Distribution and mobility of aluminium in an Al-accumulating plant, Fagopyrum esculentum Moench

Buckwheat (Fagopyrum esculentum Moench. cv. Jianxi) accumulateshigh concentrations of Al in the leaves without showing anytoxicity. To understand the accumulation mechanism of Al inbuckwheat, the distribution and mobility of Al in buckwheatwere investigated. Relatively long-term treatment (28 d) withAl led to a decrease in Al concentration from old to young leaves,while a short-term (1 d) exposure to Al resulted in a uniformdistribution of Al in the leaves. When the fourth leaf was wrappedinside a transparent plastic bag to suppress transpiration,the Al concentration of this leaf was only one-quarter of thatin the corresponding leaf without wrappng. Within a leaf, theAl concentration at the margins was much higher than that inthe centre. These results indicate that Al distribution in theleaves is controlled by both rate and duration of transpiration.The mobility of Al between old and new leaves was studied byfirst growing plants in a solution with Al, followed by culturein a solution without Al. The Al content in the two new leavesappeared after removal of external Al was very low, whereasthat in the old leaves did not decrease but continued to increase.The increased Al content was found to be translocated from Alremaining in the roots. It is concluded that Al is not mobileonce it is accumulated in the leaf. Key words: Accumulation, aluminium, buckwheat, distribution, mobility, transpiration.     

Inhibition of Anthocyanin Synthesis by Cobaltous Ions in the First Internode of Sorghum bicolor L. Moench

Cobaltous ions (Co²⁺) inhibited light-mediated anthocyanin synthesisin excised first internodes of Sorghum bicolor (L.) Moench.Studies with precursors/intermediates of the anthocyanin biosyntheticpathway, such as acetate, phenylalanine, t-cinnamic acid, tyrosine,and p-coumaric acid were undertaken to identify the metabolicsite at which Co²⁺ ions inhibit anthocyanin synthesis. p-Coumaricacid partially restored anthocyanin synthesis. No other intermediatewas effective in bringing about recovery. It is suggested thatCo²⁺ might interfere with process/es which leads to the formationof p-coumaric acid, an intermediate of the anthocyanin biosyntheticpathway. Key words: Sorghum bicolor (L.) Moench, anthocyanin, cobaltous ions, phenylalanine ammonia-lyase     

Structure of anthocyanin from the blue petals of Phacelia campanularia and its blue flower color development

The dicaffeoyl anthocyanin, phacelianin, was isolated from blue petals of Phacelia campanularia. Its structure was determined to be 3-O-(6-O-(4'-O-(6-O-(4'-O-beta-d-glucopyranosyl-(E)-caffeoyl)-beta-d-glucopyranosyl)-(E)-caffeoyl)-beta-d-glucopyranosyl)-5-O-(6-O-malonyl-beta-d-glucopyranosyl)delphinidin. The CD of the blue petals of the phacelia showed a strong negative Cotton effect and that of the suspension of the colored protoplasts was the same, indicating that the chromophores of phacelianin may stack intermolecularly in an anti-clockwise stacking manner in the blue-colored vacuoles. In a weakly acidic aqueous solution, phacelianin displayed the same blue color and negative Cotton effect in CD as those of the petals. However, blue-black colored precipitates gradually formed without metal ions. A very small amount of Al(3+) or Fe(3+) may be required to stabilize the blue solution. Phacelianin may take both an inter- and intramolecular stacking form and shows the blue petal color by molecular association and the co-existence of a small amount of metal ions. We also isolated a major anthocyanin from the blue petals of Evolvulus pilosus and revised the structure identical to phacelianin.     

Plasma Membrane Permeability of Root-Tip Cells Following Temporary Exposure to Al Ions Is a Rapid Measure of Al Tolerance among Plant Species

