Effect of Heat Stress on Assimilate Metabolism in Tomato Flower Buds

Assimilate import by flower buds in two cultivars of tomato(Lycopersicon esculentum Mill.) was inhibited by heat stress.With increasing temperature, levels of sucrose in the sourceorgan increased while levels of starch decreased. The transportof radioactive carbon was correlated with the starch contentof the flower buds. In Saladette, a heat-tolerant cultivar,conversion of the imported carbon to starch occurred to a greaterextent than in Roma VF, a heat-sensitive cultivar. Uptake ofsucrose from agar medium by detached flower buds was negativelycorrelated with their internal ratio of sucrose to hexoses.Glucose uptake from agar medium by detached flower buds decreasedwith increasing temperatures. Sucrose hydrolysis was negativelyaffected by high temperatures, and this was more pronouncedin the heat-sensitive than in the heat-tolerant cultivar. Theeffect of heat stress on assimilate translocation from the leavesto the sink organ is discussed. Lycopersicon esculentum Mill., starch, sucrose, heat stress     

Heat Stress and Spermidine: Effect on Chlorophyll Fluorescence in Tomato Plants

Two tomato (Lycopersicon esculentum L.) cultivars: Robin (tolerant) and Roma (sensitive to heat stress) were studied. Chlorophyll fluorescence induction parameters (F_v/F_p, A_max, and Rfd) at 25 °C showed that the PS2 activity was similar for both cultivars. The parameters, measured at 38 °C, decreased in both cultivars, but more in cv. Roma. Exogenous application of 4 mM spermidine improved the plant heat-resistance in both cultivars, and especially in cv. Roma. Analysis of chlorophyll fluorescence changes during linear increase in temperature showed that cv. Robin plants have higher ability to hardening and higher resistance to thermal damage of the pigment-protein complexes structure and the activity of PS2 than cv. Roma.     

Assimilate Partitioning in the Variegated Coleus Leaf

Mature leaves of a variegated cultivar of Coleus blumei Benth. with a green border and central albino region constitute a source-sink system suitable for studies on assimilate partitioning. Leaves treated with ¹⁴CO₂ on a small part of the intact green border export assimilate via the shortest path into the stem. Leaves with all but a small lobe of the green border removed show different partitioning of labeled assimilates when the leaf is exposed to ¹⁴CO₂ (Fisher and Eschrich, 1985): The whole albino region of the leaf is supplied but no tracer is exported into the stem. When the green border is completely removed, ¹⁴CO₂-treatment of the albino region leads to the fixation of CO₂, obviously by PEP carboxylase, as indicated by the occurrence of labeled malate. Results show that the albino region of the variegated leaf constitutes a potential sink when deprived of its green border. In addition, CO₂-fixation by PEP carboxylase in albino tissue seems to indicate a common capacity of leaves which is normally masked by photosynthesis. The difference of assimilate partitioning between leaves with intact and leaves with partly removed green borders demonstrates that the unlabeled assimilates control the movement of labeled assimilates.     

Effect of Water Stress on Grain Growth and Assimilate Partitioning in two Cultivars of Wheat Contrasting in their Yield Stability in a Drought-Environment

Grain growth pattern and grain weight in relation to its positionbetween and within spikelets showed assimilate limitation tobe a factor reducing grain yield in wheat plants grown on storedmoisture in the field. Estimation of the relative contributionof pre- and post-anthesis assimilates to grain yield by a ¹⁴Clabelling technique indicated that cultivar C 306, known forits stability in yield and drought-tolerance, was characterizedby substantial mobilization of pre-anthesis assimilate (P),both in irrigated (24 per cent) and unirrigated (33 per cent)plants. As against this, in Kalyansona, a high yielding cultivarwith moderate stress tolerance, the contribution of P to grainyield was only 13 and 22 per cent in irrigated and unirrigatedplants, respectively. The mobilization of amino acids, estimatedfrom nitrogen contents at anthesis and maturity, was decreasedby water stress and was accompanied by a corresponding increasedtransport of carbohydrates. Assimilate partitioning, drought tolerance, grain growth, stability, water stress, wheat     

