Identification of amino acids important for substrate specificity in sucrose transporters using gene shuffling

Plant sucrose transporters (SUTs) are H(+)-coupled uptake transporters. Type I and II (SUTs) are phylogenetically related but have different substrate specificities. Type I SUTs transport sucrose, maltose, and a wide range of natural and synthetic α- and β-glucosides. Type II SUTs are more selective for sucrose and maltose. Here, we investigated the structural basis for this difference in substrate specificity. We used a novel gene shuffling method called synthetic template shuffling to introduce 62 differentially conserved amino acid residues from type I SUTs into OsSUT1, a type II SUT from rice. The OsSUT1 variants were tested for their ability to transport the fluorescent coumarin β-glucoside esculin when expressed in yeast. Fluorescent yeast cells were selected using fluorescence-activated cell sorting (FACS). Substitution of five amino acids present in type I SUTs in OsSUT1 was found to be sufficient to confer esculin uptake activity. The changes clustered in two areas of the OsSUT1 protein: in the first loop and the top of TMS2 (T80L and A86K) and in TMS5 (S220A, S221A, and T224Y). The substrate specificity of this OsSUT1 variant was almost identical to that of type I SUTs. Corresponding changes in the sugarcane type II transporter ShSUT1 also changed substrate specificity, indicating that these residues contribute to substrate specificity in type II SUTs in general.     

Cyclic acetals of 4,1',6'-trichloro-4,1',6'-trideoxy-galacto-sucrose and their conversion into methyl ether derivatives

The acid-catalysed reaction of 4,1',6'-trichloro-4,1',6'-trideoxy-galacto- sucrose (1) with 5.5 equiv. of 2-methoxypropene in N,N-dimethylformamide followed by acetylation gave 3',4'-di-O-acetyl-4,1',6'-trichloro-4,1',6'-trideoxy-2,3-O- isopropylidene-6-O-(1-methoxy-1-methylethyl)-galacto-sucrose (2, 2%), 6,3',4'- tri- O-acetyl-4,1',6'-trichloro-4,1',6'-trideoxy-2,3-O-isopropylidene-galacto -sucrose (3, 31%), 3',4'-di-O-acetyl-4,1',6'-trichloro-4,1',6'-trideoxy-2,3-O- isopropylidene- galacto-sucrose (4, 38%), 3'-O-acetyl-4,1',6'-trichloro-4,1',6'-trideoxy-2,3-O- isopropylidene- galacto-sucrose (5, 13%), and 2,3',4'-tri-O-acetyl-4,1',6'-trichloro- 4,1',6'-trideoxy-galacto-sucrose (6, 13%). Methylation of 4 followed by removal of the protecting groups gave 4,1',6'-trichloro-4,1',6'-trideoxy-6-O-methyl- galacto- sucrose (8). 4,1',6'-Trichloro-4,1',6'-trideoxy-3-O-methyl-galacto-sucrose (11) was synthesised from 6 by preferential tert-butyldiphenylsilylation of HO-6 followed by methylation and removal of the protecting groups. Likewise, 4,1',6'-trichloro- 4,1',6'-trideoxy-4'-O-methyl-galacto-sucrose (14) was synthesised from 5. Treatment of 3 with aqueous acetic acid followed by methylation and removal of the protecting groups afforded 4,1',6'-trichloro-4,1'6'-trideoxy-2,3-di-O-methyl- galacto-sucrose (17).     

Biocatalytic synthesis of disaccharide high-intensity sweeterner sucralose via a tetrachlororaffinose intermediate

A second high-yielding bioorganic synthesis of the highintensity sweetener sucralose (4,1',6'-trichloro-4,1',6'-trideoxygalactosucrose) is described. This procedure involves the chemical chlorination of raffinose to form a novel tetrachloroaffinose intermediate (6,4',1',6'-tetrachloro-6,4',1',6'-tetradeoxygalactoraffinose; TCR) followed by the enzymic hydrolysis of the alpha-1-6 glycosidic bond of TCR to give sucralose and 6-chlorogalactose. Commercial enzyme preparations and microorganisms were screened to select alpha-galactosidases which have high catalytic activity on this compound. The most active enzyme was produced by a strain of Mortierella vinacea and had a maximum rate of 118 mumol sucralose/g dry weight cells/h, which was approximately 5% of the activity toward raffinose, and a K(m) of 5.8 mM toward TCR. The enzyme could be used in the form of mycelial pellets in a continuous packed bed column reactor. The reaction was also studied in a water-immiscible hydrophilic organic solvent, such as methyl isobutyl ketone, to overcome the poor aqueous solubility of TCR and to increase volumetric productivity. Synthesis of raffinose was achieved from saturated aqueous solutions of galactose and sucrose using a selected alpha-galactosidase from Aspergillus niger. When raffinose is used as a starting material for sucralose synthesis, this route has fewer steps than either the preceeding method using glucose-6-acetate as an intermediate or the complete chemical synthesis from sucrose. The relative merits of the two bioorganic routes and the utility of such methods to synthesize new sugars are discussed.     

