Christopher G. Elliott scite author profile

SummaryThe matricellular protein periostin is expressed in the skin. Although periostin has been hypothesized to contribute to dermal homeostasis and repair, this has not been directly tested. To assess the contribution of periostin to dermal healing, 6 mm full-thickness excisional wounds were created in the skin of periostin-knockout and wild-type, sex-matched control mice. In wild-type mice, periostin was potently induced 5-7 days after wounding. In the absence of periostin, day 7 wounds showed a significant reduction in myofibroblasts, as visualized by expression of a-smooth muscle actin (a-SMA) within the granulation tissue. Delivery of recombinant human periostin by electrospun collagen scaffolds restored a-SMA expression. Isolated wild-type and knockout dermal fibroblasts did not differ in in vitro assays of adhesion or migration; however, in 3D culture, periostin-knockout fibroblasts showed a significantly reduced ability to contract a collagen matrix, and adopted a dendritic phenotype. Recombinant periostin restored the defects in cell morphology and matrix contraction displayed by periostin-deficient fibroblasts in a manner that was sensitive to a neutralizing anti-b1-integrin and to the FAK and Src inhibitor PP2. We propose that periostin promotes wound contraction by facilitating myofibroblast differentiation and contraction.

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Spatiotemporal expression of periostin during skin development and incisional wound healing: lessons for human fibrotic scar formation

Zhou

Wang

Elliott

et al. 2010

J. Cell Commun. Signal.

123

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Loss of PTEN Expression by Dermal Fibroblasts Causes Skin Fibrosis

Parapuram

Elliott

et al. 2011

Journal of Investigative Dermatology

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Fibrosis represents a common pathway leading to organ failure and death in many diseases and has no effective therapy. Dysregulated repair and excessive tissue scarring provides a unifying mechanism for pathological fibrosis. The protein phosphatase and tensin homolog (PTEN) acts to dephosphorylate proteins, which promotes tissue repair and thus could be a key fibrogenic mediator. To test this hypothesis, we first showed that PTEN expression was reduced in skin fibroblasts from patients with the fibrotic autoimmune disease diffuse systemic sclerosis (dSSc). To evaluate whether this deficiency could be sufficient for fibrogenesis in vivo, we deleted PTEN in adult mouse fibroblasts. Compared with littermate control mice, loss of PTEN resulted in a 3-fold increase in dermal thickness due to excess deposition of collagen. PTEN-deleted fibroblasts showed elevated Akt phosphorylation and increased expression of connective tissue growth factor (CTGF/CCN2). Selective inhibition of the phosphatidylinositol 3-kinase/Akt pathway reduced the overexpression of collagen and CCN2 by PTEN-deficient fibroblasts. Overexpression of PTEN reduced the overexpression of type I collagen and CCN2 by dSSc fibroblasts. Thus, PTEN appears to be a potential in vivo master regulator of fibrogenesis; PTEN agonists may represent anti-fibrotic treatments.

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TGF-β1 and FAK Regulate Periostin Expression in PDL Fibroblasts

Wen¹,

Chau²,

Jackson-Boeters³

et al. 2010

J Dent Res

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Recently identified as a key component of the murine periodontal ligament (PDL), periostin has been implicated in the regulation of collagen fibrillogenesis and fibroblast differentiation. We investigated whether periostin protein is expressed in the human PDL in situ and the mechanisms regulating periostin expression in PDL fibroblasts in vitro. With immunohistochemistry, periostin protein was identified in the PDL, with expression lower in teeth with reduced occlusal loading. In vitro application of uniaxial cyclic strain to PDL fibroblasts elevated periostin mRNA levels, depending on the age of the patient. Treatment with transforming growth factor-beta1 (TGF-β1) also significantly increased periostin mRNA levels, an effect attenuated by focal adhesion kinase (FAK) inhibition. FAK-null fibroblasts contained no detectable periostin mRNA, even after stimulation with cyclic strain. In conclusion, periostin protein is strongly expressed in the human PDL. In vitro, periostin mRNA levels are modulated by cyclic strain as well as TGF-β1 via FAK-dependent pathways.

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Creating 3D Angiogenic Growth Factor Gradients in Fibrous Constructs to Guide Fast Angiogenesis

Guo

Elliott

et al. 2012

Biomacromolecules

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Fast angiogenesis in 3D fibrous constructs that mimic the morphology of the extracellular matrix remains challenging due to limited porosity in the densely packed constructs. We investigated whether mimicking the in vivo chemotaxis microenvironment for native blood vessel formation would stimulate angiogenesis in the fibrous constructs. The chemotaxis microenvironment was created by introducing 3D angiogenic growth factor gradients into the constructs. We have developed a technique that can quickly fabricate (∼40 min) such 3D gradients by simultaneously electrospinning polycaprolactone (PCL) fibers, encapsulating gradient amount of bFGF (stabilized by heparin) into poly(lactide-co-glycolide) (PLGA) microspheres, and electrospraying the microspheres into PCL fibers. Gradient formation was confirmed by fluorescence microscopy. Gradients with different steepnesses were obtained by modulating the initial concentration of the bFGF solution. All of the constructs were able to sustainedly release bioactive bFGF over a 28 day period. The release kinetics was dependent on the bFGF loading and steepness of the gradient. In vitro cell migration study demonstrated that bFGF gradients significantly increased the depth of cell migration. To assess the efficacy of bFGF gradients in inducing angiogenesis, we implanted constructs subcutaneously using mouse model. bFGF gradients significantly promoted cell penetration into the constructs. After 10 days of implantation, a high density of mature blood vessels (positive to both CD31 and α-SMA) were formed in the constructs. Vessel density was increased with the increase in steepness of the bFGF gradient. These gradient constructs may have potential to engineer vascularized tissues for various applications.

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