The Growth and Development of the Wheat Apex: The Effects of Photoperiod on Spikelet Production and Sucrose Concentration in the Apex

Spring wheat (Triticum aestivum cv. Warimba) plants were grownin a controlled environment (20°C) in two photoperiods (8or 16 h). In the first instance, plants were maintained in eachof the photoperiods from germination onwards at the same irradiance(375 µE m^–2 s^–1). In the second case, allplants were grown in a long photoperiod until 4 days after double-ridgeinitiation when half the plants were transferred to a shortphotoperiod with double the irradiance (16 h photoperiod at225 or 8 h at 475 µE ^–2 s^–1). The rates of growth and development of the apices were promotedby the longer photoperiod in both experiments. Shoot dry weightgain was proportional to the total light energy received perday whereas the dry weight of the shoot apex increased withincreasing photoperiod even when the total daily irradiancewas constant. The principal soluble carbohydrate present in the shoot apexwas sucrose, although low concentrations of glucose and fructosewere found in the apices of long photoperiod plants late indevelopment. Sucrose concentration was invariably greater inthe slow-growing apices of short photoperiod plants, but roseto approach this level in the long photoperiod plants when theterminal spikelet had been initiated. Triticum aestivum, wheat, apex, spikelet initiation, photoperiod, flower initiation     

Influence of Vernalization and Photoperiod on Supernumerary Spikelet Expression in Wheat

Two tetraploid (Triticum turgidum L.emend gr. turgidum and gr.durum) and five hexaploid wheats (Triticum x aestivum L. emendgr. aestivum) with reported tendencies for ‘branched heads’(supernurnerary spikelets) exhibited variation in its expressionunder different vernalization photoperiod and temperature regimes. Two main types of supernumerary spikelets were identified, multiplesessile spikelets (MSS) with two or more complete spikeletsat a rachis node and indeterminate rachilla spikelets (IRS)with two to 13 spikelets on an extended rachilla. The degree of supernumerary spikelet expression in wheats withvernalization response differed from those without. Short photoperiods(9–14 h) both outdoors and in a glasshouse environment,were more conducive to supernumerary spikelet expression than24 h photoperiod in both environments. The 24 h photoperiodglasshouse environment (higher mean temperatures) was leastconducive to its expression except in lines with a strong vernalizationresponse. The high stability of supernumerary spikelet expression in certaingenotypes in the different environments indicated the feasibilityof incorporating this character in breeding and selecting commercialwheats to increase grain number per head. Triticum, wheat, ear-branching, supernumerary spikelets, vernalization, photoperiod, temperature     

Development in wheat as affected by timing and length of exposure to long photoperiod

Seeds of a spring wheat (Triticum aestivum L. cv. ‘Condor’)were vernalized and then grown at 19C in two naturally–litenvironments, one with a moderate (12 h) and the other withlong (18 h) photoperiod. Treatments consisted of transfers ofplants from the moderate to the long photoperiod chamber ondifferent occasions, or for periods of different durations.The main objectives were to determine whether wheat developmentresponds to current and previous photoperiodic environmentsand whether there is a juvenile phase when the plants are insensitiveto photoperiod. Plants under constant 18 h photoperiod had fewerleaves which appeared faster than those under constant 12 hphotoperiod (i.e. phyllochron was increased from 4.4 to 5.1d leaf^–1). Plants transferred from 12 h to 18 h photoperiodat terminal spikelet appearance (TSA) reached anthesis 4 d earlierthan plants retained at 12 h, while plants under continuouslong photoperiod (18 h) completed this phase most rapidly. Thus,there was some evidence for a historic effect of photoperiodon development. Exposure to long photoperiod during the first 5 d after plantemergence accelerated the rate of development towards anthesis,suggesting that there was no juvenile period of photoperiodicinsensitivity. There were, however, changes during ontogenyin the degree of sensitivity to long photoperiod, increasingfrom seedling emergence to a maximum c. 15 d later, and thendecreasing again. Although all treatments were imposed beforeTSA, the response was not limited to the pre-TSA phase, suggestingthat well before the terminal spikelet appeared, the plant wasalready committed to the initiation of this spikelet. Spikeletnumber decreased with delayed transfer to long photoperiod witha minimum for plants transferred to long days from 16-20 d afterseedling emergence. Additionally, there was a trend for an increasein the rate of leaf appearance (decrease in phyllochron) whenthe plants were exposed to long days between 10 and 35 d afterseedling emergence. Although the differences were small, whenconsidered in conjunction with the effects on final leaf numberthey become important in explaining differences in time to anthesis. Key words: Development, flowering, leaf number, photoperiod, phyllochron, Triticum aestivum     

