A Mobile PTS2 Receptor for Peroxisomal Protein Import in Pichia pastoris

Abstract. Using a new screening procedure for the isolation of peroxisomal import mutants in Pichia pastoris, we have isolated a mutant (pex7) that is specifically disturbed in the peroxisomal import of proteins containing a peroxisomal targeting signal type II (PTS2). Like its Saccharomyces cerevisiae homologue, PpPex7p interacted with the PTS2 in the two-hybrid system, suggesting that Pex7p functions as a receptor. The pex7Δ mutant was not impaired for growth on methanol, indicating that there are no PTS2-containing enzymes involved in peroxisomal methanol metabolism. In contrast, pex7Δ cells failed to grow on oleate, but growth on oleate could be partially restored by expressing thiolase (a PTS2-containing enzyme) fused to the PTS1. Because the subcellular location and mechanism of action of this protein are controversial, we used various methods to demonstrate that Pex7p is both cytosolic and intraperoxisomal. This suggests that Pex7p functions as a mobile receptor, shuttling PTS2-containing proteins from the cytosol to the peroxisomes. In addition, we used PpPex7p as a model protein to understand the effect of the Pex7p mutations found in human patients with rhizomelic chondrodysplasia punctata. The corresponding PpPex7p mutant proteins were stably expressed in P. pastoris, but they failed to complement the pex7Δ mutant and were impaired in binding to the PTS2 sequence.     

Oxidation of Methanol by the Yeast,Pichia pastoris. Purification and Properties of the Alcohol Oxidase

The enzymes of methanol oxidation were investigated in a new yeast strain, Pichia pastoris IFP 206, with high yield (0.42 g cell per g of methanol). The following enzymes were detected in cell free extracts of P. pastoris: alcohol oxidase, catalase, formaldehyde and formate dehydrogenases. The alcohol oxidase was purified from cell free extracts of P. pastoris containing high amount of the enzyme (33%) with a good yield (55%). The preparation was homogenous by immunochemical methods. The enzyme had a molecular weight of 675,000 and was composed of eight identical subunits of M.W. 80,000. Each subunit contained one FAD. The N-terminal sequence was found to be: Ala-Ile-Pro-Glu-Glu-Phe-Asp-Ile-Leu-Val-Leu-Gly-The protein had 65 free ?SH groups per molecule. The optimum temperature for the enzyme activity was 37°C and the activation energy was 11.1 kcal/mol. Optimum pH was 7.5 and the enzyme activity was unstable at acidic pH. The apparent Km for methanol were 1.4 and 3.1 mm at oxygen concentrations of 0.19 and 0.93 mm. Similarly, the apparent Kms for oxygen were 0.40 and 1.0 mm at methanol concentrations of 1, 10 and 100 mm. The enzyme oxidized primary alcohols with short carbon chains like ethanol and propanol. Inhibition of enzyme activity by hydrogen peroxide was a consequence of the oxidation of essential ?SH groups. The inhibition was reversed by reducing agents.     

靶向性DNA甲基化酶在毕赤酵母中的表达和鉴定

目的：在毕赤酵母中表达融合Myc—His标签的靶向性甲基化酶B1—3a并进行鉴定。方法：以含有B1—3a基因的pcDNA4．0-myc／his质粒为模板,通过PCR扩增获得融合有myc／his标签序列的目的区段B1—3a基因,然后克隆入表达载体pPIC3-5k;电穿孔转化毕赤酵母菌株GS115,经G418筛选后进行甲醇诱导表达,并以SDS—PAGE和Western印迹对表达产物进行鉴定。结果：表达产物中可见与目的蛋白相对分子质量（50000）相符的条带,该条带可被Myc标签单克隆抗体特异识别。结论：正确构建了靶向性甲基化酶Bl-3a的酵母表达载体,靶向性甲基化酶能够在毕赤酵母中成功表达。     

