Lateral root frequency decreases when nitrate accumulates in tobacco transformants with low nitrate reductase activity: consequences for the regulation of biomass partitioning between shoots and root1

Accumulation of nitrate in the shoot of low-nitrate reductase tobacco transformants leads to an increase of the shoot:root ratio to higher values than in nitrogen-sufficient wild-type plants, even though the transformants are severely deficient in organic nitrogen. In the present paper, wild-type plants and low- nitrate reductase transformants were grown on vertical agar plates to investigate whether this inhibition of root growth by internal nitrate (i) can be reversed by adding sugars to the roots and (ii) is due to slower growth of the main roots or to a decreased number of lateral roots. When grown with a low nitrate supply, the transformants resembled wild-type plants with respect to amino acid and protein levels, shoot-root allocation, lateral root frequency, and rates of growth. When the transformants were grown with a high nitrate supply in the absence of sucrose they grew more slowly and had lower levels of amino acids and protein than wild-type plants, but accumulated more nitrate and developed a high shoot:root ratio. Root length was not affected, but the number of lateral roots per plant decreased. The slower root growth was accompanied by an increase of the concentration of sugars in the roots. Addition of 2% sucrose to the medium partially reversed the high shoot:root ratio in the transformants, but did not increase the frequency of lateral roots. It is concluded that nitrate accumulation in the plant leads to decreased root growth via (i) changes in carbon allocation leading to decreased allocation of sugars to root growth, and (ii) a decrease in the number of lateral roots and a shift in the sensitivity with which root growth responds to the sugar supply. This revised version was published online in June 2006 with corrections to the Cover Date.     

Accumulation of nitrate in the shoot acts as a signal to regulate shoot-root allocation in tobacco†

Mutants and transformants of tobacco (Nicotiania tabacum L. cv Gatersleben 1) with decreased expression of nitrate reductase have been used to investigate whether nitrate accumulation in the shoot acts as a signal to alter allocation between shoot and root growth. (a) Transformants with very low (1–3% of wild-type levels) nitrate reductase activity had growth rates, and protein, amino acid and glutamine levels similar to or slightly lower than a nitrate-limited wild-type, but accumulated large amounts of nitrate. These plants should resemble a nitrate-limited wild-type, except in responses where nitrate acts as a signal. (b) Whereas the shoot:root ratio decreases from about 3.5 in a well-fertilized wild-type to about 2 in a nitrate-limited wild-type, the transformants had a very high shoot:root ratio (8–10) when they were grown on high nitrate. When they were grown on lower nitrate concentrations their shoot:root ratio declined progressively to a value similar to that in nitrate-limited wild-types. Mutants with a moderate (30–50%) decrease of nitrate reductase also had a small but highly significant increase of their shoot:root ratio, compared to the wild-type. The increased shoot:root ratio in the mutants and transformants was due to a stimulation of shoot growth and an inhibition of root growth. (c) There was a highly significant correlation between leaf nitrate content and the shoot:root ratio for eight genotypes growing at a wide range of nitrate supply. (d) A similar increase of the shoot:root ratio in nitrate reductase-deficient plants, and correlation between leaf nitrate content and the shoot:root ratio, was found in plants growing on ammonium nitrate. (f) Split-root experiments, in which the transformants were grown with part of their root system in high nitrate and the other part in low nitrate, showed that root growth is inhibited by the accumulation of nitrate in the shoot. High concentrations of nitrate in the rooting medium actually stimulate local root growth. (g) The inhibition of root growth in the transformants was relieved when the transformants were grown on limiting phosphate, even though the nitrate content of the root remained high. This shows that the nitrate-dependent changes in allocation can be overridden by other signals that increase allocation to root growth. (h) The reasons for the changed allocation were investigated in transformants growing normally, and in split-root culture. Accumulation of nitrate in the shoot did not lead to decreased levels of amino acids or protein in the roots. However, it did lead to a strong inhibition of starch synthesis and turnover in the leaves, and to decreased levels of sugars in the root. The rate of root growth was correlated with the root sugar content. It is concluded that these changes of carbon allocation could contribute to the changes in shoot and root growth.     