Environmental Control of Flowering in some Northern Carex Species

The environmental control of flowering in some arctic-alpineCarexspecies has been studied in controlled environments.Carex nigra,C. brunnescens, C. atrata, C. norwegica andC. serotina all hada dual induction requirement for flowering. In all exceptC.nigra either low temperature (12 °C or lower) or short days(SD) over a wider range of temperatures were needed for primaryfloral induction and inflorescence formation. InC. nigra primaryfloral induction took place in SD only (9–21 °C),8–10 weeks of exposure being required for a full response.In all these species long days (LD) were required for, or stronglypromoted, culm elongation and inflorescence development (secondaryinduction). Quantitative ecotype differences in both primaryand secondary induction were demonstrated. Unlike the otherspecies,C. bicolor proved to be a regular LD plant which requiredLD only for inflorescence initiation and development. In allspecies leaf growth was strongly promoted by LD, especiallyin the higher temperature range (15–21 °C). In SDand temperatures below 15 °C the leaves became senescentand the plants entered a semi-dormant condition which was immediatelyreversed by LD. The results are discussed in relation to growthform and life history of shoots. Carex ; dual induction; ecotypic diversity; flowering; growth; photoperiod; sedges; temperature     

Rate of Leaf Appearance and Final Number of Leaves in Wheat: Effects of Duration and Rate of Change of Photoperiod

This study was conducted to test the hypothesis that photoperiodor its rate of change significantly affects the rate of leafappearance (RLA) and final number of leaves (FNL) in wheat,as suggested from several time-of-sowing experiments. Two wheatcultivars (Condor and Thatcher) were sown in the field on 2Sep. 1992 at Melbourne (38°S). Photoperiod was extendedartificially to give five treatments up to terminal spikeletinitiation (TS) viz.: natural photoperiod (rate of change ofphotoperiod = 2 min d^-1), two faster rates of change (8·5and 13·3 min d^-1) and two constant photoperiods of 14·0and 15·5 h. After TS, the two constant photoperiods wereextended to 15·0 and 16·5 h, respectively, andtreatments were re-randomised, i.e. some plots received differentphotoperiod regimes before and after TS. The rate of leaf appearance maintained strong linear relationshipswith thermal time. It was greater for Condor [0·012-0·013(°C d)^-1] than for Thatcher [0·011-0·012 (°Cd)^-1] and did not alter during plant development or in responseto the change in photoperiod at TS. Rate of leaf appearanceon the main culm was not influenced by the rate of change ofphotoperiod nor by the average photoperiod. Cultivar and photoperiod significantly affected FNL on the mainculm. Condor produced more leaves than Thatcher under long butnot under short photoperiods. The rate of change of photoperioddid not affect FNL independently of the effect of average photoperiod.Most of the variation in FNL due to photoperiod resulted fromdifferences in duration of leaf initiation. The lack of effects of the photoperiod treatments on RLA contrastwith previous reports of its effects on the rate of phasic developmentfrom seedling emergence to double ridge. Therefore, the numberof visible leaves on the main culm (NL) at double ridge andat TS were not constant. However, NL on the main culm at doubleridge was closely correlated with FNL.Copyright 1994, 1999 AcademicPress Triticum aestivum L., wheat, leaf appearance, phyllochron, photoperiod     

