Biosynthesis of Glucosyl Diglycerides by Mycoplasma laidlawii Strain B

Monoglucosyl diglyceride is synthesized from 1,2-diglyceride and uridine-5'-diphosphoglucose (UDP); diglucosyl diglyceride from monoglucosyl diglyceride, and uridine-5'-diphosphoglucose by membranes of Mycoplasma laidlawii strain B. All of these enzymatic activities reside in the membrane. Membranes solubilized by detergent action or succinylation and acetone powders of membranes were inactive. Requirements for Mg(2+), UDP, and appropriate lipid acceptor were demonstrated for biosynthesis of both glycolipids. Glucose-1-phosphate plus uridine triphosphate could replace the UDP requirement. A medium of relatively high ionic strength and a critical concentration of sodium lauryl sulfate stimulated biosynthesis of the monoglucosyl diglyceride. The optimal pH for both reactions was 8.0. A specificity for 1,2-diglyceride from the homologous organism was found for optimal synthesis of the monoglucosyl diglyceride, and a specificity for monoglucosyl diglyceride was found in the case of diglucosyl diglyceride synthesis. Both reactions were specific for UDP.     

The Biosynthesis of Steryl Glucosides in Plants

Mitochondrial preparations from pea root (Pisum sativum L. var. Alaska) cauliflower inflorescence (Brassica cauliflora Gars.) and avocado inner mesocarp (Persea americana Mill. var. Fuerte), and chloroplast preparations from spinach leaf (Spinacia oleracea L. var. Bloomsdale) incorporate glucose into steryl glucoside and acylated steryl glucoside when either uridine diphosphate-glucose or uridine diphosphate-galactose is supplied as precursor. In the case of pea root mitochondria, galactosyl diglycerides are not formed from either nucleotide sugar. In the case of spinach chloroplasts only 3% of the metabolized uridine diphosphate-galactose is found as steryl glycosides. Time course experiments indicate that the steryl glucoside is the precursor of the acylated steryl glucoside. The effect of pH on the over-all reaction and analysis of the reaction products suggest that the glucosylation of the sterol has a pH optimum of 8 to 9, and the pH optimum for the acylation of the steryl glucoside is 6.5 to 7. The synthesis of steryl glucoside and acylated steryl glucoside, catalyzed by acetone powders of pea root mitochondria, is stimuated by added sitosterol and stigmasterol.     

Glycosyl fluorides can function as substrates for nucleotide phosphosugar-dependent glycosyltransferases

alpha-Galactosyl fluoride is shown to function as a substrate, in place of uridine-5'-diphosphogalactose, for the alpha-galactosyltransferase from Neisseria meningitidis. The reaction only occurs in the presence of catalytic quantities of uridine 5'-diphosphate. In the presence of galactosyl acceptors, the expected oligosaccharide product is formed in essentially quantitative yields, reaction having been performed on multi-milligram scales. In the absence of a suitable acceptor, the enzyme synthesizes uridine-5'-diphosphogalactose, as demonstrated through a coupled assay in which uridine-5'-diphosphogalactose is converted to uridine-5'-diphosphoglucuronic acid with conversion of NAD to NADH. These glycosyl fluoride substrates therefore offer the potential of an inexpensive alternative donor substrate in the synthesis of oligosaccharides as well a means of generating steady state concentrations of nucleotide diphosphate sugars for in situ use by other enzymes. Further, they should prove valuable as mechanistic probes.     

Enzymic Synthesis of Indole-3-Acetyl-1-O-β-d-Glucose : II. Metabolic Characteristics of the Enzyme

The first enzyme-catalyzed reaction leading from indole-3-acetic acid (IAA) to the myo-inositol esters of IAA is the synthesis of indole-3-acetyl-1-O-β-d-glucose from uridine-5′-diphosphoglucose (UDPG) and IAA. The reaction is catalyzed by the enzyme, UDPG-indol-3-ylacetyl glucosyl transferase (IAA-glucose-synthase). This work reports methods for the assay of the enzyme and for the extraction and partial purification of the enzyme from kernels of Zea mays sweet corn. The enzyme has an apparent molecular weight of 46,500 an isoelectric point of 5.5, and its pH optimum lies between 7.3 and 7.6. The enzyme is stable to storage at zero degrees but loses activity during column chromatographic procedures which can be restored only fractionally by addition of column eluates. The data suggest either multiple unknown cofactors or conformational changes leading to activity loss.     

