Your search keyword '"Jens Meiler"' showing total 63 results

1. Combining machine learning with structure-based protein design to predict and engineer post-translational modifications of proteins.

Author

Moritz Ertelt, Vikram Khipple Mulligan, Jack B Maguire, Sergey Lyskov, Rocco Moretti, Torben Schiffner, Jens Meiler, and Clara T Schoeder

Subjects

Biology (General), QH301-705.5

Abstract

Post-translational modifications (PTMs) of proteins play a vital role in their function and stability. These modifications influence protein folding, signaling, protein-protein interactions, enzyme activity, binding affinity, aggregation, degradation, and much more. To date, over 400 types of PTMs have been described, representing chemical diversity well beyond the genetically encoded amino acids. Such modifications pose a challenge to the successful design of proteins, but also represent a major opportunity to diversify the protein engineering toolbox. To this end, we first trained artificial neural networks (ANNs) to predict eighteen of the most abundant PTMs, including protein glycosylation, phosphorylation, methylation, and deamidation. In a second step, these models were implemented inside the computational protein modeling suite Rosetta, which allows flexible combination with existing protocols to model the modified sites and understand their impact on protein stability as well as function. Lastly, we developed a new design protocol that either maximizes or minimizes the predicted probability of a particular site being modified. We find that this combination of ANN prediction and structure-based design can enable the modification of existing, as well as the introduction of novel, PTMs. The potential applications of our work include, but are not limited to, glycan masking of epitopes, strengthening protein-protein interactions through phosphorylation, as well as protecting proteins from deamidation liabilities. These applications are especially important for the design of new protein therapeutics where PTMs can drastically change the therapeutic properties of a protein. Our work adds novel tools to Rosetta's protein engineering toolbox that allow for the rational design of PTMs.

Published

2024

2. Benchmarking AlphaMissense pathogenicity predictions against cystic fibrosis variants.

Author

Eli Fritz McDonald, Kathryn E Oliver, Jonathan P Schlebach, Jens Meiler, and Lars Plate

Subjects

Medicine, Science

Abstract

Variants in the cystic fibrosis transmembrane conductance regulator gene (CFTR) result in cystic fibrosis-a lethal autosomal recessive disorder. Missense variants that alter a single amino acid in the CFTR protein are among the most common cystic fibrosis variants, yet tools for accurately predicting molecular consequences of missense variants have been limited to date. AlphaMissense (AM) is a new technology that predicts the pathogenicity of missense variants based on dual learned protein structure and evolutionary features. Here, we evaluated the ability of AM to predict the pathogenicity of CFTR missense variants. AM predicted a high pathogenicity for CFTR residues overall, resulting in a high false positive rate and fair classification performance on CF variants from the CFTR2.org database. AM pathogenicity score correlated modestly with pathogenicity metrics from persons with CF including sweat chloride level, pancreatic insufficiency rate, and Pseudomonas aeruginosa infection rate. Correlation was also modest with CFTR trafficking and folding competency in vitro. By contrast, the AM score correlated well with CFTR channel function in vitro-demonstrating the dual structure and evolutionary training approach learns important functional information despite lacking such data during training. Different performance across metrics indicated AM may determine if polymorphisms in CFTR are recessive CF variants yet cannot differentiate mechanistic effects or the nature of pathophysiology. Finally, AM predictions offered limited utility to inform on the pharmacological response of CF variants i.e., theratype. Development of new approaches to differentiate the biochemical and pharmacological properties of CFTR variants is therefore still needed to refine the targeting of emerging precision CF therapeutics.

Published

2024

3. Docking cholesterol to integral membrane proteins with Rosetta.

Author

Brennica Marlow, Georg Kuenze, Jens Meiler, and Julia Koehler Leman

Subjects

Biology (General), QH301-705.5

Abstract

Lipid molecules such as cholesterol interact with the surface of integral membrane proteins (IMP) in a mode different from drug-like molecules in a protein binding pocket. These differences are due to the lipid molecule's shape, the membrane's hydrophobic environment, and the lipid's orientation in the membrane. We can use the recent increase in experimental structures in complex with cholesterol to understand protein-cholesterol interactions. We developed the RosettaCholesterol protocol consisting of (1) a prediction phase using an energy grid to sample and score native-like binding poses and (2) a specificity filter to calculate the likelihood that a cholesterol interaction site may be specific. We used a multi-pronged benchmark (self-dock, flip-dock, cross-dock, and global-dock) of protein-cholesterol complexes to validate our method. RosettaCholesterol improved sampling and scoring of native poses over the standard RosettaLigand baseline method in 91% of cases and performs better regardless of benchmark complexity. On the β2AR, our method found one likely-specific site, which is described in the literature. The RosettaCholesterol protocol quantifies cholesterol binding site specificity. Our approach provides a starting point for high-throughput modeling and prediction of cholesterol binding sites for further experimental validation.

Published

2023

4. Computational epitope mapping of class I fusion proteins using low complexity supervised learning methods.

Author

Marion F S Fischer, James E Crowe, and Jens Meiler

Subjects

Biology (General), QH301-705.5

Abstract

Antibody epitope mapping of viral proteins plays a vital role in understanding immune system mechanisms of protection. In the case of class I viral fusion proteins, recent advances in cryo-electron microscopy and protein stabilization techniques have highlighted the importance of cryptic or 'alternative' conformations that expose epitopes targeted by potent neutralizing antibodies. Thorough epitope mapping of such metastable conformations is difficult but is critical for understanding sites of vulnerability in class I fusion proteins that occur as transient conformational states during viral attachment and fusion. We introduce a novel method Accelerated class I fusion protein Epitope Mapping (AxIEM) that accounts for fusion protein flexibility to improve out-of-sample prediction of discontinuous antibody epitopes. Harnessing data from previous experimental epitope mapping efforts of several class I fusion proteins, we demonstrate that accuracy of epitope prediction depends on residue environment and allows for the prediction of conformation-dependent antibody target residues. We also show that AxIEM can identify common epitopes and provide structural insights for the development and rational design of vaccines.

Published

2022

5. Epitope-focused immunogen design based on the ebolavirus glycoprotein HR2-MPER region.

Author

Clara T Schoeder, Pavlo Gilchuk, Amandeep K Sangha, Kaitlyn V Ledwitch, Delphine C Malherbe, Xuan Zhang, Elad Binshtein, Lauren E Williamson, Cristina E Martina, Jinhui Dong, Erica Armstrong, Rachel Sutton, Rachel Nargi, Jessica Rodriguez, Natalia Kuzmina, Brooke Fiala, Neil P King, Alexander Bukreyev, James E Crowe, and Jens Meiler

Subjects

Immunologic diseases. Allergy, RC581-607, Biology (General), QH301-705.5

Abstract

The three human pathogenic ebolaviruses: Zaire (EBOV), Bundibugyo (BDBV), and Sudan (SUDV) virus, cause severe disease with high fatality rates. Epitopes of ebolavirus glycoprotein (GP) recognized by antibodies with binding breadth for all three ebolaviruses are of major interest for rational vaccine design. In particular, the heptad repeat 2 -membrane-proximal external region (HR2-MPER) epitope is relatively conserved between EBOV, BDBV, and SUDV GP and targeted by human broadly-neutralizing antibodies. To study whether this epitope can serve as an immunogen for the elicitation of broadly-reactive antibody responses, protein design in Rosetta was employed to transplant the HR2-MPER epitope identified from a co-crystal structure with the known broadly-reactive monoclonal antibody (mAb) BDBV223 onto smaller scaffold proteins. From computational analysis, selected immunogen designs were produced as recombinant proteins and functionally validated, leading to the identification of a sterile alpha motif (SAM) domain displaying the BDBV-HR2-MPER epitope near its C terminus as a promising candidate. The immunogen was fused to one component of a self-assembling, two-component nanoparticle and tested for immunogenicity in rabbits. Robust titers of cross-reactive serum antibodies to BDBV and EBOV GPs and moderate titers to SUDV GP were induced following immunization. To confirm the structural composition of the immunogens, solution NMR studies were conducted and revealed structural flexibility in the C-terminal residues of the epitope. Overall, our study represents the first report on an epitope-focused immunogen design based on the structurally challenging BDBV-HR2-MPER epitope.

Published

2022

6. Predicting the functional impact of KCNQ1 variants with artificial neural networks.

Author

Saksham Phul, Georg Kuenze, Carlos G Vanoye, Charles R Sanders, Alfred L George, and Jens Meiler

Subjects

Biology (General), QH301-705.5

Abstract

Recent advances in experimental and computational protein structure determination have provided access to high-quality structures for most human proteins and mutants thereof. However, linking changes in structure in protein mutants to functional impact remains an active area of method development. If successful, such methods can ultimately assist physicians in taking appropriate treatment decisions. This work presents three artificial neural network (ANN)-based predictive models that classify four key functional parameters of KCNQ1 variants as normal or dysfunctional using PSSM-based evolutionary and/or biophysical descriptors. Recent advances in predicting protein structure and variant properties with artificial intelligence (AI) rely heavily on the availability of evolutionary features and thus fail to directly assess the biophysical underpinnings of a change in structure and/or function. The central goal of this work was to develop an ANN model based on structure and physiochemical properties of KCNQ1 potassium channels that performs comparably or better than algorithms using only on PSSM-based evolutionary features. These biophysical features highlight the structure-function relationships that govern protein stability, function, and regulation. The input sensitivity algorithm incorporates the roles of hydrophobicity, polarizability, and functional densities on key functional parameters of the KCNQ1 channel. Inclusion of the biophysical features outperforms exclusive use of PSSM-based evolutionary features in predicting activation voltage dependence and deactivation time. As AI is increasingly applied to problems in biology, biophysical understanding will be critical with respect to 'explainable AI', i.e., understanding the relation of sequence, structure, and function of proteins. Our model is available at www.kcnq1predict.org.

Published

2022

7. Rosetta FlexPepDock to predict peptide-MHC binding: An approach for non-canonical amino acids.

Author

Nathaniel Bloodworth, Natália Ruggeri Barbaro, Rocco Moretti, David G Harrison, and Jens Meiler

Subjects

Medicine, Science

Abstract

Computation methods that predict the binding of peptides to MHC-I are important tools for screening and identifying immunogenic antigens and have the potential to accelerate vaccine and drug development. However, most available tools are sequence-based and optimized only for peptides containing the twenty canonical amino acids. This omits a large number of peptides containing non-canonical amino acids (NCAA), or residues that undergo varied post-translational modifications such as glycosylation or phosphorylation. These modifications fundamentally alter peptide immunogenicity. Similarly, existing structure-based methods are biased towards canonical peptide backbone structures, which may or may not be preserved when NCAAs are present. Rosetta FlexPepDock ab-initio is a structure-based computational protocol able to evaluate peptide-receptor interaction where no prior information of the peptide backbone is known. We benchmarked FlexPepDock ab-initio for docking canonical peptides to MHC-I, and illustrate for the first time the method's ability to accurately model MHC-I bound epitopes containing NCAAs. FlexPepDock ab-initio protocol was able to recapitulate near-native structures (≤1.5Å) in the top lowest-energy models for 20 out of 25 cases in our initial benchmark. Using known experimental binding affinities of twenty peptides derived from an influenza-derived peptide, we showed that FlexPepDock protocol is able to predict relative binding affinity as Rosetta energies correlate well with experimental values (r = 0.59, p = 0.006). ROC analysis revealed 80% true positive and a 40% false positive rate, with a prediction power of 93%. Finally, we demonstrate the protocol's ability to accurately recapitulate HLA-A*02:01 bound phosphopeptide backbone structures and relative binding affinity changes, the theoretical structure of the lymphocytic choriomeningitis derived glycosylated peptide GP392 bound to MHC-I H-2Db, and isolevuglandin-adducted peptides. The ability to use non-canonical amino acids in the Rosetta FlexPepDock protocol may provide useful insight into critical amino acid positions where the post-translational modification modulates immunologic responses.

