The Effect of Temperature and Moisture Content on the Longevity of Seed of Ulmus carpinifolia and Terminalia brassii

Seeds of the Smooth-leafed Elm (Uimus carpinifolia) and of thetropical forest tree Terb (Terminalia brassii) were stored hermeticallyand sampled at intervals for periods of up to two years. Bothspecies possess ‘orthodox’ seed (increasing longevityis observed as either moisture content or temperature are reduced)within the temperature ranges from — 13 to 52°C (Elm)and from —4 to 42°C (Terb) and within the moisturecontent ranges from 3 to 19 per cent (Elm) and from 5 to 14per cent (Terb) on a fresh weight basis. Elm seed stored at—75°C showed the expected relationship between longevityand moisture content, but did not differ significantly in longevityfrom seed kept at — 13°C when moisture contents wereheld constant. Probit analysis of the relationship between germinationpercentage and time was performed for each storage environment,yielding a slope from which the standard deviation of the distributionof seed deaths over time () was calculated. Standard deviationvalues were used in turn to determine the values of constantsin a viability equation which had previously been applied toseed of barley, chickpea, cowpea and soybean. The equation,which gave a good fit to the results obtained, can be used topredict viability for seed in storage over a wide range of environmentalconditions. Some limitations to the applicability of the viability equationwere defined. At 22 per cent and higher moisture contents Elmseed survived longer than predicted. Furthermore, all Elm andTerb seed was killed quickly on placing in —75°C at22 and 20 per cent moisture content respectively, but high viabilitywas retained for several days at 19 and 17 per cent respectively.Practical implications of the results are discussed. Uimus carpinifolia Gleditsch, Smooth-leafed Elm, Terminalia brassii Exell, Terb, seed longevity, seed storage, moisture content, temperature     

Thermostability of the Photosynthetic System of the Thermoacidophilic Alga Cyanidium caldarium in Continuous Culture

Ford, T. W. 1986. Thermostability of the photosynthetic systemof the thermoaadophilic alga Cyanidium caldarium in continuousculture.—J. exp. Bot. 37: 1698–1707. Cyanidium caldarium, when exposed to gradual increases in temperaturein continuous culture, exhibits a growth temperature maximumof 55 °C. This correlates with the thermostability of themembrane-located photosynthetic electron transport system butnot with in vivo ribulose-1,5-bisphosphate (RUBP) carboxylaseactivity, which retained full activity after 1 h at 60 °C.Pigment content and phycocyanin: chlorophyll a ratios were relativelyconstant at growth temperatures up to 50 °C, but both declinedin cells cultured at 55 °C. Some modification of the photosyntheticsystem of the alga, in response to growth temperature, was detectedwith both oxygen evolution and RUBP carboxylase activity showingimproved thermostability in cells grown at 50 °C or 55 °Ccompared with those cultured at lower temperatures. However,this enhanced thermostability was at the expense of total pigmentcontent and overall photosynthetic capacity which were considerablyreduced in high temperature cells, as was the temperature spectrumfor efficient RUBP carboxylase operation. The contributionsof membrane and macromolecular components of the cell to theimposition of optimum and maximum growth temperatures are discussed. Key words: Cyanidium, photosynthesis, RUBP carboxylase     

Phase Transition Temperatures Determined for Chloroplast Thylakoid Membranes and for Liposomes Prepared from Charged Lipids Extracted from Thylakoid Membranes of Higher Plants

