Interacting Effects of Light and Day and Night Temperatures on the Growth of Four Species in the Vegetative Phase

A comparative examination has been made under controlled conditionsof the interacting effects on growth in the vegetative phasewhich takes place when the diurnal temperature is either maintainedconstant at 20 and 25 ?C or reduced at night by 5 and 10 ?Cand the plants subjected daily to either 2.16 or 4.32 ? 10⁴lx for 14 h. For each species (Gossypium hirsutum, Hclianthusannuus, Phaseolus vulgaris and Zea mays) the changes in netassimilation rate, the leaf area ratio and the relative growthrates in plant weight and leaf area were recorded. Contrary to some previous findings, none of these componentsof growth are favoured by cool nights. Rather such reductionsin temperature retard the growth processes to a varying degreeaccording to the species and the component. In general, significantreductions are more evident for the two relative growth rateswhen a drop from 20 to 10 ?C is combined with the lower levelof illumination. The implications of these results are considered in relationto a prior study where for similar light conditions the samespecies plants were subjected to constant temperatures rangingfrom 10 to 25 ?C.     

Growth Rates and Carbohydrate Fluxes within the Elongation Zone of Tall Fescue Leaf Blades

Investigations were performed to better understand the carbon economy in the elongation zone of tall fescue leaf blades. Plants were grown at constant 21°C and continuous 300 micromoles per square meter per second photosynthetic photon flux density where leaf elongation was steady for several days. Elongation occurred in the basal 20 mm of the blade (0-20 millimeters above the ligule) and was maximum at 9 to 12 millimeters. Eight 3-millimeter long segments were sampled along the length of the elongation zone and analyzed for water-soluble carbohydrates. Sucrose concentration was high in the zone of cell division (0-6 millimeters) whereas monosaccharide concentration was high at and distal to the location where cell elongation terminated (20 millimeters). Fructan concentration increased in the basal part, then remained constant at about 85% of the total mass of water-soluble carbohydrates through the remainder of the elongation zone. Data on spatial distribution of growth velocities and substance contents (e.g. microgram fructan per millimeter leaf length) were used to calculate local net rates of substance deposition (i.e. excess rates of substance synthesis and/or import over substance degradation and/or export) and local rates of sucrose import. Rates of sucrose import and net deposition of fructan were positively associated with local elongation rate, whereas net rates of sucrose deposition were high in the zone of cell division and those of monosaccharide were high near the termination of elongation. At the location of most active elongation imported sucrose (29.5 milligrams per square decimeter per hour) was used largely for synthesis of structural components (52%) and fructan (41%).     

Time Lapse Analysis of Root Elongation Rates of Rice and Sorghum During the Day and Night

This paper describes a technique to monitor the root elongationrate (RER) per hour for several days, and variation in RER duringthe day and night. Rice (Oryza sativaL.) and sorghum (SorghumbicolorMoench) were grown in root boxes placed inside a growthchamber set at 25 °C with a 12 h photoperiod. Seminal rootaxes were sandwiched between a transparent acrylic board andfilter paper placed on a loamy sand soil. The roots were photographedunder dim green light using a CCD camera connected to a timelapse video recorder. The environment of the root, includingtemperature, light, nutrient, water and air supply, was controlledprecisely and maintained constant. RER fluctuated hourly insorghum and to a greater extent in rice. Maximum RERs were 1.4to 4.4 times faster than minimum rates. RERs during the dayand night did not differ statistically when temperatures werethe same.Copyright 1998 Annals of Botany Company Oryza sativaL., periodicity, root elongation,Sorghum bicolorMoench, time lapse.     