Published

2022

8. PlaceWaters: Real-time, explicit interface water sampling during Rosetta ligand docking

Author

Shannon T. Smith, Laura Shub, and Jens Meiler

Subjects

Medicine, Science

Abstract

Water molecules at the protein-small molecule interface often form hydrogen bonds with both the small molecule ligand and the protein, affecting the structural integrity and energetics of a binding event. The inclusion of these ‘bridging waters’ has been shown to improve the accuracy of predicted docked structures; however, due to increased computational costs, this step is typically omitted in ligand docking simulations. In this study, we introduce a resource-efficient, Rosetta-based protocol named “PlaceWaters” to predict the location of explicit interface bridging waters during a ligand docking simulation. In contrast to other explicit water methods, this protocol is independent of knowledge of number and location of crystallographic waters in homologous structures. We test this method on a diverse protein-small molecule benchmark set in comparison to other Rosetta-based protocols. Our results suggest that this coarse-grained, structure-based approach quickly and accurately predicts the location of bridging waters, improving our ability to computationally screen drug candidates.

Published

2022

9. Computational redesign of a fluorogen activating protein with Rosetta

Author

Nina G. Bozhanova, Joel M. Harp, Brian J. Bender, Alexey S. Gavrikov, Dmitry A. Gorbachev, Mikhail S. Baranov, Christina B. Mercado, Xuan Zhang, Konstantin A. Lukyanov, Alexander S. Mishin, and Jens Meiler

Subjects

Biology (General), QH301-705.5

Abstract

The use of unnatural fluorogenic molecules widely expands the pallet of available genetically encoded fluorescent imaging tools through the design of fluorogen activating proteins (FAPs). While there is already a handful of such probes available, each of them went through laborious cycles of in vitro screening and selection. Computational modeling approaches are evolving incredibly fast right now and are demonstrating great results in many applications, including de novo protein design. It suggests that the easier task of fine-tuning the fluorogen-binding properties of an already functional protein in silico should be readily achievable. To test this hypothesis, we used Rosetta for computational ligand docking followed by protein binding pocket redesign to further improve the previously described FAP DiB1 that is capable of binding to a BODIPY-like dye M739. Despite an inaccurate initial docking of the chromophore, the incorporated mutations nevertheless improved multiple photophysical parameters as well as the overall performance of the tag. The designed protein, DiB-RM, shows higher brightness, localization precision, and apparent photostability in protein-PAINT super-resolution imaging compared to its parental variant DiB1. Moreover, DiB-RM can be cleaved to obtain an efficient split system with enhanced performance compared to a parental DiB-split system. The possible reasons for the inaccurate ligand binding pose prediction and its consequence on the outcome of the design experiment are further discussed. Author summary Computational approaches have recently made significant progress in the protein engineering field evolving from a tool for helping experimentalists to prioritize or short-list mutations for testing to being capable of making fully reliable predictions. However, not all the fields of protein modeling are evolving at a similar pace. That is why evaluating the capabilities of computational tools on different tasks is important to provide other scientists with up-to-date information on the state of the field. Here we tested the performance of Rosetta (one of the leading macromolecule modeling tools) in improving small molecule-binding proteins. We successfully redesigned a fluorogen binding protein DiB1 –a protein that binds a non-fluorescent molecule and enforces its fluorescence in the obtained complex–for improved brightness and better performance in super-resolution imaging. Our results suggest that such tasks can be already achieved without laborious library screenings. However, the flexibility of the proteins might still be underestimated during standard modeling protocols and should be closely evaluated.

Published

2021

10. Methodology for rigorous modeling of protein conformational changes by Rosetta using DEER distance restraints.

Author

Diego Del Alamo, Kevin L Jagessar, Jens Meiler, and Hassane S Mchaourab

Subjects

Biology (General), QH301-705.5

Abstract

We describe an approach for integrating distance restraints from Double Electron-Electron Resonance (DEER) spectroscopy into Rosetta with the purpose of modeling alternative protein conformations from an initial experimental structure. Fundamental to this approach is a multilateration algorithm that harnesses sets of interconnected spin label pairs to identify optimal rotamer ensembles at each residue that fit the DEER decay in the time domain. Benchmarked relative to data analysis packages, the algorithm yields comparable distance distributions with the advantage that fitting the DEER decay and rotamer ensemble optimization are coupled. We demonstrate this approach by modeling the protonation-dependent transition of the multidrug transporter PfMATE to an inward facing conformation with a deviation to the experimental structure of less than 2Å Cα RMSD. By decreasing spin label rotamer entropy, this approach engenders more accurate Rosetta models that are also more closely clustered, thus setting the stage for more robust modeling of protein conformational changes.

Published

2021

11. Prediction of amphipathic helix-membrane interactions with Rosetta.

Author

Alican Gulsevin and Jens Meiler

Subjects

Biology (General), QH301-705.5

Abstract

Amphipathic helices have hydrophobic and hydrophilic/charged residues situated on opposite faces of the helix. They can anchor peripheral membrane proteins to the membrane, be attached to integral membrane proteins, or exist as independent peptides. Despite the widespread presence of membrane-interacting amphipathic helices, there is no computational tool within Rosetta to model their interactions with membranes. In order to address this need, we developed the AmphiScan protocol with PyRosetta, which runs a grid search to find the most favorable position of an amphipathic helix with respect to the membrane. The performance of the algorithm was tested in benchmarks with the RosettaMembrane, ref2015_memb, and franklin2019 score functions on six engineered and 44 naturally-occurring amphipathic helices using membrane coordinates from the OPM and PDBTM databases, OREMPRO server, and MD simulations for comparison. The AmphiScan protocol predicted the coordinates of amphipathic helices within less than 3Å of the reference structures and identified membrane-embedded residues with a Matthews Correlation Constant (MCC) of up to 0.57. Overall, AmphiScan stands as fast, accurate, and highly-customizable protocol that can be pipelined with other Rosetta and Python applications.

Published

2021

12. Rosetta design with co-evolutionary information retains protein function.

Author

Samuel Schmitz, Moritz Ertelt, Rainer Merkl, and Jens Meiler

Subjects

Biology (General), QH301-705.5

Abstract

Computational protein design has the ambitious goal of crafting novel proteins that address challenges in biology and medicine. To overcome these challenges, the computational protein modeling suite Rosetta has been tailored to address various protein design tasks. Recently, statistical methods have been developed that identify correlated mutations between residues in a multiple sequence alignment of homologous proteins. These subtle inter-dependencies in the occupancy of residue positions throughout evolution are crucial for protein function, but we found that three current Rosetta design approaches fail to recover these co-evolutionary couplings. Thus, we developed the Rosetta method ResCue (residue-coupling enhanced) that leverages co-evolutionary information to favor sequences which recapitulate correlated mutations, as observed in nature. To assess the protocols via recapitulation designs, we compiled a benchmark of ten proteins each represented by two, structurally diverse states. We could demonstrate that ResCue designed sequences with an average sequence recovery rate of 70%, whereas three other protocols reached not more than 50%, on average. Our approach had higher recovery rates also for functionally important residues, which were studied in detail. This improvement has only a minor negative effect on the fitness of the designed sequences as assessed by Rosetta energy. In conclusion, our findings support the idea that informing protocols with co-evolutionary signals helps to design stable and native-like proteins that are compatible with the different conformational states required for a complex function.

Published

2021

13. Improving homology modeling from low-sequence identity templates in Rosetta: A case study in GPCRs.

Author

Brian Joseph Bender, Brennica Marlow, and Jens Meiler

Subjects

Biology (General), QH301-705.5

Abstract

As sequencing methodologies continue to advance, the availability of protein sequences far outpaces the ability of structure determination. Homology modeling is used to bridge this gap but relies on high-identity templates for accurate model building. G-protein coupled receptors (GPCRs) represent a significant target class for pharmaceutical therapies in which homology modeling could fill the knowledge gap for structure-based drug design. To date, only about 17% of druggable GPCRs have had their structures characterized at atomic resolution. However, modeling of the remaining 83% is hindered by the low sequence identity between receptors. Here we test key inputs in the model building process using GPCRs as a focus to improve the pipeline in two critical ways: Firstly, we use a blended sequence- and structure-based alignment that accounts for structure conservation in loop regions. Secondly, by merging multiple template structures into one comparative model, the best possible template for every region of a target can be used expanding the conformational space sampled in a meaningful way. This optimization allows for accurate modeling of receptors using templates as low as 20% sequence identity, which accounts for nearly the entire druggable space of GPCRs. A model database of all non-odorant GPCRs is made available at www.rosettagpcr.org. Additionally, all protocols are made available with insights into modifications that may improve accuracy at new targets.

Published

2020

14. Better together: Elements of successful scientific software development in a distributed collaborative community.

Author

Julia Koehler Leman, Brian D Weitzner, P Douglas Renfrew, Steven M Lewis, Rocco Moretti, Andrew M Watkins, Vikram Khipple Mulligan, Sergey Lyskov, Jared Adolf-Bryfogle, Jason W Labonte, Justyna Krys, RosettaCommons Consortium, Christopher Bystroff, William Schief, Dominik Gront, Ora Schueler-Furman, David Baker, Philip Bradley, Roland Dunbrack, Tanja Kortemme, Andrew Leaver-Fay, Charlie E M Strauss, Jens Meiler, Brian Kuhlman, Jeffrey J Gray, and Richard Bonneau

Subjects

Biology (General), QH301-705.5

Abstract

Many scientific disciplines rely on computational methods for data analysis, model generation, and prediction. Implementing these methods is often accomplished by researchers with domain expertise but without formal training in software engineering or computer science. This arrangement has led to underappreciation of sustainability and maintainability of scientific software tools developed in academic environments. Some software tools have avoided this fate, including the scientific library Rosetta. We use this software and its community as a case study to show how modern software development can be accomplished successfully, irrespective of subject area. Rosetta is one of the largest software suites for macromolecular modeling, with 3.1 million lines of code and many state-of-the-art applications. Since the mid 1990s, the software has been developed collaboratively by the RosettaCommons, a community of academics from over 60 institutions worldwide with diverse backgrounds including chemistry, biology, physiology, physics, engineering, mathematics, and computer science. Developing this software suite has provided us with more than two decades of experience in how to effectively develop advanced scientific software in a global community with hundreds of contributors. Here we illustrate the functioning of this development community by addressing technical aspects (like version control, testing, and maintenance), community-building strategies, diversity efforts, software dissemination, and user support. We demonstrate how modern computational research can thrive in a distributed collaborative community. The practices described here are independent of subject area and can be readily adopted by other software development communities.

