Secondary structures of hyaluronate and chondroitin sulphates. A 1H n.m.r. study of NH signals in dimethyl sulphoxide solution

Room-temperature reversible F-ion batteries based on sulfone electrolytes with a mild anion acceptor additive

Rechargeable fluoride ion batteries (FIBs) as an emerging anion shuttle system are attracting much attention due to their potential advantages in terms of energy density, cost and safety. A liquid electrolyte system enables the FIB operation at low or room temperature due to its higher ionic conductivity than that of a solid F-ion electrolyte. However, the insolubility of fluoride salts in aprotic solvents limits the development of liquid F-ion electrolytes. Although the boron-based anion acceptors (AAs) can facilitate the dissolution of F-ion salts, they are prone to lead to a tough desolvation process for F- due to strong Lewis acidity and therefore an inferior electrochemical performance. Here, a new non-boron AA (6-thioguanine) with moderate Lewis acidity is proposed to dissolve F- in the sulfone solvent. The ionic conductivity of the corresponding electrolytes reaches a level of mS cm-1 at room temperature. A model FIB coin cell is successfully operated with high conversion reaction reversibility based on the coupled defluorination/fluorination mechanism of electrodes, enabling a low overpotential of 0.36 V and a reversible capacity of 126 mA h g-1 after 40 cycles.

Hyaluronic acid nanofibers crosslinked with a nontoxic reagent

The poor water resistance of the eletrospun hyaluronic acid (HA) nanofibers prevents their biomedical applications. In this manuscript, we crosslinked HA nanofibers with the periodate oxidation - adipic acid dihydrazide (ADH) crosslinking strategy. Quantification results showed that ∼ 57 % of aldehydes in oxidized HA were crosslinked by ADH and the crosslinking density could reach 75.7 %. Correspondingly, the crosslinked HA nanofiber mats exhibited wet tensile strength up to 0.88 MPa and could maintain their nanofibrous morphology after 14 days in simulated body fluid. Although ∼ 28 % of the aldehydes in oxidized HA were unreacted, the crosslinked HA nanofibers did not cause toxicity to L929 fibroblast cells, possibly because that the unreacted aldehyde groups were linked on macromolecular fragments and could not go across cell membranes. The water resistant and biocompatible HA nanofibers are expected to seek extensive applications in biomedical fields such as wound healing, adhesion prevention, and tissue engineering.

Constructing 3-Dimensional Atomic-Resolution Models of Nonsulfated Glycosaminoglycans with Arbitrary Lengths Using Conformations from Molecular Dynamics

Glycosaminoglycans (GAGs) are the linear carbohydrate components of proteoglycans (PGs) and are key mediators in the bioactivity of PGs in animal tissue. GAGs are heterogeneous, conformationally complex, and polydisperse, containing up to 200 monosaccharide units. These complexities make studying GAG conformation a challenge for existing experimental and computational methods. We previously described an algorithm we developed that applies conformational parameters (i.e., all bond lengths, bond angles, and dihedral angles) from molecular dynamics (MD) simulations of nonsulfated chondroitin GAG 20-mers to construct 3-D atomic-resolution models of nonsulfated chondroitin GAGs of arbitrary length. In the current study, we applied our algorithm to other GAGs, including hyaluronan and nonsulfated forms of dermatan, keratan, and heparan and expanded our database of MD-generated GAG conformations. Here, we show that individual glycosidic linkages and monosaccharide rings in 10- and 20-mers of hyaluronan and nonsulfated dermatan, keratan, and heparan behave randomly and independently in MD simulation and, therefore, using a database of MD-generated 20-mer conformations, that our algorithm can construct conformational ensembles of 10- and 20-mers of various GAG types that accurately represent the backbone flexibility seen in MD simulations. Furthermore, our algorithm efficiently constructs conformational ensembles of GAG 200-mers that we would reasonably expect from MD simulations.

UDP-glucose Dehydrogenase: The First-step Oxidation Is an NAD+-dependent Bimolecular Nucleophilic Substitution Reaction (SN2)

UDP-glucose dehydrogenase (UGDH) catalyzes the conversion of UDP-glucose to UDP-glucuronic acid by NAD⁺-dependent two-fold oxidation. Despite extensive investigation into the catalytic mechanism of UGDH, the previously proposed mechanisms regarding the first-step oxidation are somewhat controversial and inconsistent with some biochemical evidence, which instead supports a mechanism involving an NAD⁺-dependent bimolecular nucleophilic substitution (S_N2) reaction. To verify this speculation, the essential Cys residue of Streptococcus zooepidemicus UGDH (SzUGDH) was changed to an Ala residue, and the resulting Cys260Ala mutant and SzUGDH were then co-expressed in vivo via a single-crossover homologous recombination method. Contrary to the previously proposed mechanisms, which predict the formation of the capsular polysaccharide hyaluronan, the resulting strain instead produced an amide derivative of hyaluronan, as validated via proteinase K digestion, ninhydrin reaction, FT-IR and NMR. This result is compatible with the NAD⁺-dependent S_N2 mechanism.

