Effects of Low Temperature on Winter Wheat and Cabbage Leaves

Contents of soluble proteins, proline and chlorophyll in winter wheat (Triticum aestivum cv. Doğu-88) and cabbage leaves (Brassica oleracea convar. acephala) during acclimation to low temperature were investigated. When both of the plants species were cold acclimated, soluble proteins, proline and chlorophyll contents were higher than in the controls (non-acclimated). Also protein patterns differed between the plants at control and cold conditions. This revised version was published online in July 2006 with corrections to the Cover Date.     

水分亏缺对冬小麦净光合速率影响程度研究

水分亏缺对冬小麦净光合速率影响程度研究王慧（西北大学城市与资源学系,西安７１００６９）ＥｆｆｅｃｔｏｆＷａｔｅｒＤｅｆｉｃｉｔｏｎＮｅｔＰｈｏｔｏｓｙｎｔｈｅｓｉｓＲａｔｅｏｆＷｉｎｔｅｒＷｈｅａｔ．ＷａｎｇＨｕｉ（ＤｅｐａｔｍｅｎｔｏｆＵｒｂａｎ...     

The Redistribution of Assimilate in Field-grown Winter Wheat

The long- and short-term movement of carbon in a field cropof winter wheat was investigated with the radioactive tracercarbon-14. The flag leaves of individual plants assimilateda pulse of ¹⁴CO₂ and the plant parts were assayed subsequently.Groups of plants were pulse-labelled four times during the mainperiod of growth—twice before and twice after anthesis.Plants were harvested and assayed twice weekly after labellingand the time-course of the changes in the amount of ¹⁴C recoveredfrom the leaves, stems and ears was observed for each groupof plants. Concurrently with these long-term studies, otherwheat plants were pulse-labelled, then harvested and assayed24 h later. The partitioning of ¹⁴C between leaves, stem, earand in some cases roots, was measured over the period from thestart of stem elongation to the end of grain filling. Two distinct types of relocation of carbon were observed. Carbonassimilated early in the growth of the plant and used in thegrowth of new leaves was seen to be partly relocated to theear. Carbon assimilated 8 d after anthesis was partly storedin the stem, and 15 d later relocated to the ear. This relocationcorresponded to a decrease in stem dry mass seen in growth analysis.Little other change in the ¹⁴C content of the plants occurred,suggesting that most respiration used current rather than storedassimilate. Key words: Carbon assimilate, redistribution, wheat     

Effects of Low Concentrations of Sulphur Dioxide on Net Photosynthesis and Dark Respiration of Vicia faba

Rates of net photosynthesis, P_N, and dark respiration of Viciafaba plants were measured in the laboratory in clean air andin air containing up to 175 parts 10^–9 (500 µg m^–3)SO₂. At all SO₂ concentrations exceeding 35 parts 10^–9,P_N was inhibited compared with clean air. At light saturation,the magnitude of inhibition depended on SO₂ concentration butat low irradiances the inhibition was independent of concentration.Dark respiration rates increased substantially, independentof concentration. When exposures continued for up to 3 days,P_N returned to clean air values about 1 h after fumigation ceased:dark respiration recovered after one photoperiod. There wereno visible injuries. Reviewing possible mechanisms responsible for the inhibitionof P_N, it is suggested that SO₂ competes with CO₂ for bindingsites in RuBP carboxylase. Analysis of resistance analoguesdemonstrates that SO₂ altered both stomatal and internal (residual)resistances. A model of crop photosynthesis shows the implications of theobserved responses for the growth of field crops in which plantsare assumed to respond like laboratory plants. Photosynthesisof the crop would be less sensitive than that of individualplants to SO₂ concentration. Daily dry matter accumulation ofhypothetical ‘polluted crops’ would be substantiallyless than clean air values but would vary relatively littlewith SO₂ concentration. It is concluded that physiological basesexist to account for observed reductions in growth of plantsat very low SO₂ concentrations, and that thresholds for plantresponses to SO₂ require reassessment.     

Effects of Low Temperature on Photosynthesis in Flag Leaves of Rice (Oryza sativa L.)

