Your search keyword '"Kopp, Marie R. G."' showing total 18 results

1. Isotope labeling to determine the dynamics of metabolic response in CHO cell perfusion bioreactors using MALDI‐TOF‐MS

Author

Karst, Daniel J., Steinhoff, Robert F., Kopp, Marie R. G., Soos, Miroslav, Zenobi, Renato, and Morbidelli, Massimo

Published

2017

2. Programmable Zwitterionic Droplets as Biomolecular Sorters and Model of Membraneless Organelles (Adv. Mater. 4/2022)

Author

Capasso Palmiero, Umberto, primary, Paganini, Carolina, additional, Kopp, Marie R. G., additional, Linsenmeier, Miriam, additional, Küffner, Andreas M., additional, and Arosio, Paolo, additional

Published

2022

3. Programmable Zwitterionic Droplets as Biomolecular Sorters and Model of Membraneless Organelles

Author

Capasso Palmiero, Umberto, primary, Paganini, Carolina, additional, Kopp, Marie R. G., additional, Linsenmeier, Miriam, additional, Küffner, Andreas M., additional, and Arosio, Paolo, additional

Published

2021

4. Microfluidic Shrinking Droplet Concentrator for Analyte Detection and Phase Separation of Protein Solutions

Author

Kopp, Marie R. G., primary, Linsenmeier, Miriam, additional, Hettich, Britta, additional, Prantl, Sebastian, additional, Stavrakis, Stavros, additional, Leroux, Jean-Christophe, additional, and Arosio, Paolo, additional

Published

2020

5. A Nanoparticle-Based Assay To Evaluate Surface-Induced Antibody Instability

Author

Kopp, Marie R. G., primary, Capasso Palmiero, Umberto, additional, and Arosio, Paolo, additional

Published

2020

6. Corrigendum: Dynamics of Synthetic Membraneless Organelles in Microfluidic Droplets

Author

Linsenmeier, Miriam, primary, Kopp, Marie R. G., additional, Grigolato, Fulvio, additional, Emmanouilidis, Leonidas, additional, Liu, Dany, additional, Zürcher, Dominik, additional, Hondele, Maria, additional, Weis, Karsten, additional, Capasso Palmiero, Umberto, additional, and Arosio, Paolo, additional

Published

2019

7. Berichtigung: Dynamics of Synthetic Membraneless Organelles in Microfluidic Droplets

Author

Linsenmeier, Miriam, primary, Kopp, Marie R. G., additional, Grigolato, Fulvio, additional, Emmanoulidis, Leonidas, additional, Liu, Dany, additional, Zürcher, Dominik, additional, Hondele, Maria, additional, Weis, Karsten, additional, Capasso Palmiero, Umberto, additional, and Arosio, Paolo, additional

Published

2019

8. Dynamics of Synthetic Membraneless Organelles in Microfluidic Droplets

Author

Linsenmeier, Miriam, primary, Kopp, Marie R. G., additional, Grigolato, Fulvio, additional, Emmanoulidis, Leonidas, additional, Liu, Dany, additional, Zürcher, Dominik, additional, Hondele, Maria, additional, Weis, Karsten, additional, Capasso Palmiero, Umberto, additional, and Arosio, Paolo, additional

Published

2019

9. Microfluidic Diffusion Analysis of the Size Distribution and Microrheological Properties of Antibody Solutions at High Concentrations

Author

Kopp, Marie R. G., primary, Villois, Alessia, additional, Capasso Palmiero, Umberto, additional, and Arosio, Paolo, additional

Published

2018

10. Intracellular CHO Cell Metabolite Profiling Reveals Steady-State Dependent Metabolic Fingerprints in Perfusion Culture

Author

Karst, Daniel J., primary, Steinhoff, Robert F., additional, Kopp, Marie R. G., additional, Serra, Elisa, additional, Soos, Miroslav, additional, Zenobi, Renato, additional, and Morbidelli, Massimo, additional

Published

2017

11. A hydrophobic low-complexity region regulates aggregation of the yeast pyruvate kinase Cdc19 into amyloid-like aggregates in vitro.

