酶的定向进化策略

定向进化技术已成为改造酶分子的一种有效策略,是在体外模拟自然进化进程,通过随机突变和（或）体外重组产生基因的多样性．再经筛选（或选择）获得所需性能大幅提高的酶。该文介绍近几年来酶定向进化技术研究的最新进展以及一些成功实例。     

酶定向进化的研究进展

定向进化在改造酶的性质方面已得到广泛应用,各种建立突变库的方法不断涌现。对新近发展的几种突变技术(如寡核苷酸设计型装配重组技术ADO、非序列同源蛋白重组SHIPREC等)进行了简要地介绍与分类。与突变技术相对应的筛选方法也在逐渐改变和完善,这里仅介绍高通量筛选方面的一些最新进展。     

蛋白质体外定向进化策略研究进展

定向进化已广泛应用于蛋白质的分子改造,是改善蛋白质特性的最有效策略之一。为了获得更高的突变效率,构建含有更多突变体的文库,不断地发明创新各种高效的蛋白质体外定向进化方法。对近年来出现的几种定向进化方法三核苷酸突变(TriNex)、序列饱和突变(SeSaM)、随机链交换突变法(RAISE)、重叠延伸蛋白域文库法(PDLGO)和迭代饱和突变法(ISM)的原理、特点及应用进行综述。     

酶的定向进化研究及其在工业生物催化中的应用

综合概括了各种蛋白质改造与微生物代谢途径改造的非理性定向进化技术的原理、特点,介绍了这些技术在高性能工业生物催化剂改造中的应用。     

几种定向进化技术的比较及文库构建策略

蛋白质定向进化在蛋白质工程中取得了令人瞩目的成就,其核心技术---随机突变库构建技术已成为近年来体外定向进化研究的热点。在概述定向进化基本原理基础上,对几种随机突变技术进行了介绍、分类和比较,并对突变库的特征及构建策略予以分析和描述 。     

酶祖先序列重建与定向进化

酶祖先序列重建是指通过计算机算法推导来自灭绝生物的祖先酶的氨基酸序列的技术.通常可分为6个步骤,依次为现代酶的核酸/氨基酸序列收集、多序列比对、系统发育树构建、祖先酶序列的计算机推测、基因克隆、酶学性质表征.该方法广泛应用于研究分子在行星时间尺度上对环境条件不断变化的适应性和进化机制.随着酶在生物催化领域中扮演越来越重...     

酶的定向进化及其应用

综述了生物催化剂（酶）分子定向进化的产生、原理、方法及应用,深入阐述酶分子定向进化过程中的相关问题,重点介绍了易错PCR（Error-prone PCR）和DNA改组（DNA shuffling）等几种典型的酶定向进化方法与成功实例,展望了生物定向进化研究的发展前景。     

大肠杆菌碱性磷酸酶的体外定向进化研究

大肠杆菌碱性磷酸酶（E.coli alkaline phosphatase, EAP, EC 3.1.3.1）是一个非特异性二聚体磷酸单酯酶. 采用易错聚合酶链反应(error prone PCR)的方法,在原有高活力突变株的基础上,对EAP远离活性中心催化三联体的区域进行定向进化,经两轮error prone PCR,获得催化活力较亲本D101S突变株提高3倍、较野生型酶提高35倍的进化酶4-186,并对该酶的催化动力学特征进行了分析. 进化酶基因的DNA测序表明4-186含两个有义氨基酸置换：K167R和S374C,二者既不位于底物结合位点,也不位于酶的金属离子结合位点.     

蛋白质定向进化技术的研究进展

蛋白质定向进化技术是蛋白质分子改造的一个重要策略.重点介绍了易错PCR、DNA改组等对编码蛋白质的基因进行随机突变和重组的技术,以及构建突变体库和高通量筛选的方法,并探讨了定向进化技术在蛋白质工程中的应用及前景.     

