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Compact artificial neural network models for predicting protein residue - RNA base binding

  • Stanislav Selitskiy
Research Output: Chapter in Book/Report/Conference proceeding Conference contribution Peer-review

Abstract

Large Artificial Neural Network (ANN) models have demonstrated success in various domains, including general text and image generation, drug discovery, and protein-RNA (ribonucleic acid) binding tasks. However, these models typically demand substantial computational resources, time, and data for effective training. Given that such extensive resources are often inaccessible to many researchers and that life sciences data sets are frequently limited, we investigated whether small ANN models could achieve acceptable accuracy in protein-RNA prediction. We experimented with shallow feed-forward ANNs comprising two hidden layers and various non-linearities. These models did not utilize explicit structural information; instead, a sliding window approach was employed to implicitly consider the context of neighboring residues and bases. We explored different training techniques to address the issue of highly unbalanced data. Among the seven most popular non-linearities for feed-forward ANNs, only three—Rectified Linear Unit (ReLU), Gated Linear Unit (GLU), and Hyperbolic Tangent (Tanh)—yielded converging models. Common re-balancing techniques, such as under- and over-sampling of training sets, proved ineffective, whereas increasing the volume of training data and using model ensembles significantly improved performance. The optimal context window size, balancing both false negative and false positive errors, was found to be approximately 30 residues and bases. Our findings indicate that high-accuracy protein-RNA binding prediction is achievable using computing hardware accessible to most educational and research institutions.

Publication Information

Output type

Research Output: Chapter in Book/Report/Conference proceeding Conference contribution Peer-review

Original language

English

Pages from-to (Number of pages)

Pages 145-159 (15 pages)

Publication milestones

  • Published - 04/03/2025

Publication status

Published - 04/03/2025

Publisher

Springer, Japan, India, Australia, Germany, United States, United Arab Emirates, Austria, Switzerland, Italy, China, United Kingdom, Netherlands, Brazil, France, Singapore

Publication series

  • Publication series name: Lecture Notes in Computer Science
    ISSN (Print): 0302-9743
    ISSN (Electronic): 1611-3349
    Volume: 15509 LNCS
9783031824838

External Publication IDs

  • Scopus: 105000893029

Host publication title

Machine Learning, Optimization, and Data Science - 10th International Conference, LOD 2024, Revised Selected Papers

Host publication editors

  • Giuseppe Nicosia
  • Varun Ojha
  • Sven Giesselbach
  • M. Panos Pardalos
  • Renato Umeton