干酪乳杆菌L-乳酸脱氢酶突变体在毕赤酵母中的表达及其不对称还原苯丙酮酸

为提高L-苯乳酸(L-phenyllactic acid,L-PLA)的生产效率,以干酪乳杆菌Lactobacillus casei L-乳酸脱氢酶突变体L-Lc LDH1Q88A/I229A为研究对象,实现其在毕赤酵母Pichia pastoris GS115中的分泌表达,并与葡萄糖脱氢酶SyGDH偶联,构建并优化体外辅酶循环体系,不对称还原苯丙酮酸(Phenylpyruvate,PPA)制备L-PLA。结果显示,毕赤酵母重组酶re Lc LDH1Q88A/I229A的表观分子量为36.8 kDa,比活力为270.5 U/mg,是原酶的42.9倍。在40℃,初始pH为5.0,底物PPA、辅酶NAD+和葡萄糖浓度分别为100、2和120mmol/L,SyGDH和re Lc LDH1Q88A/I229A添加量分别为1和10U/mL的最优条件下,L-PLA的产率可达99.8%,对映体过量(ee)值>99.9%,时空产率和平均转化率分别高达9.5 g/(L·h)和257.0 g/(g·h)。结果表明,re Lc LDH1Q88A/I229A在不对称还原PPA制备L-PLA中生产效率高,...     

Arg77和Glu80定点突变同时去除葡激酶中的T和B细胞抗原表位

【目的】对葡激酶的T和B细胞抗原表位重叠的关键氨基酸Arg77和Glu80进行定点突变以降低葡激酶的免疫原性。【方法】基于Arg77和Glu80的溶剂可及表面积设计葡激酶的突变体;突变体在大肠杆菌DH5α中进行表达。经过三步层析法纯化后,分析突变体的纤溶活性和免疫原性。【结果】免疫学实验提示,葡激酶导致Th2免疫反应;Glu80突变为丙氨酸和丝氨酸减少了溶剂可及表面积,同时去除了部分T和B细胞抗原表位;Arg77突变为天冬酰胺、谷氨酰胺和赖氨酸仅去除了部分T细胞抗原表位;6个组合突变体中,Sak(R77Q/E80A)和Sak(R77Q/E80S)有效去除了部分B和T细胞抗原表位,降低了葡激酶的免疫原性;Sak(R77Q/E80A)and Sak(R77Q/E80S)的纤溶活性和催化效率与r-Sak相当。     

基于结构B因子分析指导的头孢菌素C酰化酶动力学稳定性改造

【目的】筛选Pseudomonas sp.SE83 acy Ⅱ定点饱和突变库,获得动力学稳定性提高的头孢菌素C(CPC)酰化酶突变体,并对突变酶进行初步的结构-功能关系分析。【方法】靶标酶Pseudomonas sp.SE83 acy Ⅱ与Pseudomonas diminuta N176具有较高的同源性,通过分析N176的结构B因子,构建CPC酰化酶SE83定点饱和突变库;基于pH指示剂显色法,采用Biomek FX~P自动工作站建立CPC酰化酶高通量筛选方法,获得优良突变酶,对其活性、稳定性等酶学性质进行表征;利用SWISS-MODEL对突变体进行同源建模,探讨突变体结构与功能的关系。【结果】通过B因子分析和同源结构比对,共找出9个靶标位点;经过3轮筛选,发现R218及K226位点突变显著提高酶的热稳定性,其中最显著的R218Q和K226V在40°C的半衰期分别为野生型的3.77和2.77倍,催化效率k_(cat)/K_m分别为野生型的1.8和3.1倍。同源建模分析表明氢键作用和疏水相互作用的增加可能是突变体稳定性提高的原因。【结论】B因子指导的酶分子改造是一种高效可靠的动力学稳定性改造策略,突变体R218Q和K226V均可提高CPC酰化酶的稳定性和催化效率,对进一步的CPC酰化酶分子改造具有一定的参考价值和指导意义。     