Lipid phase separation temperatures of intact thylakoid membranesfrom a number of chilling sensitive plants were measured usingchlorophyll a as the intrinsic fluorescent probe. The phospho-and sulfolipids were extracted from the thylakoid lamellae ofthese plants and purified by silicic acid column and thin layerchromatographies. These separated lipids were eluted and recombinedto give a total charged anionic thylakoid lipid fraction thatwas used to prepare liposomes containing purified chlorophylla as the fluorescent probe. The phase separation temperaturesof these liposomes were compared to phase separation temperaturesin intact thylakoid membranes isolated from the same plants. The chilling-sensitive plants—corn, pepper, tomato andwater hyacinth — showed phase separation temperaturesranging from 9 to 19°C for both the liposomes and the thylakoidmembranes. In addition, low temperature phase separations wereseen from –21 to –27°C. Mimulus, which is notas chilling sensitive as the former plants, had a phase separationtemperature near 0 to 2.5°C and at –27°C. In general,there was a good agreement between the phase separation temperaturesof intact thylakoids and the purified anionic lipid fractionextracted from these thylakoids. Similar results were obtained using either trans-parinaric acidor chlorophyll a as the fluorescent probe in liposomes madefrom anionic thylakoid lipids or in liposomes prepared frompure dimyristoyl phosphatidyl choline, distearoyl phosphatidylcholine, or mixtures of equal amounts of these phospholipids. ¹ CIW-DPB Publication # 728. ³ Present address: Laboratory of Experimental Physics, Departmentof Biophysics, State University of Utrecht, Princetonplein 5,Utrecht, The Netherlands. (Received January 18, 1981; Accepted July 2, 1981)     

Growth of Trifolium subterraneum L. Selected for Sparse and Abundant Nodulation as Affected by Root Temperature and Rhizobium Strain

Root temperature greatly affected plant growth whether or notplants depended on symbiotic nitrogen fixation. The two plantselections responded differently to the three strains of Rhizobiumand this response was differentially affected by root temperature. Plant yield was significantly decreased by each fall of 4 °Cin temperature from 19 to 7 °C by amounts that dependedboth on the host and Rhizobium strain. Symbiosis with strainTA1, originally isolated from a cold environment, was most tolerantof a root temperature of 11 °C; TA1 produced as much ormore plant material of the abundantly nodulating host in 40days growth at 7 and 11 °C as did the uninoculated plantsgiven KNO³. Root temperature affected the number, rate of formation, anddistribution of nodules on the root system. At 7 °C fewernodules formed than between 11 and 19 °C. At 7 °C nodulesdid not form on secondary roots by 40 days but at 11 °Cthe secondary roots nodulated rapidly between 30 and 40 days.Nodule formation at 19 °C was almost completed at 20 days,when secondary root nodules accounted for 60 per cent of thetotal. Within the range 15 to 19 °C, at which the originalselections for sparse and abundant nodulation were made, plantsnodulated true to selection, but not at 11 °C. At 7 and11 °C plants nodulated with TA1 yielded more with increasingnumber of nodules.     

Effect of Temperature on Interception and Conversion of Solar Radiation by Stands of Groundnut

Stands of groundnut were grown in controlled environment glasshousesat air temperatures of 19, 22, 25, 28, and 31°C. Leaf areaindex (L) increased with rise of temperature, and after 85 dwas about 10-fold larger at 31°C than 19°C. Over mostof the range of temperature, both L and fractional interceptionof solar radiation (f) were functions of thermal time accumulatedfrom sowing (above a base of 10°C). In this respect, theywere tightly coupled to developmental rate at the main apex.In one experiment, only 38% of seeds emerged at 22°C and21% at 19°C, compared with more than 70% at 25°C and31°C, but the low population density was compensated byfaster leaf expansion by each plant (at 22°C only) and agreater fraction of solar radiation intercepted by unit leafarea. The amount of solar radiation intercepted by stands increasedwith rise in temperature, but the greatest differences betweentreatments occurred before the canopies achieved complete groundcover (i.e.f>0.9) and the relative effect of a rise in temperaturediminished the longer the duration of growth. The dry matterproduced for unit solar radiation intercepted was not stronglyaffected by temperature between 22°C and 31°C, wherethe mean was 2.1 g MJ^–1; the value at 19°C was uncertainsince the stands were sparse throughout the experiment. After85 d, the stand at 31°C had produced eight times the drymatter of that at 19°C—a difference caused mainlyby the effect of temperature on the rates of development andexpansion. Key words: Dry matter production, groundnut, radiation interception, temperature, thermal time, roses     

