Cellular Processes Limiting Leaf Growth in Plants under Hypoxic Root Stress

The effects of root hypoxia on leaf growth of a Populus trichocarpa? deltoides hybrid have been assessed. Clonal plants were subjectedto hypoxic root conditions in pot culture by flooding and insolution culture by gassing with nitrogen. The rate of leafexpansion declined within 8 h and was suppressed for the durationof the treatment. Final leaf size was reduced by 35% to 60%compared to aerated plants. Final epidermal cell size and numberdepended both on the developmental stage of the leaf at theonset of stress and on the duration of the treatment. No differencesin bulk leaf water potential were measured between the hypoxicand aerated plants. Cell wall extensibility was lower, leafsolute potential was more negative and turgor potential washigher in leaves of hypoxia-treated plants than of aerated plants.These data suggest that leaf growth of hypoxia-stressed plantsis limited by cell wall extensibility. The mechanism by whichthe root stress induces changes in leaf cell wall characteristicsis not known. Key words: Populus, flooding     

Effects of Constant and Variable Nitrogen Supply on Sunflower (Helianthus annuus L.) Leaf Cell Number and Size

The effects of nitrogen (N) availability on cell number andcell size, and the contribution of these determinants to thefinal area of fully expanded leaves of sunflower (Helianthusannuus L.) were investigated in glasshouse experiments. Plantswere given a high (N =315 ppm) or low (N=21 ppm) N supply andwere transferred between N levels at different developmentalstages (5 to 60% of final size) of target leaves. The dynamicsof cell number in unemerged (< 0.01 m in length) leaves ofplants growing at high and low levels of N supply were alsofollowed. Maximum leaf area (LA_max) was strongly (up to two-fold)and significantly modified by N availability and the timingof transfer between N supplies, through effects on leaf expansionrate. Rate of cell production was significantly (P<0.05)reduced in unemerged target leaves under N stress, but therewas no evidence of a change in primordium size or in the durationof the leaf differentiation–emergence phase. In fullyexpanded leaves, number of cells per leaf (N_cell), leaf areaper cell (LA_cell) and cell area (A_cell) were significantly reducedby N stress. WhileLA_cell and A_cellresponded to changeover treatmentsirrespective of leaf size, significant (P<0.05) changes inN_cellonly occurred when the changeover occurred before the leafreached approx. 10% of LA_max. There were no differential effectsof N on numbers of epidermal vs. mesophyll cells. The resultsshow that the effects of N on leaf size are largely due to effectson cell production in the unemerged leaf and on both cell productionand expansion during the first phase of expansion of the emergedleaf. During the rest of the expansion period N mainly affectsthe expansion of existing cells. Cell area plasticity permitteda response to changes in N supply even at advanced stages ofleaf expansion. Increased cell expansion can compensate forlow N_cellif N stress is relieved early in the expansion of emergedleaves, but in later phases N_cellsets a limit to this response.Copyright 1999 Annals of Botany Company Helianthus annuus, leaf expansion, leaf cell number, leaf cell size, nitrogen, leaf growth, sunflower.     

