Genetic Variability in Recovery Growth and Synthesis of Stress Proteins in Response to Polyethylene Glycol and Salt Stress in Finger Millet

Marked differences were found among 28 finger millet genotypes(Eleusine coracana Gaertn.) in acquired tolerance to osmoticstress as assessed by the recovery of root growth from severestress [-1·2 MPa polyethylene glycol, (PEG) or 400 mMNaCl]. However, these differences in tolerance were observedonly when the seedlings were subjected to a preceding mild inductionstress (-0·6 MPa PEG or 200 mM NaCl). In two contrastinggenotypes, synthesis of stress-induced proteins was studied.Proteins with apparent molecular weight of 70-72, 52, 37, 34and 23 kDa were synthesized in the highly responsive genotype(GE 415) and poorly responsive (VL 481) genotype following amild induction stress (200 mM NaCl). However, GE-415 synthesizeda 54 kDa protein that was not observed in VL-481. Addition ofabscisic acid (ABA) to the induction medium containing 200 mMNaCl enhanced the acquired tolerance of finger millet seedlingsover those without ABA in association with the appearance ofseveral ABA-responsive proteins. GE-415 required much less ABAthan VL-481 to obtain the same response. With 10 µM ABA+ 200 mM, A NaCl induction stress, GE-415 had significantlyhigher endogenous ABA. In association with higher levels ofABA, GE-415 had greater recovery root growth following severestress from 600 mM NaCl. Pretreatment with 10 µM ABA +200 mM NaCl induced several proteins with apparent molecularweights of 70-72, 54, 45, 36, 29 and 21 kDa in both genotypes.Qualitatively, GE-415 synthesized a unique 23-24 kDa proteinand quantitatively there was significantly more of the 21 kDaprotein in GE-415 compared to VL-481. The results indicate thatthe synthesis of stress proteins is correlated with the observedvariation in acquired tolerance of the two genotypes.Copyright1995, 1999 Academic Press Eleusine coracana Gaertn., salinity, polyethylene glycol, stress proteins, ABA, ABA-responsive proteins, finger millet seedlings     

An Association between Flowering and Reduced Stomatal Sensitivity to Water Stress in Pearl Millet [Pennisetum americanum (L.) Leeke]

Stomatal sensitivity to water stress was investigated in pearlmillet [Pennisetum americanum (L.) Leeke] in relation to stageof plant development, leaf water status and ABA content by samplingplants at midday. For the same leaf water potential (), droughtedplants with emerged panicles were found to have a greater leafconductance (g_L), indicative of greater stomatal opening, thanplants sampled prior to panicle emergence. The difference betweensuch flowering (F) and non-flowering (NF) plants in at stomatalclosure was estimated to be at least 0.6 MPa. This differencewas considered unlikely to be the result of differential bulkleaf osmotic adjustment, and for most samples from both F andNF plants, bulk leaf turgor potential (_p) was estimated to bezero. Stomatal closure in NF plants was associated in two genotypes(BJ 104 and line 112) with higher leaf ABA levels. Differencesin ABA levels between F and NF plants were, however, smalleror absent in genotypes Serere 39 and B282. These genotypes wereat lower than BJ 104 and line 112 when sampled and showed smallerdifferences between F and NF plants in conductance. Lower ABA levels in F plants are ascribed either to effectsof leaf ageing or to effects of flowering on ABA content ofthe leaf. Significant differences in g_L in the absence of differencesin ABA content are taken to imply changes in stomatal sensitivityto the hormone or in its access to the stomatal complex. Pennisetum americanum (L.) Leeke, pearl millet, flowering, stomata, water stress, abscisic acid     

The Method of ABA Application Affects Salt Stress Responses in Resistant and Sensitive Potato Lines

