The Effect of Nutritional Factors and Certain Growth Substances on the Growth of Disks Cut from Young Leaves of Phaseolus

The roles of some chemical factors influencing leaf expansion were investigated using disks cut from the primary leaves of young plants of Phaseolus grown in subdued light. Mineral nutrients, cobalt, sucrose, GA and IAA or NAA at suitable concentrations all caused increases in fresh and dry weights of such disks. When all these substances were applied together the increases in diameter and in fresh and dry weight and cell number were very large and comparable with the rates found in intact leaf tissue. The response of disks to sucrose was found to be light dependent, and a number of other significant interactions were noted. Disks cut from older leaves, in which cell division had ceased, did not show large increases in fresh weight in response to treatment with sucrose, and in this such disks differ from those cut from leaves in which cell divisions are continuing. The possible significance of this is discussed and the roles of light and the other chemical factors investigated are assessed in terms of influence on cell division and expansion in disk tissue.     

Induction of Phenylalanine Ammonia-lyase in Strawberry Leaf Disks: Action Spectra and Effects of Wounding, Sucrose, and Light

The increase in phenylalanine ammonia-lyase (PAL) activity in strawberry (Fragaria vesca var. WSU-1232) leaf disks required wounding, sucrose, and light and was cycloheximide-sensitive. In injured leaves and in leaf disks, the highest PAL activity was detected nearest the wounded tissues. Without wounding, no increase in activity was observed when leaves were cultured in sucrose and light.     

Influence of fruit load and environmental factors on nitrate reductase activity and on concentration of nitrate and carbohydrates in leaves of eggplant (Solanum melongena)

Both the in vivo (+ nitrate) nitrate reductase (NR) activity (leaf disks incubated in the presence of KNO₃) and the in vivo (? nitrate) NR activity (leaf disks incubated without KNO₃) in leaves of eggplant (Solanum melongena L. cv. Bonica) were affected by rapidly growing fruits. Plants with a fruit load showed more pronounced diurnal variation in (+ nitrate) NR activity and higher (? nitrate) NR activity than plants without fruit. The higher (? nitrate) NR activity was accompanied by higher nitrate and lower sucrose and starch contents of leaves. The more pronounced diurnal changes in (+ nitrate) NR activity were paralleled by more pronounced diurnal variation in carbohydrate content of leaves. Fruit removal led to a decrease in both (? nitrate) NR activity and nitrate concentration in leaves, while the carbohydrate content increased. Plants supplied with ammonium instead of nitrate showed only slightly lower (+ nitrate) but no (? nitrate) NR activity. As for plants treated with nitrate, diurnal changes in (+ nitrate) NR activity were most pronounced in leaves of plants with fruit and this again was paralleled by a more pronounced diurnal variation in the carbohydrate concentration in the leaves. Increasing the oxygen level of the atmosphere to 50% led to a dramatic decrease in the (+ nitrate) NR activity and to an increase in both (? nitrate) NR activity and nitrate concentration, which was accompanied by decreasing carbohydrate contents of the leaves. Low light intensities and extended dark periods caused similar changes in NR activity and nitrate and carbohydrate concentrations in leaves. Increasing the nitrate concentration in the nutrient solution led to a rise in (+ nitrate) and (? nitrate) NR activity, but only the (? nitrate) NR activity paralleled the nitrate concentration in the leaves. This increase in the nitrate concentration was accompanied by a decrease in the carbohydrate content of the leaves. It is concluded that the level of and the diurnal changes in both (+ nitrate) and (? nitrate) NR activity and the concentration of nitrate in the leaves are dependent upon their carbohydrate status.     