发酵乳杆菌来源l-阿拉伯糖异构酶理性设计及在d-塔格糖生产中的应用

L-阿拉伯糖异构酶(L-arabinose isomerase,L-AI)是D-半乳糖异构化生成D-塔格糖的关键酶。为提高L-阿拉伯糖异构酶对D-半乳糖的活性及在生物转化中的转化率,本研究对发酵乳杆菌(Lactobacillus fermentum)CGMCC2921来源的L-阿拉伯糖异构酶进行重组表达和生物转化应用,并对其底物结合口袋进行理性设计以提高酶对D-半乳糖亲和力和催化活性。结果显示,突变体F279I对D-半乳糖的转化率提高至野生型酶的1.4倍,进一步叠加获得的双突变体M185A/F279I的K_m和k_cat分别为530.8mmol/L与19.9s^-1,底物亲和力显著提高,催化效率提高至野生型酶的8.2倍。以400 g/L乳糖为底物时,突变酶M185A/F279I转化率高达22.8%。本研究在乳糖高值化生产塔格糖方面具有重要的应用价值。     

北京棒杆菌天冬氨酸激酶突变体Q316P的酶学性质

【目的】对北京棒杆菌(Corynebacterium pekinense)天冬氨酸激酶(Aspartate kinase,AK)进行改造,期望获得具有较高酶活力且酶活性质改善的高产天冬氨酸族氨基酸的优良突变株,并削弱甚至解除Thr对AK的反馈抑制作用。【方法】利用定点突变技术对Gln(Q)316位点进行突变,高通量筛选获得活力提高明显的突变体,并将其在大肠杆菌BL21中高效表达,对野生型(Wild type,WT)和突变体Q316P AK用镍柱纯化,进行酶动力学及酶学性质研究。【结果】获得突变体Q316P,并在大肠杆菌BL21中成功表达。与野生型相比,突变体Q316P的V_(max)提高8.53倍,n值由2.15降低为1.29,正协同性减弱;最适温度由25°C升高至30°C;最适p H由8.0降低至7.5,半衰期由3.8 h延长至5.0 h;且在实验范围浓度内,底物抑制剂苏氨酸对突变体Q316P表现出激活作用;Q316P AK对金属离子K+和有机溶剂甲醇表现出良好抗性。【结论】获得酶活力提高、酶学性质改善的突变体,并一定程度上解除苏氨酸对AK的反馈抑制,为构建高产天冬氨酸族氨基酸工程菌提供参考。     

芽孢杆菌P38中乳酸脱氢酶对其产L-乳酸光学纯度的影响

【目的】研究芽孢杆菌(Bacillus sp.) P38中乳酸脱氢酶对其产高光学纯L-乳酸(光学纯度>99%)的影响。【方法】全基因组测序显示在该菌中存在3个乳酸代谢关键酶,分别为L-乳酸脱氢酶(L-LDH)、D-乳酸脱氢酶(D-LDH)和苹果酸或L-乳酸脱氢酶(M/L-LDH)。通过将这3个酶进行异源表达、纯化与酶学特性分析,结合Native-PAGE、实时荧光定量PCR等方法,初步确定该菌高产光学纯L-乳酸的机理。【结果】Bacillus sp. P38中L-LDH对丙酮酸的催化活性(Kcat/Km值)最高,分别是D-LDH的2.9倍和M/L-LDH的4.3倍。其中M/L-LDH主要起L-LDH的功能。Native-PAGE实验中未检测到D-LDH活性。Bacillus sp. P38所有发酵阶段ldhL的转录水平均高于ldhD和ldhM/L。【结论】L-LDH是Bacillus sp. P38产高光学纯L-乳酸的主要关键酶。     

甲硫氨酸γ-裂解酶基因在大肠杆菌中的高效表达和活性

【背景】为了开发海洋蕴藏的新型微生物资源,本研究团队采用不依赖培养的宏基因组技术,构建了深海宏基因组文库,并对其中的重要基因进行后续研究。【目的】使用来自深海宏基因组文库中的甲硫氨酸γ-裂解酶基因(mgl)在大肠杆菌中高效表达并对其活性进行检测。【方法】将mgl基因克隆到表达载体pET-28a(+)并转化大肠杆菌BL21(DE3),经异丙基-β-D-硫代半乳糖苷(IPTG)诱导,并对表达条件进行优化,获得甲硫氨酸γ-裂解酶(Methionine-lyase,r MGL)的大量表达。亲和层析纯化重组蛋白后对酶的活性进行研究。【结果】亲和纯化后获得大量表达蛋白r MGL,大小与预测的46 kD相符合,并具有很高的裂解L-甲硫氨酸的活性。r MGL能催化L-甲硫氨酸和DL-同型半胱氨酸的裂解,但几乎不作用于L-半胱氨酸和L-胱氨酸,其中对DL-同型半胱氨酸的催化效率比对L-甲硫氨酸的催化效率高,相对活性约为对L-甲硫氨酸催化效率的1.4倍。【结论】来自深海宏基因组文库中的mgl基因能够利用p ET-28a(+)/BL21(DE3)高效表达r MGL。     

