Isolation by zinc-affinity chromatography of the histidine–proline-rich-glycoprotein molecule associated with rabbit skeletal muscle AMP deaminase: Evidence that the formation of a protein–protein complex between the catalytic subunit and the novel component is critical for the stability of the enzyme

Abstract

The histidine–proline-rich glycoprotein (HPRG) component of rabbit skeletal muscle AMP deaminase under denaturing and reducing conditions specifically binds to a Zn 2+-charged affinity column and is only eluted with an EDTA-containing buffer that strips Zn 2+ from the gel. The isolated protein is homogeneous showing an apparent molecular weight (MW) of 95 000 and the N-terminal sequence L-T-P-T-D-X-K-T-T-K-P-L-A-E-K-A-L-D-L-I, corresponding to that of rabbit plasma HPRG. The incubation with peptide- N-glycosidase F promotes the reduction of the apparent MW of isolated HPRG to 70 000, characterizing it as a N-glycosylated protein. The separation from AMP deaminase of an 85-kDa component with a blocked N terminus is observed when the enzyme is applied to the Zn-charged column under nondenaturing conditions. On storage under reducing conditions, this component undergoes an 85- to 95-kDa transition yielding a L-T-P-T-D-X-K-T-T-K-P-L N-terminal sequence, suggesting that the shift in the migration on SDS/PAGE as well as the truncation of the protein at its N terminus are promoted by the reduction of a disulfide bond present in freshly isolated HPRG. The separation of HPRG induces a marked reduction in the solubility of AMP deaminase, strongly suggesting a role of HPRG in assuring the molecular integrity of the enzyme.