V. Talesa et al., PRESENCE OF SOLUBLE TETRAMERIC (BLOOD) AND MEMBRANE-BOUND DIMERIC FORMS OF CHOLINESTERASE IN THE MOLLUSK MUREX BRANDARIS (GASTROPODA, NEOGASTROPODA), The Journal of experimental zoology, 270(3), 1994, pp. 233-244
In the marine snail Murex brandaris about 80% of cholinesterase (ChE)
activity lies in the blood. It can be recovered as a fully soluble (FS
) form by mincing the whole animal. Two more ChE forms, detergent (DS)
and high-salt soluble (HSS) (18 and 2% of total ChE activity, respect
ively), can then be sequentially extracted from the other tissues. FS
and DS ChEs were purified to homogeneity by affinity chromatography on
procainamide- or edrophonium-Sepharose respectively. The small amount
of HSS prevented a similar purification and an extensive characteriza
tion. According to density gradient centrifugation, gel-filtration chr
omatography, and SDS-PAGE, FS ChE is likely a globular tetramer of a 6
6 kDa subunit (10.8 sedimentation constant [S], 270 kDa). Moreover, it
is an amphiphilic form including a hydrophobic domain. DS ChE appears
to be a globular dimer of a 66 kDa subunit (5.6 S, 137 kDa). The amph
iphilicity of this enzyme is likely due to a phosphatidylinositol on t
he catalytic subunits, also responsible for detergent interaction as w
ell as cell membrane insertion. Both FS and DS forms hydrolyze propion
ylthiocholine faster than other choline thioester substrates. They als
o show high catalytic efficiency with other choline esters as substrat
es, likely due to a wide and relatively unspecialized conformation of
the active site. Immunological cross-reactivity showed wide structural
affinity between FS and DS forms. Antibody-enzyme bond gave partial i
nactivation. On the whole, the results suggest that both FS and DS for
ms likely originate from only one gene. Differences in quaternary stru
cture and solubility could reflect posttranslational modifications or
alternative splicing. (C) 1994 Wiley-Liss, Inc.