Low night temperatures inhibit galactinol synthase gene expression and phloem loading in melon leaves during fruit development

Low night temperatures seriously affect plant growth and fruit quality. To investigate the effect of low night temperatures on the expression of galactinol synthase genes (GOLS) and phloem loading of raffinose family oligosaccharides, particular stachyose and raffinose (RFO represents stachyose and raffinose in this paper) and to gain a better understanding of the relationship between the phloem loading of RFO and fruit development, melon (Cucumis melo L.) plants at the fruit development stage were treated with temperatures of 28/12°C or 28/9°C (day/night) with 28/15°C as the control. Both the CmGOLS1 and CmGOLS2 gene expression and the activity of galactinol synthase were clearly repressed after treatments with 9 and 12°C at night, and the effect of 9°C was more obvious. Furthermore, low night temperatures inhibited photosynthesis and caused the lower amounts of sucrose to supply the RFO synthesis. However, the total soluble sugar, RFO, and sucrose contents were increased in leaves subjected to low night temperatures. It is supposed that low night temperature blocked symplastic phloem loading, which led to the accumulation of RFO in the leaf cells. With increasing content of RFO in the leaves, the expression of GOLS genes was inhibited according to the principle of feedback, and therefore the decreased expression of GOLS limited RFO synthesis and was indirectly harmful to phloem loading, thereby affecting fruit development.     

Important roles of drought- and cold-inducible genes for galactinol synthase in stress tolerance in Arabidopsis thaliana

Raffinose family oligosaccharides (RFO) accumulating during seed development are thought to play a role in the desiccation tolerance of seeds. However, the functions of RFO in desiccation tolerance have not been elucidated. Here we examine the functions of RFO in Arabidopsis thaliana plants under drought- and cold-stress conditions, based on the analyses of function and expression of genes involved in RFO biosynthesis. Sugar analysis showed that drought-, high salinity- and cold-treated Arabidopsis plants accumulate a large amount of raffinose and galactinol, but not stachyose. Raffinose and galactinol were not detected in unstressed plants. This suggests that raffinose and galactinol are involved in tolerance to drought, high salinity and cold stresses. Galactinol synthase (GolS) catalyses the first step in the biosynthesis of RFO from UDP-galactose. We identified three stress-responsive GolS genes (AtGolS1, 2 and 3) among seven Arabidopsis GolS genes. AtGolS1 and 2 were induced by drought and high-salinity stresses, but not by cold stress. By contrast, AtGolS3 was induced by cold stress but not by drought or salt stress. All the GST fusion proteins of GST-AtGolS1, 2 and 3 expressed in Escherichia coli had galactinol synthase activities. Overexpression of AtGolS2 in transgenic Arabidopsis caused an increase in endogenous galactinol and raffinose, and showed reduced transpiration from leaves to improve drought tolerance. These results show that stress-inducible galactinol synthase plays a key role in the accumulation of galactinol and raffinose under abiotic stress conditions, and that galactinol and raffinose may function as osmoprotectants in drought-stress tolerance of plants.     

植物中棉子糖系列寡糖代谢及其调控关键酶研究进展

棉子糖系列寡糖代谢与植物生长发育、逆境胁迫、种子耐贮性及脱水耐性等关系密切.棉子糖系列寡糖的合成从棉子糖的合成开始,由半乳糖苷肌醇上的半乳糖基的转移依次生成棉子糖、水苏糖、毛蕊花糖等.寡糖代谢是一个复杂的调控体系,其中肌醇-1-磷酸合成酶、肌醇半乳糖苷合成酶、蔗糖合成酶、棉子糖合成酶、水苏糖合成酶和毛蕊花糖合成酶等参与了棉子糖系列寡糖的生物合成过程.本文对植物中棉子糖系列寡糖的代谢及其重要调控酶的特性、功能及分子生物学研究进展进行综述.     

Expression of a GALACTINOL SYNTHASE gene is positively associated with desiccation tolerance of Brassica napus seeds during development

Desiccation tolerance of seeds is positively correlated with raffinose family oligosaccharides (RFOs). However, RFOs’ role in desiccation tolerance is still a matter of controversy. The aim of this work was to monitor the accumulation of RFO during acquisition of desiccation tolerance in rapeseed (Brassica napus L.). Rapeseeds become desiccation tolerant at 21-24 d after flowering (DAF), and the time was coincident with an accumulation of raffinose and stachyose. A gene encoding galactinol synthase (GolS; EC2.4.1.123), involved in RFO biosynthesis, was cloned and functionally characterized. Enzymatic properties of recombinant galactinol synthase were also determined. Accumulation of BnGOLS-1 mRNA in developing rapeseeds was concomitant with dry weight deposition and the acquisition of desiccation tolerance, and was concurrent with the formation of raffinose and stachyose. The physiological implications of BnGOLS-1 expression patterns in developing seeds are discussed in light of the hypothesized role of RFOs in seed desiccation tolerance.     

