Yunpeng Liu

Facile Enzymatic Synthesis of Ketoses

Studies of rare ketoses have been hampered by a lack of efficient preparation methods. A convenient, efficient, and cost-effective platform for the facile synthesis of ketoses is described. This method enables the preparation of difficult-to-access ketopentoses and ketohexoses from common and inexpensive starting materials with high yield and purity and without the need for a tedious isomer separation step.

Chemoenzymatic Synthesis of a Library of Human Milk Oligosaccharides

Human milk oligosaccharides (HMOs) are a family of diverse unconjugated glycans that exist in human milk as one of the major components. Characterization, quantification, and biofunctional studies of HMOs remain a great challenge due to their diversity and complexity. The accessibility of a homogeneous HMO library is essential to solve these issues which have beset academia for several decades. In this study, an efficient chemoenzymatic strategy, namely core synthesis/enzymatic extension (CSEE), for rapid production of diverse HMOs was reported. On the basis of 3 versatile building blocks, 3 core structures were chemically synthesized via consistent use of oligosaccharyl thioether and oligosaccharyl bromide as glycosylation donors in a convergent fragment coupling strategy. Each of these core structures was then extended to up to 11 HMOs by 4 robust glycosyltransferases. A library of 31 HMOs were chemoenzymatically synthesized and characterized by MS and NMR. CSEE indeed provides a practical approach to harvest structurally defined HMOs for various applications.

A precise approach in large scale core-fucosylated glycoprotein identification with low- and high-normalized collision energy.

UNLABELLED The core fucosylation (CF) of N-glycoproteins plays important roles in regulating protein functions during biological development, and it has also been shown to be up-regulated in several high metastasis cancer cell lines. Therefore, global profiling and quantitative characterization of CF-glycoproteins may reveal potent biomarkers for clinical applications. However, due to the complex fragmentation pattern of CF-glycopeptides, accurately identifying CF-glycosylation sites via mass spectrometry with high throughput remains a formidable challenge. In this study, we established a precise CF-glycosylation site identification strategy with UHPLC LTQ-Orbitrap Elite under low- and high-normalized collision energy (LHNCE) conditions. To demonstrate the feasibility of LHNCE, the CF-glycopeptides of target proteins in clinical plasma samples were applied and compared as a preliminary demonstration and resulted in the assignment of 357 unique CF-glycosylation sites from 209 CF-glycoproteins. In this study, the largest human plasma CF-glycosylation site database was constructed, and at least three-fold more CF-sites were identified compared to previously published studies. The results further demonstrated that LHNCE provides an important approach for CF-glycoprotein function studies and biomarker screening in cancer research. BIOLOGICAL SIGNIFICANCE Core-fucosylation (CF) is a kind of N-linked glycosylation in which an α1,6-linked fucose is added to the innermost N-acetylglucosamine (GlcNAc) residue. It has been proved that core-fucosylation is involved in regulating biological processes in mammals. Abnormal core-fucosylation has been demonstrated in human pathological processes, such as metastasis. For example, the CF-glycosylation of an α-fetoprotein isoform (AFP-L3) was approved as a biomarker of hepatocellular carcinoma (HCC). In addition, GP73 is also a well-known biomarker and its CF-glycosylation level will increase in liver cancer patients. Therefore, it is crucial to develop a strategy for mapping human CF-glycosylation.

Identification of the binding roles of terminal and internal glycan epitopes using enzymatically synthesized N-glycans containing tandem epitopes

Glycans play diverse roles in a wide range of biological processes. Research on glycan-binding events is essential for learning their biological and pathological functions. However, the functions of terminal and internal glycan epitopes exhibited during binding with glycan-binding proteins (GBPs) and/or viruses need to be further identified. Therefore, a focused library of 36 biantennary asparagine (Asn)-linked glycans with some presenting tandem glycan epitopes was synthesized via a combined Core Isolation/Enzymatic Extension (CIEE) and one-pot multienzyme (OPME) synthetic strategy. These N-glycans include those containing a terminal sialyl N-acetyllactosamine (LacNAc), sialyl Lewis x (sLex) and Siaα2-8-Siaα2-3/6-R structures with N-acetylneuraminic acid (Neu5Ac) or N-glycolylneuraminic acid (Neu5Gc) sialic acid form, LacNAc, Lewis x (Lex), α-Gal, and Galα1-3-Lex; and tandem epitopes including α-Gal, Lex, Galα1-3-Lex, LacNAc, and sialyl LacNAc, presented with an internal sialyl LacNAc or 1-2 repeats of an internal LacNAc or Lex component. They were synthesized in milligram-scale, purified to over 98% purity, and used to prepare a glycan microarray. Binding studies using selected plant lectins, antibodies, and viruses demonstrated, for the first time, that when interpreting the binding between glycans and GBPs/viruses, not only the structure of the terminal glycan epitopes, but also the internal epitopes and/or modifications of terminal epitopes needs to be taken into account.

