Estimation of Potential Tiller Production and Site Usage During Tall Fescue Canopy Development

Tiller appearance in tall fescue (Festuca arundinacea Schreb.)occurs in an orderly, predictable manner with the potentialfor a high degree of synchronization among tillers on a givenplant. Estimates of potential cumulative tiller production (Tmax)are made for synchronous (Tmax_lx = 2^Lx+1 – 1, where Lxis the axil number of the youngest leaf on the main stem whichbears an emerged tiller) and non-synchronous (Tmax₁ = 2^L–NLAT–1,where L is the number of leaves on the main stem and NLAT thenumber of leaves above the youngest primary tiller at its appearance)conditions. A method for determining the degree of synchronizationand an equation for estimating site usage are also presented.Early in seedling development, site usage of a tall fescue populationwith high tillering capacity was near 90%, and tillering wasregulated largely by rate of tiller site formation. As the canopydeveloped the phyllochron (time between successive leaf appearances)and NLAT increased, slowing the rate of tiller production intemporal terms and in relation to leaf appearance, respectively.Beyond 45 d after planting, site usage decreased rapidly, furtherreducing tiller production. High tiller production appearedto be associated with synchronized tiller appearance, with alack of synchrony being associated with decreased site usage.Tillers formed in prophyll axils were less likely to be in synchronywith other tillers and frequently failed to appear. In contrastwith branching in dicotyledons, apical dominance appears toplay a minor role in regulating tillering in tall fescue Tillerproduction initially appears to proceed at near maximum ratesthen is down-regulated during later development by longer phyllochrons,slower rate of tiller elongation and reduced site usage. Festuca arundinaceaSchreb., tall fescue, tiller production, leaf appearance, site usage, leaf elongation rate, synchronization, phyllochron, canopy development     

Epidermal Cell Division and the Coordination of Leaf and Tiller Development

Initiation and development of grass leaves and tillers are oftendescribed individually with little attention to possible interrelationshipsamong organs. In order to better understand these interrelationships,this research examined epidermal cell division during developmentaltransitions at the apical meristem of tall fescue (Festuca arundinaceaSchreb.). Ten seedlings were harvested each day for a 9-d period,and lengths of main shoot leaves and primary tillers were measured.In addition, numbers and lengths of epidermal cells were determinedfor 0·5 mm segments along the basal 3 mm of each leafand tiller. Primordia development and onset of rapid leaf elongationwere characterized by an increase in the number of cells perepidermal file with mean cell length remaining near 20 µmper cell. After the leaf had lengthened to 1-1·5 mm,cells near the leaf tip ceased dividing and increased in length,at which time leaf elongation rate increased rapidly. Liguleformation, marking the boundary between blade and sheath cells,occurred prior to leaf tip emergence above the whorl of oldersheaths, while the earliest differentiation between blade andsheath cells probably began when leaves were < 1 mm long.Major transitions in leaf and tiller development appeared tobe synchronized among at least three adjacent nodes. At theoldest node, cessation of cell division in the leaf sheath wasaccompanied by initiation of cell division and elongation inthe associated tiller bud. At the next younger node the ligulewas being initiated, while at the youngest node cell divisioncommenced in the leaf primordium, as elongation of a new leafblade began. This synchronization of events suggests a key rolefor the cell division process in regulating leaf and tillerdevelopment.Copyright 1994, 1999 Academic Press Festuca arundinacea Schreb., tall fescue, cell division, leaf initiation, tillering, ligule development     

Leaf and Tiller Production of Prairie Grass (Bromus willdenowii Kunth) and Two Ryegrass (Lolium) Species

