An expeditious synthesis of novel DNA nucleobase mimics of (+)-anisomycin

A glycal based expeditious synthesis of novel nucleoside analogues of (+)-anisomycin is reported. Readily available tri-O-benzyl-D-glucal was converted to a partially protected trihydroxypyrrolidine that is used as a common scaffold for the introduction of various nucleobases at the primary hydroxyl centre. Nucleoside analogues possessing all four DNA bases have been synthesized. Selective acetylation at C3 position was carried out with two of these unnatural nucleosides in order to mimic the structure of (+)-anisomycin. Cytotoxicity studies of some of these nucleosides showed that they display weaker activity on HeLa cells than Ara-C.

Efficient inhibition of O-glycan biosynthesis using the hexosamine analog Ac5GalNTGc

There is a critical need to develop small-molecule inhibitors of mucin-type O-linked glycosylation. The best-known reagent currently is benzyl-GalNAc, but it is effective only at millimolar concentrations. This article demonstrates that Ac₅GalNTGc, a peracetylated C-2 sulfhydryl-substituted GalNAc, fulfills this unmet need. When added to cultured leukocytes, breast cells, and prostate cells, Ac₅GalNTGc increased cell-surface VVA binding by ∼10-fold, indicating truncation of O-glycan biosynthesis. Cytometry, mass spectrometry, and western blot analysis of HL-60 promyelocytes demonstrated that 50-80 μM Ac₅GalNTGc prevented elaboration of 30%-60% of the O-glycans beyond the Tn-antigen (GalNAcα1-Ser/Thr) stage. The effect of the compound on N-glycans and glycosphingolipids was small. Glycan inhibition induced by Ac₅GalNTGc resulted in 50%-80% reduction in leukocyte sialyl-Lewis X expression and L-/P-selectin-mediated rolling under flow conditions. Ac₅GalNTGc was pharmacologically active in mouse. It reduced neutrophil infiltration to sites of inflammation by ∼60%. Overall, Ac₅GalNTGc may find diverse applications as a potent inhibitor of O-glycosylation.

Differential inhibition of mucin-type O-glycosylation (MTOG) induced by peracetyl N-thioglycolyl-d-galactosamine (Ac5GalNTGc) in myeloid cells

Investigations on the structure and functional roles of glycosylation - an intricate, complex, and dynamic post translational modification on proteins - in biological processes has been a challenging task. Glycan modifications vary depending on the specific cell type, its developmental stage, and resting or activated state. In the present study, we aim to understand the differences between the mucin-type O-glycosylation (MTOG) of two functionally divergent human cell lines, K562 (chronic myeloid leukemia) and U937 (histiocytic lymphoma), having myeloid origins. MTOG is initiated by the addition of N-acetyl-α-d-galactosamine (GalNAc) to Ser/Thr of glycoproteins. We exploited the metabolic glycan engineering (MGE) strategy using the peracetyl N-thioglycolyl-d-galactosamine (Ac₅GalNTGc), a synthetic GalNAc analogue, to engineer the glycoconjugates. Ac₅GalNTGc was metabolized and incorporated as N-thioglycolyl-d-galactosamine (GalNTGc) in cell surface glycoproteins in both the cell lines with varying degrees of efficiency. Notably, metabolic incorporation of GalNTGc resulted in differential inhibition of MTOG. It was observed that endogenous glycosylation machinery of K562 is relatively more stringent for selecting GalNTGc whereas U937 is flexible towards this selection. Additionally, we studied how the glycan modifications vary on a given CD antigen in these cell lines. Particularly, MTOG on CD43 was differentially inhibited in K562 and U937 as revealed by glycan-dependent and glycan-independent antibodies. It was observed that the effect of MGE on CD43 was similar to global effects on both cell lines. Consequences of MGE using GalNAc analogues depend on the expression and activity of various glycosyl transferases which determine global glycosylation on cell surface as well as on specific glycoproteins.