Published

2020

15. Multi-state design of flexible proteins predicts sequences optimal for conformational change.

Author

Marion F Sauer, Alexander M Sevy, James E Crowe, and Jens Meiler

Subjects

Biology (General), QH301-705.5

Abstract

Computational protein design of an ensemble of conformations for one protein-i.e., multi-state design-determines the side chain identity by optimizing the energetic contributions of that side chain in each of the backbone conformations. Sampling the resulting large sequence-structure search space limits the number of conformations and the size of proteins in multi-state design algorithms. Here, we demonstrated that the REstrained CONvergence (RECON) algorithm can simultaneously evaluate the sequence of large proteins that undergo substantial conformational changes. Simultaneous optimization of side chain conformations across all conformations increased sequence conservation when compared to single-state designs in all cases. More importantly, the sequence space sampled by RECON MSD resembled the evolutionary sequence space of flexible proteins, particularly when confined to predicting the mutational preferences of limited common ancestral descent, such as in the case of influenza type A hemagglutinin. Additionally, we found that sequence positions which require substantial changes in their local environment across an ensemble of conformations are more likely to be conserved. These increased conservation rates are better captured by RECON MSD over multiple conformations and thus multiple local residue environments during design. To quantify this rewiring of contacts at a certain position in sequence and structure, we introduced a new metric designated 'contact proximity deviation' that enumerates contact map changes. This measure allows mapping of global conformational changes into local side chain proximity adjustments, a property not captured by traditional global similarity metrics such as RMSD or local similarity metrics such as changes in φ and ψ angles.

Published

2020

16. Assessing multiple score functions in Rosetta for drug discovery.

Author

Shannon T Smith and Jens Meiler

Subjects

Medicine, Science

Abstract

Rosetta is a computational software suite containing algorithms for a wide variety of macromolecular structure prediction and design tasks including small molecule protocols commonly used in drug discovery or enzyme design. Here, we benchmark RosettaLigand score functions and protocols in comparison to results of other software recently published in the Comparative Assessment of Score Functions (CASF-2016). The CASF-2016 benchmark covers a wide variety of tests including scoring and ranking multiple compounds against a target, ligand docking of a small molecule to a target, and virtual screening to extract binders from a compound library. Direct comparison to the score functions provided by CASF-2016 results shows that the original RosettaLigand score function ranks among the top software for scoring, ranking, docking and screening tests. Most notably, the RosettaLigand score function ranked 2/34 among other report score functions in CASF-2016. We additionally perform a ligand docking test with full sampling to mimic typical use cases. Despite improved performance of newer score functions in canonical protein structure prediction and design, we demonstrate here that more recent Rosetta score functions have reduced performance across all small molecule benchmarks. The tests described here have also been uploaded to the Rosetta scientific benchmarking server and will be run weekly to track performance as the code is continually being developed.

Published

2020

17. Upgraded molecular models of the human KCNQ1 potassium channel.

Author

Georg Kuenze, Amanda M Duran, Hope Woods, Kathryn R Brewer, Eli Fritz McDonald, Carlos G Vanoye, Alfred L George, Charles R Sanders, and Jens Meiler

Subjects

Medicine, Science

Abstract

The voltage-gated potassium channel KCNQ1 (KV7.1) assembles with the KCNE1 accessory protein to generate the slow delayed rectifier current, IKS, which is critical for membrane repolarization as part of the cardiac action potential. Loss-of-function (LOF) mutations in KCNQ1 are the most common cause of congenital long QT syndrome (LQTS), type 1 LQTS, an inherited genetic predisposition to cardiac arrhythmia and sudden cardiac death. A detailed structural understanding of KCNQ1 is needed to elucidate the molecular basis for KCNQ1 LOF in disease and to enable structure-guided design of new anti-arrhythmic drugs. In this work, advanced structural models of human KCNQ1 in the resting/closed and activated/open states were developed by Rosetta homology modeling guided by newly available experimentally-based templates: X. leavis KCNQ1 and various resting voltage sensor structures. Using molecular dynamics (MD) simulations, the capacity of the models to describe experimentally established channel properties including state-dependent voltage sensor gating charge interactions and pore conformations, PIP2 binding sites, and voltage sensor-pore domain interactions were validated. Rosetta energy calculations were applied to assess the utility of each model in interpreting mutation-evoked KCNQ1 dysfunction by predicting the change in protein thermodynamic stability for 50 experimentally characterized KCNQ1 variants with mutations located in the voltage-sensing domain. Energetic destabilization was successfully predicted for folding-defective KCNQ1 LOF mutants whereas wild type-like mutants exhibited no significant energetic frustrations, which supports growing evidence that mutation-induced protein destabilization is an especially common cause of KCNQ1 dysfunction. The new KCNQ1 Rosetta models provide helpful tools in the study of the structural basis for KCNQ1 function and can be used to generate hypotheses to explain KCNQ1 dysfunction.

Published

2019

18. Integrating linear optimization with structural modeling to increase HIV neutralization breadth.

Author

Alexander M Sevy, Swetasudha Panda, James E Crowe, Jens Meiler, and Yevgeniy Vorobeychik

Subjects

Biology (General), QH301-705.5

Abstract

Computational protein design has been successful in modeling fixed backbone proteins in a single conformation. However, when modeling large ensembles of flexible proteins, current methods in protein design have been insufficient. Large barriers in the energy landscape are difficult to traverse while redesigning a protein sequence, and as a result current design methods only sample a fraction of available sequence space. We propose a new computational approach that combines traditional structure-based modeling using the Rosetta software suite with machine learning and integer linear programming to overcome limitations in the Rosetta sampling methods. We demonstrate the effectiveness of this method, which we call BROAD, by benchmarking the performance on increasing predicted breadth of anti-HIV antibodies. We use this novel method to increase predicted breadth of naturally-occurring antibody VRC23 against a panel of 180 divergent HIV viral strains and achieve 100% predicted binding against the panel. In addition, we compare the performance of this method to state-of-the-art multistate design in Rosetta and show that we can outperform the existing method significantly. We further demonstrate that sequences recovered by this method recover known binding motifs of broadly neutralizing anti-HIV antibodies. Finally, our approach is general and can be extended easily to other protein systems. Although our modeled antibodies were not tested in vitro, we predict that these variants would have greatly increased breadth compared to the wild-type antibody.

Published

2018

19. Membrane protein contact and structure prediction using co-evolution in conjunction with machine learning.

Author

Pedro L Teixeira, Jeff L Mendenhall, Sten Heinze, Brian Weiner, Marcin J Skwark, and Jens Meiler

Subjects

Medicine, Science

Abstract

De novo membrane protein structure prediction is limited to small proteins due to the conformational search space quickly expanding with length. Long-range contacts (24+ amino acid separation)-residue positions distant in sequence, but in close proximity in the structure, are arguably the most effective way to restrict this conformational space. Inverse methods for co-evolutionary analysis predict a global set of position-pair couplings that best explain the observed amino acid co-occurrences, thus distinguishing between evolutionarily explained co-variances and these arising from spurious transitive effects. Here, we show that applying machine learning approaches and custom descriptors improves evolutionary contact prediction accuracy, resulting in improvement of average precision by 6 percentage points for the top 1L non-local contacts. Further, we demonstrate that predicted contacts improve protein folding with BCL::Fold. The mean RMSD100 metric for the top 10 models folded was reduced by an average of 2 Å for a benchmark of 25 membrane proteins.

Published

2017

20. Discovery of Small-Molecule Modulators of the Human Y4 Receptor.

Author

Gregory Sliwoski, Mario Schubert, Jan Stichel, David Weaver, Annette G Beck-Sickinger, and Jens Meiler

Subjects

Medicine, Science

Abstract

The human neuropeptide Y4 receptor (Y4R) and its native ligand, pancreatic polypeptide, are critically involved in the regulation of human metabolism by signaling satiety and regulating food intake, as well as increasing energy expenditure. Thus, this receptor represents a putative target for treatment of obesity. With respect to new approaches to treat complex metabolic disorders, especially in multi-receptor systems, small molecule allosteric modulators have been in the focus of research in the last years. However, no positive allosteric modulators or agonists of the Y4R have been described so far. In this study, small molecule compounds derived from the Niclosamide scaffold were identified by high-throughput screening to increase Y4R activity. Compounds were characterized for their potency and their effects at the human Y4R and as well as their selectivity towards Y1R, Y2R and Y5R. These compounds provide a structure-activity relationship profile around this common scaffold and lay the groundwork for hit-to-lead optimization and characterization of positive allosteric modulators of the Y4R.

Published

2016

21. CASP11--An Evaluation of a Modular BCL::Fold-Based Protein Structure Prediction Pipeline.

Author

Axel W Fischer, Sten Heinze, Daniel K Putnam, Bian Li, James C Pino, Yan Xia, Carlos F Lopez, and Jens Meiler

Subjects

Medicine, Science

Abstract

In silico prediction of a protein's tertiary structure remains an unsolved problem. The community-wide Critical Assessment of Protein Structure Prediction (CASP) experiment provides a double-blind study to evaluate improvements in protein structure prediction algorithms. We developed a protein structure prediction pipeline employing a three-stage approach, consisting of low-resolution topology search, high-resolution refinement, and molecular dynamics simulation to predict the tertiary structure of proteins from the primary structure alone or including distance restraints either from predicted residue-residue contacts, nuclear magnetic resonance (NMR) nuclear overhauser effect (NOE) experiments, or mass spectroscopy (MS) cross-linking (XL) data. The protein structure prediction pipeline was evaluated in the CASP11 experiment on twenty regular protein targets as well as thirty-three 'assisted' protein targets, which also had distance restraints available. Although the low-resolution topology search module was able to sample models with a global distance test total score (GDT_TS) value greater than 30% for twelve out of twenty proteins, frequently it was not possible to select the most accurate models for refinement, resulting in a general decay of model quality over the course of the prediction pipeline. In this study, we provide a detailed overall analysis, study one target protein in more detail as it travels through the protein structure prediction pipeline, and evaluate the impact of limited experimental data.

Published

2016

22. Improving Loop Modeling of the Antibody Complementarity-Determining Region 3 Using Knowledge-Based Restraints.

Author

Jessica A Finn, Julia Koehler Leman, Jordan R Willis, Alberto Cisneros, James E Crowe, and Jens Meiler

Subjects

Medicine, Science

Abstract

Structural restrictions are present even in the most sequence diverse portions of antibodies, the complementary determining region (CDR) loops. Previous studies identified robust rules that define canonical structures for five of the six CDR loops, however the heavy chain CDR 3 (HCDR3) defies standard classification attempts. The HCDR3 loop can be subdivided into two domains referred to as the "torso" and the "head" domains and two major families of canonical torso structures have been identified; the more prevalent "bulged" and less frequent "non-bulged" torsos. In the present study, we found that Rosetta loop modeling of 28 benchmark bulged HCDR3 loops is improved with knowledge-based structural restraints developed from available antibody crystal structures in the PDB. These restraints restrict the sampling space Rosetta searches in the torso domain, limiting the φ and ψ angles of these residues to conformations that have been experimentally observed. The application of these restraints in Rosetta result in more native-like structure sampling and improved score-based differentiation of native-like HCDR3 models, significantly improving our ability to model antibody HCDR3 loops.