Dual Floral Induction Requirements in Phleum alpinum

Flowering requirements of four Norwegian populations of Phleumalpinum were studied in controlled environments. A dual inductionrequirement was demonstrated in all populations. Inflorescenceinitiation had an obligatory requirement for short days (SD)and/or low temperature, while culm elongation and heading wereenhanced by long days (LD) and higher temperatures. At 3 and6 °C primary induction was almost independent of photoperiod,whereas SD was more effective than LD at higher temperatures.The critical temperature for primary induction was about 15°C in SD and 12 °C in LD. Saturation of induction required12 weeks of exposure to inductive conditions, although someheading and flowering took place with 6 weeks exposure to optimalconditions (9 °C/SD). Inflorescence development also tookplace in 8 h SD although it was delayed and culm elongationwas strongly inhibited compared with LD conditions. Only smalldifferences in flowering response were found between the populations. Phleum alpinum L., alpine timothy, dual floral induction, flowering, photoperiod, temperature     

Studies on the Physiology of Flowering of Timothy (Phleutm pratense L.): I. Influence of Daylength and Temperature on Initiation and Differentiation of the Inflorescence

Spikelet initiation is advanced and the proportion of plantswhich attain the reproductive condition is increased in S. 48timothy by lengthening the photo-period from 14 to 24 hours.In shorter periods of light, reproduction is almost completelyinhibited, and in 8-hour short days plants remain vegetativeeven after 35 weeks. Spikelet initiation at the shoot apex occursafter exposure to 3–5 long days followed by short days.Initiation also occurs when extended daylength is replaced by‘light-breaks’ during long nights, or when a singleleaf is photo-induced while the remainder of the plant receivesshort days. High temperatures promote spikelet initiation incontinuous light; in photoperiods nearer the threshold for floweringthis response is reversed and a rise in temperature from 55°to 75° F. increasingly inhibits reproduction. Once initiationhas occurred, spike differentiation is hastened by increasesin temperature or photoperiod. Internode elongation begins atthe time of spikelet initiation, and is promoted by temperatureand photoperiod. Elongated vegetative shoots may be producedwhen spikelet initiation fails in threshold photoperiods orhigh temperatures.     

Physiology of Flowering in Saccharum: I. DAYLENGTH CONTROL OF FLORAL INITIATION AND DEVELOPMENT IN S. SPONTANEUM L.

Flowering in two clones of Saccharum spontaneum L. is controlledby photoperiod. The earliest stages of development, ‘induction’and ‘initiation of the inflorescence axis primordium’(IAP) were optimally promoted under intermediate days of 12h 30 min, while the subsequent stage ‘initiation of inflorescencebranch primordia’ (IBP) was inhibited by days longer than13 h. The following stage ‘initiation of spikelet primordia’(ISP) showed a quantitatively intermediate response with anoptimum photoperiod of 9 h to 11 h. The elongation of the differentiatedinflorescence was found to be only slightly sensitive to photoperiodsof 13 h or longer in one of the clones. Unfavourable photoperiodsat stages following induction resulted in the arrest or delayof inflorescence development and when these were given duringthe IAP and IBP stages, reversion to the vegetative conditioncommonly occurred.     

Responses of Leaf and Tiller Emergence and Primordium Initiation in Wheat and Barley to Interchanged Photoperiod

