Growth and Development in the Young Tomato: I. THE EFFECT OF TEMPERATURE AND LIGHT INTENSITY ON GROWTH OF THE SHOOT APEX AND LEAF PRIMORDIA

Tomato seedlings were grown at constant temperatures of 25°and 15° C. in a 12-hour day at light intensities of 1,600,800, and 400 f.c. The rate of increase in size of the shootapex and the rates of formation and growth of leaf primordiaduring the vegetative phase were followed by dissecting samplesfrom the time of cotyledon emergence onwards. The rate of enlargement of the shoot apex increased with lightintensity, but apical enlargement was delayed at the highertemperature, the delay being longer the lower the light intensity.The rates of leaf formation and leaf growth increased with bothtemperature and light intensity. Temperature had a larger effecton leaf growth than on leaf formation. More leaves were formedbefore flowering at 25° C. than at 15° C., the increasein leaf number being greater the lower the light intensity. It is suggested that the delay in the enlargement of the apexat high temperature can be explained in terms of competitionfor assimilate, the competitive potential of the expanding leafprimordia exceeding that of the apex at higher temperatures.     

Stimulation of the Flowering of Pharbitis nil Chois. by Gibberellin A3 : Time Dependent Action at the Apex

Gibberellin A₃ (GA₃) stimulated flowering when it was appliedto the shoot apex of seedlings of Pharbitis nil, dwarf strainKidachi; but, not when it was applied to the cotyledons. GA₃applied to the plumule before or shortly after the start ofan inductive dark period promoted both flowering and shoot elongation;but, the later the time of application during the dark periodless the promotion of flowering, although marked promotion ofshoot elongation always took place. The variation with time in the response of flowering to GA₃indicates that early floral processes at the apex are stimulatedby GA₃, but that subsequent processes are insensitive to it.The early processes of floral stimulus produced by a 16 hr inductivedark period probably are completed within 20 hr at 28°Cafter the end of the dark period. At low temperatures, suchas 15 and 20°C, early floral processes continued for morethan 40 hr. When cotyledons were removed at various times, the export ofthe floral stimulus to the shoot apex was apparent within hoursof the generation of the floral stimulus in the cotyledons,which started with the passage of the critical 9-hr dark period. (Received February 18, 1981; Accepted March 24, 1981)     

Some Effects of Light Intensity, Daylength and Temperature on Growth of Fruiting and Non-fruiting Watermelon (Citrullus lanatus)

Plants of watermelon [Citrullus lanatus(Thunb.) Matsum. &Nakai, cv. Early Yates] were grown for up to 3 months aftergermination in controlled environment cabinets, and variousaspects of vegetative growth and fruit development were measured.Effects of light intensity were studied by comparing growthat 8, 16 and 32 klx at constant temperature and daylength (25^°C, 14 h). Effects of daylength were studied by comparing8, 14 and 24 h at constant light intensity and temperature (32klx, 25 ^°C), and effects of tem perature were studied bycomparing 20^°, 25^°, 30^°, 35^° and 40 ^°C atconstant light intensity and day- length (32 klx, 14 h). Withincreasing light intensity and daylength lateral growth waspromoted whereas main shoots were less affected. Increase intemperature above 25 ^°C resulted in longer main shoots andprolific lateral growth, due both to more and to longer laterals.Environmental differences had little effect on internode lengthbut did affect the size of basal leaves. However, an increasein total leaf area at higher temperatures or with Continuouslight was mainly due to more leaves rather than larger leaves.The presence of developing fruit greatly reduced vegetativegrowth of plants. Main shoot length, lateral growth, numberof leaves, and even size of individual leaves, were all reduced.This reduction did not apply to d. wt of whole plants. Fruitingplants were very efficient, on a leaf area basis, in accumulatingd. wt. At 25 ^°C at the two higher light intensities with14 h days the presence of one developing fruit was inhibitoryto the setting of any subsequent fruit. With short days or lowlight, more fruits were set but they were small. With continuouslight or high temperature more than one fruit could developand they were large.     

