Vlad C. Sandulache

Prostaglandin E2 inhibition of keloid fibroblast migration, contraction, and transforming growth factor (TGF)-β1–induced collagen synthesis

Keloid formation has been linked to aberrant fibroblast activity, exacerbated by growth factors and inflammatory mediators. Prostaglandin E2 (PGE2), synthesized from arachidonic acid by cyclooxygenases (COX) and synthases (PGES), acts as both an inflammatory mediator and fibroblast modulator. Although PGE2 has known antifibrotic effects in the lower airway, its role in dermal fibrosis in general, and keloid formation in particular, remains unclear. This study focused on: (1) the effects of PGE2 on keloid fibroblast migration, contraction, and collagen synthesis and (2) endogenous PGE2 synthesis in response interleukin‐1β. PGE2 decreased keloid fibroblast migration and contraction via an EP2/EP4–cAMP mechanism that disrupted actin cytoskeletal dynamics and reversed transforming growth factor‐β1–induced collagen I and III synthesis. Impaired fibroblast PGE2 production has been linked to lower airway fibrosis and recently to keloid formation. Here, we showed that interleukin‐1β stimulation leads to nuclear factor‐κB translocation to the nucleus, resulting in up‐regulation of COX‐2 and microsomal PGE2 synthase 1. Up‐regulation of COX‐2 in, and secretion of PGE2 by keloid fibroblasts are diminished compared with their normal fibroblast counterparts. We suggest that the antifibrotic effects of PGE2 during keloid formation are potentially diminished due to aberrant paracrine fibroblast signaling. Exogenous PGE2 may supplement decreased endogenous levels and inhibit keloid formation or progression.

Prostaglandin E2 differentially modulates human fetal and adult dermal fibroblast migration and contraction: implication for wound healing.

Cyclooxygenase‐2 is up‐regulated shortly after dermal injury and it has been shown to have important activity during the repair process. Its main product in the skin, prostaglandin E2 (PGE2), modulates both inflammatory and fibrotic processes during wound healing and partially dictates the overall outcome of wound healing. PGE2 signaling has been shown to be altered during fetal wound healing. This study was designed to examine the mechanism(s) by which PGE2 regulates fibroblast migration and contraction and to determine whether these mechanisms are conserved in fetal‐derived dermal fibroblasts. Fetal and adult dermal fibroblasts express all four PGE2 receptors. PGE2 inhibits fetal and adult fibroblast migration in a dose‐dependent manner through the EP2/EP4–cAMP–protein kinase A pathway. However, fetal fibroblasts appear to be refractory to this effect, requiring a 10‐fold higher concentration of PGE2 to achieve a similar degree of inhibition as adult fibroblasts. Inhibition of adult fibroblast migration correlated with disruption of the actin cytoskeleton. In contrast, PGE2 or a cAMP analog did not disrupt the actin cytoskeleton of fetal dermal fibroblasts. These findings were extended using a modified free‐floating, fibroblast‐populated collagen lattice (FPCL) contraction assay designed to measure fibroblast contraction. PGE2‐inhibited FPCL contraction by adult fibroblasts, but fetal fibroblasts exhibited higher rates of FPCL contraction and a blunted response to exogenous modulation by PGE2 or a cyclase activator (forskolin). These findings indicate that fetal dermal fibroblasts are partially refractory to the effects of PGE2, a major inflammatory mediator associated with dermal wound healing. This effect may have significant and specific relevance to the scarless fetal wound‐healing phenotype.

Subglottic Stenosis Examined as a Fibrotic Response to Airway Injury Characterized by Altered Mucosal Fibroblast Activity

OBJECTIVE To investigate the association between mucosal fibroblast activity and subglottic stenosis (SGS) development. DESIGN Prospective study of an animal model of SGS. SETTING Academic research laboratory. SUBJECTS New Zealand white rabbits were assigned to either the cricothyroidotomy and carbon dioxide laser injury group or the cricothyroidotomy and silver nitrate injury group. Airways were excised for histologic analysis and the establishment of primary fibroblast cultures. Lesions from surgical excision of established SGS and subglottic tissue were used to analyze SGS recurrence. INTERVENTIONS The subglottis was approached via cricothyroidotomy and was subjected to either carbon dioxide laser or silver nitrate injury before closure. The SGS lesions were excised at 8 to 10 weeks and were used to establish explants for fibroblast culture. The animals underwent recovery for an additional 14 days to follow recurrence of SGS. After 14 days, all the animals were killed humanely, and subglottic tissue was harvested for histologic evaluation. Rates of migration and contraction of SGS and normal airway fibroblasts were assayed using established in vitro methods under basal conditions and with prostaglandin E(2) treatment. MAIN OUTCOME MEASURES For in vivo studies, injury, healing, and scarring of the mucosa and cartilage were the primary measures. For cultured fibroblast experiments, cellular responses of fibroblasts from normal and stenosed mucosa were compared and contrasted. RESULTS Mucosal injury resulted in acute fibroplasia and chronic SGS, surgical excision of mature SGS at 8 weeks resulted in rapid recurrence of stenosis, and SGS-derived fibroblasts were relatively refractory to the effects of prostaglandin E(2) on migration and contraction. CONCLUSIONS Subglottic stenosis represents a fibrotic airway repair process that involves fibroblasts that produce recurrent, excessive scar formation. We suggest that SGS development and recurrence may be partially dictated by altered fibroblast responsiveness to antifibroplastic signals during mucosal repair.

