The Analysis of Correlative Growth in the Etiolated Oat Seedling in Relation to Carbon Dioxide and Nutrient Supply

To overcome the reduced extension growth of the coleoptile whichoccurs when oats are grown in air enriched with 5 per cent.CO¹, plants have been provided with nutrients via the roots.2 per cent, sucrose, glucose or mannitol so applied furtherpromoted the mesocotyl and further depressed the coleoptile.Root growth was also depressed. To induce promotion of coleoptile growth by externally appliedsucrose, seedlings were heated in darkness at 40° C. for3 hours so restricting selectively the growth of the mesocotyl.Promotion of the coleoptile, however, was not observed. Application of mixed Na and K nitrates occasioned an immediategrowth promotion of doleoptile and leaves in both the presenceand absence of CO², and also a.much less pronounced promotionof the mesocotyl in CO²; there was no effect in air. This enhancedgrowth of the coleoptile and leaves was coupled with a correspondinglygreater dry weight and also with an increased outflow of reservesfrom the endosperm into the plumule. Thus, while externally applied sugars seemed not to reach thecoleoptile, those made available from the endosperm as a resultof improved nitrogen supply were rapidly translocated to it.Simultaneous provision to the roots of nitrate and sucrose didnot improve the absorption and translocation of sugar. An analysis of covariance has been computed using the mesocotyland coleoptile length data together with the outflow from theendosperm and the conclusions so derived are discussed in relationto the problem of growth integration in etiolated oat seedlings.     

Further Observations on the Effect of Carbon Dioxide on the Growth of Etiolated Avena Seedlings

Oat seedlings when grown in 5 per cent. CO² show an increasedgrowth of the mesocotyl and a reduced growth of the coleoptile.To elucidate this effect the following data, for both treatedand control plants, have been obtained: (1) fresh and dry weightincreases in the whole plants and in the separate organs, (2)water contents, and (3) progressive depletion of the endosperm. The enhanced growth of the mesocotyl in CO² was closely, correlatedwith dry-matter content but not with water content. The depletionof the endosperm was reduced by treatment with CO², and of thesmaller amount of carbohydrate entering the embryo a higherproportion remained in the mesocotyl; coleoptile growth wasconsequently diminished. The distribution of dry matter betweenthe coleoptile and mesocotyl must be an important factor intheir reciprocal growth behaviour.     

Effects of Aluminium on Honeylocust (Gleditsia triacanthos L.) Seedlings in Solution Culture

Honeylocust (Gleditsia triacanthos L.) seedlings were grownin solution culture at pH 4.0) with 50, 150, 600 and 1500 mmolm^–3 aluminium. All levels of aiuminium reduced the sizeand weight of roots, shoots and leaves with the exception ofroot elongation at 50 mmol m^–3 Al. Aluminium content ofroots was 50 to 100 times that of shoots. With increasing concentrationof aluminium, aluminium content of leaves and roots increasedexponentially while a linear increase was observed for stems.The nutrient content of seedlings was improved in 50 mmol m^–3where increases in shoot calcium, magnesium, and phosphorusconcentrations were observed. Aluminium concentrations greaterthan 50 mmol m^–3 reduced shoot nutrient content. Presenceof aluminium increased the root phosphorus and calcium levelsbut had no effect on potassium and magnesium concentrations.Results show that honeylocust is an aluminium sensitive treespecies whose growth may be reduced by high soil Al levels. Key words: Aluminium toxicity, Gleditsia triacanthos, nutrient solution     

The Dominant Influence of Nitrogen on Growth Correlation in Etiolated Oat Seedlings