Inhibition of mucin-type O-glycosylation through metabolic processing and incorporation of N-thioglycolyl-D-galactosamine peracetate (Ac5GalNTGc)

Mucin-type O-glycans form one of the most abundant and complex post-translational modifications (PTM) on cell surface proteins that govern adhesion, migration, and trafficking of hematopoietic cells. Development of targeted approaches to probe functions of O-glycans is at an early stage. Among several approaches, small molecules with unique chemical functional groups that could modulate glycan biosynthesis form a critical tool. Herein, we show that metabolism of peracetyl N-acyl-D-galactosamine derivatives carrying an N-thioglycolyl (Ac5GalNTGc, 1) moiety-but not N-glycolyl (Ac5GalNGc, 2) and N-acetyl (Ac4GalNAc, 3)-through the N-acetyl-D-galactosamine (GalNAc) salvage pathway induced abrogation of MAL-II and PNA epitopes in Jurkat cells. Mass spectrometry of permethylated O-glycans from Jurkat cells confirmed the presence of significant amounts of elaborated O-glycans (sialyl-T and disialyl-T) which were inhibited upon treatment with 1. O-Glycosylation of CD43, a cell surface antigen rich in O-glycans, was drastically reduced by 1 in a thiol-dependent manner. By contrast, only mild effects were observed for CD45 glycoforms. Direct metabolic incorporation of 1 was confirmed by thiol-selective Michael addition reaction of immunoprecipitated CD43-myc/FLAG. Mechanistically, CD43 glycoforms were unperturbed by peracetylated N-(3-acetylthiopropanoyl) (4), N-(4-acetylthiobutanoyl) (5), and N-methylthioacetyl (6) galactosamine derivatives, N-thioglycolyl-D-glucosamine (7, C-4 epimer of 1), and α-O-benzyl 2-acetamido-2-deoxy-D-galactopyranoside (8), confirming the critical requirement of both free sulfhydryl and galactosamine moieties for inhibition of mucin-type O-glycans. Similar, yet differential, effects of 1 were observed for CD43 glycoforms in multiple hematopoietic cells. Development of small molecules that could alter glycan patterns in an antigen-selective and cell-type selective manner might provide avenues for understanding biological functions of glycans.

Lectin microarrays for glycomic analysis

Glycomics is the study of comprehensive structural elucidation and characterization of all glycoforms found in nature and their dynamic spatiotemporal changes that are associated with biological processes. Glycocalyx of mammalian cells actively participate in cell-cell, cell-matrix, and cell-pathogen interactions, which impact embryogenesis, growth and development, homeostasis, infection and immunity, signaling, malignancy, and metabolic disorders. Relative to genomics and proteomics, glycomics is just growing out of infancy with great potential in biomedicine for biomarker discovery, diagnosis, and treatment. However, the immense diversity and complexity of glycan structures and their multiple modes of interactions with proteins pose great challenges for development of analytical tools for delineating structure function relationships and understanding glyco-code. Several tools are being developed for glycan profiling based on chromatography, mass spectrometry, glycan microarrays, and glyco-informatics. Lectins, which have long been used in glyco-immunology, printed on a microarray provide a versatile platform for rapid high throughput analysis of glycoforms of biological samples. Herein, we summarize technological advances in lectin microarrays and critically review their impact on glycomics analysis. Challenges remain in terms of expansion to include nonplant derived lectins, standardization for routine clinical use, development of recombinant lectins, and exploration of plant kingdom for discovery of novel lectins.

Targeting pro-invasive oncogenes with short chain fatty acid-hexosamine analogues inhibits the mobility of metastatic MDA-MB-231 breast cancer cells

Per-butanoylated N-acetyl-D-mannosamine (Bu(4)ManNAc), a SCFA-hexosamine cancer drug candidate with activity manifest through intact n-butyrate-carbohydrate linkages, reduced the invasion of metastatic MDA-MB-231 breast cancer cells unlike per-butanoylated-D-mannose (Bu(5)Man), a clinically tested compound that did not alter cell mobility. To gain molecular-level insight, therapeutic targets implicated in metastasis were investigated. The active compound Bu(4)ManNAc reduced both MUC1 expression and MMP-9 activity (via down-regulation of CXCR4 transcription), whereas "inactive" Bu(5)Man had counterbalancing effects on these oncogenes. This divergent impact on transcription was linked to interplay between HDACi activity (held by both Bu(4)ManNAc and Bu(5)Man) and NF-kappaB activity, which was selectively down-regulated by Bu(4)ManNAc. Overall, these results establish a new therapeutic end point (control of invasion) for SCFA-hexosamine hybrid molecules, define relative contributions of molecular players involved in cell mobility and demonstrate that Bu(4)ManNAc breaks the confounding link between beneficial HDACi activity and the simultaneous deleterious activation of NF-kappaB often found in epigenetic drug candidates.