Expression of a luteoviral movement protein in transgenic plants leads to carbohydrate accumulation and reduced photosynthetic capacity in source leaves

Elucidating the role of viral genes in transgenic plants revealed that the movement protein (MP) from tobacco mosaic virus is responsible for altered carbohydrate allocation in tobacco and potato plants. To study whether this is a general feature of viral MPs, the movement protein MP17 of potato leafroll virus (PLRV), a phloem-restricted luteovirus, was constitutively expressed in tobacco plants. Transgenic lines were strongly reduced in height and developed bleached and sometimes even necrotic areas on their source leaves. Levels of soluble sugars and starch were significantly increased in source leaves. Yet, in leaf laminae the hexose—phosphate content was unaltered and ATP reduced to only a small extent, indicating that these leaves were able to maintain homeostatic conditions by compartmentalization of soluble sugars, probably in the vacuole. On the contrary, midribs contained lower levels of soluble sugars, ATP, hexose—phosphates and UDP-glucose supporting the concept of limited uptake and catabolism of sucrose in the phloem. The accumulation of carbohydrates led to a decreased photosynthetic capacity and carboxylation efficiency of ribulose-1,5-bisphosphate carboxylase/oxygenase (rubisco) probably owing to decreased expression of photosynthetic proteins. In parallel, levels of pathogenesis-related proteins were elevated which may be the reason for the obtained limited resistance against the unrelated potato virus Y (PVY)^N in the transgenic tobacco plants. Ultrathin sections of affected leaves harvested from 2-week-old plants revealed plasmodesmal alterations in the phloem tissue while plasmodesmata between mesophyll cells were indistinguishable from wild-type. These data favour the phloem tissue to be the primary site of PLRV MP17 action in altering carbohydrate metabolism.     

Sugar and Amino Acid Content of Poa pratensis Infected with Ustilago striiformis and Urocystis agropyri

Leaf and root tissues of Poa pratensis L. showing distinct morphological changes associated with infection by Ustilago striiformis (West.) Niessl var. poae (stripe smut) or Urocystis agropyri (Pruess) Schroet. (flag smut) were analyzed for total soluble sugars and free amino acids. Decreases in the quantity of soluble sugars in stripe-smutted plants were not significant, indicating that the presence of U. striiformis sori in leaf tissue does not interfere with photosynthesis of the host. Severe decreases in the quantity of soluble sugars in flag-smutted plants suggest that U. agropyri either directly impairs photosynthesis or effectively metabolizes the photosynthate. Both pathogens caused significant decreases in total free amino acids in leaf and root tissues. The negligible decrease in soluble sugars in stripe-smutted plants was associated with a disproportionate decrease in free amino acids, suggesting that the pathogen either metabolizes amino acids or inhibits their synthesis. The severe decrease in amino acids in leaves and roots of U. agropyri-infected plants is believed due to carbohydrate starvation. It is probable that morphological changes in U. agropyri-infected plants, including reduced branching, dwarfed leaves and root systems, and the inability to produce inflorescences, are probably the direct result of severely reduced levels of sugars and amino acids. The reduced branching, somewhat smaller root systems, and inhibition of inflorescence production on plants infected by U. striiformis probably are associated to some extent with decreases in amino acids. The upright elongated leaves of U. striiformis-infected plants, however, cannot be attributed to the decrease in amino acid content and are suggestive of hyperauxiny.     

Effetto Del Dinitrofenolo Sulla Conversione Del Glicerolo A Glucidi in Fettine Di Carote E in Internodi Di Pisello

Abstract

On the effect of dinitrophenol on carbohydrate activation in higher plant tissues. — Previous investigations on the effects of 2,4 dinitrophenol (DNP) on carbohydrate metabolism in isolated pea internodes and in yeast showed that the increased rate of glycolysis induced by the uncoupler corresponds to an increased rate of the conversion of free hexoses and polysaccarides to hexose phosphates. In yeast about 30% of the radioactivity supplied and taken up as ¹⁴C labelled glucose, and 20% of that supplied and taken up as glycerol is recovered as soluble sugar and glycogen; this phenomenon is almost completely suppressed by 10^-4M DNP.

This suggested that a mechanism involving kinase enzymes, on one hand, and phosphatases, on the other, is mediating the interconversion of phosphorylathed and free sugars, and that the apparent increase of hexose phosphorylation observed in the presence of DNP might depend on a decreased rate of phosphatase mediate reactions, consequent to the decrease of phosphorylated sugars level in the cell.