Author

Grignaschi, Erica, Cereghetti, Gea, Grigolato, Fulvio, Kopp, Marie R. G., Caimi, Stefano, Faltova, Lenka, Saad, Shady, Peter, Matthias, and Arosio, Paolo

Subjects

*HYDROPHOBIC compounds, *BIOCOMPLEXITY, *PYRUVATE kinase, *SACCHAROMYCES, *AMYLOID synthesis, *PHYSIOLOGY

Abstract

Cells form stress granules (SGs) upon stress stimuli to protect sensitive proteins and RNA from degradation. In the yeast Saccharomyces cerevisiae, specific stresses such as nutrient starvation and heat-shock trigger recruitment of the yeast pyruvate kinase Cdc19 into SGs. This RNA-binding protein was shown to form amyloid-like aggregates that are physiologically reversible and essential for cell cycle restart after stress. Cellular Cdc19 exists in an equilibrium between a homotetramer and monomer state. Here, we show that Cdc19 aggregation in vitro is governed by protein quaternary structure, and we investigate the physical--chemical basis of Cdc19's assembly properties. Equilibrium shift toward the monomer state exposes a hydrophobic low-complexity region (LCR), which is prone to induce intermolecular interactions with surrounding proteins. We further demonstrate that hydrophobic/hydrophilic interfaces can trigger Cdc19 aggregation in vitro. Moreover, we performed in vitro biophysical analyses to compare Cdc19 aggregates with fibrils produced by two known dysfunctional amyloidogenic peptides. We show that the Cdc19 aggregates share several structural features with pathological amyloids formed by human insulin and the Alzheimer's disease--associated Aβ42 peptide, particularly secondary β-sheet structure, thermodynamic stability, and staining by the thioflavin T dye. However, Cdc19 aggregates could not seed aggregation. These results indicate that Cdc19 adopts an amyloid-like structure in vitro that is regulated by the exposure of a hydrophobic LCR in its monomeric form. Together, our results highlight striking structural similarities between functional and dysfunctional amyloids and reveal the crucial role of hydrophobic/hydrophilic interfaces in regulating Cdc19 aggregation. [ABSTRACT FROM AUTHOR]

Published

2018

12. Surface-Induced Protein Aggregation and Particle Formation in Biologics: Current Understanding of Mechanisms, Detection and Mitigation Strategies.

Author

Kopp MRG, Grigolato F, Zürcher D, Das TK, Chou D, Wuchner K, and Arosio P

Subjects

Chemistry, Pharmaceutical methods, Membrane Proteins, Water, Protein Aggregates, Biological Products

Abstract

Protein stability against aggregation is a major quality concern for the production of safe and effective biopharmaceuticals. Amongst the different drivers of protein aggregation, increasing evidence indicates that interactions between proteins and interfaces represent a major risk factor for the formation of protein aggregates in aqueous solutions. Potentially harmful surfaces relevant to biologics manufacturing and storage include air-water and silicone oil-water interfaces as well as materials from different processing units, storage containers, and delivery devices. The impact of some of these surfaces, for instance originating from impurities, can be difficult to predict and control. Moreover, aggregate formation may additionally be complicated by the simultaneous presence of interfacial, hydrodynamic and mechanical stresses, whose contributions may be difficult to deconvolute. As a consequence, it remains difficult to identify the key chemical and physical determinants and define appropriate analytical methods to monitor and predict protein instability at these interfaces. In this review, we first discuss the main mechanisms of surface-induced protein aggregation. We then review the types of contact materials identified as potentially harmful or detected as potential triggers of proteinaceous particle formation in formulations and discuss proposed mitigation strategies. Finally, we present current methods to probe surface-induced instabilities, which represent a starting point towards assays that can be implemented in early-stage screening and formulation development of biologics., Competing Interests: Declaration of Competing Interest The authors declare no conflict of interest, (Copyright © 2022 American Pharmacists Association. Published by Elsevier Inc. All rights reserved.)

Published

2023

13. Rapid Characterization and Quantification of Extracellular Vesicles by Fluorescence-Based Microfluidic Diffusion Sizing.

