Your search keyword '"Atz K"' showing total 29 results

1. Berichte und Mittheilungen aus Sammlungen und Museen, über staatliche Kunstpflege und Restaurationen, neue Funde

Author

Schricker, A., primary and Atz, K., additional

Published

1968

2. Discovery of 1,3,4-Oxadiazin-5-One Derivative CJ1-34 as a Partial ATP Synthase Inhibitor for CNS Applications.

Author

Jie CVML, Delparente A, Reichert L, Albrecht M, Atz K, Schneider G, Schibli R, and Mu L

Abstract

ATP synthase dysregulation has been implicated in many diseases, including cancer and neurodegenerative diseases. Whilst ATP synthase-targeting compounds have been reported, most are large or polar compounds and lack appropriate properties for a CNS drug. We designed, synthesised, and evaluated a novel series of ATP synthase targeting compounds, resulting in a 1,3,4-oxadiazin-5-one scaffold with improved physiochemical properties. In vitro evaluation of our library led to the discovery of CJ1-34 as a partial ATP synthase inhibitor with a determined IC 50 of 394 nM in isolated bovine mitochondria. Molecular docking experiments demonstrated that calculated docking scores aligned with the observed in vitro pharmacology and supports the F 1 region of the ATP synthase as the potential binding site. Overall, this provides the foundation to further investigate CJ1-34 as a potential CNS drug for diseases where mitochondria are implicated, including Alzheimer's and Parkinson's disease., (© 2025 Wiley-VCH GmbH.)

Published

2025

3. Author Correction: Prospective de novo drug design with deep interactome learning.

Author

Atz K, Cotos L, Isert C, Håkansson M, Focht D, Hilleke M, Nippa DF, Iff M, Ledergerber J, Schiebroek CCG, Romeo V, Hiss JA, Merk D, Schneider P, Kuhn B, Grether U, and Schneider G

Published

2025

4. Protein Binding Site Representation in Latent Space.

Author

Lohmann F, Allenspach S, Atz K, Schiebroek CCG, Hiss JA, and Schneider G

Subjects

Binding Sites, Deep Learning, Ligands, Neural Networks, Computer, Protein Binding, Drug Discovery, Proteins chemistry, Proteins metabolism

Abstract

Interpretability and reliability of deep learning models are important for computer-based drug discovery. Aiming to understand feature perception by such a model, we investigate a graph neural network for affinity prediction of protein-ligand complexes. We assess a latent representation of ligand binding sites and investigate underlying geometric structure in this latent space and its relation to protein function. We introduce an automated computational pipeline for dimensionality reduction, clustering, hypothesis testing, and visualization of latent space. The results indicate that the learned protein latent space is inherently structured and not randomly distributed. Several of the identified protein binding site clusters in latent space correspond to functional protein families. Ligand size was found to be a determinant of cluster geometry. The computational pipeline proved applicable to latent space analysis and interpretation and can be adapted to work for different datasets and deep learning models., (© 2024 The Author(s). Molecular Informatics published by Wiley-VCH GmbH.)

Published

2025

5. Simple User-Friendly Reaction Format.

Author

Nippa DF, Müller AT, Atz K, Konrad DB, Grether U, Martin RE, and Schneider G

Subjects

Databases, Chemical, Software, Humans, Machine Learning

Abstract

Utilizing the growing wealth of chemical reaction data can boost synthesis planning and increase success rates. Yet, the effectiveness of machine learning tools for retrosynthesis planning and forward reaction prediction relies on accessible, well-curated data presented in a structured format. Although some public and licensed reaction databases exist, they often lack essential information about reaction conditions. To address this issue and promote the principles of findable, accessible, interoperable, and reusable (FAIR) data reporting and sharing, we introduce the Simple User-Friendly Reaction Format (SURF). SURF standardizes the documentation of reaction data through a structured tabular format, requiring only a basic understanding of spreadsheets. This format enables chemists to record the synthesis of molecules in a format that is understandable by both humans and machines, which facilitates seamless sharing and integration directly into machine learning pipelines. SURF files are designed to be interoperable, easily imported into relational databases, and convertible into other formats. This complements existing initiatives like the Open Reaction Database (ORD) and Unified Data Model (UDM). At Roche, SURF plays a crucial role in democratizing FAIR reaction data sharing and expediting the chemical synthesis process., (© 2025 The Author(s). Molecular Informatics published by Wiley-VCH GmbH.)

Published

2025

6. Development of a Highly Selective NanoBRET Probe to Assess MAGL Inhibition in Live Cells.

Author

Gazzi T, Brennecke B, Olikauskas V, Hochstrasser R, Wang H, Keen Chao S, Atz K, Mostinski Y, Topp A, Heer D, Kaufmann I, Ritter M, Gobbi L, Hornsperger B, Wagner B, Richter H, O'Hara F, Wittwer MB, Jul Hansen D, Collin L, Kuhn B, Benz J, Grether U, and Nazaré M

Abstract

Cell-free enzymatic assays are highly useful tools in early compound profiling due to their robustness and scalability. However, their inadequacy to reflect the complexity of target engagement in a cellular environment may lead to a significantly divergent pharmacology that is eventually observed in cells. The discrepancy that emerges from properties like permeability and unspecific protein binding may largely mislead lead compound selection to undergo further chemical optimization. We report the development of a new intracellular NanoBRET assay to assess MAGL inhibition in live cells. Based on a reverse design approach, a highly potent, reversible preclinical inhibitor was conjugated to the cell-permeable BODIPY590 acceptor fluorophore while retaining its overall balanced properties. An engineered MAGL-nanoluciferase (Nluc) fusion protein provided a suitable donor counterpart for the facile interrogation of intracellular ligand activity. Validation of assay conditions using a selection of known MAGL inhibitors set the stage for the evaluation of over 1'900 MAGL drug candidates derived from our discovery program. This evaluation enabled us to select compounds for further development based not only on target engagement, but also on favorable physicochemical parameters like permeability and protein binding. This study highlights the advantages of cell-based target engagement assays for accelerating compound profiling and progress at the early stages of drug discovery programs., (© 2024 The Author(s). ChemBioChem published by Wiley-VCH GmbH.)

