The landscape of tolerated genetic variation in humans and primates

Gao, Hong; Hamp, Tobias; Ede, Jeffrey M.; Schraiber, Joshua G.; McRae, Jeremy F.; Singer-Berk, Moriel; Yang, Yanshen; Dietrich, Anastasia S. D.; Fiziev, Petko; Kuderna, Lukas F. K.; Sundaram, Laksshman; Wu, Yibing; Adhikari, Aashish N.; Field, Yair; Chen, Chen; Batzoglou, Serafim; Aguet, François; Lemire, Gabrielle; Reimers, Rebecca; Balick, Daniel J.; Janiak, Mareike C.; Kuhlwilm, Martin; Orkin, Joseph D.; Manu, Shivakumara; Valenzuela, Alejandro; Bergman, Juraj; Rousselle, Marjolaine; Silva, Felipe Ennes; Águeda, Lídia; Blanc, Julie; Gut, Marta; Vries, Dorien de; Goodhead, Ian; Harris, R. Alan; Raveendran, Muthuswamy; Jensen, Axel; Chuma, Idrissa S.; Horvath, Julie E.; Hvilsom, Christina; Juan, David; Frandsen, Peter; Melo, Fabiano Rodrigues de; Bertuol, Fabrício; Byrne, Hazel; Sampaio, Iracilda; Farias, Izeni Pires; Valsecchi, João; Messias, Mariluce Rezende; Silva, Maria Nazareth Ferreira da; Trivedi, M. C.; Rossi, Rogério Vieira; Hrbek, Tomas; Andriaholinirina, Nicole; Rabarivola, Clément; Zaramody, Alphonse; Jolly, Clifford J.; Phillips‐Conroy, Jane E.; Wilkerson, Gregory K.; Abee, Christian R.; Simmons, Joe H.; Fernández-Duque, Eduardo; Kanthaswamy, Sree; Shiferaw, Fekadu; Wu, Dong‐Dong; Zhou, Lecong; Shao, Yong; Keyyu, Julius D.; Knauf, Sascha; Minh, Le Quoc; Lizano, Esther; Merker, Stefan; Navarro, Arcadi; Bataillon, Thomas; Nadler, Tilo; Khor, Chiea Chuen; Lee, Jessica; Tan, Patrick; Lim, Weng Khong; Kitchener, Andrew C.; Zinner, Dietmar; Gut, Ivo; Melin, Amanda D.; Guschanski, Katerina; Schierup, Mikkel H.; Beck, Robin M. D.; Umapathy, Govindhaswamy; Roos, Christian; Boubli, Jean P.; Lek, Monkol; Sunyaev, Shamil; O’Donnell-Luria, Anne; Rehm, Heidi L.; Xu, Jinbo; Rogers, Jeffrey; Marquès‐Bonet, Tomàs; Farh, Kyle Kai‐How

doi:10.1126/science.abn8197

Cited by 66 publications

(35 citation statements)

References 153 publications

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“…In the past decade, many computaQonal methods have been developed [11][12][13][14][15][16][17][18][19][20][21][22] to predict variant effects in a binary manner aiming at disQnguishing pathogenic and benign variants. These methods showed that pathogenicity can be predicted by manually encoded or self-learned features based on sequence conservaQon, protein structures, and populaQon allele frequency.…”

Section: Mainmentioning

confidence: 99%

PreMode predicts mode-of-action of missense variants by deep graph representation learning of protein sequence and structural context

Zhong,

Zhao,

Zhuang

et al. 2024

Preprint

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Accurate prediction of the functional impact of missense variants is fundamentally important for disease gene discovery, clinical genetic diagnostics, therapeutic strategies, and protein engineering. Previous efforts have focused on predicting a binary pathogenicity classification, but the functional impact of missense variants is multi-dimensional. Pathogenic missense variants in the same gene may act through different modes of action (i.e., gain/loss-of-function) by affecting multiple protein biochemical properties. They may result in distinct clinical conditions that require different treatments. We developed a new method, PreMode, to perform gene-specific mode-of-action predictions. PreMode models effects of coding sequence variants using SE(3)-equivariant graph neural networks on protein sequences and structures. Using the largest-to-date set of mode-of-action-labeled missense variants, we show that PreMode reaches state-of-the-art performance in multiple types of mode-of-action predictions by efficient transfer-learning. Additionally, PreMode prediction of G/LoF variants in a kinase is consistent with inactive-active conformation transition. Finally, we show that PreMode enables improved mutagenesis analysis, clinical diagnosis and more broadly, artificial GoF engineering of proteins.