Sucrose partitioning between vascular bundles and storage parenchyma in the sugarcane stem: a potential role for the ShSUT1 sucrose transporter

A transporter with homology to the SUT/SUC family of plant sucrose transporters was isolated from a sugarcane (Saccharum hybrid) stem cDNA library. The gene, designated ShSUT1, encodes a protein of 517 amino acids, including 12 predicted membrane-spanning domains and a large central cytoplasmic loop. ShSUT1 was demonstrated to be a functional sucrose transporter by expression in yeast. The estimated K_m for sucrose of the ShSUT1 transporter was 2 mM at pH 5.5. ShSUT1 was expressed predominantly in mature leaves of sugarcane that were exporting sucrose and in stem internodes that were actively accumulating sucrose. Immunolocalization with a ShSUT1-specific antiserum identified the protein in cells at the periphery of the vascular bundles in the stem. These cells became lignified and suberized as stem development proceeded, forming a barrier to apoplasmic solute movement. However, the movement of the tracer dye, carboxyfluorescein from phloem to storage parenchyma cells suggested that symplasmic connections are present. ShSUT1 may have a role in partitioning of sucrose between the vascular tissue and sites of storage in the parenchyma cells of sugarcane stem internodes.     

Functional analysis of LjSUT4, a vacuolar sucrose transporter from Lotus japonicus

Sucrose transporters in the SUT family are important for phloem loading and sucrose uptake into sink tissues. The recent localization of type III SUTs AtSUT4 and HvSUT2 to the vacuole membrane suggests that SUTs also function in vacuolar sucrose transport. The transport mechanism of type III SUTs has not been analyzed in detail. LjSUT4, a type III sucrose transporter homolog from Lotus japonicus, is expressed in nodules and its transport activity has not been previously investigated. In this report, LjSUT4 was expressed in Xenopus oocytes and its transport activity assayed by two-electrode voltage clamping. LjSUT4 transported a range of glucosides including sucrose, salicin, helicin, maltose, sucralose and both alpha- and beta-linked synthetic phenyl glucosides. In contrast to other sucrose transporters, LjSUT4 did not transport the plant glucosides arbutin, fraxin and esculin. LjSUT4 showed a low affinity for sucrose (K (0.5) = 16 mM at pH 5.3). In addition to inward currents induced by sucrose, other evidence also indicated that LjSUT4 is a proton-coupled symporter: (14)C-sucrose uptake into LjSUT4-expressing oocytes was inhibited by CCCP and sucrose induced membrane depolarization in LjSUT4-expressing oocytes. A GFP-fusion of LjSUT4 localized to the vacuole membrane in Arabidopsis thaliana and in the roots and nodules of Medicago truncatula. Based on these results we propose that LjSUT4 functions in the proton-coupled uptake of sucrose and possibly other glucosides into the cytoplasm from the vacuole.     

Biological method for protection of 6-position of sucrose and its use in synthesis of disaccharide high-intensity sweetener

A general method for protecting the 6 primary hydroxyl position of sucrose is described. It involves the production of glucose-6-acetate by fermentation of glucose using a strain of Bacillus megaterium followed by conversion to sucrose-6-acetate as a kinetic product using a specially selected fructosyl transferase producted by a newly isolated strain of Bacillus subtilis. The sucrose-6-acetate was found to be more lipophilic than expected, and this property aided its purification by chromatography. Pure sucrose-6-acetate may then be chlorinated and subsequently deacetylated to give the high-intensity sweetener 4,1',6'-trichlo-4,1',6'-trideoxygalactosucrose (sucralose) in high yields. This process involves fewer steps than are required for chemical synthesis using trityl chloride and acetic anhydride. Related intensely sweet molecules which were synthesized by similar methods included 4,1',6'-trichloro, 4,1',6'-trideoxy L-arabinosucrose, and 4,1',6'-trichloro-4,6,1',6'-tetradeoxy-galactosucrose. They were obtained from xylose and 6-deoxyglucose, respectively, via the intermediates xylsucrose and 6-deoxysucrose, formed by the reaction of the fructosyl transferase on the monosaccharide acceptors.     