Published

2024

7. Combining de novo molecular design with semiempirical protein-ligand binding free energy calculation.

Author

Iff M, Atz K, Isert C, Pachon-Angona I, Cotos L, Hilleke M, Hiss JA, and Schneider G

Abstract

Semi-empirical quantum chemistry methods estimate the binding free energies of protein-ligand complexes. We present an integrated approach combining the GFN2- x TB method with de novo design for the generation and evaluation of potential inhibitors of acetylcholinesterase (AChE). We employed chemical language model-based molecule generation to explore the synthetically accessible chemical space around the natural product Huperzine A, a potent AChE inhibitor. Four distinct molecular libraries were created using structure- and ligand-based molecular de novo design with SMILES and SELFIES representations, respectively. These libraries were computationally evaluated for synthesizability, novelty, and predicted biological activity. The candidate molecules were subjected to molecular docking to identify hypothetical binding poses, which were further refined using Gibbs free energy calculations. The structurally novel top-ranked molecule was chemically synthesized and biologically tested, demonstrating moderate micromolar activity against AChE. Our findings highlight the potential and certain limitations of integrating deep learning-based molecular generation with semi-empirical quantum chemistry-based activity prediction for structure-based drug design., Competing Interests: G. S. is a co-founder of inSili.com LLC, Zurich, and Xanadys LLC, Zurich, and a consultant to the pharmaceutical industry., (This journal is © The Royal Society of Chemistry.)

Published

2024

8. Enhancing Drug Discovery and Development through the Integration of Medicinal Chemistry, Chemical Biology, and Academia-Industry Partnerships: Insights from Roche's Endocannabinoid System Projects.

Author

Aebi J, Atz K, Ametamey SM, Benz J, Blaising J, Butini S, Campiani G, Carreira EM, Collin L, De Lago E, Gazzi T, Gertsch J, Gobbi L, Guba W, Fernández-Ruiz J, Fingerle J, Haider A, He Y, Heitman LH, Honer M, Hunziker D, Kuhn B, Maccarrone M, Märki HP, Martin RE, Mohr P, Mu L, Nazaré M, Nippa DF, Oddi S, O'Hara F, Pacher P, Romero J, Röver S, Rufer AC, Schibli R, Schneider G, Stepan AF, Sykes DA, Ullmer C, Van der Stelt M, Veprintsev DB, Wittwer MB, and Grether U

Subjects

Humans, Drug Industry, Monoacylglycerol Lipases metabolism, Monoacylglycerol Lipases antagonists & inhibitors, Drug Development, Academia, Drug Discovery, Endocannabinoids metabolism, Endocannabinoids chemistry, Chemistry, Pharmaceutical

Abstract

The endocannabinoid system (ECS) is a critical regulatory network composed of endogenous cannabinoids (eCBs), their synthesizing and degrading enzymes, and associated receptors. It is integral to maintaining homeostasis and orchestrating key functions within the central nervous and immune systems. Given its therapeutic significance, we have launched a series of drug discovery endeavors aimed at ECS targets, including peroxisome proliferator-activated receptors (PPARs), cannabinoid receptors types 1 (CB1R) and 2 (CB2R), and monoacylglycerol lipase (MAGL), addressing a wide array of medical needs. The pursuit of new therapeutic agents has been enhanced by the creation of specialized labeled chemical probes, which aid in target localization, mechanistic studies, assay development, and the establishment of biomarkers for target engagement. By fusing medicinal chemistry with chemical biology in a comprehensive, translational end-to-end drug discovery strategy, we have expedited the development of novel therapeutics. Additionally, this strategy promises to foster highly productive partnerships between industry and academia, as will be illustrated through various examples., (Copyright 2024 Johannes Aebi, Kenneth Atz, Simon M. Ametamey, Jörg Benz, Julie Blaising, Stefania Butini, Giuseppe Campiani, Erick M. Carreira, Ludovic Collin, Eva de Lago, Thais Gazzi, Jürg Gertsch, Luca Gobbi, Wolfgang Guba, Javier Fernández-Ruiz, Jürgen Fingerle, Ahmed Haider, Yingfang He, Laura H. Heitman, Michael Honer, Daniel Hunziker, Bernd Kuhn, Mauro Maccarrone, Hans Peter Märki, Rainer E. Martin, Peter Mohr, Linjing Mu, Marc Nazaré, David F. Nippa, Sergio Oddi, Fionn O’Hara, Pal Pacher, Julian Romero, Stephan Röver, Arne C. Rufer, Roger Schibli, Gisbert Schneider, Antonia F. Stepan, David A. Sykes, Christoph Ullmer, Mario van der Stelt, Dmitry B. Veprintsev, Matthias B. Wittwer, Uwe Grether. License: This work is licensed under a Creative Commons Attribution 4.0 International License.)