THE EFFECT OF SUCROSE SPRAYING ON SYMPTOMS CAUSED BY BEET YELLOWS VIRUS IN SUGAR BEET

When leaves of sugar-beet plants infected with beet yellows virus were sprayed daily with 10% sucrose solution, yellowing symptoms were intensified. When glasshouse plants were shaded so that the light intensity was reduced to less than half of full daylight, yellowing symptoms were suppressed more completely on un-sprayed than on sprayed plants. Spraying with 2–5 % sucrose solution had similar, but slightly smaller effects.
Spraying with sucrose solution increased the carbohydrate content of the leaves, and the effects on symptom intensity and carbohydrate content were closely correlated. The regression coefficients of symptom score on total sugar content were nearly the same for shaded and unshaded plants. As the severity of symptoms was increased by supplying carbohydrate without change in the light conditions, it is concluded that light intensity affects symptom expression by varying the carbohydrate content of the leaves through its influence on photosynthesis.
Sucrose spraying increased the yield of roots of healthy and infected plants, and most of the increase was sucrose. This shows that sprayed sugar was translocated to the roots from the leaves of both healthy and infected plants.
Measurements of changes in carbohydrate content between evening and morning samplings confirmed that movement of carbohydrate out of infected leaves is not stopped by infection.     

Regulatory effect of stems on sucrose-induced chlorophyll degradation and anthocyanin synthesis in Egeria densa leaves

Detached green leaves of the aquatic plant Egeria densa showed chlorophyll degradation and turned red due to induced anthocyanin synthesis incubated in 0.1 M sucrose under continuous light for 7–10 days. If the leaves were placed in water, only chlorophyll degradation occurred and the detached leaves turned yellow. The levels of endogenous total carbohydrates increased in detached leaves cultured in the sucrose solution but only increased marginally in water. If the leaves were still attached to a piece of stem, with a node on either side of the single leaf whorl, then they did not accumulate anthocyanin in culture with 0.1 M sucrose. These leaves showed a similar increase in total carbohydrates and degradation of chlorophyll as detached leaves. Attached leaves, in which the midrib had been cut in situ, showed localized accumulation of anthocyanin in the leaf tissue distal to the cut in the midrib when cultured in 0.1 M sucrose. These results suggest that the stem plays a regulatory role in anthocyanin synthesis in attached leaves cultured in a sucrose solution but does not influence chlorophyll degradation or carbohydrate accumulation.     

Induction of Phenylalanine Ammonia-lyase in Xanthium Leaf Disks. Photosynthetic Requirement and Effect of Daylength

A cycloheximide-sensitive increase in the activity of phenylalanine ammonia-lyase (EC 4.3.1.5) occurs in Xanthium leaf disks exposed to light. Radioactive ammonia-lyase has been isolated by means of sucrose density gradient centrifugation and starch gel electrophoresis from disks fed l-isoleucine-U-(14)C or l-arginine-U-(14)C. The incorporation of radioactive amino acids into phenylalanine ammonia-lyase together with the inhibitory effects of cycloheximide indicate that the observed increase in enzyme activity involves the induction of lyase synthesis.The light-dependent synthesis of the ammonia-lyase is completely inhibited by 50 mum 3-(4-chlorophenyl)-1,1-dimethylurea (CMU) indicating that photosynthesis is involved. Only a trace quantity of some photosynthetic product must be needed because half light saturation occurs at very low intensity (ca. 30 ft-c). Exogenous carbohydrate is also required for continuing enzyme synthesis over a 72 hr period. But carbohydrate does not replace the photosynthetic requirement in darkness.Enzyme formed in light disappears rapidly from disks placed in the dark. The decay of ammonia-lyase activity follows first order kinetics. The half-life of the lyase ranged from 6 to 15 hr in leaf material used. Cyoloheximide inhibits the decay of lyase activity. Thus the maintenance of turnover in Xanthium leaf disks requires de novo synthesis of protein. That turnover, i.e., degradation as well as synthesis of lyase protein occurs is suggested by the apparent loss of radioactive ammonia-lyase from leaf disks placed in darkness. Light-induced synthesis coupled with rapid turnover can produce a diurnal fluctuation of ammonia-lyase activity in Xanthium leaf disks. Alternating periods of enzyme synthesis and degradation were observed in disks exposed to 24 hr cycles of light and dark. The average level of enzyme activity maintained in the tissue was directly related to the length of the light period. Induction of lyase synthesis was also observed in excised leaves and to a lesser extent in leaves of whole plants.     

