NO is a bioactive free radical produced by NO synthase in various tissues including vascular endothelium. One of the degradation products of NO is HNO2, an agent known to degrade heparin and heparan sulphate. This report documents degradation of heparin by cultured endothelial-cell-derived as well as exogenous NO. An exogenous narrow molecular-mass preparation of heparin was recovered from the medium of cultured endothelial cells using strong-anion exchange. In addition, another narrow molecular-mass preparation of heparin was gassed with exogenous NO under argon. Degradation was evaluated by gel-filtration chromatography. Since HNO2 degrades heparin under acidic conditions, the reaction with NO gas was studied under various pH conditions. The results show that the degradation of exogenous heparin by endothelial cells is inhibited by NO synthase inhibitors. Exogenous NO gas at concentrations as low as 400 p.p.m. degrades heparin and heparan sulphate. Exogenous NO degrades heparin at neutral as well as acidic pH. Endothelial-cell-derived NO, as well as exogenous NO gas, did not degrade hyaluronan, an unrelated glycosaminoglycan that resists HNO2 degradation. Peroxynitrite, a metabolic product of the reaction of NO with superoxide, is an agent that degrades hyaluronan; however, peroxynitrite did not degrade heparin. Thus endothelial-cell-derived NO is capable of degrading heparin and heparan sulphate via HNO2 rather than peroxynitrite. These observations may be relevant to various pathophysiological processes in which extracellular matrix is degraded, such as bone development, apoptosis, tissue damage from inflammatory responses and possible release of growth factors and cytokines.
SUMMARY: Nitric oxide (NO) is a powerful vascular and neural regulator. One of the breakdown products of nitric oxide is nitrite which converts to nitrous acid, a reagent routinely used for the degradation of heparin and heparan sulfate. We have recently shown that nitric oxide gas degrades heparin and heparan sulfate through a nitrous acid mechanism (Vilar et al, 1997, Biochemical Journal, 324,473-479). The purpose of the present study is to confirm these findings using the nitric oxide donor S-nitroso-N-acetyl-D,L-penicillamine (SNAP) under conditions that are close to those found in vivo. The results show that 2 mM SNAP releases a steady-state level of nitrite of over 200 ~tM. This level substantially degrades heparin and heparan sulfate at a pH of up to 5.0. This reaction may be important in breakdown of the glycosaminoglycan components of the extracellular matrix during normal and pathological conditions.
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