甲壳素酶Chisb的定向进化及生物转化合成几丁寡糖

甲壳素酶具有广泛的工业应用前景,如可将虾壳、蟹壳和其他甲壳废物降解成以几丁寡糖为主的高附加值产品,但野生型甲壳素酶催化效率低,大大限制了几丁寡糖的生产。笔者在前期研究中表达了一个具有较高效催化效率的甲壳素酶Chisb,并对其酶学性质进行了初步研究。为进一步提高甲壳素酶Chisb的催化效率,以R13NprB-C-SP-H为亲本,采用易错PCR(Error-pronePCR)技术构建随机突变体文库,对甲壳素酶Chisb进行定向进化。经过96孔板初筛和摇瓶复筛,获得了两个催化效率进一步提高的突变体C43D和E336R。对突变体的酶学性质进行分析, C43D和E336R的最适催化温度为55℃, C43D的最适pH为5.0,E336R的最适pH为9.0;其催化效率相比对照分别提高了1.35倍和1.57倍;而E336R和C43D催化产几丁寡糖的含量分别为2.53 g/L和2.06 g/L,相比对照(0.89 g/L)分别提高了2.84倍和2.31倍;底物转化率分别为84.3%和68.7%,相比对照(29.7%)分别提高了54.6%和39%。研究表明,通过易错PCR引入随机突变的方法能够有效提高甲壳素酶Chisb的催化效率。上述研究获得的催化效率提高的正向突变体及其酶学性质分析对生物转化合成几丁寡糖具有重要研究意义和应用价值。     

嗜酸热脂环酸杆菌中甘露聚糖酶活性位点的确立

【目的】通过定点突变确定嗜酸热脂环酸杆菌中甘露聚糖酶的活性催化位点。【方法】根据序列比对和GH53家族的结构信息选择可能的催化活性位点,利用重叠PCR法构建定点突变体,采用薄层层析(TLC)法和3,5-二硝基水杨酸(DNS)法检测各酶蛋白活性。【结果】通过重叠PCR法成功构建了7个位点的突变体,其中第150和159位的氨基酸突变对活性改变甚少或几乎没有,而第151和231位谷氨酸的羧基基团的改变以及双位点突变体E2Q则导致其对各种底物催化活性的丧失,说明位于β4和β7折叠的C末端的E151和E231的羧基基团作为功能基团参与了催化反应。【结论】E151和E231分别是新型甘露聚糖酶AaManA的酸碱催化位点和亲核催化位点。     

长双歧杆菌N-乙酰氨基己糖1-位激酶的活性位点

【目的】研究长双歧杆菌(Bifidobacterium longum)JCM1217的N-乙酰氨基己糖1-位激酶(Nacetylhexosamine 1-kinase,Nah K)中对催化活性有影响的位点。【方法】利用点突变试剂盒,获得Nah K的4个位点的共10种单点突变体表达菌株。诱导表达并纯化野生型和突变体酶,用DNS法和NADH偶联的微孔板分光光度法检测野生型及突变体酶的最适p H和最适Mg~(2+)浓度,并测定酶促反应动力学参数。【结果】D208A、D208N、D208E和I24A四种突变体的催化活性几乎丧失。突变体H31A、H31V、F247A和I24V的最适p H由野生型的7.5变为7.0,突变体H31A和F247A的最适Mg~(2+)浓度由野生型的5 mmol/L变为10 mmol/L。反应动力学参数测定结果表明,突变体F247Y对底物Glc NAc/Gal NAc及ATP的催化活性均高于野生型。【结论】通过定点突变,确定了对Nah K催化活性有影响的4个位点,并且获得了一个催化效率提高的突变体(F247Y),为进一步对Nah K进行分子改造奠定了一定基础。     

Role of feedback regulation of pantothenate kinase (CoaA) in control of coenzyme A levels in Escherichia coli