种植密度对两种穗型小麦品种分蘖期茎蘖生理特性的影响

选用分蘖成穗率不同的2种穗型冬小麦品种,通过3个密度水平大田试验研究了分蘖期主茎和不同蘖位分蘖间的干物质积累与光合特性的差异,以探讨2种穗型品种分蘖成穗的生理机制.结果显示:(1)在冬小麦分蘖期间,分蘖成穗率低的大穗型品种'兰考矮早八'高位分蘖干物质积累速率较慢,分蘖与主茎的差距较大;而分蘖成穗率高的多穗型品种'豫麦49-198'分蘖与主茎的干物质积累速率差距较小.(2)2品种分蘖与主茎干物重比值(蘖/茎)均随着种植密度增加而降低,成穗分蘖的蘖/茎值拔节期均大于0.5,而同期未成穗分蘖均低于0.5.(3)在分蘖期间,'兰考矮早八'分蘖的净光合速率随生育进程增长比主茎缓慢,且随密度增加分蘖与主茎的差距进一步加大;'豫麦49-198'分蘖与主茎的光合速率差异较小,且种植密度对其影响也较小.(4)拔节中前期种植密度对2品种的荧光参数影响较小,拔节后期2品种分蘖的初始荧光(F0)均显著大于主茎,而PSⅡ最大光化学效率(Fv/Fm)却显著低于主茎;随种植密度增加,2品种主茎与分蘖的F0和Fv/Fm差异增大,且这种趋势随蘖位上升表现得更加明显.研究表明,大穗型品种'兰考矮早八'拔节期主茎与分蘖间干物质积累和光合性能的差异过大是其分蘖成穗率低的主要原因.     

Specific Leaf Weight in Zones of Cell Division, Elongation and Maturation in Tall Fescue Leaf Blades

Patterns of change in specific leaf weight (SLW), water-solublecarbohydrate (WSC) content and leaf width were used to delineatethe region of secondary cell wall accumulation, and determinethe rate of increase in structural material along a developingleaf blade of tall fescue (Festuca arundinacea Schreb.). Structuralspecific leaf weight (SSLW) was determined by subtracting WSCmass from dry weight to emphasize structural material. Becausemeristematic activity, cell elongation, and cellular maturationare arranged successively in the grass leaf, these patternsrepresent a developmental sequence through which each segmentof the leaf blade passes. Patterns were generally similar fortwo genotypes, one selected for high (HYT) and the other forlow (LYT) yield per tiller, for a single genotype grown at 17or 25 C, and for two field-grown populations which differedin leaf area expansion rate (LAER). In all three studies, the elongation zone of the developingleaf had 31 to 39 per cent WSC on a dry weight basis. The LYTgenotype had a higher SLW at all stages of development whengrown at 17 than at 25 C, due to greater WSC accumulation.At 20 C, the HYT genotype had a higher SLW all along the elongatingleaf blade than the LYT genotype. This difference was due toa difference in SSLW, while WSC content was similar. The LERwas 64 per cent higher in the high population than the low,but elongation zones were similar in WSC. In all cases, SSLWwas high in the meristematic region, lowest near the distalend of the cell elongation zone, then increased linearly astissue matured. Rate of increase in SSLW was 8.5 and 5.2 g m^–2d^–1 for the HYT and LYT genotypes, respectively, and 7.6and 6.7 g m^–2 d^–1 for the high and low LAER populations,respectively. Festuca arundinacea Schreb., tall fescue, specific leaf weight, leaf width, water-soluble carbohydrates, leaf elongation rate     

Water Potential and Leaf Elongation in Radiata Pine and Wheat

The rate of leaf elongation in radiata pine (Pinus radiata) and wheat seedlings was closely related to the osmotic potential of the rooting solution. Sudden stress application and removal treatments caused immediate changes in the leaf elongation rate and a new steady-state rate independent of the old was quickly established. The osmotic potential in the active elongation zones of a leaf differed from that of the remainder of the leaf and was considered more appropriate for deriving turgor pressure to be related to leaf elongation. Shifts in elongation rate were associated with corresponding shifts in total leaf water potential in both species and with corresponding shifts in turgor pressure in wheat. There was a linear correlation between the pitch of the helical thickenings in the protoxylem of radiata pine needles and their elongation rate. A record of elongation rate is, therefore, preserved in the needle. Developmental aspects of the deposition of the helix are discussed.     

Nitrogen Effects on Leaf Anatomy within the Intercalary Meristems of Tall Fescue Leaf Blades

