Themed collection Computational protein design and structure prediction: Celebrating the 2024 Nobel Prize in Chemistry

49 items
Open Access Highlight

Unlocking novel therapies: cyclic peptide design for amyloidogenic targets through synergies of experiments, simulations, and machine learning

Proposed de novo peptide design strategy against amyloidogenic targets. After initial computational preparation of the binder and target, the computational and experimental validation are incorporated in iterative machine learning powered cycles to generate better and improved peptide-based targets.

Graphical abstract: Unlocking novel therapies: cyclic peptide design for amyloidogenic targets through synergies of experiments, simulations, and machine learning
Open Access Feature Article

Role of conformational dynamics in the evolution of novel enzyme function

Enzymes exist as a dynamic ensemble of conformations, each potentially playing a key role in substrate binding, the chemical transformation, or product release. We discuss recent advances in the evaluation of the enzyme conformational dynamics and its evolution towards new functions or substrate preferences.

Graphical abstract: Role of conformational dynamics in the evolution of novel enzyme function
Review Article

Architecture of full-length type I modular polyketide synthases revealed by X-ray crystallography, cryo-electron microscopy, and AlphaFold2

Structures of intact polyketide synthase modules reveal conformational rearrangements and suggest asynchronous use of reaction chambers.

Graphical abstract: Architecture of full-length type I modular polyketide synthases revealed by X-ray crystallography, cryo-electron microscopy, and AlphaFold2
Open Access Review Article

Navigating the landscape of enzyme design: from molecular simulations to machine learning

Efficiently harnessing big data by combining molecular modelling and machine learning accelerates rational enzyme design for its applications in fine chemical synthesis and waste valorization, to address global environmental issues and sustainable development.

Graphical abstract: Navigating the landscape of enzyme design: from molecular simulations to machine learning
Open Access Review Article

A roadmap for metagenomic enzyme discovery

Shotgun metagenomic approaches to uncover new enzymes are underdeveloped relative to PCR- or activity-based functional metagenomics. Here we review computational and experimental strategies to discover biosynthetic enzymes from metagenomes.

Graphical abstract: A roadmap for metagenomic enzyme discovery
Open Access Review Article

Coiled coil protein origami: from modular design principles towards biotechnological applications

This review illustrates the current state in designing coiled-coil-based proteins with an emphasis on coiled coil protein origami structures and their potential.

Graphical abstract: Coiled coil protein origami: from modular design principles towards biotechnological applications
Review Article

Protein thermostability engineering

Using structure and sequence based analysis we can engineer proteins to increase their thermal stability.

Graphical abstract: Protein thermostability engineering
Open Access Tutorial Review

Strategies for designing biocatalysts with new functions

Enzymes can be optimized to accelerate chemical transformations via a range of methods. In this review, we showcase how protein engineering and computational design techniques can be interfaced to develop highly efficient and selective biocatalysts.

Graphical abstract: Strategies for designing biocatalysts with new functions
Communication

Computational design of orthogonal nucleoside kinases

Rosetta design software was employed to remodel the substrate specificity of Drosophila melanogaster 2′-deoxyribonucleoside kinase for efficient phosphorylation of the nucleoside analog prodrug 3′-deoxythymidine.

Graphical abstract: Computational design of orthogonal nucleoside kinases
Open Access Edge Article

De novo design of peptides that bind specific conformers of α-synuclein

De novo designed peptides bind specific conformers of α-synuclein fibrils.

Graphical abstract: De novo design of peptides that bind specific conformers of α-synuclein
Open Access Edge Article

Substituting density functional theory in reaction barrier calculations for hydrogen atom transfer in proteins

Hydrogen atom transfer (HAT) reactions, as they occur in many biological systems, are here predicted by machine learning.