Published

2024

9. G- PLIP : Knowledge graph neural network for structure-free protein-ligand bioactivity prediction.

Author

Crouzet SJ, Lieberherr AM, Atz K, Nilsson T, Sach-Peltason L, Müller AT, Dal Peraro M, and Zhang JD

Abstract

Protein-ligand interactions (PLIs) determine the efficacy and safety profiles of small molecule drugs. Existing methods rely on either structural information or resource-intensive computations to predict PLI, casting doubt on whether it is possible to perform structure-free PLI predictions at low computational cost. Here we show that a light-weight graph neural network (GNN), trained with quantitative PLIs of a small number of proteins and ligands, is able to predict the strength of unseen PLIs. The model has no direct access to structural information about the protein-ligand complexes. Instead, the predictive power is provided by encoding the entire chemical and proteomic space in a single heterogeneous graph, encapsulating primary protein sequence, gene expression, the protein-protein interaction network, and structural similarities between ligands. This novel approach performs competitively with, or better than, structure-aware models. Our results suggest that existing PLI prediction methods may be improved by incorporating representation learning techniques that embed biological and chemical knowledge., Competing Interests: The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Jitao David Zhang, Simon J. Crouzet, Anja Maria Lieberherr, Kenneth Atz, Tobias Nilsson, Lisa Sach- Peltason and Alex T. Müller report financial support, administrative support and article publishing charges were provided by 10.13039/100004337F. Hoffmann-La Roche Ltd. Jitao David Zhang, Kenneth Atz, Tobias Nilsson, Lisa Sach-Peltason, Alex T. Müller report being currently employed by F Hoffmann-La Roche Ltd. If there are other authors, they declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2024 The Author(s).)

Published

2024

10. Geometric deep learning-guided Suzuki reaction conditions assessment for applications in medicinal chemistry.

Author

Atz K, Nippa DF, Müller AT, Jost V, Anelli A, Reutlinger M, Kramer C, Martin RE, Grether U, Schneider G, and Wuitschik G

Abstract

Suzuki cross-coupling reactions are considered a valuable tool for constructing carbon-carbon bonds in small molecule drug discovery. However, the synthesis of chemical matter often represents a time-consuming and labour-intensive bottleneck. We demonstrate how machine learning methods trained on high-throughput experimentation (HTE) data can be leveraged to enable fast reaction condition selection for novel coupling partners. We show that the trained models support chemists in determining suitable catalyst-solvent-base combinations for individual transformations including an evaluation of the need for HTE screening. We introduce an algorithm for designing 96-well plates optimized towards reaction yields and discuss the model performance of zero- and few-shot machine learning. The best-performing machine learning model achieved a three-category classification accuracy of 76.3% (±0.2%) and an F 1 -score for a binary classification of 79.1% (±0.9%). Validation on eight reactions revealed a receiver operating characteristic (ROC) curve (AUC) value of 0.82 (±0.07) for few-shot machine learning. On the other hand, zero-shot machine learning models achieved a mean ROC-AUC value of 0.63 (±0.16). This study positively advocates the application of few-shot machine learning-guided reaction condition selection for HTE campaigns in medicinal chemistry and highlights practical applications as well as challenges associated with zero-shot machine learning., Competing Interests: G. S. declares a potential financial and non-financial conflict of interest as co-founder of https://inSili.com LLC, Zurich and in his role as a scientific consultant to the pharmaceutical industry. K. A., D. F. N., A. T. M., V. J., M. R. U. G., R. E. M., C. K. and G. W. declare a potential financial and non-financial conflict of interest as full employees of F. Hoffmann-La Roche Ltd., (This journal is © The Royal Society of Chemistry.)

Published

2024

11. Prospective de novo drug design with deep interactome learning.

Author

Atz K, Cotos L, Isert C, Håkansson M, Focht D, Hilleke M, Nippa DF, Iff M, Ledergerber J, Schiebroek CCG, Romeo V, Hiss JA, Merk D, Schneider P, Kuhn B, Grether U, and Schneider G

Subjects

Humans, Ligands, Binding Sites, Protein Binding, Deep Learning, Drug Design, PPAR gamma metabolism, PPAR gamma agonists, PPAR gamma chemistry

Abstract

De novo drug design aims to generate molecules from scratch that possess specific chemical and pharmacological properties. We present a computational approach utilizing interactome-based deep learning for ligand- and structure-based generation of drug-like molecules. This method capitalizes on the unique strengths of both graph neural networks and chemical language models, offering an alternative to the need for application-specific reinforcement, transfer, or few-shot learning. It enables the "zero-shot" construction of compound libraries tailored to possess specific bioactivity, synthesizability, and structural novelty. In order to proactively evaluate the deep interactome learning framework for protein structure-based drug design, potential new ligands targeting the binding site of the human peroxisome proliferator-activated receptor (PPAR) subtype gamma are generated. The top-ranking designs are chemically synthesized and computationally, biophysically, and biochemically characterized. Potent PPAR partial agonists are identified, demonstrating favorable activity and the desired selectivity profiles for both nuclear receptors and off-target interactions. Crystal structure determination of the ligand-receptor complex confirms the anticipated binding mode. This successful outcome positively advocates interactome-based de novo design for application in bioorganic and medicinal chemistry, enabling the creation of innovative bioactive molecules., (© 2024. The Author(s).)