After low temperature (16℃) treatment, the net photosynthetic rate, chlorophyll content and FBPase activity tended to decrease and ratio of chlorophyll a/b, stomatal resistance, sucrose and starch content tended to increase in rice flag leaves at heading stage. However, the Pi content and water potential did not show pronounced change. The flag leaf chloroplasts contained large starch grains after three days at low temperature. The recovery of net photosynthetic rate in the flag leaves which had recieved stress at 16℃ for three days and transferred to normal nature condition was gradually increased. It almost came up to the value of control after five days. However, the decrease in stomatal resistance was rapid. It was almost lowered to the value of control after one day. Under normal nature comdition for five days, the chlorophyll content and FBPase activity reached near to the value of control. Meanwhile, the ratio of chlorophyll a/b, the sucrose and starch content almost declined to the value of control. The large starch grain in flag leaf chloroplast also disappeared. According to the experimental results, we discussed the relationship between the above-mentioned various changes and net photosynthetic rate We suggested that the effect of low temperature on photosynthesis might be one of factors in yield-reduction of rice.     

The Effects of Sulphur Dioxide on Phloem Transport in Two Cereals

Gould, R. P., Minchin, P. E. H. and Young, P. C. 1988. The effectsof sulphur dioxide on phloem transport in two cereals.—J.exp. BoL 39: 997–1007. In vivo investigations using ¹¹C-labelled photosynthate revealedthat there is a change in the patterns of tracer profiles whencereal leaves are exposed to SO₂. The change after exposureto SO₂ was interpreted in terms of a decrease in lateral waterflow into the sieve tubes brought about by reduced phloem loadingalong the length of a leaf. Analysis also revealed that thespeed of translocation was reduced, as expected by the Munchmodel of phloem transport. Key words: Sulphur dioxide, phloem transport, cereal leaves     

Plants under Climatic Stress: I. Low Temperature, High Light Effects on Photosynthesis

Photosynthetic rates of both C₄- and C₃-pathway plants grown at 25 C were measured before and during a period of chilling stress at 10 C, and then again at 25 C following various periods at 10 C. When temperatures are first lowered photosynthetic rates drop immediately, then undergo a further reduction which is quite rapid in species such as Sorghum, maize, and Pennisetum; slower in soybean; and very slow in Paspalum and ryegrass. Visible light causes progressive permanent damage to the photosynthetic capacity of leaves during this period of lowered photosynthesis. The extent of damage increases with light intensity and the length of time leaves are held at 10 C but varies greatly between species, being roughly correlated with the extent to which chilling initially and subsequently lowers photosynthesis. Three days of chilling (10 C) at 170 w·m⁻² reduces the photosynthetic capacity of youngest-mature Paspalum leaves only 30 to 40% while Sorghum leaves are essentially inoperative when returned to 25 C after the same stress. Root temperature has a substantial rapid effect on photosynthesis of soybean and little immediate effect on Sorghum. Photosynthesis of stress-intolerant species (Sorghum) is reduced only slightly more than that of semitolerant species (Paspalum) when temperatures are lowered at mid-photo-period, but to a far greater extent if temperatures are reduced at the commencement of a photoperiod.     

Effect of Verticillium dahliae on Photosynthesis, Leaf Expansion and Senescence of Field-grown Sunflower

On the basis of known sunflower (Helianthus annuus L.) responsesto soil water deficit, it is proposed that the effect of thefungus Verticillium dahliae Klebahn on plant leaf area precedesand is greater than its effect on leaf photosynthesis and stomatalconductance. To test this hypothesis, we measured shoot andleaf area growth, leaf photosynthetic rate, stomatal conductanceand disease symptoms in a field experiment including hybridsof high (Sankol) and low (Dekasol 3900) susceptibility to V.dahliae. Plants inoculated with V. dahliae and controls werecompared. We also investigated the effect of V. dahliae on keycomponents of plant leaf area, leaf expansion and senescence,in inoculated and control plants of Sankol and Toba, a hybridof intermediate susceptibility to V. dahliae. Reduction in plantleaf area caused by V. dahliae was first detected 31 d afterinoculation (DAI), when visual symptoms of disease in inoculatedplants were slight (Sankol) or absent (Dekasol 3900). Reductionin leaf photosynthesis was first observed 66 DAI; stomatal conductanceand leaf dark respiration were both unaffected by V. dahliaeduring the whole experiment. In comparison with controls, V.dahliae reduced seasonal duration of plant leaf area by 25%in Dekalb 3900 and by 55% in Sankol, whereas the average reductionin leaf photosynthetic rate was 9%. In correspondence with thereduction in leaf area duration, inoculation reduced shoot drymatter of mature Sankol by 50%. In both experiments, less leafexpansion accounted for most of the early reduction in plantleaf area; as the disease progressed, increasing senescencealso contributed to reduced plant leaf area. It is concludedthat the response of sunflower to V. dahliae resembled the responseof the plant to soil water deficit: (1) plant leaf area, ratherthan leaf photosynthetic rate, accounted for the reduction ingrowth in mass; and (2) reduced leaf expansion early in theseason and faster leaf senescence in older plants accountedfor the decrease in plant leaf area. Copyright 2000 Annals ofBotany Company Helianthus annuus, Verticillium dahliae, allometry, apical dominance, drought, leaf expansion, leaf senescence, photosynthesis, stomatal conductance, growth     