Graphical abstract: Substituting density functional theory in reaction barrier calculations for hydrogen atom transfer in proteins
Open Access Edge Article

Tidying up the conformational ensemble of a disordered peptide by computational prediction of spectroscopic fingerprints

Pairing experiments with simulations, we predict spectroscopic fingerprints, enhancing understanding of disordered peptides' conformational ensembles. This helps rationalize elusive structure-spectra relationships for these peptides and proteins.

Graphical abstract: Tidying up the conformational ensemble of a disordered peptide by computational prediction of spectroscopic fingerprints
Open Access Edge Article

Combining structural and coevolution information to unveil allosteric sites

Structure-based three-parameter model that integrates local binding site information, coevolutionary information, and information on dynamic allostery to identify potentially hidden allosteric sites in ensembles of protein structures.

Graphical abstract: Combining structural and coevolution information to unveil allosteric sites
Open Access Edge Article

Thermodynamic origins of two-component multiphase condensates of proteins

We develop a computational method integrating a genetic algorithm with a residue-level coarse-grained model of intrinsically disordered proteins in order to uncover the molecular origins of multiphase condensates and enable their controlled design.

Graphical abstract: Thermodynamic origins of two-component multiphase condensates of proteins
Open Access Edge Article

AlphaFold accelerates artificial intelligence powered drug discovery: efficient discovery of a novel CDK20 small molecule inhibitor

A novel CDK20 small molecule inhibitor discovered by artificial intelligence based on an AlphaFold-predicted structure demonstrates the first application of AlphaFold in hit identification for efficient drug discovery.

Graphical abstract: AlphaFold accelerates artificial intelligence powered drug discovery: efficient discovery of a novel CDK20 small molecule inhibitor
Open Access Edge Article

Protein quaternary structures in solution are a mixture of multiple forms

Comparing the different methods for determining oligomerization composition of a protein in solution at different concentrations. The ruler of μg ml−1 represents protein concentrations applicable for the different methods.

Graphical abstract: Protein quaternary structures in solution are a mixture of multiple forms
Open Access Edge Article

From peptides to proteins: coiled-coil tetramers to single-chain 4-helix bundles

Rules for designing 4-helix bundles are defined, tested, and used to generate de novo peptide assemblies and a single-chain protein.

Graphical abstract: From peptides to proteins: coiled-coil tetramers to single-chain 4-helix bundles
Open Access Edge Article

Computationally driven discovery of SARS-CoV-2 Mpro inhibitors: from design to experimental validation

The dominant binding mode of the QUB-00006-Int-07 main protease inhibitor during absolute binding free energy simulations.

Graphical abstract: Computationally driven discovery of SARS-CoV-2 Mpro inhibitors: from design to experimental validation
Open Access Edge Article

Generating 3D molecules conditional on receptor binding sites with deep generative models

We generate 3D molecules conditioned on receptor binding sites by training a deep generative model on protein–ligand complexes. Our model uses the conditional receptor information to make chemically relevant changes to the generated molecules.

Graphical abstract: Generating 3D molecules conditional on receptor binding sites with deep generative models
Open Access Edge Article

Generation of bright monomeric red fluorescent proteins via computational design of enhanced chromophore packing

We used computational design to increase quantum yield in a fluorescent protein by optimizing chromophore packing to reduce non-radiative decay, resulting in an >10-fold increase in quantum yield that was further improved by directed evolution.

Graphical abstract: Generation of bright monomeric red fluorescent proteins via computational design of enhanced chromophore packing
Open Access Edge Article

Alchemical absolute protein–ligand binding free energies for drug design

Molecular dynamics based absolute protein–ligand binding free energies can be calculated accurately and at large scale to facilitate drug discovery.

Graphical abstract: Alchemical absolute protein–ligand binding free energies for drug design
Open Access Edge Article

Prediction and mitigation of mutation threats to COVID-19 vaccines and antibody therapies

Antibody therapeutics and vaccines are among our last resort to end the raging COVID-19 pandemic.