The hydration mechanism and hydrogen bonding structure of 6-carboxylate chitooligosaccharides superabsorbent material prepared by laccase/TEMPO oxidation system

6-carboxylate chitooligosaccharides (6-CCOS), as a superabsorbent material, were prepared by way of the laccase/TEMPO oxidation system. It exhibited a higher moisture-absorption ability and stronger affinity for water. To understand the real reasons for this, the hydrogen bonding structure of 6-CCOS and the hydration mechanism of the molecule were investigated using infrared (IR), differential scanning calorimetry (DSC), and nuclear magnetic resonance (NMR). It was found that the introduction of a strongly hydrophilic carboxylate ion on the C6 site of chitooligosaccharides molecule was conducive to the enhancement of the interaction between polysaccharide polymers and water molecules. The most important was the formation of hydrogen bonds connected between carboxylate ion and residual water. In addition, the hydration mechanism of 6-CCOS molecules was presumed to be that more water molecules from outside were incorporated into the already embedded water molecules within the polymer. The whole molecule was woven into a huge water-polymer network structure through intermolecular hydrated hydrogen bonds.

Structural behavior of highly concentrated hyaluronan

When investigated under high concentration conditions, hyaluronan (HA) solutions in physiological saline are shown to generate stable superstructures. An abrupt change in the rheological properties observed on increasing the temperature suggests the breaking of certain cooperative bonds. The thermal disruption of the HA superstructure is accompanied by a sharp transition from a long- to a restricted-connectivity water structuring, which is interpreted as a concurrent transition from a stable to a temporary polymer network. The intermolecular associations are considered to be originated by hydrophobic interactions between the nonpolar groups of the polymer backbones.

Hyaluronan: the absence of amide-carboxylate hydrogen bonds and the chain conformation in aqueous solution are incompatible with stable secondary and tertiary structure models

Contradictory descriptions for the aqueous solution conformation of the glycosaminoglycan hyaluronan (HA) exist in the literature. According to hydrodynamic and simulation data, HA molecules are stiffened by a rapidly interchanging network of transient hydrogen bonds at the local level and do not significantly associate at the global level. In marked contrast, models derived from NMR data suggest that the secondary structure involves persistent hydrogen bonds and that strong associations between chains can occur to form vast stable tertiary structures. These models require an extended 2-fold helical conformation of the HA chain and specific hydrogen bonds between amide and carboxylate groups. To test these descriptions, we have used 15N-labelled oligosaccharides and high-field NMR to measure pertinent properties of the acetamido group. The amide proton chemical shift perturbation and carboxylate group pK(a) value are inconsistent with a highly populated hydrogen bond between the amide and carboxylate groups. Amide proton temperature coefficients and chemical exchange rates confirm this conclusion. Comparison of oligomer properties with polymeric HA indicates that there is no discernible difference in amide proton environment between the centre of octasaccharides and the polymer, inconsistent with the formation of tertiary structures. A [1H-1H-15N] NOESY-HSQC (heteronuclear single-quantum correlation) spectrum recorded on an HA octasaccharide revealed that amide groups in the centre are in a trans orientation and that the average solution conformation is not an extended 2-fold helix. Therefore the two key aspects of the secondary and tertiary structure models are unlikely to be correct. Rather, these new NMR data agree with descriptions from hydrodynamic and simulations data.

Hyaluronan: The Local Solution Conformation Determined by NMR and Computer Modeling is Close to a Contracted Left-handed 4-Fold Helix

The polysaccharide hyaluronan (HA) is a ubiquitous component of the vertebrate extracellular matrix with diverse physiological roles from space-filling to acting as a scaffold for other macromolecules. The molecular interactions responsible for these solution properties have been the subject of much debate and, primarily due to the lack of residue-specific experimental data, no consensus model for the three-dimensional conformation nor dynamics of HA in solution has emerged. Here, the solution conformation of HA is investigated using molecular dynamics (MD) simulations and high-field nuclear magnetic resonance (NMR). In contrast to previous studies, MD simulations incorporated explicit water molecules and sodium ions, while NMR experiments utilized (15)N-enriched oligosaccharides to allow residue-specific information to be obtained. The resultant average conformation is predicted to be almost a contracted left-handed 4-fold helix; i.e. similar to that observed for sodium hyaluronate fibers by X-ray diffraction, but with the acetamido side-chain trans to H(2). The glycosidic linkages and acetamido side-chains are predicted to have standard deviation rotations of 13 degrees and 18 degrees around their mean conformations in free solution, respectively, and are not observed to be stabilized by strong intramolecular hydrogen bonds as X-ray fiber diffraction refinements describe for the solid-state. Rather, weak and transient hydrogen bonds that are in rapid interchange with solvent molecules are predicted. These predictions are quantitatively consistent with demanding residue-specific NMR data and correspond to an HA molecule that is rod-like as an oligosaccharide and behaves as a stiffened random coil at large molecular mass, in close agreement with previous hydrodynamic observations. This new description of the solution conformation of HA is consistent with all available experimental data and accounts for its viscoelastic space-filling properties. This representation can be used as a basis for modeling the association between HA and proteins, which will elucidate important aspects of extracellular matrix assembly.

