Two pathways of sphingolipid biosynthesis are separated in the yeast Pichia pastoris.

Although the yeast Saccharomyces cerevisiae has only one sphingolipid class with a head group based on phosphoinositol, the yeast Pichia pastoris as well as many other fungi have a second class, glucosylceramide, which has a glucose head group. These two sphingolipid classes are in addition distinguished by a characteristic structure of their ceramide backbones. Here, we investigate the mechanisms controlling substrate entry into the glucosylceramide branch of the pathway. By a combination of enzymatic in vitro studies and lipid analysis of genetically engineered yeast strains, we show that the ceramide synthase Bar1p occupies a key branching point in sphingolipid biosynthesis in P. pastoris. By preferring dihydroxy sphingoid bases and C(16)/C(18) acyl-coenzyme A as substrates, Bar1p produces a structurally well defined group of ceramide species, which is the exclusive precursor for glucosylceramide biosynthesis. Correlating with the absence of glucosylceramide in this yeast, a gene encoding Bar1p is missing in S. cerevisiae. We could not successfully investigate the second ceramide synthase in P. pastoris that is orthologous to S. cerevisiae Lag1p/Lac1p. By analyzing the ceramide and glucosylceramide species in a collection of P. pastoris knock-out strains in which individual genes encoding enzymes involved in glucosylceramide biosynthesis were systematically deleted, we show that the ceramide species produced by Bar1p have to be modified by two additional enzymes, sphingolipid Δ4-desaturase and fatty acid α-hydroxylase, before the final addition of the glucose head group by the glucosylceramide synthase. Together, this set of four enzymes specifically defines the pathway leading to glucosylceramide biosynthesis.

Dynamics of the peroxisomal import cycle of PpPex20p: ubiquitin-dependent localization and regulation.

We characterize the peroxin PpPex20p from Pichia pastoris and show its requirement for translocation of PTS2 cargoes into peroxisomes. PpPex20p docks at the peroxisomal membrane and translocates into peroxisomes. Its peroxisomal localization requires the docking peroxin Pex14p but not the peroxins Pex2p, Pex10p, and Pex12p, whose absence causes peroxisomal accumulation of Pex20p. Similarities between Pex5p and Pex20p were noted in their protein interactions and dynamics during import, and both contain a conserved NH2-terminal domain. In the absence of the E2-like Pex4p or the AAA proteins Pex1p and Pex6p, Pex20p is degraded via polyubiquitylation of residue K19, and the K19R mutation causes accumulation of Pex20p in peroxisome remnants. Finally, either interference with K48-branched polyubiquitylation or removal of the conserved NH2-terminal domain causes accumulation of Pex20p in peroxisomes, mimicking a defect in its recycling to the cytosol. Our data are consistent with a model in which Pex20p enters peroxisomes and recycles back to the cytosol in an ubiquitin-dependent manner.

Catabolite repression of Aox in Pichia pastoris is dependent on hexose transporter PpHxt1 and pexophagy.

In this work, the identification and characterization of two hexose transporter homologs in the methylotrophic yeast Pichia pastoris, P. pastoris Hxt1 (PpHxt1) and PpHxt2, are described. When expressed in a Saccharomyces cerevisiae hxt-null mutant strain that is unable to take up monosaccharides, either protein restored growth on glucose or fructose. Both PpHXT genes are transcriptionally regulated by glucose. Transcript levels of PpHXT1 are induced by high levels of glucose, whereas transcript levels of PpHXT2 are relatively lower and are fully induced by low levels of glucose. In addition, PpHxt2 plays an important role in glycolysis-dependent fermentative growth, since PpHxt2 is essential for growth on glucose or fructose when respiration is inhibited. Notably, we firstly found that the deletion of PpHXT1, but not PpHXT2, leads to the induced expression of the alcohol oxidase I gene (AOX1) in response to glucose or fructose. We also elucidated that a sharp dropping of the sugar-induced expression level of Aox at a later growth phase is caused mainly by pexophagy, a degradation pathway in methylotrophic yeast. The sugar-inducible AOX1 promoter in an Deltahxt1 strain may be promising as a host for the expression of heterologous proteins. The functional analysis of these two hexose transporters is the first step in elucidating the mechanisms of sugar metabolism and catabolite repression in P. pastoris.

Promoter library designed for fine-tuned gene expression in Pichia pastoris.

