The Effects of Irradiance on Uptake and Assimilation of Nitrate by Young Barley Seedlings

The nitrogen economy of barley plants growing in a range ofirradiances from full shade (less than 0·5 W m^–2)to 119 W ^m–2 has been examined by analysing levels oftotal, organic and nitrate nitrogen, and by determining nitratereductase activity in leaf extracts. It has been confirmed thatroot growth is reduced in low irradiances which are also associatedwith a lower level of total nitrogen in the plant, and hencewith a lower uptake of nitrate. In all parts of the plant thelevel of organic nitrogen is higher in high light intensitybut nitrate-nitrogen as a proportion of the total is greatestin low irradiances. In the first leaf accumulation of free nitrateis substantially greater in low irradiances. The data indicate a higher level of nitrate assimilation inhigh irradiances and nitrate reductase activity in leaf extractsis higher in such conditions. When the first leaf is shadednitrate reductase activity falls to undetectable levels afterabout 4 days, but in the case of the second leaf, where thisis shaded, some reductase activity is always found, althoughthis is substantially less than that in unshaded conditions. It is concluded that in vitro rates of nitrate reduction mayover-estimate nitrate assimilation determined as increase inorganic nitrogen.     

Post-harvest physiology of tetraploid banana fruit: response to storage and ripening

Aspects of the post-harvest physiology relating to storage and ripening of the fruit of tetraploid banana clones resistant to Sigatoka disease, have been compared with fruit of Valery, an important commercial triploid cultivar. Significant differences in susceptibility to low temperature injury, duration of the preclimacteric period, the texture of pulp and peel and ethylene evolution have been found between tetraploid and Valery fruit and also between tetraploid fruit of different clones. Fruit of Valery and one tetraploid clone developed serious chilling injury during storage at 12 °C whereas that of five other tetraploid clones showed only slight damage. The preclimacteric period for fruit of two tetraploid clones was 30–45% less than for Valery fruit at an equivalent stage of physical development. Pulp firmness of preclimacteric tetraploid fruit was 20–30% less than that of Valery fruit and the differences persisted through ripening. The softening response to applied ethylene was up to 15 h earlier in fruit of tetraploid clones than of Valery but respiratory patterns, colour development and starch-to-sugar conversion were similar. Unlike Valery fruit, ripe tetraploid fruit did not develop senescent spotting, and shelf life was terminated by rapid deterioration of peel strength to a state of severe finger drop. Temporal and quantitative differences occurred between fruit of tetraploid clones and Valery in production of ethylene and these may relate to the observed differences in control of softening in both pulp and peel.     

The effect of gibberellins on the storage life of plantains

Dipping plantain fruits in gibberellins (GA_4/7 or GA₃) delayed the ripening of individual fruits by approximately 50%, the two treatments being equally effective. Measurement of the preclimacteric period (PCP) by increased respiration showed that plantain fruits vacuum infiltrated with GA_4/7 (10^-5 M) gave an extension of 37% in the PCP under high humidity. No effect was observed at low humidity. The use of gibberellins on plantain storage is discussed.     

The Aetiology of Vascular Discoloration in Cassava Roots after Harvesting: Development of Endogenous Resistance in Stored Roots

The susceptibility of cassava roots, Manihot esculenta Crantz, to vascular discoloration beneath two types of injury site, transverse cuts and periderm injuries, was compared for freshly harvested and stored roots. Susceptibility beneath transverse cuts changed rapidly, so that roots stored at ambient temperature for 5–9 days were largely resistant to vascular discoloration beneath this type of injury. Susceptibility to localized deterioration beneath periderm injuries changed more slowly, but significant decreases were observed in roots stored at ambient temperature for 10–16 days. Changes in susceptibility were observed in all cultivars tested, seven in Colombia and one in Jamaica. These changes were retarded but not prevented by storage at 2°C and by storage in sealed polyethylene bags. Pruning plants 1 to 3 weeks prior to harvesting, which has been shown to reduce the rate of post-harvest deterioration of roots, was also found to reduce the susceptibility of roots to vascular discoloration beneath injuries made immediately after harvesting. Water loss through injuries caused a respiratory response as well as vascular discoloration. This respiratory response was as large in stored (resistant) roots as in freshly harvested (susceptible) ones. The potential of cassava roots to develop endogenous resistance to vascular discoloration either before or after harvesting is discussed in relation to the problems of storage of harvested cassava roots.     

Fixation and transfer of nitrogen in a white clover-grass sward under hill conditions

Experiments are described to illustrate the different effect of defoliation and diurnal changes in light intensity and temperature on grazed white clover (Trifolium repens) ecotypes and pot grown clover. Removing all the fully expanded leaves from grazed clover has no effect on nodule numbers or on nitrogen fixing activity during the phase of early season rapid growth. No diurnal rhythm in nitrogen fixing activity is apparent in grazed clover swards. Isotope dilution experiments demonstrate that in the first half of the growing season underground transfer of nitrogen is low in cut plots in a previously grazed hill situation. The results are briefly described in the context of improved hill pasture utilisation.     

