Stefan Wildt

Humanization of Yeast to Produce Complex Terminally Sialylated Glycoproteins

Yeast is a widely used recombinant protein expression system. We expanded its utility by engineering the yeast Pichia pastoris to secrete human glycoproteins with fully complex terminally sialylated N-glycans. After the knockout of four genes to eliminate yeast-specific glycosylation, we introduced 14 heterologous genes, allowing us to replicate the sequential steps of human glycosylation. The reported cell lines produce complex glycoproteins with greater than 90% terminal sialylation. Finally, to demonstrate the utility of these yeast strains, functional recombinant erythropoietin was produced.

Optimization of humanized IgGs in glycoengineered Pichia pastoris

As the fastest growing class of therapeutic proteins, monoclonal antibodies (mAbs) represent a major potential drug class. Human antibodies are glycosylated in their native state and all clinically approved mAbs are produced by mammalian cell lines, which secrete mAbs with glycosylation structures that are similar, but not identical, to their human counterparts. Glycosylation of mAbs influences their interaction with immune effector cells that kill antibody-targeted cells. Here we demonstrate that human antibodies with specific human N-glycan structures can be produced in glycoengineered lines of the yeast Pichia pastoris and that antibody-mediated effector functions can be optimized by generating specific glycoforms. Glycoengineered P. pastoris provides a general platform for producing recombinant antibodies with human N-glycosylation.

Use of combinatorial genetic libraries to humanize N-linked glycosylation in the yeast Pichia pastoris

The secretory pathway of Pichia pastoris was genetically re-engineered to perform sequential glycosylation reactions that mimic early processing of N-glycans in humans and other higher mammals. After eliminating nonhuman glycosylation by deleting the initiating α-1,6-mannosyltransferase gene from P. pastoris, several combinatorial genetic libraries were constructed to localize active α-1,2-mannosidase and human β-1,2-N-acetylglucosaminyltransferase I (GnTI) in the secretory pathway. First, >32 N-terminal leader sequences of fungal type II membrane proteins were cloned to generate a leader library. Two additional libraries encoding catalytic domains of α-1,2-mannosidases and GnTI from mammals, insects, amphibians, worms, and fungi were cloned to generate catalytic domain libraries. In-frame fusions of the respective leader and catalytic domain libraries resulted in several hundred chimeric fusions of fungal targeting domains and catalytic domains. Although the majority of strains transformed with the mannosidase/leader library displayed only modest in vivo [i.e., low levels of mannose (Man)5-(GlcNAc)2] activity, we were able to isolate several yeast strains that produce almost homogenous N-glycans of the (Man)5-(GlcNAc)2 type. Transformation of these strains with a UDP-GlcNAc transporter and screening of a GnTI leader fusion library allowed for the isolation of strains that produce GlcNAc-(Man)5-(GlcNAc)2 in high yield. Recombinant expression of a human reporter protein in these engineered strains led to the formation of a glycoprotein with GlcNAc-(Man)5-(GlcNAc)2 as the primary N-glycan. Here we report a yeast able to synthesize hybrid glycans in high yield and open the door for engineering yeast to perform complex human-like glycosylation.

Genome-wide screening for trait conferring genes using DNA microarrays

We report a DNA microarray-based method for genome-wide monitoring of competitively grown transformants to identify genes whose overexpression confers a specific cellular phenotype. Whereas transcriptional profiling identifies differentially expressed genes that are correlated with particular aspects of the cellular phenotype, this functional genomics approach determines genes that result in a specific physiology. This parallel gene-trait mapping method consists of transforming a strain with a genomic library, enriching the cell population in transformants containing the trait conferring gene(s), and finally using DNA microarrays to simultaneously isolate and identify the enriched gene inserts. Various methods of enrichment can be used; here, genes conferring low-level antibiotic resistance were identified by growth in selective media. We demonstrated the method by transforming Escherichia coli cells with a genomic E. coli library and selecting for transformants exhibiting a growth advantage in the presence of the anti-microbial agent Pine-Sol. Genes conferring Pine-Sol tolerance (19 genes) or sensitivity (27 genes) were identified by hybridizing, on DNA microarrays containing 1,160 E. coli gene probes, extra-chromosomal DNA isolated from transformed cells grown in the presence of various levels of Pine-Sol. Results were further validated by plating and sequencing of individual colonies, and also by assessing the Pine-Sol resistance of cells transformed with enriched plasmid library or individual resistance genes identified by the microarrays. Applications of this method beyond antibiotic resistance include identification of genes resulting in resistance to chemotherapeutic agents, genes yielding resistance to toxic products (recombinant proteins, chemical feedstocks) in industrial fermentations, genes providing enhanced growth in cell culture or high cell density fermentations, genes facilitating growth on unconventional substrates, and others.