Developmental Physiology of Sugar-beet: IV. EFFECTS OF GROWTH SUBSTANCES AND DIFFERENTIAL ROOT AND SHOOT TEMPERATURES ON SUBSEQUENT GROWTH

The effects of three growth substances, viz. indol-3yl-aceticacid (IAA), gibberellic acid (GA₃), and kinetin (KIN), and differentialshoot and root temperatures on growth of sugar-beet (Beta vulgarisL.) plants have been studied. IAA, GA₃, and KIN were applied in aqueous lanolin at differentconcentrations (50 ppm to 5000 ppm) to decapitated sugar-beetplants at the eight-leaf stage, one group also having alternateleaves removed. The growth substances significantly increasedthe dry weights of the plants when all the leaves were present,which was mainly explained by the large increase in roots. Thegrowth substances probably stimulated cambial activity and hencethe mobilization of substrates resulting in a bigger root whena relatively large leaf area existed. The failure of the plantsto respond to treatments following the removal of alternateleaves suggests that under such conditions the growth substanceshave hardly any major effect on the production of substrates;rather they influence growth by regulating the movement of substratesby altering the ‘sink strength’ if the supply ofsubstrates is not limiting. It could also be that the rootsproduce sufficient growth substances to maintain half the leavesat maximum expansion and maximum photosynthesis. Treatment withgrowth substances would therefore have little effect. When allthe leaves were present, they are limited by insufficient growthsubstances. All combinations of root and shoot temperatures of 17 and 25°C were imposed on plants decapitated at the eight-leafstage, one group also having each alternate leaf removed. Leaf8 expanded most at shoot and root temperature of 25 °C whereasother leaves had the largest areas at shoot and root temperatureof 17 °. When all the leaves were present root growth wasmaximal at shoot temperature of 17°C and root temperatureof 25 °C, but when alternate leaves were removed maximumroot growth occurred at shoot and root temperatures of 25 °C.Generally, a higher concentration of soluble carbohydrates wasfound in the roots and leaves when either the shoot or rootor both were kept at 17 °C. Concentrations of nitrogen,phosphorus, and potassium in different organs were less at 17°C than at higher shoot or root temperatures and decreasedwith age.     

Developmental Physiology of Sugar Beet: I. THE INFLUENCE OF LIGHT AND TEMPERATURE ON GROWTH

Sugar beet plants were grown for 12 weeks from emergence ingrowth rooms at temperatures of 10, 17, 24 and 31 °C and20, 50, 80, and 110 cal visible radiation cm^-2d^-1, and the changeswith time in their dry weight, leaf area, leaf numbers, andstorage root sugar determined. The first stage of growth wasdominated by the development of the shoot, but the storage rootgradually assumed increasing importance and eventually grewat a faster rate and to a greater weight than the shoot. Therelative growth rate and final yield of dry matter of the shootwere greatest at 24 °C and of the root between 17 and 24°C. The relative rate of expansion and the final area ofthe leaf surface were also greatest at 24 °C, whilst therates of production and of unfolding of leaves were greatestat about 17 °C. All these attributes were increased withincreased radiation. Net assimilation rate increased almostproportionately with radiation and was not significantly affectedby temperature.The relationships of total leaf area with plantdry weight, root dry weight with shoot dry weight, and totalleaf number with plant dry weight were scarcely affected bychanges in radiation, but were much influenced by temperature.Plants of the same dry weight generally had bigger roots andsmaller areas of leaf surface as temperatures departed from24 °C and had most leaves at 17 °C. Sugar concentrationsin the storage root were greatest at 17 °C, but the totalamount of sugar was about the same at 17 and 24 °C. Theconcentration of sugar in the storage root depended on rootsize.Thus, temperature affected both the rate and pattern ofdevelopment, and radiation affected the rate but not the patternof development.     

Sucrose-Modulated Morphogenesis in Anagallis arvensis L.

