断根结合生长素和钾肥施用对烤烟生长及糖碱比、有机钾指数的影响

河南济源烟区存在着烟叶糖碱比高、有机钾指数较低的生产现状,通过田间试验研究了打顶时断根(C)、打顶时断根结合喷施IAA(C+I)、打顶时断根结合追施钾肥(C+K)、打顶时断根结合喷施IAA并追施钾肥(C+K+I)和对照(CK)5种处理对烤烟生物量及糖碱比、有机钾指数的影响。结果表明:不同调控措施在烟株成熟期较对照均能增加根部、叶片的干重,减少烟碱、总糖在中上部烟叶的累积。断根结合喷施IAA能降低各部位烟叶的糖碱比,且以C+K+I处理的降幅最大,在下、中、上叶位中较对照分别降低了19.12%、15.33%和8.15%。与对照相比,各处理均能提高不同部位烟叶K⁺含量,降低Cl^-和SO₄^2-含量。C+K+I处理能极显著提高各部位烟叶的有机钾指数,且在中上部烟叶中增幅最大,较对照分别提高了125.00%和209.43%。总的看来,打顶时断根结合喷施IAA并追施钾肥能促进烟叶中的干物质积累、降低糖碱比、提高有机钾指数,进而提高烟叶的内在品质。     

烟草打顶对腐胺N-甲基转移酶基因表达的影响

水培65d的烟株进行打顶后,测定打顶和不打顶烟株上部叶中烟碱含量。分别提取根中总RNA,以腐胺N-甲基转移酶基因（PMT）特异引物、肌动蛋白基因（actin）为内参作半定量RT-PCR分析;同时将提取的总RNA转膜,用地高辛标记PMTRT-PCR产物作探针,进行Northern杂交分析的结果表明,打顶后的上部烟叶中烟碱含量和PMT基因表达量显著增加。     

吡效隆对花生光合作用及产量的影响

花生结荚期施用０．１～１０ｍｇ／Ｌ吡效隆（４ＰＵ３０）溶液，能增加叶片的厚度，提高叶片叶绿素含量和光合速率，促使叶片中的同化物向荚果运输和积累增多，从而促进了荚果生长和发育，使结荚率、饱果率以及百果重和百仁重增加，最终使单株荚果产量增产１２６％左右，吡效隆的最适浓度为１ｍｇ／Ｌ。     

呲效隆对花生光合作用及产量的影响

花生结荚期施用0.1～10 mg/L吡效隆(4PU-30)溶液,能增加叶片的厚度,提高叶片叶绿素含量和光合速率,促使叶片中的同化物向荚果运输和积累增多,从而促进了荚果生长和发育,使结荚率、饱果率以及百果重和百仁重增加,最终使单株荚果产量增产12.6％左右,吡效隆的最适浓度为 1 mg/L。     

开放式空气CO2增高对水稻物质生产与分配的影响

在大田栽培条件下,研究开放式空气CO2增加(FACE)200μmol·mol^-1的处理对水稻物质生产与分配的影响．结果表明,FACE处理使移栽至抽穗后20d的干物质积累量显著增加,使抽穗后20d至成熟期的干物质生产量显著减少,生物产量显著提高．移栽至抽穗期的干物质积累量增加是由于叶面积系数和净同化率共同提高所致;抽穗期至抽穗后20d的干物质积累量增加主要是由于叶面积系数的增加所致;抽穗后20d至成熟期的干物质生产量减少主要是由于净同化率的下降所造成．提高茎鞘占全株干物重的比例,降低叶片占全株干物重的比例,对穗占全株干物重的比例无显著影响,能显著提高水稻抽穗期茎鞘中可溶性糖、淀粉的含有率和含量,提高FACE处理的生物产量能极显著提高水稻产量(r＝0．7825)．     

广东南雄烟区烤烟氮素累积分配及利用特征

在广东南雄烟区以烤烟品种K326为材料,采用田间原位培养方法和15N同位素示踪技术,在大田条件下研究了土壤氮素矿化特征、烤烟氮素累积分配规律以及当季施入肥料氮的分配情况.结果表明:南雄烟区土壤氮素矿化量随着生育期推移呈上升趋势,在移栽后75 d达到高峰,此后下降;不施氮处理土壤氮素矿化量在各生育期均显著高于施氮处理;烟株不同器官氮素积累量表现为叶片＞茎＞根.烤烟在团棵期和打顶期以吸收肥料氮为主,成熟期则以吸收土壤氮为主,烟株整个生育期吸收的氮素主要来源于土壤氮,且吸收的土壤氮及其占总氮的比例随生育期推移和叶片着生部位的升高而增加.氮肥烟株利用率、土壤残留率和损失率分别为30.8%、32.3%和36.9%.南雄烟区土壤氮素矿化能力较强,土壤氮对上部叶片质量的影响较大,在施氮量为150kg·hm-2条件下,肥料氮的残留量和损失量较高.     