Site-Directed Glycosylation of Peptide/Protein with Homogeneous O-Linked Eukaryotic N-Glycans.

Here we report a facile and efficient method for site-directed glycosylation of peptide/protein. The method contains two sequential steps: generation of a GlcNAc-O-peptide/protein, and subsequent ligation of a eukaryotic N-glycan to the GlcNAc moiety. A pharmaceutical peptide, glucagon-like peptide-1 (GLP-1), and a model protein, bovine α-Crystallin, were successfully glycosylated using such an approach. It was shown that the GLP-1 with O-linked N-glycan maintained an unchanged secondary structure after glycosylation, suggesting the potential application of this approach for peptide/protein drug production. In summary, the coupled approach provides a general strategy to produce homogeneous glycopeptide/glycoprotein bearing eukaryotic N-glycans.

Probing the roles of conserved residues in uridyltransferase domain of Escherichia coli K12 GlmU by site-directed mutagenesis.

N-Acetylglucosamine-1-phosphate uridyltransferase (GlmU) is a bifunctional enzyme that catalyzes both acetyltransfer and uridyltransfer reactions in the prokaryotic UDP-GlcNAc biosynthesis pathway. Our previous study demonstrated that the uridyltransferase domain of GlmU (tGlmU) exhibited a flexible substrate specificity, which could be further applied in unnatural sugar nucleotides preparation. However, the structural basis of tolerating variant substrates is still not clear. Herein, we further investigated the roles of several highly conserved amino acid residues involved in substrate binding and recognition by structure- and sequence-guided site-directed mutagenesis. Out of total 16 mutants designed, tGlmU Q76E mutant which had a novel catalytic activity to convert CTP and GlcNAc-1P into unnatural sugar nucleotide CDP-GlcNAc was identified. Furthermore, tGlmU Y103F and N169R mutants were also investigated to have enhanced uridyltransferase activities compared with wide-type tGlmU.

A two-step strategy for the preparation of 6-deoxy-l-sorbose

A two-step enzymatic strategy for the efficient and convenient synthesis of 6-deoxy-l-sorbose was reported herein. In the first reaction step, the isomerization of l-fucose (6-deoxy-l-galactose) to l-fuculose (6-deoxy-l-tagatose) catalyzed by l-fucose isomerase (FucI), and the epimerization of l-fuculose to 6-deoxy-l-sorbose catalyzed by d-tagatose 3-epimerase (DTE) were coupled with the targeted phosphorylation of 6-deoxy-l-sorbose by fructose kinase from human (HK) in a one-pot reaction. The resultant 6-deoxy-l-sorbose 1-phosphate was purified by silver nitrate precipitation method. In the second reaction step, the phosphate group of the 6-deoxy-l-sorbose 1-phosphate was hydrolyzed with acid phosphatase (AphA) to produce 6-deoxy-l-sorbose in 81% yield with regard to l-fucose.

CHAPTER 6:Chemoenzymatic Synthesis of N-Glycans

A major post-translational modification of proteins on cell surfaces is asparagine N-linked glycosylation, which plays critical roles in various biological processes. Over the past decade, efficient strategies for the synthesis of N-glycans have become increasingly attractive because it is highly desired to obtain structurally defined N-glycans in sufficient amounts for structure–function studies. In this respect, chemical synthesis of N-glycans has been well developed and has become the most frequently used approach to generate well-defined N-glycans. However, when synthetic targets are complicated N-glycans and especially N-glycan libraries, the chemical approach still remains challenging, tedious, and time-consuming. More recently, a facile and practical strategy, core synthesis/enzymatic extension (CSEE), has been developed for efficient synthesis of N-glycan libraries with structural diversities, wherein an N-glycan core is first chemically synthesized and further elongated by glycosyltransferases (GTs) to rapidly produce a large number of complex N-glycans. Herein, we provide a concise summary of most recent advances in chemical and chemoenzymatic synthesis of N-glycans.

Synthesis of silodosin glucuronide and its deuterated counterpart: solving a problematic O-glycosylation of a nitrogen-containing molecule

Abstract We report here the first chemical synthesis of silodosin glucuronide, a metabolite of the α1A-adrenoceptor antagonist silodosin, and its deuterium-labeled counterpart. As a key synthetic step, the incorporation of a glucuronosyl unit onto silodosin invariably led to either an undesired orthoester or a complex mixture under an array of standard glycosylation conditions. This problematic O-glycosylation may be attributed to the presence of multiple basic groups that could neutralize the acidic activators, decrease the nucleophilicity of a hydroxy group via hydrogen bond or even facilitate acyl migration side reactions. After elaborate tuning of reaction conditions, success was eventually achieved by using perbenzoylated d-glucuronosyl N-phenyltrifluroacetimidate (PTFA) as donor in combination with a procedure of sequential addition of TMSOTf. This protocol is potentially general for the glycosylation of other nitrogen-containing small molecule drugs.