Longitudinal elongation contributes most to leaf area expansionof grasses and its rate is known to be strongly affected byN. Our objective was to determine the effect of two N regimes(N₀and N+) on the gradient of leaf tissue formation in meristemsof two contrasting tall fescue (Festuca arundinacea Schreb.)genotypes. Proportions of epidermal, mesophyll and vasculartissue as well as intercellular air space were determined throughoutthe base of actively elongating leaves. The area of leaf transversesections nearly doubled between the ligule and the distal endof the growth zone (about 30 mm), and was mainly associatedwith lateral epidermal and mesophyll cell division in the proximal5.0–7.5 mm. Further increase in transverse area was dueto the formation of intercellular airspace and transverse expansionof epidermal cells. Depending on genotype and N treatment themesophyll, epidermis, vascular bundles and air space comprised45–54%, 20–28%, 6–9%, and 17–21%, respectively,of transverse leaf area in the distal part of the growth zone.After a slight increase close to the leaf base, the area ofvascular tissue remained constant throughout the growth zone.The proportion of air space to mesophyll space was higher atN₀than at N+ because mesophyll area was enhanced by N+ to agreater degree than by N₀. In the genotype with slow leaf elongation,the increase in cross-sectional leaf area was due to an increasein both leaf width and leaf thickness. In the genotype whichhad faster leaf elongation and wider leaves, only leaf thicknesswas enhanced by N+. Copyright 2001 Annals of Botany Company Festuca arundinacea(Schreb.), tall fescue, leaf anatomy, growth zone, nitrogen     

Thermo- and Photoperiodicity and Involvement of Gibberellins during Day and Night Cycle on Elongation Growth of Begonia x hiemalis Fotsch

The effects of thermo- and photoperiodicity on elongation growth and on endogenous level of gibberellins (GAs) in Begonia x hiemalis during various phases of the day-night cycle have been studied. Plant tissue was harvested during the day and night cycle after temperature and photoperiodic treatments and analyzed for endogenous GAs using combined gas chromatography and mass spectrometry. Elongation growth increased when the difference between day and night temperature (DIF = DT − NT) increased from a negative value (−9.0 and −4.5°C) to zero and with increasing photoperiod from 8 to 16 h. When applied to the youngest apical leaf, gibberellins A₁, A₄, and A₉ increased the elongation of internodes and petioles. GA₄ had a stronger effect on elongation growth than GA₁ and GA₉. In relative values, the effect of these GAs decreased when DIF increased from −9 to 0°C. The time of applying the GAs during a day and night cycle had no effect on the growth responses. In general, endogenous levels of GA₁₉ and GA₂₀ were higher under negative DIF compared with zero DIF. The level of endogenous GA₁ in short day (SD)-grown plants was higher under zero DIF than under negative DIF, but this relationship did not appear in long day (LD)-grown plants. The main effects of photoperiod seem to be a higher level of GA₁₉ and GA₁ at SD compared with LD, whereas GA₂₀ and GA₉ show the opposite response to photoperiod. No significant differences in endogenous level of GA₁, GA₉, GA₁₉, and GA₂₀ were found for various time points during the diurnal day and night cycle. Endogenous GA₂₀ was higher in petiole and leaf compared with stem, whereas there were no differences of GA₁, GA₉, and GA₁₉ between plant parts. No clear relationship was found between elongation of internodes and petioles and levels of endogenous GAs. Received December 26 1996; accepted July 1, 1997     

The Effects of Dwarfing Genes Rht1 and Rht2 on Cellular Dimensions and Rate of Leaf Elongation in Wheat

The gibberellin insensitivity genes, Rht1 and Rht2, reducedepidermal cell lengths in leaves of isogenic lines of field-and laboratory-grown wheat (Triticum aestivum L.). Rht dosagesof zero (wild type), two (semi-dwarf) and four alleles (doubledwarf) had a linear negative effect on cell length in flag leavesof field-grown plants, and in the sheaths and blades of leafnumber 1 in laboratory grown plants. Decrease in cell length,rather than reduced cell number, accounted for most to all ofthe reduction in blade and sheath length. In sheaths, cell widthincreased with Rht dosage, but not sufficiently to compensatefor decreased length in determining average projected surfacearea. Rates of extension of leaf number 1 in laboratory-grownplants were negatively and linearly correlated with Rht dosage.Maximal growth rate was maintained longer in wild type thanin double dwarf, but the total duration of measurable extensionin leaf number 1 was not affected by Rht dosage. Cell size, elongation, Rht, wheat, Triticum aestivum L     

Variations of ADPglucose Pyrophosphorylase Activity from Maize Leaf during Day/Night Cycle

