Genetic Ablation of Mast Cells Redefines the Role of Mast Cells in Skin Wound Healing and Bleomycin-Induced Fibrosis

Genetic Ablation of Mast Cells Redefines the Role of Mast Cells in Skin Wound Healing and Bleomycin-Induced Fibrosis

Conclusive evidence for the impact of mast cells (MCs) in skin repair is still lacking. Studies in mice examining the role of MC function in the physiology and pathology of skin regenerative processes have obtained contradictory results. To clarify the specific role of MCs in regenerative conditions...

Full description

Saved in:
Bibliographic Details
Published in:Journal of investigative dermatology 2014-07, Vol.134 (7), p.2005-2015
Main Authors: Willenborg, Sebastian, Eckes, Beate, Brinckmann, Jürgen, Krieg, Thomas, Waisman, Ari, Hartmann, Karin, Roers, Axel, Eming, Sabine A.
Format: Article
Language:eng
Subjects:
Animals
Antibiotics, Antineoplastic - pharmacology
Bleomycin - pharmacology
Disease Models, Animal
Fibrosis - chemically induced
Fibrosis - pathology
Fibrosis - physiopathology
Granulation Tissue - physiology
Keratinocytes - pathology
Keratinocytes - physiology
Leukocytes - pathology
Leukocytes - physiology
Mast Cells - pathology
Mast Cells - physiology
Mice
Mice, Transgenic
Skin Diseases - chemically induced
Skin Diseases - pathology
Skin Diseases - physiopathology
Wound Healing - physiology
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Conclusive evidence for the impact of mast cells (MCs) in skin repair is still lacking. Studies in mice examining the role of MC function in the physiology and pathology of skin regenerative processes have obtained contradictory results. To clarify the specific role of MCs in regenerative conditions, here we used a recently developed genetic mouse model that allows conditional MC ablation to examine MC-specific functions in skin. This mouse model is based on the cell type–specific expression of Cre recombinase in connective tissue–type MCs under control of the Mcpt5 promoter and the Cre-inducible diphtheria toxin receptor–mediated cell lineage ablation by diphtheria toxin. In response to excisional skin injury, genetic ablation of MCs did not affect the kinetics of reepithelialization, the formation of vascularized granulation tissue, or scar formation. Furthermore, genetic ablation of MCs failed to prevent the development of skin fibrosis upon bleomycin challenge. The amount of deposited collagen and the biochemistry of collagen fibril crosslinks within fibrotic lesions were comparable in MC-depleted and control mice. Collectively, our findings strongly suggest that significant reduction of MC numbers does not affect skin wound healing and bleomycin-induced fibrosis in mice, and provide to our knowledge previously unreported insight in the long-debated contribution of MCs in skin regenerative processes.
ISSN:0022-202X
1523-1747