Regulatory mechanisms of β-glucan synthases in bacteria, fungi, and plants

The evidence accumulated to date indicates that 1,3-β-glucan synthase (EC 2.3.1.12) and 1,4-β-glucan synthase (EC 2.4.1.12) are regulated by different effectors. Further that the same synthase has different effectors, depending upon its presence in green plants, fungi, and bacteria. Synthases from plants require divalent cations and β-linked glucosides whereas fungal enzymes require neither cations nor β-glucosides, but most require nucleoside triphosphates for activation. Two endogenous effectors have been characterized and shown to produce activation in vitro. One is 3',5'-cyclic diguanylic acid that is the activator of cellulose synthase in bacteria. The other is a β-linked glucosyl dioleoyl diglyceride from mung bean, capable of activating synthases that produce both β-(1–3) and β-(1–4) products. The results of product analysis of the β-linked glucoside activated reaction suggest that the synthesis of (1–3) and (1–4) glucosyl linkages may share a common enzyme in plants. All synthases utilize uridine 5'-diphosphoglucose (UDPG) and are associated with the plasma membrane. Efforts to solubilize the synthases from cellular fractions enriched in plasma membranes have been generally successful. The purification of the soluble enzymes, however, remains a major obstacle to the full understanding of their regulation.     

Cyclic nucleotide phosphodiesterase from wheat sprouts. Purification, properties, effect of systemic fungicides

Cyclic nucleotide phosphodiesterase from wheat sprouts was isolated and partially purified. The molecular weight of the enzyme is about 83 000. The enzyme activity sharply rises as the inhibiting factors present in the homogenate are separated. The pH optimum of the enzymatic reaction is 4,8. Divalent cations (Mg2+, Mn2+, Cu2+) within the concentration range of 1--5 mM and complexons (EDTA, EGTA) at the concentration of 1 mM do not affect the PDE activity. The temperature optimum for the reaction is 60 degrees. The enzyme hydrolyzes 3' : 5'-AMP, 3' : 5'-GMP and 2':3'-AMP. The Km value for cAMP is 4 . 10(-3) M. The enzyme activity is inhibited by chemical agents possessing the fungicide activity, the strongest effect being exerted by anylate.     

响应面法优化酶法水解大豆异黄酮糖苷

采用 Design-Expert 软件中 Central Composite Design（CCD）响应面分析方法对β-葡萄糖苷酶水解大豆异黄酮糖苷的4个主要因素（水解温度、水解时间、pH 以及加酶量）进行优化。方差分析发现,影响大豆异黄酮糖苷水解最主要的因素有温度、水解时间和 pH。对各因素进行回归拟合,得到最佳实验条件分别为：温度46．2℃,反应时间94 min,pH 5．1,酶量61单位,此时大豆异黄酮苷元含量达到0．096 g·L－1,比优化前提高了22％。     

Novel glycoside of vanillyl alcohol, 4-hydroxy-3-methoxybenzyl-α-d-glucopyranoside: study of enzymatic synthesis, in vitro digestion and antioxidant activity

Novel glucoside of physiological active vanillyl alcohol was synthesized for the first time using maltase from Saccharomyces cerevisiae as catalyst, and established its structure as 4-hydroxy-3-methoxybenzyl-α-D: -glucopyranoside. The key reaction factors for this transglucosylation reaction were optimized using response surface methodology and the highest yield so far in maltase catalyzed transglucosylation reaction was obtained. It was found out that optimum temperature of reaction was 37 °C, optimal maltose concentration was 60% (w/v), optimal pH was 6.6, and optimal concentration of vanillyl alcohol was 158 mM. Under these conditions, yield of glucoside was 90 mM with no by product formation. It was shown that this compound posses good antioxidant activity as well as stability in gastrointestinal tract. It was demonstrated that it is hydrolyzed on brush border membrane of enterocytes, so it can serve in protecting gastrointestinal system from oxidation, as well as source of anticonvulsive drug after the hydrolysis of glucoside on brush border membrane of small intestine.     

Partial Characterization of a Potassium-stimulated Adenosine Triphosphatase from the Plasma Membrane of Meristematic and Mature Soybean Root Tissue

A K⁺-stimulated adenosine triphosphatase was partially characterized in plasma membrane from meristematic and mature soybean root tissue. The substrate concentrations required for maximum enzyme activity (3 millimolar Mg·ATP) and pH optimum (6.5) were similar for both systems. Enrichment studies, performed to ensure that the membrane vesicle preparations were comparable, indicated similar purity levels at selected steps during purification. Phospholipid and sterol analyses further substantiated their similarity.     

