人羧酸酯酶1结构和功能的研究进展

人羧酸酯酶1(Human carboxylesterase 1,HCE1)是丝氨酸水解酶多基因家族的重要成员之一,它是一种参与肝脏外源物质解毒及代谢的肝羧酸酯酶。HCE1还能参与人体内胆固醇酯和游离脂肪酸的运输和代谢过程,与肝细胞肝癌的发生发展密切相关。文中就近十年来人羧酸酯酶1的分子结构、药物代谢、毒物代谢、脂质代谢及早期诊断肝细胞肝癌等功能方面的相关研究进展进行综述。     

运用α-氰代酯荧光底物检测抗性棉蚜羧酸酯酶代谢活性

为了研究抗性和敏感棉蚜Aphis gossypii品系对菊酯类药剂代谢的差异, 本实验合成了溴氰菊酯和高效氯氰菊酯报告荧光底物, 应用这两种底物水解后生成具有荧光化合物的特性,测定了不同品系棉蚜羧酸酯酶的代谢活性。结果表明: 氧化乐果棉蚜抗性和敏感品系羧酸酯酶对溴氰菊酯报告荧光底物的代谢活性分别为10.0和3.4 pmol/min·mg; 对高效氯氰菊酯报告荧光底物的代谢活性分别为4.0和2.4 pmol/min·mg, 抗性品系羧酸酯酶对溴氰菊酯和高效氯氰菊酯报告荧光底物的代谢活性分别为敏感品系的2.9和1.7倍; 溴氰菊酯棉蚜抗性和敏感品系羧酸酯酶对溴氰菊酯报告荧光底物的代谢活性分别为7.6和6.2 pmol/min·mg; 对高效氯氰菊酯报告荧光底物的代谢活性分别为9.3和5.2 pmol/min·mg, 抗性品系羧酸酯酶对溴氰菊酯和高效氯氰菊酯报告荧光底物的代谢活性分别为敏感品系的1.2和1.8倍。这种衍生的报告荧光底物能够用来检测抗性棉蚜羧酸酯酶的水解活性, 表明羧酸酯酶可能参与棉蚜对溴氰菊酯和氧化乐果抗性的形成。     

东亚飞蝗羧酸酯酶基因的克隆和原核表达

羧酸酯酶是昆虫体内重要的代谢解毒酶系,其主要功能是水解和结合内源性和外源性含有酯键的有毒物质,减缓其到达靶标部位的时间。东亚飞蝗Locusta migratoria manilensis(Meyen)是我国重要的农业害虫,对其羧酸酯酶基因克隆和表达有助于深入探索杀虫剂代谢毒理机制。本研究首先对羧酸酯酶基因(CarE4)进行了克隆,并将其插入到pCold TF DNA Vector中,在大肠杆菌中进行了原核表达,最后用疏水层析和离子交换层析方法对目的蛋白进行了纯化。本文成功建立了羧酸酯酶蛋白原核表达和纯化技术体系,为进一步研究东亚飞蝗羧酸酯酶的生理功能、结构特点和作用原理提供了基础资料。     

Cloning and prokaryotical expression of CarE gene in Locusta migratoria manilensis

羧酸酯酶是昆虫体内重要的代谢解毒酶系,其主要功能是水解和结合内源性和外源性含有酯键的有毒物质,减缓其到达靶标部位的时间.东亚飞蝗Locusta migratoria manilensis (Meyen)是我国重要的农业害虫,对其羧酸酯酶基因克隆和表达有助于深入探索杀虫剂代谢毒理机制.本研究首先对羧酸酯酶基因(CarE4)进行了克隆,并将其插入到pCold TF DNA Vector中,在大肠杆菌中进行了原核表达,最后用疏水层析和离子交换层析方法对目的蛋白进行了纯化.本文成功建立了羧酸酯酶蛋白原核表达和纯化技术体系,为进一步研究东亚飞蝗羧酸酯酶的生理功能、结构特点和作用原理提供了基础资料.     