Chemical labels metabolically installed into the glycoconjugates of the target cell surface can be used to track lymphocyte/target cell interplay via trogocytosis: comparisons with lipophilic dyes and biotin

Trogocytosis, the process whereby lymphocytes capture membrane components from the cells they interact with, is classically evidenced by the transfer of fluorescent lipophilic compounds or biotinylated proteins from target cells to T or B cells. A particular class of molecules, not studied explicitly so far in the context of trogocytosis is glycoconjugates. Here, we used a method to metabolically install chemical labels in target cell glycoconjugates. Working with those target cells, we describe the conditions allowing CTL to be detected based on glycoconjugate trogocytosis triggered by antigen or stimulatory antibodies. Accordingly, we used this method to monitor the CTL response triggered in mice after vaccination. In addition, we documented the applicability of this approach to the detection of CD4(+) T and B cells. Overall, glycoconjugates were transferred between target cells and lymphocytes during trogocytosis with efficiencies comparable or higher than measured for biotinylated proteins or lipophilic dyes incorporated into general membrane lipids. From a technological point of view, our approach can be employed to detect reactive lymphocytes via glycoconjugate trogocytosis. More generally, we believe that the ever-growing ability to employ chemistry in living systems to label particular compounds will be powerful in unraveling the contributions of glycosylation to various aspects of T and B cells biology.

Synthesis of non-natural ManNAc analogs for the expression of thiols on cell-surface sialic acids

The sialic acid biosynthetic pathway in mammalian cells utilizes N-acetyl-D-mannosamine (ManNAc) as a natural metabolic precursor and has the remarkable ability to biosynthetically process non-natural ManNAc analogs. Herein, we describe a recipe-style protocol for the synthesis of the novel peracetylated analog Ac5ManNTGc (1) that contains a pendant acetylthio- group and enables incorporation of thiol functionalities into the glycocalyx of living cells. We also describe the synthesis of the oxygen analog Ac5ManNGc (2), which serves as an appropriate control compound for biological experiments with 1. Both 1 and 2 were prepared from a reported, common intermediate 8, which is selectively acetylated at the hydroxyl groups. In contrast to previous methods, this synthetic approach introduces O-acetyl groups first, followed by N-acylation. Starting from the commercially available D-mannosamine hydrochloride (5), gram quantities of both 1 and 2 can be prepared over five steps in about 2-3 weeks.

Targeting glycosylation pathways and the cell cycle: sugar-dependent activity of butyrate-carbohydrate cancer prodrugs

Short-chain fatty acid (SCFA)-carbohydrate hybrid molecules that target both histone deacetylation and glycosylation pathways to achieve sugar-dependent activity against cancer cells are described in this article. Specifically, n-butyrate esters of N-acetyl-D-mannosamine (But4ManNAc, 1) induced apoptosis, whereas corresponding N-acetyl-D-glucosamine (But4GlcNAc, 2), D-mannose (But5Man, 3), or glycerol (tributryin, 4) derivatives only provided transient cell cycle arrest. Western blots, reporter gene assays, and cell cycle analysis established that n-butyrate, when delivered to cells via any carbohydrate scaffold, functioned as a histone deacetylase inhibitor (HDACi), upregulated p21WAF1/Cip1 expression, and inhibited proliferation. However, only 1, a compound that primed sialic acid biosynthesis and modulated the expression of a different set of genes compared to 3, ultimately killed the cells. These results demonstrate that the biological activity of butyrate can be tuned by sugars to improve its anticancer properties.