Gene cloning,sequencing, and characterization of a family 9 endoglucanase (CelA) with an unusual pattern of activity from the thermoacidophile Alicyclobacillus acidocaldarius ATCC27009

A gene encoding a beta-1,4-glucanase (CelA) belonging to subfamily E1 of family 9 of glycoside hydrolases was cloned and sequenced from the gram-positive thermoacidophile Alicyclobacillus acidocaldarius strain ATCC27009. The translated protein contains an immunoglobulin-like domain but lacks a cellulose-binding domain. The enzyme, when overproduced in Escherichia coli and purified, displayed a temperature optimum of 70 degrees C and a pH optimum of 5.5. CelA contained one zinc and two calcium atoms. Calcium and zinc are likely to be important for temperature stability. The enzyme was most active against substrates containing beta-1,4-linked glucans (lichenan and carboxy methyl cellulose), but also exhibited activity against oat spelt xylan. A striking pattern of hydrolysis on p-nitrophenyl-glycosides was observed, with highest activity on the cellobioside derivative, some on the cellotetraoside derivative, and none on the glucoside and cellotrioside derivatives. Unmodified cellooligosaccharides were also hydrolyzed by CelA. No signal peptide for transport across the cytoplasmic membrane was detected. This, together with the substrate specificity displayed, near neutral pH optimum and irreversible inactivation at low pH, suggests a role for CelA as a cytoplasmic enzyme for the degradation of imported oligosaccharides.     

A novel variant of Thermotoga neapolitana beta-glucosidase B is an efficient catalyst for the synthesis of alkyl glucosides by transglycosylation

Alkyl glycosides are surfactants with good biodegradability and low toxicity, attractive to produce by an enzymatic method to get a well-defined product. In this paper, we report a novel thermostable variant of a family 3 beta-glucosidase to be an efficient catalyst in alkyl-glucoside forming reactions using transglycosylation with hexanol or octanol as the acceptor molecule. The enzyme has an apparent optimum for hydrolysis at 90 degrees C, which coincides with its unfolding temperature. The total activity is lower at lower temperature (60 degrees C), but the ratio of alcoholysis/hydrolysis is slightly more favourable. This ratio is however more heavily influenced by the water content and the pH. Optimal reaction conditions for hexyl glucoside synthesis from p-nitrophenyl-beta-glucopyranoside were a water/hexanol two-phase system containing 16% (v/v) water, pH 5.8, and a temperature of 60 degrees C. Under these conditions, the total initial reaction rate was 153 micromol min(-1)mg(-1) and the alcoholysis/hydrolysis ratio was 5.1. Comparing with alcoholysis/hydrolysis ratios of other beta-glycosidases, TnBgl3B can be considered to be a very promising catalyst for alkyl glucoside production.     

Destabilization of liposome membranes by the steroidal glycoalkaloid α-tomatine

The effect of the steroidal glycoalkaloid α-tomatine on the leakage of peroxidase from liposomes was studied. At pH 7.2, the optimum pH for disruption, tomatine had little effect at concentrations less than 10μM but was increasingly disruptive at concentrations of 10–100μM. Liposome destabilization was pH-dependent declining with decreasing pH until at pH 5 lysis was achieved only at tomatine concentrations of 500–1000μM. At all pH values tested (pH 5–8), tomatine caused significant disruption only if the membrane contained sterol. The extent of membrane damage was correlated with the concentration of sterol in the liposomes but not with the nature of the sterol or of the phospholipid. These findings are inconsistent with claims that surface glycosidases, which convert the glycoside to the aglycone, are prerequisites for tomatine action and that the aglycone is the active moiety.     

Steryl glucoside biosynthesis in the alga Prototheca zopfii

A particulate enzyme fraction from the Chlorophyta Prototheca zopfii catalysed the transfer of glucose-[U-¹⁴C]from UDP-Glc-[U-¹⁴C] to endogenous sterol acceptors and the esterification of steryl glucosides with fatty acids from an endogenous acyl donor. Glucose was the only sugar present, and it appeared to have the β-configuration. In the acylated derivatives the glucose-acyl linkage appeared in the C-6 position of glucose, as indicated by periodate oxidation. UDP-Glc:sterol glucosyltransferase was solubilized with detergent and purified 34-fold. The solubilized enzyme showed no specificity for the sterol but a high affinity for the sugar nucleotide UDP-Glc. Time-course incorporation into steryl glucoside (SG) and the acylderivative (ASG) indicated that SG was the precursor of ASG and that phosphatidyl ethanolamine stimulated the formation of the latter compound, presumably acting as acyl donor. A high sterol glucosylating activity was found in the Golgirich fraction. All this evidence indicates that steryl glucosides and their acylated derivatives were synthesized by algae. The early assumption that these compounds were not present in algae must be revised.     