麦长管蚜羧酸酯酶基因cDNA片段克隆及吡虫啉胁迫对其表达的影响

羧酸酯酶在昆虫对杀虫剂的解毒代谢过程中发挥重要作用,本研究旨在分析吡虫啉胁迫对麦长管蚜羧酸酯酶基因表达的影响。采用同源克隆方法克隆麦长管蚜羧酸酯酶基因cDNA片段,实时荧光定量PCR技术检测羧酸酯酶基因在不同吡虫啉剂量下的表达量变化。扩增所得麦长管蚜羧酸酯酶基因cDNA片段大小为392 bp,命名为SaEST 3(GenBank登录号KY 441614),该片段编码130个氨基酸残基,分子量14 kD,等电点4.93。序列同源性比对及生物信息学分析表明SaEST3推导的氨基酸序列与豌豆长管蚜、麦双尾蚜、夹竹桃蚜、桃蚜的羧酸酯酶氨基酸序列相似性较高,分别为94%、85%、80%和80%。实时荧光定量PCR结果显示,不同吡虫啉处理剂量下,SaEST3 m RNA的相对表达量均上调。克隆得到的基因片段为麦长管蚜羧酸酯酶基因片段,吡虫啉对麦长管蚜羧酸酯酶基因SaEST3表达有一定的影响。     

溴氰菊酯对飞蝗羧酸酯酶基因表达的影响

【目的】研究溴氰菊酯作用下飞蝗羧酸酯酶基因的mRNA表达特性,为溴氰菊酯的代谢解毒及飞蝗Locusta migratoria防治中抗性风险的评估提供基础资料。【方法】本文采用不同剂量溴氰菊酯处理3龄飞蝗,提取总RNA,体外反转录合成cDNA模板,采用Real-time PCR技术分析飞蝗羧酸酯酶基因在溴氰菊酯不同浓度和不同时间处理后的表达模式。【结果】飞蝗经不同浓度溴氰菊酯处理12 h后,LmCesA3和LmCesE1表现为诱导效应;除LmCesA2外,其余羧酸酯酶基因经溴氰菊酯LD30剂量处理后分别在不同的时间点表现为诱导效应。【结论】5个羧酸酯酶基因LmCesA1、LmCesA3、LmCesD1、LmCesE1和LmCesI1可以被溴氰菊酯诱导,表明其可能参与飞蝗对溴氰菊酯的代谢解毒及抗性产生。     

抗性品系棉蚜乙酰胆碱酯酶和羧酸酯酶的变异

用浸叶法测定了采自我国不同地区(泰安、莱阳、南京、北京和安阳)的棉蚜品系Ⅰ、Ⅱ、Ⅲ、Ⅳ、Ⅴ对久效磷、甲胺磷、抗蚜威和灭多威等杀虫剂的抗性水平,各棉蚜品系对杀虫剂的抗性依次为Ⅴ>Ⅳ>Ⅲ,Ⅱ>Ⅰ。进一步研究表明,Ⅴ和Ⅳ品系棉蚜乙酰胆碱酯酶对杀虫剂的敏感性显著下降,Ⅱ品系次之,Ⅲ和Ⅰ品系接近于敏感品系。Ⅴ和Ⅳ品系乙酰胆碱酯酶的Km值显著下降,表明酶发生了质的变化。不同棉蚜抗性品系的酯酶（全酯酶和羧酸酯酶）活性均显著升高,其中Ⅲ品系的酯酶活力为Ⅱ品系的2倍。Ⅴ品系羧酸酯酶Km值达2460.4 μmol/L,而Ⅳ品系仅为84.4 μmol/L,该两个品系羧酸酯酶发生了质的变化。研究结果表明,不同抗性程度的棉蚜品系均存在代谢抗性和靶标抗性。低抗水平的棉蚜品系,以代谢抗性为主,靶标抗性为辅;中抗水平的棉蚜品系,抑或由于解毒代谢酶的活性显著增强,也可能由于靶标的敏感性显著下降;而高抗水平的棉蚜品系,依赖于代谢抗性和靶标抗性的联合作用。     