Grazing of echinoderm larvae (Paracentrotus lividus and Arbacia lixula) on naturally occurring particulate matter

Larvae (72 hr old) of P. lividus and A. lixula grazed on varioussuspensions of natural particulate matter with a size rangeof 2 to 30 microns, and on two species of algae (Phaeodactylumtricor-nutum and Nitzschia sp.) — Larvae graze most in the size range where the particleconcentration is highest. — If larvae deplete certain size categories of particlesthey then graze other size ranges in which the concentrationis still high. — The grazing rate of the two species varied between 988and 91.949 µm³ per pluteus per hour. — For A. lixula larvae the grazing rate increases withincreasing temperature to a maximum at 22°C.     

H+ Efflux and Trans-Root Potential Measured while Increasing the Temperature of Solutions Bathing Excised Roots of Zea mays

Kennedy, C. D. and Gonsalves, F. A. N. 1988. H⁺ efflux and trans-rootpotential measured while increasing the temperature of solutionsbathing excised roots of Zea mays.—J. exp. Bot. 39: 37–49. Novel temperature-ramp procedures have been used to measureH⁺ efflux and trans-root potential of excised roots of Zea mays(var. Fronica). Two types of experiment were performed: (1),increasing temperature from 17°C, and (2), pre-cooling theroots to 1°C before starting the temperature ramp. The ratesof increase of temperature for H⁺ efflux and trans-root potentialexperiments were 0·5 and 2·1°C min^–1respectively The H⁺ scans revealed strong sharp maxima at 30°C and 32°C,for non-pre-cooled and pre-cooled roots respectively, the latterbeing significantly smaller. The trans-root potential scansfor the pre-cooled roots showed a corresponding maximum at 30°C,which was inhibited by KCN (1-0 mmol dm^–3) with or withoutSHAM (10 mmol dm^–3), or Hg²⁺ (1, 10, 100 µmol dm^–3)in the bathing solutions. Some of the evidence suggests thatthese maxima are associated with electrogenic H⁺ pumping, mediatedby a plasma membrane-bound ATPase. However, no correspondingmaximum was observed in the trans-root potential scans for non-pre-cooledroots, the potential remaining at about — 75 m V from20°C to 35°C. As there is a 7-fold increase in H⁺ effluxbetween 20°C and 30°C, the relationship between netH+ efflux and electrogenic proton pumping in these roots isby no means clear. Some possibilities are considered here. Pre-cooled and non-pre-cooled roots show clear maxima in thetrans-root potential scans at about 46°C, at which temperaturethere is a slight net H⁺ influx. This, and other less prominentfeatures observed, are briefly discussed. Key words: H⁺ efflux, trans-root potential, temperature-ramp procedure, Zea mays, roots     

Improved Equations for the Prediction of Seed Longevity

Equations for predicting seed longevity in storage have beenimproved so that they now take into account variations withina species in initial seed quality—which is affected bygenotype and pre-storage environment—and so that theyare more accurate over a wider range of storage environmentsThese improvements have been incorporated into a seed viabilitynomograph for barley (Hordeum distichum L.) which may be usedto predict percentage viabihty of any seed lot after any timein any storage environment within the range –20 to 90°C and 5–25 per cent moisture content. Applicationsof the improved equations to seed drying and to long-term seedstorage for genetic conservation are discussed. Hordeum distichum L., barley, seed viability, seed longevity prediction, seed storage, seed drying, storage temperature, seed moisture content, genetic resources conservation     