The influence of constant (9, 13 and 19 h) and reciprocally-interchangedphotoperiods [at terminal spikelet (TS) or triple mound (TM)]on leaf, tiller and primordium development were examined usingphotoperiod-responsive cultivars of spring wheat, ‘UQ189’ and spring barley, ‘Arapiles’. In bothspecies, constant longer photoperiod reduced the duration fromsowing (S) to double ridge (DR), as expected. However, photoperiodsensitivity was not restricted to this mainly vegetative phase.There was also a marked increase or reduction in the durationof reproductive phases between TS/TM and heading (H) when plantswere transferred to shorter or longer photoperiods respectively,compared with controls. These responses were largely independentof the photoperiod during previous phases although minor effectsof the previous photoperiod were observed. For both species,the time course of leaf emergence was linear, or bi-linear,depending on the final leaf number on the main stem. The rateof leaf emergence was faster for the first six to eight leavesthan for the leaves appearing subsequently. The rate of emergenceof early-formed leaves was independent of photoperiod whereasthe rate of emergence of later leaves varied with photoperiod.Photoperiod also affected the dynamics of tillering. The rateof leaf primordium initiation was little affected by variationin photoperiod, but the rate of spikelet initiation increasedwith increases in photoperiod. The rates of leaf and spikeletprimordium initiation were both substantially higher in barleythan in wheat. The fact that the reproductive phase from TS/TMto H was largely independent of the duration of the previousphase provides evidence that this phase might be geneticallymanipulated to increase the time for floret development andhence grain number. Copyright 2000 Annals of Botany Company Photoperiod, rate of development and leaf emergence, tillering, wheat (Triticum aestivum L.) and barley (Hordeum vulgare L.)     

Expression of Vernalization Requirement and Spikelet Number in Synthetic Hexaploid Wheats and their Triticum tauschii and Tetraploid Wheat Parents

Vernalization requirement, as measured by days from sowing toear emergence (plants grown under an 18-h photoperiod), andspikelet number per ear were recorded for 17 synthetic hexaploidwheats and the six tetraploid (Triticum durum) and the ninediploid T. tauschii parents used to synthesize them. The tetraploid parents and the synthetic hexaploids had springphenotypes (little or no vernalization requirement) whereasthe T. tauschii parents were all winter types (strong vernalizationrequirement). The tetraploid wheats and the synthetic hexaploidsreached ear emergence 50·3 to 63·8 d and 58·2to 75·3 d after sowing, respectively, while the T. tauschiilines reached ear emergence 114·3 to 179·5 d aftersowing. The spring habit of the synthetic hexaploids demonstrates theepistasis of spring over winter habit. It is considered thatwith a presumed single vrn locus in the diploid species T. tauschiithe range of ear emergence in these lines is consistent withthe action of multiple alleles at that locus. Although there was no general epistasis for spikelet number,the tetraploid parents appear to be exerting more influenceover spikelet number in the synthetic hexaploids than T. tauschii.The well established association between the duration from sowingto ear emergence and spikelet number was not evident eitherwithin each ploidy group or when the 32 lines were consideredtogether. Triticum tauschii, Triticum durum, hexaploid wheat, spikelet number, vernalization requirement     

Day and Night Temperature Control of Floral Induction in Stylosanthes guianensis var. guianensis cv. Schofield

Floral initiation in seedlings of Stylosanthes guianensis var.guianensis cv. Schofield grown at a photoperiod marginal forflowering (12–11.75 h) was promoted by a combination oflow day (25 °C) and low night (16 or 21 °C) temperatures,and completely inhibited by a 35 °C day temperature. Additionally,earliness of floral initiation under naturally decreasing daylengthwas negatively related to temperature regime over the range35/30 to 20/15 °C (day/night). Stylosanthes guianensis var, guianensis, flowering, temperature, photoperiod, short-day plant     

The Uptake and Utilization of Phosphorus and Nitrogen by Diploid, Tetraploid and Hexaploid Wheats (Triticum spp.)

Twenty genotypes of Triticum and Aegilops wheats including diploid,tetraploid and hexaploid types, were grown under contrastingphosphorus (P) regimes (control and low P) at 15 °C by dayand 10 °C at night. Dry-matter production and phosphorusand nitrogen uptake and distribution were measured on matureplants. Phosphorus efficiency (PE) was considered in terms of yieldper unit of P in the main shoot and concentration of phosphorusin grain (per cent P). In the low-P set, PE, which ranged from110 to 715 mg grain mg^–1 P, increased as the yield perculm and dry-matter partitioning (harvest index) increased,with hexaploid > tetraploid > diploid. In both the controland low-P plants percentage P in grain decreased in the orderdiploids > tetraploids > hexaploid wheats. Grain phosphoruswas highly negatively correlated with the log of grain yield(r = –0.74; –0.88) and the log of harvest index(r = –0.80 and –0.88) for control and low-P plants,respectively. This suggests that future gains in plant harvestindex will cause smaller reductions in grain phosphorus concentrations.But, within either a high or low phosphorus supply, wheats witha given grain harvest index have significantly different grainphosphorus concentrations, and conscious selection for thischaracter is feasible. Low-P plants had similar grain nitrogen concentrations but lowernitrogen harvest indexes than control plants. Aegilops spp., Triticum spp., wheat, yield components, harvest index, polyploidy, evolution, phosphorus efficiency     

