Juergen H Nett

Publications (14)120.14 Total impact

• Article: A color-based stable multi-copy integrant selection system for Pichia pastoris using the attenuated ADE1 and ADE2 genes as auxotrophic markers.

  Min Du, Michael B Battles, Juergen H Nett
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  ABSTRACT: The methylotropic yeast Pichia pastoris has been used for more than two decades to successfully produce a large number of recombinant proteins. Currently, a wide variety of auxotrophic and drug based selection markers are employed to screen for clones expressing the protein of interest. For most proteins an increased copy number of the integrated plasmid results in higher levels of expression, but these multi-copy integrants can be unstable due to the propensity of P. pastoris for homologous recombination. Here we describe a multi-copy selection system based on ade1 and ade2 auxotrophic parent strains and the respective attenuated markers with truncated promoter regions. We show that for all four proteins we tested, the use of the attenuated markers leads to increased protein expression when compared with selection based on the full strength markers. The fact that the adenine auxotrophic strains grow more slowly than the complemented counterparts essentially ensures the stability of multi-copy integration. At the same time, the accumulation of a red dye in the auxotrophic strains also provides an easy, color-based selection for transformants with multiple copies.
  Bioengineered bugs 01/2012; 3(1):32-7.
• Article: Optimization of erythropoietin production with controlled glycosylation-PEGylated erythropoietin produced in glycoengineered Pichia pastoris.

  Juergen H Nett, Sujatha Gomathinayagam, Stephen R Hamilton, Bing Gong, Robert C Davidson, Min Du, Daniel Hopkins, Teresa Mitchell, Muralidhar R Mallem, Adam Nylen, [......], Denise Visco, Gail Forrest, Julie DeMartino, Thomas Linden, Thomas I Potgieter, Stefan Wildt, Terrance A Stadheim, Marc d'Anjou, Huijuan Li, Natarajan Sethuraman
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  ABSTRACT: Pichia pastoris is a methylotropic yeast that has gained great importance as an organism for protein expression in recent years. Here, we report the expression of recombinant human erythropoietin (rhEPO) in glycoengineered P. pastoris. We show that glycosylation fidelity is maintained in fermentation volumes spanning six orders of magnitude and that the protein can be purified to high homogeneity. In order to increase the half-life of rhEPO, the purified protein was coupled to polyethylene glycol (PEG) and then compared to the currently marketed erythropoiesis stimulating agent, Aranesp(®) (darbepoetin). In in vitro cell proliferation assays the PEGylated protein was slightly, and the non-PEGylated protein was significantly more active than comparator. Pharmacodynamics as well as pharmacokinetic activity of PEGylated rhEPO in animals was comparable to that of Aranesp(®). Taken together, our results show that glycoengineered P. pastoris is a suitable production host for rhEPO, yielding an active biologic that is comparable to those produced in current mammalian host systems.
  Journal of biotechnology 11/2011; 157(1):198-206. · 2.88 Impact Factor
• Article: Elimination of β-mannose glycan structures in Pichia pastoris.

  Daniel Hopkins, Sujatha Gomathinayagam, Alissa M Rittenhour, Min Du, Erik Hoyt, Khanita Karaveg, Teresa Mitchell, Juergen H Nett, Nathan J Sharkey, Terrance A Stadheim, Huijuan Li, Stephen R Hamilton
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  ABSTRACT: The methylotrophic yeast, Pichia pastoris, is an important organism used for the production of therapeutic proteins. However, the presence of fungal-like glycans, such as those containing β-mannose (Man) linkages, can elicit an immune response or bind to Man receptors, thus reducing their efficacy. Recent studies have confirmed that P. pastoris has four genes from the β-mannosyl transferase (BMT) family and that Bmt2p is responsible for the majority of β-Man linkages on glycans. While expressing recombinant human erythropoietin (rhEPO) in a developmental glycoengineered strain devoid of BMT2 gene expression, cross-reactivity was observed with an antibody raised against host cell antigens. Treatment of the rhEPO with protein N-glycosidase F eliminated cross-reactivity, indicating that the antigen was associated with the glycan. Thorough analysis of the glycan profile of rhEPO demonstrated the presence of low amounts of α-1,2-mannosidase resistant high-Man glycoforms. In an attempt to eliminate the α-mannosidase resistant glycoforms, we used a systemic approach to genetically knock-out the remaining members of the BMT family culminating in a quadruple bmt2,4,1,3 knock-out strain. Data presented here conclude that the additive elimination of Bmt2p, Bmt3p and Bmt1p activities are required for total abolition of β-Man-associated glycans and their related antigenicity. Taken together, the elimination of β-Man containing glycoforms represents an important step forward for the Pichia production platform as a suitable system for the production of therapeutic glycoproteins.
  Glycobiology 08/2011; 21(12):1616-26. · 3.58 Impact Factor
• Article: A combinatorial genetic library approach to target heterologous glycosylation enzymes to the endoplasmic reticulum or the Golgi apparatus of Pichia pastoris.

