ADOPT: intrinsic protein disorder prediction through deep bidirectional transformers

Redl, Istvan; Fisicaro, Carlo; Dutton, Oliver; Hoffmann, Falk; Henderson, Louie; Owens, Benjamin M. J.; Heberling, Matthew M.; Tamiola, Kamil

doi:10.1101/2022.05.25.493416

Cited by 6 publications

(30 citation statements)

References 74 publications

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“…The best approach, dubbed SETH, captured fine-grained nuances of disorder on a continuous scale and, in our hands, appeared to outperform all compared state-of-the-art methods ( (Nielsen and Mulder, 2019;Dass et al, 2020;Redl et al, 2022); Fig. 3).…”

Section: Discussionmentioning

confidence: 64%

“…It outperformed all but two (ODiNPred (Dass et al, 2020), SPOT-dis (Hanson et al, 2016)) of the methods not based on pLMs. However, all four methods introduced here (SETH, ANN, LinReg, LogReg) and ADOPT ESM-1b (Redl et al, 2022) Toward this end, we analyzed a large set of residues from 17 organisms and found the correlation between SETH's predictions and AlphaFold2's pLDDT (Fig. 5A) to be much higher than the correlation between the pLDDT and the ground truth CheZOD scores (ρ(AlphaFold2_pLDDT, ground truth)=0.56 vs. ρ(AlphaFold2_pLDDT, SETH)=0.67).…”

Section: Discussionmentioning

confidence: 99%

“…AlphaFold2 (Jumper et al, 2021) predicts a reliability for each residue prediction, namely, the pLDDT. This score and its running average over a window of consecutive residues have been claimed to predict disorder (Akdel et al, 2021;Wilson et al, 2021;Piovesan et al, 2022;Redl et al, 2022). Another objective function predicted by AlphaFold2, namely, the "experimentally resolved" prediction (Jumper et al, 2021) is likely also informative, as missing coordinates in experimental structures have been used to define disorder (Dunker et al, 1998;Monastyrskyy et al, 2014).…”

Section: Alphafold2mentioning

confidence: 99%

“…Since recent work showed that AlphaFold2 ’s (smoothed) pLDDT and (smoothed) RSA can be used to predict disorder (Akdel et al, 2021;Wilson et al, 2021;Piovesan et al, 2022;Redl et al, 2022), we tested AlphaFold2 on CheZOD scores (following the advice of John Jumper, we also analyzed “experimentally resolved” predictions). Furthermore, we investigated the agreement between the disorder predictions of our best method and the pLDDT for 17 organisms, to establish SETH as a speed-up pre-filter for AlphaFold2 .…”

Section: Introductionmentioning

confidence: 99%

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SETH predicts nuances of residue disorder from protein embeddings

Ilzhoefer

Heinzinger

Rost

2022

Preprint

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Predictions of millions of protein 3D structures are only a few clicks away since the release of AlphaFold2 results for entire data sets. However, many proteins have so-called intrinsically disordered regions (IDRs) that do not adopt unique structures in isolation. These IDRs are associated with several diseases, including Alzheimer's Disease. We showed that the absence of reliable AlphaFold2 predictions correlated only to a limited extent with IDRs. In contrast, many expert methods predict IDRs directly and reliably by combining complex machine learning models with expert-crafted input features and evolutionary information from multiple sequence alignments. Some of these input features are not always available and computationally expensive to generate, limiting their scalability. In this work, we present the novel prediction method SETH that predicts residue disorder from embeddings generated by the protein Language Model ProtT5, which explicitly only uses single sequences as input. Thereby SETH, a relatively shallow convolutional neural network, already outperformed much more complex state-of-the-art solutions while being much faster, allowing to create predictions for the human proteome in fewer than 30 minutes on a machine with one RTX A6000 GPU with 48GB RAM. Trained on a continuous disorder scale, our method captured subtle variations in disorder, thereby providing important information beyond the binary classification of other predictors. The new method is freely publicly available at: https://github.com/DagmarIlz/SETH.

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Section: Discussionmentioning

confidence: 64%

Section: Discussionmentioning

confidence: 99%

Section: Alphafold2mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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SETH predicts nuances of residue disorder from protein embeddings

Ilzhoefer

Heinzinger

Rost

2022

Preprint

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“…Different pLMs were compared (ProtT5 (23), ProSE(10), ESM-1b (54), ProtBERT (23), SeqVec (24)) with ProtT5 numerically outperforming the others. SETH outperformed all existing SOTA approaches in terms of mean AUC (area under the receiver operating characteristic curve) and Spearman correlation (0.72±0.01 for SETH vs. 0.67±0.01 for next best method ODinPred (21)) as well as similar current solutions operating on ESM-1b embeddings (52).…”

Section: Methodsmentioning

confidence: 88%

LambdaPP: Fast and accessible protein-specific phenotype predictions

Olenyi

Marquet

Heinzinger

et al. 2022

Preprint

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The availability of accurate and fast Artificial Intelligence (AI) solutions predicting aspects of proteins are revolutionizing experimental and computational molecular biology. The webserver LambdaPP aspires to supersede PredictProtein, the first internet server making AI protein predictions available in 1992. Given a protein sequence as input, LambdaPP provides easily accessible visualizations of protein 3D structure, along with predictions at the protein level (GeneOntology, subcellular location), and the residue level (binding to metal ions, small molecules, and nucleotides; conservation; intrinsic disorder; secondary structure; alpha-helical and beta-barrel transmembrane segments; signal-peptides; variant effect) in seconds. The structure prediction provided by LambdaPP - leveraging ColabFold and computed in minutes - is based on MMseqs2 multiple sequence alignments. All other feature prediction methods are based on the pLM ProtT5. Queried by a protein sequence, LambdaPP computes protein and residue predictions almost instantly for various phenotypes, including 3D structure and aspects of protein function.

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LambdaPP: Fast and accessible protein‐specific phenotype predictions

et al. 2022

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The availability of accurate and fast artificial intelligence (AI) solutions predicting aspects of proteins are revolutionizing experimental and computational molecular biology. The webserver LambdaPP aspires to supersede PredictProtein, the first internet server making AI protein predictions available in 1992.Given a protein sequence as input, LambdaPP provides easily accessible visualizations of protein 3D structure, along with predictions at the protein level (GeneOntology, subcellular location), and the residue level (binding to metal ions, small molecules, and nucleotides; conservation; intrinsic disorder; secondary structure; alpha-helical and beta-barrel transmembrane segments; signal-peptides; variant effect) in seconds. The structure prediction provided by LambdaPP-leveraging ColabFold and computed in minutes-is based on MMseqs2 multiple sequence alignments. All other feature prediction methods are based on the pLM ProtT5. Queried by a protein sequence, LambdaPP computes protein and residue predictions almost instantly for various phenotypes, including 3D structure and aspects of protein function. LambdaPP is freely available for everyone to use under embed.predictprotein.org, the interactive results for the case study can be found under https://embed.predictprotein.org/ Tobias Olenyi and Céline Marquet have equal first authorship.Christian Dallago and Burkhard Rost have equal senior authorship.

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ADOPT: intrinsic protein disorder prediction through deep bidirectional transformers

Cited by 6 publications

References 74 publications

SETH predicts nuances of residue disorder from protein embeddings

SETH predicts nuances of residue disorder from protein embeddings

LambdaPP: Fast and accessible protein-specific phenotype predictions

LambdaPP: Fast and accessible protein‐specific phenotype predictions

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