Loss-functions matter, on optimizing score functions for the estimation of protein models accuracy

Sidi, Tomer; Keasar, Chen

doi:10.1101/651349

Cited by 3 publications

References 35 publications

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Protein model quality assessment using rotation‐equivariant transformations on point clouds

et al. 2023

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Machine learning research concerning protein structure has seen a surge in popularity over the last years with promising advances for basic science and drug discovery. Working with macromolecular structure in a machine learning context requires an adequate numerical representation, and researchers have extensively studied representations such as graphs, discretized 3D grids, and distance maps. As part of CASP14, we explored a new and conceptually simple representation in a blind experiment: atoms as points in 3D, each with associated features. These features-initially just the basic element type of each atom-are updated through a series of neural network layers featuring rotationequivariant convolutions. Starting from all atoms, we further aggregate information at the level of alpha carbons before making a prediction at the level of the entire protein structure. We find that this approach yields competitive results in protein model quality assessment despite its simplicity and despite the fact that it incorporates minimal prior information and is trained on relatively little data. Its performance and generality are particularly noteworthy in an era where highly complex, customized machine learning methods such as AlphaFold 2 have come to dominate protein structure prediction.

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Protein model quality assessment using rotation‐equivariant transformations on point clouds

et al. 2023

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Analysis of X-Ray Images of the Lungs Using a Neural Network

Pronina

Levytska

Fedosova

et al. 2021

New Technologies, Development and Application IV

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Estimation of model accuracy by a unique set of features and tree-based regressor

Bitton

Keasar

2022

Sci Rep

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Computationally generated models of protein structures bridge the gap between the practically negligible price tag of sequencing and the high cost of experimental structure determination. By providing a low-cost (and often free) partial alternative to experimentally determined structures, these models help biologists design and interpret their experiments. Obviously, the more accurate the models the more useful they are. However, methods for protein structure prediction generate many structural models of various qualities, necessitating means for the estimation of their accuracy. In this work we present MESHI_consensus, a new method for the estimation of model accuracy. The method uses a tree-based regressor and a set of structural, target-based, and consensus-based features. The new method achieved high performance in the EMA (Estimation of Model Accuracy) track of the recent CASP14 community-wide experiment (https://predictioncenter.org/casp14/index.cgi). The tertiary structure prediction track of that experiment revealed an unprecedented leap in prediction performance by a single prediction group/method, namely AlphaFold2. This achievement would inevitably have a profound impact on the field of protein structure prediction, including the accuracy estimation sub-task. We conclude this manuscript with some speculations regarding the future role of accuracy estimation in a new era of accurate protein structure prediction.

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Loss-functions matter, on optimizing score functions for the estimation of protein models accuracy

Cited by 3 publications

References 35 publications

Protein model quality assessment using rotation‐equivariant transformations on point clouds

Protein model quality assessment using rotation‐equivariant transformations on point clouds

Analysis of X-Ray Images of the Lungs Using a Neural Network

Estimation of model accuracy by a unique set of features and tree-based regressor

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