Functions of PI4P and sterol glucoside are necessary for the synthesis of a nascent membrane structure during pexophagy

We recently showed that, in the yeast Pichia pastoris, an ergosterol glucoside synthesizing enzyme, Atg26, is recruited to the precursor of the pexophagic structure, micropexophagic membrane apparatus (MIPA), under the regulation of phosphatidylinositol 4'-monophosphate (PI4P)-signaling during pexophagy. Atg26 was found to harbor a novel PI4P-binding motif, the GRAM domain. Both lipids, PI4P and sterol glucoside, synthesized by PpPik1 and PpAtg26, respectively, were necessary for pexophagy, in the step where the MIPA was formed. In this addendum, we review these findings, and speculate on the mechanistic and physiological implications of the functions of these lipids during the autophagic process.     

Indoxyl-UDPG-glucosyltransferase from Baphicacanthus cusia

The enzyme catalyzing the transfer of glucose from uridine diphosphate glucose to indoxyl yielding the indoxyl glucoside indican was isolated from Baphicacanthus cusia Bremek (Acanthaceae). The indoxyl-uridine diphosphate glucose (UDPG)-glucosyltransferase was purified to homogeneity in six chromatographic steps. The decisive step for the recovery of a homogeneous enzyme was the application of immobilized metal affinity chromatography yielding an 863-fold purified enzyme. From a total of 60 substances tested, in addition to the natural substrate 3-OH-indole (indoxyl), only 4-OH-, 5-OH-, 6-OH-, and 7-OH-indole were accepted as substrates by the glucosyltransferase. However, the latter substrates were metabolized to varying extent. The optimum pH of the enzyme was 8.5, the optimum temperature was 30 degrees C and the isoelectric point was pH 6.5. The M(r) of the enzyme was determined to be 60 +/- 2 x 10(3). Indoxyl as substrate yielded a K(m) of 1.2 mM, while a K(m) of 1.7 mM was found for UDPG.     

Formation of benzoquinol moiety in cornoside by salidroside mono-oxygenase,a cytochrome P450 enzyme,from <Emphasis Type="Italic">Abeliophyllum distichum </Emphasis>cell suspension cultures

A microsomal fraction prepared from Abeliophyllum distichumNakai (Oleaceae) cell suspension cultures oxidized salidroside, a glucoside of 4-hydroxyphenylethyl alcohol, to cornoside possessing a unique benzoquinol ring. The enzyme named salidroside mono-oxygenase required NADPH as the only cofactor, and molecular oxygen. The reaction was strongly inhibited by CO as well as several cytochrome P450 inhibitors, such as cytochrome c and miconazole, indicating the involvement of a cytochrome P450 enzyme. Salidroside mono-oxygenase accepted salidroside as the only substrate, but did not oxidize 4-hydroxyphenylethyl alcohol, the salidroside aglucone, and 4-hydroxybenzoic acid. The optimum pH of the reaction was 7.5, and apparent K(m) values for salidroside and NADPH were 44 micro M and 33 micro M, respectively. The benzoquinol ring formation mechanism is discussed in comparison to the mechanism for ipso substitution of 4-hydroxybenzoate by active oxygen species followed by elimination leading to hydroquinone.     

UDP-Glucose: Sterol Glucosyltransferase and a Steryl Glucoside Acyltransferase Activity in Amyloplast Membranes from Potato Tubers

Envelope membranes were isolated from potato tuber amyloplastby a discontinuous sucrose density gradient and high speed centrifugation.These membranes catalyzed the transfer of [¹⁴C]glucose fromUDP-[¹⁴C]glucose to endogenous sterol acceptors and, in turn,catalyzed the esterification of steryl glucosides with fattyacids from an endogenous acyl donor. The synthesis of sterylglucosides was stimulated in the presence of Triton. X-100,while formation of acyl steryl glucosides was inhibited by thedetergent. However, in the presence of an added sterol acceptorand Triton X-100, the inhibition of acyl steryl glucoside synthesiswas overcome by the addition of phosphatidylethanolamine. Theenzyme involved in steryl glucoside formation was solubilizedby treatment of the envelope membranes with 0.3% Triton X-100.The solubilized enzyme had an almost absolute requirement forsterol acceptors. Key words: Solanum tuberosum, Sterol glucosylation, Steryl glucoside acylation, Amyloplast membrane     