Post-translational redox modification of ADP-glucose pyrophosphorylase in response to light is not a major determinant of fine regulation of transitory starch accumulation in Arabidopsis leaves

ADP-glucose pyrophosphorylase (AGP) is a heterotetrameric enzyme comprising two small and two large subunits that catalyze the production of ADP-glucose linked to starch biosynthesis. The current paradigm on leaf starch metabolism assumes that post-translational redox modification of AGP in response to light is a major determinant of fine regulation of transitory starch accumulation. According to this view, under oxidizing conditions occurring during the night the two AGP small subunits (APS1) are covalently linked via an intermolecular disulfide bridge that inactivates the protein, whereas under reducing conditions occurring during the day NADP-thioredoxin reductase C (NTRC)-dependent reductive monomerization of APS1 activates the enzyme. In this work we have analyzed changes in the redox status of APS1 during dark-light transition in leaves of plants cultured under different light intensities. Furthermore, we have carried out time-course analyses of starch content in ntrc mutants, and in aps1 mutants expressing the Escherichia coli redox-insensitive AGP (GlgC) in the chloroplast. We also characterized aps1 plants expressing a redox-insensitive, mutated APS1 (APS1mut) form in which the highly conserved Cys81 residue involved in the formation of the intermolecular disulfide bridge has been replaced by serine. We found that a very moderate, NTRC-dependent APS1 monomerization process in response to light occurred only when plants were cultured under photo-oxidative conditions. We also found that starch accumulation rates during the light in leaves of both ntrc mutants and GlgC-expressing aps1 mutants were similar to those of wild-type leaves. Furthermore, the pattern of starch accumulation during illumination in leaves of APS1mut-expressing aps1 mutants was similar to that of APS1-expressing aps1 mutants at any light intensity. The overall data demonstrate that post-translational redox modification of AGP in response to light is not a major determinant of fine regulation of transitory starch accumulation in Arabidopsis.     

Effects of carbohydrate accumulation on photosynthesis differ between sink and source leaves of Phaseolus vulgaris L

Accumulation of non-structural carbohydrate in leaves represses photosynthesis. However, the extent of repression should be different between sink leaves (sugar consumers) and source leaves (sugar exporters). We investigated the effects of carbohydrate accumulation on photosynthesis in the primary leaves of bean (Phaseolus vulgaris L.) during leaf expansion. To increase the carbohydrate content of the leaves, we supplied 20 mM sucrose solution to the roots for 5 d (sugar treatment). Plants supplied only with water and nutrients were used as controls. The carbohydrate contents, which are the sum of glucose, sucrose and starch, of the sugar-treated leaves were 1.5-3 times of those of the control leaves at all developmental stages. In the young sink leaves, the photosynthetic rate at saturating light and at an ambient CO2 concentration (A360) did not differ between the sugar-treated and control leaves. The A360 of sugar-treated source leaves gradually decreased relative to the control source leaves with leaf expansion. The initial slope of the A-Ci (CO2 concentration in the intercellular space) curve, and the Rubisco (ribulose-1,5-bisphosphate carboxylase/oxygenase) content per leaf area showed trends similar to that of A360. Differences in Amax between the treatments were slightly smaller than those in A360. These results indicate that the effect of carbohydrate accumulation on photosynthesis is significant in the source leaves, but not in the young sink leaves, and that the decrease in Rubisco content was the main cause of the carbohydrate repression of photosynthesis.     