ADPglucose pyrophosphorylase activity (measured in the directionof glucose-IP synthesis) from adult maize leaves was shown topresent diurnal variations in activity which were not relatedto the starch accumulation rate. Extractable ADPG-PPase activitywas maximum at the end of the dark period and for the first8 hours in the light. Subsequently, ADPG-PPase activity progressivelydeclined to half the initial value, by the end of the day. Ashort 1 hour-dark period during the day may transiently reversethe inhibition. Experiments with excised leaves placed on sucroseor sorbitol solution further showed that the magnitude of ADPG-PPaseinhibition was related to high leaf sucrose and starch contents.The differences in activity were not due to changes in the quantityof ADPG-PPase protein as shown by immunodot and immunoprecipitationtechniques nor to the differential response of the mesophylland bundle sheath isoforms nor to a time-dependent susceptibilityof the enzyme to proteolysis. Thus, changes in ADPG-PPase specificactivity were inferred. A search for in vivo phosphorylationof the protein was proved negative, whatever the light or darkpre-treatment which modified the ADPG-PPase activity. The differencebetween the 7:00 (morning) and 21:00 (evening) forms was alsoobserved when activity was measured by formation of ADPglucose(the physiological direction) in presence or absence of PGA,as activator. The two forms retained different activity upongel filtration. (Received December 27, 1993; Accepted May 25, 1994)     

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     

Differential Effects of Day and Night Temperature on Development to Flowering in Rice

There are conflicting reports with regard to difference in effectsof day temperature (T_D) and night temperatures (T_N) on plantdevelopment. The objective of this study is to determine whetherthere are different effects ofT_DandT_Non development from sowingto flowering in rice (Oryza sativaL.). Plants of 24 rice cultivars were grown in naturally-lightedgrowth chambers at five diurnally constant (22, 24, 26, 28 and32 °C) and four diurnally fluctuating temperatures (26 /22,30 /22, 22 /26 and 22 /30 °C forT_D/T_Nwith 12hd^-1each) witha constant photoperiod of 12hd^-1. The treatments were selectedto enable the separation of effects ofT_DandT_Non developmentrate (DR). The response of DR to constant temperatures was typically nonlinear.This nonlinearity could not explain the difference in floweringdates between fluctuating temperatures with the same mean dailyvalue but oppositeT_D/T_Ndifferences. Differential effects ofT_DandT_NonDR to flowering were detected in all but one cultivar. In mostcases,T_Dexerted a greater influence thanT_N, in contrast withmany previous reports based on the assumption of a linearitybetween DR and temperature. The data were further analysed bya nonlinear model which separated effects ofT_DandT_N. The estimatedvalue for the optimumT_Nwas generally 25 –29 °C, about2 –4 °C lower than the estimated optimumT_Din mostcultivars. The effects ofT_DandT_Non DR were found to be interactivein some cultivars. These results form a new basis for modellingflowering dates in rice. Oryza sativa; rice; flowering; development; day and night temperature; thermoperiodicity     

Nitrogen Metabolism of the Upper Three Leaf Blades of Wheat at Different Soil Nitrogen Levels

Upper three leaf blades on the mainshoot of wheat cultivar, cv. Pusa Lerma, grown under three soil nitrogen levels (0, 30 and 120 kg ha^-1), were examined for changes in total reduced nitrogen and protease activity at pH 4.0 and 7.0. No net loss of reduced nitrogen takes place prior to and around anthesis. The protease activity is low during this period. At later stages there is rise in the loss of nitrogen which is paralleled by enhancement in protease activity. From amongst the leaf blades, nitrogen concentration is significantly high in the flag and penultimate as compared to the values in the third leaf blade. There were significant differences in protease activity (pH 4.0) amongst the leaf blades. At pH 7.0, however, the differences between the flag and penultimate leaf blades were not significant. Highest enzyme activity was in the flag followed by penultimate and then third leaf blade. Soil N application significantly enhanced the nitrogen content of all the leaf blades. At pH 4.0, the protease activity (g fr. wt.^-1) increased significantly due to soil N application (N₃₀ over N₀). There was, however, decline in the enzyme activity at pH 7.0, though the differences at different soil N levels were not significant. Analysis in terms of μmol N (reduced form) accumulated in the grains (ear)^-1 revealed that two-thirds of N is translocated by 28-day stage and the rest between 28-day and final harvest. The three leaf blades together contributed 22.7, 32.6 and 48.5% of the grain N (ear)^-1 at N₀, N₃₀ and N₁₂₀- respectively. Most of the nitrogen applied to the soil is reduced by these leaf blades.     

