Functional Characterization of Two Ripening-related Sucrose Transporters from Grape Berries

The ripening of grape (Vitis vinifera L.) berries is associatedwith a large accumulation of glucose and fructose in the vacuolesof the fruit cells. These hexoses are derived from sucrose,which is released from the phloem and may be taken up by parenchymacells prior to hydrolysis. We have expressed two putative ripening-relatedsucrose transporters from grape berries, VvSUC11 (synonymouswith VvSUT1) and VvSUC12, in an invertase deficient yeast strainto characterize their transport activities. Sucrose was takenup by yeast transformed with either transporter at an optimumpH of <4.5 and with a Michaelis constant (K_m) of 0.9–1.4m M. The uptake of sucrose through VvSUC11 and VvSUC12 was inhibitedby protonophores and by vanadate. This is consistent with anactive uptake mechanism involving proton cotransport, typicalof sucrose/H⁺symporters. The transporters from grape berrieswere functionally similar to Scr1, a sucrose transporter fromRicinus cotyledons. It is likely that in grape berries VvSUC11and VvSUC12 facilitate the loading of sucrose from the apoplastinto the parenchyma cells. Copyright 2001 Annals of Botany Company Fruit, grape berries, plasma membrane, sugars, sucrose transporters, Vitis vinifera     

Influence of the carbon source on growth and rosmarinic acid production in suspension cultures of Coleus blumei

Suspension cultures of Coleus blumei were characterized with respect to growth and rosmarinic acid formation in media with different sugars and various sugar concentrations. Sucrose is the sugar with the highest stimulating effect on growth and rosmarinic acid accumulation, followed by glucose and fructose. The sugar alcohol mannitol cannot be metabolized by the plant cells. Sucrose is cleaved into glucose and fructose by the Coleus cells. Sucrose concentrations from 1 to 5% have an increasing positive effect on growth and rosmarinic acid synthesis in the cell cultures with a maximum rosmarinic acid content of 12% of the dry weight in medium with 5% sucrose; in medium with 6% sucrose rosmarinic acid accumulation obviously did not reach its highest level in the culture period of 14 days. A very high yield of rosmarinic acid (2 mg ml^-1 suspension) could also be achieved by maintaining a sucrose concentration of 2% during the whole culture period. The start of rosmarinic acid synthesis by the cell cultures seems to be regulated by the growth limitation when a nutrient, e.g. phosphate is depleted from the medium. The rate of rosmarinic acid accumulation is related to the amount of carbon left in the medium when growth ceases.Abbreviations RA rosmarinic acid     

Influence of osmotica and abscisic acid on triglyceride accumulation in peanut somatic embryos

Attempts were made to determine the influence of sucrose, mannitol, sorbitol and abscisic acid on accumulation of triglycerides in peanut (Arachis hypogaea L.) somatic embryos. The results revealed that 0.584 m sucrose in the medium produced increased triglycerides in the embryos compared to the control. At 0.730 m sucrose, embryos were necrotic although the triglyceride content was high. Sorbitol at 0.6 m or abscisic acid at 20 μm were effective in increasing triglycerides in the embryos. The increase in triglycerides on a fresh-weight basis observed with increasing concentration of osmoticium was not apparent when determined in terms of dry weight. However, an increase in triglyceride as percent fresh weight observed in the presence of 20 μm abscisic acid remained unaltered when determined in terms of percent dry weight. An increase in storage lipid did not improve conversion of peanut somatic embryos. Received: 4 April 1997 / Revision received: 15 February 1998 / Accepted: 2 March 1998     

The impact of supplemental carbon sources on <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> growth,chlorophyll content and anthocyanin accumulation

This research explores the impacts of a broad range of supplemental carbon sources on growth and development of Arabidopsis thaliana. Parameters measured include dark-germinated hypocotyl length, light-germinated root growth, rosette growth, chlorophyll concentration and anthocyanin content. Treatment sugars include sucrose, maltose, d-glucose, d-fructose, l-arabinose, l-fucose, d-galactose, d-mannose, l-rhamnose and d-xylose each supplied at 4, 20 or 100 mM. This comparison of the effect of different carbon sources on multiple parameters and under identical conditions showed that every carbon source had unique qualitative and quantitative effects on Arabidopsis growth and development. Root growth was particularly sensitive to supplemental carbon source. Growth on 100 mM sucrose, maltose, glucose or xylose stimulated root growth by ~100%. Growth on arabinose, fucose, galactose, mannose or rhamnose inhibited root growth by 50% or more. Several sugars that strongly inhibited root growth had either no effect (galactose and fucose) or a positive effect (arabinose) on hypocotyl elongation and rosette growth. Rhamnose was the only carbon source that inhibited hypocotyl elongation across all concentrations. Sucrose, maltose, glucose, fructose, arabinose or xylose stimulated rosette growth by ~50%. Chlorophyll content was strongly reduced by mannose while sucrose, glucose, galactose and rhamnose caused smaller reductions. Anthocyanin accumulation was strongly induced by both galactose and mannose. Only mannose impacted all parameters across all concentrations. Based on these data it can be concluded that the effect of each carbon source on Arabidopsis growth and development is specific in terms of both magnitude and the parameters impacted.     