D-氨基酸氧化酶在不同毕赤酵母宿主菌中的表达比较

D-氨基酸氧化酶（DAAO）在转化头孢菌素C生产7-ACA和转化DL-氨基酸制备α-酮酸和L-氨基酸上起着重要的作用。采用DNA操作技术,将来源于三角酵母的DAAO基因连接至表达载体pPIC35K上,再将表达质粒pPIC35KDAAO分别整合P. pastoris的宿主细胞KM71和GS115,经筛选获得阳性重组菌PDK13（Mut^S）和PD27（Mut⁺）。重点对两种突变菌的表达条件进行了比较。结果显示：PDK13（Mut^S）株比PD27（Mut⁺）株消耗甲醇慢、诱导时间长,但对通气量要求低、表达水平高,摇瓶活力分别达到2700和2500 IU/L,14L发酵罐内活力分别达到10140和8463 IU/L。初步探索了DAAO对DL-苯丙氨酸的拆分,结果显示基因工程菌表达的DAAO具有良好的转化DL-苯丙氨酸制备苯丙酮酸和L-苯丙氨酸的能力。     

Assembly of bacteriophage Qbeta virus-like particles in yeast Saccharomyces cerevisiae and Pichia pastoris

Recombinant bacteriophage Qbeta coat protein (CP), which has been proposed as a promising carrier of foreign epitopes via their incorporation either by gene engineering techniques or by chemical coupling, efficiently self-assembles into virus-like particles (VLPs) when expressed in Escherichia coli. Here, we demonstrate expression and self-assembly of Qbeta CP in yeast Saccharomyces cerevisiae and Pichia pastoris. Production reached 3-4 mg/1g of wet cells for S. cerevisiae and 4-6 mg for P. pastoris, which was about 15-20% and 20-30% of the E. coli expression level, respectively. Qbeta VLPs were easily purified by size-exclusion chromatography in both cases and contained nucleic acid, shown by native agarose gel electrophoresis. The obtained particles were highly immunogenic in mice and the resulting sera recognized both E. coli- and yeast-derived Qbeta VLPs equally well.     

A PEX7-Centered Perspective on the Peroxisomal Targeting Signal Type 2-Mediated Protein Import Pathway

Peroxisomal matrix proteins are synthesized on cytosolic ribosomes and transported to the organelle by shuttling receptors. Matrix proteins containing a type 1 signal are carried to the peroxisome by PEX5, whereas those harboring a type 2 signal are transported by a PEX5-PEX7 complex. The pathway followed by PEX5 during the protein transport cycle has been characterized in detail. In contrast, not much is known regarding PEX7. In this work, we show that PEX7 is targeted to the peroxisome in a PEX5- and cargo-dependent manner, where it becomes resistant to exogenously added proteases. Entry of PEX7 and its cargo into the peroxisome occurs upstream of the first cytosolic ATP-dependent step of the PEX5-mediated import pathway, i.e., before monoubiquitination of PEX5. PEX7 passing through the peroxisome becomes partially, if not completely, exposed to the peroxisome matrix milieu, suggesting that cargo release occurs at the trans side of the peroxisomal membrane. Finally, we found that export of peroxisomal PEX7 back into the cytosol requires export of PEX5 but, strikingly, the two export events are not strictly coupled, indicating that the two proteins leave the peroxisome separately.     

An Efficient Positive Selection Procedure for the Isolation of Peroxisomal Import and Peroxisome Assembly Mutants of Saccharomyces Cerevisiae

To study peroxisome biogenesis, we developed a procedure to select for Saccharomyces cerevisiae mutants defective in peroxisomal protein import or peroxisome assembly. For this purpose, a chimeric gene was constructed encoding the bleomycin resistance protein linked to the peroxisomal protein luciferase. In wild-type cells this chimeric protein is imported into the peroxisome, which prevents the neutralizing interaction of the chimeric protein with its toxic phleomycin ligand. Peroxisomal import and peroxisome assembly mutants are unable to import this chimeric protein into their peroxisomes. This enables the bleomycin moiety of the chimeric protein to bind phleomycin, thereby preventing its toxicity. The selection is very efficient: upon mutagenesis, 84 (10%) of 800 phleomycin resistant colonies tested were unable to grow on oleic acid. This rate could be increased to 25% using more stringent selection conditions. The selection procedure is very specific; all oleic acid non utilizing (onu) mutants tested were disturbed in peroxisomal import and/or peroxisome assembly. The pas (peroxisome assembly) mutants that have been used for complementation analysis represent 12 complementation groups including three novel ones, designated pas20, pas21 and pas22.     