Sucrose was found to have a modulating effect on the morphogenesisof Anagallis arvensis L. leaves cultured in a Murashige-Skoogmedium. Root formation and growth seem to be more independentthan other morphogenetic expressions. Roots formed without exogenoussugars at 25°C but sucrose seemed to be necessary at 32and 35°C. Sucrose at 3% improved shoot formation at 25°Cand had an inhibitory effect at 6%concentration and 35°C.Shoot growth (internode length) is inhibited by sucrose concentrationshigher than 3%. Sucrose could also replace light irradiancein regulating shoot and leaf growth. A higher sucrose concentration,than that required for roots and shoots formation, is necessaryfor flower and fruit formation, but sucrose could not replacethe photoperiod requirement for flowering in culture medium. (Received June 17, 1985; Accepted December 24, 1985)     

Patterns of Assimilate Distribution and Source--sink Relationships in the Young Reproductive Tomato Plant (Lycopersicon esculentum Mill.)

Patterns of distribution of ¹⁴C were determined in 47-day-oldtomato plants (Lycopersicon esculentum Mill.) 24 h after theapplication of [¹⁴C]sucrose to individual source leaves fromleaves 1–10 (leaf 1 being the first leaf produced abovethe cotyledons). The first inflorescence of these plants wasbetween the ‘buds visible’ and the ‘firstanthesis’ stages of development. The predominant sink organs in these plants were the root system,the stem, the developing first inflorescence and the shoot ‘apex’(all tissues above node 10). The contribution made by individualsource leaves to the assimilate reaching these organs dependedupon the vertical position of the leaf on the main-stem axisand upon its position with respect to the phyllotactic arrangementof the leaves about this axis. The root system received assimilateprincipally from leaf 5 and higher leaves, and the stem apexfrom the four lowest leaves. The developing first inflorescencereceived assimilates mainly from leaves in the two orthostichiesadjacent to the radial position of the inflorescence on thevertical axis of the plant; these included leaves which weremajor contributors of ¹⁴C to the root system (leaves 6 and 8)and to the shoot apex (leaves 1 and 3). This pattern of distributionof assimilate may explain why root-restriction treatments andremoval of young leaves at the shoot apex can reduce the extentof flower bud abortion in the first inflorescence under conditionsof reduced photoassimilate availability. Lycopersicon esculentum Mill, tomato, assimilate distribution, source-sink relationships     

Temperature Response of Vernalization in Wheat: A Developmental Analysis

The vernalization response of wheat ( Triticum aestivum L.)was reinterpreted from a developmental perspective, using currentconcepts of the developmental regulation of wheat morphologyand phenology. At temperatures above 0 °C, the effects ofthe process of vernalization per se in wheat are confoundedby the effects of concurrent vegetative development. These effectsare manifested by differences in the number of leaves initiatedby the shoot apex prior to floral initiation, which in turnaffects the subsequent rate of development to ear emergenceand anthesis. Leaf primordia development during vernalizationand total leaf number at flowering were used to develop criteriato define both the progress and the point of saturation of thevernalization response. These criteria were then used to reinterpretthe results of Chujo ( Proceedings of the Crop Science Societyof Japan 35 : 177–186, 1966), and derive the temperatureresponse of vernalization per se for plants grown under saturatinglong day conditions. The rate of vernalization increased linearlywith temperature between 1 and 11 °C, such that the timetaken to saturate the vernalization response decreased from70 d at 1 °C to 40 d at 11 °C. The rate declined againat temperatures above 11 °C, and 18 °C was apparentlyineffective for vernalization. Total leaf number at saturation,however, increased consistently with temperature, as a resultof the balance between the concurrent processes of leaf primordiuminitiation and vernalization. Total leaf number at saturationincreased from 6 at 1 °C to 13.3 at 15 °C, which inturn influenced the time taken to reach ear emergence. The advantagesof using this developmental interpretation of vernalizationas the basis for a mechanistic model of the vernalization responsein wheat are discussed. Triticum aestivum L.; wheat; vernalization; rate; temperature; primordia; leaf number; flowering     