Mechanism for increased leaf growth in elevated CO2

The effect of exposure to elevated CO₂ on the processes of leafcell production and leaf cell expansion was studied using primaryleaves of Phaseolus vulgaris L. Cell division and expansionwere separated temporally by exposing seedlings to dim red lightfor 10 d (when leaf cell division was completed) followed byexposure to bright white light for 14 d (when leaf growth wasentirely dependent on cell expansion). When plants were exposedto elevated CO₂ during the phase of cell expansion, epidermalcell size and leaf area development were stimulated. Three piecesof evidence suggest that this occurred as a result of increasedcell wall loosening and extensibility, (i) cell wall extensibility(WEx, measured as tensiometric extension using an Instron) wassignificantly increased, (ii) cell wall yield turgor (V, MPa)was reduced and (iii) xyloglucan endotransglycosylase (XET)enzyme activity was significantly increased. When plants wereexposed to elevated CO₂ during the phase of cell division, thenumber of epidermal cells was increased whilst final cell sizewas significantly reduced and this was associated with reducedfinal leaf area, WEx and XET activity. When plants were exposedto elevated CO₂ during both phases of cell division and expansion,leaf area development was not affected. For this treatment,however, the number of epidermal cells was increased, but cellexpansion was inhibited, despite exposure to elevated CO₂ duringthe expansion phase. Assessments were also made of the spatialpatterns of WEx across the expanding leaf lamina and the datasuggest that exposure to elevated CO₂ during the phase of leafexpansion may lead to enhanced extensibility particularly atbasal leaf margins which may result in altered leaf shape. The data show that both cell production and expansion were stimulatedby elevated CO₂, but that leaf growth was only enhanced by exposureto elevated CO₂ in the cell expansion phase of leaf development.Increased leaf cell expansion is, therefore, an important mechanismfor enhanced leaf growth in elevated CO₂, whilst the importanceof increased leaf cell production in elevated CO₂ remains tobe elucidated. Key words: Phaseolus vulgaris L., dwarf beans, elevated CO², biophysics of cell expansion, xyloglucan endotransglycosylase, XET, water relations     

Slow Leaf Development of Evergreen Broad-leaved Tree Species in Japanese Warm Temperate Forests

Rates of light-saturated net photosynthesis (P_Nmax) and darkrespiration (Rd) on a leaf area basis, leaf dry mass per area(LMA), leaf nitrogen content on a leaf area basis (LNa) andinstantaneous nitrogen use efficiency (NUE=P_Nmax/LNa) were followedduring leaf development in six evergreen broad-leaved tree speciestypical of warm-temperate forests in Japan. These species wereCastanopsissieboldii, Quercus myrsinaefolia, Quercus glauca, Machilus thunbergii,Cinnamomum japonicumandNeolitsea sericea.When expansion of leafarea was complete, P_Nmax was about one third of its peak valueand increased for another 15 to 44 d. Rd at full leaf expansionwas about 1.5 to 3.5-times greater than steady-state rates.These facts suggest that leaf development was still underwayat the time of full leaf area expansion. Low P_Nmax at full leafexpansion was caused both by low leaf nitrogen content and lowNUE. P_Nmax increased with the increase in LMA during leaf developmentin all six species; data from the literature for other specieswith different life forms also indicated a similar tendency.The steady-state LMA varied markedly among species. Becauseleaves with larger steady-state LMAs need more resources fortheir construction, they will also need longer periods for maturation.We hypothesized that the period required for the attainmentof peak P_Nmax, the ‘leaf maturation period’, dependson the steady-state LMA. Plotting data from the present studytogether with those from literature for other plants acrossseveral life forms showed a strong positive relationship betweenleaf maturation period and steady-state LMA, supporting thehypothesis.Copyright 1998 Annals of Botany Company. Castanopsis sieboldii, Cinnamomum japonicum,delayed period, expansion period, full leaf expansion,Machilus thunbergii,maturation period,Neolitsea sericea, Quercus glauca, Quercus myrsinaefolia,steady-state LMA.     

Loss of capacity for acid-induced wall loosening as the principal cause of the cessation of cell enlargement in light-grown bean leaves

