Substrate and metal ion promiscuity in mannosylglycerate synthase

The enzymatic transfer of the sugar mannose from activated sugar donors is central to the synthesis of a wide range of biologically significant polysaccharides and glycoconjugates. In addition to their importance in cellular biology, mannosyltransferases also provide model systems with which to study catalytic mechanisms of glycosyl transfer. Mannosylglycerate synthase (MGS) catalyzes the synthesis of α-mannosyl-D-glycerate using GDP-mannose as the preferred donor species, a reaction that occurs with a net retention of anomeric configuration. Past work has shown that the Rhodothermus marinus MGS, classified as a GT78 glycosyltransferase, displays a GT-A fold and performs catalysis in a metal ion-dependent manner. MGS shows very unusual metal ion dependences with Mg(2+) and Ca(2+) and, to a lesser extent, Mn(2+), Ni(2+), and Co(2+), thus facilitating catalysis. Here, we probe these dependences through kinetic and calorimetric analyses of wild-type and site-directed variants of the enzyme. Mutation of residues that interact with the guanine base of GDP are correlated with a higher k(cat) value, whereas substitution of His-217, a key component of the metal coordination site, results in a change in metal specificity to Mn(2+). Structural analyses of MGS complexes not only provide insight into metal coordination but also how lactate can function as an alternative acceptor to glycerate. These studies highlight the role of flexible loops in the active center and the subsequent coordination of the divalent metal ion as key factors in MGS catalysis and metal ion dependence. Furthermore, Tyr-220, located on a flexible loop whose conformation is likely influenced by metal binding, also plays a critical role in substrate binding.     

Glycoprotein biosynthesis: studies on thyroid mannosyltransferases. II. Characterization of a polyisoprenyl mannosyl phosphate and evaluation of its intermediary role in the glycosylation of exogenous acceptors

The transfer of mannose from GDP-mannonse to exogenous glycopeptides and simple glycosides has been shown to be carried out by calf thyroid particles (Adamany, A. M., and Spiro, R. G. (1975) J. Biol. Chem. 250, 2830-2841). The present investigation indicates that this mannosylation process is accomplished through two sequential enzymatic reactions. The first involves the transfer of mannose from the sugar nucleotide to an endogenous acceptor to form a compound which has the properties of dolichyl mannosyl phosphate, while in the properties of dolichyl mannosyl phosphate, while in the second reaction this mannolipid serves as the glycosyl donor to exogenous acceptors. The particle-bound enzyme which catalyzed the first reaction utilized GDP-mannose (Km = 0.29 microM) as the most effective mannosyl donor, required a divalent cation, preferably manganese or calcium, and acted optimally at pH 6.3. Mannolipid synthesis was reversed by addition of GDP and a ready exchange of the mannose moiety was observed between [14C]mannolipid and unlabeled GDP-mannose. Exogenously supplied dolichyl phosphate, and to a lesser extent ficaprenyl phosphate, served as acceptors for the transfer reaction. The 14C-labeled endogenous lipid had the same chromatographic behavior as synthetic dolichyl mannosyl phosphate and enzymatically mannosylated dolichyl phosphate. The mannose component in the endogenous lipid was not susceptible to reduction with sodium borohydride and was released by mild acid hydrolysis. Alkaline treatment of the mannolipid released a phosphorylated mannose with properties consistent with that of mannose 2-phosphate. The formation of this compound which can arise from a cyclic 1,2-phosphate indicated, on the basis of steric considerations, that the mannose is present in beta linkage to the phosphate of the lipid. An intermediate role of the mannolipid in the glycosylation of exogenous acceptors was suggested by the observation that addition of dolichyl phosphate to thyroid particles resulted in a marked enhancement of mannose transfer from GDP-mannose to methyl-alpha-D-mannopyranoside acceptor while the presence of the glycoside caused a decrease in the mannolipid level. The glycosyl donor function of the polyisoprenyl mannosyl phosphate in the second reaction of the mannosylation sequence could be directly demonstrated by the transfer of [14C]mannose from purified endogenous mannolipid to either methyl-alpha-D-mannoside or dinitrophenyl unit A glycopeptides by thyroid enzyme in the presence of Triton X-100. The mannosylation of the glycoside was not inhibited by EDTA whereas the transfer of mannose to glycopeptide was cation-dependent. While dolichyl [14C]mannosyl phosphate, prepared from exogenous dolichyl phosphate, served as a donor of mannose to exogenous acceptor, this function could not be fulfilled by ficaprenyl [14C]mannosyl phosphate. The two-step reaction sequence carried out by thyroid enzymes which leads to the formation of an alpha-D-manno-pyranosyl-D-mannose linkage in exogenous acceptors by transfer of mannose from GDP-mannose through a beta-linked intermediate appears to involve a double inversion of anomeric configuration of this sugar.     

