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Related Concept Videos

Improving Translational Accuracy02:07

Improving Translational Accuracy

Base complementarity between the three base pairs of mRNA codon and the tRNA anticodon is not a failsafe mechanism. Inaccuracies can range from a single mismatch to no correct base pairing at all. The free energy difference between the correct and nearly correct base pairs can be as small as 3 kcal/ mol. With complementarity being the only proofreading step, the estimated error frequency would be one wrong amino acid in every 100 amino acids incorporated. However, error frequencies observed in...
Improving Translational Accuracy02:07

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Base complementarity between the three base pairs of mRNA codon and the tRNA anticodon is not a failsafe mechanism. Inaccuracies can range from a single mismatch to no correct base pairing at all. The free energy difference between the correct and nearly correct base pairs can be as small as 3 kcal/ mol. With complementarity being the only proofreading step, the estimated error frequency would be one wrong amino acid in every 100 amino acids incorporated. However, error frequencies observed in...
Overview of Transposition and Recombination02:13

Overview of Transposition and Recombination

Transposons make up a significant part of genomes of various organisms. Therefore, it is believed that transposition played a major evolutionary role in speciation by changing genome sizes and modifying gene expression patterns. For example, in bacteria, transposition can lead to conferring antibiotic resistance. Movement of transposable elements within the genetic pool of pathogenic bacteria can aid in transfer of antibiotic-resistant genetic elements. In eukaryotes, transposons can carry out...
Transduction01:16

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Among the three main modes of HGT—transformation, conjugation, and transduction—transduction is unique in that it is mediated by bacteriophages, or bacterial viruses.Transduction occurs in two ways. Generalized transduction occurs during the lytic cycle of a bacteriophage infection. In this process, bacteriophages infect bacterial cells, replicate within them, and ultimately cause cell lysis, releasing newly assembled virions. Occasionally, random fragments of the bacterial genome are...
Survival Tree01:19

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Mutation, Gene Flow, and Genetic Drift

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Related Experiment Video

Updated: Jun 23, 2026

Generating the Transcriptional Regulation View of Transcriptomic Features for Prediction Task and Dark Biomarker Detection on Small Datasets
03:37

Generating the Transcriptional Regulation View of Transcriptomic Features for Prediction Task and Dark Biomarker Detection on Small Datasets

Published on: March 1, 2024

Fitness translocation: improving variant effect prediction with biologically-grounded data augmentation.

Adrien Mialland1, Shuzo Fukunaga2, Riku Katsuki3

  • 1Artificial Intelligence Research Center, National Institute of Advanced Industrial Science and Technology (AIST), Tokyo, Japan.

Bioinformatics (Oxford, England)
|June 21, 2026
PubMed
Summary

Fitness translocation enhances protein variant effect prediction by creating synthetic data from homologous proteins. This data augmentation strategy improves model accuracy, especially with limited training data.

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In Vivo Functional Study of Disease-associated Rare Human Variants Using Drosophila
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Last Updated: Jun 23, 2026

Generating the Transcriptional Regulation View of Transcriptomic Features for Prediction Task and Dark Biomarker Detection on Small Datasets
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Published on: August 20, 2019

Area of Science:

  • Biochemistry and Molecular Biology
  • Computational Biology
  • Protein Engineering

Background:

  • Protein fitness landscape characterization and variant effect prediction are hindered by data scarcity.
  • Existing methods struggle with limited datasets, impacting protein engineering advancements.

Purpose of the Study:

  • To introduce fitness translocation, a novel data augmentation strategy for protein variant effect prediction.
  • To address data scarcity challenges in characterizing protein fitness landscapes.

Main Methods:

  • Fitness translocation leverages variant fitness data from homologous proteins to generate synthetic variants for a target protein.
  • Protein language model embeddings are used to compute variant differences and create synthetic variants in embedding space.
  • The method involves applying fitness offsets from homolog variants to the target wild-type embedding.

Main Results:

  • Fitness translocation consistently improves predictive performance across different protein families (IGPS, GFP, SARS-CoV-2 spike proteins).
  • The strategy is particularly effective in low-data regimes, enhancing variant effect prediction accuracy.
  • The method demonstrates efficacy even when augmenting with remote homologs (as low as 35% sequence identity).

Conclusions:

  • Fitness translocation expands and diversifies protein fitness landscapes through biologically grounded data augmentation.
  • This approach supports more data-efficient protein engineering by improving variant effect prediction models.
  • The study highlights the potential of leveraging homologous protein data for enhanced predictive modeling.