Influence of Xylem Water Potential on Leaf Elongation and Osmotic Adjustment of Wheat and Lupin

The leaf elongation rate and osmotic pressure at full turgorof wheat (Triticum aestivum L.) and lupin (Lupinus cosentiniiGuss.) were measured in well watered plants, in plants thatwere allowed to dry the soil slowly over 7 d, and in plantsin which the water potential of the leaf xylem was maintainedhigh by applying pressure to the roots during the drying cycle.Maintenance of high xylem water potentials failed to preventa reduction in the rate of leaf elongation as the soil dried,while the osmotic pressure at full turgor and the degree ofosmotic adjustment increased as the soil water content decreased.The rate of leaf elongation was reduced more and the degreeof osmotic adjustment was higher in leaves with high xylem waterpotentials than in those in which leaf xylem potentials wereallowed to decrease as soil water content decreased. Osmoticadjustment was linearly correlated with the reduction in leafelongation rate in both wheat and lupin. Key words: Osmotic adjustment, leaf elongation, turgor regulation     

Root Water Uptake, Leaf Water Storage and Gas Exchange of a Desert Succulent: Implications for Root System Redundancy

A technique used for hydroponics was adapted to measure instantaneousroot water uptake from the soil for a leaf succulent CAM species,Agave deserti. Comparisons were made to previously modelledwater fluxes for A. deserti and to Encelia farinosa, a non-succulentC₃species. Net CO₂uptake and transpiration forA. deserti underwell-watered conditions occurred primarily at night whereasroot water uptake was relatively constant over 24 h. Leaf thicknessdecreased when transpiration commenced and then increased whenrecharge from the stem and soil occurred, consistent with previousmodels. A drought of 90 d eliminated net CO₂uptake and transpirationand reduced the water content of leaves by 62%. Rewetting theentire root system for 7 d led to a full recovery of leaf waterstorage but only 56% of maximal net CO₂uptake. Root water uptakewas maximal immediately after rewetting, which replenished rootwater content, and decreased to a steady rate by 14 d. Whenonly the distal 50% of the root system was rewetted, the timefor net CO₂uptake and leaf water storage to recover increased,but by 30 d gas exchange and leaf water storage were similarto 100% rewetting. Rewetting 10 or 20% of the root system resultedin much less water uptake; these plants did not recover leafwater storage or gas exchange by 30 d after rewetting. A redundancyin the root system of A. deserti apparently exists for dailywater uptake requirements under wet conditions but the entireroot system is required for rapid recovery from drought.Copyright1999 Annals of Botany Company Agave deserti Engelm., desert, drought, gas exchange, rewetting, roots, succulent, water uptake.     

Mobilization of Minerals to Developing Seeds of Legumes

The mineral nutrition of fruiting plants of Pisum sativum L.,Lupinus albus L. and Lupinus angustifolius L. is examined insand cultures supplying adequate and balanced amounts of essentialnutrients. Changes in content of specific minerals in leaves,pods, seed coat, and embryo are described. P, N and Zn tendto increase precociously in an organ relative to dry matteraccumulation, other elements more or less parallel with (K,Mn, Cu, Mg and Fe) or significantly behind (Ca and Na) dry weightincrease. Some 60–90 per cent of the N, P and K is lostfrom the leaf, pod and seed coat during senescence, versus 20–60per cent of the Mg, Zn, Mn, Fe and Cu and less than 20 per centof the Na and Ca. Mobilization returns from pods are estimatedto provide 4–39 per cent of the seeds' accumulations ofspecific minerals, compared with 4–27 per cent for testatransfer to the embryo. Endosperm minerals are of only minorsignificance in embryo nutrition. Comparisons of the mineral balance of plant parts of Lupinusspp. with that of stem xylem sap and fruit tip phloem sap supportthe view that leaves and pod are principal recipients of xylem-borneminerals and that export from these organs via phloem is themajor source of minerals to the seeds. Endosperm and embryodiffer substantially in mineral compostition from phloem sap,suggesting that selective uptake occurs from the translocationstream during seed development. Considerable differences are observed between species in mineralcomposition of plant organs and in the effectiveness of transferof specific minerals to the seeds Differences between speciesrelate principally to Ca, Na and certain trace elements.     