The Effect of Lenient Defoliation on the Nitrogen Economy of White Clover: The Contribution of Mineral Nitrogen to Plant Nitrogen Accumulation During Regrowth

Single plants of white clover (Trifolium repens L.) were grownfrom stolon cuttings rooted in sand. All plants were inoculatedwith Rhizobium trifolii, and for 14 weeks received nutrientsolution containing 0.5 mg N each week, as either ammonium ornitrate. Plants were then leniently defoliated or were leftintact and a ¹⁵N-labelled N source was applied at intervalsof 4 d to replace the unlabelled N. Lement defoliation removedfully expanded leaves only; the remaining immature leaves accountedfor 39–44% of the total. At harvests over the following21 d, leaf numbers were counted and dry matter (DM), N contentsand ¹⁵N enrichments of individual plant organs were determined. Rates of leaf emergence and expansion were accelerated in defoliatedplants; numbers of young leaves were similar in defoliated andintact plants. Total DM and N content were less in defoliatedthan intact plants and were not affected by form of N supplied.DM of young leaves, growing points and stolons and N contentof young leaves were, however, greater when ammonium ratherthan nitrate N was supplied. Rates of increase in the contentof plant total N were 8.2 ± 1.36 mg N d^-1 and 10.2±1.82 mg N d^-1 in defoliated and intact plants respectively.The increases were predominantly due to N₂ fixation, since recoveryof ¹⁵N showed that less than 1% of the increment in plant totalN was assimilated mineral N. Nevertheless, the contributionof mineral N to plant total N was 50% more in defoliated thanin intact plants; higher amounts of mineral N were found particularlyin young leaves and growing points. Partitioning of mineralN to nodulated roots increased over time and was greater whenammonium rather than nitrate N was present. White clover, Trifolium repens L. cv. S184, lenient defoliation, N accumulation, N₂ fixation     

Seasonal growth of tree lupins (Lupinus arboreus) and the effect of defoliation on leaf production

The growth of tree lupins was investigated in two experiments. In the first, two ages of plant, 4-wk-old seedlings and 1-year-old plants, were transplanted into a ryegrass sward in an upland environment. Growth, in terms of leaf production, branching and stem elongation, was measured over two successive growing seasons. Plant dry matter and nutrient contents were determined at the beginning and end of each growing season. In the first summer, the rate of production of new leaves on the main stem of seedling plants averaged 1.8 leaves per wk and main stem length increased from 5 to 67 cm. On older plants, where floral apices had been initiated on main and primary stems, there was a 3–10 fold increase in secondary branch length. In the second season, there was no effect of plant age on rates of leaf appearance or stem extension; dry matter production was higher than in the first season. In the second experiment, the effect of removal of 0%, 50% or 100% of fully expanded leaves on the subsequent growth of 23-wk-old plants was investigated. During the 7-wk growth period, defoliation promoted the rate of production of mature leaves, and area and dry weight of new laminae were slightly higher in defoliated plants. Defoliation did not affect the concentrations of N, P or K in the new laminae, but P and K concentrations in petioles of defoliated plants were significantly higher than those in intact plants. The results from the experiments are discussed in relation to the potential use of tree lupins as nurse species and biomass crops in hill and upland environments of the UK.     

The Effect of Defoliation on the Nitrogen Economy of White Clover: Regrowth and the Remobilization of Plant Organic Nitrogen

Single plants of white clover (Trifolium repens) were establishedfrom stolon cuttings rooted in acid-washed silver sand. Allplants were inoculated with Rhizobium trifolii, and receivednutrient solution containing 0·5 mg ¹⁵N as either ammoniumor nitrate weekly for 12 weeks (i.e. 6 mg ¹⁵N in total). Plantswere then leniently defoliated or left intact, and the labelledN supply was replaced with unlabelled N. Lenient defoliationremoved fully expanded leaves only, leaving immature leaveswhich accounted for 50–55% of the total; growing pointnumbers were not reduced. Nodules, leaves and growing pointswere counted over the following 21 d period, and d. wts, N contents,and ¹⁵N enrichments of individual plant organs were determined. Defoliated plants had fewer nodules, but numbers of growingpoints were unaffected by defoliation. The rates of both leafemergence and expansion were accelerated in defoliated plants;in consequence the number of young leaves remained less thanin intact plants until day 21. Total dry matter (DM) and N accumulationwere less in defoliated plants, and a greater proportion oftotal plant DM was invested in roots. About 97 % of plant totalN was derived from fixed atmospheric N, but there was incompletemixing of fixed and mineral N within the plant. Relatively moremineral N was incorporated into roots, whereas there was relativelymore fixed N in nodules. There was isotopic evidence that Nwas remobilized from root and stolon tissue for leaf regrowthafter defoliation; approximately 2 % of plant N turned overdaily in the 7-d period after defoliation, and this contributedabout 50% of the N increment in leaf tissue. White clover, Trifolium repens L. cv. SI84, lenient defoliation, N economy, regrowth, N remobilization