Determination of the Length of the Vegetative and Pre-floral Stages in the Day-Neutral Plant Helianthus annuus by Chilling Pulses

Helianthus annuus seedlings grown in an 18 h day at 28 ?C wereexposed to one 6 d chilling pulse of 12 ?C, at spaced timesduring the first 21 d from sowing. At 2 d intervals, the terminalbuds of 5 plants were dissected to determine leaf number andto score the vegetative or flowering state of the shoot apex.It was found that, while the rate of leaf initiation was reducedequally by each chilling pulse, pulses commencing on days 9or 12 reduced the total leaf number from 30 to 26, while pulsesapplied earlier had little effect. This variation is interpretedin terms of the time available for leaf production. The apicesof control plants commenced the visible transition to flowering16 d after sowing. Chilling pulses applied from days 3 or 6delayed this transition by about 5 d, whereas later pulses causedonly a 1•5 d delay. In a second experiment, where the chillingwas reduced to 2 d duration, it was again found that chillingdelayed flowering during the first 8 d and was progressivelyless effective when applied later. From this variation in temperaturesensitivity it is proposed that chilling sunflower plants immediatelyafter sowing delays flowering by extending the vegetative phaseof growth and so delaying the attainment of a ‘ripenessto flower’ state that appears to coincide with the expansionof the first pair of leaves. From day 8 onwards processes leadingto flowering that are relatively temperature insensitive apparentlybecome dominant in the apex and result in visible signs of flowering8 d later, although during this transitional stage leaf primordiacontinue to be initiated on the flanks of the apex.     

Studies on the Fragmented Shoot Apex of Grapevine: III. A SCANNING ELECTRON MICROSCOPE STUDY OF ADVENTITIOUS BUD FORMATION IN VITRO

Scanning electron microscopy (SEM) was used to provide directevidence that shoots produced in vitro from fragmented shootapices of grapevine were adventitious in origin. The effectof temperature on the formation of the adventitious buds wasalso examined using SEM. At 27°C, shoot buds were initiatedby 31 d following fragmentation of the apex, while at 35°Cshoot initiation and multiplication were already well-advancedat only 18 d after the start of culture. At 38°C, apicalfragments quickly browned and died. After 25 d at 35°C,structures resembling inflorescence primordia were also visible.These did not occur in cultures at 27°C. The primordia laterdeveloped into multiple-branched tendrils, structures whichappear to be intermediate between tendrils and inflorescencesand have not been previously described.     

Growth and Development in the Young Tomato: III. THE EFFECT OF NIGHT AND DAY TEMPERATURES ON VEGETATIVE GROWTH

Tomato seedlings were grown in a 12-hour day at constant andalternating day and night temperatures ranging from 10°to 30° C. The pattern of results was similar at light intensitiesof 400 and 800 f.c. The maximum rate of dryweight accumulationoccurred at a constant temperature close to 25° C. The effectsof day and night temperatures on total dry weight showed a considerabledegree of independence. The optimum day temperature was 25°C irrespective of the night temperature; the optimum night temperatureincreased from 18° to 25° C over the whole range ofday temperature. On average, day temperature affected totaldry weight twice as much as night temperature. High night temperaturesto some extent compensated for low day temperatures. The optimumday and night temperatures for leaf growth were both 25°C. On average day temperature affected leaf growth one and ahalf times as much as night temperature. By 12-hourly sampling it was shown that the cotyledons and leavesgrow throughout both day and night and that high night temperatureaccelerates nocturnal growth (cotyledons by cell expansion,young leaves by cell multiplication). Plants having receivedonly one night at 25° C, as compared with 15° C, showa slightly greater assimilation during the following light period,apparently as a consequence of increased photosynthetic surface.The respiratory loss in dry weight during darkness was not significantlyaffected by temperature over the range 15–25° C.     