The activity of powdery-mildew haustoria after feeding the host cells with different sugars,as measured with a potentiometric cyanine dye

The biotrophic parasite Erysiphe graminis f. sp. hordei produces haustoria within the cells of its host Hordeum vulgare. To determine the physiological activity of these haustoria, the electric potential across the membranes in the mitochondria of the haustorium was studied. The membrane potential was estimated with the fluorescent potentiometric cyanine dye 3,3-dibutyloxacarbocyanine iodide. The addition of depolarizing agents (carbonylcyanide m-chlorophenylhydrazone, 2,4-dinitrophenol or KCN) to infected cells resulted in an increase of fluorescence after the addition of low concentrations or a decrease of fluorescence after the addition of higher concentrations. When the infected host cell was fed with increasing concentrations of d-glucose (25, 50, 75 mM), corresponding decreases of fluorescence were measured immediately in the mitochondria of the fungal haustoria. Sucrose induced a similar reduction of fluorescence about 20 min late. d-Galactose and d-fructose induced a somewhat smaller reduction of fluorescence, l-glucose and d-glucitol had no effect. The results indicate that haustoria take up glucose from the host cells immediately. Sucrose, d-galactose and d-fructose seem to require time to be metabolized before their products reach the fungal haustorium or mitochondria.Abbreviations CCCP carbonylcyanide m-chlorophenylhydrazone - DiOC₄(3) 3,3-dibutyloxacarbocyanine iodide - DNP 2,4-dinitrophenol     

Metabolism of free sugars in relation to starch synthesis in the developing Sorghum vulgare grain

Accumulation of starch at expense of its free-sugar precursors was studied in the developing grains of the ‘SL-44’variety of Sorghum vulgare Pers. The content of starch gradually increased with the maturation of the grain and this increase was relatively fast until 18 days after anthesis. The daily rate of starch accumulation was at a maximum 15 days after anthesis. The content of total free sugars, reducing sugars, non-reducing sugars other than sucrose, total and non-sucrosyl fructose, and glucose also increased, reaching maximum values at 18 days after anthesis. Sucrose content gradually increased with a concomitant decrease in the activity of invertase, and sucrose was the major non-reducing sugar in the matured grains. Detached heads incubated in labelled sugars indicated that, compared to sucrose and fructose. ¹⁴C was more efficiently incorporated from glucose into grain starch, which was maximally synthesized at the mid-milky stage of grain development. Exogenous supply of NAD⁺ plus ATP stimulated the in vivo incorporation of ¹⁴C from sucrose to starch. The decline in the rate of starch accumulation did not synchronise with that of protein synthesis.     

Effect of glucose on sporulation and extracellular amylase production byClostridium perfringens type A in a defined medium

The effect of glucose and other sugars on sporulation and extracellular amylase production byClostridium perfringens NCTC 8679 type A in a defined medium was studied. Cells grown in the presence of glucose and mannose yielded the highest levels of amylase activity, while disaccharides such as lactose, maltose, and sucrose resulted in moderate amylase production. Little amylase activity was detected in the medium in the presence of ribose or galactose. The concentration of each sugar resulting in highest amylase production was between 6 and 10mm except for fructose (25mm). Levels of heat-resistant spores decreased as sugar concentrations increased. The addition of even small amounts of glucose to the medium before exponential growth suppressed sporulation but maximized amylase activity. The addition of glucose after the initiation of sporulation did not inhibit spore formation. However, its addition to 3-h amylase-producing cells did inhibit subsequent sporulation but promoted the continued excretion of amylase. The different response to glucose between sporulating cells and amylase-producing cells suggests that the mechanisms of catabolite repression of extracellular amylase production and sporulation are distinct in this strain ofC. perfringens.     

