Human and murine fibroblast single-cell transcriptomics reveals fibroblast clusters are differentially affected by ageing and serum cholesterol

Abstract Aims Specific fibroblast markers and in-depth heterogeneity analysis are currently lacking, hindering functional studies in cardiovascular diseases (CVDs). Here, we established cell-type markers and heterogeneity in murine and human arteries and studied the adventitial fibroblast response to CVD and its risk factors hypercholesterolaemia and ageing. Methods and results Murine aorta single-cell RNA-sequencing analysis of adventitial mesenchymal cells identified fibroblast-specific markers. Immunohistochemistry and flow cytometry validated platelet-derived growth factor receptor alpha (PDGFRA) and dipeptidase 1 (DPEP1) across human and murine aorta, carotid, and femoral arteries, whereas traditional markers such as the cluster of differentiation (CD)90 and vimentin also marked transgelin+ vascular smooth muscle cells. Next, pseudotime analysis showed multiple fibroblast clusters differentiating along trajectories. Three trajectories, marked by CD55 (Cd55+), Cxcl chemokine 14 (Cxcl14+), and lysyl oxidase (Lox+), were reproduced in an independent RNA-seq dataset. Gene ontology (GO) analysis showed divergent functional profiles of the three trajectories, related to vascular development, antigen presentation, and/or collagen fibril organization, respectively. Trajectory-specific genes included significantly more genes with known genome-wide associations (GWAS) to CVD than expected by chance, implying a role in CVD. Indeed, differential regulation of fibroblast clusters by CVD risk factors was shown in the adventitia of aged C57BL/6J mice, and mildly hypercholesterolaemic LDLR KO mice on chow by flow cytometry. The expansion of collagen-related CXCL14+ and LOX+ fibroblasts in aged and hypercholesterolaemic aortic adventitia, respectively, coincided with increased adventitial collagen. Immunohistochemistry, bulk, and single-cell transcriptomics of human carotid and aorta specimens emphasized translational value as CD55+, CXCL14+ and LOX+ fibroblasts were observed in healthy and atherosclerotic specimens. Also, trajectory-specific gene sets are differentially correlated with human atherosclerotic plaque traits. Conclusion We provide two adventitial fibroblast-specific markers, PDGFRA and DPEP1, and demonstrate fibroblast heterogeneity in health and CVD in humans and mice. Biological relevance is evident from the regulation of fibroblast clusters by age and hypercholesterolaemia in vivo, associations with human atherosclerotic plaque traits, and enrichment of genes with a GWAS for CVD.

[1]  S. Lemaire,et al.  Second Heart Field-derived Cells Contribute to Angiotensin II-mediated Ascending Aortopathies , 2022, bioRxiv.

[2]  Clint L. Miller,et al.  Enhanced single-cell RNA-seq workflow reveals coronary artery disease cellular cross-talk and candidate drug targets. , 2021, Atherosclerosis.

[3]  E. Biessen,et al.  Transcriptional Sex Dimorphism in Human Atherosclerosis Relates to Plaque Type. , 2021, Circulation research.

[4]  Joël M. H. Karel,et al.  Integrative multiomics analysis of human atherosclerosis reveals a serum response factor‐driven network associated with intraplaque hemorrhage , 2021, Clinical and translational medicine.

[5]  M. Weiser-Evans,et al.  Heterogeneous subpopulations of adventitial progenitor cells regulate vascular homeostasis and pathological vascular remodeling. , 2021, Cardiovascular research.

[6]  Xiumeng Hua,et al.  Single-Cell Transcriptomic Atlas of Different Human Cardiac Arteries Identifies Cell Types Associated With Vascular Physiology , 2021, Arteriosclerosis, thrombosis, and vascular biology.

[7]  J. Coselli,et al.  Single-Cell Transcriptome Analysis Reveals Dynamic Cell Populations and Differential Gene Expression Patterns in Control and Aneurysmal Human Aortic Tissue , 2020, Circulation.

[8]  Mingyao Li,et al.  Single-Cell Genomics Reveals a Novel Cell State During Smooth Muscle Cell Phenotypic Switching and Potential Therapeutic Targets for Atherosclerosis in Mouse and Human , 2020, Circulation.

[9]  J. Björkegren,et al.  Single-cell analysis uncovers fibroblast heterogeneity and criteria for fibroblast and mural cell identification and discrimination , 2020, Nature Communications.