Effects of Chilling on the Ultrastructure and Net Photosynthesis of Pellia epiphylla

Thalli of Pellia epiphylla were collected frozen from natureand chilled artificially for varying lengths of time at –22°C. The survival and recovery of this material was comparedwith that of the non-chilled material by performing CO₂ exchangeexperiments. Electron microscopy was done from the chilled andhardened thalli, and clear differences were observed in theultrastructure of these materials. The vacuoles of the hardenedtissue contained fine granular material but those of the chilledtissue had large electrondense particles embedded in finer granularsubstance. Oil bodies had greatly changed. In the cytoplasmthere were abundant lipid-like bodies resembling oil globulesof oil bodies and particularly in the vacuoles there were oily-lookingflecks. Chloroplasts had large starch grains and the lamellarsystem was somewhat disorganized. Net photosynthesis was highestwith material stored for the longest time at –22 °C. Pellia epiphylla, ultrastructure, net photosynthesis, chilling     

Effects of Temperature on Photosynthesis by Maize and Wheat

Maize and wheat plants were grown in controlled environmentswith day temperatures of 13, 18, 23, or 28 ?C. Leaves from maizegrown at 23 ?C photosynthesized faster than leaves from maizegrown at 13 or 18 ?C and, except when measured at 28 ?C, fasterthan leaves from maize grown at 28 ?C;leaves of maize grownat13 ?C were yellow and photosynthesized at insignificant rates.Leaves from wheat grown at 18 ? or 13 ?C had faster rates ofphotosynthesis than leaves from wheat grown at 23 or 28 ?C.The best rates for maize were faster than the best rates forwheat when the measurements were made at 23 or 28 ?C but at13 or 18 ?C the best rates for maize were not significantlybetter than the best rates for wheat. Leaves of maize that developedin the environment with 23 ?C as the day temperature did notrapidly lose their green colour when transferred to the environmentwith the day temperature of 13 ?C and the rate of photosynthesisof these leaves did not decline rapidly. However, new leavesexpanding in the cooler conditions were yellow and not effectivein photosynthesis. At 13 or 18 ?C maize, a C4 plant, which photorespiresslowly, did not photosynthesize more effectively than wheat,which photorespires rapidly. The maize did not produce its mosteffective leaves at 13 or 18 ?C and its optimum temperaturefor photosynthesis was 23?C or higher. It may therefore be consideredill-adapted to the temperate climate.     

切花寒菊小花对低温胁迫的生理响应及其抗寒性分析

以切花寒菊品种'寒紫'和'寒黄'为材料,比较了低温下(<0℃)2个品种舌状花和管状花的相对电导率(REC)变化及半致死温度(LT50)差异,并测定了从温室温度(14.4℃～16.2℃)至3℃的降温过程中2个品种舌状花和管状花的SOD活性和MDA、可溶性糖、可溶性蛋白含量及花粉生活力变化.结果表明:低于-6℃条件下,2个品种电导率均随温度下降而显著上升,且低温下'寒黄'舌状花、管状花的相对电导率均低于'寒紫'.两品种半致死温度均在-9℃左右或更低,且'寒黄'低于'寒紫',管状花低于舌状花.在室温至3℃的降温过程中,2个品种SOD活性、可溶性蛋白含量及花粉萌发率先升后降,MDA含量则先降后升,且均在6℃或9℃时出现拐点,而可溶性糖含量表现为持续增加,且'寒紫'花粉萌发率下降较'寒黄'早且快.结果发现,'寒黄'抗寒性强于'寒紫'、管状花强于舌状花,2品种小花出现冻害的极限低温在-6℃以下,而9℃甚至6℃是寒菊花期出现生理障碍的转折点;切花寒菊可通过提高自身SOD活性及可溶性糖、可溶性蛋白含量来抵抗低温胁迫,且调节能力'寒黄'强于'寒紫'、管状花强于舌状花.     