Prostaglandin E2 differentially regulates contraction and structural reorganization of anchored collagen gels by human adult and fetal dermal fibroblasts

Contraction and remodeling of granulation tissue by fibroblasts is a crucial component of dermal wound healing. Postnatal wounds heal with imperfect repair and scar formation, whereas tissue repair in fetal wounds is regenerative. Prostaglandin E2 (PGE2) modulates the behavior of fibroblasts in the wound bed. This study was designed to investigate the mechanism by which PGE2 regulates an in vitro model of granulation tissue, anchored collagen gels, by human adult and fetal dermal fibroblasts. We hypothesized that PGE2 differentially regulates contraction and remodeling of anchored collagen gels by these fibroblast phenotypes. These results indicate that once tension was generated, fetal fibroblasts exerted lower contractile forces resulting in less collagen contraction. This coincided with less prominent stress fibers, yet fetal fibroblasts were able to substantially remodel the collagen architecture. This mechanism was differentially modulated by PGE2 and was mimicked with a PGE2 receptor agonist, indicating a cyclic adenosine monophosphate (cAMP)‐dependent mechanism through the EP2 receptor. However, direct up‐regulation of cAMP led to decreases in contraction and remodeling by both fibroblast phenotypes indicating an altered signaling pathway. Therefore, targeting cAMP via the EP2 receptor could potentially decrease adult fibroblast contractile forces to the levels of the fetal fibroblast phenotype in order to decrease dermal scarring.

Differential regulation of free‐floating collagen gel contraction by human fetal and adult dermal fibroblasts in response to prostaglandin E2 mediated by an EP2/cAMP‐dependent mechanism

In contrast to fetal wound healing, dermal adult wound healing results in imperfect repair and scar formation. Fibroblasts are responsible for the contraction and remodeling of the wound matrix, which is influenced by inflammatory mediators including prostaglandin E2 (PGE2). This study addresses the mechanism by which PGE2 regulates contraction of collagen gels by human fetal and adult dermal fibroblasts. We hypothesized that the intrinsic phenotypic properties of the two types of fibroblasts and their responses to PGE2 alter their contraction properties and contribute to different wound healing outcomes. Contraction was evaluated using free‐floating fibroblast‐populated collagen gels that contract by migratory forces. PGE2 was found to differentially inhibit collagen gel contraction by fetal and adult fibroblasts. This effect was mimicked by a specific PGE2 receptor agonist as well as by two pharmacological agents, indicating a cyclic adenosine monophosphate‐dependent signaling pathway mediated through the EP2 receptor. Our results indicate that fetal fibroblast contraction is maintained by a more stable actin cytoskeleton. Therefore, the migratory phenotype may be sufficient for physical remodeling of the wound matrix leading to regenerative repair. Maintenance of this phenotype in the later stages of wound healing could potentially be achieved by targeting cyclic adenosine monophosphate via the EP2 receptor.

Adult-fetal fibroblast interactions: effects on cell migration and implications for cell transplantation.

Wound healing is a complex process involving close cooperation between multiple cell types. During wound healing, fibroblasts are primarily responsible for synthesis of the replacement extracellular matrix. Fibroblast therapy is under investigation in this and other laboratories for its potential use to modulate the final outcome of the wound-healing process. This study addresses the potential interactions between transplanted and host fibroblasts, using a two-dimensional mixed culture model. Our results show that fibroblasts of two different phenotypes, fetal and adult, exhibit different speeds of in vitro migration. These migration speeds are conserved in mixed cocultures, suggesting that the migratory response is an intrinsic property of the fibroblast rather than a response to juxtacrine or paracrine signals. These results have relevance for cell-based therapies in that they demonstrate that donor fibroblasts of a different phenotype may at least partially retain that phenotype in the host environment and in the presence of endogenous fibroblasts.