The phytohormone abscisic acid (ABA) has been proposed to act as a mediator in plant responses to a range of stresses, including salt stress. Most studies of ABA response apply ABA as a single dose. This may not resemble the prolonged increasing endogenous ABA levels that can occur in association with slowly increasing salinity stresses in nature or field situations. Salt stress response based on method of ABA application was examined in four potato genotypes of varying salt stress resistance: the sensitive ABA-deficient mutant and its normal sibling, a resistant genotype line 9506, and commercial cultivar ‘Norland’ of moderate resistance. ABA was applied by root drench at 0, 50, 75, or 100 μM concentrations through a single dose, or by slowly increasing multiple ABA doses in a sand-based growing system under greenhouse conditions. Salt tolerance was then evaluated after 2 weeks of exposure to 150–180 mM NaCl stress. The method of ABA application had a marked effect on the responses to salt stress. Plant responses to the method of ABA application were differentiated according to (1) growth rate, (2) root water content, and (3) apparent shoot growth response. Under a single dose, growth rate increased in all genotypes under salt stress, whereas slowly increasing multiple ABA applications generally maintained stable growth rates except in the ABA-deficient mutant where there was an upward growth trend. Percent root water content was elevated only under slowly increasing multiple ABA doses in two genotypes, whereas none of the single-dose treatments induced any change. The single ABA dose enhanced vertical growth, whereas the slowly increasing multiple ABA dose applications enhanced lateral shoot growth. Because exogenous application is still an artificial system, endogenous ABA was supplied through grafting of ABA-deficient mutant scions onto rootstocks with known elevated ABA levels. Multiple exogenous ABA applications as low as 50 μM elicited similar shoot water content responses as grafting treatments without ABA application in the mutant genotype but had no effect on the ABA normal sibling. Shoot dry weight was significantly increased through grafting over all exogenous ABA treatments. Our study further indicates that the method of ABA application regime in itself can alter plant responses under salt stress and that certain application regimes may reflect responses to elevated endogenous levels of ABA.     

Characterization of a wilty sunflower (Helianthus annuus L.) mutant II. Water relations, stomatal conductance, abscisic acid content in leaves and xylem sap of plants subjected to water deficiency

The response of w-1, a wilty sunflower (Helianthus annuus L.)mutant, to water stress is described in comparison with thecontrol line (W-1). Detached leaves of w-1 strongly dehydratedduring the first 30 min without significant changes in leafconductance, whereas W-1 responded rapidly to water loss byreducing stomatal aperture. After 2 h stress ABA increased slightlyin w-1, while W-1 leaves showed a 20-fold increase. When waterstress was imposed to potted plants by water withholding, w-1quickly dehydrated, and lost turgor, while W-1 maintained positiveturgor values for a longer period. Wild-type plants respondedto small changes in leaf water potential by accumulating ABAand by closing stomata, whereas in the mutant significant changesin ABA content and in stomatal conductance were found only atvery low water potentials. In another experiment in which waterwas withheld under high relative humidity, when soil water contentstarted to decrease W-1 rapidly closed stomata in the absenceof any change in leaf water status and the reduction in conductancewas paralleled by a rise in xylem sap ABA concentration. Bycontrast the mutant started to accumulate ABA in the xylem sapand to close stomata when soil water content and leaf waterpotential were dramatically reduced. The low endogenous ABAlevels and the inability to synthesize the hormone rapidly eitherin the leaves or in the roots seem to be responsible for thehigh sensitivity of w-1 to water stress. Key words: ABA, Helianthus annuus L, water relations, stomatal conductance, drought, wilty mutant     

Genotypic Differences in the Temperature Responses of Tropical Crops: II. SEEDLING EMERGENCE AND LEAF GROWTH OF GROUNDNUT (ARACHIS HYPOGAEA L.) AND PEARL MILLET (PENNISETUM TYPHOIDES S. & H.)