Dark Respiration of Winter Wheat Crops in Relation to Temperature and Simulated Photosynthesis

The dark respiration of shoots (measured between March and anthesisin mid-June) and of ears (measured between anthesis and maturityat end of July) of winter wheat crops, grown in 1982 and 1985under different nitrogen application and irrigation conditions,was determined in the field. The respiration rate of 126 averagesof four samples was measured hourly for a 12–14-h darkperiod including the night. Respiration (expressed per unitdry mass) generally declined through the season for both shootsand ears. The average rate of respiration obtained on the samenight was greater for fertilized and irrigated crops, comparedwith unfertilized and droughted crops. The relationship betweenthe measured respiration and photosynthesis, simulated usinga modified version of the model developed by Spitters (1986),was analysed. This revealed that: (a) Shoot respiration was less well correlated with photosynthesisfrom the day preceding measurement than with the average ofthe photosynthesis from the two days preceding measurement. (b) The constants relating shoot respiration to total crop photosynthesisper unit crop mass and ear respiration to total crop photosynthesisper unit ear mass had similar values. This suggests that allgrowth respiration takes place in the ears at the end of theseason. (c) Crop growth respiration consumes about 35% of assimilatebefore anthesis, and that growth respiration of the ear consumesabout 40% of assimilate at the end of the season. (d) No significant effect of treatment on the relationship betweenrespiration and photosynthesis was detected, suggesting thatthe observed effect of treatment on respiration is due entirelyto differences in photosynthesis. Triticwn aestivum var. Avalon, winter wheat, dark respiration, growth coefficient, photosynthesis model, nitrogen nutrition, irrigation     

Revealing Hereditary Variation of Winter Hardiness in Cereals

A set of cereal crops and differentiating cultivars was shown to be of utility for identifying the major abiotic factors that limit the survival of winter crops in the cold season of a particular year. With this approach, the season was identified (1997–1998, Belgorod) when the survival of cereals depended on the tolerance to anaerobiosis rather than on the frost resistance. Differentiation of common wheat cultivars with respect to this property was attributed to a locus designated Win1 (Winter hardiness 1) and localized 3.2–5.8% recombination away from the B1 (awnlessness 1) gene. Winter barley (cultivar Odesskii 165) displayed the highest tolerance to anaerobiosis in the cold season; low and intermediate tolerance was established for winter durum wheat (cultivar Alyi Parus) and winter common wheat, respectively. Frost resistance and winter hardiness type 1 proved to be determined by different genetic systems, which showed no statistical association. Correlation analysis revealed significant positive associations of frost resistance in the field (1996–1997, Belgorod) with productivity, sedimentation index (Zeleny test), plant height, and vegetation period in wheat. Statistical analysis associated frost resistance with gliadin-coding alleles of homeologous chromosomes 1 and 6 of the A, B, and D wheat genomes.     

夜间低温对不同光强下生长的两种热带树苗光合作用的影响

于雾凉季测定了叶片叶绿素荧光和气体交换参数、H2 O2 和丙二醛 (MDA)含量 ,探讨了 4～ 6℃夜间低温对 3种相对光强 (太阳光的 8%、2 5 %和 5 0 % )下生长的 2种山地雨林树苗光合作用的影响。夜间低温处理导致 3种光强下生长的 2种植物叶片日间和胁迫诱导的光抑制加剧 ,净光合速率 (Pn)和光呼吸速率降低 ,H2 O2 和MDA含量升高。生长环境光强升高可加剧夜间低温的效应 ,弱光下 2种植物受夜间低温影响较小 ,间接表明雾使光强减弱可缓解自然夜温降低对西双版纳热带植物的危害。处理期间滇南插柚紫Pn 主要受气孔限制 ,滇南红厚壳Pn 降低与活性氧增加引起的羧化效率降低有关 ,两种植物Pn 的降低均与光抑制关系不大。夜间低温后滇南红厚壳气孔导度降低较少 ,H2 O2 和MDA含量较高 ,光抑制较重 ,5 0 %相对光强下其未做夜间低温处理的对照植株发生了胁迫诱导的光抑制 ,表明它对夜间低温较敏感。     