Although frequently used as protein production host, there is only a limited set of promoters available to drive the expression of recombinant proteins in Pichia pastoris. Fine-tuning of gene expression is often needed to maximize product yield and quality. However, for efficient knowledge-based engineering, a better understanding of promoter function is indispensable. Consequently, we created a promoter library by deletion and duplication of putative transcription factor-binding sites within the AOX1 promoter (P(AOX1)) sequence. This first library initially spanned an activity range between approximately 6% and >160% of the wild-type promoter activity. After characterization of the promoter library employing a green fluorescent protein (GFP) variant, the new regulatory toolbox was successfully utilized in a 'real case', i.e. the expression of industrial enzymes. Characterization of the library under repressing, derepressing and inducing conditions displayed at least 12 cis-acting elements involved in P(AOX1)-driven high-level expression. Based on this deletion analysis, novel short artificial promoter variants were constructed by combining cis-acting elements with basal promoter. In addition to improving yields and quality of heterologous protein production, the new P(AOX1) synthetic promoter library constitutes a basic toolbox to fine-tune gene expression in metabolic engineering and sequential induction of protein expression in synthetic biology.

Identification of phosphatidylserine decarboxylases 1 and 2 from Pichia pastoris.

Genetic manipulation of lipid biosynthetic enzymes allows modification of cellular membranes. We made use of this strategy and constructed mutants in phospholipid metabolism of Pichia pastoris, which is widely used in biotechnology for expression of heterologous proteins. Here we describe identification of two P. pastoris phosphatidylserine decarboxylases (PSDs) encoded by genes homologous to PSD1 and PSD2 from Saccharomyces cerevisiae. Using P. pastoris psd1Delta and psd2Delta mutants we investigated the contribution of the respective gene products to phosphatidylethanolamine synthesis, membrane composition and cell growth. Deletion of PSD1 caused loss of PSD activity in mitochondria, a severe growth defect on minimal media and depletion of cellular and mitochondrial phosphatidylethanolamine levels. This defect could not be compensated by Psd2p, but by supplementation with ethanolamine, which is the substrate for the cytidine diphosphate (CDP)-ethanolamine pathway, the third route of phosphatidylethanolamine synthesis in yeast. Fatty acid analysis showed selectivity of both Psd1p and Psd2p in vivo for the synthesis of unsaturated phosphatidylethanolamine species. Phosphatidylethanolamine species containing palmitic acid (16:0), however, were preferentially assembled into mitochondria. In summary, this study provides first insight into membrane manipulation of P. pastoris, which may serve as a useful method to modify cell biological properties of this microorganism for biotechnological purposes.

Mxr1p, a key regulator of the methanol utilization pathway and peroxisomal genes in Pichia pastoris.

Growth of the yeast Pichia pastoris on methanol induces the expression of genes whose products are required for its metabolism. Three of the methanol pathway enzymes are located in an organelle called the peroxisome. As a result, both methanol pathway enzymes and proteins involved in peroxisome biogenesis (PEX proteins) are induced in response to this substrate. The most highly regulated of these genes is AOX1, which encodes alcohol oxidase, the first enzyme of the methanol pathway, and a peroxisomal enzyme. To elucidate the molecular mechanisms responsible for methanol regulation, we identify genes required for the expression of AOX1. Mutations in one gene, named MXR1 (methanol expression regulator 1), result in strains that are unable to (i) grow on the peroxisomal substrates methanol and oleic acid, (ii) induce the transcription of AOX1 and other methanol pathway and PEX genes, and (iii) form normal-appearing peroxisomes in response to methanol. MXR1 encodes a large protein with a zinc finger DNA-binding domain near its N terminus that has similarity to Saccharomyces cerevisiae Adr1p. In addition, Mxr1p is localized to the nucleus in cells grown on methanol or other gluconeogenic substrates. Finally, Mxr1p specifically binds to sequences upstream of AOX1. We conclude that Mxr1p is a transcription factor that is necessary for the activation of many genes in response to methanol. We propose that MXR1 is the P. pastoris homologue of S. cerevisiae ADR1 but that it has gained new functions and lost others through evolution as a result of changes in the spectrum of genes that it controls.

Introduction: distinctions between Pichia pastoris and other expression systems.

The construction of Pichia pastoris expression strains and the general growth and manipulation of this yeast expression system are in many ways similar to those of bacterial expression systems, particularly Escherichia coli. Because of this, it is typically easy for researches experienced with bacterial systems to make the jump to this eukaryotic system. However, because the system is similar, users can be falsely fooled into assuming that the system is completely bacterial-like and may waste time and effort performing experiments that are unlikely to yield the desired results with this yeast. To aid in preventing P. pastoris users from falling into one or more or these traps, this introduction focuses directly on key ways that the P. pastoris expression system is different.