The experiments here reported were planned to test the validity of this hypothesis in the case of higher plant tissues.

Material used in these experiments were segments from the growing part of the third internode isolated from 7 day old, etiolated pea seedlings, and carrot root diks (0,7 mm thick, 7 mm diameter) preincubated for 24 hours in aerated distilled water. Both of these materials show an active, steady respiration and some growth activity, so that they may be taken as representing a condition close enough to that of the generally physiologically active higher plant tissues.

The reversibility of the hexose phosphate-free sugar interconversion process was tested by feeding 10^-3M 1-C¹⁴ labeled glycerol, and measuring after 150 minutes the amount of radioactivity incorporated into CO₂, soluble sugars, organic acids and proteins. The results of these experiments are summarized in table I and II.

Glycerol metabolism as well as its response to DNP appears very similar in the two material used. In both cases, glycerol uptake and incorporation into organic acids and amino acids is almost insensitive to DNP. In contrast large differences are observed for the free sugar fraction. In the absence of the uncoupler, a consistent amount of the radioactivity fed as glycerol is found in this fraction. It appears reasonable to assume that the glycerol-sugar interconversion comprehends, as intermediate steps, glycerol-P, fructose di-P (or sedoeptulose di-P) and hexose-6-P. If this is true, the observed data implicate that a continuous interconversion occurs, in the cell, between sugar phosphates and free sugars and vice-versa, one reaction direction involving the activity of phosphatases, and the other one that of kinases. The true rate of this interconversion process is probably much larger than indicated by the radioactivity found in free sugars: as a considerable part of the triose-P transormed into sugars must immediately re-enter the descending flux of glycolysis.

This view finds some support in the fact that DNP almost completely inhibits the incorporation of radioactivity in the free sugar fraction. It has been previously observed that DNP very markedly decreases the level of hexose mono- and di-phosphates and of triose-phosphates in the pea stem tissues. If phosphatases acting on fructose di-phosphate and on hexose-6-P are not saturated by their substrates, a decrease of the rate of free hexose synthesis from sugar phosphates should be expected.

The present results are thus consistent with the hypothesis that hexose phosphates and free sugars in the cell are continuously interconverted by the simultaneous action of phosphatases and kinases; and that the effect of DNP, and thus of any physiological conditions decreasing the ATP/ADP ratio in accelerating free hexose utilizations is at least in part due to a decreased rate of the reactions catalized by fructose diphosphate and hexose-6-P phosphatases. The reversibility of the kinase-phosphatase system would thus represent a crucial link in the mechanism by which the rate of carbohydrate activation and breackdown is controlled by the rate of utilization of high-energy phosphate bonds.     

Impaired photoassimilate partitioning caused by phloem-specific removal of pyrophosphate can be complemented by a phloem-specific cytosolic yeast-derived invertase in transgenic plants.

Constitutive expression of the Escherichia coli ppa gene encoding inorganic pyrophosphatase resulted in sugar accumulation in source leaves and stunted growth of transgenic tobacco plants. The reason for this phenotype was hypothesized to be reduced sucrose utilization and loading into the phloem. To study the role of PPi in phloem cells, a chimeric gene was constructed using the phloem-specific rolC promoter of Agrobacterium rhizogenes to drive the expression of the ppa gene. Removal of cytosolic PPi in those cells resulted in photoassimilate accumulation in source leaves, chlorophyll loss, and reduced plant growth. From these data, it was postulated that sucrose hydrolysis via sucrose synthase is essential for assimilate partitioning. To bypass the PPi-dependent sucrose synthase step, transgenic plants were produced that express various levels of the yeast suc2 gene, which encodes cytosolic invertase, in their phloem cells. To combine the phloem-specific expression of the ppa gene and the suc2 gene, crosses between invertase- and pyrophosphatase-containing transgenic plants were performed. Analysis of their offspring revealed that invertase can complement the phenotypic effects caused by the removal of PPi in phloem cells.     