植物蔗糖转运蛋白的基因与功能

蔗糖是植物体内碳水化合物长距离转运的主要( 甚至唯一) 形式, 为植物生长发育提供碳架与能量。蔗糖转运蛋白(sucrose transporter, SUT)负责蔗糖的跨膜运输, 在韧皮部介导的源-库蔗糖运输, 以及库组织的蔗糖供给中起关键作用。自从菠菜中克隆到第一个SUT基因以来, 已先后有多个SUT基因的cDNA得到克隆与功能分析, 涉及34种双子叶与单子叶植物。每种植物都有一个中等规模 的SUT基因家族, 其不同成员之间具有较高的氨基酸序列同源性, 但在蔗糖吸收的动力学特性、转运底物的特异性和表达谱等方面存在差异。本文系统介绍国内外(主要是国外)在植物SUT基因的克隆、分类与进化、细胞定位与功能, 以及研究方法等方面的研究进展, 并简要介绍我们在橡胶树SUT基因研究上的初步结果。     

A novel sucrose/H+ symport system and an intracellular sucrase in Leishmania donovani

The flagellated form of pathogenic parasitic protozoa Leishmania, resides in the alimentary tract of its sandfly vector, where sucrose serves as a major nutrient source. In this study we report the presence of a sucrose transport system in Leishmania donovani promastigotes. The kinetics of sucrose uptake in promastigotes are biphasic in nature with both high affinity K(m) (K(m) of ～ 75 μM) and low affinity K(m) (K(m)～ 1.38 mM) components. By contrast the virulent amastigotes take up sucrose via a low affinity process with a K(m) of 2.5mM. The transport of sucrose into promastigotes leads to rapid intracellular acidification, as indicated by changes in the fluorescence of the pH indicator 2',7'-bis-(2-carboxyethyl)-5-(6) Carboxyfluorescein (BCECF). In experiments with right side-out plasma membrane vesicles derived from L. donovani promastigotes, an artificial pH gradient was able to drive the active accumulation of sucrose. These data are consistent with the operation of a H(+)-sucrose symporter. The symporter was shown to be independent of Na(+) and to be insensitive to cytochalasin B, to the flavonoid phloretin and to the Na(+)/K(+) ATPase inhibitor ouabain. However, the protonophore carbonylcyanide P- (trifluromethoxy) phenylhydrazone (FCCP) and a number of thiol reagents caused significant inhibition of sucrose uptake. Evidence was also obtained for the presence of a stable intracellular pool of the sucrose splitting enzyme, sucrase, in promastigote stage parasites. The results are consistent with the hypothesis that L. donovani promastigotes take up sucrose via a novel H(+)-sucrose symport system and that, on entering the cell, the sucrose is hydrolysed to its component monosaccharides by an intracellular sucrase, thereby providing an energy source for the parasites.     

Sucrose transport from source to sink seeds in rice

In many higher plants, sucrose is loaded as a major carbon photoassimiliate into the phloem apoplastically by sucrose transporters (SUTs) and unloaded in sink tissues, where it serves as a storage material, carbohydrate backbone, and energy source. In sink tissues, a proportion of sucrose molecules are converted by cell wall invertases (CINs) into hexose that is imported into cells by monosaccharide transporters (MSTs). Thus, in developing seeds, co-ordinated regulation of SUTs, CINs, and MSTs is crucial in carbon distribution. Here, we summarize current efforts on the identification of SUTs, CINs, and MSTs in rice.     

Molecular characterization and expression patterns of sucrose transport-related genes in sweet sorghum under defoliation

Sucrose is the principal form of photosynthesis products, and long-distance transport of sucrose requires sucrose transporters (SUTs) to perform loading and unloading functions. SUTs play an important role in plant growth, development and reproduction. In this study, five unique sucrose transporter (SbSUT) genes that contain full-length cDNA sequences were cloned from sweet sorghum, and these SbSUT genes were clustered into four different clades: SUT1, SUT3, SUT4 and SUT5. Heterologous expression of SbSUTs in yeast demonstrated that they were functional sucrose transporters. Tissue-specific expression profiles showed that sorghum SUT genes had different tissue-specific expression patterns, suggesting that sorghum SUT genes may play an important role in plant growth and developmental processes. After defoliation, expression patterns of SbSUT1, SbSUT2 and SbSUT4 were different in leaf sheaths, leaves and roots. Taken together, the results indicate that the above mentioned five unique sucrose transporter genes may play important roles in performing sucrose loading and unloading functions and that they exhibit different expression in response to leaf blade removal.     