A detailed morphological study of three prairie grass cultivars(Bromus willdenowii Kunth) was conducted under ‘vegetative’and ‘reproductive’ growth conditions (short andlong photoperiods) and at different temperatures. Perennialryegrass (Lolium perenne L.) and Westerwolds ryegrass (Loliummuhiflorum Lam.) were compared during vegetative growth. Prairie grass had higher leaf appearance rates (leaves per tillerper day) and lower site filling (tillers per tiller per leafappearance interval) than the ryegrass species. Tillering rates(tillers per tiller per day) were also lower, except under vegetativeconditions at 4C. Low tiller number in prairie grass was notdue to lack of tiller sites but a result of poor filling ofthese sites. Lower site filling occurred because of increaseddelays in appearance of the youngest axillary tiller and lackof axillary tillers emerging from basal tiller buds. In prairiegrass, no tillers came from coleoptile buds while only occasionallydid prophyll buds develop tillers. Low tiller number in prairiegrass was compensated for by greater tiller weight. Prairiegrass had more live leaves per tiller, greater area per leafand a high leaf area per plant. Considerable variation between cultivars was found in prairiegrass. The cultivar ‘Bellegarde’ had high leaf appearance,large leaves and rapid reproductive development, but had lowlevels of site filling, tillering rate, final tiller numberand herbage quality during reproductive growth. ‘Primabel’tended to have the opposite levels for these parameters, while‘Grasslands Matua’ was intermediate and possiblyprovided the best balance of all plant parameters. prairie grass, Bromus willdenowii Kunth, perennial ryegrass, Lolium perenne L., Westerwolds ryegrass, Lolium multiflorum Lam., temperature, photoperiod, leaf appearance, leaf area, tillering, site filling, tillering sites, yield     

Modulation of leaf elongation, tiller appearance and tiller senescence in spring barley by far-red light

Supplemental far-red (FR) illumination of light-grown grass seedlings inhibits tiller production while enhancing leaf elongation. Although much is known about FR enhancement of internode elongation in dicots, relatively little research has been conducted to determine the effects of FR on monocot development. In growth chamber experiments, fibre optics were used to direct supplemental FR to elongating leaf blades, main stem bases and mature leaf blades of light-grown barley (Hordeum vulgare L.) seedlings. Our objective was to identify specific sites of perception for FR enhancement of leaf elongation and inhibition of tiller production, and to assess potential FR effects on tiller senescence. Far-red illumination of elongating leaves or of the main stem base reduced the total number of tillers per plant, primarily by reducing secondary and tertiary tiller production, and enhanced leaf elongation. However, leaf elongation was less sensitive to stem base treatments than to illumination of the elongating blade. Increased leaf length resulted from increased leaf elongation rate, while the duration of leaf elongation was unaffected. Exposure of mature leaf blades to FR had no effect on tillering or leaf elongation. None of the FR treatments led to tiller senescence. Localization of FR perception in vertically oriented tissues such as elongating blades and stem bases permits early detection of reflected light from neighbouring plants, allowing rapid response to impending competition.     

Leaf primordia initiation,leaf emergence and tillering in wheat (Triticum aestivum L.) grown under low-phosphorus conditions

In two simultaneous experiments we examined the effects of phosphorus (P) supply on leaf area development in wheat (Triticum aestivum L.) grown in sand with nutrient solutions. In Experiment 1 we studied leaf emergence, leaf elongation, tiller emergence, shoot growth, and P uptake under four levels of P supply (mM) 0.025 (P1), 0.05 (P2), 0.1 (P3), and 0.5 (P4), and. In Experiment 2 there were two levels of P supply, P1 and P4, and we examined the effects of P on leaf primordia differentiation and leaf emergence. The phyllochron was calculated as the inverse of the rate of leaf emergence calculated from the regression of number of leaf tips (PHY-Ltip), Haun index (PHY-Haun), and as the cumulated thermal time between the emergence of two consecutive leaves (PHYtt). The plastochron was calculated from the inverse of the rate of leaf primordia initiation in the apex. P deficiency delayed the emergence of leaves on the main stem and on the tiller 1. Phosphorus deficiency increased the time from emergence to double ridge and anthesis. The final number of leaves was not affected by P. The effects of P on the value of the phyllochron were attributed to both a reduced rate of leaf primordia initiation, and to a reduced leaf elongation rate. P deficiency delayed or even suppressed the emergence of certain tillers. In this work a phosphorus deficiency that reduced shoot growth by 25% at 44 days after emergence significantly modified the structure of the plants by increasing the value of the phyllochron and delaying tillering. These results suggest that any attempt to simulate leaf area development and growth of wheat plants for P-limited conditions should include the effects of the deficiency on leaf emergence.     