Cell enlargement in primary leaves of bean (Phaseolus vulgaris L.) can be induced, free of cell divisions, by exposure of 10-d-old, red-light-grown seedlings to white light. The absolute rate of leaf expansion increases until day 12, then decreases until the leaves reached mature size on day 18. The cause of the reduction in growth rate following day 12 has been investigated. Turgor calculated from measurements of leaf water and osmotic potential fell from 6.5 to 3.5 bar before day 12, but remained constant thereafter. The decline of growth after day 12 is not caused by a decrease in turgor. On the other hand, Instron-measured cell-wall extensibility decreased in parallel with growth rate after day 12. Two parameters influencing extensibility were examined. Light-induced acidification of cell walls, which has been shown to initiate wall extension, remained constant over the growth period (days 10–18). Furthermore, cells of any age could be stimulated to excrete H⁺ by fusicoccin. However, older tissue was not able to grow in response to fusicoccin or light. Measurements of acid-induced extension on preparations of isolated cell walls showed that as cells matured, the cell walls became less able to extend when acidified. These data indicate that it is a decline in the capacity for acid-induced wall loosening that reduces wall extensibility and thus cell enlargement in maturing leaves.Abbreviations and symbols FC fusicoccin - P turgor pressure - RL red light - WEx wall extensibility - WL white light - P _w leaf water potential - P _s osmotic potential     

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     

Role of acid efflux during growth promotion of primary leaves of Phaseolus vulgaris L. by hormones and light

The white-light-(WL) induced enlargement of dicotyledonous leaf cells is known to occur via an acid-growth mechanism; i.e., WL causes leaf cells to excrete protons which lead to an increase in wall extensibility and thus cell enlargement. Gibberellic acid (GA₃) and N⁶-benzyladenine (BA) also induce leaf cell enlargement. To see if they also act via acid-induced cell wall loosening, a comparison has been made of WL-, GA₃-and BA-induced growth of strips, taken from primary leaves of bean (Phaseolus vulgaris L.) plants raised in continuous red light for 10 d. White light, GA₃ and BA all increased wall extensibility as measured by the Instron technique, and this change preceded the increase in growth rate. However, whereas WL induced significant proton excretion, neither GA₃ nor BA caused any acidification of the apoplast. Furthermore, neutral buffers, which effectively inhibited the growth induced by WL, were without effect on growth promoted by either GA₃ or BA. These results indicate that while WL, GA₃ and BA all initiate growth in bean leaves by altering cell-wall properties, GA₃ and BA do so through some wall loosening mechanism other than wall acidification. Neither gibberellin nor cytokinin is likely to play a major role in light-induced cell enlargement of dicotyledonous leaves.Abbreviations BA N^o-benzyladenine - FC fusicoccin - GA₃ gibberellic acid - RL red light - SK medium 10 mM sucrose+10mM KCl - WL white light     

The Relation Between the Nitrogen Concentration and Photosynthetic Capacity of Potato (Solanum tuberosum L.) Leaves

Measurements of the rate of light-saturated photosynthesis (P_max)were made on terminal leaflets of potato plants growing in cropssupplied with 0, 3, 6, 12, 24 and 36 g N m^–2. Measurementswere made between 100 and 154 d after planting. Two types ofleaf were selected—the fourth leaf on the second-levelbranch (L₄, _B1) and the youngest terminal leaflet that was measurable(L_YM). Later, the total nitrogen concentration of each leaflet(N_L) was measured. A linear regression between P_max and N_L,common to both leaf positions, explained 68.5% of the totalvariation. With L₄, _B1 leaves there was a significant improvementin the proportion of variation explained when regressions withseparate intercepts and a common slope were fitted to individualfertilizer treatments. These results suggest that an increasingproportion of leaf nitrogen was not associated with the performanceof the photosynthetic system with increasing nitrogen supply.This separation between nitrogen treatments was not as clearfor L_YM leaves. Stomatal conductance to transfer of water vapourwas neither influenced by leaf position nor directly by nitrogensupply. Rather conductance declined in parallel with the declinein photosynthetic capacity. Solanum tuberosum, potato, nitrogen, photosynthesis, stomatal conductance, leaf     

Salinity Stress Inhibits Bean Leaf Expansion by Reducing Turgor, Not Wall Extensibility