The Effect of Accelerated Aging of Sorghum Seeds on Seedling Vigour

Six different levels of vigour of sorghum seeds from an identicallot were obtained through accelerated aging for various periodsof time. Vigour was estimated according to yielding abilityof the seed in the field. After 6 d of aging, seed invigoration,to the extent of a 20% increase in yield, was observed. However,this was followed by a gradual decrease in yield following agingof up to 48 d. All seed lots showed 88–92% germinationor emergence capacity when tested in the laboratory, which correlatespoorly with vigour. However, vigour correlated well with therates of germination and root emergence when tested in the laboratory,as well as with emergence rate in the field.     

Long Distance Transport of Abscisic Acid in NaCI-Treated Intact Plants of Lupinus albus

Plants of Lupinus albus were grown for 51 d under control (1.1mol m^–3 NaCl) and saline (40 mol m^–3 NaCl) conditions.Plants were harvested and changes of carbon, nitrogen and abscisicacid (ABA) contents of individual organs were determined 41d and 51 d after germination. In the period between the twoharvests xylem and phloem saps were collected and respirationand photosynthesis of individual organs were measured. Usingflows of carbon, C/ABA ratios and increments of ABA flows ofABA in phloem and xylem and rates of biosynthesis and degradationof ABA were calculated. Both under control and saline conditionsnet biosynthesis occurred in the root, the basal strata of leavesand in the inflorescence. Metabolic degradation of ABA tookplace in the stem internodes and apical leaf strata. Salt stress increased xylem transport of ABA up to 10-fold andphloem transport to the root up to 5-fold relative to that ofthe controls. A considerable amount of ABA in the xylem saporiginated from biosynthesis in the roots, i.e. 55% in salt-treatedand smaller than 28% in control plants. The remaining part ofABA in the xylem sap originated from the shoot: it was translocatedin the phloem from fully differentiated leaves towards the rootand from there it was recirculated back to the aerial partsof the plant. The data suggest that ABA may serve as a hormonalstress signal from the root system. Key words: Lupinus albus, salt stress, abscisic acid, long distance transport     

Water relations, gas exchange and abscisic acid content of Lupinus cosentinii leaves in response to drying different proportions of the root system

Soil columns in which the root system was divided into threeequal layers, each 24 cm in diameter and 33 cm high were usedto examine the influence of drying different proportions ofthe root system on the water relations, gas exchange and abscisicacid (ABA) concentration of lupin (Lupinus cosentinii Guss.cv. Eregulla) leaves. The treatments imposed were (i) all threelayers adequately watered (control), (ii) the upper layer unwateredwith the remaining layers kept adequately watered, (iii) thetwo upper layers unwatered with the basal layer kept adequatelywatered, (iv) all three layers unwatered. The treatments wereapplied at 56 d after sowing (DAS), and continued for 21 d inthe treatment in which the three layers were dried and for 36d in the other three treatments. After 21 d, the soil matricpotential in the layers that were unwatered had decreased toemdash 1.3MPa, compared to - 0.03 MPa in the adequately-wateredlayers. Within 8 d of cessation of watering, plants with the entireroot system in drying soil had significantly lower stomatalconductances, lower rates of net photosynthesis, and higherleaf ABA contents than did adequately-watered plants. Whilethe leaf osmotic potential decreased within 8 d of cessationof watering, the leaf water potential did not change for thefirst 15 d after water was withheld. After withholding waterfrom all layers, the shoot dry matter was 63% lower than thatin the adequately-watered plants. In the two partially-droughtedtreatments, 17% and 48% of the root length was subjected todrying. Compared to the adequately-watered plants, drying upto 50% of the root system for 36 d, in the two partially-droughtedtreatments, did not reduce stomatal conductance, net photosynthesis,or plant growth. Similarly, there was no significant effecton leaf water potential or osmotic potential. When either theupper or upper and middle layers of soil were dried, the ABAcontent of the leaves for most of the drying period was slightly,but not significantly, higher than in leaves of the adequately-wateredplants. The results suggest that lupins with a well-established rootsystem can utilize localized supplies of available soil waterto maintain leaf gas exchange despite appreciable portions ofthe root system being in dry soil. In contrast to other studies,the results also suggest that when only a portion of the soilvolume is dry and adequate water is available in the wet zone,root signals do not influence stomatal conductance and leafgas exchange of lupin. Key words: Abscisic acid, gas exchange, lupins, split-roots, water deficit     