DNA-mediated transformation.

Several methods for DNA-mediated transformation of Pichia pastoris have been developed which vary in type of DNA that is transformable (e.g., linear versus circular) efficiency, cost, and labor and each is described in detail. As in Saccharomyces cerevisiae, gene replacement (also known as gene knock-out) methods provide a unique tool to investigate the function of specific P. pastoris genes. After construction, the function of the deleted gene is investigated from the phenotype of the mutant strain. In S. cerevisiae, an efficient polymerase chain reaction (PCR)-based method for the construction of gene replacement fragments has been developed. Modifications of this PCR method have been developed to adapt this approach to P. pastoris.

Classical genetics.

A significant advantage of Pichia pastoris as an experimental system is the ability to readily bring to bear both classical and molecular genetic approaches to a research problem. Although the advent of yeast molecular genetics has introduced new and exciting capabilities, classical genetics remains the approach of choice in many instances. These include the generation of mutations in previously unidentified genes (mutagenesis), the removal of unwanted secondary mutations (backcrossing), the assignment of mutations to specific genes (complementation analysis), and the construction of strains with new combinations of mutant alleles. This chapter describes these genetic manipulation methods for P. pastoris. In addition, certain yeast genes are essential for survival of the organism. However, determining whether a newly cloned gene is essential or not can be difficult with P. pastoris. In this chapter, we also describe a series of experiments to investigate the potential essential nature of a cloned gene in this yeast.

Combined effect of the methanol utilization (Mut) phenotype and gene dosage on recombinant protein production in Pichia pastoris fed-batch cultures.

An important number of heterologous proteins have been produced in the methylotrophic yeast Pichia pastoris using the alcohol oxidase promoter. Two factors that drastically influence protein production and cultivation process development in this system are gene dosage and methanol assimilation capacity of the host strain (Mut phenotype). Using a battery of four strains which secrete a Rhizopus oryzae lipase (ROL), the combined effects of gene dosage and Mut phenotype on recombinant protein production in Pichia pastoris was studied in fed-batch cultures. Regarding the effect of phenotype, the specific productivity and the Y(P/X) were 1.29- and 2.34-fold higher for Mut(s)ROL single copy strain than for Mut+ROL single copy strain. On the contrary, the productivity of Mut+ROL single copy strain was 1.34-fold higher than Mut(s)ROL single copy strain. An increase in ROL gene dosage seems to negatively affect cell's performance in bioreactor cultures, particularly in Mut(s) strains. Overall, the Mut(s) strain may be still advantageous to use because it allows for easier process control strategies.

Production of recombinant proteins in fermenter cultures of the yeast Pichia pastoris.

The Pichia pastoris expression system offers economy, ease of manipulation, the ability to perform complex post-translational modifications, and high expression levels. Using this system, recent advances have been made in the quality of recombinant proteins in fermenter culture and in the quality of the protein product, namely improved secretion signals and glycosylation patterns.

The Pichia pastoris formaldehyde dehydrogenase gene (FLD1) as a marker for selection of multicopy expression strains of P. pastoris.

The methylotrophic yeast Pichia pastoris is a popular host for the production of a variety of recombinant proteins. We describe the use of a novel selectable marker, the P. pastoris formaldehyde dehydrogenase gene (FLD1) for DNA-mediated transformations of this yeast. The product of the FLD1 gene (Fld1p) is required for growth of P. pastoris on methanol as a carbon source and methylamine as a nitrogen source. In both these C(1) pathways, Fld1p oxidizes formaldehyde to formate, which is subsequently further oxidized by a second dehydrogenase to carbon dioxide. We show that the FLD1 gene can be used as a marker in transformations of a P. pastoris fld1 host by selection on plates containing methylamine. Furthermore, we demonstrate that populations of these transformants can be enriched for strains that receive multiple copies of an FLD1-based vector by their increased resistance to formaldehyde. We provide the FLD1 selection system in a set of P. pastoris expression vectors that are composed almost entirely of P. pastoris DNA (except for the recombinant gene) and are devoid of antibiotic resistance genes or other sequences of bacterial origin. The vectors are useful for the selection of strains containing multiple copies of an expression vector and may be ideal for certain large-scale recombinant protein production processes where strains containing non-P. pastoris DNA sequences, particularly bacterial antibiotic resistance genes and replication origins, are considered a potential biological hazard to be avoided.