  Juergen H Nett, Terrance A Stadheim, Huijuan Li, Piotr Bobrowicz, Stephen R Hamilton, Robert C Davidson, Byung-Kwon Choi, Teresa Mitchell, Beata Bobrowicz, Alissa Rittenhour, Stefan Wildt, Tillman U Gerngross
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  ABSTRACT: To humanize the glycosylation pathway in the yeast Pichia pastoris, we developed several combinatorial genetic libraries and used them to properly localize active eukaryotic mannosidases and sugar transferases. Here we report the details of the fusion of up to 66 N-terminal targeting sequences of fungal type II membrane proteins to 33 catalytic domains of heterologous glycosylation enzymes. We show that while it is difficult to predict which leader/catalytic domain will result in the desired activity, analysis of the fusion protein libraries allows for the selection of the leader/catalytic domain combinations that function properly. This combinatorial approach, together with a high-throughput screening protocol, has allowed us to humanize the yeast glycosylation pathway to secrete human glycoprotein with complex N-glycosylation.
  Yeast 03/2011; 28(3):237-52. · 1.89 Impact Factor
• Article: High-throughput screening and selection of yeast cell lines expressing monoclonal antibodies.

  Gavin C Barnard, Angela R Kull, Nathan S Sharkey, Seemab S Shaikh, Alissa M Rittenhour, Irina Burnina, Youwei Jiang, Fang Li, Heather Lynaugh, Teresa Mitchell, Juergen H Nett, Adam Nylen, Thomas I Potgieter, Bianka Prinz, Sandra E Rios, Dongxing Zha, Natarajan Sethuraman, Terrance A Stadheim, Piotr Bobrowicz
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  ABSTRACT: The methylotrophic yeast Pichia pastoris has recently been engineered to express therapeutic glycoproteins with uniform human N-glycans at high titers. In contrast to the current art where producing therapeutic proteins in mammalian cell lines yields a final product with heterogeneous N-glycans, proteins expressed in glycoengineered P. pastoris can be designed to carry a specific, preselected glycoform. However, significant variability exists in fermentation performance between genotypically similar clones with respect to cell fitness, secreted protein titer, and glycan homogeneity. Here, we describe a novel, multidimensional screening process that combines high and medium throughput tools to identify cell lines producing monoclonal antibodies (mAbs). These cell lines must satisfy multiple selection criteria (high titer, uniform N-glycans and cell robustness) and be compatible with our large-scale production platform process. Using this selection process, we were able to isolate a mAb-expressing strain yielding a titer (after protein A purification) in excess of 1 g/l in 0.5-l bioreactors.
  Journal of Industrial Microbiology 09/2010; 37(9):961-71. · 1.80 Impact Factor
• Article: N-glycan modification in Aspergillus species.

  Elke Kainz, Andreas Gallmetzer, Christian Hatzl, Juergen H Nett, Huijuan Li, Thorsten Schinko, Robert Pachlinger, Harald Berger, Yazmid Reyes-Dominguez, Andreas Bernreiter, Tillmann Gerngross, Stefan Wildt, Joseph Strauss
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  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 alpha-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.
  Applied and environmental microbiology 03/2008; 74(4):1076-86. · 3.69 Impact Factor
• Article: Humanization of yeast to produce complex terminally sialylated glycoproteins.

