Hartman, Robin J.G. and Owsiany, Katie and Ma, Lijiang and Koplev, Simon and Hao, Ke and Slenders, Lotte and Civelek, Mete and Mokry, Michal and Kovacic, Jason C. and Pasterkamp, Gerard and Owens, Gary and Björkegren, Johan L.M. and den Ruijter, Hester M. (2021) Sex-Stratified Gene Regulatory Networks Reveal Female Key Driver Genes of Atherosclerosis Involved in Smooth Muscle Cell Phenotype Switching. Circulation, 143 (7). pp.713-726. ISSN 0009-7322
Hartman, Robin J.G. and Owsiany, Katie and Ma, Lijiang and Koplev, Simon and Hao, Ke and Slenders, Lotte and Civelek, Mete and Mokry, Michal and Kovacic, Jason C. and Pasterkamp, Gerard and Owens, Gary and Björkegren, Johan L.M. and den Ruijter, Hester M. (2021) Sex-Stratified Gene Regulatory Networks Reveal Female Key Driver Genes of Atherosclerosis Involved in Smooth Muscle Cell Phenotype Switching. Circulation, 143 (7). pp.713-726. ISSN 0009-7322
Hartman, Robin J.G. and Owsiany, Katie and Ma, Lijiang and Koplev, Simon and Hao, Ke and Slenders, Lotte and Civelek, Mete and Mokry, Michal and Kovacic, Jason C. and Pasterkamp, Gerard and Owens, Gary and Björkegren, Johan L.M. and den Ruijter, Hester M. (2021) Sex-Stratified Gene Regulatory Networks Reveal Female Key Driver Genes of Atherosclerosis Involved in Smooth Muscle Cell Phenotype Switching. Circulation, 143 (7). pp.713-726. ISSN 0009-7322
Abstract
BACKGROUND: Although sex differences in coronary artery disease are widely accepted with women developing more stable atherosclerosis than men, the underlying pathobiology of such differences remains largely unknown. In coronary artery disease, recent integrative systems biological studies have inferred gene regulatory networks (GRNs). Within these GRNs, key driver genes have shown great promise but have thus far been unidentified in women. METHODS: We generated sex-specific GRNs of the atherosclerotic arterial wall in 160 women and age-matched men in the STARNET study (Stockholm-Tartu Atherosclerosis Reverse Network Engineering Task). We integrated the female GRNs with single-cell RNA-sequencing data of the human atherosclerotic plaque and single-cell RNA sequencing of advanced atherosclerotic lesions from wild type and Klf4 knockout atherosclerotic smooth muscle cell (SMC) lineage-tracing mice. RESULTS: By comparing sex-specific GRNs, we observed clear sex differences in network activity within the atherosclerotic tissues. Genes more active in women were associated with mesenchymal cells and endothelial cells, whereas genes more active in men were associated with the immune system. We determined that key drivers of GRNs active in female coronary artery disease were predominantly found in (SMCs by single-cell sequencing of the human atherosclerotic plaques, and higher expressed in female plaque SMCs, as well. To study the functions of these female SMC key drivers in atherosclerosis, we examined single-cell RNA sequencing of advanced atherosclerotic lesions from wild type and Klf4 knockout atherosclerotic SMC lineage-tracing mice. The female key drivers were found to be expressed by phenotypically modulated SMCs and affected by Klf4, suggesting that sex differences in atherosclerosis involve phenotypic switching of plaque SMCs. CONCLUSIONS: Our systems approach provides novel insights into molecular mechanisms that underlie sex differences in atherosclerosis. To discover sex-specific therapeutic targets for atherosclerosis, an increased emphasis on sex-stratified approaches in the analysis of multi-omics data sets is warranted.
Metadata
Subjects: | R Medicine > R Medicine (General) |
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Depositing User: | Repository Administrator |
Date Deposited: | 25 Feb 2021 08:38 |
Last Modified: | 25 Feb 2021 08:38 |