Development of Ethylene Biosynthesis in Pear Fruits at --1 {degrees}C

Knee, M. 1987. Development of ethylene biosynthesis in pearfruits at — 1 °C.—J. exp. Bot. 38: 1724–1733. The regulation of ethylene synthesis in pear fruits was investigated.During storage for 60 d at — 1 °C the rate of ethylenesynthesis increased 100-fold but the concentration of 1-aminocyclopropane-l-carboxylicacid (ACC) increased only 2-fold and ACC synthase activity waslow. On transfer to 15 °C after storage at — 1 °Cethylene synthesis increased 10-fold within 10 h but ACC synthaseactivity only increased rapidly after 24 h; the decline in ACClevels during the first 16 h at 15 °C was insufficient tosustain ethylene synthesis. Ethylene synthesis was further investigatedusing discs cut from the mid cortex of pear fruits. Synthesiswas inhibited by aminoethoxyvinylglycine (AVG) and amino-oxyaceticacid at all stages of ripening. The rate of synthesis and ACCsynthase activity increased rapidly after slicing of pears heldat — 1 °C but more slowly in discs cut from pearsimmediately after harvest. Cycloheximide (CHI) inhibited theseincreases and reversed increases resulting from pre-incubationof discs. A combination of CHI and AVG abolished the capacityof discs to synthesize ACC and ethylene production was curtailed.Cordycepin and actinomycin-D were less effective as inhibitorsof the development of ethylene synthesis and ACC synthase activitythan as inhibitors of incorporation of 5-[³H] uridine into totalRNA or poly A rich RNA. The ability of discs to develop ethylenesynthesis and ACC synthase activity in the presence and absenceof cordycepin increased concurrently during storage of wholefruits at — 1 °C. This suggested that mRNA for ACCsynthase was formed at — 1 °C. Key words: 1-Aminocyclopropane-l-carboxylic acid, ethylene, fruit ripening, Pyrus communis L. (fruit ripening)     

Plant Growth-promoting Rhizobacteria and Soybean [ Glycine max (L.) Merr.] Growth and Physiology at Suboptimal Root Zone Temperatures

Application of plant growth-promoting rhizobacteria (PGPR) hasbeen shown to increase legume growth and development under optimaltemperature conditions, and specifically to increase nodulationand nitrogen fixation of soybean [Glycine max (L.) Merr.] overa range of root zone temperatures (RZTs). Nine rhizobacteriaapplied into soybean rooting media were tested for their abilityto reduce the negative effects of low RZT on soybean growthand development by improving the physiological status of theplant. Three RZTs were tested: 25, 17.5, and 15 °C. At eachtemperature some PGPR strains increased plant growth and development,but the stimulatory strains varied with temperature. The strainsthat were most stimulatory at each temperatures were as follows:15 °C—Serratia proteamaculans 1–102; 17.5 °C—Aeromonashydrophila P73, and 25 °C—Serratia liquefaciens 2–68.Because enhancement of plant physiological activities were detectedbefore the onset of nitrogen fixation, these stimulatory effectscan be attributed to direct stimulation of the plant by thePGPR rather than stimulation of plant growth via improvementof the nitrogen fixation symbiosis. Legume; nitrogen fixation; nodulation; root zone temperature; PGPR     

Physiology of Post-Pollination Exudate Production in Acacia

Marginson, R., Sedgley, M. and Knox, R. B. 1985. Physiologyof post-pollination exudate production in Acacia—J. exp.Bot. 36: 1660–1668. Stigmas of A. wattsiana produced 1260 nl of secretion by 90min after pollination. The optimum temperature for post-pollinationsecretion in A. baileyana, A. brownii and A. iteaphylla was20°C. Both self and cross intraspecific, interspecific andintergeneric pollinations produced a similar positive responsein A. iteaphylla and A. baileyana. In all cases aged pollenwas as effective as fresh pollen despite reduced fluorescencein the fluorescein diacetate test. Live yeast cells, fixed chickenerythrocytes, glass beads, talc and Biogel P150 did not stimulatesecretion, nor did pollen which had been washed in water orethanol despite high retention of viability in some cases Pollendiffusates dried on to glass beads produced a positive responsein A. iteaphylla and A. gracifolia. Intraspecific and interspecificpollinations involving fresh Acacia pollen resulted in pollengermination on the stigma and pollen tube growth in the styleof A. iteaphylla and A. baileyana. In contrast washed pollenfailed to germinate and pollen germination and tube growth werereduced at 35 °C as compared with 20 °C. Key words: Acacia, pollination, secretion     