Mohamed, H. A., Clark, J. A. and Ong, C. K. 1988. Genotypicdifferences in the temperature responses of tropical crops.II. Seedling emergence and leaf growth of groundnut (Arachishypogaea L.) and pearl millet (Pennisetum typhoides S. &H.).—J. exp. Bot. 39: 1129-1135. Measurements of seedling emergence and leaf growth of five milletand seven groundnut genotypes were made at soil temperaturesranging from 7 to 27?C. The rate of seedling emergence (R_e)varied greatly between millet genotypes but R_e was remarkablysimilar in groundnut genotypes. In pearl millet there is a strongcorrelation between the rate of germination and the rate ofleaf production, hourly leaf extension and seedling emergence.The results are discussed in terms of the thermal time requirementsof various processes. Key words: Temperature, emergence, groundnut, millet     

Genotypic Variation in Pearl Millet (Pennisetum americanum (L.) Leeke), in the Ability to Accumulate Abscisic Acid in Response to Water Stress

Variation between genotypes in the ability to accumulate abscisicacid (ABA) in response to water stress was investigated in pearlmillet (Pennisetum americanum (L.) Leeke). Using a detachedleaf test a more than four-fold variation in accumulation capacitywas observed amongst a set of 16 genotypes grown in a controlledenvironment. Two genotypes which contrasted in their accumulationcapacity, BJ 104 and Serere 39 (the latter accumulating mostABA), maintained the difference over a range of leaf water contentsand potentials. Some of the genotypes were grown in the field in the semi-aridtropics with and without irrigation, and sampled for ABA content.In two experiments, substantial genotypic variation in ABA accumulationwas observed, which could not be attributed to differences inleaf water potential (). In a field experiment comparing threegenotypes (Serere 39, BJ 104, and B282), differences in ABAaccumulation were also shown to be largely independent of genotypicdifferences in turgor potential (_p). For a set of six of the genotypes, the amounts of ABA accumulatingin leaves of intact, droughted plants, in the field, when adjustedfor differences in , were found to be significantly (P<0.05)correlated with amounts of ABA accumulated in detached, water-stressedleaves. It is concluded that the detached leaf test adequatelyreflects the ability of pearl millet genotypes to accumulateABA under field conditions.     

Diurnal Changes in Endogenous Abscisic Acid in Leaves of Pearl Millet (Pennisetum americanum (L. ) Leeke) under Field Conditions

Diurnal variation in leaf abscisic acid (ABA) content was investigatedin pearl millet (Pennisetum americanum (L. ) Leeke) growingin the field in the semi-arid tropics and subjected to varyingdegrees of water stress. There was a two- to three-fold change in ABA content duringthe photoperiod in three groups of ‘severely’ stressedplants of the genotype BJ 104. Maximum ABA occurred mid-morning(1030 h). ABA levels then declined to a minimum at 1500 h. Changesin ABA content of ‘moderately’ stressed and fullyirrigated plants were smaller, but still significant. Though,when averaged over the day, levels of ABA of the five groupswere positively related to the degree of water stress, relationshipsbetween ABA concentration and total water () or turgor (_p) potentialsvaried considerably with time of sampling. Within groups, changesin ABA contents during the day were not always accounted forby changes in or _p. Temporal changes in leaf ABA content similar to those foundin BJ 104, and largely unrelated to , were observed in the genotypesSerere 39 and B282 in a subsequent year. Leaf ABA content of droughted plants (BJ 104) did not declineappreciably overnight despite a marked increase in . However,a large reduction in ABA content with increase in did occurfollowing heavy rainfall. Diurnal changes in stomatal conductance (g₁) of BJ 104 couldnot be simply accounted for by temporal changes in total leafABA content, even when allowance was made for effects of irradianceand other environmental variables on g₁. It is suggested thatthe sensitivity of stomata to ABA, or accessibility of the hormoneto the stomatal complex, changes during the day.     