Relationship between lipogenesis and glycogen synthesis in maternal and foetal tissues during late gestation in the rat. Effect of dexamethasone.

We investigated whether the polyenic and allylic phosphate systems of retinyl phosphate are essential for its mannosyl acceptor and donor activities in rat liver postnuclear membranes. Perhydromonoeneretinyl phosphate, a compound without growth-promoting activity in vitamin A-deficient animals, was prepared by catalytic hydrogenation of retinol and phosphorylation. Perhydromonoeneretinyl phosphate mannose synthesis from GDP-mannose showed continued accumulation for at least 60 min, while retinyl phosphate mannose synthesis showed a maximum at 20-30 min and then declined. Moreover, only retinyl phosphate stimulated transfer of mannose from GDP-mannose to endogenous proteins, which were separated by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. Thus, hydrogenation of side-chain double bonds in retinyl phosphate impaired only slightly its mannosyl acceptor activity, but caused loss of mannosyl donor activity.     

Aggregation state of melittin in lipid vesicle membranes

We have performed time-resolved fluorescence energy transfer measurements using melittin as donor and a modified melittin as acceptor. The melittin molecules were bound to fluid vesicle membranes of dimyristoylphosphatidylcholine. Analysis of the temporal decay of the energy transfer and of its variation with the donor and acceptor concentrations led to the conclusion that melittin in fluid membranes is usually monomeric. Only at the high melittin/lipid molar ratio of 1/200 and high ionic strength evidence for aggregation was obtained, the percentage of aggregated melittin molecules being of the order of 10%. The shortcomings of previous steady-state measurements of fluorescence energy transfer between melittin molecules are discussed.     

Structural changes of yellow Cameleon domains observed by quantitative FRET analysis and polarized fluorescence correlation spectroscopy

Förster resonance energy transfer (FRET) is a widely used method for monitoring interactions between or within biological macromolecules conjugated with suitable donor-acceptor pairs. Donor fluorescence lifetimes in absence and presence of acceptor molecules are often measured for the observation of FRET. However, these lifetimes may originate from interacting and noninteracting molecules, which hampers quantitative interpretation of FRET data. We describe a methodology for the detection of FRET that monitors the rise time of acceptor fluorescence on donor excitation thereby detecting only those molecules undergoing FRET. The large advantage of this method, as compared to donor fluorescence quenching method used more commonly, is that the transfer rate of FRET can be determined accurately even in cases where the FRET efficiencies approach 100% yielding highly quenched donor fluorescence. Subsequently, the relative orientation between donor and acceptor chromophores is obtained from time-dependent fluorescence anisotropy measurements carried out under identical conditions of donor excitation and acceptor detection. The FRET based calcium sensor Yellow Cameleon 3.60 (YC3.60) was used because it changes its conformation on calcium binding, thereby increasing the FRET efficiency. After mapping distances and orientation angles between the FRET moieties in YC3.60, cartoon models of this FRET sensor with and without calcium could be created. Independent support for these representations came from experiments where the hydrodynamic properties of YC3.60 under ensemble and single-molecule conditions on selective excitation of the acceptor were determined. From rotational diffusion times as found by fluorescence correlation spectroscopy and consistently by fluorescence anisotropy decay analysis it could be concluded that the open structure (without calcium) is flexible as opposed to the rather rigid closed conformation. The combination of two independent methods gives consistent results and presents a rapid and specific methodology to analyze structural and dynamical changes in a protein on ligand binding.     