The Effect of Calcium Starvation on Assimilate Partitioning and Mineral Distribution of the Phloem

Populus plants were grown in a medium lacking calcium and exposedto ¹⁴CO₂. In contrast to plants in the complete nutrient medium,the percentage amount of ¹⁴C-assimilates increased in the leavesof calcium-deficient plants and decreased in the stem and theroots. When plants were grown without potassium or magnesiumno differences in the amount of ¹⁴C-label occurred in comparisonwith plants in the complete nutrient medium. Translocation wasrecorded by microautoradiography. It was observed that considerableamounts of labelled photoassimilates were unloaded from thephloem in the middle part of the stem in plants of the completenutrient medium. In contrast, during calcium starvation ¹⁴C-labelwas restricted to the phloem of the stem. In addition, the concentrationsof magnesium and phosphorus showed a remarkable increase instem sieve tubes of calcium-deficient plants. When sieve tubesof source leaves from Populus, barley and maize were comparedwith those of sink leaves, the latter showed higher calciumconcentrations. The results suggest that calcium is a necessaryfactor in the regulation of phloem translocation. Key words: Calcium deficiency, phloem translocation, sieve element loading and unloading, X-ray microanalysis     

Maternal,Single-Gene Regulation of Assimilate Partitioning in Pea

Assimilate partitioning has been identified as a key process in the control of yield. Although the role of reproductive structures in this process has received intensive study, our understanding of the role of the maternal plant is limited. We suggest that the Sn gene of pea (Pisum sativum L.) is a potentially valuable genetic tool for studying maternal regulation of partitioning. In this study, nearly isogenic lines differing at the Sn locus were compared with respect to seed-filling characteristics and carbon assimilation. Lines with the Sn gene had a slower rate and shorter duration of seed growth than the line recessive for this gene, and these traits could not be ascribed to reduced carbon assimilation. Flowers of the two nearly isogenic lines were manually pollinated to control the genotype of the developing embryo independently of the maternal genotype. The final dry weight of the seed was determined by the genotype of the maternal plant and not by the genotype of the embryo, supporting the hypothesis that the Sn gene acts in the vegetative plant to regulate the partitioning of assimilates between vegetative and reproductive growth. Although the Sn gene has been noted for delaying apical senescence, it also delayed leaf senescence in this study; leaves of the Sn line continued to photosynthesize long past the time that leaves of the recessive line had senesced and after the seeds and pods were dry.     

Water Potential, Translocation and Assimilate Partitioning

Lang, A. and Thorpe, M. R. 1986. Water potential, translocationand assimilate partitioning.—J. exp. Bot. 37: 495–503. The effect of water status upon translocation and assimilatepartitioning is examined both from theory and in an experimentwith young Phaseolus plants. Theory predicts that translocationis unlikely to be directly affected by water status. However,water potential differences within plants should influence translocationflow, with regions at lower potentials attracting disproportionatelylarge shares of assimilate. This prediction is supported in the experiment with Phaseolusin which the pattern of partitioning in the root changed rapidlyin response to bathing portions of it in solutions of differentosmolarity. The relevance of these findings to the growth of plants undernatural conditions is considered and evidence is presented thatwater potential gradients may be an Important factor in thecontrol of partitioning Key words: Phloem translocation, xylem transport, partitioning, water potential, control, osmotic potential     

Effects of Temperature and Photoperiod on Assimilate Partitioning in Potato Plants