Published

2016

23. Design of Protein Multi-specificity Using an Independent Sequence Search Reduces the Barrier to Low Energy Sequences.

Author

Alexander M Sevy, Tim M Jacobs, James E Crowe, and Jens Meiler

Subjects

Biology (General), QH301-705.5

Abstract

Computational protein design has found great success in engineering proteins for thermodynamic stability, binding specificity, or enzymatic activity in a 'single state' design (SSD) paradigm. Multi-specificity design (MSD), on the other hand, involves considering the stability of multiple protein states simultaneously. We have developed a novel MSD algorithm, which we refer to as REstrained CONvergence in multi-specificity design (RECON). The algorithm allows each state to adopt its own sequence throughout the design process rather than enforcing a single sequence on all states. Convergence to a single sequence is encouraged through an incrementally increasing convergence restraint for corresponding positions. Compared to MSD algorithms that enforce (constrain) an identical sequence on all states the energy landscape is simplified, which accelerates the search drastically. As a result, RECON can readily be used in simulations with a flexible protein backbone. We have benchmarked RECON on two design tasks. First, we designed antibodies derived from a common germline gene against their diverse targets to assess recovery of the germline, polyspecific sequence. Second, we design "promiscuous", polyspecific proteins against all binding partners and measure recovery of the native sequence. We show that RECON is able to efficiently recover native-like, biologically relevant sequences in this diverse set of protein complexes.

Published

2015

24. Fully Flexible Docking of Medium Sized Ligand Libraries with RosettaLigand.

Author

Samuel DeLuca, Karen Khar, and Jens Meiler

Subjects

Medicine, Science

Abstract

RosettaLigand has been successfully used to predict binding poses in protein-small molecule complexes. However, the RosettaLigand docking protocol is comparatively slow in identifying an initial starting pose for the small molecule (ligand) making it unfeasible for use in virtual High Throughput Screening (vHTS). To overcome this limitation, we developed a new sampling approach for placing the ligand in the protein binding site during the initial 'low-resolution' docking step. It combines the translational and rotational adjustments to the ligand pose in a single transformation step. The new algorithm is both more accurate and more time-efficient. The docking success rate is improved by 10-15% in a benchmark set of 43 protein/ligand complexes, reducing the number of models that typically need to be generated from 1000 to 150. The average time to generate a model is reduced from 50 seconds to 10 seconds. As a result we observe an effective 30-fold speed increase, making RosettaLigand appropriate for docking medium sized ligand libraries. We demonstrate that this improved initial placement of the ligand is critical for successful prediction of an accurate binding position in the 'high-resolution' full atom refinement step.

Published

2015

25. Integrating solid-state NMR and computational modeling to investigate the structure and dynamics of membrane-associated ghrelin.

Author

Gerrit Vortmeier, Stephanie H DeLuca, Sylvia Els-Heindl, Constance Chollet, Holger A Scheidt, Annette G Beck-Sickinger, Jens Meiler, and Daniel Huster

Subjects

Medicine, Science

Abstract

The peptide hormone ghrelin activates the growth hormone secretagogue receptor 1a, also known as the ghrelin receptor. This 28-residue peptide is acylated at Ser3 and is the only peptide hormone in the human body that is lipid-modified by an octanoyl group. Little is known about the structure and dynamics of membrane-associated ghrelin. We carried out solid-state NMR studies of ghrelin in lipid vesicles, followed by computational modeling of the peptide using Rosetta. Isotropic chemical shift data of isotopically labeled ghrelin provide information about the peptide's secondary structure. Spin diffusion experiments indicate that ghrelin binds to membranes via its lipidated Ser3. Further, Phe4, as well as electrostatics involving the peptide's positively charged residues and lipid polar headgroups, contribute to the binding energy. Other than the lipid anchor, ghrelin is highly flexible and mobile at the membrane surface. This observation is supported by our predicted model ensemble, which is in good agreement with experimentally determined chemical shifts. In the final ensemble of models, residues 8-17 form an α-helix, while residues 21-23 and 26-27 often adopt a polyproline II helical conformation. These helices appear to assist the peptide in forming an amphipathic conformation so that it can bind to the membrane.

Published

2015

26. Analysis of nidogen-1/laminin γ1 interaction by cross-linking, mass spectrometry, and computational modeling reveals multiple binding modes.

Author

Philip Lössl, Knut Kölbel, Dirk Tänzler, David Nannemann, Christian H Ihling, Manuel V Keller, Marian Schneider, Frank Zaucke, Jens Meiler, and Andrea Sinz

Subjects

Medicine, Science

Abstract

We describe the detailed structural investigation of nidogen-1/laminin γ1 complexes using full-length nidogen-1 and a number of laminin γ1 variants. The interactions of nidogen-1 with laminin variants γ1 LEb2-4, γ1 LEb2-4 N836D, γ1 short arm, and γ1 short arm N836D were investigated by applying a combination of (photo-)chemical cross-linking, high-resolution mass spectrometry, and computational modeling. In addition, surface plasmon resonance and ELISA studies were used to determine kinetic constants of the nidogen-1/laminin γ1 interaction. Two complementary cross-linking strategies were pursued to analyze solution structures of laminin γ1 variants and nidogen-1. The majority of distance information was obtained with the homobifunctional amine-reactive cross-linker bis(sulfosuccinimidyl)glutarate. In a second approach, UV-induced cross-linking was performed after incorporation of the diazirine-containing unnatural amino acids photo-leucine and photo-methionine into laminin γ1 LEb2-4, laminin γ1 short arm, and nidogen-1. Our results indicate that Asn-836 within laminin γ1 LEb3 domain is not essential for complex formation. Cross-links between laminin γ1 short arm and nidogen-1 were found in all protein regions, evidencing several additional contact regions apart from the known interaction site. Computational modeling based on the cross-linking constraints indicates the existence of a conformational ensemble of both the individual proteins and the nidogen-1/laminin γ1 complex. This finding implies different modes of interaction resulting in several distinct protein-protein interfaces.

Published

2014

27. Human germline antibody gene segments encode polyspecific antibodies.

Author

Jordan R Willis, Bryan S Briney, Samuel L DeLuca, James E Crowe, and Jens Meiler

Subjects

Biology (General), QH301-705.5

Abstract

Structural flexibility in germline gene-encoded antibodies allows promiscuous binding to diverse antigens. The binding affinity and specificity for a particular epitope typically increase as antibody genes acquire somatic mutations in antigen-stimulated B cells. In this work, we investigated whether germline gene-encoded antibodies are optimal for polyspecificity by determining the basis for recognition of diverse antigens by antibodies encoded by three VH gene segments. Panels of somatically mutated antibodies encoded by a common VH gene, but each binding to a different antigen, were computationally redesigned to predict antibodies that could engage multiple antigens at once. The Rosetta multi-state design process predicted antibody sequences for the entire heavy chain variable region, including framework, CDR1, and CDR2 mutations. The predicted sequences matched the germline gene sequences to a remarkable degree, revealing by computational design the residues that are predicted to enable polyspecificity, i.e., binding of many unrelated antigens with a common sequence. The process thereby reverses antibody maturation in silico. In contrast, when designing antibodies to bind a single antigen, a sequence similar to that of the mature antibody sequence was returned, mimicking natural antibody maturation in silico. We demonstrated that the Rosetta computational design algorithm captures important aspects of antibody/antigen recognition. While the hypervariable region CDR3 often mediates much of the specificity of mature antibodies, we identified key positions in the VH gene encoding CDR1, CDR2, and the immunoglobulin framework that are critical contributors for polyspecificity in germline antibodies. Computational design of antibodies capable of binding multiple antigens may allow the rational design of antibodies that retain polyspecificity for diverse epitope binding.

Published

2013

28. Human rotavirus VP6-specific antibodies mediate intracellular neutralization by binding to a quaternary structure in the transcriptional pore.

Author

Mohammed S Aiyegbo, Gopal Sapparapu, Benjamin W Spiller, Ilyas M Eli, Dewight R Williams, Robert Kim, David E Lee, Tong Liu, Sheng Li, Virgil L Woods, David P Nannemann, Jens Meiler, Phoebe L Stewart, and James E Crowe

Subjects

Medicine, Science

Abstract

Several live attenuated rotavirus (RV) vaccines have been licensed, but the mechanisms of protective immunity are still poorly understood. The most frequent human B cell response is directed to the internal protein VP6 on the surface of double-layered particles, which is normally exposed only in the intracellular environment. Here, we show that the canonical VP6 antibodies secreted by humans bind to such particles and inhibit viral transcription. Polymeric IgA RV antibodies mediated an inhibitory effect against virus replication inside cells during IgA transcytosis. We defined the recognition site on VP6 as a quaternary epitope containing a high density of charged residues. RV human mAbs appear to bind to a negatively-charged patch on the surface of the Type I channel in the transcriptionally active particle, and they sterically block the channel. This unique mucosal mechanism of viral neutralization, which is not apparent from conventional immunoassays, may contribute significantly to human immunity to RV.

Published

2013

29. RosettaEPR: rotamer library for spin label structure and dynamics.

Author

Nathan S Alexander, Richard A Stein, Hanane A Koteiche, Kristian W Kaufmann, Hassane S McHaourab, and Jens Meiler

Subjects

Medicine, Science

Abstract

An increasingly used parameter in structural biology is the measurement of distances between spin labels bound to a protein. One limitation to these measurements is the unknown position of the spin label relative to the protein backbone. To overcome this drawback, we introduce a rotamer library of the methanethiosulfonate spin label (MTSSL) into the protein modeling program Rosetta. Spin label rotamers were derived from conformations observed in crystal structures of spin labeled T4 lysozyme and previously published molecular dynamics simulations. Rosetta's ability to accurately recover spin label conformations and EPR measured distance distributions was evaluated against 19 experimentally determined MTSSL labeled structures of T4 lysozyme and the membrane protein LeuT and 73 distance distributions from T4 lysozyme and the membrane protein MsbA. For a site in the core of T4 lysozyme, the correct spin label conformation (Χ1 and Χ2) is recovered in 99.8% of trials. In surface positions 53% of the trajectories agree with crystallized conformations in Χ1 and Χ2. This level of recovery is on par with Rosetta performance for the 20 natural amino acids. In addition, Rosetta predicts the distance between two spin labels with a mean error of 4.4 Å. The width of the experimental distance distribution, which reflects the flexibility of the two spin labels, is predicted with a mean error of 1.3 Å. RosettaEPR makes full-atom spin label modeling available to a wide scientific community in conjunction with the powerful suite of modeling methods within Rosetta.

