Functional expression of horseradish peroxidase in Saccharomyces cerevisiae and Pichia pastoris

The ability to engineer proteins by directed evolution requires functional expression of the target polypeptide in a recombinant host suitable for construction and screening libraries of enzyme variants. Bacteria and yeast are preferred, but eukaryotic proteins often fail to express in active form in these cells. We have attempted to resolve this problem by identifying mutations in the target gene that facilitate its functional expression in a given recombinant host. Here we examined expression of HRP in Saccharomyces cerevisiae. Through three rounds of directed evolution by random point mutagenesis and screening, we obtained a 40-fold increase in total HRP activity in the S.cerevisiae culture supernatant compared with wild-type, as measured on ABTS ?2, 2'-azinobis(3-ethylbenzthiazoline-6-sulfonic acid) (260 units/l/OD(600)). Genes from wild-type and two high-activity clones were expressed in Pichia pastoris, where the total ABTS activity reached 600 units/l/OD(600) in shake flasks. The mutants show up to 5.4-fold higher specific activity towards ABTS and 2.3-fold higher specific activity towards guaiacol.     

The diheme cytochrome c peroxidase from Shewanella oneidensis requires reductive activation

We report the characterization of the diheme cytochrome c peroxidase (CcP) from Shewanella oneidensis (So) using UV-visible absorbance, electron paramagnetic resonance spectroscopy, and Michaelis-Menten kinetics. While sequence alignment with other bacterial diheme cytochrome c peroxidases suggests that So CcP may be active in the as-isolated state, we find that So CcP requires reductive activation for full activity, similar to the case for the canonical Pseudomonas type of bacterial CcP enzyme. Peroxide turnover initiated with oxidized So CcP shows a distinct lag phase, which we interpret as reductive activation in situ. A simple kinetic model is sufficient to recapitulate the lag-phase behavior of the progress curves and separate the contributions of reductive activation and peroxide turnover. The rates of catalysis and activation differ between MBP fusion and tag-free So CcP and also depend on the identity of the electron donor. Combined with Michaelis-Menten analysis, these data suggest that So CcP can accommodate electron donor binding in several possible orientations and that the presence of the MBP tag affects the availability of certain binding sites. To further investigate the structural basis of reductive activation in So CcP, we introduced mutations into two different regions of the protein that have been suggested to be important for reductive activation in homologous bacterial CcPs. Mutations in a flexible loop region neighboring the low-potential heme significantly increased the activation rate, confirming the importance of flexible loop regions of the protein in converting the inactive, as-isolated enzyme into the activated form.     

Comparative proton NMR analysis of wild-type cytochrome c peroxidase from yeast, the recombinant enzyme from Escherichia coli, and an Asp-235----Asn-235 mutant

Proton NMR spectra of cytochrome c peroxidase (CcP) isolated from yeast (wild type) and two Escherichia coli expressed proteins, the parent expressed protein [CcP(MI)] and the site-directed mutant CcP(MI,D235N) (Asp-235----Asn-235), have been examined. At neutral pH and in the presence of only potassium phosphate buffer and potassium nitrate, wild-type Ccp and CcP(MI) demonstrate nearly identical spectra corresponding to normal (i.e., "unaged") high-spin ferric peroxidase. In contrast, the mutant protein displays a spectrum characteristic of a low-spin form, probably a result of hydroxide ligation. Asp-235 is hydrogen-bonded to the proximal heme ligand, His-175. Changing Asp-235 to Asn results in alteration of the pK for formation of the basic form of CcP. Thus, changes in proximal side structure mediate the chemistry of the distal ligand binding site. All three proteins bind F-, N3-, and CN- ions, although the affinity of the mutant protein (D235N) for fluoride ion appears to be much higher than that of the other two proteins. Analysis of proton NMR spectra of the cyanide ligated forms leads to the conclusion that the mutant protein (D235N) possesses a more neutral proximal histidine imidazole ring than does either wild-type CcP or CcP(MI). It confirms that an important feature of the cytochrome c peroxidase structure is at least partial, and probably full, imidazolate character for the proximal histidine (His-175).     

