Your search keyword '"Kroell, Katharina B."' showing total 11 results

1. Structure and Dynamics Guiding Design of Antibody Therapeutics and Vaccines

Author

Fernández-Quintero, Monica L., primary, Pomarici, Nancy D., additional, Fischer, Anna-Lena M., additional, Hoerschinger, Valentin J., additional, Kroell, Katharina B., additional, Riccabona, Jakob R., additional, Kamenik, Anna S., additional, Loeffler, Johannes R., additional, Ferguson, James A., additional, Perrett, Hailee R., additional, Liedl, Klaus R., additional, Han, Julianna, additional, and Ward, Andrew B., additional

Published

2023

2. Antibodies exhibit multiple paratope states influencing VH–VL domain orientations

Author

Fernández-Quintero, Monica L., Pomarici, Nancy D., Math, Barbara A., Kroell, Katharina B., Waibl, Franz, Bujotzek, Alexander, Georges, Guy, and Liedl, Klaus R.

Published

2020

3. Corrigendum: Comparing Antibody Interfaces to Inform Rational Design of New Antibody Formats

Author

Fernández-Quintero, Monica L., primary, Quoika, Patrick K., additional, Wedl, Florian S., additional, Seidler, Clarissa A., additional, Kroell, Katharina B., additional, Loeffler, Johannes R., additional, Pomarici, Nancy D., additional, Hoerschinger, Valentin J., additional, Bujotzek, Alexander, additional, Georges, Guy, additional, Kettenberger, Hubert, additional, and Liedl, Klaus R., additional

Published

2022

4. CDR loop interactions can determine heavy and light chain pairing preferences in bispecific antibodies

Author

Fernández-Quintero, Monica L., primary, Kroell, Katharina B., additional, Grunewald, Lukas J., additional, Fischer, Anna-Lena M., additional, Riccabona, Jakob R., additional, and Liedl, Klaus R., additional

Published

2022

5. Comparing Antibody Interfaces to Inform Rational Design of New Antibody Formats

Author

Fernández-Quintero, Monica L., primary, Quoika, Patrick K., additional, Wedl, Florian S., additional, Seidler, Clarissa A., additional, Kroell, Katharina B., additional, Loeffler, Johannes R., additional, Pomarici, Nancy D., additional, Hoerschinger, Valentin J., additional, Bujotzek, Alexander, additional, Georges, Guy, additional, Kettenberger, Hubert, additional, and Liedl, Klaus R., additional

Published

2022

6. Germline-Dependent Antibody Paratope States and Pairing Specific VH-VL Interface Dynamics

Author

Fernández-Quintero, Monica L., primary, Kroell, Katharina B., additional, Bacher, Lisa M., additional, Loeffler, Johannes R., additional, Quoika, Patrick K., additional, Georges, Guy, additional, Bujotzek, Alexander, additional, Kettenberger, Hubert, additional, and Liedl, Klaus R., additional

Published

2021

7. Mutation of Framework Residue H71 Results in Different Antibody Paratope States in Solution

Author

Fernández-Quintero, Monica L., primary, Kroell, Katharina B., additional, Hofer, Florian, additional, Riccabona, Jakob R., additional, and Liedl, Klaus R., additional

Published

2021

8. Surprisingly Fast Interface and Elbow Angle Dynamics of Antigen-Binding Fragments

Author

Fernández-Quintero, Monica L., Kroell, Katharina B., Heiss, Martin C., Loeffler, Johannes R., Quoika, Patrick K., Waibl, Franz, Bujotzek, Alexander, Moessner, Ekkehard, Georges, Guy, and Liedl, Klaus R.