No correlations were recognized between Al tolerance among fourplant species, rice (Oryza sativa L.), maize (Zea mays L.),pea (Pisum sativum L.), and barley (Hordeum vulgare L.), inrank order of Al tolerance, and cation exchange capacities ofroot-tip (0-1 cm) cells or of their cell walls. The plasma membraneof root-tip of Al sensitive plant species (pea and barley) wasconsiderably permeabilized with elongation of root in Al-freesolution following 0.5 h pretreatment with Al. K⁺ release fromand Al permeation into the protoplasts isolated from the root-tipof Al-sensitive plant species were more significant than thosefor Al-tolerant plant species (rice and maize) on 10 or 30 mintreatment with Al. The permeability of the plasma membrane forprotoplasts isolated from Al sensitive plant species was considerablyincreased by treatment with hy-potonic Al-free control solutionfollowing 10 min pretreatment with Al. To our knowlege, theseare the most rapid responses to Al ions reported to date, i.e.,within 0.5 h in whole plant and within 10 min in protoplast.These results suggest that a temporary contact with Al ionsirreversibly alters the plasma membrane of root-tip cells ofAl-sensitive plant species: the cells become more leaky andrigid due to binding of Al ions to the plasma membrane. (Received January 5, 1998; Accepted February 26, 1998)     

Effect of fruit maturity on UV-B-induced post-harvest anthocyanin accumulation in red Chinese sand pear

The effect of fruit maturity on UV-B-induced post-harvest anthocyanin accumulation in red Chinese sand pear (Pyrus pyrifolia Nakai) cultivar ‘Mantianhong’ was evaluated. During the irradiation, compared with the fruit harvested at 20 days before harvest (DBH) and 10 DBH, the mature fruit (harvested at commercial harvest date) had higher soluble solids content, soluble sugars concentration but lower firmness and starch content. In addition, higher content of anthocyanin has been detected in mature fruits than in immature fruits due to the significant increase in the expression of genes related to anthocyanin biosynthesis, especially PpCHS, PpF3H, PpANS, PpUFGT, PyMYB10 and PpbHLH in red Chinese sand pears. Hierarchical clustering analysis suggested that most genes related to anthocyanin biosynthesis showed a coordinate expression pattern. These findings are helpful in understanding the molecular mechanism of anthocyanin biosynthesis and regulation, which could lead to the development of new technologies for improving fruit color in Chinese sand pears and other fruits.     

不同溶剂和保存条件对尾叶悬钩子花色素苷提取及稳定性的影响

对尾叶悬钩子(Rubus caudifolius Wuzhi)鲜果中花色素苷的提取条件、主要化学组分及pH值、温度、没食子酸和Al^3 对其颜色及稳定性的影响进行了分析探讨。结果表明,尾叶悬钩子花色素苷的主要组分可能为矢车菊素-3-葡萄糖苷;pH值和温度影响该花色素苷的色泽及其稳定性,随着pH值和温度的增加,其分解加剧,且花色素苷的分解均遵循动力学一级反应规律;添加不同浓度的Al^3 ,色素溶液的吸光值有所升高,显示出有一定的增色效应,但Al^3 和没食子酸对贮藏期间花色素苷的稳定性及色泽均无明显效果。     

不同种源黄连木秋季色素含量与叶色参数的关系

该研究以陕西汉中、河南林州、河北涉县和北京中国科学院植物研究所4个种源黄连木(Pistacia chinensis Bunge)的苗木为对象,用分光光度计和色差仪对其叶绿素、类胡萝卜素、花色素苷含量及叶色参数(L*、a*、b*)进行了测定分析,探讨不同种源苗木秋季叶色变化规律及差异,揭示黄连木叶色呈现与叶片色素含量之间的内在关联,为筛选适合城市绿化的优良黄连木种源提供依据。结果表明:(1)在秋季叶片转色期,随着时间的推移,4个种源黄连木叶片的叶绿素、类胡萝卜素和花色素苷含量的比例呈现不同的变化趋势,其中:河北种源的花色素苷含量较高,叶片呈现红色;陕西种源叶绿素含量较高,叶片呈现绿色的时间较长;河南、北京种源处于两者之间。(2)各个种源黄连木的叶色参数a*值(红/绿)均与花色素苷含量呈正相关关系,与叶绿素含量呈负相关关系,且相关系数均达到显著水平(P0.05),各个种源叶色参数L*值(光泽明亮度)也与叶绿素含量间表现出显著或极显著的正相关性。研究发现,河北种源黄连木秋季的叶色最红,陕西种源黄连木叶片呈现绿色的时间最长;色差仪的应用实现了叶色和各色素含量间量化的关系。     

