Development of a highly sensitive,high-throughput assay for glycosyltransferases using enzyme-coupled fluorescence detection

Glycosyltransferases catalyze transfer of sugar moieties from activated donor molecules to specific acceptor molecules, forming glycosidic bonds. Identification of selective modulators of glycosyltransferases is important both to provide new tools for investigating pathophysiological roles of glycosylation reactions in cells and tissues, and as new leads in drug discovery. Here we describe a universal enzyme-coupled fluorescence assay for glycosyltransferases, based on quantification of nucleotides produced in the glycosyl transfer reaction. GDP, UDP, and CMP are phosphorylated with nucleotide kinase in the presence of excess ATP, generating ADP. Via coupled enzyme reactions involving ADP-hexokinase, glucose-6-phosphate dehydrogenase, and diaphorase, the ADP is utilized for conversion of resazurin to resorufin, which is determined by fluorescence measurement. The method was validated by comparison with an HPLC method, and employed to screen the LOPAC1280 library for inhibitors in a 384-well plate format. The assay performed well, with a Z′-factor of 0.80. We identified 12 hits for human galactosyltransferase B4GALT1 after elimination of false positives that inhibited the enzyme-coupled assay system. The assay components are all commercially available and the reagent cost is only 2 to 10 US cents per well. This method is suitable for low-cost, high-throughput assay of various glycosyltransferases and screening of glycosyltransferase modulators.     

Development of a universal glycosyltransferase assay amenable to high-throughput formats

The development of a general 1-Zn(II) nucleoside diphosphate (NDP) sensor assay for rapid evaluation of glycosyltransferase (GT) activity is described. The 1-Zn(II) NDP sensor assay offers submicromolar sensitivity, compatibility with both purified enzymes and crude cell extracts, and exquisite selectivity for NDPs over the corresponding NDP-sugars. Thus, the 1-Zn(II) NDP sensor assay is anticipated to offer broad applicability in the context of GT engineering and characterization.     

A comparison of sugar indicators enables a universal high-throughput sugar-1-phosphate nucleotidyltransferase assay

A systematic comparison of six sugar indicators for their sensitivity, specificity, cross-reactivity, and suitability in the context of crude lysates revealed para-hydroxybenzoic acid hydrazide (pHBH) to be best suited for application in a plate-based phosphatase-assisted universal sugar-1-phosphate nucleotidyltransferase assay. The addition of a general phosphatase to nucleotidyltransferase reaction aliquots enabled the conversion of remaining sugar-1-phosphate to free sugar, the concentration of which could be rapidly assessed via the pHBH assay. The assay was validated using the model glucose-1-phosphate thymidylyltransferase from Salmonella enterica (RmlA) and compared favorably with a previously reported HPLC assay. This coupled discontinuous assay is quantitative, high throughput, and robust; relies only on commercially available enzymes and reagents; does not require chromatography, specialized detectors (e.g., mass or evaporative light scattering detectors), or radioisotopes; and is capable of detecting less than 5 nmol of sugar-1-phosphate. It is anticipated that this high-throughput assay system will greatly facilitate nucleotidyltransferase mechanistic and directed evolution/engineering studies.     

A high-throughput pH indicator assay for screening glycosyltransferase saturation mutagenesis libraries