A Short Day Photoperiodic Response in Constantinea subulifera

SYNOPSIS. Constantinea subulifera, a perennial red alga witha bushy type growth, uses a short day (long night) photoperiodicresponse to initiate a new blade at the tips of several stipesin September to October. These blades complete the lag phaseof their growth during the winter via a food transfer from theold blade. Under a 9L–15D photoperiod it requires 21–28 daysto initiate a new blade. The critical photoperiod is 11–12hr. This is a phytochrome-mediated response which can be negatedby a low quantum dose light break of red or blue light in themiddle of a 16-hr dark period. Blades will initiate and growin complete darkness. The initiation of new blades in the fall and their slow growththroughout the winter (lag phase) gives Constantinea subuliferaan advantage in capture of habitat space.     

Effects of Gibberellin, Clone and Environment on Cone Initiation, Shoot Growth and Branching in Pinus contorta

Effects of photoperiod, temperature and gibberellin applicationwere clearly separated from clonal differences when small rootedcuttings, originating from two ‘floriferous’ treesof the same provenance of Pinus contorta Dougl., were treatedwith a simple micro-injection technique and grown in growthcabinets. Short days (10 h) for 11 weeks induced six times asmany female cones as long days (19.5 h), completely inhibitedfurther needle elongation after 5 weeks, and also led to enhancedbranching by year 3. Cool temperatures appeared to favour malecone initiation in year 1, and (in conjunction with long days)significantly promoted height in year 2. Injection with 1 mgGA_4/7 led to substantial and highly significant increases inbud growth in year 1, and in height, needle number and totalneedle length in year 2. Gibberellin treatment also increasedbranching but did not significantly affect internode elongationin year 2, nor cone initiation or needle elongation in year1. Highly significant clonal differences occurred, with onegenotype having longer leaves and buds in year 1, and up to80 per cent greater numbers and total lengths of needles inyear 2. Marked clonal differences in height growth, branchingand sex ratio were also found. The implications of both resultsand approach are discussed in relation to developmental physiology,genetic selection and advances in forestry research. leaf growth, height growth, branching, cone initiation, sex, photoperiod, temperature, controlled environments, gibberellin, vegetative propagation, clonal differences, Pinus contorta,, pine     

Development Rate in Wheat as Affected by Duration and Rate of Change of Photoperiod

A field study was conducted to test the hypothesis that wheatdevelopment rate responds to the rate of change of photoperiod.Two wheat cultivars (Condor and Thatcher) were sown on 18 Aug.1992 at Melbourne (38° S). Photoperiod was extended artificiallyto give five treatments up to terminal spikelet initiation (TS)viz.: natural photoperiod (rate of change of photoperiod, 2·3mind d^-1), two faster rates of change (9·8 and 13·1min d^-1) and two constant photoperiods of 14·0 and 15·5h. After TS, the two constant photoperiods were extended to15·0 and 16·5 h, respectively and treatments wererandomly re-allocated, i.e. some plots received different photoperiodregimes before and after TS. There were no significant differences among treatments in thelength of the period from sowing (S) to seedling emergence (E)phase, ranging from 15 to 16·3 d. The rate of developmentfrom E to TS responded to increases in photoperiod in both cultivars,increasing with average photoperiod across all treatments butthere was no effect of rate of change of photoperiod independentof its average photoperiod. The rate of development from TSto anthesis (A) did not show any trend with average photoperiod.This lack of effect of photoperiod on the period from TS toA contrasts with other results from the literature and possiblereasons for this conflicting result are discussed. Rate of changeof photoperiod did not affect the duration of the phase fromTS to A either. Therefore, the effect of photoperiod on theduration of the S-A period was strongly and positively correlatedto that of the length of the E-TS phase.Copyright 1994, 1999Academic Press Triticum aestivum L., wheat, phasic development, photoperiod, rate of change     