Acute and Chronic Changes in the Subglottis Induced by Graded Carbon Dioxide Laser Injury in the Rabbit Airway

OBJECTIVE To investigate the repair process following carbon dioxide laser injury to the upper airway mucosa (UAM) during the development of chronic subglottic stenosis (SGS). DESIGN Animals were assigned to either sham control (cricothyroidotomy only) or injured (cricothyroidotomy and posterior subglottic laser) groups using various carbon dioxide laser exposures (8, 12, and 16 W) for 4 seconds. SUBJECTS Twenty-four New Zealand white rabbits. INTERVENTIONS The subglottis was approached via cricothyroidotomy. Sham control airways were immediately closed, whereas injured airways were subjected to graded carbon dioxide laser exposures prior to closure. Airways were endoscopically monitored preoperatively, postoperatively, and on postoperative days 7, 14, 28, 42, 56, 70, and 84. Animals were killed at 14 and 84 days. Subglottic tissue was harvested for histologic evaluation (reepithelialization, extracellular matrix, vascularity, and inflammation). MAIN OUTCOME MEASURES Endoscopic visualization and histologic analysis. RESULTS (1) Increases in UAM thickness (up to 5 times the thickness of normal mucosa) were observed but were limited primarily to the lamina propria. The mucosal epithelium regenerated without chronic changes. Focal areas of cartilage repair were encountered acutely after injury and to a greater extent in the chronic phases of repair. (2) Acutely, the thickened lamina propria comprised poorly organized extracellular matrix components and demonstrated increases in blood vessel size and number. (3) Histologic changes present in the acute phase only partially resolved in progression to chronic SGS. Chronic SGS was characterized by thick collagen fiber bundles extending into the remodeled subglottic cartilage. CONCLUSIONS The carbon dioxide laser induces acute changes to lamina propria architecture and vascularity that persist chronically. Elucidating responsible signaling pathways may facilitate the development of therapeutic agents to prevent or reduce the formation of SGS.

Migrating Cells Retain Gap Junction Plaque Structure and Function

Cell migration is an essential process in organ development, differentiation, and wound healing, and it has been hypothesized that gap junctions play a pivotal role in these cell processes. However, the changes in gap junctions and the capacity for cell communication as cells migrate are unclear. To monitor gap junction plaques during cell migration, adrenocortical cells were transfected with cDNA encoding for the connexin 43–green fluorescent protein. Time-lapse imaging was used to analyze cell movements and concurrent gap junction plaque dynamics. Immunocytochemistry was used to analyze gap junction morphology and distribution. Migration was initiated by wounding the cell monolayer and diffusional coupling was demonstrated by monitoring Lucifer yellow dye transfer and fluorescence recovery after photobleaching (FRAP) in cells at the wound edge and in cells located some distance from the wound edge. Gap junction plaques were retained at sites of contact while cells migrated in a “sheet-like” formation, even when cells dramatically changed their spatial relationship to one another. Consistent with this finding, cells at the leading edge retained their capacity to communicate with contacting cells. When cells detached from one another, gap junction plaques were internalized just prior to cell process detachment. Although gap junction plaque internalization clearly was a method of gap junction removal during cell separation, cells retained gap junction plaques and continued to communicate dye while migrating.

Prostaglandin E2 is activated by airway injury and regulates fibroblast cytoskeletal dynamics

To characterize the activation of cyclooxygenase (COX)‐2/prostaglandin (PG) E2 signaling during airway mucosal repair and its subsequent role during the wound healing process.

Cyclooxygenase-2 Inhibition for the Prevention of Subglottic Stenosis

OBJECTIVE To evaluate the role of targeted cyclooxygenase-2 inhibition in reducing scarring associated with a subglottic airway mucosal injury. DESIGN Thirty-four New Zealand white rabbits underwent anterior cricothyroidotomy. Subglottic stenosis (SGS) was created by carbon dioxide laser injury. INTERVENTION Treatment consisted of intraperitoneal injection of celecoxib or vehicle for 4 days. Endoscopies were performed to assess injury and healing. Subglottic mucosal secretions were collected with Gelfoam swabs (Pfizer Inc) before and after injury and at subsequent time points. Animals were humanely killed at 3 or 8 weeks after injury and airways were excised, followed by gross examination and histologic analysis to assess the severity of SGS. Secretions were analyzed for interleukin-1β, prostaglandin E2 (PGE2), and matrix metalloproteinase-8 by enzyme-linked immunosorbent assays. RESULTS Endoscopy showed mild to moderate stenosis in the celecoxib group, but mild to severe stenosis in the vehicle group. Histologic assessment confirmed and quantified reduction in stenosis and scarring as well as advanced reepithelialization. In the healing tissue, mucosal thickening (stenosis) was reduced significantly (P = .02) in celecoxib-treated animals compared with those treated with vehicle, at 3 and 8 weeks (decrease in thickness by 32% and 49%, respectively). Collagen density (fibrosis) was also reduced 25% at both 3 and 8 weeks but the difference was not statistically significant (P = .20). Reduced level of PGE2 in the subglottic mucosal secretions was correlated with mucosal thickness at 8 weeks (P = .02). CONCLUSION Short-duration, anti-inflammatory therapy resulted in reduced stenosis and fibrosis with correlation of PGE2 levels in subglottic mucosal secretions.