Evolution of sequence traits of prion-like proteins linked to amyotrophic lateral sclerosis (ALS)

Luo, Jie; Harrison, Paul M.

doi:10.7717/peerj.14417

Cited by 2 publications

(1 citation statement)

References 69 publications

(96 reference statements)

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“…As a representative example, SGnn has been recently used by Harrison and coworkers to predict whether ortholog sequences from metazoans and plants can be recruited into SGs [113].…”

Section: Sgnn: a Server For The Prediction Of Prion-like Domains Recr...mentioning

confidence: 99%

A Review of Fifteen Years Developing Computational Tools to Study Protein Aggregation

et al. 2023

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The presence of insoluble protein deposits in tissues and organs is a hallmark of many human pathologies. In addition, the formation of protein aggregates is considered one of the main bottlenecks to producing protein-based therapeutics. Thus, there is a high interest in rationalizing and predicting protein aggregation. For almost two decades, our laboratory has been working to provide solutions for these needs. We have traditionally combined the core tenets of both bioinformatics and wet lab biophysics to develop algorithms and databases to study protein aggregation and its functional implications. Here, we review the computational toolbox developed by our lab, including programs for identifying sequential or structural aggregation-prone regions at the individual protein and proteome levels, engineering protein solubility, finding and evaluating prion-like domains, studying disorder-to-order protein transitions, or categorizing non-conventional amyloid regions of polar nature, among others. In perspective, the succession of the tools we describe illustrates how our understanding of the protein aggregation phenomenon has evolved over the last fifteen years.

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“…As a representative example, SGnn has been recently used by Harrison and coworkers to predict whether ortholog sequences from metazoans and plants can be recruited into SGs [113].…”

Section: Sgnn: a Server For The Prediction Of Prion-like Domains Recr...mentioning

confidence: 99%

A Review of Fifteen Years Developing Computational Tools to Study Protein Aggregation

et al. 2023

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Optimizing strategy for the discovery of compositionally-biased or low-complexity regions in proteins

Harrison

2024

Sci Rep

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Proteins can contain tracts dominated by a subset of amino acids and that have a functional significance. These are often termed ‘low-complexity regions’ (LCRs) or ‘compositionally-biased regions’ (CBRs). However, a wide spectrum of compositional bias is possible, and program parameters used to annotate these regions are often arbitrarily chosen. Also, investigators are sometimes interested in longer regions, or sometimes very short ones. Here, two programs for annotating LCRs/CBRs, namely SEG and fLPS, are investigated in detail across the whole expanse of their parameter spaces. In doing so, boundary behaviours are resolved that are used to derive an optimized systematic strategy for annotating LCRs/CBRs. Sets of parameters that progressively annotate or ‘cover’ more of protein sequence space and are optimized for a given target length have been derived. This progressive annotation can be applied to discern the biological relevance of CBRs, e.g., in parsing domains for experimental constructs and in generating hypotheses. It is also useful for picking out candidate regions of interest of a given target length and bias signature, and for assessing the parameter dependence of annotations. This latter application is demonstrated for a set of human intrinsically-disordered proteins associated with cancer.

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Evolution of sequence traits of prion-like proteins linked to amyotrophic lateral sclerosis (ALS)

Cited by 2 publications

References 69 publications

A Review of Fifteen Years Developing Computational Tools to Study Protein Aggregation

A Review of Fifteen Years Developing Computational Tools to Study Protein Aggregation

Optimizing strategy for the discovery of compositionally-biased or low-complexity regions in proteins

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