光质对烟叶光合特性、类胡萝卜素和表面提取物含量的影响

以烤烟云烟87为材料,在烟株团棵期和打顶期用透光率相近的有色薄膜分别对其进行遮光处理直到采收结束,研究光质对烟叶光合特性、类胡萝卜素和表面提取物含量的影响.结果表明:烟叶生育前期各光质的整体光合性能依次为红光＞自然光＞白光＞蓝光＞黄光,后期蓝光的作用逐渐凸显.烤后烟叶β-胡萝卜素和叶黄素含量之间呈极显著正相关,且β-胡萝卜素含量明显高于叶黄素含量.团棵期增加红光,打顶期补充蓝光,有利于提高烤后烟叶β-胡萝卜素和叶黄素含量.光质对腺毛分泌物中的β-西柏三烯二醇影响最大,对降茄二酮影响最小.烷烃类蜡质成分中的三十一烷、三十三烷和异三十三烷含量受光质影响较大,异三十二烷和二十九烷含量受光质影响较小.相对于腺毛分泌物和烷烃类蜡质而言,光质对新植二烯影响较小.黄膜处理烤后烟叶的腺毛分泌物及其降解产物总量最高,光质对新植二烯和烷烃类蜡质含量的影响存在多种变化.红光和蓝光对烟叶表面提取物的影响效应主要表现在烟株生长前期,黄光和白光的影响效应主要体现在烟株生长后期.烟株生长前期增加红光比例,有利于增加烤后烟叶新植二烯和烷烃类蜡质成分积累;烟株生长后期补充黄光光质有助于提高烤后烟叶腺毛分泌物含量和表面提取物总量.     

氮、钾营养对烤烟产量、产值和优质烟叶比例的影响

通过田间小区试验,研究氮素和钾素对烤烟产量、产值及优质烟叶(中上等烟叶)比例的影响,结果表明：(1)烤烟产量与施钾肥量具有显著正相关,并与施氮肥量有关;(2)产值与施氮肥量呈显著二次曲线相关性;(3)中上等烟比例与施肥比例(N／K)呈显著负相关,与施钾量、烟叶含钾量、土壤供钾能力有关。试验区烤烟优质、适产,要求施氮量(N)105一l12．8kg／hm2,施钾量(K)217．95—261．45kg／hm2,施肥比例(N／K比)0．40—0．48(N：K＝1：2．1—2．50或N：K2O＝1：2．5—3．0)。     

氮肥形态和用量对藏东南地区烤烟产量和质量的影响

在藏东南地区进行了氮肥用量和形态对烟产量与质量影响的田间试验。结果表明,在施N量0－150kg·hm^-2范围内,施N量与烘烤后烟叶产量、产值、氧化钾及总N含量呈显著或极显著正相关,与上中等烟比例、还原糖含量则呈显著负相关,糖／碳比显著下降,氮肥用量75kg·hm^-2时,产量、质量最佳。无机氮肥对烟产量与质量的效应极显著优于有机氮肥。铵态氮、硝态氮、硝铵态氮肥处理间除上中等烟比例,其它各项指标仅略有差异,但均极显著优于酰胺态氮肥。铵态氮对烤烟产量与质量的影响略优于硝态氮,主要在于烟株吸收和同化过程的差异。     