Role of the Apoplast in the Control of Assimilate Transport,Photosynthesis, and Plant Productivity

A concept is suggested, which supposes that assimilates are transferred within the plant downward through phloem sieve tubes and, after entering the stem apoplast, are carried up with the ascending flow of transpiration water. After entering the apoplast of fully expanded leaves, these solutes are reexported through the phloem. Thus, a common pool of assimilates with uniform concentration is formed in the plant apoplast. According to this concept, the mechanism of assimilate demand represents a response of photosynthetic apparatus to changes in the apoplastic level of metabolites consumed by sink organs. The ratios of labeled photoassimilates differ between the apoplast and mesophyll cells. Most of the apoplastic labeled carbon is contained in sucrose, less in amino acids, and even less in hexoses. The ¹⁴C-labeling of amino acids increases and the sucrose/hexose labeling ratio decreased under conditions of enhanced nitrate supply. The well-known effect of relative inhibition of assimilate export from leaves under conditions of enhanced nitrogen supply is explained by an enhanced hydrolysis of apoplast-derived sucrose due to the increase in invertase activity, rather than by diversion of primary photosynthetic products from sucrose synthesis to other pathways required for activated growth processes in leaves. This notion is based on observations that the sucrose/hexose ratio is reduced to a greater extent in the apoplast than in the symplast. The last assumption was supported by data obtained after artificial changes in the apoplastic pH. In these experiments intact plants were placed in the atmosphere of NH₃ or HCl vapors, which induced opposite changes in relative content of labeled assimilates in the apoplast and in the photosynthetic rate.     

Export of amino acids to the phloem in relation to N supply in wheat

The effect of different N supply on amino acid export to the phloem was studied in young plants of wheat (Triticum aestivum L. cv. Klein Chamaco), using the exudation in EDTA technique. Plants were grown in a growth cabinet in pots with sand, and supplied with nutrient solutions of different NO₃^? concentrations. When plants were grown for 15 days with nutrient solutions containing 1.0, 3.0, 5.0, 10.0, 15.0 or 20.0 mM KNO₃, the exudation rate of sugars from the phloem was unaffected by N supply, but sugars accumulated in the leaf tissue when the N supply was limiting for growth. On the other hand, the rate of exudation of amino acids was proportional to the NO₃^? concentration in the nutrient solution. When the supply of N to plants grown for 15 days with 15.0 mM NO₃^? was interrupted, the exudation of sugars was again unaffected, but there was a fast decrease in the amount of amino acids exudated, and of the concentration of amino acids and nitrogen in the tissues. Also, when 10-day-old plants grown without N were supplied with 15.0 mM NO₃^?, there was a sharp increase in the exudation of amino acids, without changes in the amount of sugar exudated. The rate of exudation of amino acids to the phloem was independent of the concentration of free amino acids in the leaves in all three types of experiment. Asp was the most abundant amino acid in the leaf tissue, while Glu was the one most abundant in the phloem exudate. Asp and Ala were exported to the phloem at a rate lower than expected from their leaf tissue concentrations, indicating some discrimination. On the contrary, Glu showed a preferential export at low N supply. It is concluded that the rate of amino acid export from the leaf to the phloem is dependent on the N available to the plant. This N is used for synthesis of leaf protein when the supply is low, exported to the phloem when supply is adequate, and accumulated in the storage pool when supply is above plant demand.     

Decreased Rubisco activity leads to dramatic changes of nitrate metabolism,amino acid metabolism and the levels of phenylpropanoids and nicotine in tobacco antisense RBCS transformants

Tobacco transformants that express an antisense RBCS construct were used to investigate the consequences of a lesion in photosynthetic carbon metabolism for nitrogen metabolism and secondary metabolism. The results show that an inhibition of photosynthesis and decrease in sugar levels leads to a general inhibition of nitrogen metabolism, and dramatic changes in the levels of secondary metabolites. The response was particularly clear in plants that received excess nitrogen. In these conditions, a decrease of Rubisco activity led to an inhibition of nitrate reductase activity, accumulation of nitrate, a decrease of amino acid levels that was larger than the decrease of sugars, and a large decrease of chlorogenic acid and of nicotine, which are the major carbon- and nitrogen-rich secondary metabolites in tobacco leaves, respectively. Similar changes were seen when nitrogen-replete wild-type tobacco was grown in low light. The inhibition of nitrogen metabolism was partly masked when wild-type plants and antisense RBCS transformants were compared in marginal or in limiting nitrogen, because the lower growth rate of the transformants alleviated the nitrogen deficiency, leading to an increase of amino acids. In these conditions, chlorogenic acid always decreased but the decrease of nicotine was ameliorated or reversed. When the changes in internal pools are compared across all the genotypes and growth conditions, two conclusions emerge. First, decreased levels of primary metabolites lead to a dramatic decrease in the levels of secondary metabolites. Second, changes of the amino acid : sugar ratio are accompanied by changes of the nicotine:chlorogenic acid ratio.     

