracer. Based on measurements taken over 15 min from a rangeof external nitrate concentrations (0·2–250 mmolm^–3), the kinetic parameters of influx, I_max and K_m, werecalculated. Compared with plants grown in the presence of nitrate throughout,plants that had been starved of N for 3 d showed a significantlygreater value ofI_max for ¹³N-nitrate influx (by a factor of1·4–1·8), but a similar value of K_m (12–14mmol m^–3). Pre-treating N-starved plants with nitratefor about 5 h further increased the subsequent rate of ¹³N-nitrateinflux, but had little effect in the unstarved controls. Allowingfor this induction of additional nitrate transport, the differencein rates of nitrate influx in control and N-starved plants wassufficient to account for the previously-observed differencein net uptake by the two groups of plants. In barley plants grown without any exposure to nitrate, butwith ammonium as N-source, both I_max and K_m for subsequent ¹³N-nitrateinflux were significantly decreased (by about one-half) comparedwith the corresponding nitrate-grown controls. The importance of changes in the rate of influx in the regulationof net uptake of nitrate is discussed. Key words: Ion transport, nitrate, influx, kinetic parameters, N-deficiency     

Progressive Cortical Senescence and Formation of Lysigenous Gas Space (Aerenchyma) Distinguished by Nuclear Staining in Adventitious Roots of Zea mays

The pattern of loss of nuclear integrity in the epidermis andcortex of maize adventitious roots was examined during (1) non-pathogeniccortical senescence associated with root ageing, and (2) lysigenousaerenchyma formation, to determine whether these phenomena arerelated. Nuclear integrity was estimated by counting the percentageof cells with nuclei detectable by acridine orange fluorescence. In roots of both soil-grown (90 d) and solution-grown (19 d)plants, nuclei were lost progressively, from the epidermis andfrom successively deeper cortical cell layers, with increasingdistance behind the root tips; this occurred irrespective ofthe degree of aeration in solution culture, and independentlyof aerenchyma formation. Aerenchyma developed in soil-grownplants and in sub-ambient oxygen concentrations (<5 kPa partialpressure) in solution culture. It started to form in the middlecortex and coincided with a marked loss of nuclear stainingin the inner cortex, especially in the innermost cortical celllayer next to the endodermis, but not in the remaining cellsof the middle cortex. Two distinct patterns of nuclear deletionfrom the cortex were thus demonstrated; they occurred independentlybut simultaneously in some conditions. These findings are discussed in relation to mechanisms of celldeath, and the metabolic status of root cortical cells participatingin ion transport to the xylem. Zea mays L., maize, roots, aerenchyma, cell death, nuclei     

The Combined Effects of Salinity and Root Anoxia on Growth and Net Na+ and K+-accumulation in Zea mays Grown in Solution Culture

The effects of excess salinity and oxygen deficiency on growthand solute relations in Zea mays L. cv. Pioneer 3906 were examinedin greenhouse experiments. The roots of plants 14 d old growingin nutrient solution containing additions of NaCl in the range1.0–200 mol m^–3 were either exposed to a severedeficiency of O₂ by bubbling with nitrogen gas (N₂ treatment),or maintained with a supply of air (controls), for a periodof 1–7 d. The threshold NaCl concentration resulting inappreciable inhibition of leaf extension, and shoot f. wt gainin controls was between 10 and 25 mol m^–3. At 25 mol m^–3NaCl the ratio of Na+/K+ transported to shoots was about 20times greater than in plants in 1.0 mol m^–3 NaCl. Theeffect of addition of NaCl to the nutrient solution was to enhanceNa+ movement but simultaneously depress the rate of K+ transportto shoots (per g f. wt roots). Interactions between NaCl levels and aeration treatment wereshown by analyses of variance to be statistically significantfor leaf extension, shoot and root f. wt gains, Na+ and K+ concentrationsin shoots and roots. When roots were N₂-treated, shoot and rootgrowth were depressed, the effect of aeration treatment beinggreatest at NaCl concentrations of 50 mol m^–3 or less.Additionally, N₂-treatment greatly accelerated Na- transportto shoots while depressing K+ transport still further, so thatat 10 mol m^–3 NaCl the ratio Na+/K+ acquired by the shootswas 230 times greater than in controls. Over the concentrationrange 1.0 to 50 mol m^–3 NaCl, the ratio Na+/K+ transportedto shoots by anoxic roots increased by a factor of 860. Mechanisms controlling changes in solute flux to the shoot,and the significance in relation to plant tolerance of excesssalts or oxygen deficiency are discussed. Anaerobic, corn, flooding, maize, oxygen-deficiency, salinity     