Identification of a New Family of Genes Involved in β-1,2-Mannosylation of Glycans in Pichia pastoris and Candida albicans

Structural studies of cell wall components of the pathogenic yeast Candida albicans have demonstrated the presence of β-1,2-linked oligomannosides in phosphopeptidomannan and phospholipomannan. During C. albicans infection, β-1,2-oligomannosides play an important role in host/pathogen interactions by acting as adhesins and by interfering with the host immune response. Despite the importance of β-1,2-oligomannosides, the genes responsible for their synthesis have not been identified. The main reason is that the reference species Saccharomyces cerevisiae does not synthesize β-linked mannoses. On the other hand, the presence of β-1,2-oligomannosides has been reported in the cell wall of the more genetically tractable C. albicans relative, P. pastoris. Here we present the identification, cloning, and characterization of a novel family of fungal genes involved in β-mannose transfer. Employing in silico analysis, we identified a family of four related new genes in P. pastoris and subsequently nine homologs in C. albicans. Biochemical, immunological, and structural analyses following deletion of four genes in P. pastoris and deletion of four genes acting specifically on C. albicans mannan demonstrated the involvement of these new genes in β-1,2-oligomannoside synthesis. Phenotypic characterization of the strains deleted in β-mannosyltransferase genes (BMTs) allowed us to describe the stepwise activity of Bmtps and acceptor specificity. For C. albicans, despite structural similarities between mannan and phospholipomannan, phospholipomannan β-mannosylation was not affected by any of the CaBMT1–4 deletions. Surprisingly, depletion in mannan major β-1,2-oligomannoside epitopes had little impact on cell wall surface β-1,2-oligomannoside antigenic expression.

N-Glycan Modification in Aspergillus Species

ABSTRACT The production by filamentous fungi of therapeutic glycoproteins intended for use in mammals is held back by the inherent difference in protein N-glycosylation and by the inability of the fungal cell to modify proteins with mammalian glycosylation structures. Here, we report protein N-glycan engineering in two Aspergillus species. We functionally expressed in the fungal hosts heterologous chimeric fusion proteins containing different localization peptides and catalytic domains. This strategy allowed the isolation of a strain with a functional α-1,2-mannosidase producing increased amounts of N-glycans of the Man5GlcNAc2 type. This strain was further engineered by the introduction of a functional GlcNAc transferase I construct yielding GlcNAcMan5GlcNac2 N-glycans. Additionally, we deleted algC genes coding for an enzyme involved in an early step of the fungal glycosylation pathway yielding Man3GlcNAc2 N-glycans. This modification of fungal glycosylation is a step toward the ability to produce humanized complex N-glycans on therapeutic proteins in filamentous fungi.

cobA, a red fluorescent transcriptional reporter for Escherichia coli, yeast, and mammalian cells.

We demonstrate the use of Propionibacterium freudenreichii uroporphyrinogen III methyltransferase (cobA) as a reporter of gene expression in Escherichia coli, fission yeast, and mammalian cells. Overexpression of cobA in cells resulted in bright red fluorescence that was visualized with standard fluorescence microscopy and fluorescence-activated cell sorting analysis at the single-cell level. As with green fluorescent protein (GFP), no addition of exogenous substrate was required. When expressed in Chinese hamster ovary cells from a bicistronic transcript, cobA and GFP gave rise to fluorescence signals of similar intensity. The bright red fluorescence generated by the cobA reporter promises a better signal-to-noise ratio than blue and green fluorescent reporter systems, as autofluorescence and light scattering of cells, media, and materials are reduced in the red wavelengths.

Cloning and disruption of the Pichia pastoris ARG1, ARG2, ARG3, HIS1, HIS2, HIS5, HIS6 genes and their use as auxotrophic markers.

Screening of a partial genomic database of Pichia pastoris allowed us to identify the ARG1, ARG2, ARG3, HIS1, HIS2, HIS5 and HIS6 genes, based on homology to their Saccharomyces cerevisiae counterparts. Based on the cloned sequences, a set of disruption vectors was constructed, using the previously described PpURA5‐blaster as a selectable marker, and the cloned genes were individually disrupted. All disruptants exhibited the expected auxotrophic phenotypes, with only the his2 knockouts displaying a bradytroph phenotype. To allow their use as auxotrophic markers, we amplified the open reading frames and respective promoters and terminator regions of PpARG1, PpARG2, PpARG3, PpHIS1, PpHIS2 and PpHIS5. We then designed a set of integration vectors harbouring cassettes of the ARG pathway as selectable markers, to disrupt the genes of the HIS pathway and vice versa. Employing this strategy, we devised a scheme allowing for the rapid and stable introduction of several heterologous genes into the genome of P. pastoris without the need for recyclable markers or strains with multiple auxotrophies. Furthermore, simple replica‐plating, instead of cost‐consuming and labour‐intensive colony PCR or Southern analysis, can be used to identify positive transformants, making this approach amendable for initial high‐throughput applications, which can then be followed up by a more careful analysis of the selected transformants. The sequences presented here have been submitted to the EMBL data library under Accession Nos/AY532165 (ARG1), AY532166 (ARG2), AY532167 (ARG3), AY532168 (HIS1), AY532169 (HIS2), AY532170 (HIS5), AY532171 (HIS6). Copyright