The effects of temperature and photoperiod on d. wt partitioningand ¹⁴C translocation were studied in three potato varieties.High temperatures and long days enhanced plant growth in termsof plant height and number of leaves, and also affected d. wtpartitioning between the plant organs. However, no temperatureeffect was noted on total plant d. wt, nor on the export of¹⁴C from the source leaf. Translocation of ¹⁴C to the vegetativeorgans (leaves and stems) was greater at higher temperatures,while translocation to the tubers was less under these conditions.We suggest that, under the temperature regimes studied, themain effect of high temperature is on assimilate partitioningand not on total plant productivity. Differences in responseto high temperatures were observed among varieties, with Norchipshowing the least and Up-to-Date showing the most sensitivity. High temperature, partitioning of assimilates, ¹⁴C-translocation, potato, Solanum tuberosum var. Desirèe, Solanum tuberosum var. Norchip, Solanum tuberosum var. Up-to-Date     

水杨酸对受高温胁迫的葡萄幼苗光合作用和同化物分配的影响

0．1mmol．L^-1水杨酸处理高温胁迫下的葡萄幼苗叶片,能提高其调运同化物的能力,其本身的光合能力也可提高。     

Root Confinement and its Effects on the Water Relations, Growth and Assimilate Partitioning of Tomato (Lycopersicon esculentum Mill)

Although it is well established that the root growth in manyspecies is very sensitive to mechanical impedance or to confinementin small volumes, little is known about the consequent effectson growth of the whole plant and the mechanisms involved. Thiswork investigated the effects of root confinement on the waterrelations, growth and assimilate partitioning of tomato (Lycopersiconesculentum Mill) grown in solution culture. Six-week old plants were transferred to either 4500 ml or 75ml containers filled with nutrient solution, and allowed togrow for 14 d. Transpiration, leaf-air temperature differences,and leaf diffusive resistances were measured frequently. Leaf,stem and shoot dry masses, leaf area and root length, were estimatedwhen the treatments were imposed and at the end of the experiment.After 14 d growth the root and shoot hydraulic resistances wereestimated from measurements of leaf water potential and transpirationrate, using a steady-state technique. Confining root growth to the small containers substantiallyreduced shoot and root growth and increased the proportion oftotal dry matter present in the stems. These effects were dueto drought stress. The hydraulic resistance of the root systemwas greatest in the confined plants. This led to more negativeleaf water potentials, increased leaf diffusive resistance,and reduced the net assimilation rate by a factor of 2.5. Transpirationper unit leaf area was less affected. However, cumulative transpirationwas also reduced by a factor of 2.5. mostly because of the smallerleaf area on the confined plants. Root hydraulic resistivitywas measured at 3.1 x 10¹²s m^–1 in the control treatment,but increased to 3.9 x 10¹² s m^–1 for roots in the smallcontainer. The mechanisms by which root confinement caused drought stressand disrupted the pattern of assimilate partitioning are discussedin detail. Assimilate partitioning, Lycopersicon esculentum, root confinement, plant growth, root growth, root resistance, shoot resistance, tomato, transpiration, water-use efficiency     

Effects of Heat Stress on Carbon Transport from Tomato Leaves

Export of radioactive carbon from two cultivars of tomato, (Lycopersiconesculentum Mill.) leaves was inhibited in response to heat stress.Increasing temperatures resulted in a marked decrease in leafstarch levels. The depletion of starch concentration in theleaves was primarily due to hydrolysis and an inhibition ofstarch formation. At high temperatures, starch hydrolysis wasinhibited in Roma VF, a heat sensitive cultivar, while Saladette,a heat tolerant cultivar was not similarly affected. Calloseformation was found on phloem sieve tube plates of leaf petiolesexposed to 72 h of high temperatures. More sieve tube plateswere covered with a thicker callose layer in Roma VF than inSaladette. Lycopersicon esculentum (Mill.), tomato, carbon translocation, starch hydrolysis, callose, heat stress     

Assimilate Partitioning in Three White Clover Cultivars in the Autumn, and the Effect of Defoliation

