Jason P. Glotzbach scite author profile

Exuberant fibroproliferation is a common complication after injury for reasons that are not well understood1. One key component of wound repair that is often overlooked is mechanical force, which regulates cell-matrix interactions through intracellular focal adhesion components, including focal adhesion kinase (FAK)1,2. Here we report that FAK is activated after cutaneous injury and that this process is potentiated by mechanical loading. Fibroblast-specific FAK knockout mice have substantially less inflammation and fibrosis than control mice in a model of hypertrophic scar formation. We show that FAK acts through extracellular-related kinase (ERK) to mechanically trigger the secretion of monocyte chemoattractant protein-1 (MCP-1, also known as CCL2), a potent chemokine that is linked to human fibrotic disorders3–5. Similarly, MCP-1 knockout mice form minimal scars, indicating that inflammatory chemokine pathways are a major mechanism by which FAK mechanotransduction induces fibrosis. Small-molecule inhibition of FAK blocks these effects in human cells and reduces scar formation in vivo through attenuated MCP-1 signaling and inflammatory cell recruitment. These findings collectively indicate that physical force regulates fibrosis through inflammatory FAK–ERK–MCP-1 pathways and that molecular strategies targeting FAK can effectively uncouple mechanical force from pathologic scar formation.

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Enhancement of mesenchymal stem cell angiogenic capacity and stemness by a biomimetic hydrogel scaffold

Rustad

et al. 2012

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In this study, we examined the capacity of a biomimetic pullulan–collagen hydrogel to create a functional biomaterial-based stem cell niche for the delivery of mesenchymal stem cells (MSCs) into wounds. Murine bone marrow-derived MSCs were seeded into hydrogels and compared to MSCs grown in standard culture conditions. Hydrogels induced MSC secretion of angiogenic cytokines and expression of transcription factors associated with maintenance of pluripotency and self-renewal (Oct4, Sox2, Klf4) when compared to MSCs grown in standard conditions. An excisonal wound healing model was used to compare the ability of MSC-hydrogel constructs versus MSC injection alone to accelerate wound healing. Injection of MSCs did not significantly improve time to wound closure. In contrast, wounds treated with MSC-seeded hydrogels showed significantly accelerated healing and a return of skin appendages. Bioluminescence imaging and FACS analysis of luciferase+/GFP+ MSCs indicated that stem cells delivered within the hydrogel remained viable longer and demonstrated enhanced engraftment efficiency than those delivered via injection. Engrafted MSCs were found to differentiate into fibroblasts, pericytes and endothelial cells but did not contribute to the epidermis. Wounds treated with MSC-seeded hydrogels demonstrated significantly enhanced angiogenesis, which was associated with increased levels of VEGF and other angiogenic cytokines within the wounds. Our data suggest that biomimetic hydrogels provide a functional niche capable of augmenting MSC regenerative potential and enhancing wound healing.

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Surgical Approaches to Create Murine Models of Human Wound Healing

Wong

Sorkin

Glotzbach

et al. 2010

BioMed Research International

315

281

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Wound repair is a complex biologic process which becomes abnormal in numerous disease states. Although in vitro models have been important in identifying critical repair pathways in specific cell populations, in vivo models are necessary to obtain a more comprehensive and pertinent understanding of human wound healing. The laboratory mouse has long been the most common animal research tool and numerous transgenic strains and models have been developed to help researchers study the molecular pathways involved in wound repair and regeneration. This paper aims to highlight common surgical mouse models of cutaneous disease and to provide investigators with a better understanding of the benefits and limitations of these models for translational applications.

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CD105 Protein Depletion Enhances Human Adipose-derived Stromal Cell Osteogenesis through Reduction of Transforming Growth Factor β1 (TGF-β1) Signaling

Lévi

Wan

Glotzbach

et al. 2011

Journal of Biological Chemistry

155

164

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Background: ASCs are promising for skeletal regeneration, but their heterogeneity limits their use. Results: Microfluidic analysis and FACS identified a cellular subset (CD105 low ) with enhanced osteogenic capacity. Conclusion: CD105 depletion was found to enhance osteogenesis through reduction of TGF-␤1 signaling. Significance: We illuminate the functional relevance of hASC heterogeneity and enhance understanding of CD105 with respect to osteogenic differentiation.

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HIF-1α dysfunction in diabetes

Thangarajah¹,

Vial²,

Grogan³

et al. 2010

Cell Cycle

185

145

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Diabetic wounds are a significant public health burden, with slow or nonhealing diabetic foot ulcers representing the leading cause of non-traumatic lower limb amputation in developed countries. These wounds heal poorly as a result of compromised blood vessel formation in response to ischemia. We have recently shown that this impairment in neovascularization results from a high glucose-induced defect in transactivation of hypoxia-inducible factor-1alpha (HIF-1alpha), the transcription factor regulating vascular endothelial growth factor (VEGF) expression. HIF-1 dysfunction is the end result of reactive oxygen species-induced modification of its coactivator p300 by the glycolytic metabolite methylglyoxal. Use of the iron chelator-antioxidant deferoxamine (DFO) reversed these effects and normalized healing of humanized diabetic wounds in mice. Here, we present additional data demonstrating that HIF-1alpha activity, not stability, is impaired in the high glucose environment. We demonstrate that high glucose-induced impairments in HIF-1alpha transactivation persist even in the setting of constitutive HIF-1alpha protein overexpression. Further, we show that high glucose-induced hydroxylation of the C-terminal transactivation domain of HIF-1alpha (the primary pathway regulating HIF-1alpha/p300 binding) does not alter HIF-1alpha activity. We extend our study of DFO's therapeutic efficacy in the treatment of impaired wound healing by demonstrating improvements in tissue viability in diabetic mice with DFO-induced increases in VEGF expression and vascular proliferation. Since DFO has been in clinical use for decades, the potential of this drug to treat a variety of ischemic conditions in humans can be evaluated relatively quickly.

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