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1. Membranome 3.0: Database of single‐pass membrane proteins with AlphaFold models

   https://doi.org/10.1002/pro.4318  

   Lomize, Andrei L.; Schnitzer, Kevin A.; Todd, Spencer C.; Cherepanov, Stanislav; Outeiral, Carlos; Deane, Charlotte M.; Pogozheva, Irina D. (April 2022, Protein Science)

   Abstract The Membranome database provides comprehensive structural information on single‐pass (i.e., bitopic) membrane proteins from six evolutionarily distant organisms, including protein–protein interactions, complexes, mutations, experimental structures, and models of transmembrane α‐helical dimers. We present a new version of this database, Membranome 3.0, which was significantly updated by revising the set of 5,758 bitopic proteins and incorporating models generated by AlphaFold 2 in the database. The AlphaFold models were parsed into structural domains located at the different membrane sides, modified to exclude low‐confidence unstructured terminal regions and signal sequences, validated through comparison with available experimental structures, and positioned with respect to membrane boundaries. Membranome 3.0 was re‐developed to facilitate visualization and comparative analysis of multiple 3D structures of proteins that belong to a specified family, complex, biological pathway, or membrane type. New tools for advanced search and analysis of proteins, their interactions, complexes, and mutations were included. The database is freely accessible athttps://membranome.org. 

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2. Conformational ensembles explain NMR spectra of frozen intrinsically disordered proteins

   https://doi.org/10.1002/pro.4628  

   Kragelj, Jaka; Dumarieh, Rania; Xiao, Yiling; Frederick, Kendra K. (April 2023, Protein Science)

   Abstract Protein regions which are intrinsically disordered, exist as an ensemble of rapidly interconverting structures. Cooling proteins to cryogenic temperatures for dynamic nuclear polarization (DNP) magic angle spinning (MAS) NMR studies suspends most of the motions, resulting in peaks that are broad but not featureless. To demonstrate that detailed conformational restraints can be retrieved from the peak shapes of frozen proteins alone, we developed and used a simulation framework to assign peak features to conformers in the ensemble. We validated our simulations by comparing them to spectra of α‐synuclein acquired under different experimental conditions. Our assignments of peaks to discrete dihedral angle populations suggest that structural constraints are attainable under cryogenic conditions. The ability to infer ensemble populations from peak shapes has important implications for DNP MAS NMR studies of proteins with regions of disorder in living cells because chemical shifts are the most accessible measured parameter. 

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3. RCSB Protein Data Bank: Celebrating 50 years of the PDB with new tools for understanding and visualizing biological macromolecules in 3D

   https://doi.org/10.1002/pro.4213  

   Burley, Stephen K.; Bhikadiya, Charmi; Bi, Chunxiao; Bittrich, Sebastian; Chen, Li; Crichlow, Gregg V.; Duarte, Jose M.; Dutta, Shuchismita; Fayazi, Maryam; Feng, Zukang; et al (November 2021, Protein Science)

   Abstract The Research Collaboratory for Structural Bioinformatics Protein Data Bank (RCSB PDB), funded by the US National Science Foundation, National Institutes of Health, and Department of Energy, has served structural biologists and Protein Data Bank (PDB) data consumers worldwide since 1999. RCSB PDB, a founding member of the Worldwide Protein Data Bank (wwPDB) partnership, is the US data center for the global PDB archive housing biomolecular structure data. RCSB PDB is also responsible for the security of PDB data, as the wwPDB‐designated Archive Keeper. Annually, RCSB PDB serves tens of thousands of three‐dimensional (3D) macromolecular structure data depositors (using macromolecular crystallography, nuclear magnetic resonance spectroscopy, electron microscopy, and micro‐electron diffraction) from all inhabited continents. RCSB PDB makes PDB data available from its research‐focusedRCSB.orgweb portal at no charge and without usage restrictions to millions of PDB data consumers working in every nation and territory worldwide. In addition, RCSB PDB operates an outreach and educationPDB101.RCSB.orgweb portal that was used by more than 800,000 educators, students, and members of the public during calendar year 2020. This invited Tools Issue contribution describes (i) how the archive is growing and evolving as new experimental methods generate ever larger and more complex biomolecular structures; (ii) the importance of data standards and data remediation in effective management of the archive and facile integration with more than 50 external data resources; and (iii) new tools and features for 3D structure analysis and visualization made available during the past yearviatheRCSB.orgweb portal. 

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4. ComparePD : Improving protein– DNA complex model comparison with hydrogen bond energy‐based metrics

   https://doi.org/10.1002/prot.26493  

   Malik, Fareeha Kanwal; Guo, Jun‐tao (March 2023, Proteins: Structure, Function, and Bioinformatics)

   Abstract Computational modeling of protein–DNA complex structures has important implications in biomedical applications such as structure‐based, computer aided drug design. A key step in developing methods for accurate modeling of protein–DNA complexes is similarity assessment between models and their reference complex structures. Existing methods primarily rely on distance‐based metrics and generally do not consider important functional features of the complexes, such as interface hydrogen bonds that are critical to specific protein–DNA interactions. Here, we present a new scoring function, ComparePD, which takes interface hydrogen bond energy and strength into account besides the distance‐based metrics for accurate similarity measure of protein–DNA complexes. ComparePD was tested on two datasets of computational models of protein–DNA complexes generated using docking (classified as easy, intermediate, and difficult cases) and homology modeling methods. The results were compared with PDDockQ, a modified version of DockQ tailored for protein–DNA complexes, as well as the metrics employed by the community‐wide experiment CAPRI (Critical Assessment of PRedicted Interactions). We demonstrated that ComparePD provides an improved similarity measure over PDDockQ and the CAPRI classification method by considering both conformational similarity and functional importance of the complex interface. ComparePD identified more meaningful models as compared to PDDockQ for all the cases having different top models between ComparePD and PDDockQ except for one intermediate docking case. 

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5. Predicting protein flexibility with AlphaFold

   https://doi.org/10.1002/prot.26471  

   Ma, Puyi; Li, Da‐Wei; Brüschweiler, Rafael (February 2023, Proteins: Structure, Function, and Bioinformatics)

   Abstract AlphaFold2 has revolutionized protein structure prediction from amino‐acid sequence. In addition to protein structures, high‐resolution dynamics information about various protein regions is important for understanding protein function. Although AlphaFold2 has neither been designed nor trained to predict protein dynamics, it is shown here how the information returned by AlphaFold2 can be used to predict dynamic protein regions at the individual residue level. The approach, which is termed cdsAF2, uses the 3D protein structure returned by AlphaFold2 to predict backbone NMR NHS²order parameters using a local contact model that takes into account the contacts made by each peptide plane along the backbone with its environment. By combining for each residue AlphaFold2's pLDDT confidence score for the structure prediction accuracy with the predictedS²value using the local contact model, an estimator is obtained that semi‐quantitatively captures many of the dynamics features observed in experimental backbone NMR NHS²order parameter profiles. The method is demonstrated for a set nine proteins of different sizes and variable amounts of dynamics and disorder. 

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