The Relationship between Sugar and Amino Acid Export to the Phloem in Young Wheat Plants

The relationship between amino acid and sugar export to thephloem was studied in young wheat plants (Triticum aestivumL. ‘Pro-INTA, Isla Verde’) using the EDTA-phloemcollection technique. Plants grown with a 16 h photoperiod showeda rapid decrease in the concentration of sugars and amino acidsin the phloem exudate from the beginning of the dark period.When plants grown with a 16 h photoperiod were kept in the darkfor longer than 8 h the free amino acid content in leaves andexudate (on a dry weight basis) increased continually throughoutthe 72 h of darkness. During the first 24 h of darkness thesugars in the phloem exudate decreased to 30% of the initialvalue, and returned to the control level when plants were returnedto light. When plants grown under low light intensity for 10d were transferred to high light intensity, they showed an increasein leaf sugar content (dry weight basis) after 3 d but therewere no differences in leaf free amino acid content (dry weightbasis) compared to low-light plants. The sugar concentrationin the phloem exudate was increased by higher light intensities,but there was no difference in the amino acid concentrationof the phloem exudate, and thus the amino acid:sugar ratio inthe phloem decreased in the high-light plants. The present resultssuggest that amino acids can be exported to the phloem independentlyof the export of sugars. Copyright 1999 Annals of Botany Company Sugar exudation, amino acid transport, nitrogen, phloem, transport, wheat, Triticum aestivum L.     

Measurement of Metabolites Associated with Nonaqueously Isolated Starch Granules from Immature Zea mays L. Endosperm

Starch granules with associated metabolites were isolated from immature Zea mays L. endosperm by a nonaqueous procedure using glycerol and 3-chloro-1,2-propanediol. The soluble extract of the granule preparation contained varying amounts of neutral sugars, inorganic phosphate, hexose and triose phosphates, organic acids, adenosine and uridine nucleotides, sugar nucleotides, and amino acids. Based on the metabolites present and on information about translocators in chloroplast membranes, which function in transferring metabolites from the chloroplast stroma into the cytoplasm, it is suggested that sucrose is degraded in the cytoplasm, via glycolysis, to triose phosphates which cross the amyloplast membrane by means of a phosphate translocator. It is further postulated that hexose phosphates and sugars are produced from the triose phosphates in the amyloplast stroma by gluconeogenesis with starch being formed from glucose 1-phosphate via pyrophosphorylase and starch synthase enzymes. The glucose 1-phosphate to inorganic phosphate ratio in the granule preparation was such that starch synthesis by phosphorylase is highly unlikely in maize endosperm.     

Sul trasporto dei glucidi nelle piante superiori: I. — Aspetti biochimici

Abstract

CARBOHYDRATE TRANSLOCATION IN HIGHER PLANTS. I. - BIOCHEMICAL ASPECTS. — The concentration of soluble sugars and of hexose phosphates and the activity of several enzymes involved in hexose activation and polysaccaride synthesis have been investigated, separately, in the phloematic tissue and in the medullar parenchyma of Cucurbita Pepo internodes.

In the phloematic tissue (including sieve tubes, companion cells and phloematic parenchyma) the concentration of free hexoses appeared of about 50% lower, and that of glucose-6-P and of sucrose of about 100% higher then in the medullar parenchyma. Consistent amounts of raffinose were found only in the phloematic tissue. Paper chromatograms of the sieve tube exudate showed the presence of raffinose and sucrose in a ratio close to unity, and no appreciable amounts of free hexoses.

Determination of enzyme activity on preparations obtained from homogenates from the two types of tissue by repeated ammonium sulfate precipitation showed in the phloematic tissue a high activity of the enzymes hexokinase, UDP-kinase, UDPG-pyrophosphorylase and inorganic pyrophosphatase. The presence in the same tissue of galactosekinase, UDP-Gal-pyrophosphorylase and UDPG-epimerase was also ascertained.