The Influence of Plant Nitrogen Status on NO2 Uptake, NO2 Assimilation and on the Gas Exchange Characteristics of Barley Plants Exposed to Atmospheric NO2

Barley plants were grown in nutrient solution at two contrastingnitrate concentrations to produce plants of low or high nitrogen(N) status. Leaves were then exposed continuously to either0.3 mm³ dm^–3 NO₂ or clean air, with the roots and rootingmedium isolated from the polluted air. Uptake of NO₂ was measuredin two ways; as depletion from an air stream containing thegas and using ¹⁵N-labelled NO₂. Results from the two methodsagreed well and demonstrated that the flux of NO₂ into the leavesof N-deficient barley was lower than that of N-sufficient plants.Nevertheless, the relative contribution of¹⁵N derived from ¹⁵NO₂to the N status of the plant was greater in the plants suppliedwith low nitrate. A major factor in regulating NO₂ uptake bybarley leaves appeared to be stomatal conductance, althoughinternal conductance may also be involved. The effects of NO₂exposure of barley on carbon dioxide exchange rates, transpirationand water vapour conductance were also influenced by the N statusof the plant. Key words: Hordeum vulgare, ¹⁵N-labelled NO₂, carbon dioxide exchange, transpiration     

Rapid, Reversible Inhibition of Nitrate Influx in Barley by Ammonium

The rate of influx of nitrate into the roots of intact barleyplants was measured over a period of 3–5 min from externalnitrate concentrations of 1–150 mmol m^–3, using¹³N-labelled nitrate as tracer. Ammonium at external concentrationsof 0.005–50 mol m^–3 inhibited nitrate influx ina manner which did not conform to a simple kinetic model butincreased approximately as the logarithm of the ammonium concentration.At any particular ammonium concentration, inhibition of nitrateinflux reached its full extent within 3 min of the ammoniumbeing supplied and was not made more severe by up to 17 minpre-treatment with ammonium. On removing the external ammonium,nitrate influx returned to its original rate within about 3min. Potassium at 0.005–50 mol m^–3 did not reproducethe rapid effect of ammonium on nitrate influx. Net uptake of nitrate also decreased when ammonium was supplied,over a similar timescale and to a similar extent as nitrateinflux. The decrease in nitrate influx caused by ammonium wassufficient to account for the observed reduction in net uptake,without necessitating any acceleration of nitrate efflux. Key words: Hordeum vulgare, roots, ion transport, short-lived isotopes, ¹³N     

Nutrient Supply and the Growth of the Seminal Root System in Barley: II. LOCALIZED, COMPENSATORY INCREASES IN LATERAL ROOT GROWTH AND RATES OP NITRATE UPTAKE WHEN NITRATE SUPPLY IS RESTRICTED TO ONLY PART OF THE ROOT SYSTEM

The development of the seminal root system, its ability to absorbnitrate, and effects on shoot growth were studied in barleyplants in nutrient solution. The roots received either a uniformsupply of 1.0 mM nitrate (controls), or a supply of the samesolution restricted to a 4-cm length of only one of the mainseminal roots (axes) on each plant, the remainder of the rootsystem receiving a solution containing a low concentration (0.01mM). Marked increases took place in both the growth of lateralroots and the absorption and transport of ¹⁵N-labelled nitrate(per unit root weight) from the zone locally supplied with 1.0mM nitrate. These effects appear largely to compensate for thedeficient supply of nitrate to the remainder of the root system,since after 14 d the relative growth rate (g g^–1d^–1)of the total plant equals that of the controls. Rates of ¹⁵N-nitrateuptake (per unit root weight) remain relatively uniform throughoutthe 29-d experiment, during which root axes develop from theirinitial unbranched form to a complex system of laterals. Theresults are discussed in relation to possible mechanisms bywhich coordination is maintained between root growth, ion uptake,and shoot growth.