乙基多杀菌素抗性小菜蛾代谢解毒酶酶活性研究

【目的】阐明小菜蛾Plutella xylostella(L.)对乙基多杀菌素的代谢抗性机理,为延缓小菜蛾对乙基多杀菌素抗药性发展及抗性治理技术提供支持。【方法】通过酶动力学方法测定了小菜蛾对乙基多杀菌素高抗、中抗和敏感种群的谷胱甘肽-S-转移酶、羧酸酯酶、乙酰胆碱酯酶和多功能氧化酶4种代谢解毒酶的比活力。【结果】乙基多杀菌素高抗小菜蛾种群的谷胱甘肽-S-转移酶、羧酸酯酶、乙酰胆碱酯酶的比活力分别为15.38、3.15和7.30 OD·min~(-1)·mg~(-1)pro,显著高于敏感种群;但乙酰胆碱酯酶在中抗种群和敏感种群中比活力差异不显著;多功能氧化酶在高抗、中抗和敏感种群中的比活力分别为4.97、4.08和4.23 OD·min~(-1)·mg~(-1)pro,差异不显著。【结论】谷胱甘肽-S-转移酶、羧酸酯酶和乙酰胆碱酯酶的酶活随着小菜蛾对乙基多杀菌素抗性的增强而增强,而多功能氧化酶的酶活在抗性种群与敏感种群间差异不显著,因此小菜蛾对乙基多杀菌素的代谢抗性机理研究应重点关注这3种酶。     

羧酸酯酶介导的小菜蛾对氟虫腈的抗性

【目的】羧酸酯酶（carboxylesterases, CarEs）是昆虫重要的解毒代谢酶之一,可以介导靶标昆虫对多种杀虫剂的代谢抗性。本研究检测了羧酸酯酶对小菜蛾Plutella xylostella 抗药性的介导功能,旨在阐明羧酸酯酶在小菜蛾代谢解毒中的生理生化和分子机理。【方法】采用点滴法测定氟虫腈对小菜蛾敏感种群和抗氟虫腈种群的毒力,以及羧酸酯酶抑制剂磷酸三苯酯（triphenyl phosphate, TPP）对氟虫腈的增效作用;以LC₃₀和LC₅₀浓度的氟虫腈处理抗性小菜蛾,测定药剂处理后CarEs酶活性的变化;利用qRT-PCR技术分析Pxae22和Pxae31两个基因在小菜蛾不同发育阶段、组织和种群的表达模式;利用dsRNA干扰Pxae22和Pxae31后观察基因的表达变化和小菜蛾3龄幼虫对药剂敏感性的变化。【结果】TPP可以削弱小菜蛾3龄幼虫对氟虫腈的抗性,增效倍数约为6倍;使用较低剂量（LC₃₀和LC₅₀）氟虫腈处理小菜蛾3龄幼虫后,处理组CarEs比活力明显高于对照,提示氟虫腈对小菜蛾CarEs活性具有诱导作用。对羧酸酯酶基因Pxae22和Pxae31在小菜蛾不同发育阶段、4龄幼虫不同组织和不同种群3龄幼虫中的表达模式分析发现,这两个基因在小菜蛾4龄幼虫中的表达量最高;在4龄幼虫中以中肠组织中的表达量较高,头、表皮、脂肪体中的表达量很低; 抗性种群中的表达量显著高于敏感种群。通过干扰 Pxae22和 Pxae31后的qRT-PCR验证,两个基因的表达量均显著降低,进一步的氟虫腈毒力测定发现,干扰P xae22和 Pxae31后的小菜蛾3龄幼虫对氟虫腈的敏感性分别增加了1.63倍和1.73倍。【结论】羧酸酯酶在小菜蛾对氟虫腈解毒代谢中具有重要作用;Pxae22和Pxae31是小菜蛾的两个抗性相关基因,其表达水平的变化直接影响小菜蛾对氟虫腈的敏感性。     

云南主要烟区烟蚜种群解毒酶活力比较

通过测定烟蚜Myzus persicae(Sulzer)的α-NA羧酸酯酶、β-NA羧酸酯酶、谷胱甘肽转移酶和乙酰胆碱酯酶的活力,比较了云南5个主要烟区田间烟蚜种群的4种酶的活力频率分布,结果表明,云南5个烟区的烟蚜田间种群的α-NA羧酸酯酶、β-NA羧酸酯酶和乙酰胆碱酯酶的高活力个体均以楚雄和昆明种群较高,昭通种群和丽江种群较低.谷胱甘肽转移酶在5个烟区烟蚜种群间差异不大.     