Metabolism of the Raffinose Family Oligosaccharides in Leaves of Ajuga reptans L. (Inter- and Intracellular Compartmentation)

We recently suggested that leaves of the frost-hardy species Ajuga reptans L. (Lamiaceace) contain two pools of raffinose family oligosaccharides (RFO): a large long-term storage pool in the mesophyll, possibly also involved in frost resistance, and a transport pool in the phloem (M. Bachmann, P. Matile, F. Keller [1994] Plant Physiol 105: 1335-1345). In the present study, the inter- and intracellular compartmentation of anabolic RFO metabolism was investigated by comparing whole-leaf tissue with mesophyll protoplasts and vacuoles. The studies showed the mesophyll to be the primary site of RFO synthesis in A. reptans. Mesophyll protoplasts were capable of RFO formation upon in vitro 14CO2 photosynthesis. Sucrose-phosphate synthase, galactinol synthase, and the galactinol-independent galactosyltransferase, which is responsible for RFO chain elongation, were located predominantly in the mesophyll protoplasts. The percentage of stachyose synthase in the mesophyll changed greatly during the cold-acclimation period (from 26% at the beginning to 88% after 20 d). The remainder was most probably in the intermediary cells of the phloem. Compartmentation studies in which mesophyll protoplasts were compared with vacuoles isolated from them showed that, of the components of the RFO storage pool, galactinol synthase, stachyose synthase, myo-inositol, galactinol, and sucrose were extravacuolar (most probably cytosolic), whereas galactinol-independent galactosyltransferase and higher RFO oligomers (with degree of polymerization 4) were vacuolar. Raffinose was found in both locations and might serve as a cryoprotectant.     

Water Deficit Effects on Raffinose Family Oligosaccharide Metabolism in Coleus

Variegated coleus (Coleus blumei Benth.) plants were exposed to a restricted water supply for 21 d. The relative water content in leaf tissues was reduced from 80% (control) to 60% (drought-stressed). Under drought conditions, the stomatal conductance and leaf photosynthetic rate were reduced. In green leaf tissues, drought stress also greatly decreased the diurnal light-period levels of the raffinose family oligosaccharides (RFOs) stachyose and raffinose, as well as those of other non-structural carbohydrates (galactinol, sucrose, hexoses, and starch). However, drought had little effect on soluble carbohydrate content of white, non-photosynthetic leaf tissues. In green tissues, galactinol synthase activity was depressed by drought stress. An accumulation of O-methyl-inositol was also observed, which is consistent with the induction of myoinositol-6-O-methyltransferase activity seen in the stressed green tissues. In source tissues, RFO metabolism is apparently reduced by drought stress through a combined effect of decreased photosynthesis and reduced galactinol synthase activity. Moreover, a further reduction in RFO biosynthesis may have been due to a switch in carbon partitioning to O-methyl-inositol biosynthesis, creating competition for myoinositol, a metabolite shared by both biochemical pathways.     

Changes in concentrations of soluble carbohydrates during germination of <Emphasis Type="Italic">Amaranthus caudatus</Emphasis> L. seeds in relation to ethylene,gibberellin A<Subscript>3</Subscript> and methyl jasmonate

Unimbibed Amaranthus caudatus seeds were found to contain stachyose, raffinose, verbascose, sucrose, galactinol, myo-inositol, glucose and fructose, while no galactose, maltose and maltotriose was detected. During imbibition, seed concentrations of verbascose, stachyose, raffinose, galactinol, myo-inositol (temporary) and fructose (transient) were observed to decrease; concentrations of galactose and maltose remained fairly constant, while those of sucrose, glucose and maltotriose increased, the increase in sucrose concentration was only temporary. Effects of gibberellin A₃ (GA₃) at 3 × 10⁻⁴ M and ethephon at 3 × 10⁻⁴ M alone or in the presence of methyl jasmonate (Me-JA) at 10⁻³ M on concentrations of soluble sugars during germination of A. caudatus seeds were examined. Me-JA was found to inhibit seed germination and fresh weight of the seeds, but did not affect sucrose, myo-inositol, galactose and maltose concentrations during imbibition for up to 20 h. The exogenously applied GA₃ was observed to enhance germination, stachyose breakdown and glucose concentration after 20 h of incubation. Ethephon stimulated seed germination as well as utilisation of stachyose, galactinol (both after 14 and 20 h) and raffinose (after 14 h of incubation). Although the stimulatory effect of either GA₃ or ethephon on seed germination was blocked by Me-JA; these stimulators increased mobilisation of raffinose and stachyose, but only ethephon enhanced both glucose and fructose after 14 and/or 20 h of incubation in the presence of Me-JA. The maltose concentration was increased by both GA₃ and ethephon alone and in the presence of Me-JA. Of the growth regulators studied, ethephon alone and/or in combination with Me-JA significantly increased the concentrations of glucose, fructose, galactose, maltose and maltotriose. The differences in sugar metabolism appear to be linked to ethylene or GA₃ applied simultaneously with Me-JA.     