Experimental approaches to hyaluronan structure

A review of the literature describing experimental studies on hyaluronan (HA) is presented. Methods sensitive to the hydrodynamic properties of HA, analyzed in neutral aqueous solution containing NaCl at physiological concentration, can be shown to fit the expected behavior of a high molecular weight linear semi-flexible polymer. The significant nonideality of HA solutions can be predicted by a simple treatment for hydrodynamic interactions between polymer chains. Nuclear magnetic resonance and circular dichroism studies of HA are also in agreement with a model incorporating dynamically formed and broken hydrogen bonds, contributing to the semi-flexibility of the polymer chain, and segmental motions on the nanosecond time scale. HA shows the capability for self-association in the formation of a viscoelastic putty state at pH 2.5 in the presence of salt, and a gel state at pH 2.5 in mixed organic/aqueous solution containing salt. Ordered and associated structures have also been observed for HA on the surfaces, especially in the presence of surface-structured water. These phenomena can be understood in terms of counterion-mediated polyelectrolyte interactions. The possibility that hyaluronan exists in vivo in environments that induce ordered structures and assemblies is discussed.

Exploiting the carboxylate chemical shift to resolve degenerate resonances in spectra of 13C-labelled glycosaminoglycans

Glycosaminoglycans (GAG) are important vertebrate extracellular matrix polysaccharides that comprise repeated units of an acidic and an N-acetylated sugar. The constituent acidic sugars are central to their biological functions, but have been largely inaccessible to NMR because the (1)H resonances overlap with those from other residues. Here, pulse sequences that address this failure are developed using (13)C-enriched oligosaccharides of the glycosaminoglycan, hyaluronan, as model systems. Two pulse sequences are presented that exploit the unique chemical shifts and scalar couplings present at the carboxylate moiety to filter out coherences from the N-acetylated sugars and produce simple spectra containing only resonances from the acidic sugars. The first sequence uses one-bond couplings to correlate the carboxylate carbon with the adjacent carbon and its directly attached proton, while the second sequence exploits a long-range coupling to correlate the carboxylate carbon with the anomeric proton and carbon of the same residue. In addition, inclusion of an isotropic mixing block into these sequences allows resonances from the otherwise degenerate ring protons to be resolved. Spectra from the hyaluronan tetra- and hexasaccharides show that all glucuronic acid (GlcA) residues can be resolved from one another, allowing nuclei to be assigned in a sequence-specific manner. However, in some spectra, resonances are observed at positions not predicted by spin-operator analysis, and simulations reveal that these additional magnetisation transfers result from strong-coupling. These experiments represent a foundation from which new structural and biochemical information can be obtained in a sequence-specific manner for the acidic sugar residues in hyaluronan and other glycosaminoglycans.

Use of 15N-NMR to resolve molecular details in isotopically-enriched carbohydrates: sequence-specific observations in hyaluronan oligomers up to decasaccharides

The glycosaminoglycan hyaluronan is a vital structural component of extracellular matrices with diverse biological functions, a molecular understanding of which requires a detailed description of secondary and tertiary solution structures. Various models of these structures have been proposed on the basis of 1H and 13C natural-abundance nuclear magnetic resonance (NMR) experiments, but resonance overlap limits further progress with these techniques. We have therefore produced 15N- and 13C- isotopically-labeled hyaluronan oligosaccharides and applied triple-resonance and 3D experiments to overcome this restriction. Spectra recorded on oligosaccharides (of lengths 4, 6, 8, 10, and 12 sugar rings), reveal that the 15N nucleus allows resolution of the amide groups in a decamer at high magnetic field, whereas 13C natural-abundance NMR can only resolve internal groups up to hexamers. Complete 13N sequence- specific assignments of these oligosaccharides indicate that the chemical shift dispersion can be explained by end-effects, which are seen even in the middle of octamers. Triple- resonance and 15N-edited 3D experiments, among the first of their kind in oligosaccharides, have been used to achieve resolution of ring 1H and 13C nuclei where not possible previously. The subtle chemical shift perturbations resolved suggest that different conformations and dynamics occur at the ends, which may contribute to the range of biological activities displayed by varying lengths of hyaluronan. 15N-NMR in carbohydrates has not received much attention before, however, this study demonstrates it has clear advantages for achieving resolution and assessing dynamic motion. These conclusions are likely to be applicable to the study of the structure and dynamics of other nitrogen-containing carbohydrates.

