LAUSR

BACKGROUND Streptokinase, one of the most widely used thrombolytic medicines, is a favorable protein for site-specific PEGylation as it lacks any cysteine residues in its amino acid sequence; however, any changes in the protein´s structure should be carefully planned to avoid undesired changes in its function. OBJECTIVES This study aimed to design and produce novel di/tri-cysteine variants of streptokinase from previously developed cysteine analogues, Arg45, Glu263, and Arg319, as candidates for multiple site-specific PEGylation. METHODS Using bioinformatics tools and site-directed mutagenesis, we incorporated concurrent mutations at Arg45, Glu263, and Arg319 (carried out in our previous study) to create di/tri-cysteine variants of streptokinase ‎proteins (SK45-319cys, SK263-319cys, and SK45-263-319cys) and evaluated their kinetic activity parameters by a colorimetric method, using H-D-Val-Leu-Lys-pNA.2HCl (S2251) as substrate. RESULTS Based on the kinetic results, SK263-319cys with 44% enzyme efficiency increment compared to wild-type SK was the superior protein in terms of activity; as well, SK45-319cys and SK45-263-319cys showed 17 and 22% activity enhancement, respectively. Docking of the mutant streptokinase proteins with µ-plasmin demonstrated that changes in intermolecular interactions caused by amino acid substitution could be the reason for activity difference. CONCLUSION The novel mutant proteins created in this study exhibit remarkable biological activity and may be uniquely suitable for simultaneous PEGylation on two/three domains. As well, PEGylated derivates of these variants might ‎prove to be more proficient proteins, compared to the single-cysteine analogs of streptokinase; because of‎ their more surface coverage and increased molecular weight.