Pantothenate kinase (CoaA) is a key regulator of coenzyme A (CoA) biosynthesis in Escherichia coli, and its activity is controlled by feedback inhibition by CoA and its thioesters. The importance of feedback inhibition in the control of the intracellular CoA levels was tested by constructing three site-directed mutants of CoaA that were predicted to be feedback resistant based on the crystal structure of the CoaA-CoA binary complex. CoaA[R106A], CoaA[H177Q], and CoaA[F247V] were purified and shown to retain significant catalytic activity and be refractory to inhibition by CoA. CoaA[R106A] retained 50% of the catalytic activity of CoaA, whereas the CoaA[H177Q] and CoaA[F247V] mutants were less active. The importance of feedback control of CoaA to the intracellular CoA levels was assessed by expressing either CoaA or CoaA[R106A] in strain ANS3 [coaA15(Ts) panD2]. Cells expressing CoaA[R106A] had significantly higher levels of phosphorylated pantothenate-derived metabolites and CoA in vivo and excreted significantly more 4'-phosphopantetheine into the medium compared to cells expressing the wild-type protein. These data illustrate the key role of feedback regulation of pantothenate kinase in the control of intracellular CoA levels.     

茄科雷尔氏菌脂酰-CoA合成酶的功能鉴定

【目的】茄科雷尔氏菌是一种常见的农作物致病菌,引起植物青枯病。研究其脂肪酸代谢途径将有助于寻找新的抗菌药物靶点,为防治青枯病害提供新的思路。【方法】利用大肠杆菌FadD序列,进行同源比对发现茄科雷尔氏菌GMI1000中RSc2857(RsFadD)具有较高的相似性,推测其具有脂酰-CoA合成酶活性。采用PCR扩增方法获得RsfadD基因,连入表达载体pBAD24M后互补大肠杆菌fadD突变株,并检测转化子的生长情况。RsfadD与pET-28b连接后,在大肠杆菌BL(DE3)中表达,并利用Ni-NTA纯化获得带有组氨酸标签的RsFadD,体外测定RsFadD的活性。利用同源重组方法,获得RsfadD敲除突变株,分析突变株的生长性状。【结果】RsfadD异体互补大肠杆菌fadD突变株,恢复突变株在以脂肪酸为碳源的基础培养基上生长。体外活性测定RsFadD具有脂酰-CoA合成酶活性,对不同链长的脂肪酸都具有活性,但活性低于大肠杆菌FadD。RsfadD突变株在添加不同链长脂肪酸的基础培养上仅能微弱生长,而在丰富培养基上生长无差异。【结论】茄科雷尔氏菌中RsfadD编码脂酰-CoA合成酶,在脂肪酸利用过程中发挥重要作用。但RsfadD突变株在基础培养基上微弱生长,说明茄科雷尔氏菌基因组中还有其他的脂酰-CoA合成酶基因。以上研究结果为进一步研究茄科雷尔氏菌中脂酰-CoA合成酶以及脂肪酸利用机制奠定了基础。     

Improved autoprocessing efficiency of mutant subtilisins E with altered specificity by engineering of the pro-region.

Modification of substrate specificity of an autoprocessing enzyme is accompanied by a risk of significant failure of self-cleavage of the pro-region essential for activation. Therefore, to enhance processing, we engineered the pro-region of mutant subtilisins E of Bacillus subtilis with altered substrate specificity. A high-activity mutant subtilisin E with Ile31Leu replacement (I31L) as well as the wild-type enzyme show poor recognition of acid residues as the P1 substrate. To increase the P1 substrate preference for acid residues, Glu156Gln and Gly166Lys/Arg substitutions were introduced into the I31L gene based upon a report on subtilisin BPN' [Wells et al. (1987) Proc. Natl. Acad. Sci. USA 84, 1219-1223]. The apparent P1 specificity of four mutants (E156Q/G166K, E156Q/G166R, G166K, and G166R) was extended to acid residues, but the halo-forming activity of Escherichia coli expressing the mutant genes on skim milk-containing plates was significantly decreased due to the lower autoprocessing efficiency. A marked increase in active enzyme production occurred when Tyr(-1) in the pro-region of these mutants was then replaced by Asp or Glu. Five mutants with Glu(-2)Ala/Val/Gly or Tyr(-1)Cys/Ser substitution showing enhanced halo-forming activity were further isolated by PCR random mutagenesis in the pro-region of the E156Q/G166K mutant. These results indicated that introduction of an optimum arrangement at the cleavage site in the pro-region is an effective method for obtaining a higher yield of active enzymes.     

