Deep Learning in Pharmacogenomics: From Gene Regulation to Patient Stratification

Kalinin, Alexandr A.; Higgins, Gerald A.; Reamaroon, Narathip; Soroushmehr, S. M. Reza; Allyn-Feuer, Ari; Dinov, Ivo D.; Najarian, Kayvan; Athey, Brian D.

doi:10.2217/pgs-2018-0008

Cited by 144 publications

(92 citation statements)

References 132 publications

(201 reference statements)

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“…We propose that modelling the 4D Nucleome dynamics, 4D mRNA distribution and actomyosin forces that regulate tight junction protein expression and function will predict the self‐organizing of epithelial cells in a cell type‐, developmental stage‐specific manner. This information will be useful in generating a precise mathematical model of human colon crypts, which could be employed as a powerful algorithm to help design precision medicine approaches for targeted, disease‐specific treatments in a variety of medical ailments, including functional bowel disorders (FBD) and colorectal cancer (CRC) …”

Section: General Hypothesismentioning

confidence: 99%

“…This information will be useful in generating a precise mathematical model of human colon crypts, which could be employed as a powerful algorithm to help design precision medicine approaches for targeted, disease-specific treatments in a variety of medical ailments, including functional bowel disorders (FBD) and colorectal cancer (CRC). 5,12,[14][15][16] To generate "proof of concept" data, we tracked the formation of a coordinated epithelial cell sheet during Caco-2 cell differentiation on a smooth, flat and hard glass surface that recapitulates known gene expression patterns that occur along the colon crypt axis. Detailed indepth description and discussion of the rotational 3D mechanogenomic Turing patterns observed during differentiation are included in the supplementary and online material ( Figure 1 and S1) (http:// www.socr.umich.edu/projects/3d-cell-morphometry/data.html).…”

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confidence: 99%

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Hypothesis: Caco‐2 cell rotational 3D mechanogenomic turing patterns have clinical implications to colon crypts

Zheng

Kalinin

Dinov

et al. 2018

J Cellular Molecular Medi

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Colon crypts are recognized as a mechanical and biochemical Turing patterning model. Colon epithelial Caco‐2 cell monolayer demonstrated 2D Turing patterns via force analysis of apical tight junction live cell imaging which illuminated actomyosin meshwork linking the actomyosin network of individual cells. Actomyosin forces act in a mechanobiological manner that alters cell/nucleus/tissue morphology. We observed the rotational motion of the nucleus in Caco‐2 cells that appears to be driven by actomyosin during the formation of a differentiated confluent epithelium. Single‐ to multi‐cell ring/torus‐shaped genomes were observed prior to complex fractal Turing patterns extending from a rotating torus centre in a spiral pattern consistent with a gene morphogen motif. These features may contribute to the well‐described differentiation from stem cells at the crypt base to the luminal colon epithelium along the crypt axis. This observation may be useful to study the role of mechanogenomic processes and the underlying molecular mechanisms as determinants of cellular and tissue architecture in space and time, which is the focal point of the 4D nucleome initiative. Mathematical and bioengineer modelling of gene circuits and cell shapes may provide a powerful algorithm that will contribute to future precision medicine relevant to a number of common medical disorders.

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Section: General Hypothesismentioning

confidence: 99%

mentioning

confidence: 99%

Hypothesis: Caco‐2 cell rotational 3D mechanogenomic turing patterns have clinical implications to colon crypts

Zheng

Kalinin

Dinov

et al. 2018

J Cellular Molecular Medi

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“…This research emphasizes the role of the regulatory genome, including enhancer and superenhancer-based interactomes, as an approach that provides insight into pharmacogenomic network mechanisms (22)(23)(24)(25). It differs from pathway modeling methods in which altered protein folding based on missense codon variants and fixed signaling pathways serve as the foundation for the interpretation of the molecular substrate of ketamine response in humans.…”

Section: The Ketamine Pharmacogenomic Sub-networkmentioning

confidence: 99%

“…The ketamine response workflow is based on the pharmacoepigenomics informatics pipeline (PIP) (22)(23)(24)(25). Input genes to the data analysis pipeline first included those genes that encode proteins and constituents of macromolecular protein complexes obtained from past studies of the binding affinity of (R, S)-ketamine, R-ketamine and S-ketamine performed in microsomal and tissue preparations in rodents and humans.…”