Treatment of bean (Phaseolus vulgaris L.) seedlings with low levels of salinity (50 or 100 millimolar NaCl) decreased the rate of light-induced leaf cell expansion in the primary leaves over a 3 day period. This decrease could be due to a reduction in one or both of the primary cellular growth parameters: wall extensibility and cell turgor. Wall extensibility was assessed by the Instron technique. Salinity did not decrease extensibility and caused small increases relative to the controls after 72 hours. On the other hand, 50 millimolar NaCl caused a significant reduction in leaf bulk turgor at 24 hours; adaptive decreases in leaf osmotic potential (osmotic adjustment) were more than compensated by parallel decreases in the xylem tension potential and the leaf apoplastic solute potential, resulting in a decreased leaf water potential. It is concluded that in bean seedlings, mild salinity initially affects leaf growth rate by a decrease in turgor rather than by a reduction in wall extensibility. Moreover, longterm salinization (10 days) resulted in an apparent mechanical adjustment, i.e. an increase in wall extensibility, which may help counteract reductions in turgor and maintain leaf growth rates.     

Growth and Senescence of the Successive Leaves on a Cocksfoot Tiller. Effect of Nitrogen and Cutting Regime

The effects of nitrogen supply and cutting regime on the morphologicalcharacteristics (leaf appearance and expansion rates, leaf growthduration, leaf lifespan) of a cocksfoot sward were studied overthree growing seasons to gain a better understanding of thechanges in tiller characteristics (length and age of laminae,number of leaves per tiller) over time and in different seasons.We show that, for a given regrowth, the lamina expansion rateat the tiller level depended on herbage nitrogen status, butthe time course of its components differed according to nitrogensupply. When nitrogen was supplied, leaf appearance was fasterbut also decreased faster. In other words, the length of successivelaminae increased faster when nitrogen was supplied. The samewas true for the growth duration of the laminae and their lifespan.These changes resulted from the length of the sheaths from whichthe successive laminae emerged. As nitrogen increased cell number,it changed the ratio of lamina length_n+1/sheath length_nmorethan the ratio lamina length_n/sheath length_nat the same insertionlevel. Therefore sheath length increased faster and leaf appearancedecreased faster when nitrogen was supplied. This finding helpsto explain the effects of different heights and frequenciesof cutting in terms of their effects on sheath length. Copyright2000 Annals of Botany Company Nitrogen, defoliation, cocksfoot, sheath     

Proton excretion and cell expansion in bean leaves

Light-induced expansion of Phaseolus vulgaris L. leaf cells is accompanied by increased cell-wall plasticity. The possibility that leaf-cell walls are loosened by excreted protons has been investigated. First, light causes acidification, detected at the leaf surface, within 5–15 min. Growth starts 10–20 min after exposure to light. Second, exogenous acid induces loosening of isolated leaf cell walls. Third, infiltration of the tissue with a neutral buffer inhibits light-induced growth. Fourth, fusicoccin stimulates growth of as well as H⁺ excretion by bean leaf cells, without light. These findings show that the acid-growth theory is applicable to light-induced growth of leaf cells, and indicate that light-induced proton excretion initiates cell enlargement in leaves.Abbreviations FC fusicoccin - RL red light - WEx wall extensibility - WL white light     

Gibberellic Acid Regulates Cell Wall Extensibility in Wheat (Triticum aestivum L.)

Mutations (Rht genes) blocking sensitivity to gibberellic acid (GA) were used to examine phytohormone mediated cell wall expansion in wheat (Triticum aestivum L.). Irreversible extensibility of immature leaf segments, as determined by stress/strain (instron) measurements, declined with Rht gene dose. Exogenous GA₃ significantly increased wall extensibility in the nonmutant controls but had no effect on the near-isogenic GA-insensitive genotypes. Furthermore, ancymidol, an inhibitor of gibberellin biosynthesis, diminished wall extensibility in the nonmutant control. Extensibility of immature segments was highly correlated with mature leaf sheath length (R = +0.95). The results indicate that wall yielding properties of expanding wheat leaves are associated with leaf cell expansion potential and that GA is involved in the determination of those properties.     

