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Main Authors: Suyunu, Burak, Dolu, Özdeniz, Olaosebikan, Ibukunoluwa Abigail, Bristow, Hacer Karatas, Özgür, Arzucan
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.08838
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author Suyunu, Burak
Dolu, Özdeniz
Olaosebikan, Ibukunoluwa Abigail
Bristow, Hacer Karatas
Özgür, Arzucan
author_facet Suyunu, Burak
Dolu, Özdeniz
Olaosebikan, Ibukunoluwa Abigail
Bristow, Hacer Karatas
Özgür, Arzucan
contents Proteins are the essential drivers of biological processes. At the molecular level, they are chains of amino acids that can be viewed through a linguistic lens where the twenty standard residues serve as an alphabet combining to form a complex language, referred to as the language of life. To understand this language, we must first identify its fundamental units. Analogous to words, these units are hypothesized to represent an intermediate layer between single residues and larger domains. Crucially, just as protein diversity arises from evolution, these units should inherently reflect evolutionary relationships. We introduce PUMA (Protein Units via Mutation-Aware Merging) to discover these evolutionarily meaningful units. PUMA employs an iterative merging algorithm guided by substitution matrices to identify protein units and organize them into families linked by plausible mutations. This process creates a hierarchical genealogy where parent units and their mutational variants coexist, simultaneously producing a unit vocabulary and the genealogical structure connecting them. We validate that PUMA families are biologically meaningful; mutations within a PUMA family correlate with clinically benign variants and with high-scoring mutations in high-throughput assays. Furthermore, these units align with the contextual preferences of protein language models and map to known functional annotations. PUMA's genealogical framework provides evolutionarily grounded units, offering a structured approach for understanding the language of life.
format Preprint
id arxiv_https___arxiv_org_abs_2503_08838
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle PUMA: Discovery of Protein Units via Mutation-Aware Merging
Suyunu, Burak
Dolu, Özdeniz
Olaosebikan, Ibukunoluwa Abigail
Bristow, Hacer Karatas
Özgür, Arzucan
Computation and Language
Quantitative Methods
Proteins are the essential drivers of biological processes. At the molecular level, they are chains of amino acids that can be viewed through a linguistic lens where the twenty standard residues serve as an alphabet combining to form a complex language, referred to as the language of life. To understand this language, we must first identify its fundamental units. Analogous to words, these units are hypothesized to represent an intermediate layer between single residues and larger domains. Crucially, just as protein diversity arises from evolution, these units should inherently reflect evolutionary relationships. We introduce PUMA (Protein Units via Mutation-Aware Merging) to discover these evolutionarily meaningful units. PUMA employs an iterative merging algorithm guided by substitution matrices to identify protein units and organize them into families linked by plausible mutations. This process creates a hierarchical genealogy where parent units and their mutational variants coexist, simultaneously producing a unit vocabulary and the genealogical structure connecting them. We validate that PUMA families are biologically meaningful; mutations within a PUMA family correlate with clinically benign variants and with high-scoring mutations in high-throughput assays. Furthermore, these units align with the contextual preferences of protein language models and map to known functional annotations. PUMA's genealogical framework provides evolutionarily grounded units, offering a structured approach for understanding the language of life.
title PUMA: Discovery of Protein Units via Mutation-Aware Merging
topic Computation and Language
Quantitative Methods
url https://arxiv.org/abs/2503.08838