Estimating conformational heterogeneity of tryptophan synthase with a template‐based <scp>Alphafold2</scp> approach

Casadevall, Guillem; Duran, Cristina; Estévez‐Gay, Miquel; Osuna, Sílvia

doi:10.1002/pro.4426

Cited by 15 publications

(28 citation statements)

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“…For example, the multiple sequence alignment (MSA) generated by AlphaFold can be manipulated to reveal alternative protein conformations. [47][48][49][50] Additional information can also be extracted from the per-residue uncertainty factor called the predicted local distance difference test (pLDDT), which was shown to correlate with protein dynamics. [51][52] While confident structure prediction enabled a plethora of opportunities in protein design, such as the de novo design of backbones from random sequences via Monte Carlo "hallucination" [53] or diffusion models, [54] the reliable prediction of the structure of point mutations, lamentably, is still an unmet need.…”

Section: Sequence and Static Structure-based Methodsmentioning

confidence: 99%

“…Some of the currently popular AI structure prediction tools create valuable, sequence‐related output. For example, the multiple sequence alignment (MSA) generated by AlphaFold can be manipulated to reveal alternative protein conformations [47–50] . Additional information can also be extracted from the per‐residue uncertainty factor called the predicted local distance difference test (pLDDT), which was shown to correlate with protein dynamics [51–52] .…”

Section: Methods In Computational Enzyme Engineeringmentioning

confidence: 99%

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Curse and Blessing of Non‐Proteinogenic Parts in Computational Enzyme Engineering

Korbeld

Fürst

2023

ChemBioChem

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Enzyme engineering aims to improve or install a new function in biocatalysts for applications ranging from chemical synthesis to biomedicine. For decades, computational techniques have been developed to predict the effect of protein changes and design new enzymes. However, these techniques may have been optimized to deal with proteins composed of the standard amino acid alphabet, while the function of many enzymes relies on non‐proteogenic parts like cofactors, nucleic acids, and post‐translational modifications. Enzyme systems containing such molecules might be handled or modeled improperly by computational tools, and thus be unsuitable, or require additional tweaking, parameterization, or preparation. In this review, we give an overview of common and recent tools and workflows available to computational enzyme engineers. We highlight the various pitfalls that come with including non‐proteogenic compounds in computations and outline potential ways to address common issues. Finally, we showcase successful examples from the literature that computationally engineered such enzymes.

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Section: Sequence and Static Structure-based Methodsmentioning

confidence: 99%

Section: Methods In Computational Enzyme Engineeringmentioning

confidence: 99%

Curse and Blessing of Non‐Proteinogenic Parts in Computational Enzyme Engineering

Korbeld

Fürst

2023

ChemBioChem

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“…Inspired by these previous publications showing AF2’s ability to sample additional conformational states, we developed a template-based AF2 approach to assess the conformational heterogeneity and how this is altered by mutations on the β subunit of several tryptophan synthase enzymes (TrpB, see Figure ). − As done in the work of del Alamo et al, we tested the effect of reducing the provided number of sequences in the MSA, but we additionally assessed how AF2 predictions are altered when different templates displaying multiple conformational states are provided . We tested the template-based AF2 pipeline by providing either X-ray based or conformations extracted from MD simulations as templates.…”

Section: Application Of Af2 For Capturing Conformational Heterogeneitymentioning

confidence: 99%

“…The new FEL generated from the 10 ns MD simulations starting from the ca. 1000 AF2 outputs at different MSA is shown in a blue to red colormap on top of the computationally reconstructed FEL obtained via well-tempered multiple-walker metadynamics simulations (in gray). , The x and y axis of the reconstructed FELs indicate the Open-to-Closed (O-to-C) transition of the COMM domain of TrpB that covers the active site, and the Mean Square Deviation (MSD) from the path of the generated O-to-C structures, respectively. − The input sequence is the 0B2- pf TrpB variant . Reproduced with permission from ref .…”

Section: Application Of Af2 For Capturing Conformational Heterogeneitymentioning

confidence: 99%

“…Overview of strategies developed for predicting alternate states with AlphaFold2 (AF2). As done in del Alamo et al12 the Multiple Sequence Alignment (MSA) depth can be altered, some of the MSA positions can be masked as shown by Stein and McHaourab,13 and the MSA can be clustered as in the Kern and Ovchinnikov preprint paper.37 The provided set of templates can also be changed as done in some cases in del Alamo et al12 and also in our recent publication 34.…”

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confidence: 99%

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AlphaFold2 and Deep Learning for Elucidating Enzyme Conformational Flexibility and Its Application for Design

Casadevall

Duran

Osuna

2023

JACS Au

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The recent success of AlphaFold2 (AF2) and other deep learning (DL) tools in accurately predicting the folded three-dimensional (3D) structure of proteins and enzymes has revolutionized the structural biology and protein design fields. The 3D structure indeed reveals key information on the arrangement of the catalytic machinery of enzymes and which structural elements gate the active site pocket. However, comprehending enzymatic activity requires a detailed knowledge of the chemical steps involved along the catalytic cycle and the exploration of the multiple thermally accessible conformations that enzymes adopt when in solution. In this Perspective, some of the recent studies showing the potential of AF2 in elucidating the conformational landscape of enzymes are provided. Selected examples of the key developments of AF2-based and DL methods for protein design are discussed, as well as a few enzyme design cases. These studies show the potential of AF2 and DL for allowing the routine computational design of efficient enzymes.

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Estimating conformational heterogeneity of tryptophan synthase with a template‐based Alphafold2 approach

et al. 2022

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The three‐dimensional structure of the enzymes provides very relevant information on the arrangement of the catalytic machinery and structural elements gating the active site pocket. The recent success of the neural network Alphafold2 in predicting the folded structure of proteins from the primary sequence with high levels of accuracy has revolutionized the protein design field. However, the application of Alphafold2 for understanding and engineering function directly from the obtained single static picture is not straightforward. Indeed, understanding enzymatic function requires the exploration of the ensemble of thermally accessible conformations that enzymes adopt in solution. In the present study, we evaluate the potential of Alphafold2 in assessing the effect of the mutations on the conformational landscape of the beta subunit of tryptophan synthase (TrpB). Specifically, we develop a template‐based Alphafold2 approach for estimating the conformational heterogeneity of several TrpB enzymes, which is needed for enhanced stand‐alone activity. Our results show the potential of Alphafold2, especially if combined with molecular dynamics simulations, for elucidating the changes induced by mutation in the conformational landscapes at a rather reduced computational cost, thus revealing its plausible application in computational enzyme design.

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Estimating conformational heterogeneity of tryptophan synthase with a template‐based Alphafold2 approach

Cited by 15 publications

References 46 publications

Curse and Blessing of Non‐Proteinogenic Parts in Computational Enzyme Engineering

Curse and Blessing of Non‐Proteinogenic Parts in Computational Enzyme Engineering

AlphaFold2 and Deep Learning for Elucidating Enzyme Conformational Flexibility and Its Application for Design

Estimating conformational heterogeneity of tryptophan synthase with a template‐based Alphafold2 approach

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