Solute Accumulation and Growth in Plants of Pearl Millet (Pennisetum americanum [L.] Leeke) Exposed to Abscisic Acid or Water Stress

Henson, I. E. 1985. Solute accumulation and growth in plantsof pearl millet (Pennisetum americanum [L.] Leeke) exposed toabscisic acid or water stress.—J. exp. Bot. 36: 1889–1899.Experiments were conducted to investigate whether abscisic acid(ABA) elicits the accumulation of solutes and lowering of osmotic(solute) potential (₂) which occurs in leaves of pearl millet(Pennisetum americanum [L.] Leeke) exposed to water stress.When (?)–ABA was injected into the base of the shoot of15–d–old plants, ₂ of the fifth leaf was reducedsignificantly below controls 27–72 h after treatment.The reductions, however, were small (< 0.10 MPa) and wereaccompanied by a significant inhibition of shoot growth. Incontrast, no significant reduction in ₂ or in growth occurredwhen the hormone was introduced directly into leaf five viaits mid–rib. ABA concentrations in leaf five were highshortly after direct injection, but declined to control levelswithin 48 h. Injecting ABA into the shoot base resulted in lowerleaf five ABA concentrations. Hence, the ABA concentration inthe leaf was not the most critical factor for its effect on₂. ABA also reduced ₂ of shoots when applied to seedlings 48h or 72 h after sowing via the roots. As with older plants,the effects of ABA on ₂ were small ( 0–2 MPa) and wereaccompanied by inhibition of shoot growth. A water stress treatmentand an ABA treatment were compared. Although both treatmentsresulted in a similar degree of growth inhibition, the stresstreatment was much more effective than was ABA in reducing ₂. Key words: Pennisetum americanum [L.], pearl millet, abscisic acid, water stress, osmotic     

Genotypic Differences in the Temperature Responses of Tropical Crops: I. GERMINATION CHARACTERISTICS OF GROUNDNUT (ARACHIS HYPOGAEA L.) AND PEARL MILLET (PENNISETUM TYPHOIDES S. & H.)

Mohamed, H. A., Clark, J. A. and Ong, C. K. 1988. Genotypicdifferences in the temperature responses of tropical crops.I. Germination characteristics of groundnut (Arachis hypogaeaL.) and pearl millet (Pennisetum typhoides S. & H.).—J.exp. Bot. 39: 1121–1128. The germination at constant temperature of several genotypesof groundnut and pearl millet was investigated between 0?C and50?C on a thermal gradient plate. Large differences in bothgermination rate and percentage germination were observed inboth species. Base temperatures vary from 8–11.5?C and 8–13.5?Cin groundnut and millet, respectively and optimum temperaturesfrom about 29–36.5?C in both. Maximum temperatures forgermination ranged from 41–47?C. The results are discussedin terms of adaptation to high soil temperature and crop establishmentin the semi-arid tropics. Key words: Temperature, germination, millet, groundnut     

Characterization of a wilty sunflower (Helianthus annuus L.) mutant: III. Phenotypic interaction in reciprocal grafts from wilty mutant and wild-type plants

The present study was conducted to evaluate phenotypic interactionin reciprocal grafts between wilty (w-1) sunflower mutant andnormal (W-1) plants. The w-1 genotype is a ‘leaky’ABA-deficient mutant, characterized by high stomatal conductance,in both light and dark conditions, and high transpiration rate. In well-watered conditions, mutant scions grafted on to normalrootstock (w-1/W-1) showed higher leaf relative water content,leaf water potential and ABA levels than those of control grafts(w-1/w-1). In addition, detached leaves of w-1/W-1 exhibitedlower water loss than w-1/w-1 grafts, while mutant rootstockdid not affect the transpiration rate of detached W-1 leaves.When drought stress was imposed to potted plants by withholdingwater, the mutant scions grafted on to normal roots showed apartial phenotypic reversion. A rapid stomatal closure and arise in ABA levels in response to a small decrease in leaf waterpotential was observed. By contrast, in w-1/w-1 grafts significantreductions in stomatal conductance and ABA accumulation weredetected only in conjunction with a severe water deficit. W-1scions on mutant stocks (W-1/w-1) maintained the normal phenotypeof control wild-type grafts (W1/W-1). Key words: ABA, grafting, Helianthus annuus, stomatal conductance, water relations, wilty mutant     

