No evidence for the occurrence of substrate inhibition of Arabidopsis thaliana sucrose synthase-1 (AtSUS1) by fructose and UDP-glucose

Sucrose synthase (SuSy) catalyzes the reversible conversion of sucrose and NDP into the corresponding nucleotide-sugars and fructose. The Arabidopsis genome possesses six SUS genes (AtSUS1–6) that code for proteins with SuSy activity. As a first step to investigate optimum fructose and UDP-glucose (UDPG) concentrations necessary to measure maximum sucrose-producing SuSy activity in crude extracts of Arabidopsis, in this work we performed kinetic analyses of recombinant AtSUS1 in two steps: (1) SuSy reaction at pH 7.5, and (2) chromatographic measurement of sucrose produced in step 1. These analyses revealed a typical Michaelis-Menten behavior with respect to both UDPG and fructose, with Km values of 50 μM and 25 mM, respectively. Unlike earlier studies showing the occurrence of substrate inhibition of UDP-producing AtSUS1 by fructose and UDP-glucose, these analyses also revealed no substrate inhibition of AtSUS1 at any UDPG and fructose concentration. By including 200 mM fructose and 1 mM UDPG in the SuSy reaction assay mixture, we found that sucrose-producing SuSy activity in leaves and stems of Arabidopsis were exceedingly higher than previously reported activities. Furthermore, we found that SuSy activities in organs of the sus1/sus2/sus3/sus4 mutant were ca. 80–90% of those found in WT plants.     

Carbon partitioning to cellulose synthesis

This article discusses the importance and implications of regulating carbon partitioning to cellulose synthesis, the characteristics of cells that serve as major sinks for cellulose deposition, and enzymes that participate in the conversion of supplied carbon to cellulose. Cotton fibers, which deposit almost pure cellulose into their secondary cell walls, are referred to as a primary model system. For sucrose synthase, we discuss its proposed role in channeling UDP-Glc to cellulose synthase during secondary wall deposition, its gene family, its manipulation in transgenic plants, and mechanisms that may regulate its association with sites of polysaccharide synthesis. For cellulose synthase, we discuss the organization of the gene family and how protein diversity could relate to control of carbon partitioning to cellulose synthesis. Other enzymes emphasized include UDP-Glc pyrophosphorylase and sucrose phosphate synthase. New data are included on phosphorylation of cotton fiber sucrose synthase, possible regulation by Ca²⁺ of sucrose synthase localization, electron microscopic immunolocalization of sucrose synthase in cotton fibers, and phylogenetic relationships between cellulose synthase proteins, including three new ones identified in differentiating tracheary elements of Zinnia elegans. We develop a model for metabolism related to cellulose synthesis that implicates the changing intracellular localization of sucrose synthase as a molecular switch between survival metabolism and growth and/or differentiation processes involving cellulose synthesis. Abbreviations: CesA, cellulose synthase; Csl, cellulose-like synthase (genes); DCB, dichlobenil; DPA, days after anthesis; SPS, sucrose phosphate synthase; SuSy, sucrose synthase; P-SuSy, particulate SuSy; S-SuSy, soluble SuSy     

A kinetic study of sugarcane sucrose synthase.

The kinetic data on sugarcane (Saccharum spp. hybrids) sucrose synthase (SuSy, UDP-glucose: D-fructose 2-alpha-D-glucosyltransferase, EC 2.4.1.13) are limited. We characterized kinetically a SuSy activity partially purified from sugarcane variety N19 leaf roll tissue. Primary plot analysis and product inhibition studies showed that a compulsory order ternary complex mechanism is followed, with UDP binding first and UDP-glucose dissociating last from the enzyme. Product inhibition studies showed that UDP-glucose is a competitive inhibitor with respect to UDP and a mixed inhibitor with respect to sucrose. Fructose is a mixed inhibitor with regard to both sucrose and UDP. Kinetic constants are as follows: Km values (mm, +/- SE) were, for sucrose, 35.9 +/- 2.3; for UDP, 0.00191 +/- 0.00019; for UDP-glucose, 0.234 +/- 0.025 and for fructose, 6.49 +/- 0.61. values were, for sucrose, 227 mm; for UDP, 0.086 mm; for UDP-glucose, 0.104; and for fructose, 2.23 mm. Replacing estimated kinetic parameters of SuSy in a kinetic model of sucrose accumulation with experimentally determined parameters of the partially purified isoform had significant effects on model outputs, with a 41% increase in sucrose concentration and 7.5-fold reduction in fructose the most notable. Of the metabolites included in the model, fructose concentration was most affected by changes in SuSy activity: doubling and halving of SuSy activity reduced and increased the steady-state fructose concentration by about 42 and 140%, respectively. It is concluded that different isoforms of SuSy could have significant differential effects on metabolite concentrations in vivo, therefore impacting on metabolic regulation.     