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Section: Mainmentioning

confidence: 99%

PreMode predicts mode-of-action of missense variants by deep graph representation learning of protein sequence and structural context

Zhong,

Zhao,

Zhuang

et al. 2024

Preprint

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show abstract

“…Newly described in a publication in Science, Primate-AI3D is a deep learning model that leverages natural variation in primates to make inferences about the impact of DNA variants in humans (Gao et al, 2023). Built on the premise that protein-altering variants commonly found in any non-human primate have been tolerated by natural selection-and are thus likely benign in humans-Primate-AI3D uses deep learning to map genetic variants onto 3D protein structures partially derived from AlphaFold (Jumper et al, 2021) to make predictions about their pathogenicity.…”

Section: Clinical Classification Of Sequence Variantsmentioning

confidence: 99%

Applications of artificial intelligence in clinical laboratory genomics

Aradhya

Facio

Metz

et al. 2023

American J of Med Genetics Pt C

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The transition from analog to digital technologies in clinical laboratory genomics is ushering in an era of “big data” in ways that will exceed human capacity to rapidly and reproducibly analyze those data using conventional approaches. Accurately evaluating complex molecular data to facilitate timely diagnosis and management of genomic disorders will require supportive artificial intelligence methods. These are already being introduced into clinical laboratory genomics to identify variants in DNA sequencing data, predict the effects of DNA variants on protein structure and function to inform clinical interpretation of pathogenicity, link phenotype ontologies to genetic variants identified through exome or genome sequencing to help clinicians reach diagnostic answers faster, correlate genomic data with tumor staging and treatment approaches, utilize natural language processing to identify critical published medical literature during analysis of genomic data, and use interactive chatbots to identify individuals who qualify for genetic testing or to provide pre‐test and post‐test education. With careful and ethical development and validation of artificial intelligence for clinical laboratory genomics, these advances are expected to significantly enhance the abilities of geneticists to translate complex data into clearly synthesized information for clinicians to use in managing the care of their patients at scale.

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“…Another application of ML models is to predict the effect of genetic variants by learning the mapping between DNA sequence and functional genomic annotations. Specifically, PrimateAI 114 and its successor PrimateAI‐3D 115 predict whether genetic variants observed in humans are likely to be deleterious or benign based on whether the variant is common in non‐human primate populations. The underlying premise being that if a variant is tolerated in species closely related to humans, it is more likely to be benign in humans as well.…”

Section: Translating Between Speciesmentioning

confidence: 99%

Artificial intelligence for neurodegenerative experimental models

Marzi,

Schilder,

Nott

et al. 2023

Alzheimer's & Dementia

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INTRODUCTIONExperimental models are essential tools in neurodegenerative disease research. However, the translation of insights and drugs discovered in model systems has proven immensely challenging, marred by high failure rates in human clinical trials.METHODSHere we review the application of artificial intelligence (AI) and machine learning (ML) in experimental medicine for dementia research.RESULTSConsidering the specific challenges of reproducibility and translation between other species or model systems and human biology in preclinical dementia research, we highlight best practices and resources that can be leveraged to quantify and evaluate translatability. We then evaluate how AI and ML approaches could be applied to enhance both cross‐model reproducibility and translation to human biology, while sustaining biological interpretability.DISCUSSIONAI and ML approaches in experimental medicine remain in their infancy. However, they have great potential to strengthen preclinical research and translation if based upon adequate, robust, and reproducible experimental data.Highlights There are increasing applications of AI in experimental medicine. We identified issues in reproducibility, cross‐species translation, and data curation in the field. Our review highlights data resources and AI approaches as solutions. Multi‐omics analysis with AI offers exciting future possibilities in drug discovery.

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The landscape of tolerated genetic variation in humans and primates

Cited by 66 publications

References 153 publications

PreMode predicts mode-of-action of missense variants by deep graph representation learning of protein sequence and structural context

PreMode predicts mode-of-action of missense variants by deep graph representation learning of protein sequence and structural context

Applications of artificial intelligence in clinical laboratory genomics

Artificial intelligence for neurodegenerative experimental models

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