[10]  J. Sluimer,et al.  Fibroblasts in atherosclerosis: heterogeneous and plastic participants , 2020, Current opinion in lipidology.

[11]  Corey M. Williams,et al.  Stem Cell Pluripotency Genes Klf4 and Oct4 Regulate Complex SMC Phenotypic Changes Critical in Late-Stage Atherosclerotic Lesion Pathogenesis , 2020, Circulation.

[12]  F. Tang,et al.  A single-cell transcriptomic landscape of primate arterial aging , 2020, Nature Communications.

[13]  Xiuzhen Huang,et al.  Arterial Sca1+ Vascular Stem Cells Generate De Novo Smooth Muscle for Artery Repair and Regeneration. , 2019, Cell stem cell.

[14]  Ronald R. Coifman,et al.  Visualizing structure and transitions in high-dimensional biological data , 2019, Nature Biotechnology.

[15]  Guoping Wang,et al.  Foam Cell-Derived CXCL14 Muti-Functionally Promotes Atherogenesis and Is a Potent Therapeutic Target in Atherosclerosis , 2019, Journal of Cardiovascular Translational Research.

[16]  Huiping Li,et al.  Chemokine (C‐X‐C motif) ligand 14 contributes to lipopolysaccharide‐induced fibrogenesis in mouse L929 fibroblasts via modulating PPM1A , 2019, Journal of cellular biochemistry.

[17]  C. Betsholtz,et al.  Heterogeneity and plasticity in healthy and atherosclerotic vasculature explored by single-cell sequencing , 2019, Cardiovascular research.

[18]  Aditya S. D. Kalluri,et al.  Single Cell Analysis of the Normal Mouse Aorta Reveals Functionally Distinct Endothelial Cell Populations. , 2019, Circulation.

[19]  Clint L. Miller,et al.  Atheroprotective roles of smooth muscle cell phenotypic modulation and the TCF21 disease gene as revealed by single-cell analysis , 2019, Nature Medicine.

[20]  J. Vilo,et al.  g:Profiler: a web server for functional enrichment analysis and conversions of gene lists (2019 update) , 2019, Nucleic Acids Res..

[21]  Qingbo Xu,et al.  Adventitial Cell Atlas of wt (Wild Type) and ApoE (Apolipoprotein E)-Deficient Mice Defined by Single-Cell RNA Sequencing , 2019, Arteriosclerosis, thrombosis, and vascular biology.

[22]  Qing Nie,et al.  Single-cell analysis reveals fibroblast heterogeneity and myeloid-derived adipocyte progenitors in murine skin wounds , 2019, Nature Communications.

[23]  M. Bennett,et al.  Disease-relevant transcriptional signatures identified in individual smooth muscle cells from healthy mouse vessels , 2018, Nature Communications.

[24]  James T. Webber,et al.  Single-cell transcriptomics of 20 mouse organs creates a Tabula Muris , 2018, Nature.

[25]  Erik Sundström,et al.  RNA velocity of single cells , 2018, Nature.

[26]  Xuting Bian,et al.  Direct reprogramming of fibroblasts into neural stem cells by single non-neural progenitor transcription factor Ptf1a , 2018, Nature Communications.

[27]  Peter Chen,et al.  Single-Cell Deconvolution of Fibroblast Heterogeneity in Mouse Pulmonary Fibrosis , 2018, Cell reports.

[28]  Dennis Wolf,et al.  Single-Cell RNA-Seq Reveals the Transcriptional Landscape and Heterogeneity of Aortic Macrophages in Murine Atherosclerosis , 2018, Circulation research.

[29]  J. Lim,et al.  Beyond the Role of CD55 as a Complement Component , 2018, Immune network.

[30]  R. Touyz,et al.  Lysyl Oxidase Induces Vascular Oxidative Stress and Contributes to Arterial Stiffness and Abnormal Elastin Structure in Hypertension: Role of p38MAPK. , 2017, Antioxidants & redox signaling.

[31]  M. Tallquist,et al.  Tracking Adventitial Fibroblast Contribution to Disease: A Review of Current Methods to Identify Resident Fibroblasts. , 2017, Arteriosclerosis, thrombosis, and vascular biology.

[32]  Qingbo Xu,et al.  Adventitial SCA-1+ Progenitor Cell Gene Sequencing Reveals the Mechanisms of Cell Migration in Response to Hyperlipidemia , 2017, Stem cell reports.