不同富硒土壤对烤烟生长及硒吸收转运的影响

以烤烟品种‘云烟87’为材料,采用盆栽试验研究安徽池州烟区不同全硒含量土壤(0.30、0.45、1.00、1.75mg·kg-1)对烤烟生长发育以及硒吸收和转运的影响。结果显示:(1)土壤硒含量≤1.00mg·kg-1时能够促进烤烟生长,而土壤硒含量≥1.75mg·kg-1则抑制烤烟的生长。(2)土壤硒含量的增加能够显著提高烤烟根系、茎秆、叶片的硒含量,烟株各部位的硒含量呈现根系叶片茎秆的特点,且根系硒含量是叶片的2~3倍,叶片硒含量则是茎秆的3~4倍。(3)土壤硒含量由0.30mg·kg-1增加至1.75mg·kg-1时,烟株对硒的吸收系数由1.08显著降低至0.36,次级转运系数则由2.84显著升高至4.03,即土壤硒含量增加降低了根系吸收硒的效率,但却增加了硒在叶中的转运和相对累积量。(4)烤烟整株硒的富集量在土壤硒含量为1.00mg·kg-1时达到最大,每株达到72μg。研究表明,在安徽池州烟区的富硒土壤(0.45~1.00 mg·kg-1)上能够生产出富硒(0.15~0.23 mg·kg-1)烟叶,不需要额外添加外源硒,既可以减少生产成本,也能够避免造成水土污染。     

Effect of Potassium Supply on the Transport of Photosynthates to the Fruits of Tomatoes (Lycopersicon esculentum)

In experiments with intact tomato plants the effect of potassium on the translocation of photosynthates was studied. Four series of plants were grown in nutrient solutions with two different potassium levels (K₁ and K₂ treatments). When the fruits of the first truss had developed the plants were treated with labelled CO₂ for 2 h in a glove box. The plants were then divided in roots, stems, fruits and leaves, which were prepared for chemical analysis. In all experimental series the plants with the higher K supply grew better and therefore assimilated higher amounts of labelled CO₂ (cpm/plant). The assimilation rates per g fresh material, however, were not increased in each experimental set by the K₂ treatment. The absolute quantities of labelled photosynthates transported from leaves and stems to the fruits were also greater in the plant with the higher potassium supply. In all experimental series the proportion of labelled material found in the fruits was higher in the plants of the K₂ treatment (total label of the plant=100%) than in the plants of the K₁ treatment. This beneficial effect of potassium was also observed in cases, where potassium had not affected the CO₂ assimilation rate. Expressing the distribution of labelled material in relative terms (percentage proportions) means that the effect of CO₂ assimilation on the transport of photosynthates was excluded to a high extent. The higher percentage proportions of labelled material found in fruits and roots of the K₂ as compared to the K₁ treatment is, therefore, predominantly dependent on a specific effect of potassium on the translocation of assimilates. The labelled material found in the soluble fraction of the stems consisted of about 90% sugars, nearly half of which was sucrose, the rest being mainly glucose and fructose. This finding suggests that sucrose is the most important transport form of carbohydrates in tomatoes.     

施氮量对小麦氮磷钾养分吸收利用和产量的影响

高产条件下研究了不同施氮量对小麦植株氮、磷、钾养分吸收利用及籽粒产量的影响.结果表明,适量施氮可促进小麦植株对氮素的吸收与积累,较高的施氮量不利于起身期之后的氮素积累,致使成熟期小麦氮素积累量未能显著提高;与不施氮肥相比,施氮显著提高植株磷素积累量;随施氮量增加,植株磷素积累量增加不显著;施氮量增加促进小麦生育前期对钾素的吸收积累,在生育后期降低植株钾素的流失.随施氮量增加,籽粒氮素含量呈先增后降的趋势,氮素向籽粒的分配比例趋于降低,植株氮素利用效率无显著变化,氮素收获指数下降;不同施氮处理之间籽粒磷素含量和钾素含量无显著差异,施氮量增加,营养器官钾素含量、钾素积累量和钾素向叶片的分配比例均呈增加趋势;同时,磷素和钾素利用效率降低;不同施氮处理间,植株磷素、钾素收获指数无显著差异.籽粒产量随施氮量增加呈先增加后降低的趋势,以施氮195 kg/hm2的处理籽粒产量最高.     

Phytosterols and polyphenols in reciprocally grafted tobacco—tomato plants

Intact and reciprocally grafted tobacco and tomato plants were studied to examine their roles as scions and stocks in the formation, composition, and total amount of 3-β-hydroxysterol and polyphenols. Intact tobacco plants have a higher phytosterol content than do tomato plants. Tobacco leaves from the Tob/Tom grafted plants contained much less phytosterol than leaves from intact tobacco plants. The distribution of four major sterols, however, did not vary significantly. The concentration of total polyphenols in intact tobacco and tomato was about the same, but tobacco was high in chlorogenic acid, and tomato was high in rutin. Tobacco leaves from Tob/Tom grafted plants showed only a slight decrease in total polyphenol concentration compared with intact tobacco. Tomato roots appeared to contribute to the increased total polyphenol per plant in either intact tomato or in Tob/Tom grafted plants, despite the fact that no polyphenolic compounds were detected in the tomato root itself. Grafting may provide a limited technique for reducing the phytosterol concentration of tobacco leaves.     