Substrate specificity and kinetic properties of enzymes belonging to the hormone-sensitive lipase family: comparison with non-lipolytic and lipolytic carboxylesterases

We have studied the kinetics of hydrolysis of triacylglycerols, vinyl esters and p-nitrophenyl butyrate by four carboxylesterases of the HSL family, namely recombinant human hormone-sensitive lipase (HSL), EST2 from Alicyclobacillus acidocaldarius, AFEST from Archeoglobus fulgidus, and protein RV1399C from Mycobacterium tuberculosis. The kinetic properties of enzymes of the HSL family have been compared to those of a series of lipolytic and non-lipolytic carboxylesterases including human pancreatic lipase, guinea pig pancreatic lipase related protein 2, lipases from Mucor miehei and Thermomyces lanuginosus, cutinase from Fusarium solani, LipA from Bacillus subtilis, porcine liver esterase and Esterase A from Aspergilus niger. Results indicate that human HSL, together with other lipolytic carboxylesterases, are active on short chain esters and hydrolyze water insoluble trioctanoin, vinyl laurate and olive oil, whereas the action of EST2, AFEST, protein RV1399C and non-lipolytic carboxylesterases is restricted to solutions of short chain substrates. Lipolytic and non-lipolytic carboxylesterases can be differentiated by their respective value of K(0.5) (apparent K(m)) for the hydrolysis of short chain esters. Among lipolytic enzymes, those possessing a lid domain display higher activity on tributyrin, trioctanoin and olive oil suggesting, then, that the lid structure contributes to enzyme binding to triacylglycerols. Progress reaction curves of the hydrolysis of p-nitrophenyl butyrate by lipolytic carboxylesterases with lid domain show a latency phase which is not observed with human HSL, non-lipolytic carboxylesterases, and lipolytic enzymes devoid of a lid structure as cutinase.     

超嗜热羧酸酯酶的性质和应用研究

摘要 来源于超嗜热菌的超嗜热羧酸酯酶,结构上与激素敏感性脂肪酶(HSL)家族近似,属于α/β-水解酶,但是其空间结构比HSL更加紧密而有韧性,具有很强的热稳定性。性质研究表明,温度和有机溶剂对超嗜热羧酸酯酶的活性和对映选择性影响显著;其最适底物一般是对硝基苯酯,部分酯酶的基因含有GGGX基序,能够水解叔醇酯结构。由于超嗜热羧酸酯酶的独特结构和性质,其应用潜力巨大,尤其在拆分手性的外消旋酯方面独具优势。     

Novel metagenome-derived carboxylesterase that hydrolyzes β-lactam antibiotics

It has been proposed that family VIII carboxylesterases and class C β-lactamases are phylogenetically related; however, none of carboxylesterases has been reported to hydrolyze β-lactam antibiotics except nitrocefin, a nonclinical chromogenic substrate. Here, we describe the first example of a novel carboxylesterase derived from a metagenome that is able to cleave the amide bond of various β-lactam substrates and the ester bond of p-nitrophenyl esters. A clone with lipolytic activity was selected by functional screening of a metagenomic library using tributyrin agar plates. The sequence analysis of the clone revealed the presence of an open reading frame (estU1) encoding a polypeptide of 426 amino acids, retaining an S-X-X-K motif that is conserved in class C β-lactamases and family VIII carboxylesterases. The gene was overexpressed in Escherichia coli, and the purified recombinant protein (EstU1) was further characterized. EstU1 showed esterase activity toward various chromogenic p-nitrophenyl esters. In addition, it exhibited hydrolytic activity toward nitrocefin, leading us to investigate whether EstU1 could hydrolyze β-lactam antibiotics. EstU1 was able to hydrolyze first-generation β-lactam antibiotics, such as cephalosporins, cephaloridine, cephalothin, and cefazolin. In a kinetic study, EstU1 showed a similar range of substrate affinities for both p-nitrophenyl butyrate and first-generation cephalosporins while the turnover efficiency for the latter was much lower. Furthermore, site-directed mutagenesis studies revealed that the catalytic triad of EstU1 plays a crucial role in hydrolyzing both ester bonds of p-nitrophenyl esters and amide bonds of the β-lactam ring of antibiotics, implicating the predicted catalytic triad of EstU1 in both activities.     