The Temperature Response of Gas Exchange in Sorghum Leaves and the Effect of Heterosis

The aim of this research was to describe the temperature responseof gas exchange in grain sorghum (Sorghum bicolor L. Moench)leaves as temperature was increased in a fashion similar toits daily increase in a hot environment. The hypothesis thatsorghum hybrids manifested heterosis for carbon dioxide exchangerate on a wider temperature range as compared with their parentallines was also evaluated. Gas exchange of detached turgid leaveswas measured in four sorghum hybrids and their parents as leaftemperature rose steadily from 32 °C to 43 °C in 4 h.CER was maximal at about 37–40 °C depending on thegenotype. In one genotype (Tx378), CER was maximal at 42 °C.In three out of four hybrids significant heterosis was foundfor CER at the lower, the higher or at the full range of temperaturestested depending on the hybrid. Consequently, all three heterotichybrids displayed a greater temperature range for high CER ascompared with their parents. Heterosis in CER was largely explainedby heterosis in stomatal conductance, though the effects ofnon-stomatal components could not be elucidated here. Heterosisin transpiration was revealed in the same three hybrids, especiallyat moderate temperatures. Since heterosis in CER was relativelygreater than heterosis in transpiration, significant heterosisin transpiration ratio at moderate temperatures was seen intwo of the four hybrids. An effect of heat hardening on CERwas observed in parental line Tx430 and its two hybrids as seenin the reduction of CER at 36–37 °C and its subsequentrecovery as temperatures rose slowly to 43 °C. The effectof heat hardening on photosynthesis was also observed in someof the genotypes as a hysteresis in the association betweenstomatal conductance and CER as temperatures increased. Thishysteresis indicated that, for the same stomatal conductance,CER was greater after than before leaves were exposed to hightemperature. Key words: Photosynthesis, hybrid vigour, heat stress     

Cold Acclimation, Freezing Resistance and Protein Synthesis in Alfalfa (Medicago sativaL. cv. Saranac)

Mohapatra, S. S., Poole, R. J. and Dhindsa, R. S. 1987. Coldacclimation, freezing resistance and protein synthesis in alfalfa(Medicago sativa L. cv. Saranac).—J. exp. Bot. 38: 1697–1703. Changes in freezing resistance (percent survival at —10°C), pattern of protein synthesis and translatable mRNApopulation during cold acclimation of alfalfa (Medicago sativaL. cv. Saranac) have been examined. Two days of cold acclimationat 4 °C increased freezing resistance from about 6% to 40%,protein content by 200% and total RNA content by 100%. Acclimationfor longer periods did not cause further increases in freezingresistance, protein content or RNA content. Examination of proteinchanges by sodium dodecyl sulphate-polyacrylamide gel electrophoresis(SDS-PAGE) coupled with protein staining, and by fluorographyof in vivo labelled proteins separated by SDS-PAGE, showed thatseveral proteins are increasingly or newly synthesized duringcold acclimation. Analysis of in vitro translation productsby SDS-PAGE and fluorography shows changes in the populationof translatable mRNAs. It is concluded that in this varietyof alfalfa cold acclimation for only 2 d is sufficient to confermaximum freezing resistance, and that changes in proteins duringcold acclimation are regulated most probably at the transcnptionallevel. Key words: Freezing resistance, protein synthesis, cold acclimation, SDS-PAGE, Medicago sativa L.     

INFLUENCE OF TEMPERATURE ON SURVIVAL AND GROWTH OF TWO FRESHWATER PLANORBID SPECIES, PLANORBARIUS CORNEUS (L.) AND PLANORBIS PLANORBIS (L.)