Protein engineering using directed evolution or saturation mutagenesis at hot spots is often used to improve enzyme properties such as their substrate selectivity or stability. This requires access to robust high-throughput assays to facilitate the analysis of enzyme libraries. However, relatively few studies on directed evolution or saturation mutagenesis of glycosyltransferases have been reported in part due to a lack of suitable screening methods. In the present study we report a general screening assay for glycosyltransferases that has been developed using the blood group α-(1→3)-galactosyltransferase (GTB) as a model. GTB utilizes UDP-Gal as a donor substrate and α-L-Fucp-(1→2)-β-D-Galp-O-R (H antigen) as an acceptor substrate and synthesizes the blood group B antigen α-D-Galp-(1→3)-[α-L-Fucp-(1→2)]-β-D-Galp-O-R. A closely related α-(1→3)-N-acetylgalactosaminyltransferase (GTA) uses UDP-GalNAc as a donor with the same H acceptor, yielding the A antigen α-D-Galp-NAc-(1→3)-[α-L-Fuc(1→2)]-β-D-Gal-O-R. GTA and GTB are highly homologous enzymes differing in only 4 of 354 amino acids, Arg/Gly-176, Gly/Ser-235, Leu/Met-266, and Gly/Ala-268. The screening assay is based on the color change of the pH indicator bromothymol blue when a proton is released during the transfer of Gal/GalNAc from UDP-Gal/UDP-GalNAc to the acceptor substrate. Saturation mutagenesis of GTB enzyme at M214, a hot spot adjacent to the ²¹¹DVD²¹³ metal binding motif, was performed and the resulting library was screened for increases in UDP-GalNAc transfer activity. Two novel mutants, M214G and M214S, identified by pH indicator screening, were purified and kinetically characterized. M214S and M214G both exhibited two-fold higher k_cat and specific activity than wild-type GTB for UDP-GalNAc. The results confirm the importance of residue M214 for donor enzyme specificity.     

A Structural and Biochemical Model of Processive Chitin Synthesis

Chitin synthases (CHS) produce chitin, an essential component of the fungal cell wall. The molecular mechanism of processive chitin synthesis is not understood, limiting the discovery of new inhibitors of this enzyme class. We identified the bacterial glycosyltransferase NodC as an appropriate model system to study the general structure and reaction mechanism of CHS. A high throughput screening-compatible novel assay demonstrates that a known inhibitor of fungal CHS also inhibit NodC. A structural model of NodC, on the basis of the recently published BcsA cellulose synthase structure, enabled probing of the catalytic mechanism by mutagenesis, demonstrating the essential roles of the DD and QXXRW catalytic motifs. The NodC membrane topology was mapped, validating the structural model. Together, these approaches give insight into the CHS structure and mechanism and provide a platform for the discovery of inhibitors for this antifungal target.     

A strategy for cloning glycosyltransferase genes involved in natural product biosynthesis

The soil-borne and marine gram-positive Actinomycetes are a particularly rich source of carbohydrate-containing metabolites. With the advent of molecular tools and recombinant methods applicable to Actinomycetes, it has become feasible to investigate the biosynthesis of glycosylated compounds at genetic and biochemical levels, which has finally set the basis for engineering novel natural product derivatives. Glycosyltransferases (GT) are key enzymes for the biosynthesis of many valuable natural products that contain sugar moieties and they are most important for drug engineering. So far, the direct cloning of unknown glycosyltransferase genes by polymerase chain reaction (PCR) has not been described because glycosyltransferases do not share strongly conserved amino acid regions. In this study, we report a method for cloning of novel so far unidentified glycosyltransferase genes from different Actinomycetes strain. This was achieved by designing primers after a strategy named consensus-degenerate hybrid oligonucleotide primer (CODEHOP). Using this approach, 22 novel glycosyltransferase encoding genes putatively involved in the decoration of polyketides were cloned from the genomes of 10 Actinomycetes. In addition, a phylogenetic analysis of glycosyltransferases from Actinomycetes is shown in this paper.     

Universal phosphatase-coupled glycosyltransferase assay

A nonradioactive glycosyltransferase assay is described here. This method takes advantage of specific phosphatases that can be added into glycosyltransferase reactions to quantitatively release inorganic phosphate from the leaving groups of glycosyltransferase reactions. The released phosphate group is then detected using colorimetric malachite-based reagents. Because the amount of phosphate released is directly proportional to the sugar molecule transferred in a glycosyltransferase reaction, this method can be used to obtain accurate kinetic parameters of the glycosyltransferase. The assay can be performed in multiwell plates and quantitated by a plate reader, thus making it amenable to high-throughput screening. It has been successfully applied to all glycosyltransferases available to us, including glucosyltransferases, N-acetylglucosaminyltransferases, N-acetylgalactosyltransferases, galactosyltransferases, fucosyltransferases and sialyltransferases. As examples, we first assayed Clostridium difficile toxin B, a protein O-glucosyltransferase that specifically monoglucosylates and inactivates Rho family small GTPases; we then showed that human KTELC1, a homolog of Rumi from Drosophila, was able to hydrolyze UDP-Glc; and finally, we measured the kinetic parameters of human sialyltransferase ST6GAL1.     