Osmotic Stress Temporarily Reverses the Inhibitions of Photosynthesis and Stomatal Conductance by Abscisic Acid--Evidence that Abscisic Acid Induces a Localized Closure of Stomata in Intact, Detached Leaves

Ward, D. A. and Drake, B. G. 1988. Osmotic stress temporarilyreverses the inhibitions of photosynthesis and stomatal conductanceby abscisic acid—evidence that abscisic acid induces alocalized closure of stomata in intact, detached leaves.—J.exp. Bot 39: 147–155. The influence of osmotic stress on whole leaf gas exchange wasmonitored in detached leaves of Glycine max supplied with anexogenous concentration (10^–5 mol dm^–3) of ±abscisicacid (ABA) sufficient to inhibit net photosynthesis and stomatalconductance by 60% and 70%, respectively, under a saturatingirradiance and normal air. Raising the osmotic (sorbitol) concentrationof the ABA solutions feeding leaves elicited rapid and synchronousreversals of the ABA-dependent inhibitions of net photosynthesisand conductance. These reversals reached a peak simultaneously,after which photosynthesis and conductance declined. The magnitudeof the transient stimulations at peak height was dependent uponthe sorbitol concentration of the ABA feeding solution, althoughthe time-course of the transients (half time, 4–6 min)was similar for the different osmotic concentrations applied.Irrespective of transient size the relative changes of photosynthesisand conductance were comparable; consequently the calculatedpartial pressure of CO₂ in the substomatal space (Ci) remainedrelatively constant during the transient phase. In contrastto the ABA-treated leaves, elevating the osmotic concentrationof the distilled water supply feeding control leaves stimulatedconductance to a much greater relative extent than photosynthesis.The co-stimulations of photosynthesis and conductance inducedin ABA-treated leaves by osmotic shock were not due to a restrictionin the transpirational uptake of ABA and occurred irrespectiveof the source osmoticum applied. These data are consistent with the hypothesis that the ABA-dependentinhibition of photosynthesis at constant Ci is an artifact causedby the spatially heterogeneous closure of stomata in responseto ABA. Alternative explanations for the responses are, however,considered. Key words: Abscisic acid, photosynthesis, osmotic stress, Glycine max, stomatal conductance     

The Influence of Prior Water Stress and Abscisic Acid Foliar Spraying on Stomatal Responses to CO2, IAA, ABA, and Calcium in Leaves of Solanum melongena

The influence of a water stress or foliar ABA spraying pretreatmenton stomatal responses to water loss, exogenous ABA, IAA, Ca²⁺,and CO₂ were studied using excised leaves of Solanum melongena.Both pretreatments increased stomatal sensitivity of water loss,in the presence and absence of CO₂, but decreased stomatal sensitivityto exogenous ABA. CO₂ greatly reduced the effect of exogenouslyapplied ABA. IAA decreased leaf diffusion resistance for controland ABA sprayed leaves, but did not influence the LDR of previouslywater-stressed leaves. CA²⁺ did not influence LDR of any leavesof any treatments. Key words: Water stress, stomatal response, pretreatments     

Genotypic Variation in Leaf Water Potential, Stomatal Conductance and Abscisic Acid Concentration in Spring Wheat Subjected to Artificial Drought Stress