The Influence of Water Deficit on the Factors Controlling the Daily Pattern of Growth of Phaseolus Trifoliates

Phaseolus seedlings were grown in liquid culture under controlledtemperature and irradiance and measurements were made of dailyvariation in growth of the first trifoliate leaves. Leaf growthrate was significantly enhanced within a few hours of the startof the light period. Over a similar time, a small decrease inleaf turgor and an increase in cell wall plasticity were recorded.Slowly declining growth rates as the light period progressedmay have been caused by decreases in turgor during this time.When water availability to the leaves was restricted by growingthe plants for several days in nutrient solution maintainedat a low temperature (12°C), the daily pattern of growthof the trifoliates was changed quite markedly. Dark-growth rateswere slightly enhanced, while light-growth rates were significantlyreduced when compared to growth rates of plants well-suppliedwith water (roots at 20°C). Relative ‘plateau’growth rates of plants well-supplied (ww) with water or sufferinga restricted supply (ws) in the light (L) and in the dark (D)were as follows: ww L > ws D > ww D > ws L. In thelight, turgors of the two groups of plants were similar, suggestingthat the reduced growth rate of the cooled plants resulted froma change in cell wall structure and/or properties. Immediatelybefore the lights were switched on, plants grown with a restrictedwater supply showed relatively high turgors in the trifoliatesand these were presumably responsible for the enhanced growthrates at this time. Restriction of water availability may haveslightly increased the plasticity of cell walls and decreasedthe yield threshold for growth. The control of leaf growth inplants developing water deficit is discussed. Key words: Leaf growth turgor, Cell wall plasticity, Water deficit, Light     

Phytochrome-regulated Expansion of Mustard (Sinapis alba L.) Cotyledons

In developing mustard (Sinapis alba L.) seedlings continuousred light acting via the agency of phytochrome stimulates therate of expansion of cotyledons. Although phytochrome actionon cotyledon expansion is evident only after 36 h from sowing,the photoresponse escapes from reversibility at about 15 h fromsowing. The time lag of 21 h between loss of photoreversibilityand the onset of photoregulated cotyledon expansion indicatesthe existence of long-lived components in the phytochrome-triggeredsignal chain. Phytochrome-regulated cotyledon expansion doesnot require the involvement of photosynthesis, as applicationof SAN 9789, an inhibitor of chloroplast biogenesis, did notaffect cotyledon expansion. The role of turgor pressure-relatedcellular parameters such as osmotic potential () cell wall extensibility(m), hydraulic conductivity (L) and yield threshold (Y) forcell expansion were examined during photoregulated cotyledonexpansion. Using the general equation of cell growth dv/dt =[Lm/(L+m)]( - Y), where dv/dt is the rate of volumetric growth,it was demonstrated that the light-mediated cotyledon expansionresults from an increase in cell wall extensibility (m). Theseresults are discussed in relation to the photoregulation ofcotyledon expansion. Key words: Cell wall extensibility, growth, Sinapis alba L., phytochrome     

Physiological disturbances caused by high rhizospheric calcium in the calcifuge Lupinus luteus

A detailed study of the calcifuge Lupinus Iuteus L. (yellowlupin) has been carried out in an attempt to explain its poorperformance in the presence of high concentrations of rhizosphenccalcium. Plants were grown on two different calcium regimes,1 or 15 mol m^– Ca and, after an establishment period,measurements were made of the rate of leaf extension, finallength of the leaflets and the leaf gas exchange. In addition,the distribution of calcium within the leaf tissue was investigated. At 15 mol m^–3 Ca, leaflet length at full expansion wasreduced as a consequence of reduced extension rate and a declinein cell wall extensibility. Transpiration in excised leaves,assayed gravimetrically, was significantly reduced in plantsgrown in high calcium. Similar results were also obtained fromgas exchange measurements. Analysis of A/C, curves indicatedthat in plants grown in high [Ca] there was a substantial reductionin net assimilation over a range of concentrations of CO₂ X-raymicroanalysis revealed that a large amount of cal cium deliveredin the xylem sap is retained in the mesophyll tissue, and mostof that reaching the epidermal tissue is not found in the guardcells but in the cells adjacent to them, which in this speciesare not anatomically distinct as ‘subsidiary’ cells. Key words: Calcium, calcifuge, Lupinus luteus, stomata, leaf growth     

