Your search keyword '"Bjørn, Sara P."' showing total 15 results

1. In vivo neutralization of coral snake venoms with an oligoclonal nanobody mixture in a murine challenge model

Author

Benard-Valle, Melisa, Wouters, Yessica, Ljungars, Anne, Nguyen, Giang Thi Tuyet, Ahmadi, Shirin, Ebersole, Tasja Wainani, Dahl, Camilla Holst, Guadarrama-Martínez, Alid, Jeppesen, Frederikke, Eriksen, Helena, Rodríguez-Barrera, Gibran, Boddum, Kim, Jenkins, Timothy Patrick, Bjørn, Sara Petersen, Schoffelen, Sanne, Voldborg, Bjørn Gunnar, Alagón, Alejandro, and Laustsen, Andreas Hougaard

Published

2024

2. CHOmics: A web-based tool for multi-omics data analysis and interactive visualization in CHO cell lines.

Author

Lin, Dongdong, Yalamanchili, Hima B, Zhang, Xinmin, Lewis, Nathan E, Alves, Christina S, Groot, Joost, Arnsdorf, Johnny, Bjørn, Sara P, Wulff, Tune, Voldborg, Bjørn G, Zhou, Yizhou, and Zhang, Baohong

Subjects

Bioinformatics, Mathematical Sciences, Biological Sciences, Information and Computing Sciences

Abstract

Chinese hamster ovary (CHO) cell lines are widely used in industry for biological drug production. During cell culture development, considerable effort is invested to understand the factors that greatly impact cell growth, specific productivity and product qualities of the biotherapeutics. While high-throughput omics approaches have been increasingly utilized to reveal cellular mechanisms associated with cell line phenotypes and guide process optimization, comprehensive omics data analysis and management have been a challenge. Here we developed CHOmics, a web-based tool for integrative analysis of CHO cell line omics data that provides an interactive visualization of omics analysis outputs and efficient data management. CHOmics has a built-in comprehensive pipeline for RNA sequencing data processing and multi-layer statistical modules to explore relevant genes or pathways. Moreover, advanced functionalities were provided to enable users to customize their analysis and visualize the output systematically and interactively. The tool was also designed with the flexibility to accommodate other types of omics data and thereby enabling multi-omics comparison and visualization at both gene and pathway levels. Collectively, CHOmics is an integrative platform for data analysis, visualization and management with expectations to promote the broader use of omics in CHO cell research.

Published

2020

3. Evolution-guided engineering of small-molecule biosensors

Author

Snoek, Tim, Chaberski, Evan K, Ambri, Francesca, Kol, Stefan, Bjørn, Sara P, Pang, Bo, Barajas, Jesus F, Welner, Ditte H, Jensen, Michael K, and Keasling, Jay D

Subjects

Biochemistry and Cell Biology, Biological Sciences, Chemical Sciences, Industrial Biotechnology, Biotechnology, Bioengineering, Generic health relevance, Biosensing Techniques, DNA, DNA-Binding Proteins, Directed Molecular Evolution, Escherichia coli, Gene Library, Genes, Reporter, Genetic Engineering, Green Fluorescent Proteins, Ligands, Models, Molecular, Mutagenesis, Protein Domains, Protein Structure, Secondary, Saccharomyces cerevisiae, Sorbic Acid, Transcription Factors, Environmental Sciences, Information and Computing Sciences, Developmental Biology, Biological sciences, Chemical sciences, Environmental sciences

Abstract

Allosteric transcription factors (aTFs) have proven widely applicable for biotechnology and synthetic biology as ligand-specific biosensors enabling real-time monitoring, selection and regulation of cellular metabolism. However, both the biosensor specificity and the correlation between ligand concentration and biosensor output signal, also known as the transfer function, often needs to be optimized before meeting application needs. Here, we present a versatile and high-throughput method to evolve prokaryotic aTF specificity and transfer functions in a eukaryote chassis, namely baker's yeast Saccharomyces cerevisiae. From a single round of mutagenesis of the effector-binding domain (EBD) coupled with various toggled selection regimes, we robustly select aTF variants of the cis,cis-muconic acid-inducible transcription factor BenM evolved for change in ligand specificity, increased dynamic output range, shifts in operational range, and a complete inversion-of-function from activation to repression. Importantly, by targeting only the EBD, the evolved biosensors display DNA-binding affinities similar to BenM, and are functional when ported back into a prokaryotic chassis. The developed platform technology thus leverages aTF evolvability for the development of new host-agnostic biosensors with user-defined small-molecule specificities and transfer functions.