The Respiratory Costs of Nitrogen Fixation in Soyabean, Cowpea, and White Clover: II. COMPARISONS OF THE COST OF NITROGEN FIXATION AND THE UTILIZATION OF COMBINED NITROGEN

Plants of soyabean, cowpea, and white clover were grown singlyin pots in Saxcil growth cabinets at 23/18 °C, 30/24 °C,and 20/15 °C, respectively, until seed maturation or for85 d (white clover). Two populations were produced within eachspecies: one population effectively nodulated and wholly dependentfor nitrogen on fixation in the root nodules, and a second populationcompletely lacking nodules but receiving abundant nitrate nitrogen.In each species, the two populations were compared in termsof rate of gross photosynthesis, rate of shoot respiration,and rate of root respiration. Source of nitrogen had littleor no effect on rate of photosynthesis or shoot respiration.In contrast, the rate of respiration of the nodulated rootsof plants fixing their own nitrogen was greater, sometimes two-foldgreater, than that of equivalent plants lacking nodules andutilizing nitrate nitrogen. This superiority in terms of rateof root respiration was generally confined to the period ofintense nitrogen fixation. An analysis of the magnitude of thisrespiratory burden in terms of daily photosynthesis indicatesthat, in all three legumes, plants fixing their own nitrogenrespire 11–13% more of their fixed carbon each day thanequivalent plants lacking nodules and utilizing nitrate nitrogen.     

Flowering in Pisum: Kinetics of the Vernalization Response in Genotype If e Sn Hr

Previous work has shown that vernalization acts at two sites,one in the cotyledons and one in the shoot, in young plantsof genotype Ife Sn Hr. During the present study the size ofthe vernalization responses in both the cotyledons and shootincreased as the temperature was lowered from 17 to 3 °C.This occurred regardless of whether the treatment was givenfor the same chronological period of time or for the same physiologicalperiod of time. Vernalization treatment was effective from thetime the seeds were developing in the pods on the maternal plantuntil at least 20 leaves were expanded and became graduallymore effective as the length of the treatment was increasedfrom 2 to 5 weeks. High pre– or post–vernalizationtemperatures can reduce the cotyledon effect and to a lesserextent the shoot effect of vernalization. Devernalization occurredto a larger extent in low light intensities and darkness thanin high light intensities. No stabilization of the vernalizationeffects in the cotyledons or shoot appeared to occur at normalgrowing temperatures (15–25 °C). These results arediscussed in terms of the previously hypothesized mechanismsfor the cotyledon and shoot effects of vernalization. Pisum sativum, flowering, vernalization     

Time of sowing and temperature effects on the flowering of Stylosanthes guianensis

Seedlings of Stylosanthes guianensis var. guianensis cv. Cook and of two selections of S. guianensis var. pauciflora (CIAT 1280 and CIAT 1062) were grown at day/night temperatures of 20°/25°, 30°/25°, and 35°/30°C in a naturally-lit glasshouse at latitude 27°30'S. Sowings were made in decreasing daylength at 30-day intervals from 22 January to 21 May. Cv. Cook and the CIAT 1280 selection did not flower fully if sown after 22 January and the CIAT 1062 selection did not flower if sown after 22 March. This is interpreted as a long-short day flowering response. Usually, flowers were initiated earlier and at a lower node at 25?/20°C than at the warmer temperatures. At 25?/20°C the first flowers to appear were produced predominantly at the terminal apex of the main stem in cv. Cook and the CIAT 1062 selection, but not in the CIAT 1280 selection. At the two warmer temperatures first flowers were more commonly produced at the terminal apex of primary, secondary and tertiary branches. There were more inflorescences per plant on earlier than later sown plants when measured 21 days from appearance of the first flower and the most inflorescences were produced by cv. Cook at 25?/20°C, by selection CIAT 1062 at 30°/25°C, and by CIAT 1280 at 35°/30°C.     

