Your search keyword '"Chen, Xiabin"' showing total 6 results

1. Preparation and in vivo characterization of a cocaine hydrolase engineered from human butyrylcholinesterase for metabolizing cocaine.

Author

Xue L, Hou S, Tong M, Fang L, Chen X, Jin Z, Tai HH, Zheng F, and Zhan CG

Subjects

Animals, Butyrylcholinesterase genetics, CHO Cells, Cell Line, Cocaine-Related Disorders, Cricetinae, Female, Humans, Male, Mice, Motor Activity drug effects, Rats, Rats, Sprague-Dawley, Butyrylcholinesterase metabolism, Cocaine metabolism, Protein Engineering methods

Abstract

Cocaine is a widely abused drug without an FDA (Food and Drug Administration)-approved medication. It has been recognized that an ideal anti-cocaine medication would accelerate cocaine metabolism producing biologically inactive metabolites via a route similar to the primary cocaine-metabolizing pathway, i.e. human BChE (butyrylcholinesterase)-catalysed hydrolysis. However, the native human BChE has a low catalytic activity against cocaine. We recently designed and discovered a BChE mutant (A199S/F227A/S287G/A328W/Y332G) with a high catalytic activity (kcat=5700 min-1, Km=3.1 μM) specifically for cocaine, and the mutant was proven effective in protecting mice from acute cocaine toxicity of a lethal dose of cocaine (180 mg/kg of body weight, LD100). Further characterization in animal models requires establishment of a high-efficiency stable cell line for the BChE mutant production at a relatively larger scale. It has been extremely challenging to develop a high-efficiency stable cell line expressing BChE or its mutant. In the present study, we successfully developed a stable cell line efficiently expressing the BChE mutant by using a lentivirus-based repeated-transduction method. The scaled-up protein production enabled us to determine for the first time the in vivo catalytic activity and the biological half-life of this high-activity mutant of human BChE in accelerating cocaine clearance. In particular, it has been demonstrated that the BChE mutant (administered to mice 1 min prior to cocaine) can quickly metabolize cocaine and completely eliminate cocaine-induced hyperactivity in rodents, implying that the BChE mutant may be developed as a promising therapeutic agent for cocaine abuse treatment.

Published

2013

2. Long-acting cocaine hydrolase for addiction therapy

Author

Chen, Xiabin, Xue, Liu, Hou, Shurong, Jin, Zhenyu, Zhang, Ting, Zheng, Fang, and Zhan, Chang-Guo

Published

2016

3. Development of Fc-Fused Cocaine Hydrolase for Cocaine Addiction Treatment: Catalytic and Pharmacokinetic Properties

Author

Chen, Xiabin, Deng, Jing, Cui, Wenpeng, Hou, Shurong, Zhang, Jinling, Zheng, Xirong, Ding, Xin, Wei, Huimei, Zhou, Ziyuan, Kim, Kyungbo, Zhan, Chang-Guo, and Zheng, Fang

Published

2018

4. Computational Design and Crystal Structure of a Highly Efficient Benzoylecgonine Hydrolase.

Author

Chen, Xiabin, Deng, Xingyu, Zhang, Yun, Wu, Yanan, Yang, Kang, Li, Qiang, Wang, Jiye, Yao, Weixuan, Tong, Junsen, Xie, Tian, Hou, Shurong, and Yao, Jianzhuang

Subjects

*CRYSTAL structure, *COCAINE-induced disorders, *BENZOIC acid, *COCAINE, *PROTEIN engineering

Abstract

Benzoylecgonine (BZE) is the major toxic metabolite of cocaine and is responsible for the long‐term cocaine‐induced toxicity owing to its long residence time in humans. BZE is also the main contaminant following cocaine consumption. Here, we identified the bacterial cocaine esterase (CocE) as a BZE‐metabolizing enzyme (BZEase), which can degrade BZE into biological inactive metabolites (ecgonine and benzoic acid). CocE was redesigned by a reactant‐state‐based enzyme design theory. An encouraging mutant denoted as BZEase2, presented a >400‐fold improved catalytic efficiency against BZE compared with wild‐type (WT) CocE. In vivo, a single dose of BZEase2 (1 mg kg−1, IV) could eliminate nearly all BZE within only two minutes, suggesting the enzyme has the potential for cocaine overdose treatment and BZE elimination in the environment by accelerating BZE clearance. The crystal structure of a designed BZEase was also determined. [ABSTRACT FROM AUTHOR]

Published

2021

5. Development of a long-acting Fc-fused cocaine hydrolase with improved yield of protein expression.

Author

Chen, Xiabin, Deng, Jing, Zheng, Xirong, Zhang, Jinling, Zhou, Ziyuan, Wei, Huimei, Zhan, Chang-Guo, and Zheng, Fang