光质与人参淀粉酶活性、总糖和淀粉含量的关系

研究了生长在同等透光率六种滤光膜覆盖下的人参淀粉酶活性、总糖和淀粉含量的季节性变化。人参叶片的淀粉酶活性、总糖和淀粉含量明显低于根部,叶片酶活性的高峰在红果期,糖和淀份含量在成熟期最高;根部与叶片相反,酶活性高峰在成熟期,糖和淀粉含量在红果期最高。红光、红蓝和红蓝绿复合光下人参的淀粉酶活性,总糖和淀粉含量均较高,单质蓝光和绿光下偏低。红光对糖分的合成与积累有明显促进作用,但有红光参与的复合光更有利于人参的生长。     

Changes in a Leaf-growth Substance in Cotyledons and Primary Leaves during the Growth of Dwarf Bean Seedlings

The growth of etiolated dwarf bean leaf disks in darkness wasused to assay leaf-growth substances extracted from plant tissuesand separated on chromato-grams. A leaf-growth substance, with the same Rf value in isopropanol/ammoniaas gibberellic acid, was found in the acidic fraction of extractsfrom dwarf bean primary leaves and cotyledons. Neither neutralnor basic leaf-growth substances were found in primary leafextracts. The amount of leaf-growth substance per cotyledon reached amaximum at the 4th day in cotyledons, whether bean plants weregrown in the light or dark. Primary leaves of dwarf bean plantsgrown in the light reached their maximum content of leaf-growthsubstance later than the cotyledons; the time of maximum contentcoincided with the maximum growth-rate of the primary leaves.Leaf-growth substances did not accumulate in primary leavesof plants grown in the dark.     

Alterations in leaf carbohydrate metabolism in response to nitrogen stress

A series of experiments was conducted to characterize alterations in carbohydrate utilization in leaves of nitrogen stressed plants. Two-week-old, nonnodulated soybean plants (Glycine max [L.] Merrill, `Ransom'), grown previously on complete nutrient solutions with 1.0 millimolar NO₃⁻, were transferred to solutions without a nitrogen source at the beginning of a dark period. Daily changes in starch and sucrose levels of leaves were monitored over the following 5 to 8 days in three experiments. Starch accumulation increased relative to controls throughout the leaf canopy during the initial two light periods after plant exposure to N-free solutions, but not after that time as photosynthesis declined. The additional increments of carbon incorporated into starch appeared to be quantitatively similar to the amounts of carbon diverted from amino acid synthesis in the same tissues. Since additional accumulated starch was not degraded in darkness, starch levels at the beginning of light periods also were elevated. In contrast to the starch effects, leaf sucrose concentration was markedly higher than controls at the beginning of the first light period after the N-limitation was imposed. In the days which followed, diurnal turnover patterns were similar to controls. In source leaves, the activity of sucrose-P synthase did not decrease until after day 3 of the N-limitation treatment, whereas the concentration of fructose-2,6-bisphosphate was decreased on day 2. Restricted growth of sink leaves was evident with N-limited plants within 2 days, having been preceeded by a sharp decline in levels of fructose-2,6 bisphosphate on the first day of treatment. The results suggest that changes in photosynthate partitioning in source leaves of N-stressed plants resulted largely from a stable but limited capacity for sucrose formation, and that decreased sucrose utilization in sink leaves contributed to the whole-plant diversion of carbohydrate from the shoot to the root.     

A re-examination of the induction of phloem transfer cell development in pea leaves (Pisum sativum)

Abstract The development of phloem transfer cells in expanded dark grown leaflets of pea seedlings (Pisum sativum) has been re-examined. In agreement with previous observations transfer cells in leaflets maintained in the dark did not form wall ingrowths to the same extent as those placed in the light. A previous report that exposure to light in a carbon dioxide depleted atmosphere inhibited wall ingrowth formation could not be confirmed. It was found that dark grown leaflets could be induced to form wall ingrowths without illumination by immersing them in a glucose solution, demonstrating for the first time that light is not necessary for phloem transfer cell differentiation in leaves. Attempts were made to alter the carbohydrate level in the whole seedling by removing the cotyledons, but this had no recognizable effect on wall ingrowth formation in any of the treatments. Starch grain formation in the plastids was taken as an indication of available soluble carbohydrate level in the leaflets. It is concluded that both light and the presence of soluble carbohydrate can independently induce wall ingrowth formation in phloem transfer cells of pea leaflets.     