Expression, purification, and characterization of equistatin in Pichia pastoris

Equistatin (EI) is a cysteine protease inhibitor that was isolated from the sea anemone Actinia equina. It belongs to a recently discovered group of thyroglobulin type-I domain inhibitors called thyropins. Since native EI is found only in low amounts in the body of sea anemone and expression of recombinant EI in Escherichia coli yielded only 1 mg/liter of protein, we used the Pichia pastoris expression system to obtain higher yields. A cDNA encoding EI was inserted into pPIC9 vector and transformed into the P. pastoris, strain GS115. Clones expressing high levels of EI were selected from 48 transformants. Recombinant EI was produced in 2-liter shake flasks and recovered from the fermentation broth by affinity chromatography using CM-papain-Sepharose. SDS-PAGE and N-terminal sequence analysis revealed that EI was N-terminally intact and running at the expected molecular weight of 22 kDa. The equilibrium dissociation constants of EI with papain and bovine cathepsin D were determined and were found to be similar to the results for the native inhibitor. EI production was scaled up to a bench top fermentor with a 25 mg/liter yield of active EI.     

蜂毒素分子的改造及其基因在毕赤酵母中的表达

为获得保留有抗菌活性而降低溶血作用的蜂毒素,对蜂毒素的分子结构进行了改造.将第5位的Val变为Arg,第15位Ala变为Arg,删除了第16位的Leu.用PCR技术获得了改造后的蜂毒素基因,将其克隆入酵母表达载体pPICZa-A,获得重组表达质粒pPICZa-A-MEA.该质粒转化毕赤酵母菌GS115,甲醇诱导下表达,发酵上清液经抑菌活性、溶血活性测定及亲和层析纯化,结果表明,蜂毒素基因成功地在毕赤酵母中表达,经改造后表达的蜂毒素保留了抗菌活性且溶血活性显著降低,经纯化后用Bradford法测定表达蜂毒素的含量约为0.29mg/ml.     