Subjects

*PROTEIN expression, *COCAINE-induced disorders, *COCAINE abuse, *COCAINE abuse treatment, *PROTEIN domains, *HYDROLASES

Abstract

Human butyrylcholinesterase (BChE) is known as a safe and effective protein for detoxification of organophosphorus (OP) nerve agents. Its rationally designed mutants with considerably improved catalytic activity against cocaine, known as cocaine hydrolases (CocHs), are recognized as the most promising drug candidates for the treatment of cocaine abuse. However, it is a grand challenge to efficiently produce active recombinant BChE and CocHs with a sufficiently long biological half-life. In the present study, starting from a promising CocH, known as CocH3 (i.e. A199S/F227A/S287G/A328W/Y332G mutant of human BChE), which has a ~2000-fold improved catalytic activity against cocaine compared to wild-type BChE, we designed an N-terminal fusion protein, Fc(M3)-(PAPAP) 2 -CocH3, which was constructed by fusing Fc of human IgG1 to the N-terminal of CocH3 and further optimized by inserting a linker between the two protein domains. Without lowering the enzyme activity, Fc(M3)-(PAPAP) 2 -CocH3 expressed in Chinese hamster ovary (CHO) cells has not only a long biological half-life of 105 ± 7 h in rats, but also a high yield of protein expression. Particularly, Fc(M3)-(PAPAP) 2 -CocH3 has a ~21-fold increased protein expression yield in CHO cells compared to CocH3 under the same experimental conditions. Given the observations that Fc(M3)-(PAPAP) 2 -CocH3 has not only a high catalytic activity against cocaine and a long biological half-life, but also a high yield of protein expression, this new protein entity reported in this study would be a more promising candidate for therapeutic treatment of cocaine overdose and addiction. • CocH3 fusion with Fc of IgG1 has improved the biological half-life. • A linker between Fc(M3) and CocH3 can improve protein expression yield. • A rigid linker is more effective than a flexible linker in protein expression. • The new fusion protein entity is a more promising therapeutic candidate. [ABSTRACT FROM AUTHOR]

Published

2019

6. DEVELOPMENT OF COCAINE HYDROLASE FOR THERAPEUTIC TREATMENT OF COCAINE ABUSE

Author

Chen, Xiabin

Subjects

Cocaine abuse, benzoylecgonine, enzyme therapy, protein engineering, butyrylcholinesterase, LC-MS/MS, Pharmaceutics and Drug Design

Abstract

Cocaine abuse is a world-wide public health and social problem without a U.S. Food and Drug Administration (FDA)-approved medication. An ideal anti-cocaine medication would accelerate cocaine metabolism producing biologically inactive metabolites by administration of an efficient cocaine-specific exogenous enzyme. Recent studies in our lab have led to discovery of the desirable, highly efficient human cocaine hydrolases (hCocHs) that can efficiently detoxify and inactivate cocaine without affecting normal functions of central nervous system (CNS). Preclinical and clinical data have demonstrated that these hCocHs are safe for use in humans and effective for accelerating cocaine metabolism. However, the actual therapeutic use of a hCocH in cocaine addiction treatment is limited by the short biological half-life (e.g. 8 hours or shorter in rats) of the hCocH. In the investigation described in this thesis, we have demonstrated that mCocH and hCocH have improved the catalytic efficiency of mBChE and hBChE against cocaine by ~8- and ~2000-fold, respectively, although the catalytic efficiencies of mCocH and hCocH against other substrates, including acetylcholine (ACh) and butyrylthiocholine (BTC), are close to those of the corresponding wild-type enzymes mBChE and hBChE. In addition, we have identified the first benzoylecgonine-metabolizing enzymes that can hydrolyze benzoylecgonine and accelerate its clearance in rats. The developed LC-MS/MS method has enabled us to simultaneously determine cocaine and nine cocaine-related metabolites in whole blood samples. In development of the long-acting hCocHs, we have designed and discovered a novel hCocH form, catalytic antibody analog, which is an Fc-fused hCocH dimer (hCocH-Fc). The hCocH-Fc has not only a high catalytic efficiency against cocaine, but also a considerably longer biological half-life. A single dose of hCocH-Fc was able to accelerate cocaine metabolism in rats even after 20 days and, thus, block cocaine-induced hyperactivity for a long period of time. In consideration of the general observation that the biological half-life of a protein drug in humans is significantly longer than that in rodents, the hCocH-Fc could allow dosing once every 2-4 weeks, or longer for cocaine addiction treatment in humans.

Published

2016