Highly efficient enzymatic synthesis of Z-aspartame in aqueous medium via in situ product removal

Keke Liu; Fucheng Zhu; Ling Zhu; Guoguang Chen; Bingfang He

doi:10.1016/j.bej.2015.01.012

Highly efficient enzymatic synthesis of Z-aspartame in aqueous medium via in situ product removal

Keke Liu, Fucheng Zhu, Ling Zhu, Guoguang Chen, Bingfang He

School of Pharmaceutical Sciences

Nanjing Tech University

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

Z-Aspartame (Z-APM) was obtained using an aqueous reaction at pH 6.0 based on thermodynamic control and in situ product removal. The lower pH reaction medium led to higher solubilities of the two substrates, l-PheOMe and Z-l-Asp and dramatically lowered the solubility of the product. The higher pH stability of the protease PT121 and the mutant Y114S enabled the pH modulation of the reaction medium to shift the thermodynamic equilibrium toward product synthesis. The reaction-separation coupling provided a "driving force" for the enzymatic synthesis and resulted in high yields of 88.5% (C_Z-l-Asp=50mM,C_l-PheOMe=500mM) and 82.2% (C_Z-l-Asp=100mM,C_l-PheOMe=500mM), without further purification for removing protection group, of Z-aspartame. Moreover, we rationalized the inhibition by Z-l-Asp at a relatively higher concentration on the synthesis of Z-APM using a molecular docking approach.

Original language	English
Pages (from-to)	63-67
Number of pages	5
Journal	Biochemical Engineering Journal
Volume	98
DOIs	https://doi.org/10.1016/j.bej.2015.01.012
State	Published - 5 Jun 2015

Keywords

Biocatalysis
Enzyme technology
Mass transfer
Molecular docking
Protease
Z-aspartame

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10.1016/j.bej.2015.01.012

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title = "Highly efficient enzymatic synthesis of Z-aspartame in aqueous medium via in situ product removal",

abstract = "Z-Aspartame (Z-APM) was obtained using an aqueous reaction at pH 6.0 based on thermodynamic control and in situ product removal. The lower pH reaction medium led to higher solubilities of the two substrates, l-PheOMe and Z-l-Asp and dramatically lowered the solubility of the product. The higher pH stability of the protease PT121 and the mutant Y114S enabled the pH modulation of the reaction medium to shift the thermodynamic equilibrium toward product synthesis. The reaction-separation coupling provided a {"}driving force{"} for the enzymatic synthesis and resulted in high yields of 88.5% (CZ-l-Asp=50mM,Cl-PheOMe=500mM) and 82.2% (CZ-l-Asp=100mM,Cl-PheOMe=500mM), without further purification for removing protection group, of Z-aspartame. Moreover, we rationalized the inhibition by Z-l-Asp at a relatively higher concentration on the synthesis of Z-APM using a molecular docking approach.",

keywords = "Biocatalysis, Enzyme technology, Mass transfer, Molecular docking, Protease, Z-aspartame",

author = "Keke Liu and Fucheng Zhu and Ling Zhu and Guoguang Chen and Bingfang He",

note = "Publisher Copyright: {\textcopyright} 2015 Elsevier B.V.",

year = "2015",

month = jun,

day = "5",

doi = "10.1016/j.bej.2015.01.012",

language = "英语",

volume = "98",

pages = "63--67",

journal = "Biochemical Engineering Journal",

issn = "1369-703X",

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TY - JOUR

T1 - Highly efficient enzymatic synthesis of Z-aspartame in aqueous medium via in situ product removal

AU - Liu, Keke

AU - Zhu, Fucheng

AU - Zhu, Ling

AU - Chen, Guoguang

AU - He, Bingfang

PY - 2015/6/5

Y1 - 2015/6/5

N2 - Z-Aspartame (Z-APM) was obtained using an aqueous reaction at pH 6.0 based on thermodynamic control and in situ product removal. The lower pH reaction medium led to higher solubilities of the two substrates, l-PheOMe and Z-l-Asp and dramatically lowered the solubility of the product. The higher pH stability of the protease PT121 and the mutant Y114S enabled the pH modulation of the reaction medium to shift the thermodynamic equilibrium toward product synthesis. The reaction-separation coupling provided a "driving force" for the enzymatic synthesis and resulted in high yields of 88.5% (CZ-l-Asp=50mM,Cl-PheOMe=500mM) and 82.2% (CZ-l-Asp=100mM,Cl-PheOMe=500mM), without further purification for removing protection group, of Z-aspartame. Moreover, we rationalized the inhibition by Z-l-Asp at a relatively higher concentration on the synthesis of Z-APM using a molecular docking approach.

AB - Z-Aspartame (Z-APM) was obtained using an aqueous reaction at pH 6.0 based on thermodynamic control and in situ product removal. The lower pH reaction medium led to higher solubilities of the two substrates, l-PheOMe and Z-l-Asp and dramatically lowered the solubility of the product. The higher pH stability of the protease PT121 and the mutant Y114S enabled the pH modulation of the reaction medium to shift the thermodynamic equilibrium toward product synthesis. The reaction-separation coupling provided a "driving force" for the enzymatic synthesis and resulted in high yields of 88.5% (CZ-l-Asp=50mM,Cl-PheOMe=500mM) and 82.2% (CZ-l-Asp=100mM,Cl-PheOMe=500mM), without further purification for removing protection group, of Z-aspartame. Moreover, we rationalized the inhibition by Z-l-Asp at a relatively higher concentration on the synthesis of Z-APM using a molecular docking approach.

KW - Biocatalysis

KW - Enzyme technology

KW - Mass transfer

KW - Molecular docking

KW - Protease

KW - Z-aspartame

UR - http://www.scopus.com/inward/record.url?scp=84923929303&partnerID=8YFLogxK

U2 - 10.1016/j.bej.2015.01.012

DO - 10.1016/j.bej.2015.01.012

M3 - 文章

AN - SCOPUS:84923929303

SN - 1369-703X

VL - 98

SP - 63

EP - 67

JO - Biochemical Engineering Journal

JF - Biochemical Engineering Journal

ER -

Highly efficient enzymatic synthesis of Z-aspartame in aqueous medium via in situ product removal

Abstract

Keywords

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