Yeast cytochrome c peroxidase expression in Escherichia coli and rapid isolation of various highly pure holoenzymes

A more efficient 2-day isolation and purification method for recombinant yeast cytochrome c peroxidase produced in Escherichia coli is presented. Two types of recombinant "wild-type" CcP have been produced and characterized, the recombinant nuclear gene sequence and the 294-amino-acid original protein sequence. These two sequences constitute the majority of the recombinant "native" or wild-type CcP currently in production and from which all recombinant variants now derive. The enzymes have been subjected to extensive physical characterizations, including sequencing, UV-visible spectroscopy, HPLC, gel electrophoresis, kinetic measurements, NMR spectroscopy, and mass spectrometry. Less extensive characterization data are also presented for recombinant, perdeuterated CcP, an enzyme produced in >95% deuterated medium. All of these results indicate that the purified recombinant wild-type enzymes are functionally and spectroscopically identical to the native, yeast-isolated wild-type enzyme. This improved method uses standard chromatography to produce highly purified holoenzyme in a more efficient manner than previously achieved. Two methods for assembling the holoenzyme are described. In one, exogenous heme is added at lysis, while in the other heme biosynthesis is stimulated in E. coli. A primary reason for developing this method has been the need to minimize loss of precious, isotope-labeled enzyme and, so, this method has also been used to produce both the perdeuterated and the (15)N-labeled enzyme, as well as several variants.     

Divergent evolutionary lines of fungal cytochrome c peroxidases belonging to the superfamily of bacterial, fungal and plant heme peroxidases

Novel open reading frames coding for cytochrome c peroxidase (CcP) belonging to the superfamily of bacterial, fungal, and plant heme peroxidases were analyzed in the available fungal genomes. Multiple sequence alignment of 71 selected peroxidase genes revealed the presence of three conserved regions essential for their function: one on the distal and two on the proximal side of the prosthetic heme group. Conserved sequence motifs on the proximal heme side are peculiar for CcPs and are responsible for their reactivity. Phylogenetic analysis performed with the distance method as well as with the maximum likelihood method revealed the existence of three distinct subfamilies of fungal CcP and their relationship to other members of the peroxidase superfamily. These divergent CcP evolutionary lines apparently evolved from a single primordial heme peroxidase gene in parallel with the evolution of ascorbate peroxidase genes. Analyzed CcPs differ significantly in their N-terminal sequences. Only subfamily I did not exhibit a presence of any signal sequence. Subfamily II members possess a well defined signal sequence allowing processing and release into mitochondrion and also in subfamily III a signal sequence was detected. Several here analyzed peroxidase genes mainly from Candida albicans and from Rhizopus oryzae can be considered interesting for the investigation of the structure-function relationship of novel CcPs revealing differences to the well documented properties of cytochrome c peroxidase from Saccharomyces cerevisiae.     

Geobacter sulfurreducens cytochrome c peroxidases: electrochemical classification of catalytic mechanisms