Structural basis for the β‐lactamase activity of EstU1, a family VIII carboxylesterase

EstU1 is a unique family VIII carboxylesterase that displays hydrolytic activity toward the amide bond of clinically used β‐lactam antibiotics as well as the ester bond of p‐nitrophenyl esters. EstU1 assumes a β‐lactamase‐like modular architecture and contains the residues Ser100, Lys103, and Tyr218, which correspond to the three catalytic residues (Ser64, Lys67, and Tyr150, respectively) of class C β‐lactamases. The structure of the EstU1/cephalothin complex demonstrates that the active site of EstU1 is not ideally tailored to perform an efficient deacylation reaction during the hydrolysis of β‐lactam antibiotics. This result explains the weak β‐lactamase activity of EstU1 compared with class C β‐lactamases. Finally, structural and sequential comparison of EstU1 with other family VIII carboxylesterases elucidates an operative molecular strategy used by family VIII carboxylesterases to extend their substrate spectrum. Proteins 2013; 81:2045–2051. © 2013 Wiley Periodicals, Inc.     

Structure, function and regulation of carboxylesterases

This review covers current developments in molecular-based studies of the structure and function of carboxylesterases. To allay the confusion of the classic classification of carboxylesterase isozymes, we have proposed a novel nomenclature and classification of mammalian carboxylesterases on the basis of molecular properties. In addition, mechanisms of regulation of gene expression of carboxylesterases by xenobiotics and involvement of carboxylesterase in drug metabolism and enzyme induction are also described.     

Functional fat body proteomics and gene targeting reveal in vivo functions of Drosophila melanogaster α-Esterase-7

Carboxylesterases constitute a large enzyme family in insects, which is involved in diverse functions such as xenobiotic detoxification, lipid metabolism and reproduction. Phylogenetically, many insect carboxylesterases are represented by multienzyme clades, which are encoded by evolutionarily ancient gene clusters such as the α-Esterase cluster. Much in contrast to the vital importance attributed to carboxylesterases in general, the in vivo function of individual α-Esterase genes is largely unknown. This study employs a functional proteomics approach to identify esterolytic enzymes of the vinegar fly Drosophila melanogaster fat body. One of the fat body carboxylesterases, α-Esterase-7, was selected for mutational analysis by gene targeting to generate a deletion mutant fly. Phenotypic characterization of α-Esterase-7 null mutants and transgenic flies, which overexpress a chimeric α-Esterase-7:EGFP gene, reveals important functions of α-Esterase-7 in insecticide tolerance, lipid metabolism and lifespan control. The presented first deletion mutant of any α-Esterase in the model insect D. melanogaster generated by gene targeting not only provides experimental evidence for the endogenous functions of this gene family. It also offers an entry point for in vivo structure-function analyses of α-Esterase-7, which is of central importance for naturally occurring insecticide resistance in wild populations of various dipteran insect species.     

The carboxylesterase family exhibits C-terminal sequence diversity reflecting the presence or absence of endoplasmic-reticulum-retention sequences.

