Laser light scattering measurements on vitreous and rooster comb hyaluronic acids

Molecular weights and translational diffusion coefficients have been measured for rooster comb and vitreous hyaluronic acid (HA) at pH 7.2 and 11. The results indicate that the molecular weight, second virial coefficient and translational diffusion coefficient for vitreous HA can be reversibly decreased by increasing the solution pH from 7.2 to 11, whereas the physical properties of rooster comb HA are independent of pH studied. In addition, it is reported that the second virial coefficient for vitreous HA is negative, suggesting intermolecular interactions exist in solution at both neutral and alkaline pH as opposed to rooster comb HA which exhibits a positive second vitrial coefficient associated with decreasing molecular weights may be related to the accessibility and number of hydrogen bond forming groups. Differences in the dependence of molecular weight on pH between vitreous and rooster comb HA may be due to differences in the number of intramolecular interactions per molecule. These studies indicate that molecules of low molecular weight HA are able to form higher molecular weight complexes and differences in the organization of the polysaccharide chains may contribute to the differences in molecular weight of HAs isolated from various tissues.     

The effect of testosterone on ascorbic acid synthesis in rooster comb

The level of “total” ascorbic acid (ascorbate+dehydroascorbate) has been measured in the mucoid layer of combs from normal roosters, capons and capons treated with testosterone. The “total” ascorbate level in capon comb was lower than the value obtained from combs from normal roosters. This value returned towards normal in combs from capons treated with testosterone. The specific activity of L-gulonate-NADP⁺ oxidoreductase, an enzyme in the pathway of ascorbate biosynthesis, also was measured. The specific activity levels followed a pattern similar to the ascorbate levels in the three types of combs utilized. The results are consistent with the possible role of L-ascorbic acid as a cofactor in the synthesis of collagen, a process which also appears to be dependent on the level of testosterone in the comb mucoid layer.     

Studies on the affinity of hyaluronic acid binding protein to glycosaminoglycans

The affinity of hyaluronic acid binding protein (HBP) to different glycosaminoglycans (GAGs) was examined. The purified protein was pretreated with hyaluronic acid (HA), heparin, glucuronic acid and N-Acetyl-glucosamine and was loaded onto Hyaluronate-Sepharose affinity column. The binding of HBP to HA immobilized on sepharose column was specifically blocked only by pretreatment of HBP to HA and the elution of HBP was decreased proportionately with the addition of higher quantity of HBP. The specificity of HBP to HA was confirmed as it did not bind to Heparin-Sepharose or Chondroitin-4-Sulphate-Sepharose columns. The complex of HBP in association with HA was further shown on Sephadex G-200 and 7.5% polyacrylamide gel. All the experimental findings indicate that HBP binds specifically to HA only.     

Studies on the structure of hyaluronic acid. Characterization of the product formed when hyaluronic acid is treated with ascorbic acid

Physical and chemical methods were used to characterize hyaluronic acid before (fraction HAIIBI) and after (fraction HA-AA) treatment with ascorbic acid. Fraction HA-AA was recovered with an almost quantitative yield and was shown to be chemically identical with fraction HAIIBI by all the methods used. These two materials, however, differed markedly in their molecular sizes and degree of polydispersity. By using sedimentation, diffusion and sedimentation-equilibrium analyses, weight-average molecular weights of about 1.2x10(6) and 6.5x10(4) respectively were obtained for fractions HAIIBI and HA-AA. It is concluded from these results that hyaluronic acid has a molecular weight of about 65000 and that the polysaccharide chain of this molecule is not depolymerized by ascorbic acid. It is further proposed that hyaluronic acid molecules in the matrix of connective tissues are present either in an aggregated form or as subunits of heterogeneous macromolecules, and that it is the linkages responsible for the organization of these structures which are broken by ascorbic acid.     