Bacterial cytochrome c peroxidase (CcP) enzymes are diheme redox proteins that reduce hydrogen peroxide to water. They are canonically characterized by a peroxidatic (called L, for "low reduction potential") active site heme and a secondary heme (H, for "high reduction potential") associated with electron transfer, and an enzymatic activity that exists only when the H-heme is prereduced to the Fe(II) oxidation state. The prereduction step results in a conformational change at the active site itself, where a histidine-bearing loop will adopt an "open" conformation allowing hydrogen peroxide to bind to the Fe(III) of the L-heme. Notably, the enzyme from Nitrosomonas europaea does not require prereduction. Previously, we have shown that protein film voltammetry (PFV) is a highly useful tool for distinguishing the electrocatalytic mechanisms of the Nitromonas type of enzyme from other CcPs. Here, we apply PFV to the recently described enzyme from Geobacter sulfurreducens and the Geobacter S134P/V135K double mutant, which have been shown to be similar to members of the canonical subclass of peroxidases and the Nitrosomonas subclass of enzymes, respectively. Here we find that the wild-type Geobacter CcP is indeed similar electrochemically to the bacterial CcPs that require reductive activation, yet the S134P/V135K mutant shows two phases of electrocatalysis: one that is low in potential, like that of the wild-type enzyme, and a second, higher-potential phase that has a potential dependent upon substrate binding and pH yet is at a potential that is very similar to that of the H-heme. These findings are interpreted in terms of a model in which rate-limiting intraprotein electron transfer governs the catalytic performance of the S134P/V135K enzyme.     

Thyroid hormone synthesis and thyroglobulin iodination related to the peroxidase localization of oxidizing equivalents: studies with cytochrome c peroxidase and horseradish peroxidase

Cytochrome c peroxidase (CcP) and horseradish peroxidase (HRP), when combined with a stoichiometric amount of H2O2, form stable compounds I which are known as FeIV Ro and FeIV o pi + structures, respectively. These compounds were assayed in the catalysis of thyroid hormone synthesis and the iodination reaction. As previously shown for the lactoperoxidase FeIV Ro compound, the CcP FeIV Ro compound was involved in the coupling and not in the iodination reactions. In contrast, the HRP FeIV o pi + compound catalyzed both iodination and hormone formation. The possible role of the different peroxidase-H2O2 compounds in the two sequential reactions, thyroglobulin iodination and thyroid hormone formation, is discussed.     

Mesopone cytochrome c peroxidase: functional model of heme oxygenated oxidases

The effect of heme ring oxygenation on enzyme structure and function has been examined in a reconstituted cytochrome c peroxidase. Oxochlorin derivatives were formed by OsO(4) treatment of mesoporphyrin followed by acid-catalyzed pinacol rearrangement. The northern oxochlorin isomers were isolated by chromatography, and the regio-isomers assignments determined by 2D COSY and NOE 1H NMR. The major isomer, 4-mesoporphyrinone (Mp), was metallated with FeCl(2) and reconstituted into cytochrome c peroxidase (CcP) forming a hybrid green protein, MpCcP. The heme-altered enzyme has 99% wild-type peroxidase activity with cytochrome c. EPR spectroscopy of MpCcP intermediate compound I verifies the formation of the Trp(191) radical similar to wild-type CcP in the reaction cycle. Peroxidase activity with small molecules is varied: guaiacol turnover increases approximately five-fold while that with ferrocyanide is approximately 85% of native. The electron-withdrawing oxo-substitutents on the cofactor cause a approximately 60-mV increase in Fe(III)/Fe(II) reduction potential. The present investigation represents the first structural characterization of an oxochlorin protein with X-ray intensity data collected to 1.70 A. Although a mixture of R- and S-mesopone isomers of the FeMP cofactor was used during heme incorporation into the apo-protein, only the S-isomer is found in the crystallized protein.     

pH Dependence of heme iron coordination, hydrogen peroxide reactivity, and cyanide binding in cytochrome c peroxidase(H52K)

Replacement of the distal histidine, His-52, in cytochrome c peroxidase (CcP) with a lysine residue produces a mutant cytochrome c peroxidase, CcP(H52K), with spectral and kinetic properties significantly altered compared to those of the wild-type enzyme. Three spectroscopically distinct forms of the enzyme are observed between pH 4.0 and 8.0 with two additional forms, thought to be partially denatured forms, making contributions to the observed spectra at the pH extremes. CcP(H52K) exists in at least three, slowly interconverting conformational states over most of the pH range that was investigated. The side chain epsilon-amino group of Lys-52 has an apparent pK(a) of 6.4 +/- 0.2, and the protonation state of Lys-52 affects the spectral properties of the enzyme and the reactions with both hydrogen peroxide and HCN. In its unprotonated form, Lys-52 acts as a base catalyst facilitating the reactions of both hydrogen peroxide and HCN with CcP(H52K). The major form of CcP(H52K) reacts with hydrogen peroxide with a rate approximately 50 times slower than that of wild-type CcP but reacts with HCN approximately 3 times faster than does the wild-type enzyme. The major form of the mutant enzyme has a higher affinity for HCN than does native CcP.     