Published

2020

4. Combating viral contaminants in CHO cells by engineering innate immunity.

Author

Chiang, Austin WT, Li, Shangzhong, Kellman, Benjamin P, Chattopadhyay, Gouri, Zhang, Yaqin, Kuo, Chih-Chung, Gutierrez, Jahir M, Ghazi, Faezeh, Schmeisser, Hana, Ménard, Patrice, Bjørn, Sara Petersen, Voldborg, Bjørn G, Rosenberg, Amy S, Puig, Montserrat, and Lewis, Nathan E

Abstract

Viral contamination in biopharmaceutical manufacturing can lead to shortages in the supply of critical therapeutics. To facilitate the protection of bioprocesses, we explored the basis for the susceptibility of CHO cells to RNA virus infection. Upon infection with certain ssRNA and dsRNA viruses, CHO cells fail to generate a significant interferon (IFN) response. Nonetheless, the downstream machinery for generating IFN responses and its antiviral activity is intact in these cells: treatment of cells with exogenously-added type I IFN or poly I:C prior to infection limited the cytopathic effect from Vesicular stomatitis virus (VSV), Encephalomyocarditis virus (EMCV), and Reovirus-3 virus (Reo-3) in a STAT1-dependent manner. To harness the intrinsic antiviral mechanism, we used RNA-Seq to identify two upstream repressors of STAT1: Gfi1 and Trim24. By knocking out these genes, the engineered CHO cells exhibited activation of cellular immune responses and increased resistance to the RNA viruses tested. Thus, omics-guided engineering of mammalian cell culture can be deployed to increase safety in biotherapeutic protein production among many other biomedical applications.

Published

2019

5. Independent component analysis of E. coli's transcriptome reveals the cellular processes that respond to heterologous gene expression

Author

Tan, Justin, Sastry, Anand V., Fremming, Karoline S., Bjørn, Sara P., Hoffmeyer, Alexandra, Seo, Sangwoo, Voldborg, Bjørn G., and Palsson, Bernhard O.

Published

2020

6. Biochemical characterization of human gluconokinase and the proposed metabolic impact of gluconic acid as determined by constraint based metabolic network analysis.

Author

Rohatgi, Neha, Nielsen, Tine Kragh, Bjørn, Sara Petersen, Axelsson, Ivar, Paglia, Giuseppe, Voldborg, Bjørn Gunnar, Palsson, Bernhard O, and Rolfsson, Óttar

Subjects

Erythrocytes, Humans, Escherichia coli, Gluconates, Phosphotransferases (Alcohol Group Acceptor), Protein Conformation, Substrate Specificity, Phosphorylation, Kinetics, Models, Molecular, Metabolic Networks and Pathways, Models, Molecular, Phosphotransferases, General Science & Technology

Abstract

The metabolism of gluconate is well characterized in prokaryotes where it is known to be degraded following phosphorylation by gluconokinase. Less is known of gluconate metabolism in humans. Human gluconokinase activity was recently identified proposing questions about the metabolic role of gluconate in humans. Here we report the recombinant expression, purification and biochemical characterization of isoform I of human gluconokinase alongside substrate specificity and kinetic assays of the enzyme catalyzed reaction. The enzyme, shown to be a dimer, had ATP dependent phosphorylation activity and strict specificity towards gluconate out of 122 substrates tested. In order to evaluate the metabolic impact of gluconate in humans we modeled gluconate metabolism using steady state metabolic network analysis. The results indicate that significant metabolic flux changes in anabolic pathways linked to the hexose monophosphate shunt (HMS) are induced through a small increase in gluconate concentration. We argue that the enzyme takes part in a context specific carbon flux route into the HMS that, in humans, remains incompletely explored. Apart from the biochemical description of human gluconokinase, the results highlight that little is known of the mechanism of gluconate metabolism in humans despite its widespread use in medicine and consumer products.

Published

2014

7. Highly Selective Lysine Acylation in Proteins Using a Lys‐His Tag Sequence

Author

Kofoed, Christian, primary, Wu, Shunliang, additional, Sørensen, Kasper K., additional, Treiberg, Tuule, additional, Arnsdorf, Johnny, additional, Bjørn, Sara P., additional, Jensen, Tanja L., additional, Voldborg, Bjørn G., additional, Thygesen, Mikkel B., additional, Jensen, Knud J., additional, and Schoffelen, Sanne, additional

Published

2022

8. CHOmics:A web-based tool for multi-omics data analysis and interactive visualization in CHO cell lines

Author

Lin, Dongdong, Yalamanchili, Hima B., Zhang, Xinmin, Lewis, Nathan E., Alves, Christina S., Groot, Joost, Arnsdorf, Johnny, Bjørn, Sara P., Wulff, Tune, Voldborg, Bjørn G., Zhou, Yizhou, Zhang, Baohong, Lin, Dongdong, Yalamanchili, Hima B., Zhang, Xinmin, Lewis, Nathan E., Alves, Christina S., Groot, Joost, Arnsdorf, Johnny, Bjørn, Sara P., Wulff, Tune, Voldborg, Bjørn G., Zhou, Yizhou, and Zhang, Baohong