Condensed tannin and anthocyanin production in Vitis vinifera cell suspension cultures

Suspension cultures of Vitis vinifera were cultured in different media in order to establish a model system for promoting high levels of phenolic substances identical with those found in wine. These media were: a low sucrose maintenance medium (MM) and four high sucrose media (differing mainly in sucrose and mineral contents) which were shown to induce secondary metabolism. In MM medium, polyphenol accumulation in the cells was low, and concentrations of 0.1 mg/gfw for condensed tannins and 0.3 mg/gfw for anthocyanins were reached within two weeks of cultivation. Values of 1.4 and 6.4 mg/gfw, respectively, were obtained with a low nitrate and high sucrose medium (HM1), but cell proliferation was reduced. To obtain a maximal production of polyphenols, we investigated the most effective conditions for cell growth and polyphenol production (a high mineral and high sucrose medium, IM1; inoculum dilution of 1.25:10). Under these conditions, the cells produced mainly anthocyanins (1100 mg/l), proanthocyanidins (300 mg/l) and catechins (25 mg/l).Abbreviations BuOH n-butanol - dw dry weight - fw fresh weight     

Sulla stimolazione da Saccarosio della Crescita di Cotiledoni Isolati di Semi di Ricino germinanti

Abstract

The effect of sugars on growth of isolated cotyledons from germinating castor bean seeds. — The presence of sugars in the medium induces a number of biochemical and physiological changes in the cotyledons isolated from germinating castor bean seeds. In the present research, the extent and the mechanism of the effect of sugars on growth of the isolated cotyledons was investigated.

The results achieved may be summarized as follows:

• Sucrose markedly stimulates the growth (as increase of fresh weight) of the isolated cotyledons; its action is already apparent when using a 10^-2M concentration and reaches a maximum (stimulation by about 400%) for the concentration between 5.10^-2M and 1,5.10^-3M. The increase of sucrose induced growth is due in almost equal proportions to water uptake and to increase of dry weight.

• The difference (Δ P.O.) between the osmotic pressure (P.O.) of the cell sap and that of the external medium is markedly higher for the cotyledons treated with sucrose (7–8 atm.) than the Δ P.O. of cotyledons incubated in water.

• Analyses of cell contents in sugars show that sucrose is taken up by the cotyledon cells against a concentration gradient. The increase of the difference of osmotic pressure between cotyledon and the external medium is satisfactorily accounted for by this active accumulation of sugars.

• When mannitol is added to the incubating medium in addition to sucrose, the active uptake of sugar is not disturbed; but the effect of sucrose on growth decreases, and it completly disappears when mannitol concentration in the medium is such, to make the value of Δ P.O. for the cotyledons in sucrose plus mannitol equal to the Δ P.O. for the cotyledons incubated in water.

• Besides increasing the P.O. in the cotyledons, sucrose markedly accelerates the decrease of free aminoacid in the isolated cotyledons.

• Auxin (β—indolacetic acid) does not stimulate, or stimulates weakly, growth of the cotyledon incubated in water; some stimulation can be observed only when sucrose is present. Gibberellic acid stimulates growth (though to a much lower extent than sucrose) in the cotyledons in water, while its action does no longer appear when sugar is present.

The decrease of free aminoacid together with other observations, indicates an effect of sucrose on protein metabolism; however, growth stimulation by sucrose seems to depend essentially on its active accumulation - against a concentration gradient - and thuson the increase of osmotic pressure. It is thus suggested that in these tissues osmotic pressure is the most important factor in limiting growth by cell extension.     

Sucrose uptake by cotyledons of Ricinus communis L.: Characteristics,mechanism, and regulation

Cotyledons of Ricinus communis take up externally supplied sucrose at a rate of up to 150 mol/h/g fresh weight, which is very high when compared with other sugar transport systems of higher plants. The uptake of sucrose is catalysed with a K _m of 25 mmol l^–1; at high sucrose concentrations a linear (diffusion) component becomes obvious. Other mono-, di-, or trisaccharides do not compete for sucrose uptake. Sucrose is accumulated by the cotyledons up to 100-fold, whereby most of the transported, externally supplied sucrose mixes with sucrose present in the tissue. At low sucrose concentrations, however; a small unexchangeable internal pool of sucrose becomes evident. Poisons of energy metabolism such as FCCP inhibit uptake and accumulation of sucrose. The transport of sucrose induces an increase of respiration, from which an energy requirement of 1.4 ATP/sucrose taken up can be calculated. Sucrose is taken up together with protons at an apparent stoichiometry of 0.3 protons/sucrose. Other sugars do not cause proton uptake. The K _m for sucrose induced proton uptake is 5 mmol l^–1; the discrepancy to the K _m for sucrose uptake as well as the low proton: sucrose stoichiometry might possibly be caused by a large contribution of diffusion barriers. The estimated proton-motive potential difference would by sufficient to explain an electrogenic sucrose accumulation. The rate of uptake of sucrose is subject to feedback inhibition by internal sucrose. It is also regulated during growth of the seedlings since it develops rapidly during the first days of germination and declines again after the 4th day of germination, though no substantial increase of passive permeability resistance was observed.Abbreviations DMO dimethyloxazolidinedione - FCCP trifluoromethoxy (carbonyl-cyanide) phenylhydrazon - fr. wt. fresh weight     

