Background: The transglutaminase activated factor XIII (FXIIIa) acts to strengthen pathological fibrin clots and to slow their dissolution, in part by crosslinking active alpha(2)-antiplasmin (alpha(2)AP) to fibrin. We previously reported that a yeast-derived recombinant fusion protein comprising alpha(2)AP residues 13-42 linked to human serum albumin (HSA) weakened in vitro clots but failed to become specifically incorporated into in vivo clots. In this study, our aims were to improve both the stability and clot localization of the HSA fusion protein by replacing alpha(2)AP residues 13-42 with shorter sequences recognized more effectively by FXIIIa.
Results: Expression plasmids were prepared encoding recombinant HSA with the following N-terminal 23 residue extensions: H(6)NQEQVSPLTLLAG(4)Y (designated XL1); H(6)DQMMLPWAVTLG(4)Y (XL2); H(6)WQHKIDLPYNGAG(4)Y (XL3); and their 17 residue non-His-tagged equivalents (XL4, XL5, and XL6). The HSA moiety of XL4- to XL6-HSA proteins was C-terminally His-tagged. All chimerae were efficiently secreted from transformed Pichia pastoris yeast except XL3 HSA, and following nickel chelate affinity purification were found to be intact by amino acid sequencing, as was an N-terminally His-tagged version of alpha(2)AP(13-42)-HSA. Of the proteins tested, XL5-HSA was cross-linked to biotin pentylamine (BPA) most rapidly by FXIIIa, and was the most effective competitor of alpha(2)AP crosslinking not only to BPA but also to plasma fibrin clots. In the mouse ferric chloride vena cava thrombosis model, radiolabeled XL5-HSA was retained in the clot to a greater extent than recombinant HSA. In the rabbit jugular vein stasis thrombosis model, XL5-HSA was also retained in the clot, in a urea-insensitive manner indicative of crosslinking to fibrin, to a greater extent than recombinant HSA.
Conclusions: Fusion protein XL5-HSA (DQMMLPWAVTLG(4)Y-HSAH(6)) was found to be more active as a substrate for FXIIIa-mediated transamidation than seven other candidate fusion proteins in vitro. The improved stability and reactivity of this chimeric protein was further evidenced by its incorporation into in vivo clots formed in thrombosis models in both mice and rabbits.

• 出版日期2011-12-20