Analysis of the raffinose family oligosaccharide pathway in pea seeds with contrasting carbohydrate composition.

Raffinose family oligosaccharides (RFOs) are synthesized by a set of galactosyltransferases, which sequentially add galactose units from galactinol to sucrose. The accumulation of RFOs was studied in maturing seeds of two pea (Pisum sativum) lines with contrasting RFO composition. Seeds of the line SD1 accumulated stachyose as the predominant RFO, whereas verbascose, the next higher homolog of stachyose, was almost absent. In seeds of the line RRRbRb, a high level of verbascose was accumulated alongside with stachyose. The increase in verbascose in developing RRRbRb seeds was associated with galactinol-dependent verbascose synthase activity. In addition, a galactinol-independent enzyme activity was detected, which catalyzed transfer of a galactose residue from one stachyose molecule to another. The two enzyme activities synthesizing verbascose showed an optimum at pH 7.0. Both activities were almost undetectable in SD1. Maximum activity of stachyose synthase was about 4-fold higher in RRRbRb compared with SD1, whereas the activities of galactinol synthase and raffinose synthase were only about 1.5-fold higher in RRRbRb. The levels of galactinol synthase and stachyose synthase activity were reflected by steady-state levels of corresponding mRNAs. We suggest that the accumulation of verbascose in RRRbRb was controlled by a coordinated up-regulation of the last steps of verbascose biosynthesis.     

Physiological aspects of raffinose family oligosaccharides in plants: protection against abiotic stress

Abiotic stresses resulting from water deficit, high salinity or periods of drought adversely affect plant growth and development and represent major selective forces during plant evolution. The raffinose family oligosaccharides (RFOs) are synthesised from sucrose by the subsequent addition of activated galactinol moieties donated by galactinol. RFOs are characterised as compatible solutes involved in stress tolerance defence mechanisms, although evidence also suggests that they act as antioxidants, are part of carbon partitioning strategies and may serve as signals in response to stress. The key enzyme and regulatory point in RFO biosynthesis is galactinol synthase (GolS), and an increase of GolS in expression and activity is often associated with abiotic stress. It has also been shown that different GolS isoforms are expressed in response to different types of abiotic stress, suggesting that the timing and accumulation of RFOs are controlled for each abiotic stress. However, the accumulation of RFOs in response to stress is not universal and other functional roles have been suggested for RFOs, such as being part of a carbon storage mechanism. Transgenic Arabidopsis plants with increased galactinol and raffinose concentrations had better ROS scavenging capacity, while many sugars have been shown in vitro to have antioxidant activity, suggesting that RFOs may also act as antioxidants. The RFO pathway also interacts with other carbohydrate pathways, such as that of O‐methyl inositol (OMI), which shows that the functional relevance of RFOs must not be seen in isolation to overall carbon re‐allocation during stress responses.     