酶的分子定向进化及其应用

酶的分子定向进化是20世纪90年代初兴起的一种蛋白质工程的新策略,是一种在生物体外模拟自然进化过程的、具有一定目的性的快速改造蛋A质的方法.该方法引起了生物催化技术领域的又一次革命.目前分子定向进化技术已被广泛应用于工业、农业及制药业等的相关领域.本文详细综述了酶的分子定向进化的概念、过程、基本策略及其核心技术,并着重介绍了酶的分子定向进化技术在提高酶的活力、稳定性、底物特异性和对映体选择性等几方面的应用及取得的相关成果.     

Challenges of the genetic code for exploring sequence space in directed protein evolution

Directed protein evolution is the most versatile method for studying protein structure-function relationships, and for tailoring a protein's properties to the needs of industrial applications. In this review, we performed a statistical analysis on the genetic code to study the extent and consequence of the organization of the genetic code on amino acid substitution patterns generated in directed evolution experiments. In detail, we analyzed amino acid substitution patterns caused by (a) a single nucleotide (nt) exchange at each position of all 64 codons, and (b) two subsequent nt exchanges (first and second nt, first and third nt, second and third nt). Additionally, transitions and transversions mutations were compared at the level of amino acid substitution patterns. The latter analysis showed that single nucleotide substitution in a codon generates only 39.5% of the natural diversity on the protein level with 5.2-7 amino acid substitutions per codon. Transversions generate more complex amino acid substitution patterns (increased number and chemically more diverse amino acid substitutions) than transitions. Simultaneous nt exchanges at both first and second nt of a codon generates very diverse amino acid substitution patterns, achieving 83.2% of the natural diversity. The statistical analysis described in this review sets the objectives for novel random mutagenesis methods that address the consequences of the organization of the genetic code. Random mutagenesis methods that favor transversions or introduce consecutive nt exchanges can contribute in this regard.     

An efficient method for mutant library creation in Pichia pastoris useful in directed evolution

Abstract

The yeast Pichia pastoris is being increasingly used as a host for expressing enzymes on a large scale, but application in directed evolution requiring efficient expression of libraries of mutants is hampered due to the time-consuming multistep procedure which includes an intermediate bacterial host (Escherichia coli). Here we introduce a fast and highly simplified method to produce gene libraries in P. pastoris expression vectors. For the purpose of illustration, Galactomyces geotrichum lipase 1 (GGL1) was used as the catalyst in the enantioselective hydrolytic kinetic resolution of 2-methyldecanoic acid p-nitrophenyl ester, the gene mutagenesis method being saturation mutagenesis. The phosphorylated linear plasmid which is integrated in the yeast genome was obtained by combination of partially overlapped fragments using overlap-extension PCR. An intermediate bacterial host is not necessary, neither are restriction enzymes. This method is also applicable when using error-prone PCR for library creation in directed evolution.     

Challenges of the genetic code for exploring sequence space in directed protein evolution

Directed protein evolution is the most versatile method for studying protein structure–function relationships, and for tailoring a protein's properties to the needs of industrial applications. In this review, we performed a statistical analysis on the genetic code to study the extent and consequence of the organization of the genetic code on amino acid substitution patterns generated in directed evolution experiments. In detail, we analyzed amino acid substitution patterns caused by (a) a single nucleotide (nt) exchange at each position of all 64 codons, and (b) two subsequent nt exchanges (first and second nt, first and third nt, second and third nt). Additionally, transitions and transversions mutations were compared at the level of amino acid substitution patterns. The latter analysis showed that single nucleotide substitution in a codon generates only 39.5% of the natural diversity on the protein level with 5.2–7 amino acid substitutions per codon. Transversions generate more complex amino acid substitution patterns (increased number and chemically more diverse amino acid substitutions) than transitions. Simultaneous nt exchanges at both first and second nt of a codon generates very diverse amino acid substitution patterns, achieving 83.2% of the natural diversity. The statistical analysis described in this review sets the objectives for novel random mutagenesis methods that address the consequences of the organization of the genetic code. Random mutagenesis methods that favor transversions or introduce consecutive nt exchanges can contribute in this regard.     

Efficient site-directed saturation mutagenesis using degenerate oligonucleotides.