The survivorships and growth rates ofPlanorbarius corneus andPlanorbis planorbis were measured during the whole life spanof the snails at constant temperatures of 5, 10, 15, 20 and25°C. Life expectancy tables were constructed. The maximumlongevities for P. corneus (231 weeks) and P. planorbis (175weeks) occurred at 15°C and 10°C respectively. The extremetemperatures were particularly unfavourable. Snail growth which was expressed logarithmically was most sensitiveto temperature during the exponential stage. However, if weconsider a given species duringjts entire life span, there wereno significant differences between temperature groups whichwere in order of decreasing suitability: —P. corneus: 25, 20 and 15°C; 10°C; 5°C; —P.planorbis: 20 and 15°C; 25 and 10°C; 5°C. Using the growth constants from the Von Berta-lanffy's modeladjusted to give a gaussian curve, it was calculated that theoptimum temperatures for the growth of P. planorbis and P. corneuswere 19 and 20.5°C respectively. A mathematical model basedon spline functions makes it possible to predict the growthof snails over a wide range of temperatures. (Received 2 June 1993; accepted 18 November 1993)     

Freezing avoidance mechanism of primordial shoots of conifer buds

Excised winter buds of very hardy fir supercooled to —30or — 35?C, though primordial shoots excised from thesewinter buds (freezing point: about —5.5?C) supercooledonly to —12 to — 14?C. Also, excised primordialshoots did not tolerate freezing, but were rather resistantto desiccation. Differential thermal analysis (DTA) of primordialshoots revealed that the capability of supercooling increasedwith decreasing water content and that no exotherm could bedetected in the primordial shoots with a water content belowabout 20%. When excised whole buds were cooled very slowly,the exotherm temperature shifted markedly to a lower value andthe exotherm became much smaller. Also, masses of needle icewere observed, mainly beneath the crown of the primordial shoot.From these results, it may be concluded that most of the waterin primordial shoots gradually migrates out through the crownand freezes as the temperature decreases (extraorgan freezing),which enables primordial shoots to survive at very low temperatures.Winter buds of Abies balsamea held at — 20?C for 30 daysand then slowly cooled down to —50 or —60?C remainedalive. Thus, there seems to be no low temperature limit to thisfrost avoidance mechanism, if the primordial shoots can resistintensive freeze-dehydration. Low temperature exotherms wereobserved in all genera which belong to Abietoideae and Laricoideaeof Pinaceae, all of which have a crown in the primordial shoots,but not in other conifers. ¹ Contribution No. 2037 from the Institute of Low TemperatureScience. (Received June 25, 1979; )     

Isocitrate Lyase from Germinating Soybean Cotyledons: Purification and Characterization

Ruchti, M. and Widmer, F. 1986. Isocitrate lyase from germinatingsoybean cotyledons: purification and characterization.—J.exp. Bot. 37: 1685–1690. Isocitrate lyase (E.C. 4.1.3.1 [EC] ) was purified from the cotyledonsof 7-d-old soybean seedlings. Three molecular forms were detectedwith pi values of 6·46, 6·25 and 6·0. Themain form (pl = 6·46) had an approximate Mr of 130000,a pH optimum of 8·0, a K_m (isocitrate) close to 2·0mol m^–3 and a molecular activity of 615 min ^–1 at25 °C. The purified enzyme is not a glycoprotein and isheat labile. Key words: Isocitrate lyase, soybean     

The Effect of Temperature on Growth, Oil Yield and Oil Quality of Japanese Mint

Field studies of factors affecting yield and composition ofJapanese mint oil are confounded by interacting environmentalagencies. The effect of temperature, separated from other influences,was examined on Japanese mint (Mentha arvensis L. var. piperascensHolmes) in the naturally lit controlled environment Phytotron,Canberra, Australia. The So Wo I variety of Japanese mint wasgrown under 12 treatments consisting of four day and three nighttemperatures. Maximum leaf, stem and root dry matter was producedunder 30 °C day temperatures, regardless of night temperature,but maximum stolon growth occurred at 20 °C temperatures.Generally, oil yield could be estimated by determining dry matterof above ground parts, but number of oil glands on the leavesdid not provide a reliable indication of oil yield. Differenttemperature treatments did not appear to affect greatly thepercentage of menthol, an important component of the oil. Underfield conditions, maximum yield of Japanese mint oil has beenfound to occur during flowering. This close relationship betweenoil yield and flowering did not occur under extremes of temperature.Although 30 °C was found to be the optimum day temperaturefor oil yield in this experiment where only one harvest wasmade, it is possible that where multiple harvests are conducted,a lower optimum temperature might be found, since the highertemperature was detrimental to dry matter reserves in the stolons. Mentha arvensis L. var. piperascens Holmes, Japanese mint, temperature, controlled environment, menthol, methone, essential oil, flowering     

