Using Machine Learning to Predict Obesity Based on Genome-Wide and Epigenome-Wide Gene–Gene and Gene–Diet Interactions

Lee, Yu‐Chi; Christensen, Jacob J.; Parnell, Laurence D.; Smith, Caren E.; Shao, Jonathan; McKeown, Nicola M.; Ordovás, José M.; Lai, Chao‐Qiang

doi:10.3389/fgene.2021.783845

Cited by 24 publications

(18 citation statements)

References 47 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The integration of genomics with other functional omics analyses may significantly improve the accuracy of host genetic data for explaining health outcomes [ 6 ]. For example, using multiple machine learning algorithms, best predictors of obesity status were identified, and included single-nucleotide polymorphisms (mapped to genes such as STXBP6 , BBX , PLXDC2 , PCDH15 , TPH2 , PCDH15 , CALN1 , FGF14 , LRRN1 , ACTBP2 , RBMXP1 , and ZNF32 ) together with differentially methylated sites (in proximity to CPT1A , ABCG1 , SLC7A11 , RNF145 , and SREBF1 genes) and interactions with dietary factors encompassing specific foods, micronutrients, and bioactive compounds [ 7 ]. Additionally, the consortium of single-nucleotide polymorphisms in genes related to obesity and cardiometabolic diseases, low adherence to the Mediterranean diet, and harboring specific urolithin metabotypes (as biomarkers of the gut microbiota), was able to predict obesity in childhood and adolescence [ 8 ].…”

Section: Genomics In Combination Epigenomics Metagenomics Transcripto...mentioning

confidence: 99%

Holistic Integration of Omics Tools for Precision Nutrition in Health and Disease

2022

View full text Add to dashboard Cite

The combination of multiple omics approaches has emerged as an innovative holistic scope to provide a more comprehensive view of the molecular and physiological events underlying human diseases (including obesity, dyslipidemias, fatty liver, insulin resistance, and inflammation), as well as for elucidating unique and specific metabolic phenotypes. These omics technologies include genomics (polymorphisms and other structural genetic variants), epigenomics (DNA methylation, histone modifications, long non-coding RNA, telomere length), metagenomics (gut microbiota composition, enterotypes), transcriptomics (RNA expression patterns), proteomics (protein quantities), and metabolomics (metabolite profiles), as well as interactions with dietary/nutritional factors. Although more evidence is still necessary, it is expected that the incorporation of integrative omics could be useful not only for risk prediction and early diagnosis but also for guiding tailored dietary treatments and prognosis schemes. Some challenges include ethical and regulatory issues, the lack of robust and reproducible results due to methodological aspects, the high cost of omics methodologies, and high-dimensional data analyses and interpretation. In this review, we provide examples of system biology studies using multi-omics methodologies to unravel novel insights into the mechanisms and pathways connecting the genotype to clinically relevant traits and therapy outcomes for precision nutrition applications in health and disease.

show abstract

Section: Genomics In Combination Epigenomics Metagenomics Transcripto...mentioning

confidence: 99%

Holistic Integration of Omics Tools for Precision Nutrition in Health and Disease

2022

View full text Add to dashboard Cite

show abstract

“…This is not surprising, because obesity is known to have a genetic background; therefore, incorporation of the polygenic score naturally adds to the prediction accuracy. The most recent and currently the most comprehensive study aimed at developing a predictor for obesity risk combined BMI‐associated SNPs and methylation CpG sites with dietary and lifestyle factors in machine‐learning algorithms [105]. The best‐performing model in the study had an overall accuracy of 70% in predicting current obesity by using 21 SNPs, 230 CpG sites, and 26 dietary factors—such as processed meat, high‐fat dairy, French fries, artificial sweeteners, and alcohol intake.…”

Section: Introductionmentioning

confidence: 99%

The potential of DNA methylation as a biomarker for obesity and smoking

2022

View full text Add to dashboard Cite

show abstract

“…Classifying different human conditions - phenotypes or pathologies - using DNA methylation data from a single tissue is more difficult. Phenotype classification can question smoking or obesity status, although existing results suggest that such conditions may not be clearly reflected in DNA methylation [21, 31, 32]. Classification of cases and controls for certain diseases is also performed using DNA methylation data.…”

Section: Introductionmentioning

confidence: 99%

Disease classification for whole blood DNA methylation: meta-analysis, missing values imputation, and XAI

Kalyakulina

Yusipov

Bacalini

et al. 2022

Preprint

View full text Add to dashboard Cite

Background: DNA methylation has a significant effect on gene expression and can be associated with various diseases. Meta-analysis of available DNA methylation datasets requires development of a specific pipeline for joint data processing. Results: We propose a comprehensive approach of combined DNA methylation datasets to classify controls and patients. The solution includes data harmonization, construction of machine learning classification models, dimensionality reduction of models, imputation of missing values, and explanation of model predictions by explainable artificial intelligence (XAI) algorithms. We show that harmonization can improve classification accuracy by up to 20% when preprocessing methods of the training and test datasets are different. The best accuracy results were obtained with tree ensembles, reaching above 95% for Parkinson's disease. Dimensionality reduction can substantially decrease the number of features, without detriment to the classification accuracy. The best imputation methods achieve almost the same classification accuracy for data with missing values as for the original data. Explainable artificial intelligence approaches have allowed us to explain model predictions from both populational and individual perspectives. Conclusions: We propose a methodologically valid and comprehensive approach to the classification of healthy individuals and patients with various diseases based on whole blood DNA methylation data using Parkinson's disease and schizophrenia as examples. The proposed algorithm works better for the former pathology, characterized by a complex set of symptoms. It allows to solve data harmonization problems for meta-analysis of many different datasets, impute missing values, and build classification models of small dimensionality.

show abstract

Using Machine Learning to Predict Obesity Based on Genome-Wide and Epigenome-Wide Gene–Gene and Gene–Diet Interactions

Cited by 24 publications

References 47 publications

Holistic Integration of Omics Tools for Precision Nutrition in Health and Disease

Holistic Integration of Omics Tools for Precision Nutrition in Health and Disease

The potential of DNA methylation as a biomarker for obesity and smoking

Disease classification for whole blood DNA methylation: meta-analysis, missing values imputation, and XAI

Contact Info

Product

Resources

About