Changes of the Structure of Pea Chromatin by Aluminum

Structural changes of pea chromatin due to in vitro or in vivotreatment with Al were investigated. The absorption spectrumshowed that chromatin might be condensed and/or aggregated withAl treatment. Analysis of the melting profile showed that chromatinprepared from Al-treated roots was more stable to thermal treatment. Chromatin from Al-treated roots and chromatin treated with Alin vitro were less susceptible to DNase II digestion. When thepartially digested chromatin with DNase II was chromatographedwith Bio-Gel A5m, the digestibility of chromatin obtained fromAl-treated roots was less than that from control roots. Furthermore,most of the Al was associated with a chromatin fraction whichwas minimally digested with DNase II and of large size afterthe gel chromatography. The results suggested that Al absorbedby pea roots is somehow related to alteration of the chromatinstructure, i.e. its condensation and/or aggregation. The conclusionreached was that Al toxicity results from disturbance of thenuclear activity. (Received July 22, 1987; Accepted December 7, 1987)     

金属离子对黑米花青苷色素吸收光谱的影响

以黑糯B糙米皮为实验材料 ,用 1 .5mol/L盐酸— 95 %乙醇 (V/V :1 5 / 85 )溶液提取黑米花青苷色素(BRAP) ,采用紫外可见分光光度法研究了 1 1种金属离子以及 (NH4 ) 1+ 离子对BRAP的作用。结果表明 ,未加离子条件下色素溶液可见光区λmax5 35nm ,紫外光区λmax2 80nm ,加入Al3 + 、Fe3 + 、Fe2 + 、Cu2 + 、Mn2 + 、Zn2 + 、Sn2 + 对其吸收光谱有显性影响。其中Al3 + 、Fe3 + 使 5 35nm特征吸收峰发生蓝移 ,Sn2 + 使其发生明显红移 ;Al3 + ,Fe2 + ,Mn2 + ,Zn2 +在 5 35nm附近有增加ABS值作用 ,Fe3 + 有减小ABS值作用 ;延长作用时间 ,Cu2 + 对BRAP吸收光谱的影响表现为λmax5 35nm发生蓝移 ,ABS值减小     

Intercellular and Intercultural Heterogeneity in Secondary Metabolite Accumulation in Cultures of Catharanthus roseus following Cell Line Selection

Hall, R. D. and Yeoman, M. M. 1987. Intercellular and interculturalheterogeneity in secondary metabolite accumulation in culturesof Catharanthus roseus following cell line selection.—J.exp. Bot. 38: 1391–1398. Anthocyanin accumulation in a stock culture of Catharanthusroseus was consistently found, using microscopic and microdensitometrictechniques, to involve only c. 10% of the cell population. However,an analysis of 26 cell lines isolated from this culture hasindicated that all of the cells within the culture were, theoretically,capable of anthocyanin synthesis. Nevertheless, these linesdid display substantially different capacities for anthocyaninaccumulation. Detailed studies on individual cells from thesecultures have revealed that the variation in accumulation wasprimarily due to differing proportions of pigmented (i.e. productive)cells rather than differing mean intracellular anthocyanin concentrationswithin these cells. Both the proportion of productive cellsand the overall culture yield of the cell lines varied by >30-fold whereas the mean intracellular anthocyanin concentrationvaried by < 2-fold. The relevance of these results to thepossible control mechanisms involved in secondary metaboliteproduction in this and other culture systems is discussed. Key words: Catharanthus roseus, cell culture, anthocyanin, heterogeneity     

Blueing of sepal colour of Hydrangea macrophylla

Blue and red sepals of Hydrangea macrophylla were quantitatively analyzed for aluminium, anthocyanin (delphinidin 3-glucoside) and copigments (caffeoyl- and p-coumaroylquinic acids). All the blue sepals examined contained both Al and copigments (especially 3-caffeoylquinic acid) in considerable amounts. In in vitro experiments using 3- and 5-caffeoylquinic acids, Al and delphinidin 3-glucoside, it was shown that 3-caffeoylquinic acid and Al formed a blue complex with the anthocyanin. Absorption spectra of the blue complex were practically identical with those of the blue solutions obtained from blue hydrangea sepals by extraction with 4 M NACl. In contrast, 5-caffeoylquinic acid (chlorogenic acid) which was also present in hydrangea sepals gave only a red-purple colour with Al and the anthocyanin. Neither 3-caffeoylquinic acid nor Al independently produced blue colour when mixed with the anthocyanin in the mole ratios of 1–30, this being the range that the compounds were found in blue sepals. These results suggest that blue colour of hydrangea sepals is due mainly to the blue complex of delphinidin 3-glucoside-aluminium-3-caffeoylquinic acid. The role of aluminium may be to stabilize an interaction between the quinic ester and the anthocyanin.     

