Abstract
As one of the most extensively studied glycosaminoglycan lyases, heparinase I has been used in producing low or ultra-low molecular weight heparin. Its’ important applications are to neutralize the heparin in human blood and analyze heparin structure in the clinic. However, the low productivity and activity of the enzyme have greatly hindered its applications. In this study, a novel Hep-I from Bacteroides cellulosilyticus (BcHep-I) was successfully cloned and heterologously expressed in E. coli BL21 (DE3) as a soluble protein. The molecular mass and isoelectric point (pI) of the enzyme are 44.42 kDa and 9.02, respectively. And the characterization of BcHep-I after purified with Ni-NTA affinity chromatography suggested that it is a mesophilic enzyme. BcHep-I can be activated by 1 mM Ca2+, Mg2+, and Mn2+, while severely inhibited by Zn2+, Co2+, and EDTA. The specific activity of the enzyme was 738.3 U·mg-1 which is the highest activity ever reported. The Km and Vmax were calculated as 0.17 mg·mL-1 and 740.58 U·mg-1, respectively. Besides, the half-life of 300 min at 30°C showed BcHep-I has practical applications. Homology modeling and substrate docking revealed that Gln15, Lys74, Arg76, Lys104, Arg149, Gln208, Tyr336, Tyr342, and Lys338 were mainly involved in the substrate binding of Hep-I, and 11 hydrogen bonds were formed between heparin and the enzyme. These results indicated that BcHep-I with high activity has great potential applications in the industrial production of heparin, especially in the clinic to neutralize heparin.
Highlights
Heparinase I (Hep-I) was first isolated from Pedobacter heparinus [1]
It’s capable of cleaving heparin and heparan sulfate at the 1–4 linkages by β-elimination [2]
Cys135 and His203 are the vital nucleophile amino acids of FhHep-I in the endocytic cleavage of heparin [28], and Lys199 is one of two calcium-binding sites which are necessary for the maintenance of enzymatic activity of FhHep-I [29]
Summary
Heparinase I (Hep-I) was first isolated from Pedobacter heparinus (formerly known as Flavobacterium heparinum) [1]. It’s capable of cleaving heparin and heparan sulfate at the 1–4 linkages by β-elimination [2] This specific site recognition makes it a useful tool in various fields. It can be used for manufacturing low molecular weight or ultra-low molecular weight heparin in industry [3,4], and can be applied in analyzing heparin structure and contamination [5], eliminating the heparin in human blood [6].
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