Metabolic oligosaccharide engineering: perspectives, applications, and future directions

Many adhesion and signaling molecules critical for development, as well as surface markers implicated in diseases ranging from cancer to influenza, contain oligosaccharides that modify their functions. Inside a cell, complex glycosylation pathways assemble these oligosaccharides and attach them to proteins and lipids as they traffic to the cell surface. Until recently, practical technologies to manipulate glycosylation have lagged unlike the molecular biologic and genetic methods available to intervene in nucleic acid and protein biochemistry; now, metabolic oligosaccharide engineering shows promise for manipulating glycosylation. In this methodology, exogenously-supplied non-natural sugars intercept biosynthetic pathways and exploit the remarkable ability of many of the enzymes involved in glycosylation to process metabolites with slightly altered chemical structures. To date, non-natural forms of sialic acid, GalNAc, GlcNAc, and fucose have been incorporated into glycoconjugates that appear on the cell surface; in addition O-GlcNAc protein modification involved in intracellular signaling has been tagged with modified forms of this sugar. Reactive functional groups, including ketones, azides, and thiols, have been incorporated into glycoconjugates and thereby provide chemical 'tags' that can be used for diverse purposes ranging from drug delivery to new modes of carbohydrate-based cell adhesion that can be used to control stem cell destiny. Finally, strategies for further engineering non-natural sugars to improve their pharmacological properties and provide complementary biological activities, such as addition of short chain fatty acids, are discussed in this article.

Metabolic expression of thiol-derivatized sialic acids on the cell surface and their quantitative estimation by flow cytometry

The N-acetyl-D-mannosamine (ManNAc) analog Ac5ManNTGc, a non-natural metabolic precursor for the sialic acid biosynthetic pathway, can be used to display thiols on the cell surface. Sugar-expressed cell-surface thiols are readily accessible compared to their protein counterparts, making them ideal for exploitation in cell-adhesion and tissue-engineering applications. This report describes a protocol for the incubation of Jurkat (human acute T-cell leukemia) cells with Ac5ManNTGc and the quantitative estimation of the resulting sialic acid displayed thiols by flow cytometry after a reaction with a water-soluble biotin-conjugated maleimide reagent and fluorescein isothiocyanate-conjugated (FITC) avidin staining. These methods, with minimal optimization, are generally also applicable to other human cell lines. The labeling and flow cytometry steps of this protocol can be performed in five to eight hours.

Sialic acid and the central nervous system: perspectives on biological functions, detection, imaging methods and manipulation

Glycobiology, broadly defined as the study of sugars in living systems, is becoming increasingly important for understanding the basic biology of the central nervous system (CNS) and diagnosing and devising new treatments for neurological disorders. Decades of research have uncovered many roles for both glycolipids and glycoproteins in the proper functioning of the brain; moreover many diseases are characterized by abnormalities in either the biosynthesis or catabolism of these cellular components. In many cases, however, only a rudimentary understanding of the basic biological roles of sugars in neural function exists. Similarly, methods to detect and diagnose glycosylation disorders are far from state-of-the-art compared to many facets of modern medicine. This review focuses on sialic acid, arguably the most important monosaccharide in CNS, and describes how recent advances in its manipulation by chemical and metabolic methods hold the possibility to converge with advanced instrumentation such as magnetic resonance imaging, positron emission tomography, diffusion tensor imaging, and single photon emission computerized tomography now used for imaging of the CNS in human subjects. Specifically, methods are under development for tagging sialic acids in living systems with contrast agents suitable for magnetic resonance imaging, in essence allowing for the functional imaging of sugars at a molecular level. One of these methods, biochemical engineering of sialic acids by use of small molecule metabolic substrates, also holds promise for the manipulation of sialic acids for the development of novel therapies for neurological disorders.

Synthesis of hexa- to tridecasaccharides related to Shigella dysenteriae type 1 for incorporation in experimental vaccines

Hexa- to tridecasaccharides corresponding to the O-specific polysaccharide (O-SP) of the Gram-negative bacterium Shigella dysenteriae type 1 were synthesized in solution phase. The syntheses utilized tetra-, octa-, and dodecasaccharide intermediates that represent one to three contiguous tetrasaccharide repeating units of the O-SP [Synlett2003, 743]. These compounds were glycosylated with mono-, di-, and trisaccharide trichloroacetamidates, which were synthesized in this study. The excellent stereodirecting effect of 4,6-O-benzophenone ketals in glycosylation reactions of 2-azido-2-deoxy-glucopyranosyl donors was demonstrated. The free oligosaccharides were characterized by 1H and 13C NMR spectroscopy and by high-resolution mass spectrometry. The oligosaccharides described herein contain the 5-(methoxycarbonyl)pentyl aglycon for eventual attachment to immunogenic carriers using a recently published protocol [J. Org. Chem.2005, 70, 6987].