On a protein basis, the activity of UDPG-pyrophosphorylase, inorganic pyrophosphatase and hexokinase appared about 3 times higher in the phloematic tissue than in the parenchyma; while this difference between the two tissues was not so marked for phosphofructokinase, and very small for other enzymes such as ATP-ase and phosphomono-esterase.

These results suggest that the very high activity, in the phloem cells neighbouring the sieve tubes, of the enzyme system catalyzing oligopolysaccaride synthesis could be an important component of the mechanism involved in the accumulation of oligopolysaccarides in the sieve tubes, and thus in sugar translocation. A scheme is proposed according to which the ATP and UTP energy would be utilized by the phloem cells to reach and to maintein a concentration of soluble sugars consistently higher than that prevailing in the contiguous tissues.     

Changes occurring during aging and senescence in a submerged aquatic angiosperm (Potamogeton pectinatus)

Changes occurring during aging and senescence of leaves of a submerged aquatic angiosperm ( Potamogeton pectinatus L.) were studied. Total chlorophyll and chlorophylls a and b were maximal in mature, and minimal in old leaves. The chlorophyll a to b ratio was highest in mature leaves. During senescence, the chlorophyll content and the ratio of chlorophyll a to b decreased. The content of DNA, RNA, protein and dry weight, and the activity of alkaline pyrophosphatase decreased while free amino acids, the activity of protease, RNase and acid pyrophosphatase, and the ratio of acid to alkaline pyrophosphatase activity increased during aging and senescence. Kinetin (0.23 m M ) deferred leaf senescence by delaying the loss of chlorophyll, protein, nucleic acids and dry weight, and reducing the rise in free amino acids, the activity of protease, RNase and acid pyrophosphatase and the ratio of acid to alkaline pyrophosphatase activity; while both 0.69 m M ethrel and 0.075 m M ABA hastened senescence. Kinetin pretreatment for an optimum period (12 h) followed by ethrel or ABA treatment partially erased the senescence-promoting effect of the latter. But treatments in a reverse order markedly reduced the delaying effect of kinetin on senescence.     

Changes in phloem export of sucrose in leaves in response to phosphorus, potassium and magnesium deficiency in bean plants

The effect of varied phosphorus (10 and 250 mmol P m^–3potassium (50 and 2010 mmol K m^–3) and magnesium (20 and1000 mmol Mg m^–3 supply on sucrose, reducing sugars, aminoacids, P, K, and Mg in phloem exudate was studied in bean (Phaseolusvulgaris L.) plants over a 12 d growth period in nutrient solution.Phloem exudates were collected from detached primary leavesusing the EDTA-promoted exudation technique. Compared with controlnutrient-sufficient plants, sucrose export in the phloem exudatewas drastically decreased by K deficiency and, particularly,by Mg deficiency, whereas P deficiency either had no effector stimulated sucrose export. In Mg-deficient plants the rateof sucrose export was decreased to 10–20% of the controlplants. There was a close Inverse relationship between phloemexport and leaf concentration of sucrose: higher leaf concentrationsof sucrose were accompanied by lower phloem export of sucrose.In contrast to sucrose, reducing sugars in the exudates werevery low and not affected by P, K and Mg deficiency. The phloemexport of amino acids was strongly depressed by Mg deficiency,but only slightly by P and K deficiency. Resupplying Mg to Mg-deficientplants for 12 h during the dark or light periods rapidly stimulatedsucrose export. After resup ply of Mg for 24 h and 48 h therate of sucrose export was comparable with the rate in the controlplants. The results demonstrate a key role for Mg in phloem loadingand export of photosynthates from source leaves, especiallysucrose. Inhibition of root growth and development of visualsymptoms of chlorosis in Mg-deficient plants are suggested asconsequences of Impaired phloem loading. In agreement with thisin P-deficient plants where phloem loading was not impaired,chlorosis was absent and root growth was maintained at a highlevel. Key words: Bean, carbon partitioning, magnesium nutrition, phloem transport, phosphorus nutrition, potassium nutrition     

Ultrastructural effects in potato leaves due to antisense-inhibition of the sucrose transporter indicate an apoplasmic mode of phloem loading