Partitioning of recently assimilated¹⁴C in three cloned whiteclover cultivars (Aberherald, Grasslands Huia and Sandra), grownoutdoors, was determined at the end of Aug., the end of Sep.and the end of Oct. to examine the relative strength of differentsinks within the plant when growing conditions increasinglyfavour carbohydrate accumulation in relation to growth. Also,the effect of removing two out of three expanded leaves on¹⁴Cpartitioning was studied. Export of¹⁴C from leaves increasedfrom late Aug. to late Oct. More¹⁴C was partitioned to the rootsand less to the apex at the Sep. and Oct. harvests than at theharvest in Aug., irrespective of cultivar. Severe defoliationresulted in more¹⁴C being partitioned to the apex and less tothe main stolon irrespective of cultivar and harvest occasion.Sandra (a cultivar of northern origin) generally partitionedmore¹⁴C to the stolon and less to the apex than did the othertwo cultivars. Trifolium repens L.; white clover; assimilate partitioning; defoliation; photosynthesis; autumn growth     

Effects of Elevated Sucrose-Phosphate Synthase Activity on Photosynthesis,Assimilate Partitioning,and Growth in Tomato (Lycopersicon esculentum var UC82B)

The expression of a sucrose-phosphate synthase (SPS) gene from maize (Zea mays, a monocotyledon) in tomato (Lycopersicon esculentum, a dicotyledon) resulted in marked increases in extractable SPS activity in the light and the dark. Diurnal modulation of the native tomato SPS activity was found. However, when the maize enzyme was present the tomato leaf cells were unable to regulate its activation state. No detrimental effects were observed and total dry matter production was unchanged. However, carbon allocation within the plants was modified such that in shoots it increased, whereas in roots it decreased. There was, therefore, a change in the shoot:root dry weight ratio favoring the shoot. This was positively correlated with increased SPS activity in leaves. SPS was a major determinant of the amount of starch in leaves as well as sucrose. There was a strong positive correlation between the ratio of sucrose to starch and SPS activity in leaves. Therefore, SPS activity is a major determinant of the partitioning of photosynthetically fixed carbon in the leaf and in the whole plant. The photosynthetic rate in air was not significantly increased as a result of elevated leaf SPS activity. However, the light- and CO2-saturated rate of photosynthesis was increased by about 20% in leaves expressing high SPS. In addition, the temporary enhancement of the photosynthetic rate following brief exposures to low light was increased in the high SPS plants relative to controls. We conclude that the level of SPS in the leaves plays a pivotal role in carbon partitioning. Furthermore, high SPS levels have the potential to boost photosynthetic rates under favorable conditions.     

Regulation of Assimilate Translocation Between Leaves and Fruits in the Tomato

Simultaneous measurement of export from leaves and import tofruits were made on tomato plants reduced to one fully expandedleaf and one fruit. Experimental leaves were exposed to sixlight flux densities (0.5–100 W m^–2) for 24 h whilerapidly growing fruits were kept in the dark at 22 °C. The rates of export of assimilate from these leaves varied from70 to 120 mg C leaf^–1 day^–1 corresponding with ratesof carbon fixation from 3 to 290 mg C leaf^–1 day^–1.Export from leaves with the lowest carbon fixation rates weremaintained by a loss of up to one-sixth of their initial carbon.In contrast, leaves with the highest carbon fixation rates exportedonly half the newly fixed carbon. The rates of import of assimilate to similar-sized fruits (c.16 cm³) were between 80 and 110 mg C fr^–1 day^–1but differed from the export rates of the source leaves. Thespecific growth rates and the specific respiration rates ofthe fruits were related to their initial carbon content at thebeginning of the experiment. Thus, over 24 h, the rate of importwas predetermined by the developmental stage of the fruit unalteredby the rate of current carbon fixation in the source leaf. Translocationof assimilate was regulated by sink demand under both source-and sink-limiting conditions in this short-term situation. The dynamic relationship between assimilate production in leavesand its utilization in fruits is discussed together with therole of sucrose concentration in these organs in regulatingtransport. Lycopersicon esculentumL, tomato assimilate translocation, source-sink relationships     