Sucrose synthase isoforms in cultured tobacco cells.

The plant enzyme sucrose synthase (SuSy; EC 2.4.1.13) catalyzes the reversible conversion of sucrose and UDP into UDP-glucose (UDP-Glc) and fructose. The enzyme exists in different isoforms and is both located in the cytosol, membrane-bound and associated to the actin cytoskeleton. We here investigate sucrose synthase from tobacco (Nicotiana tabacum L.) BY-2 heterotrophic cell suspensions. Two different isoforms of sucrose synthase SuSy1 and SuSy2, could be purified from cytosolic extracts of these cells using a combination of poly(ethylene glycol) (PEG) precipitation, gel filtration, ion-exchange chromatography and affinity chromatography. They were clearly distinct, both with regard to the binding to the ion-exchange column and with regard to their kinetic and regulatory properties. SuSy1, the more abundant species, showed lower V(max) and K(m) for sucrose and UDP compared to the less abundant SuSy2. The activity of SuSy2 in the breakdown direction was stimulated by 60% by actin, in contrast to that of SuSy1, which showed a 17% inhibition. An indication of interaction between SuSy1 and actin was obtained by partitioning in aqueous Dextran-PEG two-phase systems. Furthermore, fructose 2,6-bisphosphate (F26BP) at micromolar concentrations stimulated SuSy2 in the presence of actin while SuSy1 was strongly inhibited by fructose. Possible roles of these two isoforms in the sucrose turnover in BY-2 cells are discussed.     

Altered sucrose metabolism impacts plant biomass production and flower development

Nicotiana tabacum (tobacco) was transformed with three genes involved in sucrose metabolism, UDP-glucose pyrophosphorylase (UGPase, EC 2.7.7.9), sucrose synthase (SuSy, EC 2.4.1.13) and sucrose phosphate synthase (SPS, EC 2.4.1.14). Plants harbouring the single transgenes were subsequently crossed to produce double and triple transgenic lines, including: 2 × 35S::UGPase × SPS, 4CL::UGPase × SPS, 2 × 35S::SuSy × SPS, 4CL::SuSy × SPS, 2 × 35S::UGPase × SuSy × SPS, and 4CL::UGPase × SuSy × SPS. The ultimate aim of the study was to examine whether it is possible to alter cellulose production through the manipulation of sucrose metabolism genes. While altering sucrose metabolism using UGPase, SuSy and SPS does not have an end effect on cellulose production, their simultaneous overexpression resulted in enhanced primary growth as seen in an increase in height growth, in some cases over 50%. Furthermore, the pyramiding strategy of simultaneously altering the expression of multiple genes in combination resulted in increased time to reproductive bud formation as well as altered flower morphology and foliar stipule formation in 4CL lines. Upregulation of these sucrose metabolism genes appears to directly impact primary growth and therefore biomass production in tobacco.     

Activation of β-Glucan Synthases by Wall-Bound Purple Acid Phosphatase in Tobacco Cells

Wall-bound purple acid phosphatases have been shown to be potentially involved in the regulation of plant cell growth. The aim of this work was to further investigate the function of one of these phosphatases in tobacco (Nicotiana tabacum), NtPAP12, using transgenic cells overexpressing the enzyme. The transgenic cells exhibited a higher level of phosphatase activity in their walls. The corresponding protoplasts regenerating a cell wall exhibited a higher rate of β-glucan synthesis and cellulose deposition was increased in the walls of the transgenic cells. A higher level of plasma membrane glucan synthase activities was also measured in detergent extracts of membrane fractions from the transgenic line, while no activation of Golgi-bound glycan synthases was detected. Enzymatic hydrolysis and methylation analysis were performed on the products synthesized in vitro by the plasma membrane enzymes from the wild-type and transgenic lines extracted with digitonin and incubated with radioactive UDP-glucose. The data showed that the glucans consisted of callose and cellulose and that the amount of each glucan synthesized by the enzyme preparation from the transgenic cells was significantly higher than in the case of the wild-type cells. The demonstration that callose and cellulose synthases are activated in cells overexpressing the wall-bound phosphatase NtPAP12 suggests a regulation of these carbohydrate synthases by a phosphorylation/dephosphorylation process, as well as a role of wall-bound phosphatases in the regulation of cell wall biosynthesis.     