Characterization of enzymatically digested hyaluronic acid using NMR, Raman, IR, and UV-Vis spectroscopies

Hyaluronic acid (HA) is a linear polysaccharide formed from disaccharide units containing N-acetylglucosamine and glucuronic acid. When HA was digested with the enzyme hyaluronidase, a double bond is formed. It is known that this double bond forms a complex (radical scavenger) with the radicals (ROO, HO) during UV irradiation, and reduced the toxicity of the radicals before they are absorbed in the human skin. Therefore, the characterization of the double bond formed after the enzymatic digestion of HA is very important. In this study, 1H NMR, 13C NMR, Raman, infrared (IR), and UV-Vis spectroscopies were used for characterization of the double bond of HA after enzymatic digestion. HA derivatives in shape of films were tested using Raman and infrared (IR) spectroscopies and the wavenumber of the double bond and some other assignment were determined. The 1H and 13C NMR spectra were measured for HA derivatives in D(2)O solutions. The chemical shifts and coupling constant of 1H and 13C were assigned to the CH=C fragment. The relative amount of olefinic proportion in the mixture was obtained from 1H and 13C NMR spectra. The spectroscopy measurement showed an increase in the double bond amount with increasing enzymatic digestion time.

The molecular basis of the solution properties of hyaluronan investigated by confocal fluorescence recovery after photobleaching

Hyaluronan (HA) is a highly hydrated polyanion, which is a network-forming and space-filling component in the extracellular matrix of animal tissues. Confocal fluorescence recovery after photobleaching (confocal-FRAP) was used to investigate intramolecular hydrogen bonding and electrostatic interactions in hyaluronan solutions. Self and tracer lateral diffusion coefficients within hyaluronan solutions were measured over a wide range of concentrations (c), with varying electrolyte and at neutral and alkaline pH. The free diffusion coefficient of fluoresceinamine-labeled HA of 500 kDa in PBS was 7.9 x 10(-8) cm(2) s(-1) and of 830 kDa HA was 5.6 x 10(-8) cm(2) s(-1). Reductions in self- and tracer-diffusion with c followed a stretched exponential model. Electrolyte-induced polyanion coil contraction and destiffening resulted in a 2.8-fold increase in self-diffusion between 0 and 100 mM NaCl. Disruption of hydrogen bonds by strong alkali (0.5 M NaOH) resulted in further larger increases in self- and tracer-diffusion coefficients, consistent with a more dynamic and permeable network. Concentrated hyaluronan solution properties were attributed to hydrodynamic and entanglement interactions between domains. There was no evidence of chain-chain associations. At physiological electrolyte concentration and pH, the greatest contribution to the intrinsic stiffness of hyaluronan appeared to be due to hydrogen bonds between adjacent saccharides.

Deducing polymeric structure from aqueous molecular dynamics simulations of oligosaccharides: predictions from simulations of hyaluronan tetrasaccharides compared with hydrodynamic and X-ray fibre diffraction data

Molecular dynamics simulations of the two hyaluronan tetrasaccharides in water predict that over a period of 500 ps, their central linkages populate a single primary minima. Over the same period the peripheral linkages explore this minima, but also a secondary minima. Structures constructed using the primary minima were found to be extended left-handed helices of axial rise per disaccharide (h) 0.8 to 1.0 nm and 2.8 to 4.5 disaccharides per turn (n), in good agreement with n=3 and n=4 helices found by X-ray fibre diffraction studies. We have used the predicted average conformation from molecular dynamics to calculate the translational diffusion coefficients of the oligosaccharide series up to decasaccharide, and compared these with experimental measurements obtained using the method of capillary dispersion. Our calculated values are found to be in good agreement with experiment beyond the size of a tetrasaccharide. A partial digest of hyaluronan in the molecular mass range 10 to 100 kDa was fractionated by gel chromatography. Molecular weights were determined by in-line laser light-scattering measurements, and the translational diffusion coefficients of selected fractions were determined by dynamic laser light-scattering. A similar experiment was performed on hyaluronan with a molecular mass greater than 1MDa. The data suggest a change from rod-like to stiff coil behaviour beyond a molecular weight of 10 kDa. We have also examined the conformations available using the secondary minima, found at the peripheral linkages. In contrast to the extended structures previously described we have found left and right-handed helices with high values of n (5-10) and low values of h. Although there is no experimental evidence for these structures, they are of interest as, over short stretches, they would introduce folds, loops, and turns into the hyaluronan molecule. Such shapes may play an important role in the hydrodynamics of hyaluronan and its interaction with lipids and proteins.

Intrinsic viscosity calculated out of single point measurements for chondroitin-4-sulfate and chondroitin-6-sulfate solutions

The differences in the structure of polymer chain between the chondroitin-4-sulfate (C4-S) and the chondroitin-6-sulfate (C6-S) are reflected in the intrinsic viscosity values calculated starting from the traditional methods of Huggins, Kraemer, Mead and Fouss, and Martin, and by the method for a single-point determination of intrinsic viscosity [eta]. For the range between 0.4 and 0.5% (w/v) concentrations, we get an agreement in the intrinsic viscosity values. The chains of both polymers present a flexible structure and are not ramified between 0.28 and 1.00% (w/v) concentrations.