Effects of Growth Regulators on the Induction of Anthocyanin Synthesis in Carrot Suspension Cultures

The effects of plant growth regulators were investigated onanthocyanin synthesis induced by removing auxin from carrotsuspension cultures. Of the auxins tested, 2,4-D showed thestrongest inhibiting effect on anthocyanin synthesis and hadthe strongest promoting effect on undifferentiated growth. When2,4-D was added to anthocyanin synthesizing cells, in whichcell division had ceased, anthocyanin synthesis was repressedimmediately, accumulated anthocyanin disappeared and cell divisionresumed. All cytokinins examined promoted anthocyanin synthesisin the absence of auxin. Both gibberellic acid (GA₃) and abscisicacid inhibited anthocyanin synthesis in media lacking 2,4-D,though GA³ showed no effect on cell division. These effectsof growth regulators on anthocyanin synthesis are similar tothose reported for their effects on embryogenesis [Fujimuraand Komamine (1975) Plant Sci. Lett. 5: 359, (1979) Z. Pflanzenphysiol.95: 13, (1980) Z. PJlanzenphysiol. 99: 1]. The relationshipbetween the induction of anthocyanin synthesis, metabolic differentiation,and embryogenesis are discussed. ¹ Present address: Department of Biology, College of Arts andSciences, The University of Tokyo, Komaba, Meguro-ku, Tokyo153, Japan. ² Present address: Biological Institute, Faculty of Science,Tohoku University, Sendai, Miyagi 980, Japan. (Received November 28, 1985; Accepted July 23, 1986)     

A combination of five mechanisms confers a high tolerance for aluminum to a wild species of Poaceae,Andropogon virginicus L.

How can high tolerance against aluminum (Al) toxicity be obtained in plants? To address this question, tolerant mechanisms were characterized in a highly Al tolerant wild species of Poaceae, Andropogon virginicus L. A. virginicus showed an Al-stress-induced synthesis and secretion of citrate and malate in roots. This mechanism may help to suppress an increase of toxic Al ions in the root region. Microscopic observation of the morin-stained leaves indicated that the Al transferred to shoots was specifically accumulated in the trichomes and spikes of the leaves and that some portion of the accumulated Al was furthermore secreted as sap from the tips of trichomes. Al-induced synthesis of poly-phenolic compounds including anthocyanin also occurred in roots as a long term response to Al toxicity and anthocyanin production did not co-localize with either Al accumulation, nitric oxide (NO) production or lipid peroxides production in the roots. It was suggested that oxidative damage caused by Al stress was suppressed in these areas where anthocyanin was localized. Moreover, induction of NO production occurred in roots within 24 h of Al treatment. Our results suggested that NO could not efficiently ameliorate the Al-dependent nuclei deformation and DNA fragmentation, but could function as a trigger to stimulate anti-peroxidation enzymes under Al stress. Collectively the results suggested that A. virginicus manifests its high Al tolerance by a unique combination of effective mechanisms.     

Specific Secretion of Citric Acid Induced by Al Stress in Cassia tora L.

A rapid and sensitive assay method for Al-chelating activitywas established to screen Al-chelating substances secreted fromroots of Al-resistant species in response to Al stress. Fromone Al-resistant species, Cassia tora L., an Al-chelating substancewas detected in the root exudates when they were exposed toSO µM Al in 0.5 mM CaCl₂ solution at pH 4.5; the dominantcomponent was identified as citric acid. The secretion of citricacid was very low during the first 4 h after initiation of Altreatment, but increased markedly thereafter. A 3-h pulse with50 µM Al also induced significant secretion of citricacid after 6 h. The lag between Al addition and secretion ofcitric acid suggests that inducible processes are involved.A dose-response experiment showed that the amount of secretedcitric acid increased with increasing external concentrationsof Al. Eight-d treatment of P deficiency did not induce thesecretion of citric acid. Exposure to 50µM of either lanthanum(La³⁺) or ytterbium (Yb³⁺) did not induce the secretion of citricacid either. These findings indicate that the secretion of citricacid is a response specific to Al stress in .C. toraand constitutesa mechanism of Al resistance. (Received April 23, 1997; Accepted June 25, 1997)     