Aglycone specificity of Escherichia coli alpha-xylosidase investigated by transxylosylation

The specificity of the aglycone-binding site of Escherichia coli alpha-xylosidase (YicI), which belongs to glycoside hydrolase family 31, was characterized by examining the enzyme's transxylosylation-catalyzing property. Acceptor specificity and regioselectivity were investigated using various sugars as acceptor substrates and alpha-xylosyl fluoride as the donor substrate. Comparison of the rate of formation of the glycosyl-enzyme intermediate and the transfer product yield using various acceptor substrates showed that glucose is the best complementary acceptor at the aglycone-binding site. YicI preferred aldopyranosyl sugars with an equatorial 4-OH as the acceptor substrate, such as glucose, mannose, and allose, resulting in transfer products. This observation suggests that 4-OH in the acceptor sugar ring made an essential contribution to transxylosylation catalysis. Fructose was also acceptable in the aglycone-binding site, producing two regioisomer transfer products. The percentage yields of transxylosylation products from glucose, mannose, fructose, and allose were 57, 44, 27, and 21%, respectively. The disaccharide transfer products formed by YicI, alpha-D-Xylp-(1-->6)-D-Manp, alpha-D-Xylp-(1-->6)-D-Fruf, and alpha-d-Xylp-(1-->3)-D-Frup, are novel oligosaccharides that have not been reported previously. In the transxylosylation to cello-oligosaccharides, YicI transferred a xylosyl moiety exclusively to a nonreducing terminal glucose residue by alpha-1,6-xylosidic linkages. Of the transxylosylation products, alpha-d-Xylp-(1-->6)-D-Manp and alpha-d-Xylp-(1-->6)-D-Fruf inhibited intestinal alpha-glucosidases.     

NMR spectroscopic and molecular modeling investigations of the trans-sialidase from Trypanosoma cruzi

Nuclear magnetic resonance (NMR) spectroscopy was used to investigate the transfer of sialic acid from a range of sialic acid donor compounds to acceptor molecules, catalyzed by Trypanosoma cruzi trans-sialidase (TcTS). We demonstrate here that NMR spectroscopy is a powerful tool to monitor the trans-sialidase enzyme reaction for a variety of donor and acceptor molecules. The hydrolysis or transfer reactions that are catalyzed by TcTS were also investigated using a range of N-acetylneuraminosyl-based donor substrates and asialo acceptor molecules. These studies showed that the synthetic N-acetylneuraminosyl donor 4-methylumbelliferyl alpha-d-N-acetylneuraminide (MUN) is hydrolyzed by the enzyme approximately 3-5 times faster than either the disaccharide Neu5Acalpha(2,3)Galbeta1Me or the trisaccharide Neu5Acalpha(2,3)Lacbeta1Me. In the transfer reaction, we show that Neu5Acalpha(2,3)Lacbeta1Me is the most favorable substrate for TcTS and is a better substrate than the naturally-occurring N-acetylneuraminosyl donor alpha1-acid glycoprotein. In the case of MUN as the donor molecule, the transfer of Neu5Ac to different acceptors is significantly slower than when other N-acetylneuraminosyl donors are used. We hypothesize that when MUN is bound by the enzyme, the orientation and steric bulk of the umbelliferyl aglycon moiety may restrict the access for the correct positioning of an acceptor molecule. AutoDock studies support our hypothesis and show that the umbelliferyl aglycon moiety undergoes a strong pi-stacking interaction with Trp-312. The binding properties of TcTS towards acceptor (lactose) and donor substrate (Neu5Ac) molecules have also been investigated using saturation transfer difference (STD) NMR experiments. These experiments, taken together with other published data, have clearly demonstrated that lactose in the absence of other coligands does not bind to the TcTS active site or other binding domains. However, in the presence of the sialic acid donor, lactose (an asialo acceptor) was observed by NMR spectroscopy to interact with the enzyme's active site. The association of the asialo acceptor with the active site is an absolute requirement for the transfer reaction to proceed.     

Inhibition of lipid-linked oligosaccharide synthesis by aryl phosphates.