Published

2024

12. Exploring protein-ligand binding affinity prediction with electron density-based geometric deep learning.

Author

Isert C, Atz K, Riniker S, and Schneider G

Abstract

Rational structure-based drug design relies on accurate predictions of protein-ligand binding affinity from structural molecular information. Although deep learning-based methods for predicting binding affinity have shown promise in computational drug design, certain approaches have faced criticism for their potential to inadequately capture the fundamental physical interactions between ligands and their macromolecular targets or for being susceptible to dataset biases. Herein, we propose to include bond-critical points based on the electron density of a protein-ligand complex as a fundamental physical representation of protein-ligand interactions. Employing a geometric deep learning model, we explore the usefulness of these bond-critical points to predict absolute binding affinities of protein-ligand complexes, benchmark model performance against existing methods, and provide a critical analysis of this new approach. The models achieved root-mean-squared errors of 1.4-1.8 log units on the PDBbind dataset, and 1.0-1.7 log units on the PDE10A dataset, not indicating significant advantages over benchmark methods, and thus rendering the utility of electron density for deep learning models context-dependent. The relationship between intermolecular electron density and corresponding binding affinity was analyzed, and Pearson correlation coefficients r > 0.7 were obtained for several macromolecular targets., Competing Interests: G. S. declares a potential financial conflict of interest as co-founder of https://insili.com/ GmbH, Zurich, and in his role as a scientific consultant to the pharmaceutical industry., (This journal is © The Royal Society of Chemistry.)

Published

2024

13. Enabling late-stage drug diversification by high-throughput experimentation with geometric deep learning.

Author

Nippa DF, Atz K, Hohler R, Müller AT, Marx A, Bartelmus C, Wuitschik G, Marzuoli I, Jost V, Wolfard J, Binder M, Stepan AF, Konrad DB, Grether U, Martin RE, and Schneider G

Subjects

High-Throughput Screening Assays, Deep Learning

Abstract

Late-stage functionalization is an economical approach to optimize the properties of drug candidates. However, the chemical complexity of drug molecules often makes late-stage diversification challenging. To address this problem, a late-stage functionalization platform based on geometric deep learning and high-throughput reaction screening was developed. Considering borylation as a critical step in late-stage functionalization, the computational model predicted reaction yields for diverse reaction conditions with a mean absolute error margin of 4-5%, while the reactivity of novel reactions with known and unknown substrates was classified with a balanced accuracy of 92% and 67%, respectively. The regioselectivity of the major products was accurately captured with a classifier F-score of 67%. When applied to 23 diverse commercial drug molecules, the platform successfully identified numerous opportunities for structural diversification. The influence of steric and electronic information on model performance was quantified, and a comprehensive simple user-friendly reaction format was introduced that proved to be a key enabler for seamlessly integrating deep learning and high-throughput experimentation for late-stage functionalization., (© 2023. The Author(s).)

Published

2024

14. Identifying opportunities for late-stage C-H alkylation with high-throughput experimentation and in silico reaction screening.

Author

Nippa DF, Atz K, Müller AT, Wolfard J, Isert C, Binder M, Scheidegger O, Konrad DB, Grether U, Martin RE, and Schneider G

Abstract

Enhancing the properties of advanced drug candidates is aided by the direct incorporation of specific chemical groups, avoiding the need to construct the entire compound from the ground up. Nevertheless, their chemical intricacy often poses challenges in predicting reactivity for C-H activation reactions and planning their synthesis. We adopted a reaction screening approach that combines high-throughput experimentation (HTE) at a nanomolar scale with computational graph neural networks (GNNs). This approach aims to identify suitable substrates for late-stage C-H alkylation using Minisci-type chemistry. GNNs were trained using experimentally generated reactions derived from in-house HTE and literature data. These trained models were then used to predict, in a forward-looking manner, the coupling of 3180 advanced heterocyclic building blocks with a diverse set of sp 3 -rich carboxylic acids. This predictive approach aimed to explore the substrate landscape for Minisci-type alkylations. Promising candidates were chosen, their production was scaled up, and they were subsequently isolated and characterized. This process led to the creation of 30 novel, functionally modified molecules that hold potential for further refinement. These results positively advocate the application of HTE-based machine learning to virtual reaction screening., (© 2023. The Author(s).)

Published

2023

15. Allosteric targeting resolves limitations of earlier LFA-1 directed modalities.

Author

Mancuso RV, Schneider G, Hürzeler M, Gut M, Zurflüh J, Breitenstein W, Bouitbir J, Reisen F, Atz K, Ehrhardt C, Duthaler U, Gygax D, Schmidt AG, Krähenbühl S, and Weitz-Schmidt G

Subjects

Ligands, Intercellular Adhesion Molecule-1 metabolism, Lymphocyte Function-Associated Antigen-1 chemistry, Lymphocyte Function-Associated Antigen-1 metabolism, Signal Transduction

Abstract

Integrins are a family of cell surface receptors well-recognized for their therapeutic potential in a wide range of diseases. However, the development of integrin targeting medications has been impacted by unexpected downstream effects, reflecting originally unforeseen interference with the bidirectional signalling and cross-communication of integrins. We here selected one of the most severely affected target integrins, the integrin lymphocyte function-associated antigen-1 (LFA-1, α L β 2 , CD11a/CD18), as a prototypic integrin to systematically assess and overcome these known shortcomings. We employed a two-tiered ligand-based virtual screening approach to identify a novel class of allosteric small molecule inhibitors targeting this integrin's αI domain. The newly discovered chemical scaffold was derivatized, yielding potent bis-and tris-aryl-bicyclic-succinimides which inhibit LFA-1 in vitro at low nanomolar concentrations. The characterisation of these compounds in comparison to earlier LFA-1 targeting modalities established that the allosteric LFA-1 inhibitors (i) are devoid of partial agonism, (ii) selectively bind LFA-1 versus other integrins, (iii) do not trigger internalization of LFA-1 itself or other integrins and (iv) display oral availability. This profile differentiates the new generation of allosteric LFA-1 inhibitors from previous ligand mimetic-based LFA-1 inhibitors and anti-LFA-1 antibodies, and is projected to support novel immune regulatory regimens selectively targeting the integrin LFA-1. The rigorous computational and experimental assessment schedule described here is designed to be adaptable to the preclinical discovery and development of novel allosterically acting compounds targeting integrins other than LFA-1, providing an exemplary approach for the early characterisation of next generation integrin inhibitors., Competing Interests: Declaration of Competing Interest Gisbert Schneider, Daniel Gygax, Albrecht G. Schmidt and Gabriele Weitz-Schmidt are co-founders and shareholders of AlloCyte Pharmaceuticals AG, Basel (AlloCyte). Riccardo V. Mancuso owns stock options of AlloCyte. Gisbert Schneider is also a co-founder of inSili.com LLC, Zurich, and a scientific consultant to the pharmaceutical industry. The remaining authors declare no competing interests., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