Published

2013

30. Octarellin VI: using rosetta to design a putative artificial (β/α)8 protein.

Author

Maximiliano Figueroa, Nicolas Oliveira, Annabelle Lejeune, Kristian W Kaufmann, Brent M Dorr, André Matagne, Joseph A Martial, Jens Meiler, and Cécile Van de Weerdt

Subjects

Medicine, Science

Abstract

The computational protein design protocol Rosetta has been applied successfully to a wide variety of protein engineering problems. Here the aim was to test its ability to design de novo a protein adopting the TIM-barrel fold, whose formation requires about twice as many residues as in the largest proteins successfully designed de novo to date. The designed protein, Octarellin VI, contains 216 residues. Its amino acid composition is similar to that of natural TIM-barrel proteins. When produced and purified, it showed a far-UV circular dichroism spectrum characteristic of folded proteins, with α-helical and β-sheet secondary structure. Its stable tertiary structure was confirmed by both tryptophan fluorescence and circular dichroism in the near UV. It proved heat stable up to 70°C. Dynamic light scattering experiments revealed a unique population of particles averaging 4 nm in diameter, in good agreement with our model. Although these data suggest the successful creation of an artificial α/β protein of more than 200 amino acids, Octarellin VI shows an apparent noncooperative chemical unfolding and low solubility.

Published

2013

31. Assessment and challenges of ligand docking into comparative models of G-protein coupled receptors.

Author

Elizabeth Dong Nguyen, Christoffer Norn, Thomas M Frimurer, and Jens Meiler

Subjects

Medicine, Science

Abstract

The rapidly increasing number of high-resolution X-ray structures of G-protein coupled receptors (GPCRs) creates a unique opportunity to employ comparative modeling and docking to provide valuable insight into the function and ligand binding determinants of novel receptors, to assist in virtual screening and to design and optimize drug candidates. However, low sequence identity between receptors, conformational flexibility, and chemical diversity of ligands present an enormous challenge to molecular modeling approaches. It is our hypothesis that rapid Monte-Carlo sampling of protein backbone and side-chain conformational space with Rosetta can be leveraged to meet this challenge. This study performs unbiased comparative modeling and docking methodologies using 14 distinct high-resolution GPCRs and proposes knowledge-based filtering methods for improvement of sampling performance and identification of correct ligand-receptor interactions. On average, top ranked receptor models built on template structures over 50% sequence identity are within 2.9 Å of the experimental structure, with an average root mean square deviation (RMSD) of 2.2 Å for the transmembrane region and 5 Å for the second extracellular loop. Furthermore, these models are consistently correlated with low Rosetta energy score. To predict their binding modes, ligand conformers of the 14 ligands co-crystalized with the GPCRs were docked against the top ranked comparative models. In contrast to the comparative models themselves, however, it remains difficult to unambiguously identify correct binding modes by score alone. On average, sampling performance was improved by 10(3) fold over random using knowledge-based and energy-based filters. In assessing the applicability of experimental constraints, we found that sampling performance is increased by one order of magnitude for every 10 residues known to contact the ligand. Additionally, in the case of DOR, knowledge of a single specific ligand-protein contact improved sampling efficiency 7 fold. These findings offer specific guidelines which may lead to increased success in determining receptor-ligand complexes.

Published

2013

32. Towards ligand docking including explicit interface water molecules.

Author

Gordon Lemmon and Jens Meiler

Subjects

Medicine, Science

Abstract

Small molecule docking predicts the interaction of a small molecule ligand with a protein at atomic-detail accuracy including position and conformation the ligand but also conformational changes of the protein upon ligand binding. While successful in the majority of cases, docking algorithms including RosettaLigand fail in some cases to predict the correct protein/ligand complex structure. In this study we show that simultaneous docking of explicit interface water molecules greatly improves Rosetta's ability to distinguish correct from incorrect ligand poses. This result holds true for both protein-centric water docking wherein waters are located relative to the protein binding site and ligand-centric water docking wherein waters move with the ligand during docking. Protein-centric docking is used to model 99 HIV-1 protease/protease inhibitor structures. We find protease inhibitor placement improving at a ratio of 9:1 when one critical interface water molecule is included in the docking simulation. Ligand-centric docking is applied to 341 structures from the CSAR benchmark of diverse protein/ligand complexes [1]. Across this diverse dataset we see up to 56% recovery of failed docking studies, when waters are included in the docking simulation.

Published

2013

33. BCL::Fold--de novo prediction of complex and large protein topologies by assembly of secondary structure elements.

Author

Mert Karakaş, Nils Woetzel, Rene Staritzbichler, Nathan Alexander, Brian E Weiner, and Jens Meiler

Subjects

Medicine, Science

Abstract

Computational de novo protein structure prediction is limited to small proteins of simple topology. The present work explores an approach to extend beyond the current limitations through assembling protein topologies from idealized α-helices and β-strands. The algorithm performs a Monte Carlo Metropolis simulated annealing folding simulation. It optimizes a knowledge-based potential that analyzes radius of gyration, β-strand pairing, secondary structure element (SSE) packing, amino acid pair distance, amino acid environment, contact order, secondary structure prediction agreement and loop closure. Discontinuation of the protein chain favors sampling of non-local contacts and thereby creation of complex protein topologies. The folding simulation is accelerated through exclusion of flexible loop regions further reducing the size of the conformational search space. The algorithm is benchmarked on 66 proteins with lengths between 83 and 293 amino acids. For 61 out of these proteins, the best SSE-only models obtained have an RMSD100 below 8.0 Å and recover more than 20% of the native contacts. The algorithm assembles protein topologies with up to 215 residues and a relative contact order of 0.46. The method is tailored to be used in conjunction with low-resolution or sparse experimental data sets which often provide restraints for regions of defined secondary structure.

Published

2012

34. Using RosettaLigand for small molecule docking into comparative models.

Author

Kristian W Kaufmann and Jens Meiler

Subjects

Medicine, Science

Abstract

Computational small molecule docking into comparative models of proteins is widely used to query protein function and in the development of small molecule therapeutics. We benchmark RosettaLigand docking into comparative models for nine proteins built during CASP8 that contain ligands. We supplement the study with 21 additional protein/ligand complexes to cover a wider space of chemotypes. During a full docking run in 21 of the 30 cases, RosettaLigand successfully found a native-like binding mode among the top ten scoring binding modes. From the benchmark cases we find that careful template selection based on ligand occupancy provides the best chance of success while overall sequence identity between template and target do not appear to improve results. We also find that binding energy normalized by atom number is often less than -0.4 in native-like binding modes.

Published

2012

35. BCL::Score--knowledge based energy potentials for ranking protein models represented by idealized secondary structure elements.

Author

Nils Woetzel, Mert Karakaş, Rene Staritzbichler, Ralf Müller, Brian E Weiner, and Jens Meiler

Subjects

Medicine, Science

Abstract

The topology of most experimentally determined protein domains is defined by the relative arrangement of secondary structure elements, i.e. α-helices and β-strands, which make up 50-70% of the sequence. Pairing of β-strands defines the topology of β-sheets. The packing of side chains between α-helices and β-sheets defines the majority of the protein core. Often, limited experimental datasets restrain the position of secondary structure elements while lacking detail with respect to loop or side chain conformation. At the same time the regular structure and reduced flexibility of secondary structure elements make these interactions more predictable when compared to flexible loops and side chains. To determine the topology of the protein in such settings, we introduce a tailored knowledge-based energy function that evaluates arrangement of secondary structure elements only. Based on the amino acid C(β) atom coordinates within secondary structure elements, potentials for amino acid pair distance, amino acid environment, secondary structure element packing, β-strand pairing, loop length, radius of gyration, contact order and secondary structure prediction agreement are defined. Separate penalty functions exclude conformations with clashes between amino acids or secondary structure elements and loops that cannot be closed. Each individual term discriminates for native-like protein structures. The composite potential significantly enriches for native-like models in three different databases of 10,000-12,000 protein models in 80-94% of the cases. The corresponding application, "BCL::ScoreProtein," is available at www.meilerlab.org.

Published

2012

36. RosettaScripts: a scripting language interface to the Rosetta macromolecular modeling suite.

Author

Sarel J Fleishman, Andrew Leaver-Fay, Jacob E Corn, Eva-Maria Strauch, Sagar D Khare, Nobuyasu Koga, Justin Ashworth, Paul Murphy, Florian Richter, Gordon Lemmon, Jens Meiler, and David Baker

Subjects

Medicine, Science

Abstract

Macromolecular modeling and design are increasingly useful in basic research, biotechnology, and teaching. However, the absence of a user-friendly modeling framework that provides access to a wide range of modeling capabilities is hampering the wider adoption of computational methods by non-experts. RosettaScripts is an XML-like language for specifying modeling tasks in the Rosetta framework. RosettaScripts provides access to protocol-level functionalities, such as rigid-body docking and sequence redesign, and allows fast testing and deployment of complex protocols without need for modifying or recompiling the underlying C++ code. We illustrate these capabilities with RosettaScripts protocols for the stabilization of proteins, the generation of computationally constrained libraries for experimental selection of higher-affinity binding proteins, loop remodeling, small-molecule ligand docking, design of ligand-binding proteins, and specificity redesign in DNA-binding proteins.

Published

2011

37. A correspondence between solution-state dynamics of an individual protein and the sequence and conformational diversity of its family.

Author

Gregory D Friedland, Nils-Alexander Lakomek, Christian Griesinger, Jens Meiler, and Tanja Kortemme

Subjects

Biology (General), QH301-705.5

Abstract

Conformational ensembles are increasingly recognized as a useful representation to describe fundamental relationships between protein structure, dynamics and function. Here we present an ensemble of ubiquitin in solution that is created by sampling conformational space without experimental information using "Backrub" motions inspired by alternative conformations observed in sub-Angstrom resolution crystal structures. Backrub-generated structures are then selected to produce an ensemble that optimizes agreement with nuclear magnetic resonance (NMR) Residual Dipolar Couplings (RDCs). Using this ensemble, we probe two proposed relationships between properties of protein ensembles: (i) a link between native-state dynamics and the conformational heterogeneity observed in crystal structures, and (ii) a relation between dynamics of an individual protein and the conformational variability explored by its natural family. We show that the Backrub motional mechanism can simultaneously explore protein native-state dynamics measured by RDCs, encompass the conformational variability present in ubiquitin complex structures and facilitate sampling of conformational and sequence variability matching those occurring in the ubiquitin protein family. Our results thus support an overall relation between protein dynamics and conformational changes enabling sequence changes in evolution. More practically, the presented method can be applied to improve protein design predictions by accounting for intrinsic native-state dynamics.