Regulation of Assimilate Partitioning in Soybean : Initial Effects following Change in Nitrate Supply

Increased concentrations of nitrate in a nutrient solution (2, 5, and 10 millimolar KNO₃) were correlated with increased shoot:root ratios of non-nodulated soybeans (Glycine max [L.] Merr.) grown in sand culture. While altering the pattern of C and N partitioning, the N treatments did not affect whole plant photosynthesis over the study period. To determine the mechanism responsible for the observed changes in assimilate partitioning, detailed C and N budgets were worked out with plants from each N treatment over three consecutive 4-day periods of midvegetative growth. The information for the C and N budgets from the 2 and 10 millimolar NO₃⁻ treatments was combined with data on the composition of xylem and phloem exudates to construct a series of models of C and N transport and partitioning. These models were used to outine a `chain-reaction' of cause-and-effect relationships that may account for the observed changes in assimilate partitioning in these plants. The proposed mechanism identifies two features which may be important in regulating the partitioning of N and other nutrients within the whole plant. (a) The concentration of N in the phloem is highly correlated with the N concentration in the xylem. (b) The amount of N which cycles through the root—from phloem imported from the shoot to xylem exported by the root—is regulated by the root's requirement for N: only that N in excess of the root's N requirements is returned to the shoot in the xylem. Therefore, roots seem to have the highest priority for N in times of N stress.     

Heat Tolerance and Assimilate Transport in Different Potato Genotypes

Six potato genotypes with different degrees of heat tolerancewere grown in pots at 38/25 'b0C maximum/minimum temperatureat 14 h daylength under natural light glasshouse conditions.Prior to sampling, the plants were given a 14 h dark period.Photosynthesis was measured at 28 'b0C and at a saturating lightintensity of more than 1200 µEm^-2 s^-1. During the optimumphotosynthetic period (09.00–12.30 h), the leaves of heat-tolerantpotato genotypes (DTO-28, Norchip, and Desiree) had 4–5times more soluble sugars (mainly sucrose) and higher sucrose-phosphatesynthase activity than the leaves of the heat-susceptible genotypes(Kufri Jyoti, Kufri Chandramukhi, and Kufri Muthu). However,starch accumulation in leaves of susceptible genotypes was abouttwice that in tolerant genotypes. All susceptible genotypesshowed a low rate of assimilate transport from leaves and ahigher shoot/root ratio which indicated that the shoot remainedthe predominant sink for photosynthate. Activities of amylaseand invertase in leaves were also higher in susceptible genotypes.It is suggested that the poor yield of heat-susceptible genotypesat high temperature and long day conditions is related to insufficientavailability of the transportable sugar, sucrose. Key words: Solarium tuberosum, carbon partitioning, heat stress     

Patterns of 14C-labelled Assimilate Partitioning in Red and White Clover During Vegetative Growth

A quantitative analysis of the ¹⁴C-labelled assimilate suppliedby the expanded leaves on the primary shoot to growing leaves,stem, lateral shoots (branches or stolons) and roots in redand white clover was conducted during vegetative growth. Stem growth of the primary shoot was inhibited in both cloversand utilized no energy resources. The growing leaves at theprimary shoot apex of white clover imported 4 per cent of theshoot's assimilate compared with 10 per cent in red clover.At the basal end of the primary shoot, the tap root of whiteclover imported 16 per cent of the shoot's assimilate comparedwith 22 per cent in red clover. Branches in red clover and stolonsin white clover were by far the largest sinks for primary shootassimilate, importing 39 per cent and 63 per cent of the labelledassimilate, respectively. Analyses of the translocation of assimilate from individualprimary shoot leaves demonstrated that in both clovers olderleaves exported more of their assimilate to branches or stolons,whereas younger leaves exported more of their assimilate toroots, and possibly in white clover, to growing leaves at thetip of the shoot. Of the labelled assimilate exported to branchesor stolons, each primary shoot leaf exported preferentiallyto the branch or stolon in its own axil, but in addition exportedsubstantial quantities of assimilate to all other axillary shoots,particularly those arising from basal axils where the subtendingleaf had died. Trifolium repens, Trifolium pratense, red clover, white clover, assimilate partitioning, perennation     