A nutritive hypothesis is put forward to account for the inhibitoryeffect of carbon dioxide, and of sucrose, on the elongationof the coleoptile and leaves of etiolated oat seedlings. Growthdepends, it is assumed, on the availability of nitrogen, andthe way in which the supply is diminished by these treatmentshas been elucidated. Three factorially arranged experimentswere carried out to provide the necessary growth data and observationswere also made of the distribution throughout the seedlingsof dry-weight, of sugars and of nitrogen. Additionally, thequantity of reserves, and of nitrogen, flowing into the seedlingduring growth have been determined. The dependence of coleoptileand leaf growth on the supply of nitrogen has been demonstratedand also the dependence of the amount of nitrogen transferredon the total weight of translocate. The growth inhibition canthen be explained on the assumption that treatment with carbondioxide and sucrose decreases the weight of reserves translocatedfrom the endosperm and so reduces the amount of nitrogen passinginto the seedling. Consumption of nitrogen by the mesocotyland roots, however, is not correspondingly reduced; the coleoptilesand leaves, perforce, bear the entire shortage and their growthis checked. These results may also be utilized to explain the transientgrowth promotion of the coleoptile and leaves brought aboutby illumination and heating, so avoiding the need to postulatechanges in auxin metabolism. The importance of the nitrogen supply during germination isdiscussed.     

Exudation of Recently Fixed Carbon by Non-Sterile Roots

Preliminary results on exudation of recently fixed carbon fromthe roots of non-sterile, hydroponically grown wheat seedlingsare presented. Within the first 200 min after photosynthesisof a ¹¹CO₂ pulse up to 30% of the total tracer transported tothe root had appeared as labelled carbon dioxide within theroot bathing solution. Through the use of inhibitors it wasfound that 30% of the total tracer released from the roots wasprobably root exudate, the remaining fraction being carbon dioxidefrom root respiration. When no inhibitors were present the micro-organismpopulation on the root was able to utilize all of the root exudateso that none accumulated in the root bathing solution. Export of recently fixed carbon from the root back to the shootwas very dependent on root respiration. Key words: Wheat, Roots, Carbon exudation     

The Influence of Partial Pressure of Carbon Dioxide upon Carbon Metabolism in the Tomato Leaf

The incorporation of radioactive carbon into various photosyntheticproducts was investigated with tomato plants in atmospherescontaining between 40 and 1400 parts/10⁶ carbon dioxide. A significantlygreater proportion of ¹⁴C entered sucrose and alcohol-insolublematerial at high concentrations of carbon dioxide. Incorporationinto glycine and serine was significantly greater at lower carbon-dioxideconcentrations. The pool size of these intermediates was alsodetermined and it was concluded that in the presence of highpartial pressures of carbon dioxide the flow of carbon fromthe photosynthetic cycle through the C² pathway is decreased.     

盐胁迫对不同生境盐地碱蓬光合及离子积累的影响

为了探讨盐地碱蓬(Suaeda salsa)适应不同生境的生理机制, 研究了盐处理(1、200和600 mmol·L^-1 NaCl)对盐碱地和潮间带两种生境盐地碱蓬地上部分及根系有机干重、叶片叶绿素含量及光合放氧速率、叶片和根中离子积累的影响。结果表明: 200 mmol·L^-1 NaCl对两种生境盐地碱蓬地上部分及根系的有机干重无显著影响, 说明两种生境盐地碱蓬均具有较强的抗盐性; NaCl处理显著降低了两种生境盐地碱蓬叶片的光合放氧速率; 各浓度NaCl处理下, 盐碱地生境盐地碱蓬叶片的光合放氧速率均高于潮间带生境的, 潮间带生境盐地碱蓬叶片中叶绿素a与叶绿素b的比值均高于盐碱地生境的; 各浓度NaCl处理下, 潮间带生境盐地碱蓬叶片中的Cl^-含量均低于盐碱地生境的; 与叶片中情况相反, 高盐处理下, 潮间带生境盐地碱蓬根中的Cl^-含量均高于盐碱地生境的。说明与盐碱地生境盐地碱蓬相比, 潮间带生境盐地碱蓬的根系可能对Cl^-具有较强的积累或限制其向地上部分运输的能力, 这些特征可能是盐地碱蓬适应不同生境的结果。     

The Influence of Plant Water Deficit on Distribution of 14C-labelled Assimilates in Cacao Seedlings