Our previous work has shown that phenyl phosphate acts as an exogenous substrate for GDP-mannose:dolichyl phosphate mannosyltransferase in rat liver microsomal fractions to give rise to phenyl phosphate beta-D-mannose, a compound which, unlike Dol-P-Man (dolichyl phosphate beta-D-mannose), cannot act as mannose donor for further mannose-adding reactions in microsomal fractions. The study has now been extended to the action of various aryl phosphates and structurally related compounds on several other glycosyltransferase systems in the microsomal fractions. (1) Examination of the ability of these compounds to accept sugars from various sugar nucleotides indicated that the individual compounds have specificity as sugar acceptors. Thus phenyl phosphate acted as an effective acceptor for both mannose and glucose, whereas benzenephosphonic acid was active only in accepting mannose. p-Nitrophenyl phosphate was a more effective glucose acceptor than phenyl phosphate, but had only 8% of the mannose-accepting activity of phenyl phosphate. (2) Phenyl phosphate had an inhibitory effect on the transfer of mannose form GDP-mannose to lipid-linked oligosaccharides and to glycoproteins in rat liver microsomal fractions. The inhibition depended on the concentration of phenyl phosphate and on the extent of inhibition of Dol-P-Man synthesis. It is proposed that phenyl phosphate has a direct effect on the synthesis of Dol-P-Man and that its inhibition of synthesis of lipid-linked oligosaccharides and glycoproteins could be a consequence of this effect.     

Enzymatic synthesis of 2-O-alpha-D-mannopyranosyl-methyl-alpha-D-mannopyranoside by a cell-free particulate system of Mycobacterium smegmatis.

A cell-free particulate enzyme preparation of Mycobacterium smegmatis ATCC 607 catalyzed the transfer of labeled mannose from GDP[14C] mannose to methyl-alpha-D-mannopyranoside (an exogenously added acceptor) to form a product that was characterized to be 2-O-alpha-D[14C] mannopyranosyl-methyl-alpha-D-mannopyranoside. This transmannosylase activity was specific for both the sugar nucleotide donor and methyl monosaccharide acceptor. The reaction was stimulated by the addition of various metal ions and had a pH optimum of 6.0. The apparent Km of this transmannosylase reaction for methyl-alpha-D-mannopyranoside was 35 mM. The possible relationship between this "artificial" mannosyl-transfer system and the "natural" system which leads to the formation of the oligomannosides and glycoproteins is discussed.     

Long - lasting synchrony of the division of enteric bacteria

Recent finding of α-N-acetylglucosamine(1)phospho(6)mannose diesters in lysosomal enzymes suggested that formation of mannose 6-phosphate residues involves transfer of N-acetylglucosamine 1-phosphate to mannose. Using dephosphorylated β-hexosaminidase as acceptor and [β-³²P]UDP-N-acetylglucosamine as donor for the phosphate group, phosphorylation of β-hexosaminidase by microsomes from rat liver, human placenta and human skin fibroblasts was achieved. The reaction was not affected by tunicamycin. Acid hydrolysis released mannose 6-[³²P]phosphate from the phosphorylated β-hexosaminidase. Our results suggest that lysosomal enzymes are phosphorylated by transfer of N-acetylglucosamine 1-phosphate from UDP-N-acetylglucosamine. The transferase activity was deficient in fibroblasts from patients affected with l-cell disease. This deficiency is proposed to be the primary enzyme defect in l-cell disease.     

Fluorescence coupling across lipid bilayer membranes

Summary An energy transfer between donor and acceptor fluorophores across single lipid bilayer membranes is demonstrated. Anilino-naphthalene sulfonate is used as the donor chromophore: its fluorescence is enhanced by the presence of lipid and thus indicates association with the purely lipid membranes of our preparation of vesicles in suspension. Light emit ted by the donor molecules excites fluorescence of acriflavine, a suitable acceptor enclosed inside the vesicles. Absorption and fluorescence spectra of this system, in its components and as a whole, are presented in evidence for an energy transfer.Supported by a grant from the Medical Research Council of Canada. The results of this work were presented, in part, at the 17th Annual Meeting of the Biophysical Society, February 27–March 2, 1973, Columbus, Ohio.Scholar of the Medical Research Council of Canada.     

Role of mannosyl lipid intermediate in the synthesis of Neurospora crassa glycoproteins.