Oxidative stress-resistance assay for screening yeast strains overproducing heterologous proteins

Many natural proteins have been developed into drugs and produced for direct application. Identifying improved hosts to achieve high-level heterologous protein production is a challenge in the study of heterologous protein expression in recombinant yeast. In this study, a novel high-throughput assay to screen such overproducing Saccharomyces cerevisiae strains was systematically developed. The protocol designed was based on screening host strain derivatives with increased superoxide dismutase dependent resistance to oxidative stress. Yeast cells transformed with recombinant plasmid carrying SOD1 gene as a reporter responded exquisitely to oxidative stress induced by elevated concentrations of paraquat. Improved yeast strains resulting from screening clones subjected to genome shuffling through selective pressure argue for a more effective screening system compared with traditonal selection. Moreover, this approach can be employed in general biochemical analysis without utilization of flow cytometry or well plate reader. Therefore, it is expected that the high-throughput assay would make superior strains producing heterologous proteins.     

Small Molecule Inhibitors of Phospholipase C from a Novel High-throughput Screen

Phospholipase C (PLC) isozymes are important signaling molecules, but few small molecule modulators are available to pharmacologically regulate their function. With the goal of developing a general approach for identification of novel PLC inhibitors, we developed a high-throughput assay based on the fluorogenic substrate reporter WH-15. The assay is highly sensitive and reproducible: screening a chemical library of 6280 compounds identified three novel PLC inhibitors that exhibited potent activities in two separate assay formats with purified PLC isozymes in vitro. Two of the three inhibitors also inhibited G protein-coupled receptor-stimulated PLC activity in intact cell systems. These results demonstrate the power of the high-throughput assay for screening large collections of small molecules to identify novel PLC modulators. Potent and selective modulators of PLCs will ultimately be useful for dissecting the roles of PLCs in cellular processes, as well as provide lead compounds for the development of drugs to treat diseases arising from aberrant phospholipase activity.     

A simple set-and-mix assay for screening of protein kinase inhibitors in cell lysates

Here we developed a simple set-and-mix assay to perform high-throughput screening of protein kinase A (PKA) inhibitors from the LOPAC 1280 compound library. This assay is based on the color change of gold nanoparticles on aggregation induced by a cationic substrate peptide as coagulant. In spite of the simplicity of this assay system, this assay can be applied to drug screening based on cellular kinases. We successfully found several highly active inhibitors, including compounds that have not been reported before.     

Application of the BD ACTOne technology for the high-throughput screening of Gs-coupled receptor antagonists

A novel technology for monitoring the changes of 3,'5'-adenosine cyclic monophosphate (cAMP) in live cells suitable for drug screening relies on the use of cyclic nucleotide-gated channels as biosensors coexpressed with the appropriate target receptor. The technique (termed BD ACTOne) offers measurement of cAMP-dependent calcium influx or membrane depolarization with conventional fluorescent methods both in kinetic and in endpoint modes, optimal for high-throughput and subsequent compound screening. The utility of the technique is reported here based on assay development and high-throughput screening for small-molecule antagonists of the peptide parathyroid hormone 2 receptor (PTH2R). The dual-signaling properties of the receptor were retained in the recombinant system, and the observed pharmacological profile corresponded to data from radiolabeled cAMP determination. The membrane-potential-based high-throughput assay produced reproducible actives and led to the identification of several chemical scaffolds with potential utility as PTH2R ligands.     