Thermosensitivity in Spring White Lupin

Spring morphotypes of white lupin (Lupinus albus L.) are veryresponsive to cool temperatures during seedling developmentas expressed in a number of subsequent developmental characters.Thermosensitivity was examined in a number of studies whereseedlings were incubated at various stages of development andat differing temperatures. Plants were scored for thermosensitivity,as expressed by the number of mainstem and first order lateralvegetative nodes, at flowering. The stages of radicle emergenceand split seed coat were observed to be the developmental stageswhen mainstem and first-order lateral meristems were most sensitiveto incubation temperature. These data show that the optimumwindow for cold treating spring lupin seed is very narrow andoccurs prior to seedling emergence. Seedlings at radicle emergencestage were incubated at temperatures ranging from 1 to 27 °Cfor 0 to 14 d in 2 d increments. For temperatures less than12 °C, mainstem node number decreased curvilinearly withduration of incubation. For temperatures between 12 and 17 °C,mainstem node number decreased linearly with duration of incubation.However, mainstem node number increased linearly with durationof incubation at temperatures greater than 17 °C. The datashow that 'warm' temperatures during early seedling developmenthave a profound influence on subsequent plant morphology. Responseto 'warm' temperatures is greater than to 'cool' temperaturesand it is suggested that the differential response to warm vs.cold incubation temperatures could account for morphologicaland phenological differences observed within genotypes in fieldstudies among sites and years. The lack of temperature responsein one genotype, 'Start' may indicate thermoneutrality in thisgenotype.Copyright 1995, 1999 Academic Press Lupinus albus L., lupin, vernalization, thermosensitivity, vegetative development     

Nitrogen Deficiency Slows Leaf Development and Delays Flowering in Narrow-leafed Lupin

Effects of nitrogen (N) supply on leaf and flower developmentinLupinus angustifolius L. cv Merrit were examined in a temperature-controlledglasshouse. Low N supply (0.05 or 0.4 mM N) had little effecton leaf initiation but slowed leaf emergence on the main stemcompared with plants receiving high N supply (6.0 or 6.4 mMN), or with symbiotic N₂-fixation. Plants experiencing transientN deficiency had slower leaf emergence than plants with a continuoussupply of 6.4 mM N. Nitrogen supply did not affect the timeof floral initiation, which occurred within 4 weeks of sowing,by which time nine to ten leaves had emerged. However, the floweringof low-N plants was delayed by 68 to 220 °C d (i.e. 4–14d) even though they had fewer leaves. The effect of N deficiencyon flowering time was largely a result of slower leaf emergence. Lupinus angustifolius L.; nitrogen; leaf; flower initiation; thermal time; plastochron; phyllochron     

Positive and Negative Messages from Roots Induce Foliar Desiccation and Stomatal Closure in Flooded Pea Plants

Flooding the soil for 5–7 d caused partial desiccationin leaves of pea plants (Pisum sativum. L. cv. ‘Sprite’).The injury was associated with anaerobiosis in the soil, a largeincrease in the permeability of leaf tissue to electrolytesand other substances, a low leaf water content and an increasedwater saturation deficit (WSD). Desiccating leaves also lackedthe capacity to rehydrate in humid atmospheres, a disabilityexpressed as a water resaturation deficit (WRSD). This irreversibleinjury was preceded during the first 4–5 d of floodingby closure of stomata within 24 h, decreased transpiration,an unusually large leaf water content and small WSD. Leaf waterpotentials were higher than those in well-drained controls.Also, there was no appreciable WRSD. Leaflets detached fromflooded plants during this early phase retained their watermore effectively than those from controls when left exposedto the atmosphere for 5 min. Stomatal closure and the associated increase in leaf hydrationcould be simulated by excising leaves and incubating them withtheir petioles in open vials of water. Thus, such changes inflooded plants possibly represented a response to a deficiencyin the supply of substances that would usually be transportedfrom roots to leaves in healthy plants (negative message). Ionleakage and the associated loss of leaf hydration that occurswhen flooding is extended for more than 5 d could not be simulatedby isolating the leaves from the roots. Appearance of this symptomdepended on leaves remaining attached to flooded root systems,implying that the damage is caused by injurious substances passingupwards (positive message). Both ethylene and ethanol have beeneliminated as likely causes, but flooding increased phosphorusin the leaves to concentrations that may be toxic. Key words: Pisum sativum, Flooding, Foliar desiccation, Stomata, Ethylene     