Particulate membrane preparations from Neurospora crassa incorporated mannose from GDP-[14C] mannose into endogenous lipid and particulate protein acceptors. Synthesis of the mannosyl lipid is reversible in the presence of GDP. Chemical and chromatographic characterization of the mannosyl lipid suggest that it is a mannosylphosphorylpolyisoprenol. The other endogenous acceptor was precipitated by trichloracetic acid. Gel filtration and electrophoresis studies before and after treatment with proteolytic enzymes indicate that the second acceptor is a glycoprotein(s). beta Elimination studies on the mannosyl protein formed from GDP-[14C] mannose with Mg2+ in the reaction mixture or formed from mannosyl lipid indicate thad with the peptide chain. Several lines of evidence indicate that in Neurospora crassa the mannosyl lipid is an obligatory intermediate in the in vitro mannosylation of the protein. (a) At 15 degrees C the initial formation of the mannosyl lipid is faster than the initial formation of the mannosyl protein. (b) Exogenous partially purified mannosyl lipid can function as a mannosyl donor for the synthesis of the mannosyl protein. This reaction was also dependent on a divalent metal. The rate of this reaction was optimal at a concentration of Triton X-100 which effectively inhibited the transfer of mannose from GDP-[14C] mannose to lipid and protein, indicating that GDP-mannose was not an intermediate in the transfer of mannose from lipid to protein. The mannosyl protein formed in this reaction was indistinguishable by several criteria from the mannosyl protein formed from GDP-[14C] mannose and Mg2+. (c) The effect of a chase with an excess of unlabeled GDP-mannose on the incorporation of mannose into endogenous acceptors was immediate cessation of the synthesis and subsequent turnover of the mannosyl lipid; in contrast, however, incorporation of mannose into protein continued and was proportional to the loss of mannose from the mannosyl lipid.     

Fluorescence energy transfer between Ca2+ transport ATPase molecules in artificial membranes.

The purified ATPase of sarcoplasmic reticulum was covalently labeled with N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine (1,5-IAEDANS) or with iodoacetamidofluorescein (IAF). In reconstituted vesicles containing both types of ATPase molecules fluorescence energy transfer was observed from the IAEDANS (donor) to the IAF (acceptor) fluorophore as determined by the ratio of donor and acceptor fluorescence intensities, and by nanosecond decay measurements of donor fluorescence in the presence or absence of the acceptor. The observed energy transfer may arise by random collisions between ATPase molecules due to Brownian motion or by formation of complexes containing several ATPase molecules. Experimental distinction between these two models of energy transfer is possible based on predictions derived from mathematical models. Up to tenfold dilution of the lipid phase of reconstituted vesicles with egg lecithin had no measurable effect upon the energy transfer, suggesting that random collision between ATPase molecules in the lipid phase is not the principal cause of the observed effect. Addition of unlabeled ATPase in five- to tenfold molar excess over the labeled molecules abolished energy transfer. These observations together with electron microscopic and chemical cross-linking studies support the existence of ATPase oligomers in the membrane with sufficiently long lifetimes for energy transfer to occur. A hypothetical equilibrium between monomeric and tetrameric forms of the ATPase governed by the membrane potential is proposed as the structural basis of the regulation of Ca uptake and release by sarcoplasmic reticulum membranes during muscle contraction and relaxation.     

Structure of Kre2p/Mnt1p: a yeast alpha1,2-mannosyltransferase involved in mannoprotein biosynthesis

Kre2p/Mnt1p is a Golgi alpha1,2-mannosyltransferase involved in the biosynthesis of Saccharomyces cerevisiae cell wall glycoproteins. The protein belongs to glycosyltransferase family 15, a member of which has been implicated in virulence of Candida albicans. We present the 2.0 A crystal structures of the catalytic domain of Kre2p/Mnt1p and its binary and ternary complexes with GDP/Mn(2+) and GDP/Mn(2+)/acceptor methyl-alpha-mannoside. The protein has a mixed alpha/beta fold similar to the glycosyltransferase-A (GT-A) fold. Although the GDP-mannose donor was used in the crystallization experiments and the GDP moiety is bound tightly to the active site, the mannose is not visible in the electron density. The manganese is coordinated by a modified DXD motif (EPD), with only the first glutamate involved in a direct interaction. The position of the donor mannose was modeled using the binary and ternary complexes of other GT-A enzymes. The C1" of the modeled donor mannose is within hydrogen-bonding distance of both the hydroxyl of Tyr(220) and the O2 of the acceptor mannose. The O2 of the acceptor mannose is also within hydrogen bond distance of the hydroxyl of Tyr(220). The structures, modeling, site-directed mutagenesis, and kinetic analysis suggest two possible catalytic mechanisms. Either a double-displacement mechanism with the hydroxyl of Tyr(220) as the potential nucleophile or alternatively, an S(N)i-like mechanism with Tyr(220) positioning the substrates for catalysis. The importance of Tyr(220) in both mechanisms is highlighted by a 3000-fold reduction in k(cat) in the Y220F mutant.     