Subjects

VH–VL interface dynamics, CH1–CL dynamics, elbow angle, lcsh:Biology (General), antibody structure prediction, Molecular Biosciences, Biochemistry, Genetics and Molecular Biology (miscellaneous), Molecular Biology, Biochemistry, antibody structure design, lcsh:QH301-705.5, Original Research

Abstract

Fab consist of a heavy and light chain and can be subdivided into a variable (VH and VL) and a constant region (CH1 and CL). The variable region contains the complementarity-determining region (CDR), which is formed by six hypervariable loops, shaping the antigen binding site, the paratope. Apart from the CDR loops, both the elbow angle and the relative interdomain orientations of the VH–VL and the CH1–CL domains influence the shape of the paratope. Thus, characterization of the interface and elbow angle dynamics is essential to antigen specificity. We studied nine antigen-binding fragments (Fab) to investigate the influence of affinity maturation, antibody humanization, and different light-chain types on the interface and elbow angle dynamics. While the CDR loops reveal conformational transitions in the micro-to-millisecond timescale, both the interface and elbow angle dynamics occur on the low nanosecond timescale. Upon affinity maturation, we observe a substantial rigidification of the VH and VL interdomain and elbow-angle flexibility, reflected in a narrower and more distinct distribution. Antibody humanization describes the process of grafting non-human CDR loops onto a representative human framework. As the antibody framework changes upon humanization, we investigated if both the interface and the elbow angle distributions are changed or shifted. The results clearly showed a substantial shift in the relative VH–VL distributions upon antibody humanization, indicating that different frameworks favor distinct interface orientations. Additionally, the interface and elbow angle dynamics of five antibody fragments with different light-chain types are included, because of their strong differences in elbow angles. For these five examples, we clearly see a high variability and flexibility in both interface and elbow angle dynamics, highlighting the fact that Fab interface orientations and elbow angles interconvert between each other in the low nanosecond timescale. Understanding how the relative interdomain orientations and the elbow angle influence antigen specificity, affinity, and stability has broad implications in the field of antibody modeling and engineering.

Published

2020

9. Germline-Dependent Antibody Paratope States and Pairing Specific VH-VL Interface Dynamics.

Author

Fernández-Quintero, Monica L., Kroell, Katharina B., Bacher, Lisa M., Loeffler, Johannes R., Quoika, Patrick K., Georges, Guy, Bujotzek, Alexander, Kettenberger, Hubert, and Liedl, Klaus R.

Subjects

INTERFACE dynamics, AMINO acid sequence, IMMUNOGLOBULINS, IMMUNOTECHNOLOGY, BINDING sites

Abstract

Antibodies have emerged as one of the fastest growing classes of biotherapeutic proteins. To improve the rational design of antibodies, we investigate the conformational diversity of 16 different germline combinations, which are composed of 4 different kappa light chains paired with 4 different heavy chains. In this study, we systematically show that different heavy and light chain pairings strongly influence the paratope, interdomain interaction patterns and the relative VH-VL interface orientations. We observe changes in conformational diversity and substantial population shifts of the complementarity determining region (CDR) loops, resulting in distinct dominant solution structures and differently favored canonical structures. Additionally, we identify conformational changes in the structural diversity of the CDR-H3 loop upon different heavy and light chain pairings, as well as upon changes in sequence and structure of the neighboring CDR loops, despite having an identical CDR-H3 loop amino acid sequence. These results can also be transferred to all CDR loops and to the relative VH-VL orientation, as certain paratope states favor distinct interface angle distributions. Furthermore, we directly compare the timescales of sidechain rearrangements with the well-described transition kinetics of conformational changes in the backbone of the CDR loops. We show that sidechain flexibilities are strongly affected by distinct heavy and light chain pairings and decipher germline-specific structural features co-determining stability. These findings reveal that all CDR loops are strongly correlated and that distinct heavy and light chain pairings can result in different paratope states in solution, defined by a characteristic combination of CDR loop conformations and VH-VL interface orientations. Thus, these results have broad implications in the field of antibody engineering, as they clearly show the importance of considering paired heavy and light chains to understand the antibody binding site, which is one of the key aspects in the design of therapeutics. [ABSTRACT FROM AUTHOR]

Published

2021

10. Antibodies exhibit multiple paratope states influencing VH–VL domain orientations.

Author

Fernández-Quintero, Monica L., Pomarici, Nancy D., Math, Barbara A., Kroell, Katharina B., Waibl, Franz, Bujotzek, Alexander, Georges, Guy, and Liedl, Klaus R.