Induction of resistance against rice blast fungus in rice plants treated with a potent elicitor, N-acetylchitooligosaccharide

The mode of action of a potent elicitor, N-acetylchitooligosaccharide, in rice plants was examined. In intact seedlings, no significant uptake of the elicitor via the roots was observed within 3 h, whereas rapid uptake was observed in excised leaves. Rapid and transient expression of an elicitor-responsive gene, EL2, was induced in the leaves of intact seedlings sprayed with the elicitor or in the roots and leaves of intact seedlings by immersing roots in the elicitor solution. Histochemical analysis indicated that EL2 was expressed in cells exposed to the elicitor of root and leaves. In seedlings treated with the elicitor for 1 d or longer, hyphal growth of rice blast fungus was significantly delayed, and an accumulation of auto-fluorescence around the infection site was observed. Two defense-related genes, PR-1 and PR-10 (PBZ1), were induced in a systemic and local manner by elicitor treatment, in correlation with the induction of resistance against rice blast fungus. N-Acetylchitoheptaose did not inhibit the hyphal growth of the fungi. These results indicate the occurrence of systemic signal transmission from N-acetylchitooligosaccharide in rice plants.     

Photosynthesis in intact leaves of C3 plants: Physics,physiology and rate limitations

The instantaneous rate of photosynthetic CO₂ assimilation in C₃ plants has generally been studied in model systems such as isolated chloroplasts and algae. From these studies and from theoretical analyses of gas exchange behavior it is now possible to study the biochemistry of photosynthesis in intact leaves using a combination of methods, most of which are nondestructive. The limitations to the rate of photosynthesis can be divided among three general classes: (1) the supply or utilization of CO₂, (2) the supply or utilization of light, and (3) the supply or utilization of phosphate. The first limitation is most readily studied by determining how the CO₂ assimilation rate varies with the partial pressure of CO₂ inside the leaf. The second limitation can be studied by determining the quantum requirement of photosynthesis. The third limitation is most easily detected as a loss of O₂ sensitivity of photosynthesis. Measurement of fluorescence from intact leaves can give additional information about the various limitations. These methods are all non-destructive and so can be observed repeatedly as the environment of a leaf is changed. In addition, leaves can be quick-frozen and metabolite concentrations then measured to give more information about the limitations to intact leaf photosynthesis rates. In this review the physics and biochemistry of photosynthesis in intact C₃ leaves, and the interface between physiology and photosynthesis—triose phosphate utilization—are discussed.     

Supplemental manganese improves the relative growth, net assimilation and photosynthetic rates of salt-stressed barley

Previous results in our laboratory indicated that a reduced Mn concentration in the leaves of barley was highly correlated with the reduced relative growth and net assimilation rates of salt-stressed plants. If Mn deficiency limits the growth of salt-stressed barley, then increasing leaf Mn concentrations should increase growth. In the present study, the effect of supplemental Mn on the growth of salt-stressed barley ( Hordeum vulgare L. cv. CM 72) was tested to determine if a salinity-induced Mn deficiency was limiting growth. Plants were salinized with 125 mol m⁻³ NaCl and 9.6 mol m⁻³ CaCl₂. Supplemental Mn was applied in 2 ways: 1) by increasing the Mn concentration in the solution culture and 2) by spraying Mn solutions directly onto the leaves. Growth was markedly inhibited at this salinity level. Dry matter production was increased 100% in salt-stressed plants treated with supplemental Mn to about 32% of the level of nonsalinized controls. The optimum solution culture concentration was 2.0 mmol m⁻³, and the optimum concentration applied to the leaves was 5.0 mol m⁻³. Supplemental Mn did not affect the growth of control plants. Further experiments showed that supplemental Mn increased Mn concentrations and uptake to the shoot. Supplemental Mn increased the relative growth rate of salt-stressed plants and this increase was attributed to an increase in the net assimilation rate; there were no significant effects on the leaf area ratio. Supplemental Mn also increased the net photosynthetic rate of salt-stressed plants. The data support the hypothesis that salinity induced a Mn deficiency in the shoot, which partially reduced photosynthetic rates and growth.     