Graphical abstract: Prediction and mitigation of mutation threats to COVID-19 vaccines and antibody therapies
Open Access Edge Article

Computational strategy for intrinsically disordered protein ligand design leads to the discovery of p53 transactivation domain I binding compounds that activate the p53 pathway

A hierarchical computational strategy for IDP drug virtual screening (IDPDVS) was proposed and successfully applied to identify compounds that bind p53 TAD1 and restore wild-type p53 function in cancer cells.

Graphical abstract: Computational strategy for intrinsically disordered protein ligand design leads to the discovery of p53 transactivation domain I binding compounds that activate the p53 pathway
Open Access Edge Article

Discovery of cryptic allosteric sites using reversed allosteric communication by a combined computational and experimental strategy

Using reversed allosteric communication, we performed MD simulations, MSMs, and mutagenesis experiments, to discover allosteric sites. It reproduced the known allosteric site for MDL-801 on Sirt6 and uncovered a novel cryptic allosteric Pocket X.

Graphical abstract: Discovery of cryptic allosteric sites using reversed allosteric communication by a combined computational and experimental strategy
Open Access Edge Article

Enhancing a de novo enzyme activity by computationally-focused ultra-low-throughput screening

De novo enzymes capable of efficiently catalysis of a non-natural reaction are obtained through minimalist design plus computationally-focused variant library screening.

Graphical abstract: Enhancing a de novo enzyme activity by computationally-focused ultra-low-throughput screening
Open Access Edge Article

DEEPScreen: high performance drug–target interaction prediction with convolutional neural networks using 2-D structural compound representations

The DEEPScreen system is composed of 704 target protein specific prediction models, each independently trained using experimental bioactivity measurements against many drug candidate small molecules, and optimized according to the binding properties of the target proteins.

Graphical abstract: DEEPScreen: high performance drug–target interaction prediction with convolutional neural networks using 2-D structural compound representations
Edge Article

Remodeling a β-peptide bundle

We apply the Rosetta algorithm to repack the hydrophobic core of a β-peptide bundle while retaining both structure and stability.

Graphical abstract: Remodeling a β-peptide bundle
Open Access Paper

Computational study of the mechanism of a polyurethane esterase A (PueA) from Pseudomonas chlororaphis

We investigate the possible molecular mechanism of polyurethane esterase A, previously identified as responsible for degradation of a polyester polyurethane sample in Pseudomonas chlororaphis.

Graphical abstract: Computational study of the mechanism of a polyurethane esterase A (PueA) from Pseudomonas chlororaphis
From the themed collection: Biocatalysis
Open Access Paper

Dual inhibitory potential of ganoderic acid A on GLUT1/3: computational and in vitro insights into targeting glucose metabolism in human lung cancer

Human glucose transporters (GLUTs) facilitate the uptake of hexoses into cells. In cancer, the increased proliferation necessitates higher expression of GLUTs. This study demonstrates the inhibitory function of ganoderic acid A (GAA) on GLUT1/3.

Graphical abstract: Dual inhibitory potential of ganoderic acid A on GLUT1/3: computational and in vitro insights into targeting glucose metabolism in human lung cancer
Paper

Reaction mechanism and regioselectivity of uridine diphosphate glucosyltransferase RrUGT3: a combined experimental and computational study

A substrate binding induced conformational change was found to be essential for the occurrence of RrUGT3 catalyzed transglycosylation reactions.

Graphical abstract: Reaction mechanism and regioselectivity of uridine diphosphate glucosyltransferase RrUGT3: a combined experimental and computational study
Open Access Paper

ProtAgents: protein discovery via large language model multi-agent collaborations combining physics and machine learning

ProtAgents is a de novo protein design platform based on multimodal LLMs, where distinct AI agents with expertise in knowledge retrieval, protein structure analysis, physics-based simulations, and results analysis tackle tasks in a dynamic setting.