Abstract

Chinese hamster ovary (CHO) cell lines are widely used in industry for biological drug production. During cell culture development, considerable effort is invested to understand the factors that greatly impact cell growth, specific productivity and product qualities of the biotherapeutics. While high-throughput omics approaches have been increasingly utilized to reveal cellular mechanisms associated with cell line phenotypes and guide process optimization, comprehensive omics data analysis and management have been a challenge. Here we developed CHOmics, a web-based tool for integrative analysis of CHO cell line omics data that provides an interactive visualization of omics analysis outputs and efficient data management. CHOmics has a built-in comprehensive pipeline for RNA sequencing data processing and multi-layer statistical modules to explore relevant genes or pathways. Moreover, advanced functionalities were provided to enable users to customize their analysis and visualize the output systematically and interactively. The tool was also designed with the flexibility to accommodate other types of omics data and thereby enabling multi-omics comparison and visualization at both gene and pathway levels. Collectively, CHOmics is an integrative platform for data analysis, visualization and management with expectations to promote the broader use of omics in CHO cell research.

Published

2020

9. Evolution-guided engineering of small-molecule biosensors

Author

Snoek, Tim, primary, Chaberski, Evan K, additional, Ambri, Francesca, additional, Kol, Stefan, additional, Bjørn, Sara P, additional, Pang, Bo, additional, Barajas, Jesus F, additional, Welner, Ditte H, additional, Jensen, Michael K, additional, and Keasling, Jay D, additional

Published

2019

10. Nuclear Export Inhibitors and Kinase Inhibitors Identified Using a MAPK-Activated Protein Kinase 2 Redistribution®Screen

Author

Almholt, Dorthe L. C., primary, Loechel, Frosty, additional, Nielsen, Søren J., additional, Krog-Jensen, Christian, additional, Terry, Robert, additional, Bjørn, Sara P., additional, Pedersen, Hans C., additional, Praestegaard, Morten, additional, Møller, Søren, additional, Heide, Morten, additional, Pagliaro, Len, additional, Mason, Anthony J., additional, Butcher, Steven, additional, and Dahl, Søren W., additional

Published

2004

11. High Content Translocation Assays for Pathway Profiling.

Author

Walker, John M., Taylor, D. Lansing, Haskins, Jeffrey R., Giuliano, Kenneth A., Loechel, Frosty, Bjørn, Sara, Linde, Viggo, Præstegaard, Morten, and Pagliaro, Len

Abstract

This chapter describes the design and development of cell-based assays, in which quantitation of the intracellular translocation of a target protein—rather than binding or catalytic activity—provides the primary assay readout. These are inherently high content assays, and they provide feedback on cellular response at the systems level, rather than data on activities of individual, purified molecules. Multiple protein translocation assays can be used to profile cellular signaling pathways and they can play a key role in determination of mechanism of action for novel classes of compounds with therapeutic potential. This assay technology has developed from laboratory curiosity into main stream industrial research over the past decade, and its promise is beginning to be realized as data acquisition and analysis technology evolve to take advantage of the rich window into systems biology provided by translocation assays. [ABSTRACT FROM AUTHOR]

Published

2006

12. A Simple Cell-Based HTS Assay System to Screen for Inhibitors of p53-Hdm2 Protein–Protein Interactions

Author

Lundholt, Betina Kerstin, Heydorn, Arne, Bjørn, Sara Petersen, and Præstegaard, Morten

Abstract

Green fluorescent protein-assisted readout for interacting proteins (GRIP) is a universal protein interaction discovery system that can be used to generate truly high throughput screening-compatible cellular assays to be used to screen for inhibitors of protein-protein interactions. The technology uses a "bait and prey" principle based on the distinct translocation behavior of the human cyclic AMP phosphodiesterase 4A4. Here we use the p53-Hdm2 Redistribution®assay (Fisher BioImage ApS, Søborg, Denmark) as an example to describe the GRIP technology. The p53-Hdm2 Redistribution assay is a high content imaging assay based on the GRIP technology that is designed to measure the interaction between Hdm2 and the tumor suppressor p53. Hdm2 regulates p53 and inhibits its function by modulating its transcriptional activity and stability. Activation of p53 in tumor cells through inhibition of its physical interaction with Hdm2 is therefore a focus of cancer drug discovery. We have performed a pilot screen by screening 3,165 compounds from a diverse small-molecule library for inhibitors of the p53-Hdm2 interaction by using the p53-Hdm2 Redistribution assay. Here we show that by taking advantage of the translocation behavior of nonbound p53, it is possible to identify true inhibitors of the p53-Hdm2 interaction by extracting high content information from the acquired images.