A rigorous experimental framework for detecting protein oligomerization using bioluminescence resonance energy transfer

Bioluminescence resonance energy transfer (BRET), which relies on nonradiative energy transfer between luciferase-coupled donors and GFP-coupled acceptors, is emerging as a useful tool for analyzing the quaternary structures of cell-surface molecules. Conventional BRET analyses are generally done at maximal expression levels and single acceptor/donor ratios. We show that under these conditions substantial energy transfer arises from random interactions within the membrane. The dependence of BRET efficiency on acceptor/donor ratio at fixed surface density, or expression level at a defined acceptor/donor ratio, can nevertheless be used to correctly distinguish between well-characterized monomeric and oligomeric proteins, including a very weak dimer. The pitfalls associated with the nonrigorous treatment of BRET data are illustrated for the case of G protein-coupled receptors (GPCRs) proposed to form homophilic and/or mixed oligomers on the basis of previous, conventional BRET experiments.     

Fluorescence resonance energy transfer-based stoichiometry in living cells

Imaging of fluorescence resonance energy transfer (FRET) between fluorescently labeled molecules can measure the timing and location of intermolecular interactions inside living cells. Present microscopic methods measure FRET in arbitrary units, and cannot discriminate FRET efficiency and the fractions of donor and acceptor in complex. Here we describe a stoichiometric method that uses three microscopic fluorescence images to measure FRET efficiency, the relative concentrations of donor and acceptor, and the fractions of donor and acceptor in complex in living cells. FRET stoichiometry derives from the concept that specific donor-acceptor complexes will give rise to a characteristic FRET efficiency, which, if measured, can allow stoichiometric discrimination of interacting components. A first equation determines FRET efficiency and the fraction of acceptor molecules in complex with donor. A second equation determines the fraction of donor molecules in complex by estimating the donor fluorescence lost due to energy transfer. This eliminates the need for acceptor photobleaching to determine total donor concentrations and allows for repeated measurements from the same cell. A third equation obtains the ratio of total acceptor to total donor molecules. The theory and method were confirmed by microscopic measurements of fluorescence from cyan fluorescent protein (CFP), citrine, and linked CFP-Citrine fusion protein, in solutions and inside cells. Together, the methods derived from these equations allow sensitive, rapid, and repeatable detection of donor-, acceptor-, and donor-acceptor complex stoichiometry at each pixel in an image. By accurately imaging molecular interactions, FRET stoichiometry opens new areas for quantitative study of intracellular molecular networks.     

Dolichyl monophosphate and its sugar derivatives in plants.

A glucose acceptor was isolated from soya beans by extraction with chloroform/methanol (2:1, v/v), followed by DEAE-cellulose column chromatography of the extract. This acceptor could not be distinguished from liver dolichyl monophosphate by t.l.c. It could replace dolichyl monophosphate as a mannose acceptor with a liver enzyme and its glucosylated derivative could replace dolichyl monophosphate glucose as a glucose donor in the same system. These results, together with those already reported [Pont Lezica, Brett, Romero Martinez & Dankert (1975) Biochem, Biophys. Res. Commun. 66, 980-987], indicate that the acceptor from soya bean is a dolichyl monophosphate. Gel filtration of its glucosylated derivative on Sephadex G-75 in the presence of sodium deoxycholate indicated that the acceptor contained 17 or 18 isoprene units. An enzyme preparation from pea seedlings was shown to use endogenous acceptors to form lipid phosphate sugars containing mannose and N-acetylglucosamine from GDP-mannose and UDP-N-acetylglucosamine. Chromatographic and degradative techniques indicated that the compounds formed were lipid monophosphate mannose, lipid pyrophosphate N-acetylglucosamine, lipid pyrophosphate chitobiose and a series of lipid pyrophosphate oligosaccharides containing both mannose and N-acetylglucosamine. None of these compounds was degraded by catalytic hydrogenation, and so the lipid moiety in each case was probably an alpha-saturated polyprenol. The endogenous acceptors for mannose and N-acetylglucosamine in peas may therefore be dolichyl monophosphate, as has been found in mammalian systems.     