Cytokinin Metabolism in Phaseolus vulgaris L.: I: VARIATIONS IN CYTOKININ LEVELS IN LEAVES OF DECAPITATED PLANTS IN RELATION TO LATERAL BUD OUTGROWTH

A stable isotope dilution method employing a deuterium-labelledinternal standard and combined gas chromatography-mass spectrometryhas been used to quantify the accumulation of di-hydrozeatin-O-ß-D-glucosidein the primary leaves of decapitated, disbudded bean plants.This cytokinin accumulated at a rate of 11 ng g^–1 fr.wt. d^–1 (eq. to an increase of 50 ng d^–1 per leaf),reaching a maximum of c. 500 ng g^–1 after 40 d from decapitation.This accumulation appeared to parallel the gradual increasein leaf fresh weight, and did not occur in detached leaves,in leaves of intact plants, or in leaves of plants that weredecapitated but not disbudded. When secondary lateral buds wereallowed to grow out from decapitated and initially disbuddedplants, the levels of dihydrozeatin-O-ß-D-glucosidein the primary leaves rapidly declined to a value similar toor lower than that found in leaves of intact plants. A similardecline in dihydrozeatin-O-ß-D-glucoside levels wasseen over 5 d in detached leaves of plants which had been decapitatedand disbudded for 15 d; this effect was reduced but not preventedwhen the leaves were supplied with inorganic nutrients. Theseresults are discussed in relation to the metabolism and distributionof cytokinins in the whole plant.     

The Effect of Manganese on the Assimilation and Respiration Rate of Isolated Rooted Leaves

The effect of manganese on carbon assimilation, respiration,and translocation has been studied using isolated rooted potatoleaves and small potato plants. Methods are described for therooting and culture of the leaves and plants. It was found thatnormal potato leaves rooted readily when treated with -naphtha-leneaceticacid (2 p.p.m.), but that very few of the manganese-deficientleaves produced roots, the critical level being about 15 p.p.m.manganese on a dry weight basis. The growth of isolated deficientleaves was also much less than that of control leaves, but inno case did characteristic manganese-deficiency symptoms develop,although the manganese level had fallen below that of leaveswhich showed symptoms when attached to the plant. A marked differencein net assimilation rate was found between leaves which hada high or low manganese content at the time of rooting. Theaddition of manganese after rooting to low manganese leavesdid not, however, cause an increase in assimilation rate, althoughthe manganese content of the leaves had been raised to thatof the control leaves. Manganese was shown to have only a smalleffect on respiration, higher respiration rate being consistentlyassociated with a higher manganese content; the addition ofmanganese to ‘deficient’ leaves did not cause anyincrease in respiration. No effect of manganese on translocationwas detected.     

施用钾肥对烟粉虱实验种群生命表参数的影响

设置0,30,60,120和240mg/L5种钾肥浓度处理黄瓜植株,测定不同处理黄瓜叶片的含钾量及相应处理上烟粉虱Bemisiatabaci(Gennadius)种群的生命表参数。结果表明,黄瓜叶片含钾量不随钾肥施用量增加而增大,30mg/L钾肥溶液处理的黄瓜叶片含钾量最高。在上述5种钾浓度处理黄瓜植株上,烟粉虱种群的内禀增长率rm分别为0.14,0.17,0.17,0.15和0.13,净增殖率R0依次为47.79,111.55,115.18,61.96和49.58。因此,黄瓜叶片中含钾量高有利于烟粉虱的种群增长。讨论研究结果对生产上烟粉虱种群调控的意义。     

Responses of Papaya Seedlings (Carica papaya L.) to Water Stress and Re-Hydration: Growth, Photosynthesis and Mineral Nutrient Imbalance

The effects of water stress and subsequent re-hydration on growth, leaf abscission, photosynthetic activity, leaf water potential and ion content were investigated in papaya seedlings (Carica papaya L.) cv. “Baixinho de Santa Amalia”. Water stress was imposed by suspending irrigation during 34 days. Thereafter, plants were regularly re-watered. Drought arrested plant growth, induced leaf abscission and drastically decreased photosynthetic rate. However, leaf water potential was hardly reduced. Water deficit also induced sodium, potassium and chloride accumulation in leaves and roots, and did not modify nitrogen levels in both organs. Re-hydration stimulated growth, promoted emergence of new leaves, reactivated photosynthetic machinery function and reduced ion content to control levels. The results indicated that the ability of papaya plants to improve drought tolerance is not mediated through the reduction of leaf abscission, the detention of growth or the decrease of net CO₂ assimilation. In contrast, the data suggested that under water stress conditions these plants appear to posses a certain capacity to increase ion content, which might contribute to osmotic adjustment.