Resident proteins of the endoplasmic reticulum lumen are continuously retrieved from an early Golgi compartment by a receptor-mediated mechanism. The sorting or retention sequence on the endoplasmic reticulum proteins is located at the C-terminus and was initially shown to be the tetrapeptide KDEL in mammalian cells and HDEL in Saccharomyces cerevisiae. The carboxylesterases are a large family of enzymes primarily localized to the lumen of the endoplasmic reticulum. Retention sequences in these proteins have been difficult to identify due to atypical and heterogeneous C-terminal sequences. Utilizing the polymerase chain reaction with degenerate primers, we have identified and characterized the C-termini of four members of the carboxylesterase family from rat liver. Three of the carboxylesterases sequences contained C-terminal sequences (HVEL, HNEL or HTEL) resembling the yeast sorting signal which were reported to be non-functional in mammalian cells. A fourth carboxylesterase contained a distinct C-terminal sequence, TEHT. A full-length esterase cDNA clone, terminating in the sequence HVEL, was isolated and was used to assess the retention capabilities of the various esterase C-terminal sequences. This esterase was retained in COS-1 cells, but was secreted when its C-terminal tetrapeptide, HVEL, was deleted. Addition of C-terminal sequences containing HNEL and HTEL resulted in efficient retention. However, the C-terminal sequence containing TEHT was not a functional retention signal. Both HDEL, the authentic yeast retention signal, and KDEL were efficient retention sequences for the esterase. These studies show that some members of the rat liver carboxylesterase family contain novel C-terminal retention sequences that resemble the yeast signal. At least one member of the family does not contain a C-terminal retention signal and probably represents a secretory form.     

人羧酯酶的研究进展

羧酯酶是一类可与有机磷化合物结合且活性受抑制的B－酯酶,分布很广,能水解许多羧酯类、酰胺类、硫酯类物质,其天然底物尚未清楚,故其生理功能仍在研究中,可能与脂质代谢,药物或毒物的生物转化有关．对羧酯酶的一级结构及基因序列的研究表明,羧酯酶是由许多生化特性不同的同工酶组成．     

CARBOXYLESTERASES WITH DIFFERENT SUBSTRATE SPECIFICITY IN HUMAN BRAIN EXTRACTS

Abstract— Methods for the determination of carboxylesterase activity in soluble as well as in particulate samples with p -mtrophenylacetate and -butyrate and α-naphthylacetate and -butyrate as substrates are described. Of the carboxylesterase activity of human brain, 8-20% was present in aqueous extracts. Particle-bound carboxylesterases could not be solubilized. By DEAE-cellulose chromatography the carboxylesterases were separated into 6 more or less inhomogeneous fractions. One of these was further resolved into 2 fractions by chromatography on CM-cellulose. Fractions obtained by ion exchange chromatography were resolved into several fractions by isoelectric focusing. Gel chromatography on Sephadex G-200 resolved the carboxylesterases of brain extract into two fractions (molecular weights about 60.000 and 300,000). At least 4 different types of carboxylesterases could be distinguished on the basis of different substrate specificity.     

The Carboxylesterase Gene Family from <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Carboxylesterases hydrolyze esters of short-chain fatty acids and have roles in animals ranging from signal transduction to xenobiotic detoxification. In plants, however, little is known of their roles. We have systematically mined the genome from the model plant Arabidopsis thaliana for carboxylesterase genes and studied their distribution in the genome and expression profile across a range of tissues. Twenty carboxylesterase genes (AtCXE) were identified. The AtCXE family shares conserved sequence motifs and secondary structure characteristics with carboxylesterases and other members of the larger / hydrolase fold superfamily of enzymes. Phylogenetic analysis of the AtCXE genes together with other plant carboxylesterases distinguishes seven distinct clades, with an Arabidopsis thaliana gene represented in six of the seven clades. The AtCXE genes are widely distributed across the genome (present in four of five chromosomes), with the exception of three clusters of tandemly duplicated genes. Of the interchromosomal duplication events, two have been mediated through newly identified partial chromosomal duplication events that also include other genes surrounding the AtCXE loci. Eighteen of the 20 AtCXE genes are expressed over a broad range of tissues, while the remaining 2 (unrelated) genes are expressed only in the flowers and siliques. Finally, hypotheses for the functional roles of the AtCXE family members are presented based on the phylogenetic relationships with other plant carboxylesterases of known function, their expression profile, and knowledge of likely esterase substrates found in plants.