温度对绿豆离体叶片光合作用的影响

绿豆离体叶片分别经25、30、35、40、45、50、55℃处理60 min后,发现净光合速率和光系统Ⅱ的最大量子效率(Fv/Fm)当温度分别高于35和40℃时明显下降;细胞间隙CO2浓度的变化趋势与净光合速率的基本相反.因此认为,Fv/Fm比净光合速率(Pn)更能耐受高温;气孔因素不是各种温度处理中净光合速率升高或降低的主要原因.     

Effects of Variations in Daylength and Temperature on Net Rates of Photosynthesis, Dark Respiration, and Excretion by Isochrysis galbana Parke

The effects of variable daylength and temperature on net rates of photosynthesis, dark respiration, and excretion of a unicellular marine haptophyte, Isochrysis galbana Parke, were examined and related to division rates. Six combinations of daylength (18:6, 12:12, 6:18 light:dark, LD) and temperature (20, 25 C) were used. Daily rates of net photosynthesis were closely correlated to division rates, suggesting a direct relationship, and were maximal when cells were grown at 12:12 LD at both temperatures and 18:6 LD at 20 C. A daylength of 6 hours decreased daily rates by decreasing the time for carbon uptake. Further, cells grown with this daylength had maximal chlorophyll a contents, suggesting a physiological adaptation by photosynthetic units to short light periods. A photoperiod of 18:6 LD at 25 C decreased daily rates of net photosynthesis by reducing the hourly rate of net photosynthesis via an unidentified mechanism. The importance of rates of net dark respiration in controlling daily net photosynthesis was small, with carbon lost during dark periods varying between 4 and 14% of that gained during light periods. Also, the influence of net excretion was small, varying between 1.0 and 5.5% of daily net photosynthesis.     

低温胁迫下钼对冬小麦抗氧化防御系统及膜脂过氧化的影响

研究了低温（0～5℃）胁迫下钼对冬小麦抗氧化系统和膜脂过氧化的影响。结果表明,低温胁迫下施钼植株电解质渗漏率和丙二醛含量显著降低。施用钼肥提高了冬小麦叶片中抗氧化酶类如超氧化物歧化酶（SOD,EC1．15．1．1）、过氧化物酶（POX,EC1．11．1．7）和过氧化氢酶（CAT,ECl．11．1．6）的活性。低温胁迫下施钼对抗氧化酶（SOD、POX和CAT）活性提高幅度比常温下高。不论常温还是低温下,施铝均提高了冬小麦叶片中抗坏血酸和脯氨酸含量,低温胁迫下提高幅度更大。常温下缺钼和施钼处理后,叶片中类胡萝卜素含量差异不显著;低温下施钼后,冬小麦叶片类胡萝卜素含量显著增加。因此,低温胁迫下施钼植株活性氧清除能力增强、细胞膜伤害减轻可能是冬小麦抗寒力提高的原因之一。     

The Effects of Nitrogen Fertilization and the Growing Season on Photosynthesis of Field-grown Tall Fescue (Festuca arundinacea Schreb.) Canopies

Canopy gross photosynthesis of tall fescue receiving three tofour rates of N fertilization was studied under field conditionsduring three contrasting growing seasons. Under non-limitingN growing conditions, the growing seasons did not have a significanteffect on the maximum canopy gross photosynthesis (canopy grossphotosynthesis at saturating PAR) and the maximum light yield(quantum efficiency of the canopy at low PAR). In the absenceof N fertilization and for a similar LAI, the values of themaximum canopy gross photosynthesis were approximately equalto 70% of those obtained under non-limiting N conditions. Thisresponse of the tall fescue canopy to N concentration is muchsmaller than that reported at the leaf level. The reductionin canopy photosynthetic capacity with no N applied comparedto non-limiting N conditions is much less than the reductionobserved previously in above-ground dry matter accumulation.The effect of N fertilization on above-ground dry matter accumulationis due primarily to changes in C partitioning and the resultingfaster leaf area development and greater light interceptionrather than the effect of N on the canopy photosynthetic capacityper se .Copyright 1993, 1999 Academic Press Festuca arundinacea Schreb., photosynthesis, nitrogen, grass, carbon