Identification of pathogenic missense mutations using protein stability predictors

Gerasimavicius, Lukas; Liu, Xin; Marsh, Joseph A.

doi:10.1101/2020.06.11.146068

Cited by 17 publications

(31 citation statements)

References 78 publications

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“…Our previous study on the identification of pathogenic mutations with protein stability predictors considered only monomeric proteins, in particular because many of the predictors we tested work only for single polypeptide chains 17 . As the dataset used in this study was derived from both monomeric and complex structures, we first investigated the impact of using full structures.…”

Section: Consideration Of Full Protein Complex Structures Improves the Identification Of Disease Mutationsmentioning

confidence: 99%

“…While these methods were not specifically designed for the identification of pathogenic variants, they are routinely used when evaluating candidate mutations [10][11][12][13] in order to identify those that are damaging to protein structure and will thus cause a loss of function (LOF) [14][15][16] . Alternatively, increased protein stabilisation can also be associated with disease, and it has been shown that using the absolute ΔΔG values results in higher accuracy when identifying disease mutations, although this may also be due to predictor inability to correctly distinguish the direction of the effect 17,18 . Interestingly, a recent study found that stability predictors performed much better in the identification of pathogenic missense mutations in genes associated with haploinsufficiency 19 , supporting the utility of stability predictors for identifying LOF mutations.…”

Section: Introductionmentioning

confidence: 99%

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Loss-of-function, gain-of-function and dominant-negative mutations have profoundly different effects on protein structure: implications for variant effect prediction

Gerasimavicius

Livesey

Marsh

2021

Preprint

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Most known pathogenic mutations occur in protein-coding regions of DNA and change the way proteins are made. Taking protein structure into account has therefore provided great insight into the molecular mechanisms underlying human genetic disease. While there has been much focus on how mutations can disrupt protein structure and thus cause a loss of function (LOF), alternative mechanisms, specifically dominant-negative (DN) and gain-of-function (GOF) effects, are less understood. Here, we have investigated the protein-level effects of pathogenic missense mutations associated with different molecular mechanisms. We observe striking differences between recessive vs dominant, and LOF vs non-LOF mutations, with dominant, non-LOF disease mutations having much milder effects on protein structure, and DN mutations being highly enriched at protein interfaces. We also find that nearly all computational variant effect predictors underperform on non-LOF mutations, even those based solely on sequence conservation. However, we do find that non-LOF mutations could potentially be identified by their tendency to cluster in space. Overall, our work suggests that many pathogenic mutations that act via DN and GOF mutations are likely being missed by current variant prioritisation strategies, but that there is considerable scope to improve computational predictions through consideration of molecular disease mechanisms.

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Section: Consideration Of Full Protein Complex Structures Improves the Identification Of Disease Mutationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Loss-of-function, gain-of-function and dominant-negative mutations have profoundly different effects on protein structure: implications for variant effect prediction

Gerasimavicius

Livesey

Marsh

2021

Preprint

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“…One mechanism by which a missense mutation can exert a pathogenic effect is by destabilizing the protein in which it is located, leading to deficiency of the protein, not just its enzymatic activity (1)(2)(3)(4)(5). A smaller amount of the protein is then available to carry out its function, particularly since the destabilized protein is more likely to be cleared by quality control machinery (6)(7)(8).…”

Section: Introductionmentioning

confidence: 99%

Protein structural features predict responsiveness to pharmacological chaperone treatment for three lysosomal storage disorders

Woodard

Zheng

Zhang

2021

Preprint

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Three-dimensional structures of proteins can provide important clues into the efficacy of personalized treatment. We perform a structural analysis of variants within three inherited lysosomal storage disorders, comparing variants responsive to pharmacological chaperone treatment to those unresponsive to such treatment. We find that predicted ΔΔG of mutation is higher on average for variants unresponsive to treatment, in the case of datasets for both Fabry disease and Pompe disease, in line with previous findings. Using both a single decision tree and an advanced machine learning approach based on the larger Fabry dataset, we correctly predict responsiveness of three Gaucher disease variants, and we provide predictions for untested variants. Many variants are predicted to be responsive to treatment, suggesting that drug-based treatments may be effective for a number of variants in Gaucher disease. In our analysis, we observe dependence on a topological feature reporting on contact arrangements which is likely connected to the order of folding of protein residues, and we provide a potential justification for this observation based on steady-state cellular kinetics.Author summaryPharmacological chaperones are small molecule drugs that bind to proteins to help stabilize the folded state. One set of diseases for which this treatment has been effective is the lysosomal storage disorders, which are caused by defective lysosomal enzymes. However, not all genotypes are equally responsive to treatment. For instance, missense mutants that are particularly destabilized relative to WT are less likely to respond. The availability of datasets containing responsiveness data for large numbers of mutants, along with crystal structures of the protein involved in each disease, make machine learning methods incorporating sequence-based and structural data feasible. We hypothesize that data from two diseases, Fabry and Pompe disease, may be useful for predicting responsiveness of variants in the related Gaucher disease. Results suggest that many rare variants in Gaucher disease could be amenable to existing drugs. Results suggest that drug responsiveness depends on protein topology is such a way that mutations in early-to-fold residues are more likely to be non-responsive to pharmacological chaperone treatment, which is consistent with a simple kinetic model of stability rescue. This study provides an example of how machine learning can be used to inform further studies towards personalized treatment in medicine.

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“…This is consistent with the observations from Figures 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, and 17, which do not show any consistent changes in the overall protein structures upon mutation, precluding any further statistical analysis. While we did not find overall principles that can be used to classify WT and oncogenic variables in this dataset, the judicious use of 3D structure prediction methods remains a valuable tool to understand oncogenic mutations further, as demonstrated previously [11,12,32,33,34,35]. We recognize that comparing these results with those that could be obtained from neutral non-pathogenic variants could provide more details on the problem and perhaps could help in differentiating the structural effects in different types of variants.…”

Section: Discussionmentioning

confidence: 62%

Understanding protein structural changes for oncogenic missense variants

Hernandez

Facelli

2021

Heliyon

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Understanding and predicting the changes of protein structure and function upon mutation and their relationship to human health is a critical element to translate the genomic revolution into actionable interventions. Therefore, it is pertinent to explore how mutations result in structural changes leading to pathogenic proteins, but due to the protein structural knowledge gap, experimental approaches are lacking. Protein structure prediction methods, such as I-TASSER, have made it possible to predict the structure of a given amino acid sequence, thus opening a new way to explore protein structure changes upon mutations when experimental information is not available. Using known mutations from the Catalogue of Somatic Mutation in Cancer (COSMIC) and ClinVar databases, we compare predicted structure-derived properties from wild type (WT) and mutated proteins and find differences between the local and global 3D protein structures of the WT and the mutants. The studies in this relatively small sample reveal that the structural changes are quite diverse.

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Identification of pathogenic missense mutations using protein stability predictors

Cited by 17 publications

References 78 publications

Loss-of-function, gain-of-function and dominant-negative mutations have profoundly different effects on protein structure: implications for variant effect prediction

Loss-of-function, gain-of-function and dominant-negative mutations have profoundly different effects on protein structure: implications for variant effect prediction

Protein structural features predict responsiveness to pharmacological chaperone treatment for three lysosomal storage disorders

Understanding protein structural changes for oncogenic missense variants

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