Aluminium Effects on ATPase Activity and Lipid Composition of Plasma Membranes in Sugar Beet Roots

The effect of aluminium (Al) in vivo and in vitro on root plasmamembranes has been studied in two sugar beet (Beta vulgarisL.) cultivars, Monohill (Al-sensitive) and Regina (relativelyAl-tolerant). Although Al in vitro inhibited the MgATPase inan uncompetitive way for both cultivars raised in the absenceof Al, the specific K⁺-activation of the MgATPase was only inhibitedby Al in cv. Monohill. Arrhenius analysis of the MgATPase activity showed that theeffect of Al in vitro depended on whether or not the plantswere exposed to Al in vivo. Al treatment in vitro of the MgATPasefrom control plants cultivated at a low pH (5·4) causedan increase in the phase transition temperature from 17 to 22°C. Only at a higher pH range (pH 6·1) could a secondtransition temperature be induced (at 9 °C). By additionof Al in vitro to plants cultivated with Al at pH 5·4,the slopes of the activity plots did not change. Aluminium changedthe K_m of the ATPase for MgATP in an opposite way by treatmentin vivo and in vitro. Lipid analyses of the plasma membranes showed that the acylcomposition differed little following Al treatment in vivo,but that the ratio of phosphatidylcholine: phosphatidylethanolamineincreased. The changes correlated with the observed change inthe K_m for the MgATPase. We conclude that the main effect ofAl on the MgATPase is not due to the formation of an Al-ATPcomplex. Instead, Al may bind to the membrane-bound enzyme(s)and/or modify the lipid environment. Key words: Aluminium, ATPase, Beta vulgaris, lipids     

Involvement of Riboflavin in UV-A and White Light-induced Synthesis of Anthocyanin in Sorghum bicolor

Synthesis of anthocyanin in isolated mesocotyls of Sorghum bicolor(var. Vidisha 60–1) is promoted by the external feedingof riboflavin (FMN) under white and UV-A light. Potassium iodide,salicylhydroxamic acid and sodium azide, which are known tointerfere with the photoreactions of riboflavin, inhibit thesynthesis of anthocyanin induced by white and UV-A light. Thisinhibition is reversed by riboflavin and there is a direct interactionbetween the inhibitors and riboflavin. It is concluded thatriboflavin is the major photoreceptor for the induction of anthocyaninsynthesis in Sorghum bicolor by white and UV-A light. Key words: Sorghum, anthocyanin, riboflavin, UV-A     

Senescence in Leaves of Acer pseudoplatanus L. and Parthenocissus tricuspidata Planch: 1. Changes in Some Leaf Constituents during Maturity and Senescence

Data are recorded of the changes in chlorophylls, carotene,sugar, shikimic acid, and anthocyanin in leaves of sycamore(Acer pseudoplatanus L.) and Virginia creeper (Parthenocissustricuspidata Planch.) during leaf maturity and senescence. InParthenocissus the losses of chlorophylls, carotene, sugar,and shikimic acid during senescence were closely correlated,and were inversely related to the accumulation of anthocyanin.The losses of chlorophylls, carotene, and sugar by Acer leaveswere also closely correlated. No evidence was found to supportthe suggestion that anthocyanin formation was caused by accumulationof sugar during senescence, but marked differences in shikimicacid content were found between leaves of Acer, which did notform anthocyanin, and Parthenocissus. which did. It is suggestedthat autumn senescence of these leaves involves the rapid senescenceof an increasing proportion of the leaf tissue during a periodof 80 days, and that measurements of the content of constituentsgive an estimate of the proportion of the leaf tissue whichhas senesced.     