Effects of soil resistance to root penetration on leaf expansion in wheat (Triticum aestivum L.): kinematic analysis of leaf elongation

Wheat leaves (Triticum aestivum L.) elongated 50% more slowlywhen plants were grown in soils with high mechanical resistanceto penetration (R_s. The profiles of epidermal cell lengths alongthe growth zone of expanding leaves and the locations of newlyformed walls were recorded in order to compare the kineticsof elongation and partitioning of both meristematic and non-meristematiccells. In leaf 5, which completely developed under stress, highR_s, did not affect the flux of mature cells through the elongationzone; leaf elongation was reduced only because these cells wereshorter. This reduced size reflected a reduction in cell lengthat partitioning, associated with shorter cycling time. The relativerates of cell elongation before and after partitioning wereunchanged. Cell fluxes were similar because the population ofmeristematic cells was reduced, offsetting their increased partitioningrate. In contrast, in leaf 1, high R_s, had no effect on thenumber of dividing cells; elongation rate was reduced becauseof slower relative cell expansion rate and slower cell partitioningrate. These differences could reflect differences in the stageat which successive leaves perceived root stress and also time-dependentchanges in the responsiveness of leaf development to stress-inducedroot signals or in the nature of these signals. The data reveal that cell cycling time may in fact be decreasedby unfavourable growth conditions and is not directly relatedto cell expansion rates; they also show that the elongationrate of meristematic cells is partly independently controlledfrom that of non-meristematic cells. Key words: Wheat, kinematics of leaf expansion, cell partitioning, cell elongation, root impedance     

Cessation of cell elongation in rye coleoptiles is accompanied by a loss of cell-wall plasticity

The mechanism by which endogenous cessation of coleoptile elongationafter emergence of the primary leaf is brought about was investigatedin rye seedlings (Secale cereale L.) that were either grownin darkness or irradiated with continuous white light. In 3-d-oldetiolated (growing) coleoptiles a turgor pressure of 0.59 MPawas measured. In 6-d-old coleoptiles, which had ceased to elongate,cell turgor was 0.51 MPa and thus only 13% lower than in therapidly growing organ. Hence, the driving force for growth (turgor)is largely maintained. Cell-wall plasticity (E_pl) and elasticity(E_Ql were determined with a constant load extensiometer bothin vivo (turgid coleoptile segments) and in vitro (frozen-thawedsamples). Cessation of coleoptile elongation was correlatedwith a 95% reduction in E_pl9 whereas E_Ql was only slightly affected.Extension kinetics were measured with living and frozen-thawedsegments cut from growing and non-growing coleoptiles. The correspondingstress-strain (load-extension) curves indicate that the cellwall of the growing coleoptile behaves like an elastic-plasticmaterial whereas that of the non-growing organ shows the behaviourof an elastic solid. These data demonstate that E_pl representsa true plastic (irreversible) deformation of the cell wall.It is concluded that cessation of coleoptile growth after emergenceof the primary leaf is attributable to a loss of cell-wall plasticity.Hence, a mechanical stiffening of the cell wall and not a lossof turgor pressure may be responsible for the deceleration ofcell elongation in the rye coleoptile. Key words: Extension growth, rye coleoptile, cell-wall extensibility, turgor pressure     

Water-stressed maize, barley and rice seedlings show species diversity in mechanisms of leaf growth inhibition