A loop involving catalytic chain residues 230-245 is essential for the stabilization of both allosteric forms of Escherichia coli aspartate transcarbamylase

The allosteric transition of Escherichia coli aspartate transcarbamylase involves significant alterations in structure at both the quaternary and tertiary levels. On the tertiary level, the 240s loop (residues 230-245 of the catalytic chain) repositions, influencing the conformation of Arg-229, a residue near the aspartate binding site. In the T state, Arg-229 is bent out of the active site and may be stabilized in this position by an interaction with Glu-272. In the R state, the conformation of Arg-229 changes, allowing it to interact with the beta-carboxylate of aspartate, and is stabilized in this position by a specific interaction with Glu-233. In order to ascertain the function of Arg-229, Glu-233, and Glu-272 in the catalytic and cooperative interactions of the enzyme, three mutant enzymes were created by site-specific mutagenesis. Arg-229 was replaced by Ala, while both Glu-233 and Glu-272 were replaced by Ser. The Arg-229----Ala and Glu-233----Ser enzymes exhibit 10,000-fold and 80-fold decreases in maximal activity, respectively, and they both exhibit a 2-fold increase in the aspartate concentration at half the maximal observed velocity, [S]0.5. The Arg-229----Ala enzyme still exhibits substantial homotropic cooperativity, but all cooperativity is lost in the Glu-233----Ser enzyme. The Glu-233----Ser enzyme also shows a 4-fold decrease in the carbamyl phosphate [S]0.5, while the Arg-229----Ala enzyme shows no change in the carbamyl phosphate [S]0.5 compared to the wild-type enzyme. The Glu-272 to Ser mutation results in a slight reduction in maximal activity, an increase in [S]0.5 for both aspartate and carbamyl phosphate, and reduced cooperativity. Analysis of the isolated catalytic subunits from these three mutant enzymes reveals that in each case the changes in the kinetic properties of the isolated catalytic subunit are similar to the changes caused by the mutation in the holoenzyme. PALA was able to activate the Glu-233----Ser enzyme, at low aspartate concentrations, even though the mutant holoenzyme did not exhibit any cooperativity, indicating that cooperative interactions still exist between the active sites in this enzyme. It is proposed that Glu-233 of the 240s loop helps create the high-activity-high-affinity R state by positioning the side chain of Arg-229 for aspartate binding while Glu-272 helps stabilize the low-activity-low-affinity T state by positioning the side chain of Arg-229 so that it cannot interact with aspartate.(ABSTRACT TRUNCATED AT 400 WORDS)     

Kinetics of redox interaction between substituted quinones and ascorbate under aerobic conditions.

One-electron reduction of quinones (Q) by ascorbate (AscH ); (1) AscH + Q --> Q*- + Asc*- + H+, followed by the oxidation of semiquinone (Q*-) by molecular oxygen; (2) Q*- + O2 --> Q + O2*-, results in the catalytic oxidation of ascorbate (with Q as a catalyst) and formation of active forms of oxygen. Along with enzymatic redox cycling of Q. this process may be related to Q cytotoxicity and underlie an antitumor activity of some Qs. In this work, the kinetics of oxygen consumption accompanied the interaction of ascorbate with 55 Qs including substituted 1,4- and 1,2-benzoquinones, naphthoquinones and other quinoid compounds were studied in 50 mM sodium phosphate buffer, pH 7.40, at 37 degrees C by using the Clark electrode technique. The capability of Q to catalyze ascorbate oxidation was characterized by the effective value of kEFF calculated from the initial rate of oxygen consumption (R(OX)) by the equation R(OX) = kEFF[Q][AscH-] as well as by a temporary change in R(OX). The correlation of kEFF with one-electron reduction potential, E(Q/Q*-), showed a sigma-like plot, the same for different kinds of Qs. Only the Qs which reduction potential E(Q/Q*-) ranged from nearly -250 to + 50 mV displayed a pronounced catalytic activity, kEFF increased with shifting E(Q/Q*-) to positive values. The following linear correlation between kEFF (in M (-1) s(-1)) and E(Q/Q*-) (in mV) might be suggested for these Qs: lg(kEFF)= 3.91 + 0.0143E(Q/Q*-). In contrast, Qs with E(Q/Q*-) < - 250 mV and E(Q/Q*-) > + 50 mV showed no measurable catalytic activity. The Qs studied displayed a wide variety in the kinetic regularities of oxygen consumption. When E(Q/Q*-) was more negative than - 100 mV, Q displayed a simple ('standard') kinetic behavior--R(OX) was proportional to [AscH-][Q] independently of concentration of individual reagents, [AscH-] and [Q]; R(OX) did not decrease with time if [AscH-] was held constant: Q recycling was almost reversible. Meanwhile, Qs with E(Q/Q*-) > - 100 mV demonstrated a dramatic deviation from the 'standard' behavior that was manifested by the fast decrease in R(OX) with time and non-linear dependence of even starting values of R(OX) on [Q] and [AscH-]. These deviations were caused basically by the participation of Q*- in side reactions different from (2). The above findings were confirmed by kinetic computer simulations. Some biological implications of Q-AscH- interaction were discussed.     