An easy colorimetric assay for glycosyltransferases

Glycosyltransferases are involved in biosynthesis of both protein-bound and non-bound glycans that have multiple and important biological functions in all species. A variety of methods for assaying glycosyltransferase activity have been developed driven by the specific interests and type of information required by researchers. In this work, a novel colorimetric assay for the glycosyltransferase-catalyzed reaction was established. Compared with measuring the newly formed product, which might not exhibit visible absorption, the unreacted acceptor could be readily detected by measuring the visible absorption of the hydrolysis product. In the assay, 4-nitrophenyl-β-D-glycoside (glycosyl-β-pNP) is used as the glycosyl acceptor, which can be hydrolyzed by a special exoglycosidase to release the p-nitrophenol before glycosylation reactions. Absorbance change of the p-nitrophenolate corresponds to unreacted glycosyl acceptor that accompanied the glycosyl transfer. The assay is demonstrated to be useful in the initial characterization of recombinant glycosyltransferases for their kinetic parameters, optimal metal cofactor, and pH value. It provides a simple, sensitive, and quantitative method for assessing glycosyltransferase activity and is thus expected to have broad applications including automated high-throughput screening.     

Phenylpropanoid glycosyltransferases from osage orange (Maclura pomifera) fruit

Flavonoids and isoflavonoids are well known for their beneficial effects on human health and their anti-insect and anti-microbial activities in plants. Osage orange fruit is rich in prenylated isoflavones and dihydrokaempferol and its glucoside. Four glycosyltransferases were identified from a collection of osage orange fruit expressed sequence tags. Biochemical characterization suggested that the glycosyltransferase UGT75L4 might be responsible for glucosylation of dihydrokaempferol in vivo, although this enzyme exhibited broad substrate recognition toward isoflavonoids and flavonoids in vitro. UGT88A4 was active on coumarin substrates. Identification of highly active phenylpropanoid glycosyltransferases will facilitate the metabolic engineering of glycosylated natural products in plants.     

Features and applications of bacterial glycosyltransferases: current state and prospects

The bioactivity of many natural products including valuable antibiotics and anticancer therapeutics depends on their sugar moieties. Changes in the structures of these sugars can deeply influence the biological activity, specificity and pharmacological properties of the parent compounds. The chemical synthesis of such sugar ligands is exceedingly difficult to carry out and therefore impractical to establish on a large scale. Therefore, glycosyltransferases are essential tools for chemoenzymatic and in vivo approaches for the development of complex glycosylated natural products. In the last 10 years, several examples of successful alteration and diversification of natural product glycosylation patterns via metabolic pathway engineering and enzymatic glycodiversification have been described. Due to the relaxed substrate specificity of many sugar biosynthetic enzymes and glycosyltransferases involved in natural product biosynthesis, it is possible to obtain novel glycosylated compounds using different methods. In this review, we would like to provide an overview of recent advances in diversification of the glycosylated natural products and glycosyltransferase engineering.     

Development of a coupled spectrophotometric assay for GlfT2, a bifunctional mycobacterial galactofuranosyltransferase

As a key constituent of their protective cell wall all mycobacteria produce a large structural component, the mycolyl-arabinogalactan (mAG) complex, which has at its core a galactan moiety of alternating beta-(1-->5) and beta-(1-->6) galactofuranosyl residues. Galactan biosynthesis is essential for mycobacterial viability and thus inhibitors of the enzymes involved in its assembly are potential drugs for the treatment of mycobacterial diseases, including tuberculosis. Only two galactofuranosyltransferases, GlfT1 and GlfT2, are responsible for the biosynthesis of the entire galactan domain of the mAG and we report here the first high-throughput assay for GlfT2. Successful implementation of the assay required the synthesis of multi-milligram amounts of the donor for the enzyme, UDP-Galf, 1, which was achieved using a chemoenzymatic approach. We also describe an improved expression system for GlfT2, which provides a larger amount of active protein for the assay. Kinetic analysis of 1 and a known trisaccharide acceptor for the enzyme, 2, have been carried out and the apparent K(m) and k(cat) values obtained for the latter are in agreement with those obtained using a previously reported radiochemical assay. The assay has been implemented in 384-well microtiter plates, which will facilitate the screening of large numbers of potential GlfT2 inhibitors, with possible utility as novel anti-TB drugs.     