Leaf Emergence of Spring Wheat Receiving Varying Nitrogen Supply at Different Stages of Development

We examined effects of nitrogen (N) supply on leaf emergenceof spring wheat (Triticum aestivum L.) grown in sand with nutrientsolution containing different N concentrations (9NO₃: 1NH₄).In expt 1, the cultivar 'Gamenya' received nutrient solutiontwice weekly containing a constant N supply ranging from 50to 2400 µM N. In expts 2 and 3, cultivars 'Aroona' and'Gamenya' were irrigated hourly with nutrient solution containingeither low (L = 50 µM N) or high (H = 2000 µM N)N supply. In expt 2, the N supply to half of the plants receivingL and H was changed at the double ridge stage of apical development,producing plants receiving LL, LH, HL and HH. In expt 3, N supplywas changed firstly when the main stem apex was vegetative (oneto two leaves) and secondly when the main stem apex was at doubleridge stage (four to five leaves), producing plants receivingLLL, LHL, HLH and HHH. Leaves on the main stem and primary tillerswere counted. Rate of leaf emergence was estimated from regressionof number of leaves against thermal time; the phyllochron wascalculated as 1/ rate of emergence. Severely N-deficient plants (which had at least a 60% reductionin shoot dry weight) had slower rates of leaf emergence (expt1). Fluctuating N supply sometimes, but not always, changedthe rate of leaf emergence (expts 2 and 3). The N supply beforedouble ridge stage had bigger effects on the phyllochron thanthat afterwards (expt 3). The phyllocrons of the main stemswere generally lower than those of tillers, with a greater differencebetween stems in N-deficient plants. Low N supply at the vegetativeapex stage decreased the total number of leaves on the mainstem, while low N supply after double ridge did not.Copyright1994, 1999 Academic Press Nitrogen, stress, spring wheat, Triticum aestivum, leaf emergence, phyllochron, apical development     

Morphological Analysis of Leaf and Tiller Number Dynamics of Wheat (Triticum aestivumL.): Responses to Temperature and Light Intensity

In recent literature on Gramineae species, leaf and tiller numberdynamics have been studied by analysing site filling and thephyllochron of the mainstem. However, site filling is influencedby three components: (1) the phyllochron of the mainstem anddaughter tillers; (2) specific site usage (i.e. fraction ofbuds that ultimately develop into a visible tiller at a specificsite); and (3) HS-delay (i.e. difference in Haun Stage (HS)between the parent tiller and daughter tiller above the pointwhere the daughter tiller appears). These three morphologicalcomponents affecting site filling were studied under differentenvironmental conditions in a growth chamber experiment withspring and winter wheat (Triticum aestivumL.). Treatments weretemperature (daily average 10.5, 15.5 or 20.5 °C) and lightintensity (111, 191 or 286 µmol m^-2s^-1). Effects of temperatureand light intensity on phyllochron were well described by equationsalready reported in the literature. Specific site usage washigher at cooler temperatures and greater light intensitiesand was related to tiller position. It is proposed that theseeffects on specific site usage reflect differences in availabilityof local assimilate for tiller appearance. HS-delay of a tillerwas shorter if the expected tiller appearance was later andwas only slightly affected by light intensity or temperature.This new concept, combining HS-delay and specific site usage,can be useful in constructing more general models of the effectsof environmental factors on the dynamics of leaf number andleaf area ofGramineaespecies.Copyright 1998 Annals of BotanyCompany Triticum aestivum; wheat; phyllochron; temperature; light intensity; leaf number; tillering; site filling; site usage.     

Growth and Senescence of the Successive Grass Leaves on a Tiller. Ontogenic Development and Effect of Temperature

The tiller characteristics (length and age of laminae, numberof leaves per tiller) which depend on morphogenetic characterssuch as leaf appearance and expansion rates, leaf growth durationand leaf lifespan were studied in the field over four growingseasons to gain a better understanding of the progressive changesin leaf digestibility over time, and to facilitate the developmentof predictive mathematical models. We show that, for a givenregrowth, only the number of leaves per tiller and the laminaexpansion rate remain constant throughout growth. In other words,the length of successive laminae, their growth duration andlifespan increased while their rate of appearance decreasedin such a way that the lamina expansion rate at the tiller levelremained constant. These changes were associated with an increasein sheath length which governs both the lamina appearance rateand its growth duration. As temperature increased, the averagelamina expansion rate and the number of laminae which grew bothincreased simultaneously. Therefore, high temperature acceleratesthe changes in tiller characteristics which occur as growthprogresses. Copyright 2000 Annals of Botany Company Leaf, senescence, phyllochron, lifespan, digestibility, temperature, cocksfoot, Dactylis glomerata L     

Population differentiation in the tiller architecture of Microstegium vimineum (Poaceae) in relation to habitat