The relationship between plant water status and distributionof ¹⁴C-labelled assimilates in cacao (Theobroma cacao L.) wasevaluated after ¹⁴CO₂ pulse labelling leaves of seedlings subjectedto varying levels of water deficiency. The proportion of ¹⁴Cexported by source leaves was strongly affected by seedlingwater status. An increasing proportion of labelled assimilatesremained in source leaves at both 24-h and 72-h harvests aswater stress intensity increased. Water stress reduced the distributionof exported label to leaves and to the expanding flush in particularbut increased the proportion of label in stems and roots. Theresults suggest that current photoassimilates may be temporarilystored in source leaves and stems of cacao seedlings duringperiods of plant water deficit. The stress-induced changes inpartitioning of labelled carbon were in concordance with changesin shoot to root biomass ratios, which was likely due to greaterreduction in growth of above-ground organs to that of roots. Theobroma cacao L, assimilate partitioning, cacao, ¹⁴C-photoassimilate, water stress, water potential     

盐生植物海马齿离体再生

建立盐生植物海马齿(Sesuvium portulacastrum)的离体再生体系,为其生物技术改良奠定基础。以海马齿叶片、茎和腋芽为外植体, 在不同激素配比的培养基上进行愈伤组织诱导、继代培养以及不定芽的分化和生根培养。结果表明: 最适愈伤组织诱导的外植体为叶片, 其次为幼嫩的茎段和腋芽。以叶片为外植体, 愈伤组织诱导率最高的培养基为MS+2.0mg·L^–12, 4-D + 0.5 mg·L^–16-BA + 3%sucrose; 芽分化最适培养基为MS + 1.0 mg·L^–1 2, 4-D + 0.2 mg·L^–1 6-BA + 3% sucrose;生根最适培养基为MS + 3%sucrose + 0.1%AC。炼苗移栽后, 成活率可达80%。     

Translocation of Radiolabeled Indole-3-Acetic Acid and Indole-3-Acetyl-myo-Inositol from Kernel to Shoot of Zea mays L.

Either 5-[³H]indole-3-acetic acid (IAA) or 5-[³H]indole-3-acetyl-myo-inositol was applied to the endosperm of kernels of dark-grown Zea mays seedlings. The distribution of total radioactivity, radiolabeled indole-3-acetic acid, and radiolabeled ester conjugated indole-3-acetic acid, in the shoots was then determined. Differences were found in the distribution and chemical form of the radiolabeled indole-3-acetic acid in the shoot depending upon whether 5-[³H]indole-3-acetic acid or 5-[³H]indole-3-acetyl-myo-inositol was applied to the endosperm. We demonstrated that indole-3-acetyl-myo-inositol applied to the endosperm provides both free and ester conjugated indole-3-acetic acid to the mesocotyl and coleoptile. Free indole-3-acetic acid applied to the endosperm supplies some of the indole-3-acetic acid in the mesocotyl but essentially no indole-3-acetic acid to the coleoptile or primary leaves. It is concluded that free IAA from the endosperm is not a source of IAA for the coleoptile. Neither radioactive indole-3-acetyl-myo-inositol nor IAA accumulates in the tip of the coleoptile or the mesocotyl node and thus these studies do not explain how the coleoptile tip controls the amount of IAA in the shoot.     

Hypoxia Induces Membrane Depolarization and Potassium Loss from Wheat Roots but does not Increase their Permeability to Sorbitol