Effect of culture conditions on astaxanthin production by a mutant of Phaffia rhodozyma in batch and chemostat culture

Temperature and pH had only a slight effect on the astaxanthin content of a Phaffia rhodozyma mutant, but influenced the maximum specific growth rate and cell yield profoundly. The optimum conditions for astaxanthin production were 22°C at pH 5.0 with a low concentration of carbon source. Astaxanthin production was growth-associated, and the volumetric astaxanthin concentration gradually decreased after depletion of the carbon source. The biomass concentration decreased rapidly during the stationary growth phase with a concomitant increase in the cellular content of astaxanthin. Sucrose hydrolysis exceeded the assimilation rates of D-glucose and D-fructose and these sugars accumulated during batch cultivation. D-Glucose initially delayed D-fructose uptake, but D-fructose utilization commenced before glucose depletion. In continuous culture, the highest astaxanthin content was obtained at the lowest dilution rate of 0.043 h^–1. The cell yield reached a maximum of 0.48 g cells·g^–1 glucose utilized between dilution rates of 0.05 h^–1 and 0.07 h^–1 and decreased markedly at higher dilution rates. Correspondence to: J. C. Du Preez     

Densitometry of yeast cells and protoplasts during sugar uptake

Densitometry was applied to the study of sugar transport in yeast cells and protoplasts. The uptake curves of nonmetabolized monosaccharides were without the transient peak observed analytically. Differences in the space of distribution of different monosaccharides (e.g.d-arabinosev.l-arabinose) were confirmed. The uptake of metabolizable sugars (d-glucose,d-fructose) resulted in a gradual increase in protoplast (and cell) volume. The optical density of cells rose abruptly after some 20–60 min of incubation but this rise was not accompanied by a decrease in cell volume. The increase was prevented by 2,4-dinitrophenol but not by iodoacetic acid. The effect of temperature and of ionic strength of the medium was examined. Differences between protoplasts and intact cells in the utilization of sucrose were confirmed.     

Sucrose deficiency delays lycopene accumulation in tomato fruit pericarp discs

Tomato (Solanum lycopersicum) fruit ripening is characterized by a massive accumulation of carotenoids (mainly lycopene) as chloroplasts change to chromoplasts. To address the question of the role of sugars in controlling carotenoid accumulation, fruit pericarp discs (mature green fruits) were cultured in vitro in the presence of various sucrose concentrations. A significant difference in soluble sugar content was achieved depending on external sucrose availability. Sucrose limitation delayed and reduced lycopene and phytoene accumulation, with no significant effect on other carotenoids. Chlorophyll degradation and starch catabolism were not affected by variations of sucrose availability. The reduction of lycopene synthesis observed in sucrose-limited conditions was mediated through metabolic changes illustrated by reduced hexose accumulation levels. In addition, variations of sucrose availability modulated PSY1 gene expression. Taken together our results suggest that the modulation of carotenoid accumulation by sucrose availability occurs at the metabolic level and involves the differential regulation of genes involved in carotenoid biosynthesis.     

Overexpression of cytosolic malate dehydrogenase (MDH2) causes overproduction of specific organic acids in Saccharomyces cerevisiae

Saccharomyces cerevisiae accumulates l-malic acid through a cytosolic pathway starting from pyruvic acid and involving the enzymes pyruvate carboxylase and malate dehydrogenase. In the present study, the role of malate dehydrogenase in the cytosolic pathway was studied. Overexpression of cytosolic malate dehydrogenase (MDH2) under either the strong inducible GAL10 or the constitutive PGK promoter causes a 6- to 16-fold increase in cytosolic MDH activity in growth and production media and up to 3.7-fold increase in l-malic acid accumulation in the production medium. The high apparent K _m of MDH2 for l-malic acid (11.8 mM) indicates a low affinity of the enzyme for this acid, which is consistent with the cytosolic function of the enzyme and differs from the previously published K _m of the mitochondrial enzyme (MDH1, 0.28 mM). Under conditions of MDH2 overexpression, pyruvate carboxylase appears to be a limiting factor, thus providing a system for further metabolic engineering of l-malic acid production. The overexpression of MDH2 activity also causes an elevation in the accumulation of fumaric acid and citric acid. Accumulation of fumaric acid is presumably caused by high intracellular l-malic acid concentrations and the activity of the cytosolic fumarase. The accumulation of citric acid may suggest the intriguing possibility that cytosolic l-malic acid is a direct precursor of citric acid in yeast. Received: 22 January 1997 / Received revision: 14 April 1997 / Accepted: 19 April 1997     