Soil Water Extraction, Measured by Computer-Assisted Tomography, in Seedling Lupinus angustifolius cv. Yandee when Healthy and Infected with Phytophthora cinnamomi

The water-mould fungus Phytophthora cinnamomi Rands causes drought-likesymptoms on many hosts, and yet the mechanisms by which infectionleads to wilting are not fully understood. This is the firststudy to describe in detail changes in soil water around theroot with infection. Computer-assisted tomography (CAT) wasused with Lupinus angustifolius L. cv. Yandee to examine drawdowns(removal of soil water) around a central root infected by P.cinnamomi in a white sand. No growth differences in roots or shoots were found betweenhealthy and diseased plants during the 8 d of the experiment.However,drawdowns failed at high levels of inoculum (8–16 /Pc-infectedmillet seeds/plant) by 8 d. Water contents in pots with uninfectedplants were in the range 0·09–0·12 cm³ watercm^–3 soil in the centre of the pot, while water contentsin pots with infected plants at 16 millet seeds applied werein the range of 0·16–0·19 cm³ water cm^–3soil in the centre of the pot. A higher transpirational demand produced lower soil water contentsnear the root but this effect was confounded with infection:disease was more pronounced with higher transpirational demand,and disease led to an increase in water content. Key words: Root disease, Phytophthora cinnamomi, water uptake, soil-root interface, computer-assisted tomography     

Modelling of the flows and partitioning of carbon and nitrogen in the holoparasite Cuscuta reflexa Roxb. and its host Lupinus albus L.: II. Flows between host and parasite and within the parasitized host

A recently developed empirically based modelling technique wasused to quantify uptake, flow and utilization of C and N inLupinus albus L., uninfected and parasitized by Cuscuta reflexaRoxb. plants over a 12 d period during flowering and early fruitsetting of the host. The modelling combined data on molar C:Nratios in host phloem and pressure-induced xylem sap, net incrementsof C and N in host and parasite plant parts and respiratorylosses of C. The modelling of the solute transfer between hostand Cuscuta was achieved by assuming non-specific intake fromthe xylem. The models predicted that Cuscuta derived 99.5% ofits carbon and 93.6% of its nitrogen demand from the host phloem.The overriding sink strength of the parasite diverted most ofthe basipetally translocated host assimilates and massivelycompeted with the host root and inhibited fruit setting. Carbonincorporation in Cuscuta consumed 56%, respiration 24% and secretionby extrafloral nectaries 1.8% of the current host photosynthate.Root respiration was inhibited by 59% and carbon was mobilizedfrom host root and leaves. Competition by the parasite for Nwas even more severe and Cuscuta incorporated nitrogen equalling223% of current fixation, but N₂ fixation of the host was severelyrestricted to 37%. Withdrawal of N from host phloem led to severelosses of N from leaves and the root and marked decreases inN concentration. It required massive xylem-to-phloem transferof N, because the xylem as the major supply route for N wasnot exploited substantially by Cuscuta. The results are discussedin relation to likely causes for parasite-induced pathogeniceffects, suggesting that Cuscuta affected the host adverselyby depriving it mainly of its nitrogen, but that causal to incipientnitrogen deficiency and restricted N2 fixation was the superiorsink potential of Cuscuta, which prevented adequate supply ofassimilates to the nodulated root. The dominating sink potentialof Cuscuta is compared with the similarly strong sink competitionexerted by fruits at the stage of seed filling in annual plants. Key words: Cuscuta reflexa, Lupinus albus, parasitism, carbon, nitrogen, phloem, xylem, transport     