Golgi-localized UDP-glucose transporter is required for cell wall integrity in rice

Cell wall-related nucleotide sugar transporters (NSTs) theoretically supply the cytosolic nucleotide sugars for glycosyltransferases (GTs) to carry out ploysaccharide synthesis and modification in the Golgi apparatus. However, the regulation of cell wall synthesis by NSTs remains undescribed. Recently, we have reported the functional characterization of Oryza sativa nucleotide sugar transport (Osnst1) mutant and its corresponding gene. OsNST1/BC14 is localized in the Golgi apparatus and transports UDP-glucose. This mutant provides us with a unique opportunity for evaluation of its broad impacts on cell wall structure and components. We previously examined cell wall composition of bc14 and wild type plants. Here, the spatial distribution of these cell wall alterations was analyzed by immunolabeling approach. Analysis of the sugar yield in different cell wall fractions indicated that this mutation improves the extractability of cell wall components. Field emission scanning electron microscopy further showed that the orientation of microfibrils in bc14 is irregular when compared to that in wild type. Therefore, this UDP-glucose transporter, making substrates available for polysaccharide biosynthesis, plays a critical role in maintaining cell wall integrity.Key words: UDP-glucose transporter, Golgi apparatus, cell wall polysaccharides, xylan, riceNucleotide sugars mainly generated in cytosol are the substrates for the synthesis of cell wall polysaccharides. Supply of nucleotide sugars is thus a key level for regulation of cell wall components and structure. Mutation in MUR1, an isoform of GDP-D-mannose-4,6-dehydratase, causes reduced amount of GDP-fucose and abnormal xyloglucan structure.^1,2 Disturbance of UDP-rhamnose synthesis via the mutation in RHM2/MUM4 decreases the rhamnogalacturonan I contents in Arabidopsis seeds. Cellulose synthase catalytic subunits (CESAs) generally use cytosolic UDP-glucoses to synthesize cellulose on the plasma membrane. UDP-glucose can be produced either via the catalysis of sucrose by sucrose synthase (SuSy) or through the phosphorylation of glucose-1-phosphate by UDP-glucose pyrophosphorylase (UGPase).³ Suppression of SuSy function in cotton inhibited fiber initiation and elongation.⁴ For the synthesis of noncellulosic polysaccharides occurring inside the Golgi lumen, the cytosolic nucleotide sugars should be translocated inwards by Golgi nucleotide sugar transporters (NSTs).⁵ However, this hypothesis remains to be confirmed, although transport activities have been identified in some plant NSTs.^6–10 Altering the precursor supply may also affect the overall carbon allocation in plants. It is reasonable that substrate regulation often causes pleiotropic effects on cell wall biosynthesis and plant growth. Without genetic resources or mutants on cell wall related NST, the exact evaluation of NSTs'' impacts on cell wall structure and composition is largely delayed. Until recently, we identified a Golgi-localized transporter OsNST1 mutant in rice. This transporter has been found to supply UDP-glucose for the formation of matrix polysaccharides, thereby modulating cellulose biosynthesis.¹¹ Here, we examine these alterations of cell wall polymers at the cellular level. The orientation of cellulose microfibrils and extractability of wall polysaccharides were also compared between the mutant and wild type. All those further our understandings of the functions of NSTs and the synergetic synthesis of different polymers.     