Towards improved membrane protein production in Pichia pastoris: general and specific transcriptional response to membrane protein overexpression.

Membrane proteins are the largest group of human drug targets and are also used as biocatalysts. However, due to their complexity, efficient expression remains a bottleneck for high level production. In recent years, the methylotrophic yeast Pichia pastoris has emerged as one of the most commonly used expression systems for membrane protein production. Here, we have analysed the transcriptomes of P. pastoris strains producing different classes of membrane proteins (mitochondrial, ER/Golgi and plasma membrane localized) to understand the cellular response and to identify targets to engineer P. pastoris towards an improved chassis for membrane protein production. Microarray experiments revealed varying transcriptional responses depending on the enzymatic activity, subcellular localization and physiological role of the membrane proteins. While an alternative oxidase evoked primarily a response within the mitochondria, the overexpression of transporters entering the secretory pathway had a wide effect on lipid metabolism and induced the upregulation of the UPR (unfolded protein response) transcription factor Hac1p. Coexpression of P. pastoris endogenous HAC1 increased the levels of ER-resident membrane proteins 1.5- to 2.1-fold. Subsequent transcriptome analysis of HAC1 coexpression revealed an upregulation of the folding machinery correlating with an expansion of the ER membrane capacity, thus boosting membrane protein production. Hence, our study has helped to elucidate the cellular response of P. pastoris to the expression of different classes of membrane proteins and led specifically to new insights into the effect of PpHac1p on membrane proteins entering the secretory pathway.

Atg35, a micropexophagy-specific protein that regulates micropexophagic apparatus formation in Pichia pastoris.

Autophagy-related (Atg) pathways deliver cytosol and organelles to the vacuole in double-membrane vesicles called autophagosomes, which are formed at the phagophore assembly site (PAS), where most of the core Atg proteins assemble. Atg28 is a component of the core autophagic machinery partially required for all Atg pathways in Pichia pastoris. This coiled-coil protein interacts with Atg17 and is essential for micropexophagy. However, the role of Atg28 in micropexophagy was unknown. We used the yeast two-hybrid system to search for Atg28 interaction partners from P. pastoris and identified a new Atg protein, named Atg35. The atg35∆ mutant was not affected in macropexophagy, cytoplasm-to-vacuole targeting or general autophagy. However, both Atg28 and Atg35 were required for micropexophagy and for the formation of the micropexophagic apparatus (MIPA). This requirement correlated with a stronger expression of both proteins on methanol and glucose. Atg28 mediated the interaction of Atg35 with Atg17. Trafficking of overexpressed Atg17 from the peripheral ER to the nuclear envelope was required to organize a peri-nuclear structure (PNS), the site of Atg35 colocalization during micropexophagy. In summary, Atg35 is a new Atg protein that relocates to the PNS and specifically regulates MIPA formation during micropexophagy.

Expression in the yeast Pichia pastoris.

The yeast Pichia pastoris has become the premier example of yeast species used for the production of recombinant proteins. Advantages of this yeast for expression include tightly regulated and efficient promoters and a strong tendency for respiratory growth as opposed to fermentative growth. This chapter assumes the reader is proficient in molecular biology and details the more yeast specific procedures involved in utilizing the P. pastoris system for gene expression. Procedures to be found here include: strain construction by classical yeast genetics, the logic in selection of a vector and strain, preparation of electrocompetent yeast cells and transformation by electroporation, and the yeast colony western blot or Yeastern blot method for visualizing secreted proteins around yeast colonies.

Posttransformational vector amplification in the yeast Pichia pastoris.

Generating a high yield of recombinant protein is a major goal when expressing a foreign gene in any expression system. In the methylotrophic yeast Pichia pastoris, a common means of achieving this end is to select for transformants containing multiple integrated copies of an expression vector by plating them on high levels of a selectable marker drug followed by screening for rare colonies with multiple copies. We describe a more convenient method to select for such clones. Using Zeocin-resistance-based vectors, we demonstrate that strains transformed with only one or a few vector copies can, long after transformation, be subjected to further selection at high levels of drug. This resulted in the frequent selection of clones containing increased copy numbers of the vector. This posttransformational vector amplification (PTVA) process resulted in strains containing multiple head-to-tail copies of the entire vector integrated at a single locus in the genome. Of our PTVA selected clones, 40% showed a three- to fivefold increase in vector copy number. So-called 'jackpot' clones with >10 copies of the expression vector represented 5-6% of selected clones and had a proportional increase in recombinant protein.

