Resolution Mediator Chemerin15 Reprograms the Wound Microenvironment to Promote Repair and Reduce Scarring

Cash, Jenna L.; Bass, Mark D.; Campbell, Jessica; Barnes, Matthew J.; Kubes, Paul; Martin, Paul

doi:10.1016/j.cub.2014.05.006

Cited by 62 publications

(52 citation statements)

References 35 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Conditional depletion of macrophages has been shown to reduce liver fibrosis when induced early, but had pro-fibrotic effects when induced at advanced stages of fibrosis (Duffield et al, 2005). Macrophages are now understood to exist in a spectrum of different activation (polarization) types that control different phases of healing and it will be important to target specific macrophages to achieve scarless healing (Cash et al, 2014;Davies et al, 2013;Friedman et al, 2013;Lucas et al, 2010;Mantovani et al, 2013;Martinez and Gordon, 2014;Mosser and Edwards, 2008;Wynn et al, 2013).…”

Section: A C C E P T E D Accepted Manuscriptmentioning

confidence: 98%

Myofibroblasts

Hinz¹

2016

Experimental Eye Research

362

341

View full text Add to dashboard Cite

Myofibroblasts are activated in response to tissue injury with the primary task to repair lost or damaged extracellular matrix. Enhanced collagen secretion and subsequent contraction - scarring - are part of the normal wound healing response and crucial to restore tissue integrity. Due to myofibroblasts ability to repair but not regenerate, accumulation of scar tissue is always associated with reduced organ performance. This is a fair price to pay by the body for not falling apart. Whereas myofibroblasts typically vanish after successful repair, dysregulation of the normal repair process can lead to persistent myofibroblast activation, for instance by chronic inflammation or mechanical stress in the tissue. Excessive repair leads to the accumulation of stiff collagenous ECM contractures - fibrosis - with dramatic consequences for organ function. The clinical need to terminate detrimental myofibroblast activities has stimulated researchers to answer a number of essential questions: where do myofibroblasts come from, what are the factors leading to their activation, how do we discriminate myofibroblasts from other cells, what is the molecular basis for their contractile activity, and how can we stop or at least control them? This article reviews the current state of the myofibroblast literature by emphasizing their role in ocular repair and fibrosis. It appears that although the eye is quite an extraordinary organ, ocular myofibroblasts behave or misbehave just like their siblings in other organs.

show abstract

Section: A C C E P T E D Accepted Manuscriptmentioning

confidence: 98%

Myofibroblasts

Hinz¹

2016

Experimental Eye Research

362

341

View full text Add to dashboard Cite

show abstract

“…Chemerin-15, a synthetic peptide, signals via Cmklr1 to elicit many of the same biological effects as chemerin (Cash et al 2008). Cash et al (2014) reported that chemerin-15 alters collagen deposition in injured skin. Since chemerin-15 and chemerin signal via Cmklr1 (Cash et al 2008;Bondue et al 2011), it is plausible that chemerin-Cmklr1 signaling modifies collagen deposition in skin as well as in other organs, including the lungs, a phenomenon that would significantly impact the quasistatic elastic properties of the respiratory system.…”

Section: Effect Of O 3 and Ccrl2 Deficiency On Lung Injury And Lung Imentioning

confidence: 99%

Chemokine (C-C Motif) Receptor-Like 2 is not essential for lung injury, lung inflammation, or airway hyperresponsiveness induced by acute exposure to ozone

et al. 2017

View full text Add to dashboard Cite

Inhalation of ozone (O3), a gaseous air pollutant, causes lung injury, lung inflammation, and airway hyperresponsiveness. Macrophages, mast cells, and neutrophils contribute to one or more of these sequelae induced by O3. Furthermore, each of these aforementioned cells express chemokine (C‐C motif) receptor‐like 2 (Ccrl2), an atypical chemokine receptor that facilitates leukocyte chemotaxis. Given that Ccrl2 is expressed by cells essential to the development of O3‐induced lung pathology and that chemerin, a Ccrl2 ligand, is increased in bronchoalveolar lavage fluid (BALF) by O3, we hypothesized that Ccrl2 contributes to the development of lung injury, lung inflammation, and airway hyperresponsiveness induced by O3. To that end, we measured indices of lung injury (BALF protein, BALF epithelial cells, and bronchiolar epithelial injury), lung inflammation (BALF cytokines and BALF leukocytes), and airway responsiveness to acetyl‐β‐methylcholine chloride (respiratory system resistance) in wild‐type and mice genetically deficient in Ccrl2 (Ccrl2‐deficient mice) 4 and/or 24 hours following cessation of acute exposure to either filtered room air (air) or O3. In air‐exposed mice, BALF chemerin was greater in Ccrl2‐deficient as compared to wild‐type mice. O3 increased BALF chemerin in mice of both genotypes, yet following O3 exposure, BALF chemerin was greater in Ccrl2‐deficient as compared to wild‐type mice. O3 increased indices of lung injury, lung inflammation, and airway responsiveness. Nevertheless, no indices were different between genotypes following O3 exposure. In conclusion, we demonstrate that Ccrl2 modulates chemerin levels in the epithelial lining fluid of the lungs but does not contribute to the development of O3‐induced lung pathology.

show abstract

“…These pathways offer enormous potential to therapeutically modulate the resolution phase of inflammation and thus impact on the repair process (158,160). Indeed, we have previously shown that topical application of the peptide resolution mediator chemerin15 dampens the wound inflammatory response and skews the Mϕ phenotype to one typically associated with repair (reduced inducible NOS and TNF-α; increased arginase-1), resulting in accelerated healing with reduced scarring (161).…”

Section: Harnessing Proresolving Pathways To Drive Repairmentioning

confidence: 98%

Myeloid Cells in Cutaneous Wound Repair

Cash

Martin

2016

Microbiol Spectr

Self Cite

View full text Add to dashboard Cite

Cutaneous wound repair is a complex, dynamic process with the goal of rapidly sealing any breach in the skin's protective barrier. Myeloid cells compose a significant proportion of the inflammatory cells recruited to a wound site and play important roles in decontaminating the injured tissue of any invading microorganisms. Subsequently, myeloid cells are able to influence many aspects of the healing response, in part through their capacity to release a large array of signaling molecules that allow them to communicate with and regulate the behavior of other wound cells and in turn, be themselves exquisitely regulated by the wound microenvironment. Macrophages, for example, appear to play important, temporally changing roles in the initiation of scarring and subsequently in matrix remodeling to resolve fibrosis. In this way, myeloid cells seem to play both positive (e.g., pathogen killing and matrix remodeling) and negative (e.g., scarring) roles in wound repair. Further research is of course needed to elucidate the precise temporal and spatial myeloid cell phenotypes and behaviors and ultimately to design effective strategies to optimize the beneficial functions of these cells while minimizing their detrimental contributions to improve wound healing in the clinic.

show abstract

Resolution Mediator Chemerin15 Reprograms the Wound Microenvironment to Promote Repair and Reduce Scarring

Cited by 62 publications

References 35 publications

Myofibroblasts

Myofibroblasts

Chemokine (C-C Motif) Receptor-Like 2 is not essential for lung injury, lung inflammation, or airway hyperresponsiveness induced by acute exposure to ozone

Myeloid Cells in Cutaneous Wound Repair

Contact Info

Product

Resources

About