A technique for studying variation in the accumulation of abscisicacid (ABA) in response to drought stress is described. Two experiments,each testing 26 spring wheat genotypes, were carried out usingpot grown plants in controlled environment cabinets with nutrientsolution culture, though the results of only one experimentare described in detail. Plants were subjected to water stressby withholding water as the fifth or sixth leaf on the mainstem was emerging. Two stressed plants of each genotype wereharvested 5 and 7 days after the treatment commenced and measurementsof leaf water potential, stomatal conductance and ABA concentrationwere taken. There was considerable genotypic variation in the rate at whichwater potential decreased, partly explained by variation inplant size. Inia 66 (a genotype common to both experiments)had consistently much lower water potentials than the othergenotypes. Stomatal conductances of all genotypes decreasedrapidly and after 5 and 7 days they were negatively correlatedwith the changes in water potential. ABA concentrations varied considerably between genotypes afterboth 5 and 7 days without water, the variation being associatedwith genotypic differences in water potential on these occasions.The overall relationship between ABA concentration and waterpotential was highly significant. Significant differences betweenthe slopes of the regressions for individual genotypes werefound. The cultivar Sirius accumulated the most ABA at any waterpotential and Pelissier, Wascana and Hybrid 46 accumulated theleast. The significance for drought resistance of variation in ABAaccumulation is discussed. Triticum aestivum L. ABA, wheat, absasic acid, leaf water potential, stomatal conductance     

Changes in Stomatal Conductance in Intact Ageing Wheat Leaves in Response to Abscisic Acid

The characteristics of ABA-induced changes in the fluxes ofCO₂ and water vapour from whole leaves of spring wheat (Triticumaestivum cv. Wembley) were examined. Aqueous solutions of ABAwere supplied via the transpiration stream to intact leavesof different ages mounted within a gas exchange cuvette. ABA caused a reduction in stomatal conductance (g) that wasproportional to the concentration in the solution fed to theleaf. For the maintenance of a reduction in g there was a requirementfor a continual supply of ABA. At concentrations greater than10^–2 mol m^–3 ABA reduced g by at least 50% of thecontrol value, while 1.0 mol m^–3 closed stomata within2 h. Concentrations as low as 10^–3 mol m^–3 produceda 20% reduction in g. As leaves aged they became less responsiveto applied ABA. The possibility that the stomatal response may change aftera leaf has previously experienced a pulse of ABA was exploredby repeating the exposure of a leaf to 10^–2 mol m^–3ABA. The first pulse of ABA produced a greater reduction ing than a subsequent exposure the following day. This declinein response of g to ABA on repeated exposure was maintainedwith leaves of different ages. The characteristics of the stomatal response to ABA are discussedin the context of what is known about the location of receptorsfor the hormone. It seems likely that a failure to respond toABA that has previously accumulated in the guard cells shouldbe viewed by means of maximizing the sensitivity to the currentsupply of ABA. It is suggested that the smaller response ofthe stomata of older leaves to ABA makes them more susceptibleto water stress, so that they can act as sensors for decliningwater potentials to give early protection to younger, metabolicallyactive leaves. Key words: Abscisic acid, leaf age, stomatal conductance, Triticum aestivum     

Heat Shock Proteins of Sorghum [Sorghum bicolor (L.) Moench] and Pearl Millet [Pennisetum glaucum (L.) R.Br.] Cultivars with Differing Heat Tolerance at Seedling Establishment Stage

The production of heat shock proteins was compared in sorghumand pearl millet genotypes differing in seedling establishmentcharacteristics under heat stress. Two major heat shock proteins(hsps) of apparent mol. wt. 65 kD and 62 kD were seen in allthe genotypes of sorghum tested when the incubation temperatureof the 40 h seedlings was altered from 35 ?C to 45 ?C for 2h. Under identical conditions, pearl millet genotypes showedmore hsps and the apparent mol. wt. of these ranged from 30–70kD. The hsp bands were more prominent in whole seedlings androots as compared to plumules. Differences in the productionof hsps were seen in sorghum and pearl millet genotypes withcontrasting heat tolerance at seedling establishment stage butthe significance of these needs to be studied further. Key words: Heat shock proteins, sorghum, genotypic differences     