Engineering resonance energy transfer for advanced immunoassays: the case of celiac disease

Celiac disease (CD) is an immune-mediated disorder affecting genetically predisposed subjects. It is caused by the ingestion of wheat gluten and related prolamins. A final diagnosis for this disease can be obtained by examination of jejunal biopsies. Nevertheless, different analytical approaches have been established to detect the presence of anti-tissue transglutaminase antibodies that represent a serological hallmark of the disease. In this work, we explored a new method for the diagnosis of CD based on the detection of serum anti-transglutaminase antibodies by resonance energy transfer (RET) between donor molecules and acceptor molecules. In particular, we labeled the liver transglutaminase (tTG) enzyme from guinea pig and the rabbit anti-tTG antibodies with a couple of fluorescence probes that are able to make RET if they are located within with Förster distance. We labeled tTG with the fluorescence probe DyLight 594 as donor and the anti-tTG antibodies with the fluorescence probe DyLight 649 as acceptor. However, due to the large size of the formed complex (tTG/anti-tTG), and consequently to the low efficiency energy transfer process between the donor–acceptor molecules, we explored a new experimental approach that allows us to extend the utilizable range of RET between donor:acceptor pairs by using one single molecule as donor and multiple molecules as energy acceptors, instead of using a single acceptor molecule as usually occurs in RET experiments. The obtained results clearly show that the use of one donor and multiacceptor strategy enables for a simple and rapid detection of serum anti-transglutaminase antibodies. In addition, our results point out that it is possible to consider this approach as a new method for a wide variety of analytical assays.     

Glycoprotein biosynthesis: studies on thyroid mannosyltransferases. I. Action on glycopeptides and simple glycosides.

A particulate fraction from calf thyroid catalyzes the transfer of mannose from GDP-mannose to exogenous glycopeptides and methyl or aryl glycosides to form alpha-D-mannopyranosyl-D-mannose sequences. The transfer to the simple glycosides required a single nonreducing mannose residue linked to a lipophilic aglycone. Thus p-nitrophenyl-, 4-methylumbelliferyl-, phenyl- and methyl-alpha-D-mannopyranosides were effective acceptors while free mannose and glycosides of several other sugars were totally inactive. The Km value for methyl-alpha-D-mannopyranoside was 2.6 mM. Specificity for the anomeric configuration of the acceptor was glycosylated to the extent of 50% of the alpha anomer and mutual inhibition between these two acceptors was observed. Acetolysis or mild acid hydrolysis of the 14C-labeled products from the glycoside acceptors yielded the disaccharide, 2-O-alpha-D-mannopyranosyl-D-mannose, which represents the predominant linkage between mannose residues in the carbohydrate unit A of thyroglobulin. Glycopeptides with mannose sequences served as acceptors for the transfer reaction but only after dinitrophenylation of their peptide portion. The unit A glycopeptides of thyroglobulin with 10 mannose residues (Km equals 0.89 mM) were much better acceptors than glycopeptides containing the core portion of unit B which contains only three mannose components. Reduction in size of unit A glycopeptide acceptors by timed alpha-mannosidase treatment resulted in a progressive decrease in activity. Peptide-free unit A was inactive even after it was modified to carry dinitrophenyl groups on its glucosamine residues. GDP-mannose was the most effective glycosyl donor, with a Km value of 1.4 muM for methyl-alpha-D-mannopyranoside and 0.30 muM for dinitrophenyl unit A glycopeptides, although ADP- and UDP-mannose could substitute to the extent of 40 to 45%. The mannose transfer to the glycopeptides had a optimum of 6.3 while that to the simple glycopeptides was best at pH 7.0. Both types of transfer reactions required a divalent cation with manganese serving most effectively in that capacity. Mannoslytransferase activity for both groups of acceptors was found predominantly in particulate subcellular fractions. A number of aromatic compounds and reagents which are disruptive of membrane integrity caused loss of enzyme activity presumably by interfering with the function of the lipophilic substituents on the various acceptors.     

Preliminary 1H NMR investigation of sialic acid transfer by the trans-sialidase from Trypanosoma cruzi

¹H NMR spectroscopy has been used to investigate the transfer of sialic acid from sialic acid donor molecules to acceptor molecules using the trans-sialidase from Typanosoma cruzi. It is clearly demonstrated that NMR spectroscopy is an efficient and powerful means of monitoring the trans-sialidase promoted transfer of sialic acid from donor to acceptor.