Potentiometric and colorimetric methods for the assay of 2',3'-cyclic nucleotide 3'-phosphohydrolase

Abstract— A potentiometric titration method for the assay of 2′,3′-cyclic nucleotide 3′-phosphohydrolase is presented. Progress curves of the reaction were recorded automatically by pH-stat. 2-Mercaptoethanol was added to the reaction mixture to maintain a linear rate of reaction. The method is suitable for obtaining kinetic parameters and can be used for the rapid assay of 2′,3′-cyclic nucleotide 3′-phosphohydrolase in nervous tissues. An improved colorimetric method for estimation of 2′,3′-cyclic nucleotide 3′-phosphohydrolase activity at the optimum pH is described. This method employs the two-step procedure in which decyclization by 2′,3′-cyclic nucleotide 3′-phosphohydrolase and dephosphorylation by Escherichia coli alkaline phosphatase (EC 3.1.3.1) are carried out separately under the optimum conditions for each enzyme. The method is sensitive and most convenient for routine assays.     

Sterol methyltransferase: functional analysis of highly conserved residues by site-directed mutagenesis

Sterol methyltransferase (SMT), the enzyme from Saccharomyces cerevisiae that catalyzes the conversion of sterol acceptor in the presence of AdoMet to C-24 methylated sterol and AdoHcy, was analyzed for amino acid residues that contribute to C-methylation activity. Site-directed mutagenesis of nine aspartate or glutamate residues and four histidine residues to leucine (amino acids highly conserved in 16 different species) and expression of the resulting mutant proteins in Escherichia coli revealed that residues at H90, Asp125, Asp152, Glu195, and Asp276 are essential for catalytic activity. Each of the catalytically impaired mutants bound sterol, AdoMet, and 25-azalanosterol, a high energy intermediate analogue inhibitor of C-methylation activity. Changes in equilibrium binding and kinetic properties of the mutant enzymes indicated that residues required for catalytic activity are also involved in inhibitor binding. Analysis of the pH dependence of log kcat/Km for the wild-type SMT indicated a pH optimum for activity between 6 and 9. These results and data showing that only the mutant H90L binds sterol, AdoMet, and inhibitor to similar levels as the wild-type enzyme suggest that H90 may act as an acceptor in the coupled methylation-deprotonation reaction. Circular dichroism spectra and chromatographic information of the wild-type and mutant enzymes confirmed retention of the overall conformation of the enzyme during the various experiments. Taken together, our studies suggest that the SMT active center is composed of a set of acidic amino acids at positions 125, 152, 195, and 276, which contribute to initial binding of sterol and AdoMet and that the H90 residue functions subsequently in the reaction progress to promote product formation.     

Replacement of the active site tyrosine of vaccinia DNA topoisomerase by glutamate, cysteine or histidine converts the enzyme into a site-specific endonuclease.

Vaccinia topoisomerase forms a covalent protein-DNA intermediate at 5'-CCCTT downward arrow sites in duplex DNA. The T downward arrow nucleotide is linked via a 3'-phosphodiester bond to Tyr-274 of the enzyme. Here, we report that mutant enzymes containing glutamate, cysteine or histidine in lieu of Tyr-274 catalyze endonucleolytic cleavage of a 60 bp duplex DNA at the CCCTT downward arrow site to yield a 3' phosphate-terminated product. The Cys-274 mutant forms trace levels of a covalent protein-DNA complex, suggesting that the DNA cleavage reaction may proceed through a cysteinyl-phosphate intermediate. However, the His-274 and Glu-274 mutants evince no detectable accumulation of a covalent protein-DNA adduct. Glu-274 is the most active of the mutants tested. The pH dependence of the endonuclease activity of Glu-274 (optimum pH = 6.5) is distinct from that of the wild-type enzyme in hydrolysis of the covalent adduct (optimum pH = 9.5). At pH 6.5, the Glu-274 endonuclease reaction is slower by 5-6 orders of magnitude than the rate of covalent adduct formation by the wild-type topoisomerase, but is approximately 20 times faster than the rate of hydrolysis by the wild-type covalent adduct. We discuss two potential mechanisms to account for the apparent conversion of a topoisomerase into an endonuclease.