We describe a reliable protocol for constructing single-site saturation mutagenesis libraries consisting of all 20 naturally occurring amino acids at a specific site within a protein. Such libraries are useful for structure-function studies and directed evolution. This protocol extends the utility of Stratagene's QuikChange Site-Directed Mutagenesis Kit, which is primarily recommended for single amino acid substitutions. Two complementary primers are synthesized, containing a degenerate mixture of the four bases at the three positions of the selected codon. These primers are added to starting plasmid template and thermal cycled to produce mutant DNA molecules, which are subsequently transformed into competent bacteria. The protocol does not require purification of mutagenic oligonucleotides or PCR products. This reduces both the cost and turnaround time in high-throughput directed evolution applications. We have utilized this protocol to generate over 200 site-saturation libraries in a DNA polymerase, with a success rate of greater than 95%.     

Improving the quality of industrially important enzymes by directed evolution

Directed evolution is a new process for developing industrially viable biocatalysts. This technique does not require a comprehensive knowledge of the relationships between sequence structure and function of proteins as required by protein engineering. It mimics the process of Darwinian evolution in a test tube combining random mutagenesis and recombination with screening or selection for enzyme variants that have the desired properties. Directed evolution helps in enhancing the enzyme performance both in natural and synthetic environments. This article reviews the process of directed evolution and its application to improve substrate specificity, activity, enantioselectivity and thermal stability.     

A statistical analysis of random mutagenesis methods used for directed protein evolution

We have developed a statistical method named MAP (mutagenesis assistant program) to equip protein engineers with a tool to develop promising directed evolution strategies by comparing 19 mutagenesis methods. Instead of conventional transition/transversion bias indicators as benchmarks for comparison, we propose to use three indicators based on the subset of amino acid substitutions generated on the protein level: (1) protein structure indicator; (2) amino acid diversity indicator with a codon diversity coefficient; and (3) chemical diversity indicator. A MAP analysis for a single nucleotide substitution was performed for four genes: (1) heme domain of cytochrome P450 BM-3 from Bacillus megaterium (EC 1.14.14.1); (2) glucose oxidase from Aspergillus niger (EC 1.1.3.4); (3) arylesterase from Pseudomonas fluorescens (EC 3.1.1.2); and (4) alcohol dehydrogenase from Saccharomyces cerevisiae (EC 1.1.1.1). Based on the MAP analysis of these four genes, 19 mutagenesis methods have been evaluated and criteria for an ideal mutagenesis method have been proposed. The statistical analysis showed that existing gene mutagenesis methods are limited and highly biased. An average amino acid substitution per residue of only 3.15-7.4 can be achieved with current random mutagenesis methods. For the four investigated gene sequences, an average fraction of amino acid substitutions of 0.5-7% results in stop codons and 4.5-23.9% in glycine or proline residues. An average fraction of 16.2-44.2% of the amino acid substitutions are preserved, and 45.6% (epPCR method) are chemically different. The diversity remains low even when applying a non-biased method: an average of seven amino acid substitutions per residue, 2.9-4.7% stop codons, 11.1-16% glycine/proline residues, 21-25.8% preserved amino acids, and 55.5% are amino acids with chemically different side-chains. Statistical information for each mutagenesis method can further be used to investigate the mutational spectra in protein regions regarded as important for the property of interest.     

Knowledge‐guided laboratory evolution of protein thermolability

In rare but nevertheless important cases it is of practical interest to decrease the thermostability of an enzyme, that is, to increase thermolability in a controlled manner. In the present model study, this unconventional goal has been reached by applying directed evolution to the lipase from Pseudomonas aeruginosa (PAL). By utilizing the B‐factor iterative test (B‐FIT), previously developed to increase the thermostability of enzymes, it was possible to reduce the value from 71.6°C in the case of wild type (WT‐PAL) to 35.6°C (best mutant) without affecting the catalytic profile in terms of substrate acceptance or enantioselectivity at room temperature. Accordingly, saturation mutagenesis was performed at sites in PAL, which on the basis of its X‐ray structure, have the lowest B‐factors indicative of high rigidity. Focused mutations were introduced which can be expected to decrease rigidity, the ensuing increased flexibility leading to higher thermolability without changing the actual catalytic profile. Biotechnol. Bioeng. 2009;102: 1712–1717. © 2008 Wiley Periodicals, Inc.