This paper deals with the responses of roots of wheat {Triticumaestivum L.) to hypoxia with special emphasis on the effectsof severe O2 deficiency on membrane integrity, loss of K+ fromthe root and root membrane potentials. Seminal and crown roots of 26-d-old plants exposed to severehypoxia (0.003 mol O₂ m^–3) for 3 h or 10 d prior to excisionand subsequently exposed to hypoxic solutions, had slightlylower rates of sorbitol influx and a slightly smaller apparentfree space than roots in aerated solutions. These results indicatethat neither a few hours nor a 10-d exposure to hypoxia hadadverse effects on the membrane integrity of the bulk of thecells in the roots. However, both 6-d-old seedlings and 26-d-oldplants lost K⁺ from the roots following their transfer fromaerated to hypoxic nutrient solutions. In the 26-d-old plants,which were of high nutritional status, there was a net K⁺ effluxfrom the roots to the external solution. In contrast, with the6-d-old seedlings, which were of low nutritional status, thedecrease in the K⁺ content of the roots was smaller than thenet K⁺ uptake to the shoots. Exposure of excised roots to 0.008 mol O₂ m^–3caused arapid and reversible membrane depolarization from –120to ––80 mV. These data and the magnitude of thenet effluxes strongly suggest that K⁺ losses during the earlystages of hypoxia are due to membrane depolarization ratherthan to increases in the permeability of membranes to K ⁺. Key words: Hypoxia, membrane integrity, membrane potentials, seminal and crown roots     

Anoxia tolerance in rice seedlings: exogenous glucose improves growth of an anoxia-'intolerant', but not of a 'tolerant' genotype

This study demonstrated that, in rice seedlings, genotypic differencein tolerance to anoxia only occurred when anoxia was imposedat imbibition, but not at 3 d after imbibition. When seeds wereimbibed and grown in anoxia, IR22 (anoxia-‘intolerant’)grew much slower and had lower soluble sugar concentrationsin coleoptiles and seeds than Amaroo (anoxia-‘tolerant’),while Calrose was intermediate. After 3 d in anoxia, the sugarconcentrations in embryos and endosperms of anoxic seedlingswere nearly 4-fold lower in IR22 than in Amaroo. Sugar deficitin the embryo of IR22 is presumably due to the limitation ofsugar mobilization rather than the capacity of transport asshown by similar sugar accumulation ratios of 1.8 between embryoand endosperm in IR22 and Amaroo at 3 d in anoxia. With 20 molm^–3 exogenous glucose, coleoptile extension and freshweight increments in anoxic seedlings of IR22 were much closerto those in the two other genotypes, nevertheless protein concentrationremained lowest on a fresh weight basis in the coleoptiles ofIR22; indicating that protein synthesis has a lower priorityfor energy apportionment during anoxia than processes crucialto coleoptile extension. In contrast to these responses to anoxiaimposed at imbibition, IR22 had nearly the same high toleranceto anoxia as Calrose and Amaroo, when anoxia was imposed onseedlings subsequent to 48 h aeration followed by 16 h hypoxicpretreatment. In fact, coleoptiles of anoxic IR22 had highersugar concentrations and grew faster than Calrose, and exogenousglucose had no effect on the coleoptile extension of IR22. Excisedcoleoptile tips of IR22 and Amaroo with exogenous glucose hadsimilar rates of ethanol production and were equally tolerantto anoxia. In conclusion, much of the anoxia ‘intolerance’of IR22 when germinated in anoxia could be attributed to limitedsubstrate availability to the embryo and coleoptile, presumablydue to slow starch hydrolysis in the endosperm. Key words: Anoxia, coleoptile, embryo, endosperm, ethanol production, germination, growth, Oryza sativa L., solute net uptake or loss, sugar availability.     

The Effect of Defoliation on the Carbon Balance in Dactylis glomerata

Measurements were made of the carbon dioxide exchange of rootsand shoots, changes in soluble carbohydrates, rates of rootextension, and rate of phosphorus uptake of young plants ofDactylis glomerata (Cocksfoot) during eight days following defoliation.The results indicated that the soluble carbohydrates formedpart of a labile pool which was used in respiration and forproviding substrates for new growth. Where defoliation was notsevere, the changes in reserve carbohydrates could account fornet respiratory losses and amounts of new growth made. Wheredefoliation was severe, even high concentrations of reservecarbohydrates were inadequate and other substances, presumablyproteins, must have been remobilized for use in respirationand new growth. The content of soluble carbohydrate in the root was completelyinadequate to meet the needs of root respiration; transfer fromthe tops and/or remobilization of other substances in the rootsmust have occurred. Following a severe defoliation, root extension stopped and ratesof respiration and phosphorus uptake fell markedly. Phosphorusuptake remained at a low level for the eight days considered.After a light defoliation the roots recovered relatively rapidly. It is suggested that, following a severe defoliation, regrowthduring the first week is limited in turn first by the solublecarbohydrate content in the bases of expanding leaves, thenby the rate of photosynthesis, and then in the later Stagesby the rate of nutrient uptake sustained by the roots.     