Apolar distal pocket mutants of yeast cytochrome c peroxidase: Hydrogen peroxide reactivity and cyanide binding of the TriAla,TriVal, and TriLeu variants

Three yeast cytochrome c peroxidase (CcP) variants with apolar distal heme pockets have been constructed. The CcP variants have Arg48, Trp51, and His52 mutated to either all alanines, CcP(triAla), all valines, CcP(triVal), or all leucines, CcP(triLeu). The triple mutants have detectable enzymatic activity at pH 6 but the activity is less than 0.02% that of wild-type CcP. The activity loss is primarily due to the decreased rate of reaction between the triple mutants and H₂O₂ compared to wild-type CcP. Spectroscopic properties and cyanide binding characteristics of the triple mutants have been investigated over the pH stability region of CcP, pH 4 to 8. The absorption spectra indicate that the CcP triple mutants have hemes that are predominantly five-coordinate, high-spin at pH 5 and six-coordinate, low-spin at pH 8. Cyanide binding to the triple mutants is biphasic indicating that the triple mutants have two slowly-exchanging conformational states with different cyanide affinities. The binding affinity for cyanide is reduced at least two orders of magnitude in the triple mutants compared to wild-type CcP and the rate of cyanide binding is reduced by four to five orders of magnitude. Correlation of the reaction rates of CcP and 12 distal pocket mutants with H₂O₂ and HCN suggests that both reactions require ionization of the reactants within the distal heme pocket allowing the anion to bind the heme iron. Distal pocket features that promote substrate ionization (basic residues involved in base-catalyzed substrate ionization or polar residues that can stabilize substrate anions) increase the overall rate of reaction with H₂O₂ and HCN while features that inhibit substrate ionization slow the reactions.     

High-Activity Barley \bold\ralpha-Amylase by Directed Evolution

Barley -amylase isozyme 2 was cloned into and constitutively secreted by Saccharomyces cervisiae. The gene coding for the wild-type enzyme was subjected to directed evolution. Libraries of mutants were screened by halo formation on starch agar plates, followed by high-throughput liquid assay using dye-labeled starch as the substrate. The concentration of recombinant enzyme in the culture supernatant was determined by immunodetection, and used for the calculation of specific activity. After three rounds of directed evolution, one mutant (Mu322) showed 1000 times the total activity and 20 times the specific activity of the wild-type enzyme produced by the same yeast expression system. Comparison of the amino acid sequence of this mutant with the wild type revealed five substitutions: Q44H, R303K and F325Y in domain A, and T94A and R128Q in domain B. Two of these mutations, Q44H and R303K, result in amino acids highly conserved in cereal -amylases. R303K and F325Y are located in the raw starch-binding fragment of the enzyme molecule.     

Protective effect of L-carnitine on hyperammonemia

The diheme cytochrome c-554 which participates in ammonia oxidation in the chemoautotroph , Nitrosomonas europaea has been studied by Soret excitation resonance Raman spectroscopy. The Raman spectrum of reduced cytochrome c-554 at neutral pH is similar classical 6-coordinate low-spin ferrous mammalian cytochrome c. In contrast, the spectrum of ferric cytochrome c-554 suggests a 5-coordinate state which is unusual for c hemes. The oxidized spectrum closely resemble that of horseradish peroxidase (HRP) or cytochrome c peroxidase (CcP) at pH 6.4. The narrow linewidth of the heme core-size vibrations indicates that both heme irons of c-554 have similar geometries.     