Shoot Apex Demand Determines Assimilate and Nutrients Partitioning and Nutrient-uptake Rate in Tobacco Plants

Our previous experiment revealed that apex-removed plants have larger root systems but a lower K＋-uptake rates than intact tobacco plants. Since the apex is not only a center of growth and metabolism, but also an important place of auxin synthesis and export, the aims of this study were to distinguish whether the apex demand or auxin synthesized in the apex regulates assimilate and nutrients partitioning within plant, and to explain the reason for the lower K＋-uptake rate of the apex-removed plant. In comparison with the control plant, covering the shoot apex with a black transparent plastic bag reduced net increases in dry matter and nutrients; however, the distribution of the dry matter and nutrients between shoot and roots and nutrient-uptake rates were not changed. Removal of the shoot apex shifted the dry mass and nutrients distributions to roots, and reduced the rate of nutrient uptake. Application of 1-naphthylacetic acid （NAA） could partly replace the role of the removed apex, stimulated assimilate and nutrient deposition into the treated tissue, and enhanced the reduced plasma membrane ATPase activity of roots to the control level. However, treatment of the apex-removed plants with NAA could not rescue the reduced nutrient uptake rate and the shifted assimilates and nutrients partitioning caused by excision of the apex. Higher nutrient uptake rate of the intact plants could not be explained by root growth parameters, such as total root surface area and number of root tips. The results from the present study indicate that strong apex demand determined assimilates and nutrients partitioning and nutrient-uptake rate in tobacco （Nicotiana tabacum） plants.     

Far-Red Light Reflection from Green Leaves and Effects on Phytochrome-Mediated Assimilate Partitioning under Field Conditions

The influence of plant spacing and row orientation on spectral distribution of light received by growing soybean (Gylcine max [L.] Merr.) plants was measured under field conditions. Light absorption, reflection and transmission of individual leaves showed that most of the blue and red was absorbed while most of the far-red was either reflected or transmitted. Plants growing in the field received different ratios of far-red relative to red, depending on nearness and/or orientation of other vegetation. Plants grown in close-spaced rows, or high population densities, received higher far-red/red ratios than did those grown in wide rows, or sparse populations. Heliotropic movements of the leaves also contributed to the far-red reflection patterns associated with row orientation. Under field conditions, differences in far-red/red ratios associated with nearness of competing vegetation became more pronounced with low solar angle near the end of the day. Plants exposed to far-red for 5 minutes at the end of each day in controlled environments, and those grown in close-spaced rows in the field, developed longer internodes and fewer branches. Red, far-red photoreversibility in the controlled environment study indicated involvement of phytochrome. Dry matter partitioning among plant components in the field was related to far-red/red light ratio received during growth and development.     

Nano-TiO2 Improve the Photosynthesis of Tomato Leaves under Mild Heat Stress

Nano-TiO₂ has been reported to promote photosynthesis in some crops; however, the mechanism behind this action remains unknown. In this research, the effects of nano-TiO₂ on leaf photosynthesis under mild heat stress were investigated. Results showed that the net photosynthetic rate, conductance to H₂O, and transpiration rate of tomato leaves increased after application of an appropriate concentration of nano-TiO₂. Nano-TiO₂ also significantly decreased the minimum chlorophyll fluorescence and relative electron transport in leaves. Under mild heat stress, Nano-TiO₂ increased regulated photosystem II (PS II) energy dissipation and decreased non-regulated PS II energy dissipation. These results indicate that nano-TiO₂ plays a positive role in promoting photosynthesis in tomato leaves under mild heat stress.