Smooth muscle–derived adventitial progenitor cells direct atherosclerotic plaque composition complexity in a Klf4-dependent manner
Allison M. Dubner, Sizhao Lu, Austin J. Jolly, Keith A. Strand, Marie F. Mutryn, Tyler Hinthorn, Tysen Noble, Raphael A. Nemenoff, Karen S. Moulton, Mark W. Majesky, Mary C.M. Weiser-Evans
Allison M. Dubner, Sizhao Lu, Austin J. Jolly, Keith A. Strand, Marie F. Mutryn, Tyler Hinthorn, Tysen Noble, Raphael A. Nemenoff, Karen S. Moulton, Mark W. Majesky, Mary C.M. Weiser-Evans
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Research Article Stem cells Vascular biology

Smooth muscle–derived adventitial progenitor cells direct atherosclerotic plaque composition complexity in a Klf4-dependent manner

Abstract

We previously established that vascular smooth muscle–derived adventitial progenitor cells (AdvSca1-SM) preferentially differentiate into myofibroblasts and contribute to fibrosis in response to acute vascular injury. However, the role of these progenitor cells in chronic atherosclerosis has not been defined. Using an AdvSca1-SM cell lineage tracing model, scRNA-Seq, flow cytometry, and histological approaches, we confirmed that AdvSca1-SM–derived cells localized throughout the vessel wall and atherosclerotic plaques, where they primarily differentiated into fibroblasts, smooth muscle cells (SMC), or remained in a stem-like state. Krüppel-like factor 4 (Klf4) knockout specifically in AdvSca1-SM cells induced transition to a more collagen-enriched fibroblast phenotype compared with WT mice. Additionally, Klf4 deletion drastically modified the phenotypes of non–AdvSca1-SM–derived cells, resulting in more contractile SMC and atheroprotective macrophages. Functionally, overall plaque burden was not altered with Klf4 deletion, but multiple indices of plaque composition complexity, including necrotic core area, macrophage accumulation, and fibrous cap thickness, were reduced. Collectively, these data support that modulation of AdvSca1-SM cells through KLF4 depletion confers increased protection from the development of potentially unstable atherosclerotic plaques.

Authors

Allison M. Dubner, Sizhao Lu, Austin J. Jolly, Keith A. Strand, Marie F. Mutryn, Tyler Hinthorn, Tysen Noble, Raphael A. Nemenoff, Karen S. Moulton, Mark W. Majesky, Mary C.M. Weiser-Evans

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Figure 1

AdvSca1-SM cell–derived YFP+ cells are distributed throughout the vascular wall and atherosclerotic plaque.

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AdvSca1-SM cell–derived YFP+ cells are distributed throughout the vascul...
(A) Schematic of experimental approach. (B) A subset of animals were injected i.v. with fluorescently labeled Griffonia simplicifolia lectin I (GSL I) isolectin B4 5 minutes prior to sacrifice to label functional vasculature in vivo. Representative immunofluorescence of aortic root sections from 24-week plaques (n = 6) stained for YFP (AdvSca1-SM and AdvSca1-SM–derived cells; green); lectin (red); DAPI for all cell nuclei (blue). Arrows indicate functional adventitial microvasculature (lectin labeled) surrounded by YFP+ cells; arrowheads indicate intraplaque YFP+ cells. (C) Representative immunofluorescence image of 28-week aortic root plaque (n = 5) stained for αSMA (red) and YFP (green). Arrows indicate YFP+ medial cells. (D and E) Aortic root slides from 24-week plaques (n = 10) stained for YFP (green), αSMA (red), Ter-119 (magenta), and DAPI (blue). Low-power and high-power insert (D) show YFP+ cells in the cap of the plaque. (E) YFP+ cells in the plaque cap (arrows), YFP+/αSMA+ cells in the plaque cap (asterisk), and YFP+ cells in the body of the plaque (arrowheads). Scale bars: 50 μm, 100 μm (low-power D).