高粱SUT基因家族的生物信息学分析

蔗糖转运蛋白(sucrose transporters,SUTs)属于跨膜转运蛋白,大多数参与蔗糖的吸收和转运。迄今为止,对高粱蔗糖转运蛋白知之甚少,为进一步研究高粱蔗糖转运蛋白家族(SbSUTs),本研究利用生物信息学方法对SbSUTs的6个成员(编号SbSUT1~SbSUT6)进行蛋白理化性质、基因结构、蛋白结构、同源性及系统进化树构建等分析。结果表明:SbSUTs是一种无信号肽、定位于质膜和叶绿体类囊膜上的疏水性膜蛋白;SbSUTs均具有GPH结构功能域,是高度保守的蛋白;α-螺旋和无规卷曲是主要的二级结构元件,其三级结构较为相似。本研究为探究SbSUTs蛋白家族在高粱的蔗糖吸收及转运中的功能提供理论依据。     

植物蔗糖转运蛋白的基因与功能

蔗糖是植物体内碳水化合物长距离转运的主要（甚至唯一）形式，为植物生长发育提供碳架与能量。蔗糖转运蛋白（sucrose transporter，SUT）负责蔗糖的跨膜运输，在韧皮部介导的源-库蔗糖运输，以及库组织的蔗糖供给中起关键作用。自从菠菜中克隆到第一个SUT基因以来，已先后有多个SUT基因的cDNA得到克隆与功能分析，涉及34种双子叶与单子叶植物。每种植物都有一个中等规模的SUT基因家族，其不同成员之间具有较高的氨基酸序列同源性，但在蔗糖吸收的动力学特性、转运底物的特异性和表达谱等方面存在差异。本文系统介绍国内外（主要是国外）在植物SUT基因的克隆、分类与进化、细胞定位与功能，以及研究方法等方面的研究进展，并简要介绍我们在橡胶树SUT基因研究上的初步结果。     

Purification and regulation of glucose-6-phosphate dehydrogenase from Bacillus licheniformis

d-Glucose-6-phosphate nicotinamide adenine dinucleotide phosphate (NADP) oxidoreductase (EC 1.1.1.49) from Bacillus licheniformis has been purified approximately 600-fold. The enzyme appears to be constitutive and exhibits activity with either oxidized NAD (NAD(+)) or oxidized NADP (NADP(+)) as electron acceptor. The enzyme has a pH optimum of 9.0 and has an absolute requirement for cations, either monovalent or divalent. The enzyme exhibits a K(m) of approximately 5 muM for NADP(+), 3 mM for NAD(+), and 0.2 mM for glucose-6-phosphate. Reduced NADP (NADPH) is a competitive inhibitor with respect to NADP(+) (K(m) = 10 muM). Phosphoenolpyruvate (K(m) = 1.6 mM), adenosine 5'-triphosphate (K(m) = 0.5 mM), adenosine diphosphate (K(m) = 1.5 mM), and adenosine 5'-monophosphate (K(m) = 3.0 mM) are competitive inhibitors with respect to NAD(+). The molecular weight as estimated from sucrose density centrifugation and molecular sieve chromatography is 1.1 x 10(5). Sodium dodecyl sulfate gel electrophoresis indicates that the enzyme is composed of two similar subunits of approximately 6 x 10(4) molecular weight. The intracellular levels of glucose-6-phosphate, NAD(+), and NADP(+) were measured and found to be approximately 1 mM, 0.9 mM, and 0.2 mM, respectively, during logarithmic growth. From a consideration of the substrate pool sizes and types of inhibitors, we conclude that this single constitutive enzyme may function in two roles in the cell-NADH production for energetics and NADPH production for reductive biosynthesis.     

Uptake and metabolism of sucrose by Streptococcus lactis

Transport and metabolism of sucrose in Streptococcus lactis K1 have been examined. Starved cells of S. lactis K1 grown previously on sucrose accumulated [14C]sucrose by a phosphoenolpyruvate-dependent phosphotransferase system (PTS) (sucrose-PTS; Km, 22 microM; Vmax, 191 mumol transported min-1 g of dry weight of cells-1). The product of group translocation was sucrose 6-phosphate (6-O-phosphoryl-D-glucopyranosyl-1-alpha-beta-2-D-fructofuranoside). A specific sucrose 6-phosphate hydrolase was identified which cleaved the disaccharide phosphate (Km, 0.10 mM) to glucose 6-phosphate and fructose. The enzyme did not cleave sucrose 6'-phosphate(D-glucopyranosyl-1-alpha-beta-2-D-fructofuranoside-6'-phosphate). Extracts prepared from sucrose-grown cells also contained an ATP-dependent mannofructokinase which catalyzed the conversion of fructose to fructose 6-phosphate (Km, 0.33 mM). The sucrose-PTS and sucrose 6-phosphate hydrolase activities were coordinately induced during growth on sucrose. Mannofructokinase appeared to be regulated independently of the sucrose-PTS and sucrose 6-phosphate hydrolase, since expression also occurred when S. lactis K1 was grown on non-PTS sugars. Expression of the mannofructokinase may be negatively regulated by a component (or a derivative) of the PTS.     