Sugar synthesis and phloem loading in Coleus blumei leaves

Sugar-synthesis and -transport patterns were analyzed in Coleus blumei Benth. leaves to determine where galactinol, raffinose, and stachyose are made and whether phloem loading includes an apoplastic (extracellular) step or occurs entirely within the symplast (plasmodesmata-connected cytoplasm). To clarify the sequence of steps leading to stachyose synthesis, a pulse (15 s) of ¹⁴CO₂ was given to attached leaves followed by a 5-s to 20-min chase: sucrose was rapidly labeled while galactinol, raffinose and stachyose were labeled more slowly and, within the first few minutes, to approximately the same degree. Leaf tissue was exposed to either ¹⁴CO₂ or [¹⁴C]glucose to identify the sites of synthesis of the different sugars. A 2-min exposure of peeled leaf tissue to [¹⁴C]glucose resulted in preferential labeling of the minor veins, as opposed to the mesophyll; galactinol, raffinose and stachyose were more heavily labeled than sucrose in these preparations. In contrast, when leaf tissue was exposed to ¹⁴CO₂ for 2 min for preferential labeling of the mesophyll, sucrose was more heavily labeled than galactinol, raffinose or stachyose. We conclude that sucrose is synthesized in mesophyll cells while galactinol, raffinose and stachyose are made in the minorvein phloem. Competition experiments were performed to test the possibility that phloem loading involves monosaccharide uptake from the apoplast. Two saturable monosaccharide carriers were identified, one for glucose, galactose and 3-O-methyl glucose, and the other for fructose. Washing the apoplast of peeled leaf pieces with buffer or saturating levels of 3-O-methyl glucose, after providing a pulse of ¹⁴CO₂, did not inhibit vein loading or change the composition of labeled sugars, and less than 0.5% of the assimilated label was recovered in the incubation medium. These and previous results (Turgeon and Gowan, 1991, Plant Physiol. 94, 1244–1249) indicate that the phloem loading pathway in Coleus is probably symplastic.Abbreviations 3-OMG 3-O-methyl glucose - PCMBS p-chloromercuribenzenesulfonic acid - SE-CCC sieve-element-companion-cell complex This research was supported by National Science Foundation Grant DCB-9104159, U.S. Department of Agriculture Competetive Grant 90000854, and Hatch funds.     

Stachyose synthesis in leaves of Cucurbita pepo

An enzyme synthesizing stachyose, galactinol-raffinose galactosyltransferase (EC2.4.1.67), has been purified ca 40-fold from mature leaves of Cucurbita pepo using ammonium sulphate precipitation, Sephadex gel filtration and DEAE-Sephadex gel chromatography. The purified enzyme fraction was separated from all but 2 % of the total,α-galactosidase activity extracted from the tissue. The enzyme was optimally active at pH 6.9 and was stable for at least a month at 4° in the presence of 20 mM 2-mercaptoethanol. The enzyme displayed high specificity for the donor galactinol (K_m 7.7 mM) and the acceptor raffinose (K_m 4.6 mM) and was unable to effect synthesis of any other member of the raffinose series of galactosyl-sucrose oligosaccharides. Co²⁺, Hg²⁺, Mn²⁺ and Ni²⁺ ions were particularly inhibitory; no metal ion promotion was observed and 5 mM EDTA was ineffective. Myo-inositol was strongly inhibitory (K_i 2 mM), melibiose weakly so. Tris buffer (0. 1 M) was also inhibitory. Galactinol hydrolysis occurred in the absence of the acceptor raffinose but there was no hydrolysis of either raffinose or stachyose in the absence of the donor galactinol. The reaction was readily reversible and exchange reactions were detected between substrates and products. It is proposed that the synthesis of stachyose in mature leaves ofC. pepo proceeds via this galactosyltransferase and not via α-galactosidase.     

Allocation of raffinose family oligosaccharides to transport and storage pools in Ajuga reptans: the roles of two distinct galactinol synthases

Raffinose family oligosaccharides (RFOs) are important phloem transport and storage carbohydrates for many plants. Ajuga reptans, a frost-hardy evergreen labiate, ideally combines these two physiological roles and served as our model plant to study the regulation and importance of RFO metabolism. Galactinol is the galactosyl donor for the synthesis of raffinose (RFO-trisaccharide) and stachyose (RFO-tetrasaccharide), and its synthesis by galactinol synthase (GolS) is the first committed step of the RFO biosynthetic pathway. Two cDNAs encoding two distinct GolS were isolated from A. reptans source and sink leaves, designated GolS-1 and GolS-2, respectively. Warm- and cold-grown sink and source leaves were compared, revealing both isoforms to be cold-inducible and GolS-1 to be source leaf-specific; GolS-1 expression correlated positively with GolS activity. Conversely, GolS-2 expression was comparatively much lower and its contribution to the total extractable GolS activity is most probably only minor. These observations, together with results from phloem exudation and leaf shading experiments suggest that GolS-1 is mainly involved in the synthesis of storage RFOs and GolS-2 in the synthesis of transport RFOs. Furthermore, in situ hybridization studies showed GolS-1 to be primarily expressed in the mesophyll, the site of RFO storage, and GolS-2 in the phloem-associated intermediary cells known for their role in RFO phloem loading. A model depicting the spatial compartmentation of the two GolS isoforms is proposed.     

Are sucrosyl-oligosaccharides synthesized in mesophyll protoplasts of mature leaves of Cucumis melo?