Published

2009

38. Methodology for rigorous modeling of protein conformational changes by Rosetta using DEER distance restraints

Author

Jens Meiler, Kevin L. Jagessar, Diego del Alamo, and Hassane S. Mchaourab

Subjects

0301 basic medicine, Protein Structure Comparison, Models, Molecular, Protein Conformation, Distance Measurement, 01 natural sciences, Resonance (particle physics), Biochemistry, Alternative protein, Mathematical and Statistical Techniques, Macromolecular Structure Analysis, Bacteriophage T4, Biology (General), Spin label, Conformational isomerism, Physics, Mammals, Measurement, Quantitative Biology::Biomolecules, Crystallography, Ecology, Entropy (statistical thermodynamics), Applied Mathematics, Simulation and Modeling, Eukaryota, Ruminants, Condensed Matter Physics, Enzymes, Pyrococcus furiosus, Computational Theory and Mathematics, Modeling and Simulation, Vertebrates, Physical Sciences, Crystal Structure, Engineering and Technology, Multidrug Resistance-Associated Proteins, Biological system, Algorithms, Research Article, Protein Structure, QH301-705.5, Lysozyme, Molecular Dynamics Simulation, 010402 general chemistry, Research and Analysis Methods, 03 medical and health sciences, Cellular and Molecular Neuroscience, Genetics, Animals, Solid State Physics, Time domain, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Deer, Organisms, Electron Spin Resonance Spectroscopy, Biology and Life Sciences, Proteins, Computational Biology, Methionine Adenosyltransferase, Multilateration, 0104 chemical sciences, 030104 developmental biology, Amniotes, Enzymology, Time Domain Analysis, Muramidase, Spin Labels, Zoology, Mathematical Functions, Multidrug transporter, Mathematics, Software

Abstract

We describe an approach for integrating distance restraints from Double Electron-Electron Resonance (DEER) spectroscopy into Rosetta with the purpose of modeling alternative protein conformations from an initial experimental structure. Fundamental to this approach is a multilateration algorithm that harnesses sets of interconnected spin label pairs to identify optimal rotamer ensembles at each residue that fit the DEER decay in the time domain. Benchmarked relative to data analysis packages, the algorithm yields comparable distance distributions with the advantage that fitting the DEER decay and rotamer ensemble optimization are coupled. We demonstrate this approach by modeling the protonation-dependent transition of the multidrug transporter PfMATE to an inward facing conformation with a deviation to the experimental structure of less than 2Å Cα RMSD. By decreasing spin label rotamer entropy, this approach engenders more accurate Rosetta models that are also more closely clustered, thus setting the stage for more robust modeling of protein conformational changes., Author summary Proteins transition between different conformations during function. Double Electron-Electron Resonance (DEER) spectroscopy enables the direct observation of structural rearrangements that underpin these transitions. Typically, histograms of distances between spin labels, called distance distributions, are measured under different conditions. Structural rearrangements that underlie conformational transitions are manifested by changes in the averages and widths of the distance distributions. To transform these distance distributions into restraints for modeling alternate protein conformations, we developed an algorithm in the modeling suite Rosetta for direct analysis of DEER primary data that yield the optimum ensemble of spin label positions in space, referred to as rotamers, that account for the data. We benchmarked the effectiveness of this algorithm using experimental data collected in two proteins, the model system T4 Lysozyme and the multidrug transporter PfMATE in an outward-facing conformation. We then used optimized spin label rotamers to model the inward-facing conformation of PfMATE from the starting outward-facing conformation. Our results demonstrate substantial improvements in both precision and accuracy among the resulting models. Further improvement of this strategy will enable modeling of protein conformational changes involving complex modes of movements.

Published

2021

39. Prediction of amphipathic helix-membrane interactions with Rosetta

Author

Jens Meiler and Alican Gulsevin

Subjects

Protein Conformation, alpha-Helical, 0301 basic medicine, Cell Membranes, Peripheral Membrane Proteins, Protein Structure Prediction, Molecular Dynamics, Biochemistry, 01 natural sciences, Database and Informatics Methods, Protein Structure Databases, Computational Chemistry, Macromolecular Structure Analysis, Biochemical Simulations, Biology (General), Databases, Protein, Integral membrane protein, 010304 chemical physics, Ecology, Chemistry, Applied Mathematics, Simulation and Modeling, Peripheral membrane protein, Membrane, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Amphipathic helix, Cellular Structures and Organelles, Algorithms, Protein Binding, Research Article, Protein Structure, QH301-705.5, Biophysics, Molecular Dynamics Simulation, Research and Analysis Methods, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0103 physical sciences, Amphiphile, Genetics, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Computational Biology, Membrane Proteins, Biology and Life Sciences, Proteins, Cell Biology, Biological Databases, 030104 developmental biology, Helix, Mathematics

Abstract

Amphipathic helices have hydrophobic and hydrophilic/charged residues situated on opposite faces of the helix. They can anchor peripheral membrane proteins to the membrane, be attached to integral membrane proteins, or exist as independent peptides. Despite the widespread presence of membrane-interacting amphipathic helices, there is no computational tool within Rosetta to model their interactions with membranes. In order to address this need, we developed the AmphiScan protocol with PyRosetta, which runs a grid search to find the most favorable position of an amphipathic helix with respect to the membrane. The performance of the algorithm was tested in benchmarks with the RosettaMembrane, ref2015_memb, and franklin2019 score functions on six engineered and 44 naturally-occurring amphipathic helices using membrane coordinates from the OPM and PDBTM databases, OREMPRO server, and MD simulations for comparison. The AmphiScan protocol predicted the coordinates of amphipathic helices within less than 3Å of the reference structures and identified membrane-embedded residues with a Matthews Correlation Constant (MCC) of up to 0.57. Overall, AmphiScan stands as fast, accurate, and highly-customizable protocol that can be pipelined with other Rosetta and Python applications., Author summary Amphipathic helices are important targets as antibacterial peptides and as domains of membrane proteins that play a role in sensing the membrane environment. Understanding how amphipathic helices interact with membrane enables us to design better peptides and understand how membrane proteins use them to interact with their environment. However, there is a limited number of tools available for the modeling of amphipathic helices in membranes. Implicit membrane models can be used for this purpose as simplistic representations of the membrane environment. In this work, we developed the AmphiScan protocol that can be used to predict membrane coordinates of amphipathic helices starting with a helix structure in an implicit membrane environment. We benchmarked the performance of AmphiScan on engineered LK peptides, naturally-occurring amphipathic helices, and hydrophobic and hydrophilic peptides. Our approach provides a reliable and customizable tool to model amphipathic helix–membrane interactions, and pose a platform for the screening of amphipathic helix properties in silico.

Published

2021

40. Rosetta design with co-evolutionary information retains protein function

Author

Jens Meiler, Samuel Schmitz, Rainer Merkl, and Moritz Ertelt

Subjects

Models, Molecular, 0301 basic medicine, Protein Conformation, Interaction Networks, Biochemistry, Physical Chemistry, Database and Informatics Methods, Protein Structure Databases, 0302 clinical medicine, Macromolecular Structure Analysis, Amino Acids, Biology (General), Macromolecular Engineering, Conserved Sequence, Sequence, Protein function, Multiple sequence alignment, Ecology, Physics, Protein structure prediction, Chemistry, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Benchmark (computing), Thermodynamics, Engineering and Technology, Dimerization, Research Article, Protein Structure, QH301-705.5, Protein design, Bioengineering, Computational biology, Research and Analysis Methods, Evolution, Molecular, 03 medical and health sciences, Cellular and Molecular Neuroscience, Protein Domains, DNA-binding proteins, Genetics, Amino Acid Sequence, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Computational Biology, Proteins, Biology and Life Sciences, Macromolecular Design, Protein superfamily, Biological Databases, 030104 developmental biology, Chemical Properties, Protein Structure Networks, Sequence Alignment, 030217 neurology & neurosurgery, Function (biology), Sinorhizobium meliloti

Abstract

Computational protein design has the ambitious goal of crafting novel proteins that address challenges in biology and medicine. To overcome these challenges, the computational protein modeling suite Rosetta has been tailored to address various protein design tasks. Recently, statistical methods have been developed that identify correlated mutations between residues in a multiple sequence alignment of homologous proteins. These subtle inter-dependencies in the occupancy of residue positions throughout evolution are crucial for protein function, but we found that three current Rosetta design approaches fail to recover these co-evolutionary couplings. Thus, we developed the Rosetta method ResCue (residue-coupling enhanced) that leverages co-evolutionary information to favor sequences which recapitulate correlated mutations, as observed in nature. To assess the protocols via recapitulation designs, we compiled a benchmark of ten proteins each represented by two, structurally diverse states. We could demonstrate that ResCue designed sequences with an average sequence recovery rate of 70%, whereas three other protocols reached not more than 50%, on average. Our approach had higher recovery rates also for functionally important residues, which were studied in detail. This improvement has only a minor negative effect on the fitness of the designed sequences as assessed by Rosetta energy. In conclusion, our findings support the idea that informing protocols with co-evolutionary signals helps to design stable and native-like proteins that are compatible with the different conformational states required for a complex function., Author summary In homologous proteins, functionally or structurally important residues are strongly conserved. Thus, the consideration of conservation signals during protein design protocols can help to create sequences that are more native-like. However, the number of conserved residues is small in many proteins and not all important residues can be captured by conservation analysis. Residues are forming networks whose composition is dictated by protein structure function and thus is visible through the co-evolutionary analysis. Nowadays, advanced methods allow us to deduce these networks from multiple sequence alignments. Thus, we have implemented the novel Rosetta method termed ‘ResCue’ that informs the design protocol with co-evolutionary signals. Recapitulation designs based on ten difficult benchmarks made clear that this protocol creates sequences that are more native-like than three other, state-of-the-art design protocols.

Published

2021

41. Assessing multiple score functions in Rosetta for drug discovery

Author

Jens Meiler and Shannon T. Smith

Subjects

Protein Structure Comparison, 0301 basic medicine, Computer science, Datasets as Topic, computer.software_genre, Biochemistry, 01 natural sciences, Binding Analysis, Drug Discovery, Macromolecular Structure Analysis, Medicine and Health Sciences, chemistry.chemical_classification, Multidisciplinary, 010304 chemical physics, Organic Compounds, Drug discovery, Software Engineering, Protein structure prediction, Small molecule, Chemistry, Pharmaceutical Preparations, Physical Sciences, Medicine, Engineering and Technology, Research Article, Biotechnology, Macromolecule, Computer and Information Sciences, Protein Structure, Drug Research and Development, Science, Bioengineering, Library Screening, Research and Analysis Methods, Machine learning, Computer Software, 03 medical and health sciences, 0103 physical sciences, Humans, Molecular Biology Techniques, Protein Interactions, Molecular Biology, Chemical Characterization, Pharmacology, Molecular Biology Assays and Analysis Techniques, Virtual screening, business.industry, Ligand, Organic Chemistry, Chemical Compounds, Biology and Life Sciences, Proteins, 030104 developmental biology, Enzyme, chemistry, Small Molecules, Docking (molecular), Artificial intelligence, business, computer, Software

Abstract

Rosetta is a computational software suite containing algorithms for a wide variety of macromolecular structure prediction and design tasks including small molecule protocols commonly used in drug discovery or enzyme design. Here, we benchmark RosettaLigand score functions and protocols in comparison to results of other software recently published in the Comparative Assessment of Score Functions (CASF-2016). The CASF-2016 benchmark covers a wide variety of tests including scoring and ranking multiple compounds against a target, ligand docking of a small molecule to a target, and virtual screening to extract binders from a compound library. Direct comparison to the score functions provided by CASF-2016 results shows that the original RosettaLigand score function ranks among the top software for scoring, ranking, docking and screening tests. Most notably, the RosettaLigand score function ranked 2/34 among other report score functions in CASF-2016. We additionally perform a ligand docking test with full sampling to mimic typical use cases. Despite improved performance of newer score functions in canonical protein structure prediction and design, we demonstrate here that more recent Rosetta score functions have reduced performance across all small molecule benchmarks. The tests described here have also been uploaded to the Rosetta scientific benchmarking server and will be run weekly to track performance as the code is continually being developed.