Mitochondrial Protein Synthesis,Import, and Assembly

The mitochondrion is arguably the most complex organelle in the budding yeast cell cytoplasm. It is essential for viability as well as respiratory growth. Its innermost aqueous compartment, the matrix, is bounded by the highly structured inner membrane, which in turn is bounded by the intermembrane space and the outer membrane. Approximately 1000 proteins are present in these organelles, of which eight major constituents are coded and synthesized in the matrix. The import of mitochondrial proteins synthesized in the cytoplasm, and their direction to the correct soluble compartments, correct membranes, and correct membrane surfaces/topologies, involves multiple pathways and macromolecular machines. The targeting of some, but not all, cytoplasmically synthesized mitochondrial proteins begins with translation of messenger RNAs localized to the organelle. Most proteins then pass through the translocase of the outer membrane to the intermembrane space, where divergent pathways sort them to the outer membrane, inner membrane, and matrix or trap them in the intermembrane space. Roughly 25% of mitochondrial proteins participate in maintenance or expression of the organellar genome at the inner surface of the inner membrane, providing 7 membrane proteins whose synthesis nucleates the assembly of three respiratory complexes.TO think about how mitochondrial proteins are synthesized, imported, and assembled, it is useful to have a clear picture of the organellar structures that they, along with membrane lipids, compose and the functions that they carry out. As almost every schoolchild learns, mitochondria carry out oxidative phosphorylation, the controlled burning of nutrients coupled to ATP synthesis. Since Saccharomyces cerevisiae prefers to ferment sugars, respiration is a dispensable function and nonrespiring mutants are viable [although they cannot undergo meiosis (Jambhekar and Amon 2008)]. However, mitochondria themselves are not dispensable. A substantial fraction of intermediary metabolism occurs in mitochondria (Strathern et al. 1982), and at least one of these pathways, iron–sulfur cluster assembly, is essential for growth (Kispal et al. 2005). Thus, any mutation that prevents the biogenesis of mitochondria by, for example, preventing the import of protein constituents from the cytoplasm, is lethal (Baker and Schatz 1991).The mitochondria of S. cerevisiae are tubular structures at the cell cortex. While the number of distinct compartments can range from 1 to ∼50 depending upon conditions (Stevens 1981; Pon and Schatz 1991), continual fusion and fission events among them effectively form a single dynamic network (Nunnari et al. 1997). The outer membrane surrounds the tubules. The inner membrane has a boundary domain closely juxtaposed beneath the outer membrane and cristae domains that project internally from the boundary into the matrix (Figure 1A). The matrix is the aqueous compartment surrounded by the inner membrane. The aqueous intermembrane space lies between the membranes and is continuous with the space within cristae.Open in a separate windowFigure 1 Overview of mitochondrial structure in yeast. (A) Schematic of compartments comprising mitochondrial tubules. The outer membrane surrounds the organelle. The inner membrane surrounds the matrix and consists of two domains, the inner boundary membrane and the cristae membranes, which are joined at cristae junctions. The intermembrane space lies between the outer membrane and inner membrane. (B) Electron tomograph image of a highly contracted yeast mitochondrion observed en face (a) with the outer membrane (red) and (b) without the outer membrane. Reprinted by permission from John Wiley & Sons from Mannella et al. (2001).Inner membrane cristae are often depicted as baffles emanating from the boundary domain. However, electron tomography of mitochondria from several species, including yeast, shows that cristae actually emanate from the boundary membrane as narrow tubular structures at sites termed “crista junctions” and expand as they project into the matrix (Frey and Mannella 2000; Mannella et al. 2001) (Figure 1B). It seems clear that the boundary and cristae domains of the inner membrane have distinct compositions with respect to the respiratory complexes that are embedded preferentially in the cristae membrane domains, as well as other components (Vogel et al. 2006; Wurm and Jakobs 2006; Rabl et al. 2009; Suppanz et al. 2009; Zick et al. 2009; Davies et al. 2011).The outer and inner boundary membranes are connected at multiple contact sites, at least some of which are involved in protein translocation and may be transient (Pon and Schatz 1991). In addition, there appear to be firm contact sites, not directly involved with protein translocation, preferentially colocalized with crista junctions (Harner et al. 2011a).Overall, there appear to be ∼1000 distinct proteins in yeast mitochondria (Premsler et al. 2009). One series of proteomic studies on highly purified organelles identified 851 proteins thought to represent 85% of the total number of species (Sickmann et al. 2003; Reinders et al. 2006; Zahedi et al. 2006). Another study identified an additional 209 candidates (Prokisch et al. 2004). A computationally driven search for candidates involved in yeast mitochondrial function, coupled with experiments to assay respiratory function and maintenance of mitochondrial DNA (mtDNA), identified 109 novel candidates, although many of these may not be mitochondrial per se (Hess et al. 2009). Taking the boundary and cristae domains together, the inner membrane is the most protein-rich mitochondrial compartment, followed by the matrix (Daum et al. 1982).Only eight of the yeast mitochondrial proteins detected in proteomic studies are encoded by mtDNA and synthesized within the organelle. They are hydrophobic subunits of respiratory complexes III (bc₁ complex or ubiquinol-cytochrome c reductase), IV (cytochrome c oxidase), and V (ATP synthase), as well as a hydrophilic mitochondrial small subunit ribosomal protein. The remaining ∼99% of yeast mitochondrial proteins are encoded by nuclear genes, synthesized in cytoplasmic ribosomes, and imported into the organelle.An overview of known nuclearly encoded mitochondrial protein functions (Figure 2) reveals that ∼25% of them are involved directly in genome maintenance and expression of the eight major mitochondrial genes (Schmidt et al. 2010). The functions of ∼20% of the proteins are not known. Fifteen percent are involved in the well-known processes of energy metabolism. Protein translocation, folding, and turnover functions occupy ∼10% of mitochondrial proteins.Open in a separate windowFigure 2 Classification of identified mitochondrial proteins according to function. Reprinted by permission from Nature Publishing Group from Schmidt et al. (2010).The following discussion reviews our understanding of the biogenesis of mitochondria starting on the outside, the cytoplasm, and working inward through the mitochondrial compartments.     

