Characterization of arsenite-complexed xanthine oxidase at room temperature. Spectral properties and pH-dependent redox behavior of the molybdenum-arsenite center

Several aspects of the interaction of xanthine oxidase with arsenite are investigated. Room temperature potentiometric titrations using EPR to monitor Molybdenum reduction reveal midpoint potentials of -225 mV for the Mo(VI)-arsenite/Mo(V)-arsenite couple and -440 mV for the Mo(V)-arsenite/Mo(IV)-arsenite couple at pH 8.3. Under the same conditions, the values for native enzyme are -395 mV and -420 mV, respectively. The predicted effects of the altered Mo(VI)/Mo(V) potential on the distributions of reducing equivalents in partially reduced enzyme are compared with the experimentally observed effects in optical experiments. The bleaching that occurs on reduction of the chromophore that is generated when arsenite binds to oxidized enzyme is characterized and found to be associated with reduction of Mo(V)-arsenite to Mo(V)-arsenite. This probe enables determination of the midpoint potential for this conversion using optical data. From such data at a series of pH values ranging from 6.15 to 9.9, a pH dependence of -60 mV/pH unit increase is determined for this couple above pH 7. The ability of arsenite to bind to reduced xanthine oxidase and to desulfo enzyme are also investigated. Reduced active enzyme binds arsenite much more tightly (Kd less than 0.1 microM) and more rapidly than does oxidized active enzyme (Kd = 8 microM); oxidized desulfo enzyme binds arsenite almost as tightly (Kd = 20 microM) as does the oxidized active enzyme.     

Surface activation of pro-cathepsin L.

Pro-cathepsin L is an inactive zymogen that has been shown previously to undergo autolysis at pH 3.0 to give mature forms of the enzyme. We have now been able to demonstrate that this enzyme can undergo activation at pH 5.5 in the presence of negatively charged surfaces. Activation could also be measured at pH 6.0, but no activation occurred at pH 6.5 or higher. The initiation of activation depends upon the presence of a small percentage of active pro-enzyme, and this is then followed by a more rapid activation to give mature forms of the enzyme. No significant intermediate molecular forms of the enzyme were seen. The time taken for processing of the pro-enzyme to single-chain mature enzyme is comparable to that seen in biosynthetic pulse-chase experiments.     

Kynuramine, a fluorescent substrate and probe of plasma amine oxidase

The fluorescence substrate kynuramine was used as a probe of the catalytic site of plasma amine oxidase. Under anaerobic conditions, the binding of kynuramine causes several spectroscopic changes. The Stokes shift (deltav = 5326 cm-) associated with binding of the substrate to the enzyme can be attributed to nonpolar properties of the binding site, whereas the increase in emission anisotropy (A = 33) indicates rigid attachment of the substrate to the enzyme. The fluorescence enhancement that follows the binding of substrate was used to determine the association constant (Ka). The enzyme plasma amine oxidase binds only 1 molecule of substrate with a Ka = 1.8 X 10(5) M-1 under anaerobic conditions. The use of fluorescence substrates seems to offer the possibility of monitoring conformational changes occurring prior to the catalytic event.