抗生素对农杆菌的抑制和对油菜外植体分化的影响

通过哌拉青霉素、氨苄青霉素、青霉素钠、羧苄青霉素、头孢拉定、头孢唑啉钠、磷霉素钠、乳糖酸红霉素、白霉素9种抗生素对根癌农杆菌EHA105和LBA4404的抑制效果,以及对油菜子叶柄分化影响的研究,结果表明：羧苄青霉素在500mg／L时对农杆菌EHA105的抑菌效果最好,而其它8种抗生素对EHA105无明显的抑菌作用;对于LBA4404浓度为200mg／L的羧苄青霉素、氨苄青霉素和头孢唑啉钠都有良好的抑菌效果。不同抗生素对油菜子叶柄的分化试验结果表明,羧苄青霉素和头孢唑啉钠对离体油菜子叶柄再生分化及生长没有影响,磷霉素钠、乳糖酸红霉素、自霉素几乎完全抑制了油菜子叶柄分化。同时对卡那霉素(作为筛选剂)的浓度进行了筛选,确定了油菜33B的筛选浓度为15mg／L,油菜918B的筛选浓度为10mg／L。     

Diurnal Growth of Tall Fescue Leaf Blades : II. Dry Matter Partitioning and Carbohydrate Metabolism in the Elongation Zone and Adjacent Expanded Tissue

The spatial distributions of net deposition rates of water soluble carbohydrate-free dry matter (WSC-free DM) and WSC were evaluated within and above the elongation zone of tall fescue (Festuca arundinacea Schreb.) leaf blades during light and darkness. Imported DM used for WSC-free DM synthesis during darkness (67% of the total in experiment I and 59% in experiment II) was greater than during light (47% in both experiments), suggesting that the 65% higher leaf elongation rate during darkness was accompanied by higher rates of synthesis of cellular structural components. Deposition rates of WSC in the basal and central part of the elongation zone (0-20 mm from the ligule) were similar during light and darkness, but above 20 millimeters WSC deposition occurred during light and WSC loss occurred during darkness. WSC deposition and loss throughout the elongation zone and the recently expanded tissue were mostly due to net synthesis and degradation of fructan. Fructan was predominantly low molecular weight and contributed about 50% of the total osmotic partial pressure of WSC. In the most actively growing region, where fructan synthesis was most rapid, no diurnal change occurred in molecular weight distribution of fructan. WSC solute concentrations were diluted in the most actively growing tissue during darkness because net monosaccharide and fructan deposition were unaltered and sucrose deposition was decreased, but growth-associated water deposition was increased by 77%. Net rates of fructan synthesis and degradation were not related to tissue sucrose concentration, but appeared to respond to the balance between assimilate import and assimilate use in synthesis of cellular structural components (i.e. WSC-free DM) and deposition of monosaccharides. Fructan synthesized in tissue during most active elongation was degraded when the respective tissue reached the distal limit of the elongation zone where assimilate import in darkness was insufficient to maintain synthetic processes associated with further differentiation of cells.     

Effects of Certain Inhibitors on Photorespiration by Wheat Leaf Segments

The effect on the carbon metabolism of wheat leaf segments ofcertain inhibitors of photorespiration was studied. Sodium 2-hydroxy-3-butynoatesupplied for 40 min resulted in accumulation of ¹⁴C in glycolicacid with only a 7% inhibition of photosynthesis; when suppliedfor 90 min, photosynthesis was inhibited by 47%. When ¹⁴CO₂was replaced by 1000 vpm ¹²CO₂, radioactivity in glycine decreasedbut increased more rapidly in sucrose with less release of ¹⁴CO₂.Isonicotinyl hydrazide (INH) inhibited photosynthesis from ¹⁴CO₂by 50% and glycine replaced sucrose as the main product. When,after 15 min, ¹⁴CO₂ was replaced by 150 vpm ¹²CO₂, in the presenceof INH less ¹⁴CO₂ was released, ¹⁴CO in glycine decreased moreslowly, and less [¹⁴CO]sucrose accumulated. Glycidate (potassium2,3-epoxypropionate) at 2 mM had no effect on photosyntheticrate and little effect on carbon metabolism; 20 mM glycidateinhibited photosynthesis by 64% and resulted in less radioactivityin glycine, more in phosphate esters, and less ¹⁴CO₂ released.When photosynthesis was measured in 1000 vpm CO₂ the inhibitorsgave smaller effects on metabolism than during photosynthesisfrom 150 vpm ¹⁴CO₂ but 20 mM glycidate still resulted in a 42%inhibition of photosynthesis. When U- [¹⁴CO]glycerate was appliedto leaf segments in air with 320 vpm ¹⁴CO₂ the total uptakeof glycerate was not changed by the inhibitors. INH and glycidateboth decreased the amount of glycerate metabolised. More ¹⁴COaccumulated in glycine in the presence of INH and in phosphateesters and serine in the presence of glycidate. Hydroxybutynoateincreased the production of glycolate from glycerate but didnot affect the total amount of glycerate metabolised. Although all three inhibitors affected photorespiratory metabolismnone stimulated photosynthesis. The results are consistent withthe main release of CO₂ in photorespiration arising from theconversion of glycine to serine.     