金针菇细胞色素c过氧化物酶基因（ffccp）及其在菌柄伸长的差异表达初步分析

细胞色素c过氧化物酶（cytochrome C peroxidase,CcP）是细胞内H₂O₂的主要降解酶,参与真菌的氧化应答过程。本研究基于基因组数据获得一个金针菇细胞色素c过氧化物酶编码基因,命名为ffccp。该基因全长1 913bp,包含一个1 098bp的完整开放阅读框,编码365个氨基酸。生物信息学分析结果显示,该基因编码的蛋白质（FfCcP）无跨膜结构和信号肽,不形成二硫键结构,亚细胞定位于线粒体上,具备血红素结合蛋白的保守位点。序列比对和进化分析结果显示,金针菇与糙皮侧耳Pleurotus ostreatus等大型真菌的CcP序列高度相似（相似度均超过70%）,属于CcP家族蛋白。RT-qPCR的检测结果显示,氧化胁迫和损伤胁迫均能诱导ffccp基因上调表达,但两种胁迫对ffccp表达的调控机制可能并不相同。进一步检测ffccp在子实体发育过程中的差异表达情况,发现ffccp在伸长期菌柄出现显著上调表达,且表达量与菌柄伸长速度的相关性达到0.998,为极强正相关。推测ffccp的上调表达可能有利于菌柄的伸长。     

Cyanide binding to cytochrome c peroxidase (H52L)

Cyanide binding to a cytochrome c peroxidase (CcP) variant in which the distal histidine has been replaced by a leucine residue, CcP(H52L), has been investigated as a function of pH using spectroscopic, equilibrium, and kinetic methods. Between pH 4 and 8, the apparent equilibrium dissociation constant for the CcP(H52L)/cyanide complex varies by a factor of 60, from 135 microM at pH 4.7 to 2.2 microM at pH 8.0. The binding kinetics are biphasic, involving bimolecular association of the two reactants, followed by an isomerization of the enzyme/cyanide complex. The association rate constant could be determined up to pH 8.9 using pH-jump techniques. The association rate constant increases by almost 4 orders of magnitude over the pH range investigated, from 1.8 x 10(2) M(-1) s(-1) at pH 4 to 9.2 x 10(5) M(-1) s(-1) at pH 8.6. In contrast to wild-type CcP, where the binding of HCN is the dominant binding pathway, CcP(H52L) preferentially binds the cyanide anion. Above pH 8, cyanide binding to CcP(H52L) is faster than cyanide binding to wild-type CcP. Cyanide dissociates 4 times slower from the mutant protein although the pH dependence of the dissociation rate constant is essentially identical for CcP(H52L) and CcP. Isomerization of the CcP(H52L)/cyanide complex is observed between pH 4 and 8 and stabilizes the complex. The isomerization rate constant has a similar magnitude and pH dependence as the cyanide dissociation rate constant, and the two reactions are coupled at low cyanide concentrations. This isomerization has no counterpart in the wild-type CcP/cyanide complex.     

Characterisation of Fasciola hepatica cytochrome c peroxidase as an enzyme with potential antioxidant activity in vitro.