Regulation of Stem Abscission and Callus Growth in Shoot Explants of Sweet Orange [Citrus sinensis (L.) Osbeck]

Two-node explants from Sweet Orange cv. St Ives Valencia orangeshoots produced prolific callus and formed secondary abscissionzones within internodes when cultured in vitro with abscisicacid (ABA, 5 µM) or -naphthaleneacetic acid (NAA, 5 µM).Benzyladenine (BA, 1 µm) induced callus but had littleeffect on abscission. Secondary abscission zone formation wasassociated with ABA-induced and auxin-induced ethylene formation.Treatment of explants with inhibitors of ethylene synthesis[aminoethoxyvinyl glycine (AVG), Co²⁺, PO₄^3–] preventedformation of secondary abscission zones but had variable effectson callus formation. Newly made explants contained high concentrationsof endogenous ABA (up to 6000 ng g^–1 f.wt), as measuredby GC/MS/SIM. Long-term subculture of explants (two years) inmedia containing BA (1 µm) led to a reduction in endogenousABA level (40 ng g^–1 f. wt) and to loss of capacity toform extensive callus and secondary abscission zones. Citrus sinensis (L.) Osbeck cv. St Ives Valencia, sweet orange, secondary abscission zones, in vitro, ethylene, endogenous ABA, endogenous IAA     

Influence of Exogenous Glycine Betaine and Abscisic Acid on Papaya in Responses to Water-deficit Stress

The effects of exogenous foliar glycine betaine (GB) and abscisic acid (ABA) on papaya responses to water stress were investigated under distinct water regimes. Papaya seedlings (Carica papaya L. cultivar “BH-65”) were pretreated with GB or ABA and subsequently subjected to consecutive periods of drought, rehydration, and a second period of drought conditions. Results indicated that water stress induced ABA, jasmonic acid (JA), and proline accumulation but did not modify malondialdehyde (MDA) concentration. In addition, water deprivation reduced photosynthetic rate, stomatal conductance, relative water content (RWC), leaf fresh weight, and increased leaf abscission. GB applied prior to drought imposition decreased the impact of water stress on ABA, JA, proline accumulation, leaf water status, growth, and photosynthetic performance. However, ABA-pretreated plants did not show alteration of most of these parameters under water stress conditions when compared with non-pretreated plants except a clear induction of JA accumulation. Taken together, the data suggest that GB may modulate ABA, JA, and proline accumulation through the control of stomatal movement and the high availability of compatible solutes, leading to improvement of leaf water status, growth, and photosynthetic machinery function. In contrast, exogenous ABA did not stimulate papaya physiological responses under drought, but interestingly ABA in combination with drought could induce progressive JA synthesis, unlike drought alone, which induces a transitory JA increase and may trigger endogenous ABA accumulation. The data also suggest that irrespective of the pretreatments, papaya did not suffer oxidative damage.     

Senescence-Associated Changes during Long-day-induced Leaf Senescence and the Nature of the Graft-transmissible Senescence Substance in Kleinia articulata

Schwabe, W. W. and Kulkarni, V. J. 1987. Senescence-associatedchanges during long-day-induced leaf senescence and the natureof the graft-transmissible senescence substance in Kleinia articulata.— J. exp. Bot. 38: 1741–1755. The long-day-induced senescence in Kleinia articulata leaveswas characterized by a loss in fresh and dry weight, in therate of leaf expansion and progressive loss of chlorophyll inthe detached rooted leaves. Ultrastructural examination of mesophyllcells of leaves from plants grown in continuous light showedthat osmiophilic globules accumulating in the chloroplasts werethe first visible sign of senescence in the organdies. Thesefirst signs of senescence could be detected in very young leavesof plants in continuous light, even before the leaves had expanded.Attempts were made to study the cause of this photoperiodicsenescence which, from previous work, appeared to involve agraft-transmissible substance. Leaves in continuous light showed reduced stomatal opening andextracts from them had very much higher activity in the Commelinastomatal closure assay (ABA-like activity ?) compared with non-senescingleaves grown in short days (8 h). However, even if all the activitywere due to ABA, this on its own does not appear to be the senescencesubstance because a much longer exposure to continuous lightwas required to induce irreversible senescence than to reachmaximum stomatal closure promoting activity in the bioassay.Moreover, severe water stress (high ABA?) did not lead to senescenceunless combined with continuous light or ethylene treatment.It is postulated that while ABA may play an important role inKleinia leaf senescence its lethal effect may not be realizedunless ethylene-induced membrane changes may synergisticallyassist. Key words: Leaf senescence, ABA, Daylength, stomatal movement, Kleinia     