Published

2006

13. Identification of RAS-Mitogen-Activated Protein Kinase Signaling Pathway Modulators in an ERF1 Redistribution® Screen

Author

Grånäs, Charlotta, Lundholt, Betina Kerstin, Loechel, Frosty, Pedersen, Hans-Christian, Bjørn, Sara Petersen, Linde, Viggo, Krogh-Jensen, Christian, Nielsen, Eva-Maria Damsgaard, Præstegaard, Morten, and Nielsen, Søren Jensby

Abstract

The RAS-mitogen-activated protein kinase (MAPK) signaling pathway has a central role in regulating the proliferation and survival of both normal and tumor cells. This pathway has been 1 focus area for the development of anticancer drugs, resulting in several compounds, primarily kinase inhibitors, in clinical testing. The authors have undertaken a cell-based, high-throughput screen using a novel ERF1 Redistribution® assay to identify compounds that modulate the signaling pathway. The hit compounds were subsequently tested for activity in a functional cell proliferation assay designed to selectively detect compounds inhibiting the proliferation of MAPK pathway-dependent cancer cells. The authors report the identification of 2 cell membrane-permeable compounds that exhibit activity in the ERF1 Redistribution® assay and selectively inhibit proliferation of MAPK pathway-dependent malignant melanoma cells at similar potencies (IC50=< 5 μM). These compounds have drug-like structures and are negative in RAF, MEK, and ERK in vitro kinase assays. Drugs belonging to these compound classes may prove useful for treating cancers caused by excessive MAPK pathway signaling. The results also show that cell-based, high-content Redistribution® screens can detect compounds with different modes of action and reveal novel targets in a pathway known to be disease relevant.

Published

2006

14. Identification of Akt Pathway Inhibitors Using Redistribution Screening on the FLIPR and the IN Cell 3000 Analyzer

Author

Lundholt, Betina Kerstin, Linde, Viggo, Loechel, Frosty, Pedersen, Hans-Christian, Møller, Søren, Præstegaard, Morten, Mikkelsen, Ivan, Scudder, Kurt, Bjørn, Sara Petersen, Heide, Morten, Arkhammar, Per O. G., Terry, Robert, and Nielsen, Søren Jensby

Abstract

The PI3-kinase/Akt pathway is an important cell survival pathway that is deregulated in the majority of human cancers. Despite the apparent druggability of several kinases in the pathway, no specific catalytic inhibitors have been reported in the literature. The authors describe the development of a fluorometric imaging plate reader (FLIPR)-based Akt1 translocation assay to discover inhibitors of Akt1 activation. Screening of a diverse chemical library of 45,000 compounds resulted in identification of several classes of Akt1 translocation inhibitors. Using a combination of classical in vitro assays and translocation assays directed at different steps of the Akt pathway, the mechanisms of action of 2 selected chemical classes were further defined. Protein translocation assays emerge as powerful tools for hit identification and characterization. (Journal of Biomolecular Screening2005:20-29)

Published

2005

15. Highly Selective Lysine Acylation in Proteins Using a Lys-His Tag Sequence.

Author

Kofoed C, Wu S, Sørensen KK, Treiberg T, Arnsdorf J, Bjørn SP, Jensen TL, Voldborg BG, Thygesen MB, Jensen KJ, and Schoffelen S

Subjects

Acylation, Amino Acid Sequence, Peptides chemistry, Lysine, Proteins

Abstract

Chemical modification of proteins has numerous applications, but it has been challenging to achieve the required high degree of selectivity on lysine amino groups. Recently, we described the highly selective acylation of proteins with an N-terminal Gly-His 6 segment. This tag promoted acylation of the N-terminal N α -amine resulting in stable conjugates. Herein, we report the peptide sequences His n -Lys-His m , which we term Lys-His tags. In combination with simple acylating agents, they facilitate the acylation of the designated Lys N ϵ -amine under mild conditions and with high selectivity over native Lys residues. We show that the Lys-His tags, which are 7 to 10 amino acids in length and still act as conventional His tags, can be inserted in proteins at the C-terminus or in loops, thus providing high flexibility regarding the site of modification. Finally, the selective and efficient acylation of the therapeutic antibody Rituximab, pure or mixed with other proteins, demonstrates the scope of the Lys-His tag acylation method., (© 2022 Wiley-VCH GmbH.)

Published

2022