The possible occurrence of species diversity in mechanisms underlying leaf-growth inhibition by water stress, was investigated in related cereal plants. Water stress was generated by additions of the osmoticum polyethylene glycol 6000 to the root medium. Effects of external water potentials ranging from 0 to -0.6MPa, on early growth parameters of emerging leaves were measured under controlled environment conditions, using pairs of maize, barley or rice genotypes with differing resistance to water stress under field conditions. Water potentials of -0.4 MPa for 24 h, similarly reduced leaf growth, comparative production rates of leaf epidermal cells and cell size in all genotypes. These reductions did not appear to be caused by reductions in the osmotic potential gradients between the expanding leaf cells and their external water source. However, growth inhibition in maize and barley, was accompanied by significant reductions in comparative leaf and cell wall extensibility. Moreover, regression plots revealed good linear correlations (r=0.83** for maize and r=0.77** for barley) between the reductions in leaf growth induced by a series of water potentials and associated reductions in leaf extensibility. In contrast, the reduction in growth of rice leaves, was not accompanied by any significant changes in leaf or cell wall extensibility. Similarly, regression plots revealed poor correlations between leaf growth and leaf extensibility in both paddy and upland rice (r=0.17 and r=0.07, respectively). Thus, despite numerous inter-species similarities, biophysical changes associated with stress-induced leaf growth inhibition in maize and barley, differed from those in rice.Key words: Cell walls, extensibility, water stress, cereal diversity, leaf growth.      

Inhibition of Light-Stimulated Leaf Expansion by Abscisic Acid

Abscisic acid (ABA) applied to intact bean (Phaseolus vulgaris)leaves or to isolated leaf discs inhibits light-stimulated cellenlargement This effect may be obtained with 10^–4 molm^–3 ABA, but is more significant at higher concentrations.The inhibition of disc expansion by ABA is greater for discsprovided with an external supply of sucrose than for discs providedwith KC1, and may be completely overcome by increasing the KC1concentration externally to 50 mol m^–3. Decreased growthrate of ABA-treated tissue is not correlated with loss of solutesfrom growing cells, but is correlated with a decrease in cellwall extensibility. ABA does not prevent light-stimulated acidificationof the leaf surface, and stimulates the acidification of theexternal solution by leaf pieces. However, the capacity of thecell walls to undergo acid-induced wall loosening is diminishedby ABA-treatment. The possibility that ABA acts directly byinhibiting growth processes at the cellular level, or indirectlyby causing stomatal closure, is discussed. Key words: Phaseolus vulgaris, ABA, Inhibition, Leaf expansion     

The role of apical development around the time of leaf initiation in determining leaf width at maturity in wheat seedlings (Triticum aestivum L.) with impeded roots

High soil resistance to root penetration (measured as penetrometerresistance, R_s slows down leaf growth and reduces mature leafsize in wheat seedlings {Triticum aestivum L.). Underlying changesin the kinetics of cell partitioning and expansion and in thesize and organization of mature cells were reported in companionpapers (Beemster and Masle, 1996; Beemster et al., 1996). Inthe present study, the relationships between apex growth, primordiuminitiation and expansion were analysed for plants grown at contrastingR_s, focusing on a leaf whose whole development proceeded afterthe onset of root impedance (leaf 5). High R_s reduced the rates of apex and leaf development, butdid not appear to have immediate effects on the pattern of developmentof the newly initiated phytomers. During an initial short period,the rate of development of a leaf primordium and associatednode were related to plastochronic age, according to similarrelationships (slopes) at the two R_s. Effects on developmentalpatterns were first detected on phytomer radial expansion duringplastochron 2. The ontogenetic pattern of leaf elongation wasaffected later, during the next few plastochrons preceding leafemergence (‘post-primordial stage’). It is concludedthat a reduction in the number of formative divisions and inthe number of proliferative cells along the intercalary mer-istemreported earlier (Beemster and Masle, 1996; Beemster et al.,1996) is not related to the size of the apical dome at leafinitiation nor to the size and number of meristematic cellsinitially recruited to the leaf primordium, which were all unaffectedby R_s. Rather they are generated at the primordial and post-primordialstages. Key words: Wheat, apex development, leaf primodium development, mature leaf width, root impedance