Biosynthesis of sucrosyl-oligosaccharides (raffinose, stachyose) was traced in source leaves of Cucumis melo after ¹⁴C-photoassimilation. The main carbon compound exported was ¹⁴C-labeled stachyose. No oligosaccharide synthesis was detected in young, importing leaves. Mesophyll protoplasts, isolated from mature leaves which had previously photosynthesized ¹⁴CO₂, did not contain ¹⁴C-oligosaccharides but contained [¹⁴C]-sucrose and ¹⁴C-hexoses. Isolated minor-vein-enriched fractions from the same leaves, however, showed nearly 30% of the ¹⁴C of the neutral fraction to be in oligosaccharides. Isolated, viable mesophyll protoplasts incubated with NaH¹⁴CO₃ also failed to incorporate radioactivity into oligosaccharides, although sucrose and galactinol synthesis was unimpaired. Galactinolsynthase activity in leaf extracts and in mesophyll protoplasts was 16.8 mol·h^-1·mg^-1 protein and 13.8 mol·h^-1·mg^-1 protein, respectively. Galactosyltransferase (EC 2.4.1.67), which synthesizes stachyose from raffinose and galactinol, had an activity of 50 nmol·h^-1·mg^-1 protein in leaf extracts and was also present in the minor-vein-enriched fraction, but could not be detected in mesophyll protoplast lysates. The results indicate that mesophyll cells may not be the site of stachyose synthesis although precursor compounds like sucrose and galactinol are synthesized there.Abbreviation HPLC high-performance liquid chromatography     

Hexose transporter CsSWEET7a in cucumber mediates phloem unloading in companion cells for fruit development

In the fleshy fruit of cucumbers (Cucumis sativus L.), the phloem flow is unloaded via an apoplasmic pathway, which requires protein carriers to export sugars derived from stachyose and raffinose into the apoplasm. However, transporter(s) involved in this process remain unidentified. Here, we report that a hexose transporter, CsSWEET7a (Sugar Will Eventually be Exported Transporter 7a), was highly expressed in cucumber sink tissues and localized to the plasma membrane in companion cells of the phloem. Its expression level increased gradually during fruit development. Down-regulation of CsSWEET7a by RNA interference (RNAi) resulted in smaller fruit size along with reduced soluble sugar levels and reduced allocation of ¹⁴C-labelled carbon to sink tissues. CsSWEET7a overexpression lines showed an opposite phenotype. Interestingly, genes encoding alkaline α-galactosidase (AGA) and sucrose synthase (SUS) were also differentially regulated in CsSWEET7a transgenic lines. Immunohistochemical analysis demonstrated that CsAGA2 co-localized with CsSWEET7a in companion cells, indicating cooperation between AGA and CsSWEET7a in fruit phloem unloading. Our findings indicated that CsSWEET7a is involved in sugar phloem unloading in cucumber fruit by removing hexoses from companion cells to the apoplasmic space to stimulate the raffinose family of oligosaccharides (RFOs) metabolism so that additional sugars can be unloaded to promote fruit growth. This study also provides a possible avenue towards improving fruit production in cucumber.

Transporter CsSWEET7a removes hexose from companion cells to the apoplasmic space to stimulate fruit phloem unloading so that additional sugars can be unloaded to promote fruit growth.     

Chain Elongation of raffinose in pea seeds. Isolation, characterization, and molecular cloning of mutifunctional enzyme catalyzing the synthesis of stachyose and verbascose.

Raffinose oligosaccharides are major soluble carbohydrates in seeds and other tissues of plants. Their biosynthesis proceeds by stepwise addition of galactose units to sucrose, which are provided by the unusual donor galactinol (O-alpha-d-galactopyranosyl-(1-->1)-l-myo-inositol). Chain elongation may also proceed by transfer of galactose units between raffinose oligosaccharides. We here report on the purification, characterization, and heterologous expression of a multifunctional stachyose synthase (EC ) from developing pea (Pisum sativum L.) seeds. The protein, a member of family 36 of glycoside hydrolases, catalyzes the synthesis of stachyose, the tetrasaccharide of the raffinose series, by galactosyl transfer from galactinol to raffinose. It also mediates the synthesis of the pentasaccharide verbascose by galactosyl transfer from galactinol to stachyose as well as by self-transfer of the terminal galactose residue from one stachyose molecule to another. These activities show optima at pH 7.0. The enzyme also catalyzes hydrolysis of the terminal galactose residue of its substrates, but is unable to initiate the synthesis of raffinose oligosaccharides by galactosyl transfer from galactinol to sucrose. A minimum reaction mechanism which accounts for the broad substrate specificity and the steady-state kinetic properties of the protein is presented.