Subjects

IMMUNOGLOBULINS, BIOPHARMACEUTICS, MOLECULAR dynamics, HYPERVARIABLE regions, ANTIGENS

Abstract

In the last decades, antibodies have emerged as one of the most important and successful classes of biopharmaceuticals. The highest variability and diversity of an antibody is concentrated on six hypervariable loops, also known as complementarity determining regions (CDRs) shaping the antigen-binding site, the paratope. Whereas it was assumed that certain sequences can only adopt a limited set of backbone conformations, in this study we present a kinetic classification of several paratope states in solution. Using molecular dynamics simulations in combination with experimental structural information we capture the involved conformational transitions between different canonical clusters and additional dominant solution structures occurring in the micro-to-millisecond timescale. Furthermore, we observe a strong correlation of CDR loop movements. Another important aspect when characterizing different paratope states is the relative VH/VL orientation and the influence of the distinct CDR loop states on the VH/VL interface. Conformational rearrangements of the CDR loops do not only have an effect on the relative VH/VL orientations, but also influence in some cases the elbow-angle dynamics and shift the respective distributions. Thus, our results show that antibodies exist as several interconverting paratope states, each contributing to the antibody's properties. Fernández-Quintero et al. employ molecular dynamics simulations in combination with experimental structural information to demonstrate that antibodies exist as several interconverting paratope states. They propose that dynamic conformational transitions on the micro-to-millisecond timescale are responsible for antibody allostery in contrast to the long believed paradigm of static canonical structures determining binding properties and specificity of antibodies. [ABSTRACT FROM AUTHOR]

Published

2020

11. Germline-Dependent Antibody Paratope States and Pairing Specific V H -V L Interface Dynamics.

Author

Fernández-Quintero ML, Kroell KB, Bacher LM, Loeffler JR, Quoika PK, Georges G, Bujotzek A, Kettenberger H, and Liedl KR

Subjects

Complementarity Determining Regions chemistry, Humans, Immunoglobulin Heavy Chains chemistry, Immunoglobulin Light Chains chemistry, Immunoglobulin Variable Region chemistry, Protein Conformation, Binding Sites, Antibody, Germ Cells immunology, Molecular Dynamics Simulation

Abstract

Antibodies have emerged as one of the fastest growing classes of biotherapeutic proteins. To improve the rational design of antibodies, we investigate the conformational diversity of 16 different germline combinations, which are composed of 4 different kappa light chains paired with 4 different heavy chains. In this study, we systematically show that different heavy and light chain pairings strongly influence the paratope, interdomain interaction patterns and the relative V H -V L interface orientations. We observe changes in conformational diversity and substantial population shifts of the complementarity determining region (CDR) loops, resulting in distinct dominant solution structures and differently favored canonical structures. Additionally, we identify conformational changes in the structural diversity of the CDR-H3 loop upon different heavy and light chain pairings, as well as upon changes in sequence and structure of the neighboring CDR loops, despite having an identical CDR-H3 loop amino acid sequence. These results can also be transferred to all CDR loops and to the relative V H -V L orientation, as certain paratope states favor distinct interface angle distributions. Furthermore, we directly compare the timescales of sidechain rearrangements with the well-described transition kinetics of conformational changes in the backbone of the CDR loops. We show that sidechain flexibilities are strongly affected by distinct heavy and light chain pairings and decipher germline-specific structural features co-determining stability. These findings reveal that all CDR loops are strongly correlated and that distinct heavy and light chain pairings can result in different paratope states in solution, defined by a characteristic combination of CDR loop conformations and V H -V L interface orientations. Thus, these results have broad implications in the field of antibody engineering, as they clearly show the importance of considering paired heavy and light chains to understand the antibody binding site, which is one of the key aspects in the design of therapeutics., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Fernández-Quintero, Kroell, Bacher, Loeffler, Quoika, Georges, Bujotzek, Kettenberger and Liedl.)

Published

2021