Graphical abstract: ProtAgents: protein discovery via large language model multi-agent collaborations combining physics and machine learning
Paper

Exploring conformational landscapes and binding mechanisms of convergent evolution for the SARS-CoV-2 spike Omicron variant complexes with the ACE2 receptor using AlphaFold2-based structural ensembles and molecular dynamics simulations

. AlphaFold-based approaches for prediction of protein states and molecular dynamics simulations are integrated to characterize conformational ensembles and binding mechanisms of the SARS-CoV-2 spike Omicron variants with the host receptor ACE2.

Graphical abstract: Exploring conformational landscapes and binding mechanisms of convergent evolution for the SARS-CoV-2 spike Omicron variant complexes with the ACE2 receptor using AlphaFold2-based structural ensembles and molecular dynamics simulations
Paper

Interface design of SARS-CoV-2 symmetrical nsp7 dimer and machine learning-guided nsp7 sequence prediction reveals physicochemical properties and hotspots for nsp7 stability, adaptation, and therapeutic design

The study investigates the molecular intricacies of SARS-CoV-2 RdRp via computational protein design, machine learning, and structural analyses, shedding light on mutational selection events impacting viral evolution and therapeutic strategies.

Graphical abstract: Interface design of SARS-CoV-2 symmetrical nsp7 dimer and machine learning-guided nsp7 sequence prediction reveals physicochemical properties and hotspots for nsp7 stability, adaptation, and therapeutic design
From the themed collection: PCCP 2023 Emerging Investigators
Open Access Paper

Molecularly imprinted nanoparticles reveal regulatory scaffolding features in Pyk2 tyrosine kinase

We employ peptide-binding molecularly imprinted nanoparticles (MINPs) to probe the regulatory conformations and scaffolding interactions governing Pyk2 kinase activation.

Graphical abstract: Molecularly imprinted nanoparticles reveal regulatory scaffolding features in Pyk2 tyrosine kinase
Open Access Paper

PIGNet2: a versatile deep learning-based protein–ligand interaction prediction model for binding affinity scoring and virtual screening

PIGNet2, a versatile protein–ligand interaction prediction model that performs well in both molecule identification and optimization, demonstrates its potential in early-stage drug discovery.

Graphical abstract: PIGNet2: a versatile deep learning-based protein–ligand interaction prediction model for binding affinity scoring and virtual screening
Open Access Paper

Helix-based screening with structure prediction using artificial intelligence has potential for the rapid development of peptide inhibitors targeting class I viral fusion

Peptide inhibitors against the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) are designed using a screening system for peptide-based inhibitors containing an α-helix region (SPICA) and structures predicted by AlphaFold2.

Graphical abstract: Helix-based screening with structure prediction using artificial intelligence has potential for the rapid development of peptide inhibitors targeting class I viral fusion
Open Access Paper

Thermostable protein-stabilized gold nanoclusters as a peroxidase mimic

By using a genetically modified thermostable protein (KTQ5C), we have synthesized protein-stabilized goldnanoclusters (AuNC@KTQ5C) with advantageous properties, such as heat stable fluorescent emission and heat resistant peroxidase-like activity.

Graphical abstract: Thermostable protein-stabilized gold nanoclusters as a peroxidase mimic
Paper

Computational thermostability engineering of a nitrile hydratase using synergetic energy and correlated configuration for redesigning enzymes (SECURE) strategy

A computational strategy using synergetic energy and correlated configuration for redesigning enzymes (SECURE) is proposed for the thermostability engineering of multimeric proteins.

Graphical abstract: Computational thermostability engineering of a nitrile hydratase using synergetic energy and correlated configuration for redesigning enzymes (SECURE) strategy
Open Access Paper

A deep learning model for type II polyketide natural product prediction without sequence alignment

Utilizing a large protein language model, we have formulated a deep learning framework designed for predicting type II polyketide natural products.

Graphical abstract: A deep learning model for type II polyketide natural product prediction without sequence alignment
Open Access Paper

Benchmarking protein structure predictors to assist machine learning-guided peptide discovery

Machine learning models provide an informed and efficient strategy to create novel peptide and protein sequences with the desired profiles.

