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Mindin regulates fibroblast subpopulations through distinct Src family kinases during fibrogenesis
Sunny Kataria, Isha Rana, Krithika Badarinath, Rania F. Zaarour, Gaurav Kansagara, Sultan Ahmed, Abrar Rizvi, Dyuti Saha, Binita Dam, Abhik Dutta, Ravindra K. Zirmire, Edries Yousaf Hajam, Pankaj Kumar, Akash Gulyani, Colin Jamora
Sunny Kataria, Isha Rana, Krithika Badarinath, Rania F. Zaarour, Gaurav Kansagara, Sultan Ahmed, Abrar Rizvi, Dyuti Saha, Binita Dam, Abhik Dutta, Ravindra K. Zirmire, Edries Yousaf Hajam, Pankaj Kumar, Akash Gulyani, Colin Jamora
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Research Article Dermatology Inflammation

Mindin regulates fibroblast subpopulations through distinct Src family kinases during fibrogenesis

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Abstract

Fibrosis results from excessive extracellular matrix (ECM) deposition, which causes tissue stiffening and organ dysfunction. Activated fibroblasts, central to fibrosis, exhibit increased migration, proliferation, contraction, and ECM production. However, it remains unclear if the same fibroblast performs all of the processes that fall under the umbrella term of “activation.” Owing to fibroblast heterogeneity in connective tissues, subpopulations with specific functions may operate under distinct regulatory controls. Using a transgenic mouse model of skin fibrosis, we found that Mindin (also known as spondin-2), secreted by Snail-transgenic keratinocytes, differentially regulates fibroblast subpopulations. Mindin promotes migration and inflammatory gene expression in SCA1+ dermal fibroblasts via Fyn kinase. In contrast, it enhances contractility and collagen production in papillary CD26+ fibroblasts through c-Src signaling. Moreover, in the context of the fibrotic microenvironment of the tumor stroma, we found that differential responses of resident fibroblast subpopulations to Mindin extend to the generation of functionally heterogeneous cancer-associated fibroblasts. This study identifies Mindin as a key orchestrator of dermal fibroblast heterogeneity, reshaping cellular dynamics and signaling diversity in the complex landscapes of skin fibrosis and cancer.

Authors

Sunny Kataria, Isha Rana, Krithika Badarinath, Rania F. Zaarour, Gaurav Kansagara, Sultan Ahmed, Abrar Rizvi, Dyuti Saha, Binita Dam, Abhik Dutta, Ravindra K. Zirmire, Edries Yousaf Hajam, Pankaj Kumar, Akash Gulyani, Colin Jamora

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Figure 1

SCA1+ fibroblast localization is perturbed in the dermis of Snail-transgenic mice.

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SCA1+ fibroblast localization is perturbed in the dermis of Snail-transg...
Representative contour plot showing quadrants for (A) α-SMA+SCA1+/CD26–VIMhi, α-SMA+SCA1-/CD26–VIMhi, α-SMA-SCA1+/CD26–VIMhi and α-SMA–SCA1–/CD26–VIMhi and (B) α-SMA+CD26+/SCA1–VIMhi, α-SMA+CD26–/SCA1–VIMhi, α-SMA–CD26+/SCA1–VIMhi and α-SMA–CD26–/SCA1–VIMhi cells from P9 WT (left) and Snail-transgenic (SnTg) (right) mice. Individual value plots (mean ± SEM) of (C) the percentage of α-SMA+SCA1+/CD26–VIMhi and (D) the percentage α-SMA+CD26+/SCA1–VIMhi cells (n = 6; P values were calculated by Welch’s t test; *P < 0.05, ***P < 0.001). (E) SCA1+ fibroblasts (green) and nuclear staining with DAPI (blue) in WT and SnTg skin sections in P3, P5, P7, and P9 pups. The white boxes mark the insets shown in Supplemental Figure 1J. Note that the green stain at the bottom of the skin section is the autofluorescence of the paper used to keep the tissue uncurled during the embedding process. (F) Heatmap showing the probability of SCA1+ cells at a given distance below the epidermis in WT (top) and SnTg (bottom) mice. P3 (n =3 WT and Snail Tg), P5 (n = 2 WT and n = 4 Snail Tg), P7 (n = 3 WT and n = 4 Snail Tg), and P9 (n = 6 WT and n = 8 Snail Tg). (G) CD26+ fibroblasts (red) and nuclear staining with DAPI (blue) in WT and SnTg skin sections from P3, P5, P7, and P9 pups. The white boxes mark the insets shown in Supplemental Figure 1L as magnified areas. The boxed areas are shown at higher magnification in Supplemental Figure 1L. Note that the red stain at the bottom of the skin section is the autofluorescence of the paper used to keep the tissue uncurled during the embedding process. (H) Heatmap showing the probability of CD26+ cells at a given distance below the epidermis in WT (top) and SnTg (bottom) at P3 (n = 2 WT and n = 3 Snail Tg), P5 (n = 2 WT and n = 3 Snail Tg), P7 (n = 3 WT and n = 3 Snail Tg), and P9 (n = 4 WT and n = 6 Snail Tg).

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