Functional Characterization of the Rice UDP-glucose 4-epimerase 1, OsUGE1: A Potential Role in Cell Wall Carbohydrate Partitioning during Limiting Nitrogen Conditions

Plants grown under inadequate mineralized nitrogen (N) levels undergo N and carbon (C) metabolic re-programming which leads to significant changes in both soluble and insoluble carbohydrate profiles. However, relatively little information is available on the genetic factors controlling carbohydrate partitioning during adaptation to N-limitation conditions in plants. A gene encoding a uridine-diphospho-(UDP)-glucose 4-epimerase (OsUGE-1) from rice (Oryza sativa) was found to be N-responsive. We developed transgenic rice plants to constitutively over-express the OsUGE-1 gene (OsUGE1-OX1–2). The transgenic rice lines were similar in size to wild-type plants at the vegetative stage and at maturity regardless of the N-level tested. However, OsUGE1-OX lines maintained 18–24% more sucrose and 12–22% less cellulose in shoots compared to wild-type when subjected to sub-optimal N-levels. Interestingly, OsUGE1-OX lines maintained proportionally more galactose and glucose in the hemicellulosic polysaccharide profile of plants compared to wild-type plants when grown under low N. The altered cell wall C-partitioning during N-limitation in the OsUGE1-OX lines appears to be mediated by OsUGE1 via the repression of the cellulose synthesis associated genes, OsSus1, OsCesA4, 7, and 9. This relationship may implicate a novel control point for the deposition of UDP-glucose to the complex polysaccharide profiles of rice cell walls. However, a direct relationship between OsUGE1 and cell wall C-partitioning during N-limitation requires further investigation.     

Synthesis of wall glucan from sucrose by enzyme preparations from Pisum sativum

Radioactive sucrose, supplied through the cut base to Pisum sativum epicotyls, was transported to the growing apex (plumule and hook) and used there for the synthesis mainly of uridine diphosphoglucose (UDP- glucose), fructose and cell wall glucan. Enzyme extracts of the apical tissue contained sucrose synthetase activity which was freely reversible, i.e. formed UDP-glucose and fructose from sucrose (pH optimum = 6·6 for the cleavage reaction, K_m for sucrose = 63 mM). Particulate fractions of the same tissue contained a β-glucan synthetase which utilized UDP-glucose for formation of alkali-soluble and -insoluble products (pH optimum = 8·4, K_m for UDP-glucose = 1·9 mM). Values for V_max and yields of these two synthetase activities were sufficient to account for observed rates of cellulose deposition during epicotyl growth (15–25 μg/hr/epicotyl). When soluble pea enzyme was supplied with sucrose and UDP at pH 6·6 and then the preparation was supplemented with particles bearing β-glucan synthetase at pH 8·4, the glucose moiety of sucrose was converted to glucan in vitro. The results indicate that it is feasible for these synthetases to co-operate in vivo to generate β-glucan for expanding cell walls.     

Localization of sucrose synthase in wheat roots: increased in situ activity of sucrose synthase correlates with cell wall thickening by cellulose deposition under hypoxia

Sucrose synthase (SuSy; EC 2.4.1.13) plays a prominent role in O(2) deficiency and functions at a branch point, partitioning sucrose between cell wall biosynthesis and glycolysis. The cleavage of sucrose by SuSy was localized in wheat ( Triticum aestivum L. cv. Alcedo) roots subjected to 4 days of hypoxia. Increased SuSy activity was observed by in situ activity staining in the tip region and in the stele of root axes. The pattern of cellulose deposition correlated with regions of high SuSy activity. Cellulose accounted for more than 30% of root dry weight and the cellulose content increased substantially under hypoxia. The strongest accumulation of cellulose occurred in the base and mid-regions of the roots where the content rose to 163% and 182% of controls, respectively. In the root axis, cellulose deposition occurred in the endodermis and walls of pith cells. In root tips, cellulose was primarily deposited in developing xylem and phloem. The marker enzyme for O(2) shortage, pyruvate decarboxylase (EC 4.1.1.17), exhibited a 14-fold increase in the root apex, whereas in basal root tissues, which contained more aerenchyma, pyruvate decarboxylase activity was only doubled. The root apex also contained the highest concentration of sucrose and hexoses. The elevated sugar content in all root zones was partially used to synthesize cellulose for secondary wall thickening.     