Section: Selection Of Ketamine-response Genesmentioning

confidence: 99%

“…Our strategy analyzed disparate data from multiple scales of biological function combining bioinformatics, computational medicine and machine learning (22)(23)(24)(25). GWAS SNPs provided insight into the phenotypic consequences of the mutational alterations and variation within disease sub-networks impacted by ketamine, spatial interactions within chromatin that control expression of ketamine-response genes, and mesoscale functional neurocircuits within human brain regions that are rapidly activated following ketamine administration (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

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Ketamine’s pharmacogenomic network in human brain contains sub-networks associated with glutamate neurotransmission and with neuroplasticity

Higgins

Handelman

Allyn-Feurer

et al. 2020

Preprint

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The pharmacogenomic network responsible for the rapid antidepressant action of ketamine and concomitant adverse events in patients has been poorly defined. Integrative, multiscale biological data analytics helps explain ketamine's action. Using a validated computational pipeline, candidate ketamine-response genes and regulatory RNAs from published literature, binding affinity studies, and single nucleotide polymorphisms (SNPs) from genomewide association studies (GWAS), we identified 108 SNPs associated with 110 genes and regulatory RNAs. All of these SNPs are classified as enhancers, and additional chromatin interaction mapping in human neural cell lines and tissue shows enhancer-promoter interactions involving other network members. Pathway analysis and gene set optimization identified three composite sub-networks within the broader ketamine pharmacogenomic network. Expression patterns of ketamine network genes within the postmortem human brain are concordant with ketamine neurocircuitry based on the results of 24 published functional neuroimaging studies. The ketamine pharmacogenomic network is enriched in forebrain regions known to be rapidly activated by ketamine, including cingulate cortex and frontal cortex, and is significantly regulated by ketamine (p=6.26E-33; Fisher's exact test). The ketamine pharmacogenomic network can be partitioned into distinct enhancer sub-networks associated with: (1) glutamate neurotransmission, chromatin remodeling, smoking behavior, schizophrenia, pain, nausea, vomiting, and post-operative delirium; (2) neuroplasticity, depression, and alcohol consumption; and (3) pharmacokinetics. The component sub-networks explain the diverse action mechanisms of ketamine and its analogs.These results may be useful for optimizing pharmacotherapy in patients diagnosed with depression, pain or related stress disorders. GRIA4 (12), and many other known (8,13) and unknown pharmacodynamic targets within human brain. Ketamine and its metabolites strongly induce the expression of the CYP2B6 gene in human brain, which encodes a drug metabolizing enzyme that contributes to first-and second-pass metabolism of the drug and its metabolites (14). Recent genomewide association studies (GWAS) in humans demonstrate association of ketamine response and adverse events with enhancers of genes and long non-coding RNAs (lncRNAs) related to the roundabout guidance receptor 2 (ROBO2) gene, whose product binds members of the slit guidance ligand family (SLIT1, SLIT2) that are involved in dendrite guidance and synaptic plasticity (15,16). Like phencyclidine, a structurally related compound, ketamine induces acute dissociation, with both drugs exhibiting species-specific differences in response. In sum, the central nervous system (CNS) pathway(s) responsible for the rapid antidepressant effects of ketamine and its enantiomers in patients diagnosed with treatment-resistant depression (TRD) remain poorly defined, including emergence of on-and off-target effects and individual differences in response and adverse eve...

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Predictive Patient Stratification Using Artificial Intelligence and Machine Learning

Nguyen,

T. Giang,

T. Pham

et al. 2024

Big Data Analysis and Artificial Intelligence for Medical Sciences

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Deep Learning in Pharmacogenomics: From Gene Regulation to Patient Stratification

Cited by 144 publications

References 132 publications

Hypothesis: Caco‐2 cell rotational 3D mechanogenomic turing patterns have clinical implications to colon crypts

Hypothesis: Caco‐2 cell rotational 3D mechanogenomic turing patterns have clinical implications to colon crypts

Ketamine’s pharmacogenomic network in human brain contains sub-networks associated with glutamate neurotransmission and with neuroplasticity

Predictive Patient Stratification Using Artificial Intelligence and Machine Learning

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