Graphical abstract: Benchmarking protein structure predictors to assist machine learning-guided peptide discovery
Open Access Paper

Predicting small molecule binding pockets on diacylglycerol kinases using chemoproteomics and AlphaFold

We provide a family-wide assessment of accessible sites for covalent targeting that combined with AlphaFold revealed predicted small molecule binding pockets for guiding future inhibitor development of the DGK superfamily.

Graphical abstract: Predicting small molecule binding pockets on diacylglycerol kinases using chemoproteomics and AlphaFold
Open Access Paper

3DProtDTA: a deep learning model for drug-target affinity prediction based on residue-level protein graphs

We propose a new deep learning DTA model 3DProtDTA, which utilises AlphaFold structure predictions in conjunction with the graph representation of proteins.

Graphical abstract: 3DProtDTA: a deep learning model for drug-target affinity prediction based on residue-level protein graphs
Open Access Paper

Virtual screening and activity evaluation of human uric acid transporter 1 (hURAT1) inhibitors

Alphafold2 was used to predict URAT1 protein structure, then the docking sites were identified, and three hit compounds were obtained through virtual screening and bioactivity verification.

Graphical abstract: Virtual screening and activity evaluation of human uric acid transporter 1 (hURAT1) inhibitors
Open Access Paper

The impact of AlphaFold2 on experimental structure solution

AlphaFold2 predicts protein folds from sequence, which can be used for experimental structural biology, in construction and de novo protein design, prediction of complexes and perhaps even effects of mutations and conformational space exploration.

Graphical abstract: The impact of AlphaFold2 on experimental structure solution
Paper

Parallelized identification of on- and off-target protein interactions

Yeast surface display using multi target selections enables monitoring of specificity profiles for thousands of proteins in parallel.

Graphical abstract: Parallelized identification of on- and off-target protein interactions
Open Access Paper

In silico functional and tumor suppressor role of hypothetical protein PCNXL2 with regulation of the Notch signaling pathway

Since the last decade, various genome sequencing projects have led to the accumulation of an enormous set of genomic data; however, numerous protein-coding genes still need to be functionally characterized.

Graphical abstract: In silico functional and tumor suppressor role of hypothetical protein PCNXL2 with regulation of the Notch signaling pathway
Paper

Comprehensive evaluation of ten docking programs on a diverse set of protein–ligand complexes: the prediction accuracy of sampling power and scoring power

We evaluated the capabilities of ten molecular docking programs to predict the ligand binding poses (sampling power) and rank the binding affinities (scoring power).

Graphical abstract: Comprehensive evaluation of ten docking programs on a diverse set of protein–ligand complexes: the prediction accuracy of sampling power and scoring power
Paper

Accelerated electron transport from photosystem I to redox partners by covalently linked ferredoxin

Tethering ferredoxin (PetF) to photosystem I increased light-induced PetF-mediated electron transfer to soluble acceptors. Tethering was equivalent to using a ten-to-one molar ratio of soluble PetF to PSI.

Graphical abstract: Accelerated electron transport from photosystem I to redox partners by covalently linked ferredoxin
Paper

π–π and cation–π interactions in protein–porphyrin complex crystal structures

We have described the π–π and cation–π interactions between the porphyrin ring and the protein part of porphyrin-containing proteins to better understand their stabilizing role.

Graphical abstract: π–π and cation–π interactions in protein–porphyrin complex crystal structures
49 items

About this collection

This cross-journal collection celebrates the 2024 Nobel Prize in Chemistry by bringing together research published on computational protein design and protein structure prediction. Nobel Laureates Demis Hassabis and John M. Jumper have successfully used artificial intelligence to predict the structure of almost all known proteins, and Nobel Laureate David Baker has used this technology to design and create entirely new proteins. This collection highlights work on protein design and analysis using computational methods, providing applications in biocatalysis, drug design and more.

Spotlight

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