STUDIES ON PROTEIN SYNTHESIS IN TOMATO COTYLEDONS AND LEAVES. I. PROTEIN SYNTHESIS AND TURNOVER IN INTACT COTYLEDONS AND LEAVES

1. Details of aseptic culture of virus-free tomato seedlings usedin comparative in vivo and in vitro studies on protein synthesisare described.
2. Developmental changes in the levels of DNA,RNA, protein andchlorophyll content of seedling cotyledonsand leaves were recorded,and are related to protein synthesis.
3. Incorporation of isotopically labeled carbon into proteinwasfollowed both by photosynthetic uptake of ¹⁴CO₂ and by theuptakeof ¹⁴C-amino acids through the roots.
4. A marked stimulationby light of ¹⁴C uptake was observed, andthe higher rate of¹⁴C incorporation from ¹⁴CO₂ than from ¹⁴C-aminoacids intothe protein fraction is discussed in relation tothe pathwaysof protein synthesis in tomato leaves, and alsowith regardto protein turnover.

¹Present address: Dept. of Horticultural Science, Universityof Wisconsin, U.S.A.     

Tissue-Specific Isoforms of Catalase Subunits in Castor Bean Seedlings

Catalases purified from endosperm glyoxysomes and non-specializedmicrobodies from hypocotyls of castor bean seedlings differedin their specific activity [90–164 and 0.89–4.9kunits (mg protein)^–1, respectively] and in their constituentsubunits [two subunits of 54 and 56 kDa for the endosperm enzymeand only one of 56 kDa for the hypocotyl enzyme]. Immunoblotanalysis also showed that particulate fractions from the endospermsand from etiolated and green cotyledons contained two catalasesubunits of 54 and 56 kDa, whereas such fractions from the hypocotylsand roots contained only the 56-kDa subunit. Leaf peroxisomesfrom green leaves had two catalase subunits of around 55 kDaeach. Results of translation in vitro indicated that the 54-and 56-kDa subunits were translated from distinct mRNAs andlevels of both mRNAs increased in the endosperms during germination,prior to increases in levels of catalase proteins. In the hypocotyls,the 56-kDa subunit seemed to be synthesized constitutively. ¹Present addresses: YO, Toyota Central Institute, 31-9 Musashizuka,Nagabuchi, Nagakute, Aichi 480-11, Japan     

Inhibition of the Coleoptile Growth in Avena sativa by Endosperm Removal--Changes in Auxin, Osmotica and Cell Wall

Removal of the endosperm from 84-h-old etiolated oat seedlingsstrongly retarded the subsequent growth of coleoptiles. Thecontribution of the endosperm to coleoptile growth was studied.Endosperm removal was found to: (1) decrease the endogenouslevel of indole-3-acetic acid (IAA) in the coleoptile tip. IAAapplied to the coleoptile tip stimulated coleoptile growth inseedlings with and without the endosperm. The sensitivity ofthe coleoptile to a suboptimal concentration of IAA was higherin seedlings without the endosperm than in intact ones. At theoptimal concentration of IAA, however, the final length of thecoleoptile was larger in intact seedlings than in those withoutthe endosperm. (2) decrease the concentration of the solublesugars and amino acids in the cell sap. (3) retard the increasein the amount of polysaccharides in the cell wall of the coleoptile,particularly noncellulosic ones. (4) make the cell wall mechanicallyrigid according to stress-relaxation analysis of the cell wall.(5) induce an increase in the osmotic potential of the coleoptilecell sap. From these results, it was concluded that the endosperm suppliesthe coleoptile with IAA, sugars and amino acids, thus promotingcoleoptile growth. (Received September 24, 1987; Accepted February 3, 1988)     