Published

2020

42. Integrating linear optimization with structural modeling to increase HIV neutralization breadth

Author

Jens Meiler, Yevgeniy Vorobeychik, Swetasudha Panda, James E. Crowe, and Alexander M. Sevy

Subjects

0301 basic medicine, RNA viruses, Support Vector Machine, Linear programming, Computer science, Physiology, Amino Acid Motifs, HIV Infections, Protein Sequencing, HIV Antibodies, Pathology and Laboratory Medicine, Biochemistry, Sequence space, Machine Learning, Epitopes, Database and Informatics Methods, Protein sequencing, Mathematical and Statistical Techniques, Immunodeficiency Viruses, Immune Physiology, Medicine and Health Sciences, Biology (General), Macromolecular Engineering, Integer programming, Software suite, Immune System Proteins, Ecology, Linear model, 3. Good health, Computational Theory and Mathematics, Medical Microbiology, Modeling and Simulation, Viral Pathogens, Viruses, Regression Analysis, Engineering and Technology, Synthetic Biology, Pathogens, Algorithm, Sequence Analysis, Algorithms, Research Article, Biotechnology, Computer and Information Sciences, Bioinformatics, QH301-705.5, Protein design, Immunology, Bioengineering, Research and Analysis Methods, Microbiology, Antibodies, 03 medical and health sciences, Cellular and Molecular Neuroscience, Sequence Motif Analysis, Artificial Intelligence, Support Vector Machines, Retroviruses, Genetics, Humans, Linear Programming, Molecular Biology Techniques, Sequencing Techniques, Molecular Biology, Microbial Pathogens, Ecology, Evolution, Behavior and Systematics, Lentivirus, Organisms, Computational Biology, Biology and Life Sciences, Proteins, HIV, Macromolecular Design, Antibodies, Neutralizing, Support vector machine, 030104 developmental biology, Synthetic Bioengineering, HIV-1, Linear Models, Mathematical Functions, Software

Abstract

Computational protein design has been successful in modeling fixed backbone proteins in a single conformation. However, when modeling large ensembles of flexible proteins, current methods in protein design have been insufficient. Large barriers in the energy landscape are difficult to traverse while redesigning a protein sequence, and as a result current design methods only sample a fraction of available sequence space. We propose a new computational approach that combines traditional structure-based modeling using the Rosetta software suite with machine learning and integer linear programming to overcome limitations in the Rosetta sampling methods. We demonstrate the effectiveness of this method, which we call BROAD, by benchmarking the performance on increasing predicted breadth of anti-HIV antibodies. We use this novel method to increase predicted breadth of naturally-occurring antibody VRC23 against a panel of 180 divergent HIV viral strains and achieve 100% predicted binding against the panel. In addition, we compare the performance of this method to state-of-the-art multistate design in Rosetta and show that we can outperform the existing method significantly. We further demonstrate that sequences recovered by this method recover known binding motifs of broadly neutralizing anti-HIV antibodies. Finally, our approach is general and can be extended easily to other protein systems. Although our modeled antibodies were not tested in vitro, we predict that these variants would have greatly increased breadth compared to the wild-type antibody., Author summary In this article, we report a new approach for protein design, which combines traditional structural modeling with machine learning and integer programming. Using this method, we are able to design antibodies that are predicted to bind large panels of antigenically diverse HIV variants. The combination of methods from these fields allows us to surpass protein design limitations that have been seen up to this point. We predict that if we tested these modified antibodies against HIV variants they would have greater neutralization breadth than any antibodies seen to this point.

Published

2018

43. Integrating solid-state NMR and computational modeling to investigate the structure and dynamics of membrane-associated ghrelin

Author

Jens Meiler, Daniel Huster, Constance Chollet, Stephanie H. DeLuca, Gerrit Vortmeier, Annette G. Beck-Sickinger, Sylvia Els-Heindl, and Holger A. Scheidt

Subjects

Models, Molecular, Protein Conformation, Growth hormone secretagogue receptor, lcsh:Medicine, Peptide, 010402 general chemistry, 01 natural sciences, Cell membrane, 03 medical and health sciences, Protein structure, medicine, Humans, lcsh:Science, Nuclear Magnetic Resonance, Biomolecular, Protein secondary structure, 030304 developmental biology, Polyproline helix, chemistry.chemical_classification, 0303 health sciences, Multidisciplinary, Chemistry, Cell Membrane, digestive, oral, and skin physiology, lcsh:R, Computational Biology, Nuclear magnetic resonance spectroscopy, Ghrelin, 0104 chemical sciences, medicine.anatomical_structure, Biochemistry, Biophysics, lcsh:Q, Research Article

Abstract

The peptide hormone ghrelin activates the growth hormone secretagogue receptor 1a, also known as the ghrelin receptor. This 28-residue peptide is acylated at Ser3 and is the only peptide hormone in the human body that is lipid-modified by an octanoyl group. Little is known about the structure and dynamics of membrane-associated ghrelin. We carried out solid-state NMR studies of ghrelin in lipid vesicles, followed by computational modeling of the peptide using Rosetta. Isotropic chemical shift data of isotopically labeled ghrelin provide information about the peptide's secondary structure. Spin diffusion experiments indicate that ghrelin binds to membranes via its lipidated Ser3. Further, Phe4, as well as electrostatics involving the peptide's positively charged residues and lipid polar headgroups, contribute to the binding energy. Other than the lipid anchor, ghrelin is highly flexible and mobile at the membrane surface. This observation is supported by our predicted model ensemble, which is in good agreement with experimentally determined chemical shifts. In the final ensemble of models, residues 8-17 form an α-helix, while residues 21-23 and 26-27 often adopt a polyproline II helical conformation. These helices appear to assist the peptide in forming an amphipathic conformation so that it can bind to the membrane.

Published

2015

44. Membrane protein contact and structure prediction using co-evolution in conjunction with machine learning

Author

Brian E. Weiner, Marcin J. Skwark, Sten Heinze, Jens Meiler, Jeff L. Mendenhall, and Pedro L. Teixeira

Subjects

Models, Molecular, Protein Structure Comparison, 0301 basic medicine, Protein Folding, Cell Membranes, lcsh:Medicine, Protein Structure Prediction, computer.software_genre, Biochemistry, Protein Structure, Secondary, Machine Learning, Database and Informatics Methods, Mathematical and Statistical Techniques, Protein structure, Macromolecular Structure Analysis, lcsh:Science, Physics, Multidisciplinary, Protein structure prediction, Physical Sciences, Metric (mathematics), Protein folding, Cellular Structures and Organelles, Sequence Analysis, Statistical potential, Algorithms, Statistics (Mathematics), Research Article, Protein Structure, Multiple Alignment Calculation, Computer and Information Sciences, Bioinformatics, Protein design, Sequence alignment, Research and Analysis Methods, Machine learning, 03 medical and health sciences, Artificial Intelligence, Computational Techniques, Humans, Amino Acid Sequence, Statistical Methods, Molecular Biology, business.industry, lcsh:R, Membrane Proteins, Biology and Life Sciences, Proteins, Cell Biology, Split-Decomposition Method, 030104 developmental biology, Membrane protein, lcsh:Q, Artificial intelligence, business, Sequence Alignment, computer, Mathematics, Forecasting

Abstract

De novo membrane protein structure prediction is limited to small proteins due to the conformational search space quickly expanding with length. Long-range contacts (24+ amino acid separation)-residue positions distant in sequence, but in close proximity in the structure, are arguably the most effective way to restrict this conformational space. Inverse methods for co-evolutionary analysis predict a global set of position-pair couplings that best explain the observed amino acid co-occurrences, thus distinguishing between evolutionarily explained co-variances and these arising from spurious transitive effects. Here, we show that applying machine learning approaches and custom descriptors improves evolutionary contact prediction accuracy, resulting in improvement of average precision by 6 percentage points for the top 1L non-local contacts. Further, we demonstrate that predicted contacts improve protein folding with BCL::Fold. The mean RMSD100 metric for the top 10 models folded was reduced by an average of 2 Å for a benchmark of 25 membrane proteins.

Published

2017

45. Discovery of Small-Molecule Modulators of the Human Y4 Receptor

Author

Jens Meiler, David Weaver, Mario Schubert, Annette G. Beck-Sickinger, Jan Stichel, and Gregory Sliwoski

Subjects

0301 basic medicine, Physiology, Drug Evaluation, Preclinical, lcsh:Medicine, Ligands, Biochemistry, Endocrinology, 0302 clinical medicine, Chlorocebus aethiops, Medicine and Health Sciences, Enzyme Chemistry, lcsh:Science, Receptor, Multidisciplinary, COS cells, Organic Compounds, Small molecule, 3. Good health, Chemistry, Physiological Parameters, COS Cells, Physical Sciences, Niclosamide, Research Article, Biotechnology, Signal Transduction, Transmembrane Receptors, Endocrine Disorders, Allosteric regulation, Neuropeptide, Biology, Phosphates, Small Molecule Libraries, Enzyme Regulation, Structure-Activity Relationship, 03 medical and health sciences, Allosteric Regulation, Diabetes Mellitus, Animals, Humans, Structure–activity relationship, Obesity, G protein-coupled receptor, Body Weight, Organic Chemistry, lcsh:R, Chemical Compounds, Biology and Life Sciences, Proteins, Polypeptides, Cell Biology, Hormones, Receptors, Neuropeptide Y, 030104 developmental biology, Small Molecules, Metabolic Disorders, Enzymology, lcsh:Q, G Protein Coupled Receptors, Peptides, 030217 neurology & neurosurgery

Abstract

The human neuropeptide Y4 receptor (Y4R) and its native ligand, pancreatic polypeptide, are critically involved in the regulation of human metabolism by signaling satiety and regulating food intake, as well as increasing energy expenditure. Thus, this receptor represents a putative target for treatment of obesity. With respect to new approaches to treat complex metabolic disorders, especially in multi-receptor systems, small molecule allosteric modulators have been in the focus of research in the last years. However, no positive allosteric modulators or agonists of the Y4R have been described so far. In this study, small molecule compounds derived from the Niclosamide scaffold were identified by high-throughput screening to increase Y4R activity. Compounds were characterized for their potency and their effects at the human Y4R and as well as their selectivity towards Y1R, Y2R and Y5R. These compounds provide a structure-activity relationship profile around this common scaffold and lay the groundwork for hit-to-lead optimization and characterization of positive allosteric modulators of the Y4R.

Published

2016

46. BCL::Fold--de novo prediction of complex and large protein topologies by assembly of secondary structure elements

Author

Nils Woetzel, Nathan Alexander, Jens Meiler, Mert Karakaş, Brian E. Weiner, and René Staritzbichler

Subjects

Models, Molecular, Quality Control, Protein Structure, Protein Folding, Biophysics, Structure Prediction, lcsh:Medicine, Topology, Bioinformatics, Biochemistry, 01 natural sciences, Protein Structure, Secondary, 03 medical and health sciences, Protein structure, 0103 physical sciences, Macromolecular Structure Analysis, Humans, lcsh:Science, Biology, Protein secondary structure, 030304 developmental biology, Physics, 0303 health sciences, Multidisciplinary, 010304 chemical physics, Applied Mathematics, lcsh:R, Proteins, Computational Biology, Genomics, Protein structure prediction, Contact order, Benchmarking, De novo protein structure prediction, Computer Science, Simulated annealing, Protein folding, lcsh:Q, Monte Carlo Method, Statistical potential, Algorithms, Mathematics, Research Article

Abstract

Computational de novo protein structure prediction is limited to small proteins of simple topology. The present work explores an approach to extend beyond the current limitations through assembling protein topologies from idealized α-helices and β-strands. The algorithm performs a Monte Carlo Metropolis simulated annealing folding simulation. It optimizes a knowledge-based potential that analyzes radius of gyration, β-strand pairing, secondary structure element (SSE) packing, amino acid pair distance, amino acid environment, contact order, secondary structure prediction agreement and loop closure. Discontinuation of the protein chain favors sampling of non-local contacts and thereby creation of complex protein topologies. The folding simulation is accelerated through exclusion of flexible loop regions further reducing the size of the conformational search space. The algorithm is benchmarked on 66 proteins with lengths between 83 and 293 amino acids. For 61 out of these proteins, the best SSE-only models obtained have an RMSD100 below 8.0 Å and recover more than 20% of the native contacts. The algorithm assembles protein topologies with up to 215 residues and a relative contact order of 0.46. The method is tailored to be used in conjunction with low-resolution or sparse experimental data sets which often provide restraints for regions of defined secondary structure.