Infection with Phloem Limited Abutilon Mosaic Virus Causes Localized Carbohydrate Accumulation in Leaves of Abutilon striatum: Relationships to Symptom Development and Effects on Chlorophyll Fluorescence Quenching During Photosynthetic Induction

Abstract: Infection with phloem limited Abutilon Mosaic Virus caused localized carbohydrate accumulation (high levels of starch, sucrose, and hexoses) in leaves of Abutilon striatum during early symptom development. In mature leaves with attenuated symptoms, tissues showing faint vein-clearing had markedly higher carbohydrate contents than uniformly green areas of the same leaf. A similar pattern of carbohydrate accumulation was found in pale-green mosaics in mature leaves with overt symptoms when compared to green-islands of the same leaf, but overnight carbohydrate loses were comparable to controls. Because leaves with attenuated symptoms showed no further symptom development whereas the pale-green mosaics became yellow and eventually necrotic in leaves with overt symptoms, it seems unlikely that carbohydrate accumulation following impaired translocation was responsible for symptom expression. High carbohydrate status in leaves with attenuated symptoms had little effect on nonphotochemical quenching during early stages of photosynthetic induction. In leaves with overt symptoms, areas of high carbohydrate status with pale-green mosaics showed markedly slower nonphotochemical quenching. Early symptom areas of young leaves, and advanced symptom areas of mature leaves had low starch contents but were otherwise similar to controls in carbohydrate status. Impaired nonphotochemical quenching in these tissues tended to reflect the state of symptom development, rather than carbohydrate status. Plants with overt symptoms grew about half as fast as plants with attenuated symptoms.     

The Occurrence of High CO2-Compensation Points in Amaranthus Species

When the CO₂-compensation points of detached leaves of Amaranthusedulis plants grown undera range of controlled environmentswere determined, they were all found to be near zero. However,similar plants grown in a greenhouse occasionally yielded high-compensation-pointleaves. The occurrence of these could not be correlated withleaf age, moisture stress, or the prevailing environmental conditions.These high-compensation-point leaves still showed a typicalKranz anatomy. Starch was found external to the bundle sheathin both high- and low-compensation-point leaves, but the distributionof the starch appeared to vary with light intensity.     

Role of growth regulators in the senescence of Arabidopsis thaliana leaves

A homozygous, dominant, C₂H₄-resistant line of Arabidopsis thaliana (L.) Heynh (cv. Columbia; er ) was selected from ethylmethylsulfonate-mutagenized seed, and used to test the role of C₂H₄ and other growth regulators in senescence of mature leaves. Chlorophyll (Chl) loss from disks excised from leaves of er was much slower than that from wild-type (WT) disks, whether they were held in the light or in the dark. C₂H₄ accelerated Che loss from WT disks but had no effect on the yellowing of mutant disks. C₂H₄ biosynthesis was higher in disks from the mutant plants, particularly in the light. In the dark, treatment with the cytokinin, 6-benzyladenine (BA), reduced Chl loss from wild-type disks, but had no effect on mutant disks. In the light, BA treatment stimulated chlorophyll breakdown in both wild type and mutant disks. Treatment with abscisic acid (ABA) stimulated chlorophyll loss in wild-type and mutant disks, whether they were held in the light or the dark. C₂H₄ production was stimulated in ABA-treated disks, but they still yellowed even when C₂H₄ production was inhibited by application of aminooxyacetic acid (AOA). These data indicate that C₂H₄ is only one of the factors involved in leaf senescence, and that the promotion of senescence by ABA is not mediated through its stimulation of C₂H₄ production.     