Guidelines for the use and interpretation of assays for monitoring autophagy in higher eukaryotes.

Research in autophagy continues to accelerate,(1) and as a result many new scientists are entering the field. Accordingly, it is important to establish a standard set of criteria for monitoring macroautophagy in different organisms. Recent reviews have described the range of assays that have been used for this purpose.(2,3) There are many useful and convenient methods that can be used to monitor macroautophagy in yeast, but relatively few in other model systems, and there is much confusion regarding acceptable methods to measure macroautophagy in higher eukaryotes. A key point that needs to be emphasized is that there is a difference between measurements that monitor the numbers of autophagosomes versus those that measure flux through the autophagy pathway; thus, a block in macroautophagy that results in autophagosome accumulation needs to be differentiated from fully functional autophagy that includes delivery to, and degradation within, lysosomes (in most higher eukaryotes) or the vacuole (in plants and fungi). Here, we present a set of guidelines for the selection and interpretation of the methods that can be used by investigators who are attempting to examine macroautophagy and related processes, as well as by reviewers who need to provide realistic and reasonable critiques of papers that investigate these processes. This set of guidelines is not meant to be a formulaic set of rules, because the appropriate assays depend in part on the question being asked and the system being used. In addition, we emphasize that no individual assay is guaranteed to be the most appropriate one in every situation, and we strongly recommend the use of multiple assays to verify an autophagic response.

Cooverexpression of chaperones for enhanced secretion of a single-chain antibody fragment in Pichia pastoris.

In Pichia pastoris, secretion of the A33 single-chain antibody fragment (A33scFv) was shown to reach levels of approximately 4 g l(-1) in fermentor cultures. In this study, we investigated whether manipulating chaperone and foldase levels in P. pastoris could further increase secretion of A33scFv. Cells were engineered to cooverexpress immunoglobulin binding protein (BiP) and/or protein disulfide isomerase (PDI) with A33scFv during growth in methanol as the sole carbon and energy source. Cooverexpression of BiP resulted in increased secretion levels of A33scFv by approximately threefold. In contrast, cooverexpression of PDI had no apparent effect on secretion of A33scFv. In cells cooverexpressing BiP and PDI, A33scFv secretion did not increase and protein levels remained the same as the control strain. We believe that secretion of A33scFv is increased by cooverexpression of BiP as a result of an increase in folding capacity inside the endoplasmic reticulum (ER). In addition, lack of increased single-chain secretion when PDI is coexpressed was unexpected due to the presence of disulfide bonds in A33scFv. We also show that during PDI cooverexpression with the single-chain there is a sixfold increase in BiP levels, indicating that the former is possibly inducing an unfolded protein response due to excess chaperone and recombinant protein in the ER.

Identification of fungal sphingolipid C9-methyltransferases by phylogenetic profiling.

Fungal glucosylceramides play an important role in plant-pathogen interactions enabling plants to recognize the fungal attack and initiate specific defense responses. A prime structural feature distinguishing fungal glucosylceramides from those of plants and animals is a methyl group at the C9-position of the sphingoid base, the biosynthesis of which has never been investigated. Using information on the presence or absence of C9-methylated glucosylceramides in different fungal species, we developed a bioinformatics strategy to identify the gene responsible for the biosynthesis of this C9-methyl group. This phylogenetic profiling allowed the selection of a single candidate out of 24-71 methyltransferase sequences present in each of the fungal species with C9-methylated glucosylceramides. A Pichia pastoris knock-out strain lacking the candidate sphingolipid C9-methyltransferase was generated, and indeed, this strain contained only non-methylated glucosylceramides. In a complementary approach, a Saccharomyces cerevisiae strain was engineered to produce glucosylceramides suitable as a substrate for C9-methylation. C9-methylated sphingolipids were detected in this strain expressing the candidate from P. pastoris, demonstrating its function as a sphingolipid C9-methyltransferase. The enzyme belongs to the superfamily of S-adenosylmethionine-(SAM)-dependent methyltransferases and shows highest sequence similarity to plant and bacterial cyclopropane fatty acid synthases. An in vitro assay showed that sphingolipid C9-methylation is membrane-bound and requires SAM and Delta4,8-desaturated ceramide as substrates.