16. Structure-based drug design with geometric deep learning.

Author

Isert C, Atz K, and Schneider G

Subjects

Drug Design, Neural Networks, Computer, Drug Discovery methods, Machine Learning, Ligands, Deep Learning

Abstract

Structure-based drug design uses three-dimensional geometric information of macromolecules, such as proteins or nucleic acids, to identify suitable ligands. Geometric deep learning, an emerging concept of neural-network-based machine learning, has been applied to macromolecular structures. This review provides an overview of the recent applications of geometric deep learning in bioorganic and medicinal chemistry, highlighting its potential for structure-based drug discovery and design. Emphasis is placed on molecular property prediction, ligand binding site and pose prediction, and structure-based de novo molecular design. The current challenges and opportunities are highlighted, and a forecast of the future of geometric deep learning for drug discovery is presented., Competing Interests: Conflict of interest statement G.S. declares a potential financial conflict of interest as co-founder of inSili.com LLC, Zurich, and in his role as a scientific consultant to the pharmaceutical industry., (Copyright © 2023 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2023

17. Leveraging molecular structure and bioactivity with chemical language models for de novo drug design.

Author

Moret M, Pachon Angona I, Cotos L, Yan S, Atz K, Brunner C, Baumgartner M, Grisoni F, and Schneider G

Subjects

Humans, Molecular Structure, Ligands, Drug Design, Phosphatidylinositol 3-Kinase, Phosphatidylinositol 3-Kinases, Proto-Oncogene Proteins c-akt

Abstract

Generative chemical language models (CLMs) can be used for de novo molecular structure generation by learning from a textual representation of molecules. Here, we show that hybrid CLMs can additionally leverage the bioactivity information available for the training compounds. To computationally design ligands of phosphoinositide 3-kinase gamma (PI3Kγ), a collection of virtual molecules was created with a generative CLM. This virtual compound library was refined using a CLM-based classifier for bioactivity prediction. This second hybrid CLM was pretrained with patented molecular structures and fine-tuned with known PI3Kγ ligands. Several of the computer-generated molecular designs were commercially available, enabling fast prescreening and preliminary experimental validation. A new PI3Kγ ligand with sub-micromolar activity was identified, highlighting the method's scaffold-hopping potential. Chemical synthesis and biochemical testing of two of the top-ranked de novo designed molecules and their derivatives corroborated the model's ability to generate PI3Kγ ligands with medium to low nanomolar activity for hit-to-lead expansion. The most potent compounds led to pronounced inhibition of PI3K-dependent Akt phosphorylation in a medulloblastoma cell model, demonstrating efficacy of PI3Kγ ligands in PI3K/Akt pathway repression in human tumor cells. The results positively advocate hybrid CLMs for virtual compound screening and activity-focused molecular design., (© 2023. The Author(s).)

Published

2023

18. Machine Learning and Computational Chemistry for the Endocannabinoid System.

Author

Atz K, Guba W, Grether U, and Schneider G

Subjects

Drug Design, Ligands, Machine Learning, Quantitative Structure-Activity Relationship, Computational Chemistry, Endocannabinoids

Abstract

Computational methods in medicinal chemistry facilitate drug discovery and design. In particular, machine learning methodologies have recently gained increasing attention. This chapter provides a structured overview of the current state of computational chemistry and its applications for the interrogation of the endocannabinoid system (ECS), highlighting methods in structure-based drug design, virtual screening, ligand-based quantitative structure-activity relationship (QSAR) modeling, and de novo molecular design. We emphasize emerging methods in machine learning and anticipate a forecast of future opportunities of computational medicinal chemistry for the ECS., (© 2023. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

19. Translating from Proteins to Ribonucleic Acids for Ligand-binding Site Detection.

Author

Möller L, Guerci L, Isert C, Atz K, and Schneider G

Subjects

Binding Sites, Ligands, RNA metabolism, Neural Networks, Computer, Proteins chemistry

Abstract

Identifying druggable ligand-binding sites on the surface of the macromolecular targets is an important process in structure-based drug discovery. Deep-learning models have been shown to successfully predict ligand-binding sites of proteins. As a step toward predicting binding sites in RNA and RNA-protein complexes, we employ three-dimensional convolutional neural networks. We introduce a dataset splitting approach to minimize structure-related bias in training data, and investigate the influence of protein-based neural network pre-training before fine-tuning on RNA structures. Models that were pre-trained on proteins considerably outperformed the models that were trained exclusively on RNA structures. Overall, 71 % of the known RNA binding sites were correctly located within 4 Å of their true centres., (© 2022 Wiley-VCH GmbH.)