Improving the activity and stability of GL-7-ACA acylase CA130 by site-directed mutagenesis

In the present study, glutaryl-7-amino cephalosporanic acid acylase from Pseudomonas sp. strain 130 (CA130) was mutated to improve its enzymatic activity and stability. Based on the crystal structure of CA130, two series of amino acid residues, one from those directly involved in catalytic function and another from those putatively involved in surface charge, were selected as targets for site-directed mutagenesis. In the first series of experiments, several key residues in the substrate-binding pocket were substituted, and the genes were expressed in Escherichia coli for activity screening. Two of the mutants constructed, Y151alphaF and Q50betaN, showed two- to threefold-increased catalytic efficiency (k(cat)/K(m)) compared to wild-type CA130. Their K(m) values were decreased by ca. 50%, and the k(cat) values increased to 14.4 and 16.9 s(-1), respectively. The ability of these mutants to hydrolyze adipoyl 6-amino penicillinic acid was also improved. In the second series of mutagenesis, several mutants with enhanced stabilities were identified. Among them, R121betaA and K198betaA had a 30 to 58% longer half-life than wild-type CA130, and K198betaA and D286betaA showed an alkaline shift of optimal pH by about 1.0 to 2.0 pH units. To construct an engineered enzyme with the properties of both increased activity and stability, the double mutant Q50betaN/K198betaA was expressed. This enzyme was purified and immobilized for catalytic analysis. The immobilized mutant enzyme showed a 34.2% increase in specific activity compared to the immobilized wild-type CA130.     

来源于瘤胃菌Ruminococcus sp.的D-阿洛酮糖3-差向异构酶的底物结合位点分析

【目的】研究来源于瘤胃菌Ruminococcus sp.的D-阿洛酮糖3-差向异构酶的底物结合机制。【方法】通过同源模拟和同源序列比对,筛选与其底物结合相关的关键位点,进而通过定点突变构建突变体并对其动力学性质进行研究。【结果】筛选得到关键位点Y6和A109,构建了突变体Y6F、Y6I、A109P及A109L。【结论】Y6既与底物结合又与催化能力相关,其-OH只与底物结合相关,芳香环则与催化能力和结合能力均相关;而A109则只是底物结合的位点。该研究结果为D-阿洛酮糖3-差向异构酶的催化机理研究及分子改造提供了借鉴。     

鱼腥藻苯丙氨酸脱氨酶的基因克隆、表达及最适反应pH改造

【目的】表达鱼腥藻苯丙氨酸脱氨酶(AvPAL),并经分子改造降低其最适反应pH。【方法】PCR克隆AvPAL编码基因,并在大肠杆菌中表达,用Ni2+亲和层析柱和凝胶柱纯化重组蛋白。利用GETAREA软件筛选与催化残基距离较近的暴露于酶分子表面的氨基酸位点,将其突变为带电性质不同的氨基酸,并对突变体进行酶学性质研究。【结果】在大肠杆菌中成功表达了AvPAL,纯化后得到电泳纯的重组酶。突变体E75Q和E75R的最适反应pH从8.5分别偏移到7.5和7.0。E75Q在pH 7.5时的比酶活较原酶提高了25%,在pH 6.5–9.5之间酶的稳定性良好,其最适反应温度为50 °C,在此温度下保温1 h酶活无显著变化。在最适反应条件下,E75Q的kcat/Km值较原酶提高了26.6%。【结论】改变AvPAL酶分子中起路易斯碱作用的关键氨基酸残基(质子受体)附近与之有相互作用的氨基酸的带电性质,降低了AvPAL的最适反应pH,提升了其在医疗领域的应用前景。