Catalytic influence of heparin on auramine O hydrolysis: a basis for differentiating heparin from other glycosaminoglycans based on its properties as a polyelectrolyte

Catalytic Effects of Different Heparin Analogs on the Hydrolysis of Auramine O

Glycosaminoglycans, such as heparin, are a class of biomaterials with a variety of important biological functions. They were found to catalyze the hydrolysis of 4,4'-(imidocarbonyl)-bis(N,N-dimethylaniline) monohydrochloride to 4,4'-bis(dimethy-lamino) benzophenone, but the catalytic mechanism of this interesting reaction is poorly understood, mainly due to the structural complexity of polysaccharides. In order to study such an unusual reaction, a pentasaccharide, fondaparinux, with defined chemical structure was chosen as a probe to investigate the hydrolytic characteristics, along with other heparin analogs. The hydrolytic reaction was catalyzed by fondaparinux, low-molecular-weight heparins, heparin and different desulfated heparins at various rates. The present results demonstrated that the length of polysaccharide chain, the N- or O-sulfo groups are critical to the hydrolysis of 4,4'-(imidocarbonyl)-bis(N,N-dimethy-laniline) monohydrochloride in addition to pH and ionic strength, which provides new insights into the catalytic phenomenon of polysaccharides.

Metal-binding properties of the isolated glomerular basement membrane

The nature of binding of metal cations to the glomerular basement membrane has been investigated using isolated bovine glomerular basement membrane. Highest-affinity binding for a number of ions is attributable to the glycosaminoglycans (mostly heparan sulfate) of the membrane. Some ions, such as divalent Mn, Ca and Ni, have specific binding sites on these polymers, while for others the ion-polyelectrolyte interaction is of a non-specific nature. Both structural and binding data indicate a linear charge density of close to unity for the heparan sulfate of the glomerular basement membrane, which at the ionic composition of the plasma filtrate corresponds to a polymer surface potential of about -45 mV. Several independent observations are better explained by a model of counter-ion condensation about the glycosaminoglycans than by conventional double layer theories. These include the valence dependence of ion binding, the sharp ejection of divalent ions at a critical concentration of La3+, and the relative insensitivity of 63Ni2+ binding to NaCl concentration in the neighbourhood of physiological ionic strength. In its interactions with metal ions, the glomerular basement membrane behaves like a dilute solution of polyelectrolytes. This conclusion has important consequences for the extent of charge reduction of the filtration barrier of the kidney, bathed as it is in an electrolyte solution of mainly monovalent salts.