Water Deficit Enhanced Cotton Resistance to Spider Mite Herbivory

We investigated the responses of cotton (Gossypium hirsutumL.)to the combined effects of soil water deficit and two-spottedspider mite (Tetranychus urticaeKoch) infestation. Two mitetreatments (-M: uninfested, +M: artificially infested 83 d aftersowing), and two water regimes (+W: well watered, -W: waterstressed) were combined factorially in four treatments. Mitecolonies developed at similar rates in well-watered and water-stressedcrops. Despite the similar intensity of infestation, visualsymptoms of mite injury were more marked in well-watered hostplants (+M+W) than in their water-stressed counterparts (+M-W).Lint yield of unstressed controls (-M+W) was 175 g m^-2. In uninfestedcrops, water deficit reduced yield by 30%, mites reduced theyield of well-watered crops by 92%, and the combination of miteinfestation and water deficit reduced yield by 72% (water effect:P<0.01;mite and interaction effect:P<0.0001). Differences in yieldresponses to mites between well-watered and water-stressed cropswere mostly related to differences in reproductive partitioning.The interaction between mites and water deficit was also significantfor other crop variables including canopy temperature, leafwater potential, concentration of nitrogen in reproductive structuresand seed oil concentration. The magnitude and consistency ofthe interaction between both stresses indicates that, underour experimental conditions, mechanisms of adjustment to waterdeficit may have enhanced cotton resistance to mites. This isfurther supported by (a) an increase in specific leaf weightand a parallel increase in leaf penetration resistance due towater deficit; (b) a negative association between macroscopicsymptoms of mite injury and leaf penetration resistance; and(c) a choice test showing that adult female mites preferredto feed and oviposit on leaves from well-watered plants.Copyright1998 Annals of Botany Company Gossypium hirsutumL.;Tetranychus urticaeKoch; leaf water potential; leaf penetration resistance; canopy temperature; multiple stresses; specific leaf weight; radiation use efficiency; nitrogen concentration; reproductive allocation.     

Energetics of Plant Growth Under Anoxia: Metabolic Adaptations of Oryza sativa and Echinochloa phyllopogon

Unlike most plant species, Oryza sativa L. cv. S-201 and Echinochloaphyllopogon (Stev.) Koss germinate and grow under anaerobicconditions. In both species, the radicle or shoot emerged byday 3 when the seeds were germinated in air or N₂. Under eithercondition, shoot and/or root dry weight (d. wt) increased linearlyfrom day 3 to day 7, with a corresponding decrease in seed d.wt. In anaerobically grown O. sativa, d. wt accumulation wasreduced to 7% of that in air whereas d. wt lost from the seedwas reduced to only 37%. No root growth occurred during anaerobicgermination and shoot d. wt accumulation accounted for 10% ofthe d. wt lost from the seed. In E. phyllopogon, d. wt accumulationduring anoxia was 25% of that in air, but loss of d. wt fromthe seed was 44% of the aerobic rate. In air, 48% of the d.wt lost from the seed was converted to shoot or root d. wt.Like O. sativa, E. phyllopogon does not produce a root underN₂, but shoot growth accounted for 27% of the d. wt lost fromthe seed. Thus, either in air or N₂, E. phyllopogon was moreefficient at converting seed reserves to shoot/root structuraldry matter than O. sativa . Based on changes in metabolite pools,O. sativa appeared to shift exclusively to fermentation duringanaerobic growth. In E. phyllopogon, however, fermentation alonecannot satisfy the energy requirement for growth without O₂.Rather, fermentation, coupled with limited tricarboxylic acid(TCA) cycle operation could supply sufficient ATP for growthunder anaerobic conditions. An active oxidative pentose phosphatepathway and lipid synthesis were discussed as important mechanismsfor converting NADH to NAD, a necessary cofactor for fermentationand TCA cycle activity.Copyright 1994, 1999 Academic Press Anaerobiosis, Echinochloa phyllopogon, energetics model, fermentation, mitochondrial activity, Oryza sativa, rice, tricarboxylic acid cycle, watergrass     

Biosynthesis, accumulation and secretion of isoflavonoids during germination and development of white lupin (Lupinus albus L.)