Endosperm sterol phenotype and germination in wheat

Free and conjugated sterols of endosperm, coats, scutellum, coleoptile and roots have been analysed at different germination stages in two wheat cultivars with different endosperm sterol phenotypes. It seems that sterol metabolism of the developing tissues, namely coleoptile and roots, is not affected by the sterol conjugation profile of the endosperm. Enough sterol is present in the mature embryo to supply the germinating axis during the observation period (144 hr at 16°). The data suggest that sterol is transferred from scutellum to coleoptile and roots during germination.     

自然干旱胁迫下长春花叶片和根部的激素和可溶性糖代谢变化

植物在离开生长环境较短时间内（1~6 h）会导致缓慢的表面水分散失,引起自然的干旱胁迫。本文以耐旱植物长春花（Catharanthus roseus）为材料,研究其在离土干旱胁迫中的脱落酸（ABA）及可溶性糖含量变化。结果表明,长春花根部ABA含量在正常条件下低于叶片中的含量,干旱胁迫促进了ABA在根部的积累,6 h时增加至最高值。蔗糖酸性转化酶活性可能受到ABA的诱导在胁迫6 h时最高,比对照高出30%左右。长春花叶片中总可溶性糖含量在对照条件下非常稳定,但在干旱胁迫过程中,其随着时间的延长呈现线性增加的趋势（r²=0.964）,蔗糖和已糖含量在胁迫过程中也呈增加的趋势,可能发挥着渗透调控节功能。     

Sources of Free IAA in the Mesocotyl of Etiolated Maize Seedlings

Sources of free indole-3-acetic acid (IAA) for the mesocotyl of intact etiolized maize ((Zea mays L.) seedlings are evaluated. The coleoptile unit, which includes the primary leaves and the coleoptilar node, is the main source of free IAA for the mesocotyl. The seed and the roots are not immediate sources of IAA supply. Dependence of the apical growing region of the mesocotyl on the coleoptile unit as a source of free IAA is almost total. One-half or more of the supply of IAA comes from the coleoptile tip, the rest mainly from the primary leaves. Removal of the coleoptile tip results in inhibition of mesocotyl elongation. The hypothesis that growth of the mesocotyl is regulated by auxin supplied by the coleoptile is supported. Conjugated forms of IAA appear to play little part in regulating the levels of free IAA in the shoot.     

海水胁迫对苦荬菜幼苗生长及生理特性的影响

抗盐耐海水植物的种植是有效利用和开发滩涂资源的措施之一。采用温室砂培方式, 研究了不同稀释配比的海水处理8天对苦荬菜(Lactuca indica)幼苗生物量、根冠比、叶绿素含量、离子含量、可溶性蛋白和可溶性糖含量的影响。结果表明: 苦荬菜幼苗地上部受海水胁迫较为显著, 而根在海水浓度小于30%时与对照相比没有显著差异; 根冠比随着海水浓度的增加而不断提高; 在10%和20%海水浓度处理下, 叶绿素含量与对照相比差异不显著, 但随着海水浓度的进一步增加,叶绿素含量显著下降; 在10%海水浓度处理下, 苦荬菜地上部分及根部的K⁺含量与对照相比差异不显著, 而海水浓度高于10%时, 随着海水浓度的增加地上部和根部的K⁺含量均逐渐降低; 海水处理下, 苦荬菜体内Na⁺和Cl^–含量逐渐增加; 地上部可溶性糖含量逐渐增加, 而可溶性蛋白含量先升后降。海水胁迫下, 苦荬菜幼苗维持一定的K⁺选择性吸收是其一定程度上盐适应的重要原因。同时, 积累的可溶性糖和可溶性蛋白是苦荬菜幼苗在盐胁迫下的重要渗透调节物质, 可作为其抗盐性的生理参数。