表油菜素内酯促进小麦胚芽鞘伸长的作用

BR促进小麦胚芽鞘伸长的生理活性大于IAA,但高浓度的促进现象不如IAA明显。BR刺激乙烯生成与浓度相关。BR和IAA混合处理,对芽鞘切段的伸长、乙烯释放和H~+分泌都表现了加成作用。这二种激素在作用时间上有明显的差别,BR作用的滞后期更为清楚。BR有拮抗ABA对小麦胚芽鞘切段伸长的抑制作用。     

The Role of the Epidermis in the Control of Elongation Growth in Stems and Coleoptiles

The peripheral cell wall(s) of stems and coleoptiles are 6 to 20 times thicker than the walls of the inner tissues. In coleoptiles, the outer wall of the outer epidermis shows a multilayered, helicoidal cellulose architecture, whereas the walls of the parenchyma and the outer wall of the inner epidermis are unilayered. In hypocotyls and epicotyls both the epidermal and some subepidermal walls are multilayered, helicoidal structures. The walls of the internal tissues (inner cortex, pith) are unilayered, with cellulose microfibrils oriented primarily transversely. Peeled inner tissues rapidly extend in water, whereas the outer cell layer(s) contract on isolation. This indicates that the peripheral walls limit elongation of the intact organ. Experiments with the pressure microprobe indicate that the entire organ can be viewed as a giant, turgid cell: the extensible inner tissues exert a pressure (turgor) on the peripheral wall(s), which bear the longitudinal wall stress of the epidermal and internal cells. Numerous studies have shown that auxin induces elongation of isolated, intact sections by loosening of the growth-limiting peripheral cell wall(s). Likewise, the effect of light on reduction of stem elongation and cell wall extensibility in etiolated seedlings is restricted to the peripheral cell layers of the organ. The extensible inner tissues provide the driving force (turgor pressure), whereas the rigid peripheral wall(s) limit, and hence control, the rate of organ elongation.     

CO2Effects on Phasic Development, Leaf Number and Rate of Leaf Appearance in Wheat

It has been predicted that the concentration of CO₂in the aircould double during the 21st century. Though it is recognizedthat CO₂-doubling could increase yield through its effects onplant photosynthesis and stomatal behaviour, it is unclear whetherCO₂-doubling will change phasic development in wheat. A phytotronstudy was conducted with two contrasting cultivars of wheat,Condor (spring) and Cappelle Desprez (winter), to determinewhether development is affected by a season-long exposure to360 and 720 ppmv CO₂. Plants were vernalized for 50 d (8/4 °C,8 h photoperiod) before their exposure to the CO₂treatments. There were significant differences between cultivars in theduration of different phenophases as well as in the final numberof leaves. However, CO₂concentration had no effect in eithercultivar on the duration of the early developmental phase toterminal spikelet initiation, or on the final number of leaves,though CO₂-doubling did slightly increase the later phase fromterminal spikelet initiation to heading in Cappelle Desprez.Condor and Cappelle Desprez also differed markedly in the dynamicsof leaf appearance. While the former had a constant rate ofleaf appearance throughout development, the latter had a fastrate initially (between leaves 1 and 7), similar to that ofCondor, which was followed by a slower rate after the appearanceof leaf 7. Overall, CO₂-doubling did not significantly affectthe rates of leaf appearance nor the shape of the relationship.Phyllochron for the first seven leaves was the same for bothCO₂concentrations. However, the change in phyllochron associatedwith CO₂-doubling for leaves 7–12 in Cappelle Desprez,although quite small (4%), accounts for part of the slightlyincreased duration of the phase from terminal spikelet initiationto heading under high CO₂concentration in that cultivar. Weconclude that CO₂concentration does not influence developmentin wheat to a degree relevant to agronomy. Carbon dioxide; climatic change; development; leaf number; phyllochron