Effects of light, magnesium and sucrose on leaf anatomy, photosynthesis, starch and total sugar accumulation, in kiwifruit culturedin vitro

Shootlets of kiwifruit plants (Actinidia deliciosa) were culturedin vitro. Combinations of light intensity, Mg and sucrose in the cultures showed that an increase of light intensity resulted in a corresponding increase of the relative size of the leaf mesophyll cells and in a decrease of the numbers of chloroplasts and contained starch grains. The addition of sucrose to the substrate media negatively affected the size of the mesophyll cells under normal Mg concentration (35 mg l⁻¹), and positively under high Mg concentration (105 mg l⁻¹ ). Sucrose further resulted in an increase in the numbers of chloroplasts and contained starch grains. The photosynthetic capacity of leaves greatly increased when Mg concentration was enhanced and sucrose was excluded from the nutrient substrate. Total sugar accumulation in all treatments was favoured by normal light intensity and addition of sucrose.     

Lactic acid production using two food processing wastes,canned pineapple syrup and grape invertase,as substrate and enzyme

Canned pineapple syrup, a food processing waste, was utilized as a substrate for lactic acid production by Lactococcus lactis. To improve the utilization of sucrose from the syrup, grape invertase from grape juice derived from wine production was used for sucrose hydrolysis. The highest lactic acid concentrations achieved were 20 and 92 g l^–1 from 20 and 100 g total sugars l^–1, respectively, without a lag period for sucrose consumption.     

Abscisic acid,sucrose, and auxin coordinately regulate berry ripening process of the Fujiminori grape

The aim of this study was to examine the effect of abscisic acid (ABA), sucrose, and auxin on grape fruit development and to assess the mechanism of these three factors on the grape fruit ripening process. Different concentrations of ABA, sucrose, and auxin were used to treat the grape fruit, and the ripening-related indices, such as physiological and molecular level parameters, were analyzed. The activity of BG protein activity was analyzed during the fruit development. Sucrose, ABA, and auxin influenced the grape fruit sugar accumulation in different ways, as well as the volatile compounds, anthocyanin content, and fruit firmness. ABA and sucrose induced, but auxin blocked, the ripening-related gene expression levels, such as softening genes PE, PG, PL, and CELL, anthocyanin genes DFR, CHI, F3H, GST, CHS, and UFGT, and aroma genes Ecar, QR, and EGS. ABA, sucrose, and glucose induced the fruit dry weight accumulation, and auxin mainly enhanced fruit dry weight through seed weight accumulation. In the early development of grape, starch was the main energy storage; in the later, it was glucose and fructose. Sucrose metabolism pathway-related gene expression levels were significant for glucose and fructose accumulation. BG protein activity was important in the regulation of grape ABA content levels. ABA plays a core role in the grape fruit development; sucrose functions in fruit development through two pathways: one was ABA dependent, the other ABA independent. Auxin blocked ABA accumulation to regulate the fruit development process.     

Hydrolysis of sucrose within isolated vacuoles from Solanum tuberosum L. tubers

The soluble acid invertase (β-D-fructofuranoside fructohydrolase, EC 3.2.1.26) from potato (Solanum tuberosum L. cv. Kennebec) tubers was located in the vacuoles. Although the functionality of this invertase in the vacuoles has been assumed, the activity of the enzyme has never been shown within isolated vacuoles. Vacuoles were prepared by gentle osmotic shock from free protoplasts obtained by enzymic digestion of tuber tissues. The mean volume of these vacuoles, (0.26 ± 0.05) × 10⁻² μl, was estimated by optical microscopy. Sucrose, glucose and fructose concentrations were calculated to be 100 mM, 20 mM and 40 mM, respectively, in the vacuoles. Sucrose hydrolysis and the increase in glucose and fructose concentrations within the vacuoles were measured during vacuolar incubations. An almost identical pattern of sucrose hydrolysis by invertase was found by an in-vitro assay reproducing the vacuolar conditions. In view of the determinations of internal vacuolar pH (5.2), the possibility of spontaneous hydrolysis of sucrose was disregarded. Vacuoles were shown to be free from proteinaceous inhibitors, confirming the extravacuolar location of these inhibitors. The vacuolar hydrolytic pattern of sucrose confirms the regulatory role of the reaction products previously proposed for in-vitro assays. Received: 21 July 1997 / Accepted: 31 August 1997