Complexity in organic evolution

The present state of knowledge of the formation of the Compounds I of peroxidases and catalases is discussed in terms of the restrictions which must be placed upon a valid mechanism. It is likely that all Compounds I contain one oxygen atom bound to the heme-iron as in the Compound I of chloroperoxidase. Thus the formation of Compound I, obtained after molecular hydrogen peroxide and the enzyme diffuse together, involves a minimum of two bond ruptures and the formation of two new bonds. Yet this amazing reaction proceeds with an activation energy equal to or less than that for the fluidity of water. This result can only be accounted for by including at least one reversible step. Since Compound I formation requires the formation of an “inner sphere” complex, the presence or absence of water in the sixth co-ordination position of the heme-iron is of crucial importance. A comparison of the rates of ligand binding with the rate of Compound I formation indicate that the inner sphere complex leading to Compound I formation is formed by an excellent nucleophile, probably the peroxide anion, formed by a proton transfer from hydrogen peroxide. This proton cannot equilibrate with the bulk solvent. A proton derived from the active site would appear to be added to the hydroxide ion which permits a molecule of water to depart upon oxygen atom addition (or substitution) to (or at) the heme-iron. It is tentatively suggested that Compound I of catalase has a single active site per subunit molecule and that Compound I of peroxidase normally has two reactive sites.     

Migration inhibition by an agarose microdroplet assay: monitoring of tumor-associated antigens on a simian virus 40-induced sarcoma.

Macrophage migration inhibition assays, with a direct agarose microdroplet method, were used to monitor TAA activity of preparations of SV-40-induced mKSA cells. These preparations included cell-free crude membranes, papain-solubilized and NP40 detergent-solubilized membrane extracts from mKSA tumor cells. The assay was extremely sensitive and could detect migration inhibition reactivity with all three types of antigenic preparations with concentrations as low at 250 ng protein/ml. The reactivities were quite reproducible from experiment to experiment using the same or different lots of these antigen preparations, and the reactivities were specific in that peritoneal exudate cells from BALB/c mice, immunized with antigenically unrelated but syngeneic plasmacytomas, were not inhibited by these antigens. The results demonstrated the usefulness of this assay in rapidly detecting small concentrations of partially purified TAA preparations by using small number of immune cells.