NMR studies of oligosaccharides derived from hyaluronate: complete assignment of 1H and 13C NMR spectra of aqueous di- and tetra-saccharides, and comparison of chemical shifts for oligosaccharides of increasing degree of polymerisation

A series of oligosaccharides was prepared from hyaluronate by depolymerisation with bovine testicular hyaluronidase. Complete assignment of the 1H and 13C NMR spectra was obtained for the disaccharide, the tetrasaccharide, and the NaBH4-treated tetrasaccharide, by using various 1D and 2D NMR methods. The 1H assignments for the tetrasaccharide differ from the incomplete data reported recently (ref. 11). The 13C NMR spectra of the aqueous di-, tetra-, hexa-, and octa-saccharides of this series show that all resonances, apart from those subject to obvious end effects, have chemical shifts comparable to those of the corresponding resonances of hyaluronate in D2O. The observed 13C chemical shifts suggests that cooperative intramolecular hydrogen bonds probably play a minor role in determining the conformation of hyaluronate in water.

1H- and 13C-NMR studies of solutions of hyaluronic acid esters and salts in methyl sulfoxide: comparison of hydrogen-bond patterns and conformational behaviour

The 1H- and 13C-NMR spectra of the ethyl and benzyl esters and the tetrabutylammonium and tetraethylammonium salts of hyaluronic acid [[symbol: see text]2)-beta-D-GcpA+-1----3)-beta-D-GlcpNAc-(1[symbol: see text]n] in Me2SO-d6 have been assigned using 1D and 2D techniques. The chemical shifts of the resonance of GlcNAc C-3 suggest that the relative orientations of the monosaccharides at the (1----3) linkage in the esters and salts are different. Small differences in the chemical shifts of the resonance GlcA C-4 suggest only a slight conformational variation around the (1----4) linkage. The 13C-NMR data also suggest similarities in conformation between the esters in Me2SO-d6 and the salts in water. The chemical shifts of the 1H resonances for NH and OH groups and their temperature dependence for the esters and salts in Me2SO reveal markedly stronger inter-residue hydrogen bonds between the carboxyl and NH groups and between HO-4 of GlcA and O-5 of GlcNAc for the salts. The 3J2,NH values indicate a slightly different orientation for the acetamido group. For solutions in Me2SO, the higher segmental flexibility of the esters is supported by the line widths, whereas the reduced viscosity for the tetrabutylammonium salt showed a sigmoidal concentration dependence and suggests association of chains which could contribute to the segmental rigidity. The linear concentration dependence for the benzyl ester suggests a higher overall flexibility without chain association.

1H NMR studies of a biosynthetic lacto-ganglio hybrid glycosphingolipid: confirmation of structure, interpretation of "anomalous" chemical shifts, and evidence for interresidue amide-amide hydrogen bonding

Glycosphingolipids bearing GlcNAc beta 1----3 and GalNAc beta 1----4 linked to beta-Gal of lactosylceramide (lacto-ganglio hybrids), first isolated from a murine myelogenous leukemia cell line [Kannagi, R., Levery, S. B., & Hakomori, S. (1984) J. Biol. Chem. 259, 8444-8451], have since been found as normal components of mullet roe and English sole liver. In order to clarify the biosynthetic pathways responsible for its occurrence both as a product of normal tissues and as a possible mammalian cancer-associated antigen, the lacto-ganglio hybrid core structure LcGg4Cer was synthesized from Lc3Cer using a GalNAc beta 1----4 transferase preparation from English sole liver. A preliminary characterization of the enzyme, which may be identical to the GalNAc T-1 responsible for synthesis of GM2 ganglioside, is presented. The enzymatically synthesized product was analyzed by 1- and 2-D 1H NMR spectroscopy, confirmining its primary structure as GalNAc beta 1----4-(GlcNAc beta 1----3)Gal beta 1----4Glc beta 1----1Cer. In addition to assigning all nonexchangeable glycosyl proton resonances, measurements of several properties of the amide NH protons, including chemical shift, coupling constants, exchange rates, and temperature shift coefficients, were obtained and compared to those in the simpler constituent triglycosylceramides, Lc3- and Gg3Cer. An approximate three-dimensional structure for LcGg4Cer is proposed, consistent with all data obtained, which should be useful in discussing the results of 1H NMR analysis of compounds containing this core tetrasaccharide. The structure is characterized by an unusual arrangement of terminal N-acetylhexosamine residues, resulting in a pi-H hydrogen-bonding interaction between their acetamido groups.