Evidence that sucrose loaded into the phloem of a poplar leaf is used directly by sucrose synthase associated with various beta-glucan synthases in the stem

Sucrose (Suc) synthase (SuSy) is believed to function in channeling UDP-Glc from Suc to various beta-glucan synthases. We produced transgenic poplars (Populus alba) overexpressing a mutant form (S11E) of mung bean (Vigna radiata) SuSy, which appeared in part in the microsomal membranes of the stems. Expression of SuSy in these membranes enhanced the incorporation of radioactive Suc into cellulose, together with the metabolic recycling of fructose (Fru), when dual-labeled Suc was fed directly into the phloem of the leaf. This overexpression also enhanced the direct incorporation of the glucosyl moiety of Suc into the glucan backbone of xyloglucan and increased recycling of Fru, although the Fru recycling system for cellulose synthesis at the plasma membrane might differ from that for xyloglucan synthesis in the Golgi network. These findings suggest that some of the Suc loaded into the phloem of a poplar leaf is used directly by SuSys associated with xyloglucan and cellulose synthases in the stem. This may be a key function of SuSy because the high-energy bond between the Glc and Fru moieties of Suc is conserved and used for polysaccharide syntheses in this sink tissue.     

Sucrose Utilization via Invertase and Sucrose Synthase with Respect to Accumulation of Cellulose and Callose Synthesis in Wheat Roots under Oxygen Deficiency

The sucrose cleavage by sucrose synthase (SuSy) and neutral invertase was studied in wheat roots (Triticum aestivum L.) subjected to hypoxia or anoxia for 4 days. By in situ activity staining, increased SuSy activity was observed in the tip region and stele of root axes while the activity of invertase decreased. Cellulose content significantly increased in hypoxically treated roots. The cellulose deposition was correlated with regions of high SuSy activity, being mainly located in the pericycle and endodermis. Invertase activity was distributed along the root without clear difference between cortex and stele. Under root hypoxia, a significant increase in the structural carbohydrates, callose and especially cellulose, was shown. Increasing levels of soluble carbohydrates were partially used to synthesize cellulose for secondary wall thickening and callose to counteract the tissue injury following low-oxygen stress. Under strict anoxia, the roots were much more injured but sustained a high level of cellulose and callose while the soluble carbohydrates almost disappeared.     

Studies on sucrose synthetase. Kinetic mechanism

The kinetic properties of Helianthus tuberosus sucrose synthetase, which catalyzes the reaction UDP-glucose + fructose = UDP + sucrose, have been studied. A plot of the reciprocal initial velocity versus reciprocal substrate concentration gave a series of intersecting lines indicating a sequential mechanism. Product inhibition studies showed that UDP-glucose was competitive with UDP, whereas fructose was competitive with sucrose and uncompetitive with UDP. On the other hand, a dead-end inhibitor, salicine, was competitive with sucrose and uncompetitive with UDP. The results of initial velocity, product, and dead-end inhibition studies suggested that the addition of substrates to the enzyme follows an ordered mechanism.     

Regulation of glucose metabolism and cell wall synthesis in Avena stem segments by gibberellic Acid

Gibberellic acid (GA) stimulated both the elongation of Avena sativa stem segments and increased synthesis of cell wall material. The effects of GA on glucose metabolism, as related to cell wall synthesis, have been investigated in order to find specific events regulated by GA. GA caused a decline in the levels of glucose, glucose 6-phosphate, and fructose 6-phosphate if exogenous sugar was not supplied to the segments, whereas the hormone caused no change in the levels of glucose 6-phosphate, fructose 6-phosphate, UDP-glucose, or the adenylate energy charge if the segments were incubated in 0.1 m glucose. No GA-induced change could be demonstrated in the activities of hexokinase, phosphoglucomutase, UDP-glucose pyrophosphorylase, or polysaccharide synthetases using UDP-glucose, UDP-galactose, UDP-xylose, and UDP-arabinose as substrates. GA stimulated the activity of GDP-glucose-dependent β-glucan synthetase by 2- to 4-fold over the control. When glucan synthetase was assayed using UDP-glucose as substrate, only β-1,3-linked glucan was synthesized in vitro, whereas with GDP-glucose, only β-1,4-linked glucan was synthesized. These results suggest that one part of the mechanism by which GA stimulates cell wall synthesis concurrently with elongation in Avena stem segments may be through a stimulation of cell wall polysaccharide synthetase activity.