Author

Paganini C, Hettich B, Kopp MRG, Eördögh A, Capasso Palmiero U, Adamo G, Touzet N, Manno M, Bongiovanni A, Rivera-Fuentes P, Leroux JC, and Arosio P

Subjects

Biomarkers metabolism, Lab-On-A-Chip Devices, Reproducibility of Results, Extracellular Vesicles metabolism, Microfluidics

Abstract

Extracellular vesicles (EVs) are emerging as promising diagnostic and therapeutic tools for a variety of diseases. The characterization of EVs requires a series of orthogonal techniques that are overall time- and material-consuming. Here, a microfluidic device is presented that exploits the combination of diffusion sizing and multiwavelength fluorescence detection to simultaneously provide information on EV size, concentration, and composition. The latter is achieved with the nonspecific staining of lipids and proteins combined with the specific staining of EV markers such as EV-associated tetraspanins via antibodies. The device can be operated as a single-step immunoassay thanks to the integrated separation and quantification of free and EV-bound fluorophores. This microfluidic technique is capable of detecting and quantifying components associated to EV subtypes and impurities and thus to measure EV purity in a time scale of minutes, requiring less than 5 µL of sample and minimal sample handling before the analysis. Moreover, the analysis is performed directly in solution without immobilization steps. Therefore, this method can accelerate screening of EV samples and aid the evaluation of sample reproducibility, representing an important complementary tool to the current array of biophysical methods for EV characterization, particularly valuable for instance for bioprocess development., (© 2021 The Authors. Advanced Healthcare Materials published by Wiley-VCH GmbH.)

Published

2022

14. Analysis of biomolecular condensates and protein phase separation with microfluidic technology.

Author

Linsenmeier M, Kopp MRG, Stavrakis S, de Mello A, and Arosio P

Subjects

Organelles chemistry, Phase Transition, Proteins genetics, Proteins isolation & purification, RNA chemistry, RNA genetics, Surface Properties, Microfluidics methods, Organelles genetics, Proteins chemistry, RNA isolation & purification

Abstract

An increasing body of evidence shows that membraneless organelles are key components in cellular organization. These observations open a variety of outstanding questions about the physico-chemical rules underlying their assembly, disassembly and functions. Some molecular determinants of biomolecular condensates are challenging to probe and understand in complex in vivo systems. Minimalistic in vitro reconstitution approaches can fill this gap, mimicking key biological features, while maintaining sufficient simplicity to enable the analysis of fundamental aspects of biomolecular condensates. In this context, microfluidic technologies are highly attractive tools for the analysis of biomolecular phase transitions. In addition to enabling high-throughput measurements on small sample volumes, microfluidic tools provide for exquisite control of self-assembly in both time and space, leading to accurate quantitative analysis of biomolecular phase transitions. Here, with a specific focus on droplet-based microfluidics, we describe the advantages of microfluidic technology for the analysis of several aspects of phase separation. These include phase diagrams, dynamics of assembly and disassembly, rheological and surface properties, exchange of materials with the surrounding environment and the coupling between compartmentalization and biochemical reactions. We illustrate these concepts with selected examples, ranging from simple solutions of individual proteins to more complex mixtures of proteins and RNA, which represent synthetic models of biological membraneless organelles. Finally, we discuss how this technology may impact the bottom-up fabrication of synthetic artificial cells and for the development of synthetic protein materials in biotechnology., (Copyright © 2020 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2021

15. An accelerated surface-mediated stress assay of antibody instability for developability studies.

Author

Kopp MRG, Wolf Pérez AM, Zucca MV, Capasso Palmiero U, Friedrichsen B, Lorenzen N, and Arosio P

Subjects

Humans, Protein Stability, Antibodies, Monoclonal chemistry, Immunoglobulin G chemistry

