The esterase-like activity of covalently bound human third complement protein

Abstract

The acyl ester bond between the third complement protein, C3, and a variety of molcules is hydrolyzed spontaneously at neutral pH (Venkatesh et al., 1984). Modification of the free, single sulfhydryl group of bound C3 by thiol reagents suggested that a functional group other than the —SH acts as a “catalytic” group in this intramolecular hydrolytic reaction. Complete inhibition of the esterase-like activity is observed with stoichiometric amounts of mercuric chloride, palladium chloride, and the bifunctional organic mercurial, 3,6-bis-(acetoxymercuri)- o-toluidine [BAMT]. Since alkyl and aryl mercuric ions do not inhibit the esterase-like activity of C3-[ 3H]glycerol, it is conjectured that divalent mercury, palladium, and BAMT will form a complex with the —SH group and an atom of the “catalytic” group X having a lone pair of electrons. The structural features of C3 that are essential for the esterase-like activity remain intact after subjecting C3-[ 3H]glycerol to covalent chromatography on organomercurial agarose. Based on the observed effects of chemical reagents and the kinetic deuterium solvent isotope effect on the esterase-like activity, a general-base mechanism is proposed for the intramolecular hydrolysis of the acyl ester bond in covalently bound C3. The “catalytic” group X is located in the C3d region (residues 317–632 of the α chain), since C3d-[ 3H]glycerol also has esterase-like activity. A general-base mechanism mediated by the same “catalytic” group X may also apply to the formation of acyl ester bonds following the hydrolysis of the internal thiolester bond in native C3.