蜂毒素分子的改造及其基因在毕赤酵母中的表达

为获得保留有抗菌活性而降低溶血作用的蜂毒素,对蜂毒素的分子结构进行了改造。将第5位的Val变为Arg,第15位Ala变为Arg,删除了第16位的Leu。用PCR技术获得了改造后的蜂毒素基因,将其克隆入酵母表达载体pPICZa-A,获得重组表达质粒pPICZa-A-MEA。该质粒转化毕赤酵母菌GS115,甲醇诱导下表达,发酵上清液经抑菌活性、溶血活性测定及亲和层析纯化,结果表明,蜂毒素基因成功地在毕赤酵母中表达,经改造后表达的蜂毒素保留了抗菌活性且溶血活性显著降低,经纯化后用Bradford法测定表达蜂毒素的含量约为0.29mg／ml。     

Expression,purification, and characterization of equine lactoferrin in Pichia pastoris

Lactoferrin is an 80kDa iron-binding glycoprotein. It is secreted by exocrine glands. Many functions such as iron sequestering, anti-bacterial activity, regulation of gene expression, and immunomodulation are attributed to it. In the present study, we report the production of recombinant equine lactoferrin (ELF) in the methylotropic yeast Pichia pastoris using pPIC9K vector. The recombinant protein was purified by one-step affinity chromatography using heparin-Sepharose column. The purified protein has a molecular weight of 80kDa and reacted with antibody raised against the native equine lactoferrin. Its N-terminal sequence was identical to that of the native ELF. The iron-binding behavior and circular dichroism studies of the purified protein indicate that it has folded properly. The recombinant protein appears to be hyperglycosylated by the host strain, GS115. This is the first heterologous expression of equine lactoferrin and also the first report of intact lactoferrin expression using P. pastoris system. An yield of 40mg/l obtained in shake-flask cultures with this system, which is higher than the reported values for other systems.     

Recombinant protein expression in Pichia pastoris

The methylotrophic yeast Pichia pastoris is now one of the standard tools used in molecular biology for the generation of recombinant protein. P. pastoris has demonstrated its most powerful success as a large-scale (fermentation) recombinant protein production tool. What began more than 20 years ago as a program to convert abundant methanol to a protein source for animal feed has been developed into what is today two important biological tools: a model eukaryote used in cell biology research and a recombinant protein production system. To date well over 200 heterologous proteins have been expressed in P. pastoris. Significant advances in the development of new strains and vectors, improved techniques, and the commercial availability of these tools coupled with a better understanding of the biology of Pichia species have led to this microbe's value and power in commercial and research labs alike.     

巴斯德毕赤酵母表达系统研究进展

巴斯德毕赤酵母表达系统现在已经发展成为一种高效的外源蛋白基因优秀表达系统,该系统具有高表达、高稳定、高分泌、容易放大和成本低等优点,目前已有多种外源蛋白基因在该系统中实现高效表达,对巴斯德毕赤酵母表达系统的进一步研究将会促进其大规模的工业化应用。     

Bax-induced cell death in Pichia pastoris

Murine Bax was expressed in the methylotrophic yeast, Pichia pastoris, using the alcohol oxidase 1 (AOX1) or alcohol oxidase 2 (AOX2) promoter and the AOX1 terminator. Upon induction in methanol medium, transformants containing BAX cDNA under control of the strong AOX1 promoter showed complete growth inhibition and extensive cell death. Except for chromatin condensation, morphological changes typical of apoptosis in mammalian cells could not be observed, indicating that the cell death machinery in P. pastoris is marked different from the endogenous cell death program of higher eukaryotes. Staining of Bax-induced cells with propidium iodide indicated that cell death was not correlated with necrosis. Electron microscopic examination revealed no striking differences in cell morphology, but showed few cells with an enlarged vacuole containing spherical bodies, which suggests autophagic cell death.     

植酸酶基因的多点突变及在毕赤酵母中的高效表达

根据毕赤酵母基因的密码子选择偏爱性,不改变其编码氨基酸序列,对来源于黑曲霉N25植酸酶phyA基因,进行了突变,构建了含有正确突变的酵母表达载体pPIC9k-phyAm-4,电击转化毕赤酵母,获得优化了密码子的重组酵母转化子。经PCR鉴定表明,植酸酶基因已整合到酵母基因组中; 表达产物的SDS-PAGE分析表明,酶蛋白分子大小为70.15KD。Southern blotting结果表明,phyA基因整合到酵母染色体DNA中;转化子酶活测定结果表明,经密码子优化的重组酵母PP-NPm-4-2酶活可达136900U/ml,比Arg没有优化的PP-NPm-8 (47600 Uoml-1)酶活高约2.8倍。     