The Pigeonpea-Rhizobium Symbiosis as Affected by High Root Temperture: Effect on Nodule Formation

The effect of elevated temperature on root hair formation, adsorptionof rhizobia, and nodulation of pigeonpea was studied. Nodulationwas adversely affected at both 28°C and 37°C, and theeffect was more pronounced during the first 3 d of nodule formation.Temperatures above 32°C resulted in the reduction or evencomplete absence of root hairs. The root hairs formed at elevatedtemperatures were spheroid and stunted in growth. The numberof loosely and firmly adsorbed cells of Bradyrhizobium spp.(Cajanus) strain CC1021 on pigeonpea roots were reduced to 49%and 38%, respectively, at 37°C. Key words: Pigeonpea, Bradyrhizobium spp. (Cajanus), high root temperature, root hairs, adsorption     

Response to Temperature in a Stand of Pearl Millet: 10. PARTITION OF ASSIMILATE

Effects of temperature on partition of assimilate between leaves,stems and panicles of pearl millet are analysed in terms ofa duration (t_w) over which a structure increased in weight,and a partition factor (p)—the fraction of new dry matterallocated to the structure during t_w. The value of tw was, forall structures, inversely proportional to temperature abovea base of 10 °C and below an optimum of 28 to 30 °C.For stems and panicles, the value of p was, with one exception,little affected by temperature. The dry weight of these structureswas, therefore, proportional to t_w, and decreased with risein temperature. (The exception was panicles at the lowest temperature,19 °C, for which p was reduced by 40% because few grainswere set.) For leaves, however, p increased with rise in temperature,counteracting the effect on t_w, such that dry weight changedlittle with temperature. The optimum temperature for reproductiveyield was 22 °C, but the proportion of the total dry matterallocated to reproductive structures changed little between22 °C and 31 °C. Key words: Pearl millet, temperature, thermal time, partitioning     

The Influence of Temperature on Seed Germination Rate in Grain Legumes: III. A COMPARISON OF FIVE FABA BEAN GENOTYPES AT CONSTANT TEMPERATURES USING A NEW SCREENING METHOD

Ellis, R. H., Simon, G. and Covell, S. 1987. The influence oftemperature on seed germination rate in grain legumes. III.A comparison of five faba bean genotypes at constant temperaturesusing a new screening method.—J. exp. Bot. 38: 1033–1043. A screening procedure which requires information on the progressof germination at only four temperatures was able to definethe response of the rate of seed germination to sub- and supra-optimaltemperatures for whole seed populations of each of five fababean (Vicia faba L.) genotypes. In one population of the cultivarSutton the models for sub- and supra-optimal temperatures derivedfrom the screen satisfactorily explained observations from anearlier separate investigation at a wider range of temperatures.Two discrete groups of genotypes were identified. Within eachgroup the base temperature T_b did not differ significantly:for the landraces Lebanese Local Large and Syrian Local Largethe value was estimated to be –7·5°C and forthe landrace Lebanese Local Small and the cultivars Sutton andAquadulce it was –4·0°C. The optimum temperaturefor the 50th percentile [T_o(50), at which temperature the rateof germination is maximal] also varied between these two groupsof genotypes, being 20·5–21·5°C forthe first group and 24·5–26·0°C forthe second. In several temperature regimes some of the viableseeds within a seed population failed to germinate. Nevertheless,even at temperatures where a substantial proportion of the seedsfailed to germinate the models defined by the screening methodpredicted the germination times of those seeds which did germinate. Key words: Faba bean, seed gemination rate, temperature