Comparative Leaf Surface Morphology and the Glossy Characteristic of Sorghum, Maize, and Pearl Millet

Leaf surfaces of seven genotypes of Sorghum bicolor, two ofmaize, Zea mays, and two pearl millet, Pennisetum americanum,were examined by scanning electron microscopy for possible morphologicaldifferences. Leaves 1, 3, 5 and 7 were photographed and printswere used to estimate waxiness, hairiness or pubescence andstomatal density. Glossiness was determined by spraying water,which adhered to the glossy leaves. Cuticular transpirationof detached third and fifth leaves was estimated from the rateof water loss after abscisic acid induced stomatal closure.Sorghum lines SC283, CSM63, CSM90, and pearl millets Souna andTiotioni (all from Mali), were non-glossy, well covered withwax, and exhibited variable hairiness. Older leaves of sorghumvarieties Martin and Redlan were glossy and, like older leavesof the other glossy lines SC1096 and SC90, had little or nowax deposits on their cuticles. The two maize cultivars, NB611and N7A, were non-glossy with dense wax covering; no trichomeswere observed until the 5 to 7 leaf stage. Thus, the glossycharacter was correlated with the reduction or absence of waxdeposits on the leaf surfaces, while hairiness might occur ineither glossy or non-glossy genotypes. Unlike sorghum and maize,in which all leaves after the fifth or seventh were glossy,pearl millet showed no glossiness through the ninth leaf. Measurementsshowed that cuticular transpiration of glossy leaves was oftenmore than double that of non-glossy leaves. Comparisons amongsorghums showed that non-glossy lines had higher stomatal densitiesthan glossy lines. Epicuticular wax, trichome, glossy mutant, stomata, cuticular transpiration, Sorghum bicolor, (L.) Moench, Zea mays L., Pennisetum americanum, (L.) Leeke     

Phenylalanine Ammonia Lyase Activity in Pearl Millet Seedlings and its Relation to Downy Mildew Disease Resistance

Phenylalanine ammonia lyase (PAL) activity was studied in differentgenotypes of pearl millet with varying degrees of susceptibilityto downy mildew disease, after inoculating with Pathotype 1of Sclerospora graminicola. In resistant genotypes, the enzymeactivity significantly increased 24 h after fungal inoculationwhile in the susceptible genotypes, the activity decreased.The increase or decrease in enzyme activity was well-correlatedwith the degree of host resistance to the pathogen. A time-courseof change in activity of PAL after inoculation showed a considerabledifference between resistant and susceptible genotypes. Studieson the activity of PAL in different parts of pearl millet seedlingsrevealed that in the resistant genotype, enzyme activity significantlyincreased at 24 h post-inoculation only in the shoot portion,whereas in mesocotyl and root the activity decreased. In susceptibleseedlings, enzyme activity decreased at 24 h post-inoculationin shoot, mesocotyl and root. The activity of PAL was also foundto be pathotype-specific. Histochemical tests for lignin werepositive in infected cells in the resistant genotypes. The roleof PAL in imparting resistance to pearl millet against downymildew disease is discussed. Key words: Sclerospora graminicola, resistance screening, enzyme activity