Expression, purification, and activity identification of Alfimeprase in Pichia pastoris

Alfimeprase (ALF) is a truncated form of non-hemorrhagic zinc metalloproteinase fibrolase. In order to achieve a high level secretion and full activity expression of ALF, the Pichia pastoris (P. pastoris) expression system was used. ALF coding sequence fused with a 6 *histidine tag and an enterokinase recognition site at the N-terminus was cloned into the expression vector pPIC9K and then expressed in P. pastoris strains of GS115 and KM71 by methanol induction. SDS-PAGE and Western blotting analysis showed that the secreted recombinant ALF (rALF) had a molecular weight of 23.8 kDa and was bound specifically to mouse anti-His. tag monoclonal antibody. Under the optimized culture parameters of pH value, initial A(600) value, methanol daily addition concentration and induction time length, the production of rALF reached up to 510 mg/L and 465 mg/L of the GS115 and KM71 transformants, respectively. It also appeared that KM71 was producing a more pure protein than GS115 while GS115 was producing more rALF per unit volume. Through one-step affinity chromatography, the purity of rALF was as high as 96%. The fibrinolytic activity of rALF revealed by the modified fibrin plate method indicated that the protein was efficiently secreted and functionally expressed, and thrombolysis of rALF was demonstrated to be dose-dependent and time-relative. The improved expression system will facilitate further studies and industrial production of ALF.     

Cloning,Heterologous Expression,Purification and Characterization of M12 Mutant of Aspergillus niger Glucose Oxidase in Yeast Pichia pastoris KM71H

Aspergillus niger glucose oxidase (GOx) genes for wild-type (GenBank accession no. X16061, swiss-Prot; P13006) and M12 mutant (N2Y, K13E, T30 V, I94 V, K152R) were cloned into pPICZαA vector for expression in Pichia pastoris KM71H strain. The highest expression level of 17.5 U/mL of fermentation media was obtained in 0.5 % (v/v) methanol after 9 days of fermentation. The recombinant GOx was purified by cross-flow ultrafiltration using membranes of 30 kDa molecular cutoff and DEAE ion-exchange chromatography at pH 6.0. Purified wt GOx had k _cat of 189.4 s^?1 and K _m of 28.26 mM while M12 GOx had k _cat of 352.0 s^?1 and K _m of 13.33 mM for glucose at pH 5.5. Specificity constants k _cat/K _m of wt (6.70 mM^?1 s^?1) and M12 GOx (26.7 mM^?1 s^?1) expressed in P. pastoris KM71H were around three times higher than for the same enzymes previously expressed in Saccharomyces cerevisiae InvSc1 strain. The pH optimum and sugar specificity of M12 mutant of GOx remained similar to the wild-type form of the enzyme, while thermostability was slightly decreased. M12 GOx expressed in P. pastoris showed three times higher activity compared to the wt GOx toward redox mediators like N,N-dimethyl-nitroso-aniline used for glucose strips manufacturing. M12 mutant of GOx produced in P. pastoris KM71H could be useful for manufacturing of glucose biosensors and biofuel cells.     

Production of protein-based polymers in Pichia pastoris

Materials science and genetic engineering have joined forces over the last three decades in the development of so-called protein-based polymers. These are proteins, typically with repetitive amino acid sequences, that have such physical properties that they can be used as functional materials. Well-known natural examples are collagen, silk, and elastin, but also artificial sequences have been devised. These proteins can be produced in a suitable host via recombinant DNA technology, and it is this inherent control over monomer sequence and molecular size that renders this class of polymers of particular interest to the fields of nanomaterials and biomedical research. Traditionally, Escherichia coli has been the main workhorse for the production of these polymers, but the methylotrophic yeast Pichia pastoris is finding increased use in view of the often high yields and potential bioprocessing benefits. We here provide an overview of protein-based polymers produced in P. pastoris. We summarize their physicochemical properties, briefly note possible applications, and detail their biosynthesis. Some challenges that may be faced when using P. pastoris for polymer production are identified: (i) low yields and poor process control in shake flask cultures; i.e., the need for bioreactors, (ii) proteolytic degradation, and (iii) self-assembly in vivo. Strategies to overcome these challenges are discussed, which we anticipate will be of interest also to readers involved in protein expression in P. pastoris in general.