1H-NMR study of GM2 ganglioside: evidence that an interresidue amide-carboxyl hydrogen bond contributes to stabilization of a preferred conformation

Several properties of the exchangeable amide protons of the ganglioside GM2 were studied in detail by 1H-NMR spectroscopy in fully deuterated dimethylsulfoxide [2H6]DMSO/2% H2O, and compared with data obtained for the simpler constituent glycosphingolipids GA2 and GM3. In addition to chemical shifts, 3J2,HN coupling constants, and temperature shift coefficients, the kinetics of NH/2H chemical exchange were examined by following the disappearance of the amide resonances in [2H6]DMSO/2% 2H2O. The results included observation of an increase in half-life of the N-acetylgalactosamine acetamido HN by more than an order of magnitude in GM2 compared to GA2, attributable to the presence of the additional N-acetylneuraminic acid residue. Additional one-dimensional dipolar cross relaxation experiments were also performed on nonexchangeable protons of GM2. The results of all of these experiments support a three-dimensional model for the terminal trisaccharide in which a hydrogen bond is formed between the N-acetylgalactosamine acetamido NH and the N-acetylneuraminic acid carboxyl group. The interaction is proposed to be of the pi-acceptor type, a possibility which has not yet been explored in the literature on carbohydrates. The proposed model is discussed in comparison with that of Sabesan et al. (1984, Can J Chem 62:1034-45), and the models of GM1 proposed more recently by Acquotti et al. (1990, J Am Chem Soc 112:7772-8) and Scarsdale et al. (1990, Biochemistry 29:9843-55).

Partial characterization of dermatan sulfate by proton nuclear magnetic resonance spectroscopy

The degree of galactosamine N-acetylation, iduronic acid composition, and total uronic acid/hexosamine ratios of the three dermatan sulfates of human skin, DS18, DS28, and DS35 (M. O. Longas et al. (1987) Carbohydr. Res. 159, 127-136), were determined by Fourier transform, proton nuclear magnetic resonance (FT 1H NMR) spectroscopy. Analysis of DS of varying ages was conducted at 400 MHz and 60 degrees C. Chemical shifts for H-1, H-2, H-4, and H-5 of L-IdUA were independent of those for the respective protons of D-GalNAc and D-GlcUA. The resonance intensities of H-1 and acetamido methyl protons of D-GalNac did not display the expected 1:3 ratios. Therefore, their integration values were employed to estimate the percentage N-acetylation (N-CH3/3 H-1) which was corroborated chemically. The L-IdUA content, relative to total uronic acid, was calculated from signal intensities of H-1 of L-IdUA and D-GlcUA and ascertained by quantitative chemical methods. Total uronic acid/hexosamine ratios were determined from both 1H NMR spectroscopy and chemical analyses. The data show the following N-acetylation (N-CH3/3 H-1) of galactosamine in DS:DS18, 61-72% between 17 and 60 years, unaffected by senescence; DS28, 78-86% with no age-related trend; DS35, 101% at 19 years. Furthermore, in all ages investigated, the percentage (wt/wt) L-IdUA relative to total uronic acid was 42-44% for DS18 and 37-40% for DS28. At age 19 years, DS35 had a 29% (wt/wt) L-IdUA. The total uronic acid/hexosamine ratios for DS18 and DS28 varied from 1.40:1.0 to 1.70:1.0 irrespective of age.

The effects of pH on hyaluronate as observed by light scattering

Hyaluronate was investigated over a wide pH range, and at near zero and intermediate ionic strength, using dynamic and total intensity light scattering. Commercially obtained rooster comb hyaluronate was purified, and solutions were prepared in pure water by low-power bath ultrasonication and subsequent filtering. These solutions were of low polydispersity and appeared to contain single molecules of hyaluronate. Despite the absence of added electrolyte, these solutions yielded well-behaved Zimm plots. Increasing ionic strength and changing pH decreased radii of gyration and increased diffusion constants. Except for what appeared to be slow hydrolysis at either extreme of pH, molecular weights remained constant under all pH and ionic strength conditions. Under all solvent conditions investigated, diffusion coefficients increased with decreasing hyaluronate concentration. Unsonicated, lightly centrifuged solutions without added electrolyte were polydisperse, and their light scattering intensity was dominated by what appeared to be stable hyaluronate aggregates. The results are interpreted in terms of the polyelectrolyte properties of hyaluronate and its tendency to form stable entanglements, especially at low ionic strength. Previous light scattering studies in the literature on hyaluronate have shown widely varying results. The present article briefly reviews this literature and attempts to explain the variation among the previous results, emphasizing the Kuhn statistical segment length as an indicator of whether results are influenced by polydispersity or contaminants causing hyaluronate aggregation.