A Comparison of the Development of Multiflorous and Standard Wheats

This study was conducted to compare patterns of phenologicaldevelopment and agronomic traits of multiflorous and standardwheats (Triticum aestivum L. em. Thell.) when grown in environment-controlledgrowth rooms (20/15 °C, 16/8 h, day/night, 600 µmolm ² S ¹). Six winter and six spring habit genotypes were studiedin separate experiments. The winter multiflorous genotypes wereearlier than the winter standard genotypes. Their earlinessresulted in lower total biomass and grain yields, lower leafand tiller numbers per primary culm, and spikelet numbers perspike. Within the spring group, few differences were associatedwith spike type although the multiflorous genotypes had reducedgrowth as indicated by lower tiller and spike numbers per plant.Leaf emergence in the multiflorous genotypes, as in the standardgenotypes, was found to be a linear function of time. The tilleringpatterns of the multiflorous types were less pronounced thanfor the standards with lower maximum tiller numbers, and restricteddie-back and reinitiation. Floret numbers per spikelet werehigher in the multiflorous types due to higher initiation rates,longer initiation periods and/or reduced periods of die-back.The multiflorous trait was negatively associated with spikenumber and greater numbers of florets per spikelet did not alwaystranslate into greater numbers of kernels per spikelet. Becauseyield compensation was incomplete, yields per plant were lowerin the multiflorous genotypes than the standards. Triticum aestivum L. em, Thell., wheat, multiflorous trait, yield components, development     

Dormancy and Flowering in Anemone coronaria L. as Affected by Photoperiod and Temperature

The effects of day-length and temperature on flowering and dormancyinduction were studied in Anemone coronaria L., with plantsraised either from corms or achenes. An Israeli hybrid sourcewas used (de Caen cv. Hollandia x Israeli wild type). Dormancy onset is characterized by the cessation of foliageleaf production, the appearance of leaf scales protecting theperennating bud, and leaf senescence. Dormancy was induced byhigh temperature and long days but increasing temperatures (from17/12 °C to 32/12 °C) induced earlier dormancy thanprolonging the photoperiod (range 8–16 h). A significant(P = 0.01) interaction was found between these factors, withsmaller photoperiodic effects the higher the temperature. At22/17 °C the critical day-length for dormancy inductionwas between 11 and 12 h. The transition from the vegetative to the reproductive stageappears to be an autonomous process that occurs with developmentin plants raised from either corms or achenes and does not requireenvironmental induction. Photo- and thermoperiodic effects onflowering were indirect, being mediated through their influenceon dormancy induction. Anemone coronaria L., dormancy, flowering, photoperiod, thermoperiod     

The Effects of Daylength and Treatment with Gibberellic Acid on Spikelet Initiation and Development in Clipper Barley

The effects of photoperiod, light quality and a single applicationof gibberellic acid (GA₃) on the development of the main-stemapex in Clipper barley are reported. In 16 and 24 h days spikeletinitiation was rapid but extended over a short period whereasin 8 h photoperiods both spikelet initiation and developmentwere slower but occurred for a much longer time. Initiationalways stopped when the anther primordia were clearly visiblein the most advanced spikelet. Daylength extensions with lowintensity incandescent light were most effective when they followedrather than preceeded the 8 h period of high light intensity.Plants grown in 8 h high intensity followed by 8 h low intensitylight initiated spikelets almost as rapidly as those grown in16 h high intensity light. Thus, the effects of daylength onspikelet production were primarily mediated through photoperiodicallycontrolled processes rather than through photosynthesis andassimilate supply. The effects of applied GA₃ were long livedand greatest in short days where the rates of both spikeletinitiation and development were promoted. The parallels betweenthe effects of long days and GA₃ treatment are discussed togetherwith possible reasons for the cessation of initiation and thelong duration of the GA₃ effect. daylength, gibberellic acid, spikelet initiation, Hordeum vulgare L., barley, main-stem apex, primordia     