Grass tillers grow by addition of modular units known as phytomers. Differences in phytomer organ size produce subindividual variation with potential adaptive value. Here, patterns in organ mass along tillers in the invasive annual Microstegium vimineum are related to habitat and tiller architecture. In an earlier study, seed families were collected from two populations: one from a sunny, woodland edge and the other from a shady understory in New Jersey, USA. Plants from these seeds were grown in a greenhouse. Phytomers along primary tillers were divided into culms, leaves, and cleistogamous or chasmogamous spikelets and seeds, dried and weighed. These data were used to examine the quantitative genetics of subindividual variation among families and populations, and the relationship of tiller fitness (based on total seed mass) to the mean or subindividual variance of phytomer traits. Phytomer position along a tiller was the major determinant of organ mass. Leaf mass increased from basal to upper nodes; cleistogamous reproductive mass decreased from upper to lower nodes. Phytomer organs were heaviest in the population from the sunny habitat. Family explained < 18% of variation in organ mass. Tiller fitness was positively correlated with mean culm, and leaf mass, but negatively correlated with coefficients of variation. Field‐collected tillers showed evidence of selection for increased leaf mass. Subindividual variation in M. vimineum is mostly due to phytomer position along a tiller and the prevailing light environment. Differentiation between sunny and shady populations suggests selection favors heavier phytomer leaves and culms, especially in the shady understory where this species is most invasive.     

Effects of the Reversal of Day and Night Temperatures on Tillering and on the Elongation of Stems and Leaf Blades of Wheat

Different cultivars of wheat (Triticum aestivum L.) were grownin cabinets, under a 12 h photoperiod, at constant temperatures,and high day/low night and low day/high night temperatures.Plants were also transferred at different ages, between 18/10°C and 10/18 °C regimes. Application of the growth regulatorsCCC and TIBA was tested at 18/10 °C and GA₃ and IAA at 10/18°C. The reversal of day and night temperatures did not affect spikedifferentiation or the numbers of leaves and elongating internodes.However, tillering and tiller development were markedly promotedby the low day/high night temperature regimes whereas the elongationof leaf blades and stem internodes were suppressed under theseregimes. These effects were attributed to the effects of thetemperature regimes on the endogenous hormone balance of theplants. Considering the results of the transfer and growth regulatortreatments it was concluded that there were no obligatory associationsamong the number of tillers appearing, their subsequent development,leaf blade length, and stem elongation. It is suggested thatthe study of the physiological mechanisms controlling thesecharacters may benefit from experimentation under reciprocallydiffering day night temperature regimes.     

GROWTH AND NUTRITION OF TIMOTHY (PHLEUM PRATENSE)

Individual tillers of timothy ( Phleum pratense ) growing from seed in pots were labelled and their life history studied over a period of two years.
The leaf axil position of the first-produced tiller depended on its time of origin. A minimum of five leaves on the parent axis was necessary before its appearance, and no tiller emerged from the axil of any of the three terminal leaves of a shoot.
Ear-bearing capacity was high in early-formed tillers, but decreased progressively with later dates of origin despite favourable day length; all tillers arising after the end of July failed to produce inflorescences. A greater proportion of tillers on the main stem formed ears than secondary tillers of the same age. Time of ear emergence varied only within a few days for all tillers arising before the end of April. The number of leaves formed up to ear emergence varied linearly with date of origin and tiller position, the lowest recorded number being six.
Dry weight and length of inflorescence as well as seed yield per tiller varied linearly with the date of origin of tillers. Primary tillers generally had longer and heavier inflorescences and produced more seed per stem than secondary tillers of the same age.
Tillers arising at all times were found to have a limited span of life, not normally exceeding just over a year. The mean age of ear-bearing tillers varied linearly with their date of origin. Death-rates of all tillers generally increased with their age. Relative death-rates of fertile and vegetative tillers rose rapidly in the autumn but decreased during winter and early spring. Vegetative tillers which elongated in the year of formation survived for a shorter time than equivalent tillers in which stem elongation was delayed until the following year.
The perennial habit of grasses is discussed in relation to tiller survival. Successive new formation and death of tillers keep the plant in a condition of continuous dynamic change.     

