Solid-phase chemical tools for glycobiology

Techniques involving solid supports have played crucial roles in the development of genomics, proteomics, and in molecular biology in general. Similarly, methods for immobilization or attachment to surfaces and resins have become ubiquitous in sequencing, synthesis, analysis, and screening of oligonucleotides, peptides, and proteins. However, solid-phase tools have been employed to a much lesser extent in glycobiology and glycomics. This review provides a comprehensive overview of solid-phase chemical tools for glycobiology including methodologies and applications. We provide a broad perspective of different approaches, including some well-established ones, such as immobilization in microtiter plates and to cross-linked polymers. Emerging areas such as glycan microarrays and glycan sequencing, quantum dots, and gold nanoparticles for nanobioscience applications are also discussed. The applications reviewed here include enzymology, immunology, elucidation of biosynthesis, and systems biology, as well as first steps toward solid-supported sequencing. From these methods and applications emerge a general vision for the use of solid-phase chemical tools in glycobiology.     

Integrative proteomics: structure, function, and interaction report on the 3rd joint meeting of the British Society for Proteome Research and the European Bioinformatics Institute, July 2006

This report summarizes the highlights of the recent British Society for Proteome Research (BSPR) meeting jointly organized with the European Bioinformatics Institute (EBI) which was held at the Wellcome Trust Genome Campus, Hinxton, Cambridge, UK in July 2006. This was the third annual scientific meeting organized by the BSPR and EBI and the theme of this years meeting was Integrative Proteomics: Structure, function and interaction. A wealth of local and overseas speakers were invited to discuss both their own work and specific challenges present in modern day proteomic based experiments.     

Human Disease Glycomics/Proteome Initiative Workshop and the 4th HUPO Annual Congress

At the Human Disease Glycomics/Proteome Initiative workshop held on August 27 on the occasion of the fourth HUPO Congress in Munich, Germany, the working groups reported on pilot studies, performed by 21 laboratories world-wide, to analyze glycan using MS. During the steering committee on July 31 in Osaka, Japan, it was reported that these groups have developed a system using MS to assess the world-wide network on the screening of congenital disorders of glycosylation. The concept of glycobioinformatics was also explained at this meeting. The session on PTMs laid particular emphasis on the importance of functional glycomics using glycosyltransferase genes as well as on the importance of identifying the target protein(s) carrying the sugar chains.     

Web resources for the carbohydrate chemist

Bioinformatics has played a pivotal role in advancing genetics and protein sciences. The large amount of information generated by genomics, and now proteomics, has been a driving force. By comparison, glycobiology still generates small amounts of data. The need to organize our knowledge about carbohydrates is however growing constantly and has given rise to an increasing number of public databases and freely available tools. This review gives an overview of the carbohydrate-oriented resources currently available on the Internet. Many of the resources are seldom referred to in the literature and difficult to find, in part because of the constant flux of the net itself, but also because many efforts have been lead by a single individual. As the World Wide Web has matured the number of 'permanent' resources, maintained by organizations rather than individuals, has increased. In this paper, we present some of the more useful and accessible public tools and databases. There are also a few commercial initiatives but these have not been reviewed.     

Discovery of novel differentiation markers in the early stage of chondrogenesis by glycoform-focused reverse proteomics and genomics

Background

Osteoarthritis (OA) is one of the most common chronic diseases among adults, especially the elderly, which is characterized by destruction of the articular cartilage. Despite affecting more than 100 million individuals all over the world, therapy is currently limited to treating pain, which is a principal symptom of OA. New approaches to the treatment of OA that induce regeneration and repair of cartilage are strongly needed.

Methods

To discover potent markers for chondrogenic differentiation, glycoform-focused reverse proteomics and genomics were performed on the basis of glycoblotting-based comprehensive approach.