  Stephen R Hamilton, Robert C Davidson, Natarajan Sethuraman, Juergen H Nett, Youwei Jiang, Sandra Rios, Piotr Bobrowicz, Terrance A Stadheim, Huijuan Li, Byung-Kwon Choi, Daniel Hopkins, Harry Wischnewski, Jessica Roser, Teresa Mitchell, Rendall R Strawbridge, Jack Hoopes, Stefan Wildt, Tillman U Gerngross
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  ABSTRACT: 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.
  Science 10/2006; 313(5792):1441-3. · 31.20 Impact Factor
• Article: Optimization of humanized IgGs in glycoengineered Pichia pastoris.

  Huijuan Li, Natarajan Sethuraman, Terrance A Stadheim, Dongxing Zha, Bianka Prinz, Nicole Ballew, Piotr Bobrowicz, Byung-Kwon Choi, W James Cook, Michael Cukan, [......], Stephen R Hamilton, Jack P Hoopes, Youwei Jiang, Nam Kim, Renee Mansfield, Juergen H Nett, Sandra Rios, Rendall Strawbridge, Stefan Wildt, Tillman U Gerngross
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  ABSTRACT: 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.
  Nature Biotechnology 03/2006; 24(2):210-5. · 23.27 Impact Factor
• Article: Cloning and disruption of the Pichia pastoris ARG1, ARG2, ARG3, HIS1, HIS2, HIS5, HIS6 genes and their use as auxotrophic markers.

  Juergen H Nett, Nikolai Hodel, Sebastian Rausch, Stefan Wildt
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  ABSTRACT: 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.
  Yeast 04/2005; 22(4):295-304. · 1.89 Impact Factor
• Article: Engineering of an artificial glycosylation pathway blocked in core oligosaccharide assembly in the yeast Pichia pastoris: production of complex humanized glycoproteins with terminal galactose.

  Piotr Bobrowicz, Robert C Davidson, Huijuan Li, Thomas I Potgieter, Juergen H Nett, Stephen R Hamilton, Terrance A Stadheim, Robert G Miele, Beata Bobrowicz, Teresa Mitchell, Sebastian Rausch, Eduard Renfer, Stefan Wildt
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  ABSTRACT: A significant percentage of eukaryotic proteins contain posttranslational modifications, including glycosylation, which are required for biological function. However, the understanding of the structure-function relationships of N-glycans has lagged significantly due to the microheterogeneity of glycosylation in mammalian produced proteins. Recently we reported on the cellular engineering of yeast to replicate human N-glycosylation for the production of glycoproteins. Here we report the engineering of an artificial glycosylation pathway in Pichia pastoris blocked in dolichol oligosaccharide assembly. The PpALG3 gene encoding Dol-P-Man:Man(5)GlcNAc(2)-PP-Dol mannosyltransferase was deleted in a strain that was previously engineered to produce hybrid GlcNAcMan(5)GlcNAc(2) human N-glycans. Employing this approach, combined with the use of combinatorial genetic libraries, we engineered P. pastoris strains that synthesize complex GlcNAc(2)Man(3)GlcNAc(2) N-glycans with striking homogeneity. Furthermore, through expression of a Golgi-localized fusion protein comprising UDP-glucose 4-epimerase and beta-1,4-galactosyl transferase activities we demonstrate that this structure is a substrate for highly efficient in vivo galactose addition. Taken together, these data demonstrate that the artificial in vivo glycoengineering of yeast represents a major advance in the production of glycoproteins and will emerge as a practical tool to systematically elucidate the structure-function relationship of N-glycans.
  Glycobiology 10/2004; 14(9):757-66. · 3.58 Impact Factor
• Article: Functional analysis of the ALG3 gene encoding the Dol-P-Man: Man5GlcNAc2-PP-Dol mannosyltransferase enzyme of P. pastoris.