Abstract

High physical stability is required for the development of monoclonal antibodies (mAbs) into successful therapeutic products. Developability assays are used to predict physical stability issues such as high viscosity and poor conformational stability, but protein aggregation remains a challenging property to predict. Among different types of stresses, air-water and solid-liquid interfaces are well known to potentially trigger protein instability and induce aggregation. Yet, in contrast to the increasing number of developability assays to evaluate bulk properties, there is still a lack of experimental methods to evaluate antibody stability against interfaces. Here, we investigate the potential of a hydrophobic nanoparticle surface-mediated stress assay to assess the stability of mAbs during the early stages of development. We evaluate this surface-mediated accelerated stability assay on a rationally designed library of 14 variants of a humanized IgG4, featuring a broad span of solubility values and other developability properties. The assay could identify variants characterized by high instability against agitation in the presence of air-water interfaces. Remarkably, for the set of investigated molecules, we observe strong correlations between the extent of aggregation induced by the surface-mediated stress assay and other developability properties of the molecules, such as aggregation upon storage at 45°C, self-association (evaluated by affinity-capture self-interaction nanoparticle spectroscopy) and nonspecific interactions (estimated by cross-interaction chromatography, stand-up monolayer chromatography (SMAC), SMAC*). This highly controlled surface-mediated stress assay has the potential to complement and increase the ability of the current set of screening techniques to assess protein aggregation and developability potential of mAbs during the early stages of drug development. Abbreviations :AC-SINS: Affinity-Capture Self-Interaction Nanoparticle Spectroscopy; AMS: Ammonium sulfate precipitation; ANS: 1-anilinonaphtalene-8-sulfonate; CIC: Cross-interaction chromatography; DLS: Dynamic light scattering; HIC: Hydrophobic interaction chromatography; HNSSA: Hydrophobic nanoparticles surface-stress assay; mAb: Monoclonal antibody; NP: Nanoparticle; SEC: Size exclusion chromatography; SMAC: Stand-up monolayer chromatography; WT: Wild type.

Published

2020

16. Corrigendum: Dynamics of Synthetic Membraneless Organelles in Microfluidic Droplets.

Author

Linsenmeier M, Kopp MRG, Grigolato F, Emmanouilidis L, Liu D, Zürcher D, Hondele M, Weis K, Capasso Palmiero U, and Arosio P

Published

2019

17. Microfluidic Approaches for the Characterization of Therapeutic Proteins.

Author

Kopp MRG and Arosio P

Subjects

Animals, Equipment Design, Humans, Microfluidic Analytical Techniques instrumentation, Pharmaceutical Preparations chemistry, Protein Aggregates, Protein Stability, Solubility, Viscosity, Antibodies, Monoclonal chemistry, Microfluidic Analytical Techniques methods, Proteins chemistry

Abstract

In the last decades, the pharmaceutical market has experienced an increase in the number of therapeutic proteins. The high activity and selectivity of these macromolecules is often achieved at the expense of complex structures, which exhibit several biophysical properties that must be carefully controlled and optimized for the successful development of these drugs as well as for guaranteeing their quality and safety. This need has motivated the application of a variety of biophysical techniques to analyze properties of therapeutic proteins and protein solutions including interactions, aggregation, solubility, viscosity, and thermal stability. After briefly summarizing currently available experimental approaches, we highlight the emerging possibilities offered by advances in microfluidic technology for the analysis of therapeutic proteins during manufacturing and formulation., (Copyright © 2018 American Pharmacists Association®. Published by Elsevier Inc. All rights reserved.)

Published

2018

18. Microarray-based MALDI-TOF mass spectrometry enables monitoring of monoclonal antibody production in batch and perfusion cell cultures.

Author

Steinhoff RF, Karst DJ, Steinebach F, Kopp MR, Schmidt GW, Stettler A, Krismer J, Soos M, Pabst M, Hierlemann A, Morbidelli M, and Zenobi R

Subjects

Antibodies, Monoclonal chemistry, Antibody Formation, Molecular Weight, Antibodies, Monoclonal isolation & purification, Cell Culture Techniques methods, Protein Array Analysis methods, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization methods

Abstract

Cell culture process monitoring in monoclonal antibody (mAb) production is essential for efficient process development and process optimization. Currently employed online, at line and offline methods for monitoring productivity as well as process reproducibility have their individual strengths and limitations. Here, we describe a matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS)-based on a microarray for mass spectrometry (MAMS) technology to rapidly monitor a broad panel of analytes, including metabolites and proteins directly from the unpurified cell supernatant or from host cell culture lysates. The antibody titer is determined from the intact antibody mass spectra signal intensity relative to an internal protein standard spiked into the supernatant. The method allows a semi-quantitative determination of light and heavy chains. Intracellular mass profiles for metabolites and proteins can be used to track cellular growth and cell productivity., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2016