Solid-phase Refolding of Immobilized Enterokinase for Fusion Protein Cleavage

융합단백질 절단반응을 위한 고정화된 enterokinase의 고체상 재접힘

  • 서창우 (한양대학교 화학공학과 생물공정연구실) ;
  • 나세진 (한양대학교 화학공학과 생물공정연구실) ;
  • 박신혜 (㈜대웅 생명공학연구소) ;
  • 박승국 (㈜대웅 생명공학연구소) ;
  • 이은규 (한양대학교 화학공학과 생물공정연구실)
  • Published : 2003.08.01

Abstract

Solid-phase refolding of immobilized proteins can be an effective way to reuse an immobilized enzyme column. Oriented immobilization methods are known to provide higher activity of the immobilized enzymes. In this study, using recombinant EK (enterokinase) as a model enzyme and a fusion protein, that consisted of recombinant human growth hormone and six His tag that was linked by the peptide of EK-specific recognition sequence, as a model substrate, we evaluated two oriented immobilization methods, i. e., reductive alkylation of N-terminus ${\alpha}$-amine and affinity interaction between poly-histidine tag and Ni-NTA (nickel-nitrilotriacetic acid). The immobilization yield, activity and cleavage of the immobilized enzymes, and the yield of solid-phase refolding were compared. The Ni affinity immobilization and the covalent immobilization yields were about 100% and 65%, respectively. But the specific activities were the same, about 50% of that of the soluble enzyme. The cleavage rate by the covalently immobilized EK was higher than the soluble enzyme and the side reaction of cryptic cleavage was significantly decreased. Covalently immobilized EK showed almost 100% refolding yield but the affinity immobilized EK showed only 70% yield, which suggested the covalent conjugation provided more rigid ‘reference structure’ for the solid-phase refolding. The monomeric hGH could be easily obtained by capturing the cleaved poly Histidine tag by the Ni affinity column.

융합단백질의 절단을 위해 EK를 고정화하여 액상 절단반응과 같은 80%의 절단수율을 얻을 수 있었다. 그리고 니켈 친화칼럼을 이용하여 간단한 정제공정을 구축하였다. 공유결합한 EK의 경우 니켈친화 결합한 EK보다 높은 재접힘 수율을 나타내었고 풀림과 재접힘을 이용하여 효소의 초기 활성을 회복함에 따라서 반복사용을 통한 경제적인 절단공정을 구축할 수 있게 되었다. 그러나 고정화 과정에서 효소의 활성이 감소하는 문제점과 고정화 수율을 높이기 위한 연구가 필요하다.

Keywords

References

  1. protein Expr. Purif. v.10 High level expression of soluble protein in Escherichia coli using a His-tag and maltose-binding double affinity fusion system Pryor,K.D.;B.Leighting https://doi.org/10.1006/prep.1997.0759
  2. Enzyme Microb. Technol. v.3 Effect of nature of proteins on their coupling to different epoxide-containing supports Zemanova,I.;J.Turkova;M.Capka;L.A.Nakhapetyan;F.Svec;J.Kalal https://doi.org/10.1016/0141-0229(81)90091-0
  3. Immobilization of enzymes and cells Bickerstaff,G.F.
  4. Enzyme Microb. Technol. v.11 no.6 Stabilization of enzymes by multipoint covalent attachment to agarose-aldhyde gels. Borohydride reduction of trypsin agarose derivatives Blanco,R.M.;J.M.Guisan https://doi.org/10.1016/0141-0229(89)90020-3
  5. Anal. Biochem. v.224 Reductive alkylation of Proteins Means,G.E.;R.E.Feeney https://doi.org/10.1006/abio.1995.1001
  6. US patent, 5824784 Kinstler,O.B.;N.E.Gabriel;C.E.Farrar;R.B.DePrince
  7. Nature Biotech. v.14 Improved refolding of immobilized fusion protien Stempfer,G.;B.H.Neugebauer;R.Rudolph https://doi.org/10.1038/nbt0396-329
  8. J. Chromatography v.599 High-performance hydrophobic interaction chromatography as a tool for protein refolding Geng,X.;X.Chang https://doi.org/10.1016/0021-9673(92)85472-6
  9. J. Biol. Chem. v.250 Refolding of reduced, denatured trypsinogen and trypsin immobilized on agarose beads Shiha,N.K.;A.Light
  10. Biochim. et Biophys. Acta v.1339 Reactivation strategies by unfolding / refolding of chymotrypsin derivatives after inactivation by organic solvents Soler,G.;A.Bastida;R.M.Blanco;R.Fernandez-Lafuente;J.M.Guisan https://doi.org/10.1016/S0167-4838(96)00223-3
  11. Biotechnol. Appl. Biochem. v.37 Enzymic cleavage of fusion protein using immobilized urokinase covalently conjugated to glyoxyl-agarose Suh,C.W.;G.S.Choi;E.K.Lee https://doi.org/10.1042/BA20020049
  12. Biochim. et Biophys. Acta v.567 Hydrolysis of artificial substrates by enterokinase and trypsin and the development of a sensitive specific assay for enterokinase in serum Grant,D.A.W.;J.H.Taylor https://doi.org/10.1016/0005-2744(79)90187-6
  13. Kor. J. Biotechnol. Bioeng. v.15 no.1 Fusion Protein Cleavage by Urokinase Covalently Immobilized to Activated Sepharose Gels Suh,C.W.;K.Y.Kang;H.S.Lee;S.J.Ahn;E.K.Lee
  14. Enzyme Microb. Technol. v.11 Immobilization-stabilization of enzymes: variables that control the intensity of the trypsin (amine)-agarose (aldehyde) multipoint attachment Blanco,R.M.;J.J.Calvete;J.M.Guisna https://doi.org/10.1016/0141-0229(89)90019-7
  15. Biol. Chem. Hoppe. Seyler. v.376 Production of active recombinant human chymase from a construct cantaining the enterokinase cleavage site of trysinogen in plase of the native propeptide sequence Wang,Z.M.;H.Rubin;N.M.Schechter https://doi.org/10.1515/bchm3.1995.376.11.681
  16. Kor. J. Biotechnol. Bioeng. v.16 no.5 Scale-up of covalently immobilized urokinase column and repeated use of it by solid-phase refolding Suh,C.W.;S.J.Ahn;G.S.Choi;E.K.Lee
  17. Biotechnol. Bioprocess Eng. v.7 Solid-phase refolding of poly-lysine tagged fusion protein of hEGF and angiogenin Park,S.J.;K.Ryu;C.W.Suh;Y.G.Chai;O.B.Kwon;S.K.Park;E.K.Lee https://doi.org/10.1007/BF02935871