Published

2022

20. QMugs, quantum mechanical properties of drug-like molecules.

Author

Isert C, Atz K, Jiménez-Luna J, and Schneider G

Subjects

Thermodynamics, Drug Discovery, Machine Learning

Abstract

Machine learning approaches in drug discovery, as well as in other areas of the chemical sciences, benefit from curated datasets of physical molecular properties. However, there currently is a lack of data collections featuring large bioactive molecules alongside first-principle quantum chemical information. The open-access QMugs (Quantum-Mechanical Properties of Drug-like Molecules) dataset fills this void. The QMugs collection comprises quantum mechanical properties of more than 665 k biologically and pharmacologically relevant molecules extracted from the ChEMBL database, totaling ~2 M conformers. QMugs contains optimized molecular geometries and thermodynamic data obtained via the semi-empirical method GFN2-xTB. Atomic and molecular properties are provided on both the GFN2-xTB and on the density-functional levels of theory (DFT, ωB97X-D/def2-SVP). QMugs features molecules of significantly larger size than previously-reported collections and comprises their respective quantum mechanical wave functions, including DFT density and orbital matrices. This dataset is intended to facilitate the development of models that learn from molecular data on different levels of theory while also providing insight into the corresponding relationships between molecular structure and biological activity., (© 2022. The Author(s).)

Published

2022

21. Δ-Quantum machine-learning for medicinal chemistry.

Author

Atz K, Isert C, Böcker MNA, Jiménez-Luna J, and Schneider G

Subjects

Machine Learning, Neural Networks, Computer, Software, Chemistry, Pharmaceutical, Quantum Theory

Abstract

Many molecular design tasks benefit from fast and accurate calculations of quantum-mechanical (QM) properties. However, the computational cost of QM methods applied to drug-like molecules currently renders large-scale applications of quantum chemistry challenging. Aiming to mitigate this problem, we developed DelFTa, an open-source toolbox for the prediction of electronic properties of drug-like molecules at the density functional (DFT) level of theory, using Δ-machine-learning. Δ-Learning corrects the prediction error (Δ) of a fast but inaccurate property calculation. DelFTa employs state-of-the-art three-dimensional message-passing neural networks trained on a large dataset of QM properties. It provides access to a wide array of quantum observables on the molecular, atomic and bond levels by predicting approximations to DFT values from a low-cost semiempirical baseline. Δ-Learning outperformed its direct-learning counterpart for most of the considered QM endpoints. The results suggest that predictions for non-covalent intra- and intermolecular interactions can be extrapolated to larger biomolecular systems. The software is fully open-sourced and features documented command-line and Python APIs.

Published

2022

22. Detection of cannabinoid receptor type 2 in native cells and zebrafish with a highly potent, cell-permeable fluorescent probe.

Author

Gazzi T, Brennecke B, Atz K, Korn C, Sykes D, Forn-Cuni G, Pfaff P, Sarott RC, Westphal MV, Mostinski Y, Mach L, Wasinska-Kalwa M, Weise M, Hoare BL, Miljuš T, Mexi M, Roth N, Koers EJ, Guba W, Alker A, Rufer AC, Kusznir EA, Huber S, Raposo C, Zirwes EA, Osterwald A, Pavlovic A, Moes S, Beck J, Nettekoven M, Benito-Cuesta I, Grande T, Drawnel F, Widmer G, Holzer D, van der Wel T, Mandhair H, Honer M, Fingerle J, Scheffel J, Broichhagen J, Gawrisch K, Romero J, Hillard CJ, Varga ZV, van der Stelt M, Pacher P, Gertsch J, Ullmer C, McCormick PJ, Oddi S, Spaink HP, Maccarrone M, Veprintsev DB, Carreira EM, Grether U, and Nazaré M

Abstract

Despite its essential role in the (patho)physiology of several diseases, CB 2 R tissue expression profiles and signaling mechanisms are not yet fully understood. We report the development of a highly potent, fluorescent CB 2 R agonist probe employing structure-based reverse design. It commences with a highly potent, preclinically validated ligand, which is conjugated to a silicon-rhodamine fluorophore, enabling cell permeability. The probe is the first to preserve interspecies affinity and selectivity for both mouse and human CB 2 R. Extensive cross-validation (FACS, TR-FRET and confocal microscopy) set the stage for CB 2 R detection in endogenously expressing living cells along with zebrafish larvae. Together, these findings will benefit clinical translatability of CB 2 R based drugs., Competing Interests: The authors have no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2022

23. Combining generative artificial intelligence and on-chip synthesis for de novo drug design.

Author

Grisoni F, Huisman BJH, Button AL, Moret M, Atz K, Merk D, and Schneider G

Subjects

Drug Discovery methods, Artificial Intelligence, Drug Design

Abstract

Automating the molecular design-make-test-analyze cycle accelerates hit and lead finding for drug discovery. Using deep learning for molecular design and a microfluidics platform for on-chip chemical synthesis, liver X receptor (LXR) agonists were generated from scratch. The computational pipeline was tuned to explore the chemical space of known LXRα agonists and generate novel molecular candidates. To ensure compatibility with automated on-chip synthesis, the chemical space was confined to the virtual products obtainable from 17 one-step reactions. Twenty-five de novo designs were successfully synthesized in flow. In vitro screening of the crude reaction products revealed 17 (68%) hits, with up to 60-fold LXR activation. The batch resynthesis, purification, and retesting of 14 of these compounds confirmed that 12 of them were potent LXR agonists. These results support the suitability of the proposed design-make-test-analyze framework as a blueprint for automated drug design with artificial intelligence and miniaturized bench-top synthesis., (Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).)