Gibberellin-like Substances Obtained from Chilled Plants of Dianthus barbatus L. by an Agar Diffusion Technique

Plants of Dianthus barbatus with a cold requirement for floweringwere subjected to chilling treatments at 5 °C. An agar diffusiontechnique was used to collect gibberellin-like substances fromshoot tips excised from these plants and from plants that hadbeen kept in the glasshouse at a minimum temperature of 14 °C.Shoot tips from chilled plants gave markedly higher yields ofgibberellin-like substances. The effect of chilling was no longerso apparent if plants were returned to the higher temperaturesof the glasshouse for 1 week before the shoot tips were excised. The proportion of plants that flowered as a result of the differentchilling treatments varied widely but this variation was notassociated with any obvious differences in the yields of gibberellin-likesubstances. Application of gibberellins to plants grown at aminimum temperature of 14 °C did not promote flowering.     

Leaf Extension in Zea mays: II. LEAF EXTENSION IN RESPONSE TO INDEPENDENT VARIATION OF THE TEMPERATURE OF THE APICAL MERISTEM, OF THE AIR AROUND THE LEAVES, AND OF THE ROOT-ZONE

The temperatures of the roots, the apical meristem, and theshoots of Zea mays plants were varied independently of eachother and the rates of leaf extension were measured. When thetemperature of the apical meristem and region of cell expansionat the base of the leaf was kept at 25 °C, changes of leafextension in response to changes of root and shoot temperatureswere less pronounced. When the temperature of the meristematicregion was changed by increments of 5 or 10 °C from 0 to40 °C, and the root and shoot temperatures were kept at25 °C, rapid changes in leaf extension occurred. It was concluded that the rates of leaf extension were controlledat root-zone temperatures of 5 to 35 °C by heating or coolingof the meristematic region. Changes in rates of leaf extensionin response to changes in air temperature were attributed todirect effects on the temperature of the meristematic regionand on the physiology of the leaf.     

Growth, Development, and Yield of Spring Wheat in Artificial Climates

Spring wheat was grown to maturity in three growth rooms providing:(a) 18 h of light at 20° C and 6 h of darkness at 15°C (hot long days, HL); (b) 18 h of light at 15° C and 6h of darkness at 15° C (cold long days, CL); (c) 14 h lightat 20° C and 10 h of darkness at 15° C (hot short days,HS). Plants were moved between environments at spikelet initiationand anthesis, so dividing the growth period into three. Meanlengths in days of these periods in the different environmentswere: Period 1: HL 16, CL 18, HS 25; Period 2: HL 42, CL andHS 61; Period3: HL 53, CL 83, HS 63. The length of periods 2and 3 also depended on previous treatments. Grain dry weight was affected by environmental differences inall periods and effects in successive periods were additive.Compared with HL, CL or HS in period I before initiation increasedgrain yield by 6 per cent by increasing grain number per ear,HS in period 2 between initiation and anthesis decreased itby 24 per cent by decreasing the number of grains per spikeletand the proportion of spikelets that contained grain; CL inperiod 2 increased it by 21 per cent by increasing the numberof ears; CL in period 3 after anthesis increased it by 16 percent because leaves died later; HS in period 3 decreased itby 14 per cent because there was less radiation and hence lessphotosynthesis. Dry weight of shoot and root at maturity wasincreased by CL or HS in periods 1 or 2, and increased by CLand decreased by HS in period 3. The effects on final yieldof treatment during periods 1 and 2 were the consequence ofsimilar effects already produced at anthesis, and shoot androot dry weight changed little during period 3. The effects of environmental differences on grain dry weightcould not be explained by differences in leaf-area durationafter anthesis (D₃), except that CL in period 3 increased bothyield and D₃ but not proportionately, so that, as with HS inthe same period, grain: leaf ratio was decreased. Environmentaldifferences in periods 1 and 2 appeared to affect grain weightby altering the capacity of the ear to accumulate carbohydrates,determined by the number of grains per ear, rather than by alteringthe supply of carbohydrates, determined by D₃. There were some interactions between environments in differentperiods which were usually small compared with the main effects.     