Temperature and photoperiodic control of developmental responses in climatic races of Achillea

Three climatic races of Achillea from central California (20,1400 and 3100 m elevation) were grown under controlled environmentalconditions at 14 combinations of temperature (0–27°C)and photoperiod (8 or 16 hr). Periodic measurements were madeon height and flowering. Dry weights of roots and shoots ofmature plants were determined. The greatest growth in heightand weight for each race occurred at 11°C on long days (16hr). The coastal race (20 m) grew well over a wide range oftemperatures (7–27°C) but the higher elevation races(1400 and 3100 m) grew well only at low temperatures (7–15°C).In contrast to the vigorous elongation and flowering of thecoastal race in short days at nearly all temperatures, racesfrom the higher elevations remained as rosettes. The sub-alpinerace (3100 m) exhibited the highest root-shoot ratios. Floweringpreceded stem elongation in the sub-alpine race but followedstem elongation in the coastal race. Exogenous applicationsof gibberellic acid (500 mg/liter) to rosette high-elevationraces promoted stem elongation and some flowering. Steroid applicationshad little or no effects. The high-elevation races may containa high-temperature sensitive control mechanism for gibberellinproduction. ¹Present address: Faculty of Botany, Ohio State University,Columbus, Ohio, U. S. A. (Received March 7, 1970; )     

Effects of Photoperiod, Temperature and Asynchrony between Thermoperiod and Photoperiod on Development to Panicle Initiation in Sorghum

The duration of the vegetative phase (i.e. days from sowingto panicle initiation) in sorghum [Sorghum bicolor (L.) Moench]is affected by photoperiod and temperature. Plants of severalcontrasting genotypes of sorghum were grown in controlled-environmentgrowth cabinets with either synchronous or asynchronous photoperiodsand thermoperiods. Apical development was recorded. Diurnalasynchrony between photoperiod and thermoperiod reduced durationsto panicle initiation when the temperature warmed after lightswent on and cooled after lights went off, but increased thesedurations when the temperature warmed before lights went onand cooled before lights went off. These effects were shownin the maturity lines 60M and SM100 and also in the USA cv.RS610 and the Sudanese landrace IS22365, but their magnitudevaried with genotype, photothermal regime, and the degree ofasynchrony. The greatest effect was detected in IS22365 grownat 30/21 °C (12 h/12 h) with a 12 h d^-1photoperiod whenthe temperature warmed 2.5 h before lights went on and cooled2.5 h before lights went off, when the duration from sowingto panicle initiation was 69 d compared with 37 d in the control(synchronous photoperiod and thermoperiod in each diurnal cycle). Reciprocal transfers of plants of IS22365 between short andlong days revealed that asynchrony principally affected theduration of the photoperiod-insensitive pre-inductive phaseof development; i.e. asynchrony affected the time (age) at whichthe plants were first able to respond to photoperiod. In thatinvestigation in controlled-environment growth chambers, thesubsequent photoperiod-sensitive inductive phase continued untilpanicle initiation. Subsequent reciprocal transfer experimentsin controlled-environment glasshouses in four different alternatingtemperature regimes employed synchronous photoperiods and thermoperiodsin short (11 h) days with temperature warming 1.5 h after thebeginning of the day in long (12.5 h) days. In those investigations,photoperiod sensitivity ended some time before (2.5–8.1d, mean 5.7 d) panicle initiation in IS22365, Naga White andSeredo. Moreover, whereas the duration of the photoperiod-insensitivepre-inductive phase was affected by temperature, the durationsof the photoperiod-sensitive inductive and the photoperiod-insensitivepost-inductive phases were not. Sorghum bicolor (L.) Moench; sorghum; asynchrony; photoperiod; thermoperiod; vegetative phase; panicle initiation