冬小麦拔节期不同茎蘖对低温胁迫的反应及抗冻性评价

以小麦济南17和山农8355为材料,在低温胁迫条件下,测定了不同茎蘖功能叶和叶鞘超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT)活性及丙二醛(MDA)和可溶性蛋白含量,并利用主成分分析、聚类分析对其抗冻性进行综合评价.结果表明： 低温胁迫条件下,小麦拔节期不同茎蘖功能叶和叶鞘中SOD、POD和CAT活性均不同程度地上升,MDA和可溶性蛋白含量则不同程度地上升或下降.利用主成分分析和聚类分析,将济南17不同茎蘖分为3类：主茎和一级分蘖Ⅰ、Ⅱ属强抗冻蘖组,一级分蘖Ⅲ、Ⅳ和二级分蘖Ⅰp属中度抗冻蘖组,二级分蘖Ⅱp属弱抗冻蘖组;将山农8355不同茎蘖分为3类：主茎和一级分蘖Ⅰ、Ⅱ、Ⅲ属强抗冻蘖组,一级分蘖Ⅳ和二级分蘖Ⅰp属中度抗冻蘖组,二级分蘖Ⅱp属弱抗冻蘖组.表明冬小麦拔节期不同茎蘖存在抗冻性差异,且低位蘖较高位蘖抗冻.
     

Tillering Responses to the Light Environment and to Defoliation in Populations of Perennial Ryegrass (Lolium perenneL.) Selected for Contrasting Leaf Length

Tillering responses to the light environment and to defoliationwere studied in two populations of perennial ryegrass (LoliumperenneL.) selected for contrasting leaf lengths. The objectiveof this study was to determine whether differences in tilleringresponses between populations, as a result of management practices,affected their competitive ability. Young seedlings were exposed,under controlled conditions, to defoliation, neutral shading(decreased photosynthetic photon flux), low red:far-red ratioand/or decreased blue light. Selection for longer leaves reducedthe tillering rate. After defoliation, this difference betweenshort- and long-leaved populations was magnified. Defoliationdecreased both site filling and phyllochron of the long-leavedpopulation but had no effect on the short-leaved population.Lowering the photosynthetic photon flux reduced the phyllochronin both population. Decreasing the red:far-red ratio reducedtillering rate by reducing site filling, whereas decreasingblue light had no significant effects on tillering. Tilleringresponses to photosynthetic photon flux and to red:far-red ratiowere similar in the two populations selected for contrastingleaf length. The implication of these tillering responses indefining the competitive ability of the grass plants is discussedin relation to their management.Copyright 1999 Annals of BotanyCompany Blue light, defoliation, far-red, irradiance, leaf size,Lolium perenne(L.), perennial ryegrass, photomorphogenesis, phyllochron, shading, site filling, tiller production.     

Tillering in grain sorghum over a wiide range of population densities: modelling dynamics of tiller fertility

The prediction of tillering is poor or absent in existing sorghum crop models even though fertile tillers contribute significantly to grain yield. The objective of this study was to identify general quantitative relationships underpinning tiller dynamics of sorghum for a broad range of assimilate availabilities. Emergence, phenology, leaf area development and fertility of individual main culms and tillers were quantified weekly in plants grown at one of four plant densities ranging from two to 16 plants m(-2). On any given day, a tiller was considered potentially fertile (a posteriori) if its number of leaves continued to increase thereafter. The dynamics of potentially fertile tiller number per plant varied greatly with plant density, but could generally be described by three determinants, stable across plant densities: tiller emergence rate aligned with leaf ligule appearance rate; cessation of tiller emergence occurred at a stable leaf area index; and rate of decrease in potentially fertile tillers was linearly related to the ratio of realized to potential leaf area growth. Realized leaf area growth is the measured increase in leaf area, whereas potential leaf area growth is the estimated increase in leaf area if all potentially fertile tillers were to continue to develop. Procedures to predict this ratio, by estimating realized leaf area per plant from intercepted radiation and potential leaf area per plant from the number and type of developing axes, are presented. While it is suitable for modelling tiller dynamics in grain sorghum, this general framework needs to be validated by testing it in different environments and for other cultivars.     

Tillering Potential and Relationship Between Leaf and Tiller Production in Perennial Ryegrass

A detailed morphological examination of the tillering characteristicsof perennial ryegrass (Loltum perenne L.) is presented. It isshown that the tillering potential of perennial ryegrass interms of site filling is 0–693 tillers/tiller/leaf appearanceinterval. This is higher than earlier presented values and isdue to the tillering ability of the prophyll bud which has notpreviously been taken into account. In a controlled climateroom experiment with spaced plants of perennial ryegrass, meanvalues of site filling were found to be close to this theoreticalmaximum Due to growth-limiting factors, tiller formation from leaf axillarybuds can be delayed or suppressed entirely. A set of equationsis presented from which site filling and the ratio of new leavesto new tillers can be calculated for all situations of axillarybud activity. It is stressed that leaf appearance rate can onlybe determined by marking and counting leaves on single tillersat consecutive dates Loltum perenne (L.), perennial ryegrass, tillering, axillary bud, leaf appearance rate, prophyll, site filling     