Published

2012

47. Analysis of Nidogen-1/Laminin γ1 Interaction by Cross-Linking, Mass Spectrometry, and Computational Modeling Reveals Multiple Binding Modes

Author

Manuel V. Keller, Knut Kölbel, Andrea Sinz, Frank Zaucke, D.P. Nannemann, Marian Schneider, Dirk Tänzler, Christian Ihling, Philip Lössl, and Jens Meiler

Subjects

Models, Molecular, lcsh:Medicine, Sequence alignment, Biology, Research and Analysis Methods, Mass spectrometry, Biochemistry, Protein Chemistry, Mass Spectrometry, Analytical Chemistry, Protein–protein interaction, Mice, Protein structure, Tandem Mass Spectrometry, Laminin, Animals, Humans, Biomacromolecule-Ligand Interactions, Surface plasmon resonance, lcsh:Science, chemistry.chemical_classification, Membrane Glycoproteins, Multidisciplinary, Simulation and Modeling, lcsh:R, Chromatographic Techniques, Biology and Life Sciences, Proteins, Surface Plasmon Resonance, Protein Structure, Tertiary, Amino acid, Kinetics, Chemistry, Cross-Linking Reagents, HEK293 Cells, Membrane protein, chemistry, Liquid Chromatography-Tandem Mass Spectrometry, Physical Sciences, biology.protein, Biophysics, lcsh:Q, Research Article

Abstract

We describe the detailed structural investigation of nidogen-1/laminin γ1 complexes using full-length nidogen-1 and a number of laminin γ1 variants. The interactions of nidogen-1 with laminin variants γ1 LEb2-4, γ1 LEb2-4 N836D, γ1 short arm, and γ1 short arm N836D were investigated by applying a combination of (photo-)chemical cross-linking, high-resolution mass spectrometry, and computational modeling. In addition, surface plasmon resonance and ELISA studies were used to determine kinetic constants of the nidogen-1/laminin γ1 interaction. Two complementary cross-linking strategies were pursued to analyze solution structures of laminin γ1 variants and nidogen-1. The majority of distance information was obtained with the homobifunctional amine-reactive cross-linker bis(sulfosuccinimidyl)glutarate. In a second approach, UV-induced cross-linking was performed after incorporation of the diazirine-containing unnatural amino acids photo-leucine and photo-methionine into laminin γ1 LEb2-4, laminin γ1 short arm, and nidogen-1. Our results indicate that Asn-836 within laminin γ1 LEb3 domain is not essential for complex formation. Cross-links between laminin γ1 short arm and nidogen-1 were found in all protein regions, evidencing several additional contact regions apart from the known interaction site. Computational modeling based on the cross-linking constraints indicates the existence of a conformational ensemble of both the individual proteins and the nidogen-1/laminin γ1 complex. This finding implies different modes of interaction resulting in several distinct protein-protein interfaces.

Published

2014

48. RosettaEPR: Rotamer Library for Spin Label Structure and Dynamics

Author

Hanane A. Koteiche, Hassane S. Mchaourab, Jens Meiler, Kristian Kaufmann, Richard A. Stein, and Nathan Alexander

Subjects

Models, Molecular, Protein Conformation, lcsh:Medicine, Molecular Dynamics Simulation, 010402 general chemistry, Bioinformatics, 01 natural sciences, Molecular physics, law.invention, 03 medical and health sciences, Molecular dynamics, Protein structure, law, Bacteriophage T4, lcsh:Science, Spin label, Electron paramagnetic resonance, 030304 developmental biology, Spin-½, Mesylates, Physics, 0303 health sciences, Multidisciplinary, lcsh:R, Electron Spin Resonance Spectroscopy, Proteins, Reproducibility of Results, Site-directed spin labeling, Protein structure prediction, 0104 chemical sciences, Structural biology, lcsh:Q, Muramidase, Spin Labels, Software, Research Article

Abstract

An increasingly used parameter in structural biology is the measurement of distances between spin labels bound to a protein. One limitation to these measurements is the unknown position of the spin label relative to the protein backbone. To overcome this drawback, we introduce a rotamer library of the methanethiosulfonate spin label (MTSSL) into the protein modeling program Rosetta. Spin label rotamers were derived from conformations observed in crystal structures of spin labeled T4 lysozyme and previously published molecular dynamics simulations. Rosetta's ability to accurately recover spin label conformations and EPR measured distance distributions was evaluated against 19 experimentally determined MTSSL labeled structures of T4 lysozyme and the membrane protein LeuT and 73 distance distributions from T4 lysozyme and the membrane protein MsbA. For a site in the core of T4 lysozyme, the correct spin label conformation (Χ1 and Χ2) is recovered in 99.8% of trials. In surface positions 53% of the trajectories agree with crystallized conformations in Χ1 and Χ2. This level of recovery is on par with Rosetta performance for the 20 natural amino acids. In addition, Rosetta predicts the distance between two spin labels with a mean error of 4.4 Å. The width of the experimental distance distribution, which reflects the flexibility of the two spin labels, is predicted with a mean error of 1.3 Å. RosettaEPR makes full-atom spin label modeling available to a wide scientific community in conjunction with the powerful suite of modeling methods within Rosetta.

Published

2013

49. Assessment and Challenges of Ligand Docking into Comparative Models of G-Protein Coupled Receptors

Author

Christoffer Norn, Elizabeth Dong Nguyen, Jens Meiler, and Thomas M. Frimurer

Subjects

Molecular model, Structure Prediction, Molecular Conformation, lcsh:Medicine, Ligands, Bioinformatics, Biochemistry, Molecular Docking Simulation, Protein Structure, Secondary, Receptors, G-Protein-Coupled, 0302 clinical medicine, Protein structure, Stereochemistry, Macromolecular Structure Analysis, Biomacromolecule-Ligand Interactions, Databases, Protein, lcsh:Science, Root-mean-square deviation, 0303 health sciences, Multidisciplinary, Chemistry, Genomics, Ligand (biochemistry), Thermodynamics, Monte Carlo Method, Research Article, Computer Modeling, Protein Binding, Protein Structure, Molecular Sequence Data, Biophysics, Computational biology, 03 medical and health sciences, Humans, Amino Acid Sequence, Biology, 030304 developmental biology, G protein-coupled receptor, Virtual screening, Binding Sites, lcsh:R, Proteins, Computational Biology, Transmembrane Proteins, Structural Homology, Protein, Docking (molecular), Computer Science, lcsh:Q, Software, 030217 neurology & neurosurgery

Abstract

The rapidly increasing number of high-resolution X-ray structures of G-protein coupled receptors (GPCRs) creates a unique opportunity to employ comparative modeling and docking to provide valuable insight into the function and ligand binding determinants of novel receptors, to assist in virtual screening and to design and optimize drug candidates. However, low sequence identity between receptors, conformational flexibility, and chemical diversity of ligands present an enormous challenge to molecular modeling approaches. It is our hypothesis that rapid Monte-Carlo sampling of protein backbone and side-chain conformational space with Rosetta can be leveraged to meet this challenge. This study performs unbiased comparative modeling and docking methodologies using 14 distinct high-resolution GPCRs and proposes knowledge-based filtering methods for improvement of sampling performance and identification of correct ligand-receptor interactions. On average, top ranked receptor models built on template structures over 50% sequence identity are within 2.9 Å of the experimental structure, with an average root mean square deviation (RMSD) of 2.2 Å for the transmembrane region and 5 Å for the second extracellular loop. Furthermore, these models are consistently correlated with low Rosetta energy score. To predict their binding modes, ligand conformers of the 14 ligands co-crystalized with the GPCRs were docked against the top ranked comparative models. In contrast to the comparative models themselves, however, it remains difficult to unambiguously identify correct binding modes by score alone. On average, sampling performance was improved by 10(3) fold over random using knowledge-based and energy-based filters. In assessing the applicability of experimental constraints, we found that sampling performance is increased by one order of magnitude for every 10 residues known to contact the ligand. Additionally, in the case of DOR, knowledge of a single specific ligand-protein contact improved sampling efficiency 7 fold. These findings offer specific guidelines which may lead to increased success in determining receptor-ligand complexes.

Published

2013

50. Towards Ligand Docking Including Explicit Interface Water Molecules

Author

Jens Meiler and Gordon Lemmon

Subjects

Models, Molecular, Protein Structure, Protein Conformation, Stereochemistry, Biophysics, lcsh:Medicine, Ligands, Bioinformatics, Biochemistry, 01 natural sciences, Molecular Docking Simulation, 03 medical and health sciences, Computational Chemistry, HIV Protease, Chemical Biology, Drug Discovery, 0103 physical sciences, Protease Inhibitors, Biomacromolecule-Ligand Interactions, lcsh:Science, Biology, Computerized Simulations, 030304 developmental biology, Lead Finder, 0303 health sciences, Binding Sites, Multidisciplinary, 010304 chemical physics, lcsh:R, Proteins, Computational Biology, Water, Protein structure prediction, Ligand (biochemistry), Small molecule, Chemistry, Protein–ligand docking, Small Molecules, Docking (molecular), Searching the conformational space for docking, Computer Science, Molecular Mechanics, Biophysic Al Simulations, lcsh:Q, Research Article, Computer Modeling, Protein Binding

Abstract

Small molecule docking predicts the interaction of a small molecule ligand with a protein at atomic-detail accuracy including position and conformation the ligand but also conformational changes of the protein upon ligand binding. While successful in the majority of cases, docking algorithms including RosettaLigand fail in some cases to predict the correct protein/ligand complex structure. In this study we show that simultaneous docking of explicit interface water molecules greatly improves Rosetta's ability to distinguish correct from incorrect ligand poses. This result holds true for both protein-centric water docking wherein waters are located relative to the protein binding site and ligand-centric water docking wherein waters move with the ligand during docking. Protein-centric docking is used to model 99 HIV-1 protease/protease inhibitor structures. We find protease inhibitor placement improving at a ratio of 9:1 when one critical interface water molecule is included in the docking simulation. Ligand-centric docking is applied to 341 structures from the CSAR benchmark of diverse protein/ligand complexes [1]. Across this diverse dataset we see up to 56% recovery of failed docking studies, when waters are included in the docking simulation.

Published

2013