Results

Expression levels of high-mannose type N-glycans were up-regulated significantly at the late stage of differentiation of the mouse chondroprogenitor cells. Among 246 glycoproteins carrying this glycotype identified by ConA affinity chromatography and LC/MS, it was demonstrated that 52% are classified as cell surface glycoproteins. Gene expression levels indicated that mRNAs for 15 glycoproteins increased distinctly in the earlier stages during differentiation compared with Type II collagen. The feasibility of mouse chondrocyte markers in human chondrogenesis model was demonstrated by testing gene expression levels of these 15 glycoproteins during differentiation in human mesenchymal stem cells.

Conclusion

The results showed clearly an evidence of up-regulation of 5 genes, ectonucleotide pyrophosphatase/phosphodiesterase family member 1, collagen alpha-1(III) chain, collagen alpha-1(XI) chain, aquaporin-1, and netrin receptor UNC5B, in the early stages of differentiation.

General significance

These cell surface 5 glycoproteins become highly sensitive differentiation markers of human chondrocytes that contribute to regenerative therapies, and development of novel therapeutic reagents.     

Sample Preparation Scale-Up for Deep N-glycomic Analysis of Human Serum by Capillary Electrophoresis and CE-ESI-MS*

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Highlights

• •Efficient sample preparation workflow for deep N-glycomics analysis from serum.
• •Temperature gradient denaturing protocol to prevent protein precipitation.
• •Decrease of free sugar content in serum enhanced PNGase F digestion efficiency.
• •Modified evaporative labeling method increased fluorophore labeling yield.

     

编者按: 糖组学：全面了解生命基础的重要一环

糖组学：全面了解生命基础的重要一环     

Ablation of N-acetylglucosaminyltransferases in Caenorhabditis induces expression of unusual intersected and bisected N-glycans

The modification in the Golgi of N-glycans by N-acetylglucosaminyltransferase I (GlcNAc-TI, MGAT1) can be considered to be a hallmark of multicellular eukaryotes as it is found in all metazoans and plants, but rarely in unicellular organisms. The enzyme is key for the normal processing of N-glycans to either complex or paucimannosidic forms, both of which are found in the model nematode Caenorhabditis elegans. Unusually, this organism has three different GlcNAc-TI genes (gly-12, gly-13 and gly-14); therefore, a complete abolition of GlcNAc-TI activity required the generation of a triple knock-out strain. Previously, the compositions of N-glycans from this mutant were described, but no detailed structures. Using an off-line HPLC-MALDI-TOF-MS approach combined with exoglycosidase digestions and MS/MS, we reveal that the multiple hexose residues of the N-glycans of the gly-12;gly-13;gly-14 triple mutant are not just mannose, but include galactoses in three different positions (β-intersecting, β-bisecting and α-terminal) on isomeric forms of Hex_4-8HexNAc₂ structures; some of these structures are fucosylated and/or methylated. Thus, the N-glycomic repertoire of Caenorhabditis is even wider than expected and exhibits a large degree of plasticity even in the absence of key glycan processing enzymes from the Golgi apparatus.     

A glyco-competitive assay to demonstrate the stochasticity of fate decisions in Escherichia coli

Interaction bacteria-gut, via glycan associations, contribute to the selection of microbial communities along the gastrointestinal tract, influencing cancer development. The mechanism causing microbiome alterations is unknown, while this understanding would be pivotal to identify medical therapies. The molecular associations between Escherichia coli bacteria and glucose, both in solution and immobilized at the surface, were studied showing the dependence of E. coli glucose binding on the sugar form. Classical kinetic models were used to derive the reaction equilibrium and adsorption constants, 8 mM⁻¹ and 1 (cell/mL)⁻¹ and to explain the uptake. E. coli preferred the free glucose, whereas in a deprived environment, the anchored glucose became the major source of carbon for the bacteria. A stochastic algorithm disclosed that after initial transient, E. coli privileged the anchored glucose rather than the free sugar, independently on the concentration. The biochemical approach alone failed to describe the effective behavior of the cells and that several parameters can affect the behavior of the bacteria. From this result, more sophisticated models of the destruction of the gut barrier can be derived, such as the mechanism whereby E. coli can switch the immune system on and off to cause cancer and its metastasis.