A combination of ¹⁴C labelling experiments of white lupin seedlings(Lupinus albus L.) and high pressure liquid chromatography oftissue extracts indicated active biosynthesis of isoflavonoidsduring the first 2–4 d of seed germination. These weresynthesized mostly as glucosides and to a lesser extent as aglycones,with trace amounts of prenylated derivatives. There was a generaldecrease in total isoflavonoids during later stages of germination(c. until d 13), which may be ascribed to their turnover and/orexudation into the rhizosphere. In addition, exudation of isoflavonoidsby lupin seeds germinated under sterile conditions continuesfor 12 d with a preferential release of monoprenylated compounds.The relationship between the specific developmental events duringseed germination and the accumulation of certain groups of isoflavonoidsis discussed in relation to their possible role in the growthprocesses of lupin. Key words: Isoflavonoids, glucosides, aglycones, prenylated derivatives, root exudates, white lupin     

Response Breadths on Environmental Gradients of Germination and Seedling Growth in Two Dominant Forest Tree Species of Central Himalaya

The responses of Pimis roxburghii (chir pine), an early successionalspecies, andQuercus leucotrichophora(banj oak), a late successionalspecies were compared in terms of seed germination and seedlinggrowth. Seed germination was observed on single-factor gradientsof temperature, water stress, seed desiccation and light, andseedling growth on gradients of shade and soil moisture. Thesuppression of germination caused by continuous dark and far-redwas greater in Pinus than in Quercus. Pinus seed germinationshowed wider response breadth on gradients of water stress andseed desiccation, and narrower response breadth on the gradientof light quality, compared withQuercus. In terms of seedlinggrowth, the response breadth of Pinus was wider on the gradientof soil moisture and narrower on the gradient of shade comparedwith Quercus. Under higher soil moisture stress, the seedlingsof both species attained similar heights, butQuercus seedlingsachieved higher dry weights, a higher root: shoot ratio andlower leaf weight ratio than Pinus.     

The Influence of Pre and Post-storage Hydration Treatments on Chromosomal Aberrations, Seedling Abnormalities, and Viability of Lettuce Seeds

A 2 h soaking treatment in distilled water, or in aqueous solutionsof cysteine, potassium iodide, or sodium thiosulphate, had nosignificant effect (P > 0.25) on the subsequent longevityof lettuce seeds (Lactuca sativa L.) in two different storageenvironments. Neither did these treatments influence relationsbetween loss in germination and the frequency of chromosomalaberrations observed during first mitoses after storage. Incontrast partial hydration of lettuce seeds after storage byexposure to moist air (humidification) or to an osmoticum (priming)reversed some of the damage which resulted from ageing. Mostof the benefits occurred during the first 3 d of humidificationduring which seed moisture content rose to 34 per cent, or duringthe first 7 d of priming when seed moisture content increasedto 44 per cent. Both post-storage hydration treatments reducedthe frequency of chromosomal aberrations, increased the rateof root growth, and decreased the frequency of morphologicallyabnormal seedlings. Either treatment could be of practical use,but it is suggested that humidification is more convenient.Consideration should be given to adopting a humidification treatmentas standard practice following long-term seed storage for geneticconservation. Lactuca sativa, lettuce, seed storage, seed viability, chemical pre-treatment, seed longevity, seed humidification (conditioning), seed priming, chromosome repair, seedling abnormalities     

Identification, Purification and Properties of the Precursor of Conglutin {beta}, The 7S Storage Globulin of Lupinus albus L. Seeds

Lupinus albus L. developing cotyledons 35 d after floweringcontained a major polypeptide of-average M_r 64000, immunologicallyrelated to conglutin ß, the 7S storage globulin ofthis seed. This polypeptide decreased during seed maturation,without completely disappearing in the mature seed. This dropwas accompanied by the formation of polypeptide fragments typicalof the mature conglutin ß. The 64000 polypeptide hasbeen identified as the precursor polypeptide of conglutin ß. Undenatured conglutin ß precursor, purified by ionexchange chromatography and size exclusion chromatography, showedsurface and association properties identical to the mature conglutinß molecule. The precursor oligomer, of M_r 190000,consisted of an association of three 64000 subunits. They stronglyreacted with concanavalin A indicating the presence of covalentlylinked carbohydrate. Tryptic treatment of the undenatured conglutin ß precursorled to the accumulation of a relatively stable 59000 polypeptidewhich was cleaved later on and produced three large polypeptidefragments differing from the mature conglutin ß polypeptides. Key words: Conglutin ß, precursor, developing seeds, Lupinus albus L.     