Glycosaminoglycan conformations and changes on periodate oxidation

The progressive periodate oxidation of glycosaminoglycans (GAG), including hyaluronate (HA), chondroitins (CH) (chondroitin, chondroitin 4- and 6-sulfate), dermatan sulfate (DS), and keratan sulfate (KS), were monitored by CD and high performance liquid chromatography (HPLC) using a size-exclusion column. The rate of oxidation also was measured and calculated using first- and second-order kinetics, and the data appear to fit better with first-order kinetics. In both HA and CH, the n - pi amide band at 208 nm decreases in intensity upon oxidation, but in HA it becomes positive after 16 h of periodate treatment. In CH, the band disappears, and the pi - pi amide band below 200 nm becomes optically active. Concomitantly, a second negative band near 290 nm appears for these two oxidized GAG. Oxidation causes a slight change in the CD of DS. It ordinarily displays a very weak n - pi band at 210 nm, but instead shows an intense pi - pi amide band near 190 nm. CD of KS remains unaffected by periodate. Kinetic studies, however, show a higher oxidation rate for DS than HA and CH. With the exception of KS, all other oxidized polymers shown an apparent decrease in molecular weight (higher peak retention time) in HPLC analysis. Both CD and HPLC results have been attributed to a major conformational change of HA and CH, and a minor one for DS. The ease and extent of periodate oxidation as well as the changes in molecular properties following periodate treatment are critically dependent on the configuration of the individual GAG rather than the oxidation rate. There is a distinct difference in the conformational change between HA and CH, as manifested by their dichroic behavior, that was attributed to the equatorial disposition of C-4 hydroxyl group in HA and axial disposition CH.

Vacuum ultraviolet circular dichroism of keratan sulfate

The vacuum ultraviolet CD of keratan sulfate reveals an intense negative CD band at 171 nm. Its intensity can be rationalized with a recently proposed quadrant rule in terms of the acetamido group being slightly tilted toward the hexosaminidic linkage oxygen. The same structural feature accounts for the particularly intense negative n-pi CD band near 210 nm.

Proton nuclear magnetic resonance measurement of the amide hydrogen exchange rates of group A streptococcal polysaccharide in H2O

The solvent exchange rates of the acetamido hydrogen of the 2-acetamido-2-deoxy-beta-D-glucopyranosyl unit of group A streptococcal polysaccharide dissolved in H2O have been measured and compared with the corresponding exchange rates in the solvated model compound 1-O-methyl-2-acetamido-2-deoxy-beta-D-glucopyranoside. Amide hydrogen exchange rates were measured at 25 degrees C over a wide pH range by a combination of two separate NMR techniques: the transfer of solvent saturation and the amide hydrogen saturation recovery NMR experiments. The data indicate that the acetamido hydrogen essentially exists in a solvated environment and that its contribution to the conformational stability of this polysaccharide through intramolecular hydrogen bonding is negligible.

Cationic dye binding by hyaluronate fragments: dependence on hyaluronate chain length

Sodium hyaluronate, digested with bovine testicular hyaluronidase, yielded a mixture of oligosaccharides with identical repeating disaccharide structures and differing molecular weights. The oligosaccharides were separated into a ladder-like series of bands by electrophoresis on a 10% polyacrylamide gel matrix. Coelectrophoresis of purified oligosaccharides has established that adjacent bands differ in chain length by one disaccharide unit. This procedure formed the basis for a rapid screening method in which the binding of cationic dyes by hyaluronate oligosaccharides may be assayed. As a function of chain length, the oligosaccharides showed a marked change in dye binding. Species containing less than seven repeating disaccharide units are not detected by any dye tested, even at very high sample loads. Larger oligosaccharides show an increase in dye binding. The chain length at which constant maximal dye binding is reached depends on the dye structure and solvent conditions, varying from approximately 12 to 30 disaccharide units. The hyaluronate fragments of sufficient chain length to duplicate polymer behavior should be useful models for the study of hyaluronate structure and interactions in solution.

Secondary structure of hyaluronate in solution. A 1H-n.m.r. investigation at 300 and 500 MHz in [2H6]dimethyl sulphoxide solution

The 1H-n.m.r. spectra of solutions in [2H6]dimethyl sulphoxide of the sodium salts of tetra-, hexa- and octa-saccharides prepared from hyaluronate by testicular-hyaluronidase digestion were examined at 300 and 500 MHz. The signals from hydroxy groups at positions 2 and 3 in the glucuronic acid moiety were assigned. Their chemical shifts and associated temperature-dependencies, as well as their coupling constants, depended on whether or not the uronic acid was at the non-reducing end. Deviations from the 'normal' pattern of hydroxy-group proton n.m.r. behaviour were attributable to participation in hydrogen bonds, either to the acetamido carbonyl oxygen atom or the pyranose ring oxygen atom of neighbouring N-acetylhexosamine moieties. A secondary structure, containing four different hydrogen bonds per trisaccharide unit of glucuronsyl-hexosaminyl-glucuronic acid, was demonstrated. This is the first complete and detailed secondary structure to be established for hyaluronate in any solvent. Hyaluronate is compared with chondroitin sulphate, dermatan sulphate, heparan sulphate and keratan sulphate in their potential to form secondary structures with features in common. The significance of the details of the structure to its overall stability, and the probability of their persistence into aqueous environments, are discussed. The presence of all or most of the secondary structure in glycosaminoglycuronans is correlated with a space-filling function in the tissue, and with a high carbohydrate content in the parent proteoglycan in the case of the chondroitin sulphates.