Carbohydrate partitioning and metabolism during acclimatization of micropropagated Calathea

Regulation of carbohydrate metabolism and compartmentation were studied during the acclimatization of tissue cultured Calathea plantlets. At transplantation plants were characterised by a heterotrophic metabolism with roots and stems as the main storage organs for carbohydrates. As acclimatization proceeded, a switch to autotrophic growth was observed: leaves became source organs, which was among others reflected by significant increases of invertase, sucrose synthase and sucrose-P synthase activities. Mobilization of reserves in roots and stems was also observed during the same period. Sucrose and starch accumulation in leaves was positively correlated with increasing light intensity.     

Functional role of anthocyanins in high-light winter leaves of the evergreen herb Galax urceolata

High-light leaves of the evergreen herb Galax urceolata exhibit a striking color change from green to red during winter months due to anthocyanin synthesis in outermost mesophyll cells. Here we investigate three possible functions of this color change. To test the hypothesis that anthocyanins function as light attenuators, maximum photosystem II efficiency (F(v)/F(m)) of red and green leaves was measured during and after exposure to wavelengths either strongly or poorly absorbed by anthocyanin. To determine whether anthocyanins elevate radical-scavenging capacity, antioxidant activity of red and green leaves was assessed using the alpha,alpha-diphenyl-beta-picrylhydrazyl assay. Nonstructural carbohydrate levels were analyzed to test the hypothesis that anthocyanins function as a carbon sink. Declines in F(v)/F(m) under white and green light were significantly greater for green than red leaves, but were comparable under red light. Anthocyanin content positively correlated with antioxidant activity. Although levels of anthocyanins did not appear to be related to nonstructural carbohydrate concentration, high levels of sugars may be necessary for their photo-induction. Results suggest that anthocyanins function as light attenuators and may also contribute to the antioxidant pool in winter leaves.     

Spondyloarthropathy in progressive ankylosis mice: ultrastructural features of the intervertebral disk.

Progressive ankylosis mice (ank/ank) spontaneously develop a joint disorder characterized by calcium hydroxyapatite deposition and bony ankylosis of the joints of the axial and the appendicular skeleton. Mice in this study were used to determine the extent of mineralization of the intervertebral disks and to determine their suitability as a model for ankylosing spondyloarthropathies. Intervertebral disks taken from affected mice from 4 to 18 weeks of age were studied by electron-microscopic, electron energy-dispersive X-ray microanalysis and selected-area electron diffraction techniques. Necrotic foci seen in light microscope studies were found to be massive accumulations of calcium hydroxyapatite crystals deposited within the extracellular matrix. Chondrocytes of older animals demonstrated what appeared to be postmortem changes and contained numerous large vacuoles.     

The influence of larval fat body on wing disk development in vitro

The effects are noted of various fat body treatments on betaecdysone-induced cuticle deposition in cultured wing disks of Plodia interpunctella. The percentage of disks which responded to hormone treatment in vitro depended upon the age of the disk, the amount of fat body, the time the medium was incubated with fat body, and the time the disks were exposed to beta-ecdysone in fat body-conditioned medium. Fat body from pharate pupae did not stimulate disk development.     

Effects of azadirachtin after systemic uptake intoBrassica oleracea on larvae ofPieris brassicae

Petioles of intact cabbage leaves were placed in azadirachtin solutions for 24 h. Azadirachtin or active metabolites of this compound appeared to be translocated systemically as performance of first instar larvae ofPieris brassicae L. placed on disks from those leaves was affected. The position within a leaf from which disks were excised did not affect the extent of these effects, indicating a homogeneous distribution of active compounds in the laminar tissue. At doses ranging from 1–10 ppm of azadirachtin in the solution taken up by the leaves, gain of larval fresh weight and leaf area consumed were reduced. These effects were dose dependent up to 60–90 ppm. At 10 ppm and higher doses no larva reached the second instar within 72 h. Mortality during the 72 h period was highest at 10 ppm, due to the coincidence of lethal action with ecdysis in combination with the effect on developmental rate. Azadirachtin solutions applied directly to the surface of leaf disks in order to produce known doses on a leaf fresh weight basis gave results similar to the systemic treatment for weight gain, leaf area consumed and developmental rate, while mortality was higher in the latter treatment.