Published

2021

24. Cannabinoid receptor type 2 ligands: an analysis of granted patents since 2010.

Author

Brennecke B, Gazzi T, Atz K, Fingerle J, Kuner P, Schindler T, Weck G, Nazaré M, and Grether U

Subjects

Animals, Humans, Ligands, Patents as Topic, Receptors, Cannabinoid, Signal Transduction, Anti-Inflammatory Agents, Endocannabinoids

Abstract

The G-protein-coupled cannabinoid receptor type 2 (CB 2 R) is a key element of the endocannabinoid (EC) system. EC/CB 2 R signaling has significant therapeutic potential in major pathologies affecting humans such as allergies, neurodegenerative disorders, inflammation or ocular diseases. CB 2 R agonism exerts anti-inflammatory and tissue protective effects in preclinical animal models of cardiovascular, gastrointestinal, liver, kidney, lung and neurodegenerative disorders. Existing ligands can be subdivided into endocannabinoids, cannabinoid-like and synthetic CB 2 R ligands that possess various degrees of potency on and selectivity against the cannabinoid receptor type 1. This review is an account of granted CB 2 R ligand patents from 2010 up to the present, which were surveyed using Derwent Innovation ® .

Published

2021

25. Development of High-Specificity Fluorescent Probes to Enable Cannabinoid Type 2 Receptor Studies in Living Cells.

Author

Sarott RC, Westphal MV, Pfaff P, Korn C, Sykes DA, Gazzi T, Brennecke B, Atz K, Weise M, Mostinski Y, Hompluem P, Koers E, Miljuš T, Roth NJ, Asmelash H, Vong MC, Piovesan J, Guba W, Rufer AC, Kusznir EA, Huber S, Raposo C, Zirwes EA, Osterwald A, Pavlovic A, Moes S, Beck J, Benito-Cuesta I, Grande T, Ruiz de Martı N Esteban S, Yeliseev A, Drawnel F, Widmer G, Holzer D, van der Wel T, Mandhair H, Yuan CY, Drobyski WR, Saroz Y, Grimsey N, Honer M, Fingerle J, Gawrisch K, Romero J, Hillard CJ, Varga ZV, van der Stelt M, Pacher P, Gertsch J, McCormick PJ, Ullmer C, Oddi S, Maccarrone M, Veprintsev DB, Nazaré M, Grether U, and Carreira EM

Subjects

Animals, CHO Cells, Cricetulus, Disease Models, Animal, Flow Cytometry, Fluorescence Resonance Energy Transfer, Humans, Ligands, Mice, Molecular Docking Simulation, Molecular Probes chemistry, Optical Imaging, Sensitivity and Specificity, Signal Transduction, Alzheimer Disease metabolism, Fluorescent Dyes chemistry, Microglia metabolism, Receptor, Cannabinoid, CB2 analysis

Abstract

Pharmacological modulation of cannabinoid type 2 receptor (CB 2 R) holds promise for the treatment of numerous conditions, including inflammatory diseases, autoimmune disorders, pain, and cancer. Despite the significance of this receptor, researchers lack reliable tools to address questions concerning the expression and complex mechanism of CB 2 R signaling, especially in cell-type and tissue-dependent contexts. Herein, we report for the first time a versatile ligand platform for the modular design of a collection of highly specific CB 2 R fluorescent probes, used successfully across applications, species, and cell types. These include flow cytometry of endogenously expressing cells, real-time confocal microscopy of mouse splenocytes and human macrophages, as well as FRET-based kinetic and equilibrium binding assays. High CB 2 R specificity was demonstrated by competition experiments in living cells expressing CB 2 R at native levels. The probes were effectively applied to FACS analysis of microglial cells derived from a mouse model relevant to Alzheimer's disease.

Published

2020

26. Identification and Preclinical Development of a 2,5,6-Trisubstituted Fluorinated Pyridine Derivative as a Radioligand for the Positron Emission Tomography Imaging of Cannabinoid Type 2 Receptors.

Author

Haider A, Gobbi L, Kretz J, Ullmer C, Brink A, Honer M, Woltering TJ, Muri D, Iding H, Bürkler M, Binder M, Bartelmus C, Knuesel I, Pacher P, Herde AM, Spinelli F, Ahmed H, Atz K, Keller C, Weber M, Schibli R, Mu L, Grether U, and Ametamey SM

Subjects

Animals, Brain diagnostic imaging, Fluorine Radioisotopes chemistry, Humans, Ligands, Male, Molecular Docking Simulation, Molecular Structure, Positron-Emission Tomography, Pyridines chemical synthesis, Pyridines pharmacokinetics, Radiopharmaceuticals chemical synthesis, Radiopharmaceuticals pharmacokinetics, Rats, Wistar, Spinal Cord diagnostic imaging, Spleen diagnostic imaging, Structure-Activity Relationship, Tritium chemistry, Pyridines pharmacology, Radiopharmaceuticals pharmacology, Receptor, Cannabinoid, CB2 metabolism

Abstract

Despite the broad implications of the cannabinoid type 2 receptor (CB2) in neuroinflammatory processes, a suitable CB2-targeted probe is currently lacking in clinical routine. In this work, we synthesized 15 fluorinated pyridine derivatives and tested their binding affinities toward CB2 and CB1. With a sub-nanomolar affinity ( K i for CB2) of 0.8 nM and a remarkable selectivity factor of >12,000 over CB1, RoSMA-18- d 6 exhibited outstanding in vitro performance characteristics and was radiofluorinated with an average radiochemical yield of 10.6 ± 3.8% ( n = 16) and molar activities ranging from 52 to 65 GBq/μmol (radiochemical purity > 99%). [ 18 F]RoSMA-18- d 6 showed exceptional CB2 attributes as demonstrated by in vitro autoradiography, ex vivo biodistribution, and positron emission tomography (PET). Further, [ 18 F]RoSMA-18- d 6 was used to detect CB2 upregulation on postmortem human ALS spinal cord tissues. Overall, these results suggest that [ 18 F]RoSMA-18- d 6 is a promising CB2 PET radioligand for clinical translation.

