Alternate Amino Terminal Processing of Surfactant Protein A Results in Cysteinyl Isoforms Required for Multimer Formation

Abstract

The biological functions of rat surfactant protein A (SP-A), an oligomer composed of 18 polypeptide subunits derived from a single gene, are dependent on intact disulfide bonds. Reducible and collagenase-reversible covalent linkages of as many as six or more subunits in the molecule indicate the presence of at least two NH₂-terminal interchain disulfide bonds. However, the reported primary structure of rat SP-A predicts that only Cys⁶ in this region is available for interchain disulfide formation. Direct evidence for a second disulfide bridge was obtained by analyses of a set of three mutant SP-As with telescoping deletions from the reported NH₂-terminus. Two of the truncated recombinant proteins formed reducible dimers despite deletion of the domain containing Cys⁶. Edman degradation revealed that each mutant protein was a mixture of two isoforms with and without an isoleucine-lysine-cysteine (IKC) extension at the NH₂-terminus, which was derived from the COOH-terminal end of the reported signal peptide. Large variations in the abundance of the IKC isoforms between truncated SP-As suggested that the amino acid sequences located downstream from the signal peptide modulated alternate-site cleavage by signal peptidase. Elution of the newly identified cysteine in the position of DiPTH-Cys indicated participation in disulfide linkage, which was interchain based on the direct correlation between prevalence of the IKC variant and the extent of dimerization for each truncated protein. Sequencing of both native rat SP-A and human SP-A also revealed isoforms with disulfide-forming NH₂-terminal extensions. The extended rat SP-A isoforms were enriched in the more fully glycosylated and multimeric SP-A species separated on SDS−PAGE gels. Thus, a novel post translational modification results in naturally occurring cysteinyl isoforms of rat SP-A, which are essential for multimer formation.