Comparison of broad-scope assays of nucleotide sugar-dependent glycosyltransferases

Glycosyltransferases (GTs) are abundant in nature and diverse in their range of substrates. Application of GTs is, however, often complicated by their narrow substrate specificity. GTs with tailored specificities are highly demanded for targeted glycosylation reactions. Engineering of such GTs is, however, restricted by lack of practical and broad-scope assays currently available. Here we present an improvement of an inexpensive and simple assay that relies on the enzymatic detection of inorganic phosphate cleaved from nucleoside phosphate products released in GT reactions. This phosphatase-coupled assay (PCA) is compared with other GT assays: a pH shift assay and a commercially available immunoassay in Escherichia coli cell-free extract (CE). Furthermore, we probe PCA with three GTs with different specificities. Our results demonstrate that PCA is a versatile and apparently general GT assay with a detection limit as low as 1 mU. The detection limit of the pH shift assay is roughly 4 times higher. The immunoassay, by contrast, detected only nucleoside diphosphates (NDPs) but had the lowest detection limit. Compared with these assays, PCA showed superior robustness and, therefore, appears to be a suitable general screening assay for nucleotide sugar-dependent GTs.     

Microfluidic components and bio-reactors for miniaturized bio-chip applications

In this paper miniaturized disposable micro/nanofluidic components applicable to bio chip, chemical analyzer and biomedical monitoring system, such as blood analysis, micro dosing system and cell experiment, etc are reported. This system includes various microfluidic components including a micropump, micromixer, DNA purification chip and single-cell assay chip. For low voltage and low power operation, a surface tension-driven micropump is presented, as well as a micromixer, which was implemented using MEMS technology, for efficient liquid mixing is also introduced. As bio-reactors, DNA purification and single-cell assay devices, for the extraction of pure DNA from liquid mixture or blood and for cellular engineering or high-throughput screening, respectively, are presented.     

A high-throughput screen utilizing the fluorescence of riboflavin for identification of lumazine synthase inhibitors

A high-throughput screening method based on the competitive binding of a lumazine synthase inhibitor and riboflavin to the active site of Schizosaccharomyces pombe lumazine synthase was developed. This assay is sensitive, simple, and robust. During assay development, all of the known active inhibitors tested were positively identified. Preliminary high-throughput screening in 384-well format resulted in a Z factor of 0.7. The approach utilizes a thermodynamic assay to bypass the problems associated with the instabilities of both lumazine synthase substrates that complicate the use of a kinetic assay in a high-throughput format, and it removes the time element from the assay, thus simplifying the procedure.     

Selection against glycosylation sites in potential target proteins of the general HMWC N-glycosyltransferase in Haemophilus influenzae

The HMWABC system of non-typeable Haemophilus influenzae (NTHi) encodes the HMWA adhesin glycoprotein, which is glycosylated by the HMWC glycosyltransferase. HMWC is a cytoplasmic N-glycosyltransferase, homologues of which are widespread in the Pasteurellaceae. We developed an assay for nonbiased detection of glycoproteins in NTHi based on metabolic engineering of the Leloir pathway and growth in media containing radiolabelled monosaccharides. The only glycoprotein identified in NTHi by this assay was HMWA. However, glycoproteomic analyses ex vivo in Escherichia coli showed that HMWC of NTHi was a general glycosyltransferase capable of glycosylating selected asparagines in proteins other than its HMWA substrate, including Asn78 in E. coli 30S ribosomal protein S5. The equivalent residue in S5 homologues in H. influenzae or other sequenced Pasteurellaceae genomes is not asparagine, and these organisms also showed significantly fewer than expected potential sites of glycosylation in general. Expression of active HMWC in E. coli resulted in growth inhibition compared with expression of inactive enzyme, consistent with glycosylation by HMWC detrimentally affecting the function of some E. coli proteins. Together, this supports the presence of a selective pressure in the Pasteurellaceae against glycosylation sites that would be modified by the general N-glycosyltransferase activity of HMWC.