Photoregulation of Phenylalanine Ammonia Lyase is not Correlated with Anthocyanin Induction in Photomorphogenetic Mutants of Tomato(Lycopersicon esculentum)

Photoregulation of phenylalanine ammonia lyase (PAL)(EC 4.3.1.5 [EC] )was analyzed in wild type (WT) and mutants: phytochrome dencient-awrea(au), high pigment exhibiting exaggerated phytochrome response(hp) and the double mutant (au.hp) of tomato (Lycopersicon esculentum(Mill.) cv. Ailsa Craig). Red light, acting via phytochrome,stimulates PAL activity in cotyledons and hypocotyls of tomatoseedlings. The time course of photoinduction of PAL in cotyledonsof the mutants (au and au.hp) and WT seedlings has a peak ofactivity at 4 h, after which the activity falls sharply, exceptin hp seedlings where activity is maintained at a high level.In hypocotyls, photoinduction of PAL also shows an initial rise,reaching a maximum at 3 h, followed by a sharp decline in themutants (au and au.hp) and WT seedlings. However in hp seedlingsphotoinduction of PAL is about 3 fold that in WT. The photoinductionof PAL appears to be dependent on de novo synthesis of proteinand nucleic acids. The use of a PAL specific inhibitor a-aminooxyß-phenylpropionic acid indicated that PAL is an essentialcomponent of the anthocyanin biosyn-thetic pathway in the tomatoseedlings. However, a comparison of anthocyanin biosynthesis[Adamse et al. (1989) Photochem. Photobiol. 50: 107] and PALphotoinduction data revealed that phytochrome mediated inductionof PAL and anthocyanin in the tomato seedlings are not correlated.While au and au.hp mutant seedlings show a similar increasein PAL level as in the WT, there is little formation of anthocyaninin these mutant seedlings. The results indicate that, in contrastto the photoregulation of anthocyanin synthesis which is dependenton the presence of the labile phytochrome (IP) pool in tomatoseedlings, the photoinduction of PAL is mediated via a smallpool of phytochrome in au mutant: stable phytochrome (sP) ora residual /P pool. (Received August 6, 1991; Accepted September 27, 1991)     

Growth and Nutrient Status of Quercus rubra L. in Response to Al and Ca

Northern red oak (Quercus rubra L.) seedlings were grown for63 d in a complete nutrient solution (pH 3.8) containing oneof three concentrations of Al (0, 0.75 or 2-0 mol m^–3)and either 10 or 250 mmol m^–3 Ca. Of all solution variables,the In of (Al³⁺)/(Ca²⁺), the solution activities ratio, wasmost closely correlated with declines in shoot and root growth.Ln (Al³⁺)/(Ca²⁺) also most closely predicted leaf and root [Mg],[Al], and [Al]/[Ca]. These three variables in turn were closelyrelated to growth. Toxic levels of (Al³⁺) and (Al³⁺)/(Ca²⁺)in solution are compared to levels in forest soils. Key words: Al phytotoxicity, Al x Ca interaction, Quercus rubra     

Soil Solution Chemistry Controlling the Field Distribution of Melica ciliata L.

Germination, establishment and growth of Melica ciliata L.,an 'acidifuge' species of rocky habitats in Europe, were studiedexperimentally and related to chemical properties of the soilsolution, including pH, base cation composition, Al concentrationand speciation, and Mn concentration. M. ciliata failed to establishin acid leptite soil. However, it was able to grow in solutionat pH 3·6 and exhibited vigorous growth at pH 3·9,a typical soil solution pH of leptite sites, which Melica isunable to colonize. Higher concentrations of Mn than those measuredin any leptite soil solutions did not influence growth. Exposureto 0·037 mmol l^-1 (1 mg l^-1) of Al³⁺, a concentrationusually exceeded in the soil solution of leptite sites, severelyretarded root growth. Speciation technique applied to Al insoil solutions obtained by centrifugation demonstrated a closerelationship between H⁺ and Al concentrations and, in particular,between H⁺ and free ionic (quickly reacting) Al species. Soilsolution concentrations of free ionic Al proved to be < 0·002mmol l^-1 in sites lacking Melica , but often > 0·10mmol l^-1 in site lacking Metalica . It is concluded that theinability of M. ciliata to establish in acid soils is not primarilydue to the high H⁺ concentration but to the high soil solutionconcentrations of Al, especially free Al ionic species at lowsoil pH.Copyright 1993, 1999 Academic Press Melica ciliata, distribution, soil solution, pH, aluminium speciation, manganese, base cations, iron