  Robert C Davidson, Juergen H Nett, Eduard Renfer, Huijuan Li, Terrance A Stadheim, Benton J Miller, Robert G Miele, Stephen R Hamilton, Byung-Kwon Choi, Teresa I Mitchell, Stefan Wildt
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  ABSTRACT: N-glycans are synthesized in both yeast and mammals through the ordered assembly of a lipid-linked core Glc(3)Man(9)GlcNAc(2) structure that is subsequently transferred to a nascent protein in the endoplasmic reticulum. Once folded, glycoproteins are then shuttled to the Golgi, where additional but divergent processing occurs in mammals and fungi. We cloned the Pichia pastoris homolog of the ALG3 gene, which encodes the enzyme that converts Man(5)GlcNAc(2)-Dol-PP to Man(6)GlcNAc(2)-Dol-PP. Deletion of this gene in an och1 mutant background resulted in the secretion of glycoproteins with a predicted Man(5)GlcNAc(2) structure that could be trimmed to Man(3)GlcNAc(2) by in vitro alpha-1,2-mannosidase treatment. However, several larger glycans ranging from Hex(6)GlcNAc(2) to Hex(12)GlcNAc(2) were also observed that were recalcitrant to an array of mannosidase digests. These results contrast the far simpler glycan profile found in Saccharomyces cerevisiae alg3-1 och1, indicating diverging Golgi processing in these two closely related yeasts. Finally, analysis of the P. pastoris alg3 deletion mutant in the presence and absence of the outer chain initiating Och1p alpha-1,6-mannosyltransferase activity suggests that the PpOch1p has a broader substrate specificity compared to its S. cerevisiae counterpart.
  Glycobiology 06/2004; 14(5):399-407. · 3.58 Impact Factor
• Article: Cloning and disruption of the PpURA5 gene and construction of a set of integration vectors for the stable genetic modification of Pichia pastoris.

  Juergen H Nett, Tillman U Gerngross
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  ABSTRACT: A pair of degenerate primers was used for amplification and cloning of a DNA fragment containing parts of the P. pastoris URA5 and SEC65 genes. Using additional information from a partial genomic sequence of P. pastoris, we cloned and sequenced a 1.9 kb chromosomal fragment containing the complete orotate-phosphoribosyltransferase-encoding URA5 gene. A disruption cassette was constructed by replacing a small part of the open reading frame with a kanamycin-resistance gene. The P. pastoris wild-type strain NRRL Y-11430 was transformed with the disruption cassette and an ura5 auxotrophic strain was identified. To generate marker constructs that can be reused in successive transformations of a single strain, we constructed two lacZ-PpURA3-lacZ and lacZ-PpURA5-lacZ cassettes and used them to disrupt PpOCH1. The PpURA3 and PpURA5 genes in the disruptants were then successfully recycled by selecting for resistance to 5'-fluoro-orotic acid. We also assembled a set of modular plasmids that can be used for the stable genetic modification of P. pastoris via a double cross-over event. The sequence presented here has been submitted to the EMBL data library under Accession No. AY303544.
  Yeast 12/2003; 20(15):1279-90. · 1.89 Impact Factor
• Article: Production of complex human glycoproteins in yeast.

  Stephen R Hamilton, Piotr Bobrowicz, Beata Bobrowicz, Robert C Davidson, Huijuan Li, Teresa Mitchell, Juergen H Nett, Sebastian Rausch, Terrance A Stadheim, Harry Wischnewski, Stefan Wildt, Tillman U Gerngross
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  ABSTRACT: We report the humanization of the glycosylation pathway in the yeast Pichia pastoris to secrete a human glycoprotein with uniform complex N-glycosylation. The process involved eliminating endogenous yeast glycosylation pathways, while properly localizing five active eukaryotic proteins, including mannosidases I and II, N-acetylglucosaminyl transferases I and II, and uridine 5'-diphosphate (UDP)-N-acetylglucosamine transporter. Targeted localization of the enzymes enabled the generation of a synthetic in vivo glycosylation pathway, which produced the complex human N-glycan N-acetylglucosamine2-mannose3-N-acetylglucosamine2 (GlcNAc2Man3GlcNAc2). The ability to generate human glycoproteins with homogeneous N-glycan structures in a fungal host is a step toward producing therapeutic glycoproteins and could become a tool for elucidating the structure-function relation of glycoproteins.
  Science 09/2003; 301(5637):1244-6. · 31.20 Impact Factor
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  Available from: pnas.org

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

  Byung-Kwon Choi, Piotr Bobrowicz, Robert C Davidson, Stephen R Hamilton, David H Kung, Huijuan Li, Robert G Miele, Juergen H Nett, Stefan Wildt, Tillman U Gerngross
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  ABSTRACT: 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 alpha-1,6-mannosyltransferase gene from P. pastoris, several combinatorial genetic libraries were constructed to localize active alpha-1,2-mannosidase and human beta-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 alpha-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 homogeneous 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.
  Proceedings of the National Academy of Sciences 04/2003; 100(9):5022-7. · 9.68 Impact Factor