The control of leaf conductance of white lupin by xylem ABA concentration decreases with the severity of water deficits

We studied the effects of drought on leaf conductance (g), leafwater relations and on the concentration of abscisic acid (ABA)in the xylem sap of Lupinus albus L. plants. Drought was imposedby withholding watering until predawn leaf water potential (     

Water uptake resumption following soil drought: a comparison among four barley genotypes

Soil water resulting from episodic growing season rainfall evaporatesrapidly in semi-arid regions. Plants may mnot benefit from suchwater additions if near-surface roots are unable to resume wateruptake rapidly following periods of soil water deficit. Ourobjectives were to develop a means of quantifying root uptakeresponses in the upper soil layer following rewetting aftersoil water deficit, and to evaluate the existence of genotypicdifferences among four diverse barley (Hordeum vulgare L.) genotypesin this regard. Plants were grown in replicate soil columnshaving hydraulically isolated surface and subsoil layers, andinstrumented with time-domain reflectometry (TDR) waveguides.The upper 0.05 m soil layer was allowed to dry to —1.8to —3.0 MPa for 10-14 d, during which time subsoil wetnesswas maintained at about —0.6 to —0.7 MPa. The time-courseof soil water uptake was monitored at 0.5 h intervals followingrewetting of the surface layer. Substantial water uptake began1 d after rewetting following 10 d, and 2-3 d after rewettingfollowing 14 d of water deficit. Rate of water uptake was morerapid in response to a second rewetting 5-7 d later. Consistentgenotypic responses in terms of cumulative water uptake on awhole plant and leaf area-specific basis were observed duringeach trial. These results have application to evaluating droughthardiness and interspecific competitive ability under semi-aridconditions, and to investigations of root physiological andmorphological changes that contribute to recovery from waterdeficit Key words: Hordeum vulgare, root water uptake, soil water deficit, time-domain reflectometry     

Seed Number, Seed Size and Seed Diversity in Washington Lupin (Lupinus polyphyllus Lindl.)

Over 20 000 seeds of the Washington lupin (Lupinus polyphyllusLindl.) were examined and measured in an experiment carriedout over a 10 year period (1989–1999). Four differentgroups of Washington lupin seeds were found: dark, patterned,grey and light seeds. During the 10 year experiment, the totalaverage number of seeds per plant decreased from 2654 (1990)to 1220 (1999), there was a slight decrease in seed weight perplant and an increase in the average weight per seed. Therewas a clear seed size/number trade-off at the intraspecificlevel. The relative proportions of each seed group also changedwith patterned seeds becoming dominant (50% at the beginningand 90% at the end of the experiment), grey seeds remained constant(constituting 10% of the total seeds) and the proportion ofboth dark (33% at the beginning and 5% at the end) and light(10% at the beginning and 5% at the end of the experiment) seedsdecreased. Six hundred and sixty nine seeds were found to havea different testa ornamentation; they were distributed amongthe different groups as follows: 48% patterned seeds, 29% darkseeds, 12% grey seeds and 11% light seeds. There were no significantdifferences in the physical dimensions of the ornamented seedscompared with all other seeds. The results suggest that theWashington lupin is a mixture of different species and botanicalforms; this is discussed in relation to possible selection pressuresto produce both smaller and larger seeds. The possibility thatchanges in testa ornamentation are influenced by genes controllingthe synthesis of the seed coat pigment is discussed. Copyright2001 Annals of Botany Company Lupinus polyphyllus Lindl., lupine, plant biotechnology, plant parameters, selection pressure, seed size/number trade-off, testa ornamentation