Metabolic installation of thiols into sialic acid modulates adhesion and stem cell biology

Metabolic 'oligosaccharide engineering' methods based on N-acetyl-D-mannosamine (ManNAc) analogs allow the glycocalyx of living cells to be remodeled. Herein we report the analog Ac(5)ManNTGc (1) that enables thiols to be expressed in surface sialic acids. By locating this versatile functional group on the outer periphery of normally nonadhesive human Jurkat cells, we obtained spontaneous cell-cell clustering and attachment to complementary maleimide-derivatized substrates. When analyzed in human embryoid body-derived (hEBD) stem cells, Ac(5)ManNTGc induced beta-catenin expression and altered cell morphology, consistent with neuronal differentiation. Notably, these effects were modulated by the growth substrate of the cells, with a stronger response observed on a gold surface than on glass. Together, these results establish sugar analogs as small-molecule tools for tissue engineering by providing a method for attaching cells to scaffolds via their surface carbohydrates as well as offering a means to influence stem cell fates.

Establishment of N-Acetylmannosamine (ManNAc) Analogue-Resistant Cell Lines as Improved Hosts for Sialic Acid Engineering Applications

Metabolic substrate-based sialic acid engineering techniques, where exogenously supplied N-acetylmannosamine (ManNAc) analogues are utilized by the sialic acid biosynthetic pathway, allow the cell surface to be endowed with novel physical and chemical properties and show promise for increasing the quality of recombinant glycoproteins. The in vitro toxicity of many ManNAc analogues, however, hinders the large-scale adoption of this technology. In this study, we used a selection strategy where cells were subjected to progressively higher levels of ManNAc analogues to establish novel cell lines that showed decreased sensitivity to analogue-induced in vitro toxicity. The decreased sensitivity to sugar analogue-induced apoptosis, demonstrated by the Annexin V-FITC detection method and DNA fragmentation assays, corresponded to increased sialic acid production in the resistant cell lines. The ManNAc analogue-resistant cell lines exhibited cross-resistance to apoptosis induced by staurosporine and an apoptosis-activating Fas antibody. We propose that the selection strategy employed to develop these novel cell lines, which serve as superior hosts for substrate-based sialic acid engineering applications, will generally apply to the development of host cell lines for biotechnology applications.

Characterization of the metabolic flux and apoptotic effects of O-hydroxyl- and N-acyl-modified N-acetylmannosamine analogs in Jurkat cells

The supplementation of the sialic acid biosynthetic pathway with exogenously supplied N-acetylmannosamine (ManNAc) analogs has many potential biomedical and biotechnological applications. In this work, we explore the structure-activity relationship of Man-NAc analogs on cell viability and metabolic flux into the sialic acid biosynthetic pathway to gain a better understanding of the fundamental biology underlying "glycosylation engineering" technology. A panel of ManNAc analogs bearing various modifications on the hydroxyl groups as well as substitutions at the N-acyl position was investigated. Increasing the carbon chain length of ester derivatives attached to the hydroxyl groups increased the metabolic efficiency of sialic acid production, whereas similar modification to the N-acyl group decreased efficiency. In both cases, increases in chain length decreased cell viability; DNA ladder formation, Annexin V-FITC two-dimensional flow cytometry assays, caspase-3 activation, and down-regulation of sialoglycoconjugate-processing enzymes established that the observed growth inhibition and toxicity resulted from apoptosis. Two of the panel of 12 analogs tested, specifically Ac(4)ManNLev and Ac(4) ManNHomoLev, were highly toxic. Interestingly, both of these analogs maintained a ketone functionality in the same position relative to the core monosaccharide structure, and both also inhibited flux through the sialic acid pathway (the remainder of the less toxic analogs either increased or had no measurable impact on flux). These results provide fundamental insights into the role of sialic acid metabolism in apoptosis by demonstrating that ManNAc analogs can modulate apoptosis both indirectly via hydroxylgroup effects and directly through N-acyl-group effects.