Abstract
Type 2 diabetes (T2D) and cardiovascular disease (CVD) represent significant disease burdens for most societies and susceptibility to these diseases is strongly influenced by diet and lifestyle. Physiological changes associated with T2D or CVD, such has high blood pressure and cholesterol and glucose levels in the blood, are often apparent prior to disease incidence. Here we integrated genetics, lipidomics, and standard clinical diagnostics to assess future T2D and CVD risk for 4,067 participants from a large prospective population-based cohort, the Malmö Diet and Cancer-Cardiovascular Cohort. By training Ridge regression-based machine learning models on the measurements obtained at baseline when the individuals were healthy, we computed several risk scores for T2D and CVD incidence during up to 23 years of follow-up. We used these scores to stratify the participants into risk groups and found that a lipidomics risk score based on the quantification of 184 plasma lipid concentrations resulted in a 168% and 84% increase of the incidence rate in the highest risk group and a 77% and 53% decrease of the incidence rate in lowest risk group for T2D and CVD, respectively, compared to the average case rates of 13.8% and 22.0%. Notably, lipidomic risk correlated only marginally with polygenic risk, indicating that the lipidome and genetic variants may constitute largely independent risk factors for T2D and CVD. Risk stratification was further improved by adding standard clinical variables to the model, resulting in a case rate of 51.0% and 53.3% in the highest risk group for T2D and CVD, respectively. The participants in the highest risk group showed significantly altered lipidome compositions affecting 167 and 157 lipid species for T2D and CVD, respectively. Our results demonstrated that a subset of individuals at high risk for developing T2D or CVD can be identified years before disease incidence. The lipidomic risk, which is derived from only one single mass spectrometric measurement that is cheap and fast, is informative and could extend traditional risk assessment based on clinical assays.
Highlights
As reported regularly by the World Health Organization (WHO), cardiovascular diseases (CVDs) and diabetes mellitus are among the 10 leading causes of death globally
For 4,067 participants, we measured the lipidomes of fasted blood plasma samples taken at baseline by shotgun lipidomics, which involved the determination of molar concentrations of 184 lipid species or subspecies
For type 2 diabetes (T2D), we excluded all participants with prevalent diabetes at baseline, leaving 3,688 individuals for analysis from whom 509 (13.8%) developed T2D during the follow-up period
Summary
As reported regularly by the World Health Organization (WHO), cardiovascular diseases (CVDs) and diabetes mellitus are among the 10 leading causes of death globally. The risk of developing CVD and type 2 diabetes (T2D) is associated with diet and other lifestyle-related behavior. Early and accurate identification of individuals at high disease risk is crucial for lowering the disease burden by suggesting tailored and timely countermeasures, for instance, changes to the diet. Large population-based genotyping efforts undertaken during recent years have demonstrated that many phenotypes, including predisposition to human diseases, are polygenic, i.e., result from a large number of genetic loci, each having a small effect [5,6]. After reducing sets of highly correlating variants (for instance, those in strong linkage disequilibrium) to single index variants via pruning or clumping, a summation of the number of risk alleles present in an individual, weighted by their effect sizes, can be used to quantify the risk of that person for developing the disease considered relative to the average risk in the population
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