Published

2020

27. NMR pseudocontact shifts in a symmetric protein homotrimer.

Author

Müntener T, Böhm R, Atz K, Häussinger D, and Hiller S

Subjects

Algorithms, Models, Molecular, Models, Theoretical, Protein Conformation, Recombinant Proteins chemistry, Structure-Activity Relationship, Nuclear Magnetic Resonance, Biomolecular methods, Protein Multimerization, Proteins chemistry

Abstract

NMR pseudocontact shifts are a valuable tool for structural and functional studies of proteins. Protein multimers mediate key functional roles in biology, but methods for their study by pseudocontact shifts are so far not available. Paramagnetic tags attached to identical subunits in multimeric proteins cause a combined pseudocontact shift that cannot be described by the standard single-point model. Here, we report pseudocontact shifts generated simultaneously by three paramagnetic Tm-M7PyThiazole-DOTA tags to the trimeric molecular chaperone Skp and provide an approach for the analysis of this and related symmetric systems. The pseudocontact shifts were described by a "three-point" model, in which positions and parameters of the three paramagnetic tags were fitted. A good correlation between experimental data and predicted values was found, validating the approach. The study establishes that pseudocontact shifts can readily be applied to multimeric proteins, offering new perspectives for studies of large protein complexes by paramagnetic NMR spectroscopy.

Published

2020

28. Structure-Activity Relationship Studies of Pyridine-Based Ligands and Identification of a Fluorinated Derivative for Positron Emission Tomography Imaging of Cannabinoid Type 2 Receptors.

Author

Haider A, Kretz J, Gobbi L, Ahmed H, Atz K, Bürkler M, Bartelmus C, Fingerle J, Guba W, Ullmer C, Honer M, Knuesel I, Weber M, Brink A, Herde AM, Keller C, Schibli R, Mu L, Grether U, and Ametamey SM

Subjects

Animals, Brain diagnostic imaging, Cyclic AMP metabolism, Fluorine Radioisotopes chemistry, Hepatocytes metabolism, Humans, Ligands, Male, Mice, Mice, Inbred C57BL, Molecular Structure, Protein Conformation, Radiochemistry, Radiopharmaceuticals chemistry, Rats, Rats, Wistar, Receptor, Cannabinoid, CB2 chemistry, Structure-Activity Relationship, Brain metabolism, Fluorine Radioisotopes metabolism, Neuroimaging methods, Positron-Emission Tomography methods, Pyridines chemistry, Radiopharmaceuticals metabolism, Receptor, Cannabinoid, CB2 metabolism

Abstract

The cannabinoid type 2 (CB2) receptor has emerged as a valuable target for therapy and imaging of immune-mediated pathologies. With the aim to find a suitable radiofluorinated analogue of the previously reported CB2 positron emission tomography (PET) radioligand [ 11 C]RSR-056, 38 fluorinated derivatives were synthesized and tested by in vitro binding assays. With a K i (hCB2) of 6 nM and a selectivity factor of nearly 700 over cannabinoid type 1 receptors, target compound 3 exhibited optimal in vitro properties and was selected for evaluation as a PET radioligand. [ 18 F] 3 was obtained in an average radiochemical yield of 11 ± 4% and molar activities between 33 and 114 GBq/μmol. Specific binding of [ 18 F] 3 to CB2 was demonstrated by in vitro autoradiography and in vivo PET experiments using the CB2 ligand GW-405 833. Metabolite analysis revealed only intact [ 18 F] 3 in the rat brain. [ 18 F] 3 detected CB2 upregulation in human amyotrophic lateral sclerosis spinal cord tissue and may thus become a candidate for diagnostic use in humans.

Published

2019

29. Mechanical Stabilization of Helical Chirality in a Macrocyclic Oligothiophene.

Author

Weiland KJ, Brandl T, Atz K, Prescimone A, Häussinger D, Šolomek T, and Mayor M

Abstract

We introduce a design principle to stabilize helically chiral structures from an achiral tetrasubstituted [2.2]paracyclophane by integrating it into a macrocycle. The [2.2]paracyclophane introduces a three-dimensional perturbation into a nearly planar macrocyclic oligothiophene. The resulting helical structure is stabilized by two bulky substituents installed on the [2.2]paracyclophane unit. The increased enantiomerization barrier enabled the separation of both enantiomers. The synthesis of the target helical macrocycle 1 involves a sequence of halogenation and cross-coupling steps and a high-dilution strategy to close the macrocycle. Substituents tuning the energy of the enantiomerization process can be introduced in the last steps of the synthesis. The chiral target compound 1 was fully characterized by NMR spectroscopy and mass spectrometry. The absolute configurations of the isolated enantiomers were assigned by comparing the data of circular dichroism spectroscopy with TD-DFT calculations. The enantiomerization dynamics was studied by dynamic HPLC and variable-temperature 2D exchange spectroscopy and supported by quantum-chemical calculations.

Published

2019