1H NMR of glycosaminoglycans and hyaluronic acid oligosaccharides in aqueous solution: the amide proton environment

The exchangeable amide protons of hyaluronic acid (HA) oligosaccharides and a higher-molecular-weight segment dissolved in H2O at pH 2.5 or 5.5 were examined by H NMR spectroscopy at 250 MHz. The HA segment preparation showed a single amide resonance, near the chemical shift for the amide proton of the monosaccharide 2-acetamido-2-deoxy-beta-D-glucopyranose (beta-GlcNAc). Smaller HA oligosaccharides showed two or three separate amide proton resonances, corresponding in relative peak area to interior or end GlcNAc residues. The interior GlcNAc amide resonance occurred at the same chemical shift as the single resonance of the HA segment. For the end GlcNAc residues, linkage to D-glucuronopyranose (GlcUA) through C1 resulted in an upfield shift relative to the beta-anomer of GlcNAc, whereas linkage through C3 resulted in a downfield shift relative to the corresponding anomer of GlcNAc. These chemical-shift perturbations appeared to be approximately offsetting in the case of linkage at both positions. The amide proton vicinal coupling constant (ca. 9 Hz) was found to be essentially independent of chain length, residue position, or solution pH. These data favor a nearly perpendicular orientation for the acetamido group with respect to the sugar ring, little affected by linkage of GlcNAc to GlcUA. No evidence for the existence of a stable hydrogen bond linking the amide proton with the carboxyl(ate) oxygen of the adjacent uronic acid residue was found. The amide proton resonances for chondroitin, chondroitin 4-sulfate, and dermatan sulfate were compared to that of HA. The chemical shifts of these resonances deviated no more than 0.1 ppm from that of HA. A small dependence on the identity of the adjacent uronic acid residue was noted, based on the observation of two resonances for dermatan sulfate.

Chondroitin 4-sulfate: comparison of the structures of the potassium and sodium salts

Analysis of the X-ray diffraction pattern from an oriented, polycrystalline fiber of a potassium chondroitin 4-sulfate proteoglycan shows that the polysaccharide chains have a left-handed 3-fold helical secondary structure stabilized by intra- and intermolecular hydrogen bonds. Two antiparallel chains pass through each trigonal unit cell, which has dimensions a = b = 1.385 nm, c = 2.776 nm and space group symmetry P3(2)21. The cations and water molecules in the crystals are not all periodic and only one potassium ion and four water molecules per disaccharide were located by difference Fourier methods. Sodium chondroitin 4-sulfate forms an analogous structure with polyanions of similar geometry. However, the packing arrangements in the two salts are quite different, presumably because of the different co-ordination preference of K+ and Na+. Thus the relatively small differences between these two cations are greatly amplified by the idiosyncratic polymer networks they promote.

Secondary structure of chondroitin sulphate in dimethyl sulphoxide

1H NMR spectra were obtained in fully deuterated dimethyl sulphoxide of sodium chondroitin 4-sulphate and of the tetrasaccharide, hexasaccharide and octasaccharide prepared from it. Two types of NH resonance were observed, at 7.6 ppm and 8.8 ppm. The latter was the only one in the polymer spectrum, whereas both were present in the oligomer spectra: N-acetylchondrosinate produced only the 7.6-ppm signal. The upfield resonance (7.6 ppm) is characteristic of "normal", monomeric acetamido sugars and disaccharides, while the downfield resonance (8.8 ppm) suggests a hydrogen-bonded NH. The elongation of disaccharide to tetrasaccharide produces a new environment, involving a hydrogen bond at the non-reducing disaccharide NH. A structure, with three hydrogen bonds per tetrasaccharide unit, is proposed which accounts for the quantitative and qualitative aspects of the NMR spectra of polymers and oligomers. A laser light-scattering study showed that sodium chondroitin 4-sulphate has the same molecular weight in water as in dimethyl sulphoxide. The observed hydrogen bonds are therefore intramolecular, as required by the proposed structure, and probably exist in water as well as in dimethyl sulphoxide.

Detection of secondary structure in glycosaminoglycans via the H n.m.r. signal of the acetamido NH group

Two simple methods for dissolving salts of acid glycosaminoglycans with inorganic cations (e.g. Li+ and Na+) in dry dimethyl sulphoxide are described. Complete n.m.r. spectra of, e.g., Na+ and Li+ salts of chondroitin sulphate and keratan sulphate were obtained on these solutions. In [2H6]dimethyl sulphoxide the NH resonance of 2-acetamido-2-deoxy hexosides is in the range 7.2-8.0 delta, but is downfield (8.3-9.3 delta) when the NH is H-bonded to -CO2-. Heparan sulphate shows two NH resonances, of which one (at 8.3 delta) is probably indicative of H-bonding. Space-filling models show that a very close approach of NH to -CO2- across the alpha-glucosaminidic bond is possible, and a solution configuration for heparan sulphate is proposed. The n.m.r. results are entirely compatible with interpretations of periodate-oxidation kinetics, based on H-bonded secondary structures present in hyaluronate and chondroitin sulphates, but not in dermatan (or keratan) sulphate.