Heat capacities of solid poly(amino acid)s. II. The remaining polymers

In the first paper heat capacities C_p, of polyglycine, poly(L -alanine), and poly (L -valine) were analyzed using approximate group vibrations and fitting the C_p contributions of the skeletal vibrations to a two-parameter Tarasov function. In this second paper all other poly (amino acid) s are similarly analyzed. Heat capacities were measured by differential scanning calorimetry in the temperature range of 230–390 K for poly(L -leucine), poly(L -serine), poly (sodium-L -aspartate), poly(sodium-L -glutamate), poly(L -asparagine), poly(L -phenylalanine), poly(L -tyrosine), poly(L -methionine), poly (L -tryptophane), poly(L -proline), poly(L -lysine · HBr), poly(L -histidine), poly(L -histidine- HCl), and poly(L -arginine · HCl). Good agreement exists between experiment and calculation. Predictions of heat capacities were made for all not-measured poly (amino acid) s. Enthalpies, entropies, and Gibbs functions for the solid state have been derived. © 1993 John Wiley & Sons, Inc.     

Cu(II) and Zn(II) complexes with hyaluronic acid and its sulphated derivative. Effect on the motility of vascular endothelial cells

With the aim of improving the compatibility of biomaterials to be used for the construction of cardiovascular prosthesis, we have designed bioactive macromolecules resulting from chemical modifications of hyaluronic acid (Hyal). The stability constants of Cu(II) and Zn(II) complexes with the sulphated derivative of hyaluronic acid (HyalS3.5) were evaluated. Two different complexes have been found for each metal ion, CuL, Cu(OH)2L and ZnL, Zn(OH)2L (L means the disaccharide unit of the ligands) in aqueous solution at 37 degrees C. The dihydroxo Cu(II) complex was present in high percentage at pH=7.4. On the contrary, the Zn(II) ion was present with a relatively low percentage of both complexes. The ability to stimulate endothelial cell adhesion and migration was evaluated for Hyal, HyalS3.5 and their complexes with Cu(II) and Zn(II) ions. The results revealed that Hyal and [Cu(OH)2HyalS3.5](4.5)- induced cell adhesion, while [ZnHyalS3.5](2.5)- and [Zn(OH)2HyalS3.5](4.5)- inhibited the process. The chemotactic activity of increasing concentrations of the above complexes was also evaluated, demonstrating that [Cu(OH)2HyalS3.5](4.5)- complex at 1 microM concentration was the most active in inducing cell migration. These results have been also strengthened by analysing adherent cell migration in agarose. In conclusion, sulphated hyaluronic acid coordinated to Cu(II) seems to be a promising matrix molecule for the construction of cardiovascular prosthesis.     

Metal ion coordination of macromolecular bioligands: formation of zinc(II) complex of hyaluronic acid.

The coordination of zinc(II) ion to hyaluronate (Hya), a natural copolymer, in aqueous solution at pH 6 was investigated by potentiometric and circular dichroism (CD) spectroscopic methods, and by monitoring the changes in macroscopic properties by high-precision measurements. The zinc(II)-selective electrode, and CD measurements proved the binding of zinc(II) by Hya. A number of Hya fragments (Mr approximately 3.3 x 10(3)-1.4 x 10(6)) were studied to estimate the contributions of the polyelectrolyte effect, the solvation and host-guest interactions to the extra stabilization of the macromolecular zinc(II) complexes as compared with the monomeric unit. The zinc(II) ion activity increase reflected a stability decrease for the fragments with Mr < 4 x 10(4). This molecular weight differs from that where cleavage of the Hya skeleton starts (approximately 5 x 10(5), according to the size-exclusion gel, and anion-exchange chromatographic behavior of the Hya fragments) and from that where the polyelectrolyte effect stops (approximately 6 x 10(3)). The excess volumes and Bingham shear yield values of the solutions revealed the transformation of the coherent random coil structure stabilized by intermolecular association in the NaHya to an intramolecular association producing the globular structure of the ZnHya molecule, with a smaller but more strongly bound solvate water sheet.