To study the export of sugars from leaves and their long-distance transport, sucrose-proton/co-transporter activity of potato was inhibited by antisense repression of StSUT1 under control of either a ubiquitously active (CaMV 35S ) or a companion-cell-specific (rolC) promotor in transgenic plants. Transformants exhibiting reduced levels of the sucrose-transporter mRNA and showing a dramatic reduction in root and tuber growth, were chosen to investigate the ultrastructure of their source leaves. The transformants had a regular leaf anatomy with a single-layered palisade parenchyma, and bicollateral minor veins within the spongy parenchyma. Regardless of the promoter used, source leaves from transformants showed an altered leaf phenotype and a permanent accumulation of assimilates as indicated by the number and size of starch grains, and by the occurrence of lipid-storing oleosomes. Starch accumulated throughout the leaf: in epidermis, mesophyll and, to a smaller degree, in phloem parenchyma cells of minor veins. Oleosomes were observed equally in mesophyll and phloem parenchyma cells. Companion cells were not involved in lipid accmulation and their chloroplasts developed only small starch grains. The similarity of ultrastructural symptoms under both promotors corresponds to, rather than contradicts, the hypothesis that assimilates can move symplasmically from mesophyll, via the bundle sheath, up to the phloem. The microscopical symptoms of a constitutively high sugar level in the transformant leaves were compared with those in wild-type plants after cold-girdling of the petiole. Inhibition of sugar export, both by a reduction of sucrose carriers in the sieve element/companion cell complex (se/cc complex), or further downstream by cold-girdling, equally evokes the accumulation of assimilates in all leaf tissues up to the se/cc complex border. However, microscopy revealed that antisense inhibition of loading produces a persistently high sugar level throughout the leaf, while cold-girdling leads only to local patches containing high levels of sugar. Received: 4 March 1998 / Accepted: 7 April 1998     

Salicylic acid-induced adaptive response to copper stress in sunflower (Helianthus annuus L.)

The ameliorative effect of salicylic acid (SA: 0.5 mM) on sunflower (Helianthus annuus L.) under Cu stress (5 mg l⁻¹) was studied. Excess Cu reduced the fresh and dry weights of different organs (roots, stems and leaves) and photosynthetic pigments (chlorophyll a, b and carotenoids) in four-week-old plants. There was a considerable increase in Chl a/b ratio and lipid peroxidation in both the roots and leaves of plants under excess Cu. Soluble sugars and free amino acids in the roots also decreased under Cu stress. However, soluble sugars in the leaves, free amino acids in the stems and leaves, and proline content in all plant organs increased in response to Cu toxicity. Salicylic acid (SA) significantly reduced the Chl a/b ratio and the level of lipid peroxidation in Cu-stressed plants. Under excess Cu, a higher accumulation of soluble sugars, soluble proteins and free amino acids including proline occurred in plants treated with 0.5 mM SA. Exogenous application of SA appeared to induce an adaptive response to Cu toxicity including the accumulation of organic solutes leading to protective reactions to the photosynthetic pigments and a reduction in membrane damage in sunflower.     

Increased Expression of a Phloem Membrane Protein Encoded by NHL26 Alters Phloem Export and Sugar Partitioning in Arabidopsis

The complex process of phloem sugar transport involves symplasmic and apoplasmic events. We characterized Arabidopsis thaliana lines ectopically expressing a phloem-specific gene encoding NDR1/HIN1-like26 (NHL26), a putative membrane protein. NHL26 overexpressor plants grew more slowly than wild-type plants, accumulated high levels of carbohydrates in mature leaves, and had a higher shoot biomass, contrasting with slower root growth and a lower seed yield. Similar effects were observed when NHL26 was overexpressed in companion cells, under the control of a companion cell–specific promoter. The soluble sugar content of the phloem sap and sink organs was lower than that in the wild type, providing evidence of a sugar export defect. This was confirmed in a phloem-export assay with the symplastic tracer carboxyfluorescein diacetate. Leaf sugar accumulation was accompanied by higher organic acid, amino acid, and protein contents, whereas analysis of the metabolite profile of phloem sap exudate revealed no change in amino acid or organic acid content, indicating a specific effect on sugar export. NHL26 was found to be located in the phloem plasmodesmata and the endoplasmic reticulum. These findings reveal that NHL26 accumulation affects either the permeability of plasmodesmata or sugar signaling in companion cells, with a specific effect on sugar export.