Shoot--root Plasticity and Episodic Growth in Red Pine Seedlings

Red pine seedlings of a half-sib seed source were grown in growthchambers under thermoperiodic regimes of 30/20 °C, 25/15°C and 20/10 °C day/night temperatures. Classical growthanalyses based on weekly harvests of leaves, stem and rootswere employed to study the first 3 to 15 weeks of seedling development.Leaf and root growth were inversely related and episodic. Significantshort term surges in growth of either organ were effective inreversing periodic imbalances that occurred, thus maintaininga long term dry weight equilibrium between above and below groundseedling parts. Adaptive plasticity in the leaf-root balanceat different temperatures gave plants grown at 25/15 °Ca larger proportion of leaves relative to roots and a greatersize compared to seedlings grown under other regimes. Episodicfluctuations in leaf and root growth occurred simultaneouslywith depressions in net assimilation rate. Apparently, balancedgrowth is maintained at an assimilatory cost to the plant, periodic‘corrections’ of shoot—root imbalances requiringcarbohydrate conversion and energy expenditure. Pinus resinosa Ait., red pine, episodic growth, shoot—root balance, plasticity, net assimilation rate, growth analysis     

Correlative Inhibition in the Shoot of Agropyron repens ( L.) Beauv

Correlative inhibition was investigated in plants of Agropyronrepens at two temperatures. Reciprocal inhibition ocrurred betweenthe main shoot apex and the outgrowing axillary shoots, withthe balance of inhibition varying with temperature. Apical dominancewas stronger at 10 °C than at 20 °C , but even at 10°C release of apical dominance by decapitation had onlyminor effects on the timing of outgrowth, growth pattern andrate of dry weight aocumulation of the axillary shoots. Dominanceof the main shoot apex by the axillary shoots was stronger at20 °C than at 10 °C. Removal of axillary buds preventeddecline in size and activity of the main shoot apex ard resultedin increased rates of primordium initiation, leaf emergenceand dry weight accumulation in the main shoot. It is suggestedthat a system of reciprocal dominance provides a mechanism formaintaining the characteristic habit of the grass plant andlimits growth in height of vegetative shoots. Agropyron repens (L.) Beauv, couch grass, correlative inhibition, apical dominance, shoot, apex     

The Effect of Temperature during Growth on the Subsequent Rate of Photosynthesis in Leaves of Tall Fescue (Festuca arundinacea Schreb)

Two experiments are reported in which young plants of tall fescuewere grown in temperature regimes of 20 °C day/15 °Cnight or 10 °C day/5 °C night until the fourth leafon the main stem was fully expanded. These temperature regimeswere then either changed over for individual plants or continuedunchanged up to the seven-leaf stage. Photosynthesis and respirationrates were determined in the fourth and subsequent leaves andalso in ageing leaves, using an infra-red gas analyser in anopen system and at temperatures of 10 and 20 °C in one and10, 15, 20, and 25 °C in the other experiment. Rates of apparent photosynthesis per unit leaf area in fullyexpanded leaves differed little as a result of previous treatmentand were not greatly affected by temperature during measurement.However, the specific leaf area and the rate of apparent photosynthesisper unit dry weight were higher in plants grown at the hightemperature. Leaves from the high-temperature regime had a higheroptimum temperature for apparent photosynthesis, a shorter life,and a lower respiration rate at any one temperature of measurementthan did leaves from the low-temperature regime. After transfer from one temperature regime to the other, therate of apparent photosynthesis of the next leaf to become fullyexpanded was higher in plants transferred from low to high temperatureand lower in plants transferred from high to low than in plantsremaining in either temperature regime; the leaves which subsequentlyexpanded had rates similar to those of unchanged plants. Inleaves which were fully expanded at the time of transfer, therate of apparent photosynthesis rose after transfer to the high-temperatureregime and fell after transfer to the low-temperature regime. These results are discussed in relation to growth-analysis datafrom other plants grown in the same conditions.