Structural features of the maize sus1 gene and protein.

Genomic clones, cDNA clones, and protein of the maize (Zea mays L.) Suc synthase1 (sus1) gene were isolated and sequenced. Termini (5' and 3') of the transcribed unit were identified. The SUS1 protein was purified from tissue culture cells as a phosphorylated protein. The overall structure of sus1 is virtually identical with that of the paralogous gene, shrunken1 (sh1); however, the last intron of sh1 is missing in sus1. This intron bears much sequence similarity with the adjacent exon, suggesting that the intron arose from an internal duplication. Although the placement of the other 14 introns is identical in both genes, the introns exhibit markedly greater differences in size and sequence relative to that shown by the exons. An explanation for the differential rate of divergence of exons and introns is selection pressure for gene function. Additionally, comparisons of coding regions of plant sucrose synthases show that sh1-like and sus1-like genes can be found in all monocots so far analyzed. These latter observations point to an important role played by both genes in this group of plants.     

Characterization of Na+/K+-ATPase from Xenopus laevis kidney. Preliminary results

In Xenopus laevis, the renal Na+/K+-dependent ATPase is a very important enzyme involved in osmoregulatory processes and active transport. The enzyme was obtained from a microsome fraction purified by sucrose discontinuous gradient (10%, 15%, 29.4%) ultracentrifugation after SDS treatment, and concentrated in the denser layer. The assayed biochemical parameters and their values are: 1) Km (ATP): 0.24 mM; 2) K1/2 (Na+): 20.6 mM; 3) K1/2 (K+) 1.6 mM; 4) Ki (ouabain): 0.025 micrometer; 5) optimum pH: 7.2; 6) optimum temperature:" two peaks at 37 degrees C and 45 degrees C.     

Synthesis of 4,6-dideoxysucrose, and inhibition studies of Leuconostoc and Streptococcus D-glucansucrases with deoxy and chloro derivatives of sucrose modified at carbon atoms 3, 4, and 6

Starting from sucrose, 2,3,1',3',4',6'-hexa-O-benzoyl-6-deoxy-6-iodosucrose (1) was synthesized. Reaction of 1 with sulfuryl chloride in pyridine gave 2,3,1',3',4',6'-hexa-O-benzoyl-4-chloro-4,6-dideoxy-6-iodogalactosucr ose (2). Compound 2 was treated with tributyltin hydride in toluene in the presence of a radical initiator, alpha, alpha-azobis(isobutanonitrile) (AIBN), to remove iodine and chlorine groups and give hexa-O-benzoyl-4,6-dideoxysucrose. Benzoyl groups were removed by sodium methoxide in methanol to give 4,6-dideoxysucrose. Sucrose was modified at carbon atom 3, carbon atom 4, or carbon atoms 4 and 6, and these analogs were tested as inhibitors of the D-glucansucrases (D-glucosyltransferases) of Streptococcus mutans 6715 and Leuconostoc mesenteroides B-512F. Sucrose analogs used in this study are 4-deoxysucrose and 4-chloro-4-deoxygalactosucrose with S. mutans 6715 D-glucansucrases (GTF-S and GTF-I), and 3-deoxysucrose, 4-deoxysucrose, 4-chloro-4-deoxygalactosucrose, 6-deoxysucrose, and 4,6-dideoxysucrose with L. mesenteroides B-512F D-glucansucrase. The data indicate that 3-deoxysucrose, 4-deoxysucrose, and 4-chloro-4-deoxygalactosucrose are weak noncompetitive inhibitors for B-512F dextransucrase, with Ki values of 530, 201, and 202mM respectively. For the same enzyme, 6-deoxysucrose was a strong competitive inhibitor, with Ki of 1.60mM, and 4,6-dideoxysucrose was a good competitive inhibitor, with Ki of 20.3mM. 4-Deoxysucrose was a weak noncompetitive inhibitor for both GTF-I and GTF-S, with Ki values of 672 and 608mM, respectively. 4-Chloro-4-deoxygalactosucrose was also a weak noncompetitive inhibitor for GTF-I and GTF-S with Ki values of 391 and 308mM, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)