Cytochrome c peroxidase oxidises hydrogen peroxide using cytochrome c as the electron donor. This enzyme is found in yeast and bacteria and has been also described in the trematodes Fasciola hepatica and Schistosoma mansoni. Using partially purified cytochrome c peroxidase samples from Fasciola hepatica we evaluated its role as an antioxidant enzyme via the investigation of its ability to protect against oxidative damage to deoxyribose in vitro. A system containing FeIII-EDTA plus ascorbate was used to generate reactive oxygen species superoxide radical, H2O2 as well as the hydroxyl radical. Fasciola hepatica cytochrome c peroxidase effectively protected deoxyribose against oxidative damage in the presence of its substrate cytochrome c. This protection was proportional to the amount of enzyme added and occurred only in the presence of cytochrome c. Due to the low specific activity of the final partially purified sample the effects of ascorbate and calcium chloride on cytochrome c peroxidase were investigated. The activity of the partially purified enzyme was found to increase between 10 and 37% upon reduction with ascorbate. However, incubation of the partially purified enzyme with 1 mM calcium chloride did not have any effect on enzyme activity. Our results showed that Fasciola hepatica CcP can protect deoxyribose from oxidative damage in vitro by blocking the formation of the highly toxic hydroxyl radical (.OH). We suggest that the capacity of CcP to inhibit .OH-formation, by efficiently removing H2O2 from the in vitro oxidative system, may extend the biological role of CcP in response to oxidative stress in Fasciola hepatica.     

Preparation and kinetic studies of immobilised yeast cytochrome c peroxidase.

Yeast cytochrome c peroxidase (CcP) was purified from baker's yeast and immobilised onto a nylon membrane. The kinetics of the soluble and immobilised forms of the enzyme were investigated for the catalysed oxidation of potassium ferrocyanide in the presence of H2O2 and m-chloroperoxybenzoic acid. The pH dependence of the two forms of the enzyme differed. Although both the soluble and the immobilised enzymes showed optimal activity at pH 6.2, a different kinetic behaviour was demonstrated. Both forms of the enzyme showed similar activity toward H2O2, although when m-chloroperoxybenzoic acid was replaced as the electron acceptor, the immobilised form of the enzyme had a reduced turnover number and an increased Km. The activation energy of immobilised CcP was greater in the presence of both H2O2 [16.6 kJ mol-1] and m-chloroperoxybenzoic acid [37.9 kJ mol-1] than for soluble CcP [11.4 and 23.4 kJ mol-1, respectively]. The activities of both soluble and immobilised CcP were greatly reduced above 45 degrees C, although at higher temperatures the immobilised enzyme retained a relatively greater percentage of its maximum activity.     

鼻咽癌侯选抑瘤基因BRD7原核表达载体的构建及其表达

BRD7基因是一个鼻咽癌侯选抑瘤基因,为了构建BRD7基因的原核表达载体并使其在大肠杆菌得到表达,设计了带有SalⅠ,NotⅠ酶切位点的引物,以已构建好的质粒pGEM-T Easy/BRD7为模板,用PCR扩增出BRD7基因的完整阅读框架,并用SalⅠ,NotⅠ酶切PCR产物和原核表达载体PGEX-4T-2,然后用T4 DNA连接酶将其连接,得到重组表达质粒PGEX-4T-2/BRD7,经双酶切鉴定和测序验证,表达载体构建正确.重组表达质粒转化感受态大肠杆菌Jm105后用IPTG诱导,成功表达了一分子质量约为90 ku的融合蛋白;37℃诱导4 h后,SDS-聚丙烯酰胺凝胶(PAGE)电泳后,经扫描分析该融合蛋白产量占菌体蛋白总量28.48%, 蛋白质印迹(Western-blot)证实了该融合蛋白的表达获得成功.这为BRD7基因的蛋白纯化及抗体制备,进一步开展其功能研究奠定了基础.     

抗HBsAg-碱性磷酸酶双功能抗体分子的构建

为构建带有碱性磷酸酶活性的双功能基因工程抗体, 用PCR方法克隆大肠杆菌碱性磷酸酶基因, 通过酶切分析和DNA序列测定核实后,将其重组到抗乙肝表面抗原(HBsAg) Fab段的Fd羧基端,构建重组融合蛋白表达载体pHBFAP, 转化大肠杆菌XL1-Blue, 经异丙基硫代-β-D-半乳糖苷诱导表达后, 采用ELISA法检测到培养上清中存在与HBsAg的结合活性和碱性磷酸酶的催化活性, 显示抗HBsAg-碱性磷酸酶双功能抗体分子在大肠杆菌中获得了表达.