[33]  F. Abdul-Karim,et al.  CD55 regulates self-renewal and cisplatin resistance in endometrioid tumors , 2017, bioRxiv.

[34]  J. Kim,et al.  Direct Reprogramming of Human Dermal Fibroblasts Into Endothelial Cells Using ER71/ETV2 , 2017, Circulation research.

[35]  S. Pullamsetti,et al.  Metabolic Reprogramming Regulates the Proliferative and Inflammatory Phenotype of Adventitial Fibroblasts in Pulmonary Hypertension Through the Transcriptional Corepressor C-Terminal Binding Protein-1 , 2016, Circulation.

[36]  V. Fuster,et al.  Endothelial to mesenchymal transition is common in atherosclerotic lesions and is associated with plaque instability , 2016, Nature Communications.

[37]  M. Gawaz,et al.  CXCL14 as an emerging immune and inflammatory modulator , 2016, Journal of Inflammation.

[38]  B. Ebert,et al.  Perivascular Gli1+ progenitors are key contributors to injury-induced organ fibrosis. , 2015, Cell stem cell.

[39]  L. Folkersen,et al.  The collagen cross‐linking enzyme lysyl oxidase is associated with the healing of human atherosclerotic lesions , 2014, Journal of internal medicine.

[40]  Cole Trapnell,et al.  The dynamics and regulators of cell fate decisions are revealed by pseudotemporal ordering of single cells , 2014, Nature Biotechnology.

[41]  J. Frostegård Immunity, atherosclerosis and cardiovascular disease , 2013, BMC Medicine.

[42]  G. Daum,et al.  The Adventitia: A Progenitor Cell Niche for the Vessel Wall , 2011, Cells Tissues Organs.

[43]  T. Hughes,et al.  CD55 Deficiency Protects against Atherosclerosis in ApoE-Deficient Mice via C3a Modulation of Lipid Metabolism , 2011, The American journal of pathology.

[44]  A. Miyawaki,et al.  Prospective identification, isolation, and systemic transplantation of multipotent mesenchymal stem cells in murine bone marrow , 2009, The Journal of experimental medicine.

[45]  E. Birney,et al.  Mapping identifiers for the integration of genomic datasets with the R/Bioconductor package biomaRt , 2009, Nature Protocols.

[46]  U. V. von Andrian,et al.  Murine CXCL14 Is Dispensable for Dendritic Cell Function and Localization within Peripheral Tissues , 2006, Molecular and Cellular Biology.

[47]  H. Kagan,et al.  Lysyl oxidase: an oxidative enzyme and effector of cell function , 2006, Cellular and Molecular Life Sciences CMLS.

[48]  Qingbo Xu,et al.  Abundant progenitor cells in the adventitia contribute to atherosclerosis of vein grafts in ApoE-deficient mice. , 2004, The Journal of clinical investigation.

[49]  S. Ball,et al.  Simvastatin reduces human atrial myofibroblast proliferation independently of cholesterol lowering via inhibition of RhoA. , 2004, Cardiovascular research.

[50]  R. Virmani,et al.  Lessons from sudden coronary death: a comprehensive morphological classification scheme for atherosclerotic lesions. , 2000, Arteriosclerosis, thrombosis, and vascular biology.

[51]  A. Zalewski,et al.  Remodeling of autologous saphenous vein grafts. The role of perivascular myofibroblasts. , 1997, Circulation.

[52]  M. Franco-Molina,et al.  The Inflammatory Process Modulates the Expression and Localization of WT1 in Podocytes Leading to Kidney Damage , 2021, In Vivo.

[53]  W. Seeger,et al.  Two-Way Conversion between Lipogenic and Myogenic Fibroblastic Phenotypes Marks the Progression and Resolution of Lung Fibrosis. , 2017, Cell stem cell.

[54]  Mark W Majesky,et al.  Smooth Muscle Cells Derived From Second Heart Field and Cardiac Neural Crest Reside in Spatially Distinct Domains in the Media of the Ascending Aorta—Brief Report , 2017, Arteriosclerosis, thrombosis, and vascular biology.

[55]  K. Csiszȧr,et al.  Lysyl oxidases: a novel multifunctional amine oxidase family. , 2001, Progress in nucleic acid research and molecular biology.