Abstract
Fibrinogen is a plasma protein consisting of six polypeptide chains which are linked by disulfide bonds. During protein synthesis, assembly of the molecule proceeds through the formation of alphagamma and betagamma heterodimers followed by the generation of alphabetagamma half-molecules and dimerizing to generate the mature six-chain molecule. In the present study, sequences required for the formation of the alphagamma and betagamma heterodimers were examined in stably transfected baby hamster kidney cells expressing combinations of normal as well as modified polypeptide chains. Deletion of the amino terminus and the proximal first half of the coiled-coil region of the three fibrinogen chains had little or no effect on heterodimer and half-molecule formation. These deletions, however, did prevent half-molecules from forming the six-chain molecule. Deletion of the distal second half of the coiled-coil region of each chain completely prevented the assembly process. Point mutations in the second half of the coiled-coil region also indicated that hydrophilic residues that form ion pairs between interacting chains were not critical in the formation of the heterodimeric complexes. These results suggest that the initial formation of the alphagamma and betagamma complexes depends primarily on hydrophobic interactions of amino acids located in the second half of the coiled-coil region of the molecule. These interactions occur in the rough endoplasmic reticulum in the presence of various chaperones such as BiP.
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