Effects of photoperiod in the glasshouse on the growth of leaves and tillers in three perennial grasses

Leaf and tiller development in vegetative plants of S.₃₇ cocksfoot (Dactylis glomerata L.), S.₂₁₅ meadow fescue (Festuca pratensis Huds.) and S.₂₄ perennial rye-grass (Lolium perenne L.) were measured in photoperiods varied by extending a basic period of natural light with low-intensity artificial illumination so that all plants received approximately the same amount of light each day. Increasing the photoperiod usually increased leaf length and sometimes leaf width, but decreased rate of production of leaves. However, the rate of production of new leaf surface increased with photoperiod. Increasing the photoperiod generally decreased the rate of tillering; thus, plants grown in long days had few tillers with large leaves and sheaths, in short days, plants developed more but smaller tillers.     

Leaf demography of <Emphasis Type="Italic">Festuca pallens</Emphasis> in dry grassland communities

Leaf blade parameters and leaf demography of Festuca pallens Host were studied in two types of dry grasslands. The field work was carried out in the Považsky Inovec Mts (Western Carpathians) during 1993–1995. The permanent plot in the Poo badensis-Festucetum pallentis was located on a steep, strongly eroded S-facing slope covered with dolomite outcrops, scree and sparse vegetation (20%) dominated by Festuca pallens. The permanent plot in the Festuco pallentis-Caricetum humilis was located on the even ridge plateau with shallow stony soil and vegetation covering about 70% dominated by Carex humilis and Festuca pallens. In comparison to other grasses Festuca pallens had a very low rate of leaf turnover. The highest leaf birth rates and the lowest leaf death rates were observed in June. Leaf mortality was uniformly distributed in time without a distinct minimum or maximum. For the surviving tillers the leaf production exceeded the leaf mortality during the whole growing season. The steady net gain of leaves in tillers was not interrupted by the parallel process of tillering. Among the leaf cohorts the leaves produced in May had the longest leaf blades. Leaves grew during the whole year. The winter cold and summer drought might slow down the growth rate or interrupt the growth. The growth of a leaf blade took five to eight weeks. Leaf life span was estimated to 150–200 days (time from leaf appearance at the apex to the complete loss of its green assimilating parts). In comparison to other grasses Festuca pallens belongs to the species with the longest leaf life span. The effect of environmental factors on leaf demography was followed by the comparison of two populations belonging to two phytosociological associations differing mostly in habitat xericity. Differences were revealed in the following characteristics: length of leaf blade in cohorts born during May and June, maximum length of a leaf blade in a tiller and daily increments in May and June. The course of leaf natality and mortality was similar in the studied populations.     

半湿润地区氮磷钾配施对强筋小麦功能叶光合速率的影响

选用优质强筋小麦品种陕253为材料,研究了不同氮磷钾肥水平及组合对小麦生育后期主茎、主茎分蘖Ⅰ和主茎分蘖Ⅱ功能叶净光合速率的影响,结果表明:在不同的NPK肥配比处理中,功能叶净光合速率在蘖位、叶位间差异均极其显著,不同生育期间存在明显差异,具体表现为:孕穗期高于灌浆期,主茎>主茎分蘖Ⅰ>主茎分蘖Ⅱ,旗叶高于倒二叶.孕穗期以N225P120K120处理对茎蘖功能叶光合速率影响最为明显,分别比CK1和CK2增加20.41%和25.76%;灌浆期以N135P225K120处理对茎蘖旗叶净光合速率作用显著,分别比CK1和CK2增加43.48%和10.83%.研究发现,在一定磷钾肥基础上通过调节氮肥可以调节孕穗期茎蘖功能叶净叶光合速率,提高钾肥用量有利于提高灌浆期各茎蘖功能叶的净光合速率.     

The Epidermal Cell Pattern of Tetraploid Dactylis Cultivars

The length of successive leaves on the main shoot was studiedin six closely related populations of Dactylis, and the epidermalcell pattern of the 6th leaf was examined in detail. In general,cell and blade length increased together in consecutive leaves.The cell pattern was sufficiently distinctive for the cultivarsto be separable using epidermal cell length and width, in asimple replicated test.