Laboratory for Cardio-Immunology

Led by Kai-Uwe Jarr, M.D.

Chitinase 3 like 1 (CHI3L1) is a regulator of smooth muscle cell physiology and atherosclerotic lesion stability.


Journal article


P. Tsantilas, Shen Lao, Zhiyuan Wu, Anne V. Eberhard, G. Winski, Monika Vaerst, V. Nanda, Ying Wang, Y. Kojima, Jianqin Ye, Alyssa M. Flores, K. Jarr, J. Pelisek, H. Eckstein, L. Matic, U. Hedin, P. Tsao, V. Paloschi, L. Maegdefessel, N. Leeper
Cardiovascular Research, 2021

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APA   Click to copy
Tsantilas, P., Lao, S., Wu, Z., Eberhard, A. V., Winski, G., Vaerst, M., … Leeper, N. (2021). Chitinase 3 like 1 (CHI3L1) is a regulator of smooth muscle cell physiology and atherosclerotic lesion stability. Cardiovascular Research.


Chicago/Turabian   Click to copy
Tsantilas, P., Shen Lao, Zhiyuan Wu, Anne V. Eberhard, G. Winski, Monika Vaerst, V. Nanda, et al. “Chitinase 3 like 1 (CHI3L1) Is a Regulator of Smooth Muscle Cell Physiology and Atherosclerotic Lesion Stability.” Cardiovascular Research (2021).


MLA   Click to copy
Tsantilas, P., et al. “Chitinase 3 like 1 (CHI3L1) Is a Regulator of Smooth Muscle Cell Physiology and Atherosclerotic Lesion Stability.” Cardiovascular Research, 2021.


BibTeX   Click to copy

@article{p2021a,
  title = {Chitinase 3 like 1 (CHI3L1) is a regulator of smooth muscle cell physiology and atherosclerotic lesion stability.},
  year = {2021},
  journal = {Cardiovascular Research},
  author = {Tsantilas, P. and Lao, Shen and Wu, Zhiyuan and Eberhard, Anne V. and Winski, G. and Vaerst, Monika and Nanda, V. and Wang, Ying and Kojima, Y. and Ye, Jianqin and Flores, Alyssa M. and Jarr, K. and Pelisek, J. and Eckstein, H. and Matic, L. and Hedin, U. and Tsao, P. and Paloschi, V. and Maegdefessel, L. and Leeper, N.}
}

Abstract

AIMS Atherosclerotic cerebrovascular disease underlies the majority of ischemic strokes and is a major cause of death and disability. While plaque burden is a predictor of adverse outcomes, plaque vulnerability is increasingly recognized as a driver of lesion rupture and risk for clinical events. Defining the molecular regulators of carotid instability could inform the development of new biomarkers and/or translational targets for at-risk individuals.

METHODS AND RESULTS Using two independent human endarterectomy biobanks, we found that the understudied glycoprotein, Chitinase 3 like 1 (CHI3L1), is upregulated in patients with carotid disease compared to healthy controls. Further, CHI3L1 levels were found to stratify individuals based on symptomatology and histopathological evidence of an unstable fibrous cap. Gain- and loss-of-function studies in cultured human carotid artery smooth muscle cells (SMCs) showed that CHI3L1 prevents a number of maladaptive changes in that cell type, including phenotype switching towards a synthetic and hyperproliferative state. Using two murine models of carotid remodelling and lesion vulnerability, we found that knockdown of Chil1 resulted in larger neointimal lesions comprised by de-differentiated SMCs that failed to invest within and stabilize the fibrous cap. Exploratory mechanistic studies identified alterations in potential downstream regulatory genes, including large tumor suppressor kinase 2 (LATS2), which mediates macrophage marker and inflammatory cytokine expression on SMCs, and may explain how CHI3L1 modulates cellular plasticity.

CONCLUSION CHI3L1 is upregulated in humans with carotid artery disease and appears to be a strong mediator of plaque vulnerability. Mechanistic studies suggest this change may be a context-dependent adaptive response meant to maintain vascular SMCs in a differentiated state and to prevent rupture of the fibrous cap. Part of this effect may be mediated through downstream suppression of LATS2. Future studies should determine how these changes occur at the molecular level, and whether this gene can be targeted as a novel translational therapy for subjects at risk of stroke.

TRANSLATIONAL PERSPECTIVE Taken together, CHI3L1 has the potential to become a new translational target for cardiovascular disease. With further studies to understand its full causal relationship to inflammatory pathways, it could have a role in the diagnosis and management of patients with cerebrovascular disease at risk for stroke.