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Vol. 97. Núm. 5.
Páginas 575-582 (1 setembro 2022)
Original Article
Open Access
Fibroblast morphology, growth rate and gene expression in facial melasma
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5048
Ana Cláudia Cavalcante Espósitoa, Gabrielli Brianezib, Luciane Donida Bartoli Miota, Hélio Amante Miota,
Autor para correspondência
heliomiot@gmail.com

Corresponding author.
a Department of Dermatology and Radiotherapy, Faculty of Medicine, Universidade Estadual Paulista, Botucatu, SP, Brazil
b Department of Pathology, Faculty of Medicine, Universidade Estadual Paulista, Botucatu, SP, Brazil
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Abstract
Background

In addition to melanocytic hyperfunction, changes are observed in the upper dermis of melasma, and fibroblasts play a central role in collagen synthesis and pigmentation induction.

Objective

To explore the morphology, growth rate, and gene expression profile of fibroblasts from the skin with melasma in comparison to fibroblasts from the adjacent healthy skin.

Methods

Ten women with facial melasma were biopsied (lesion and adjacent healthy skin), and the fragments were processed for fibroblast culture. Samples from five participants were seeded to evaluate growth (days 2, 5 and 8) and senescence (SA-β-gal) curves. The samples from the other participants were submitted to real-time PCR to comparatively evaluation of the expression of 39 genes.

Results

Cultured fibroblasts from melasma skin were morphologically less fusiform in appearance and on average a 34% (95% CI 4%‒63%) greater proportion of cells labeled with SA-β-gal than the fibroblasts from the adjacent skin. The cell growth rate was lower for the melasma samples after eight days (p < 0.01). TheWNT3A, EDN3, ESR2, PTG2, MMP1, and SOD2 genes were up-regulated, whereas the COL4A1, CSF2, DKK3, COL7A1, TIMP4, CCL2, and CDH11 genes were down-regulated in melasma skin fibroblasts when compared to the ones from adjacent healthy skin.

Study limitations

Small sample size; absence of functional tests.

Conclusions

Fibroblasts from the skin with melasma showed a lower growth rate, less fusiform morphology and greater accumulation of SA-β-gal than those from adjacent photo exposed skin. Moreover, their gene expression profile comprised factors that may contribute to upper dermis damage and sustained melanogenesis.

Keywords:
Aging
Collagen
Melasma
Pigmentation disorders
Ultraviolet rays
Texto Completo
Introduction

Melasma is a highly prevalent acquired dyschromia, which results from an increase in the activity of the epidermal melanin unit.1 Lesions affect photo exposed areas (e.g., the face), especially in women during menacme. Its pathogenesis is not yet fully understood, and the role of basement membrane zone alterations, damage to the upper dermis, and fibroblast activity in the development of the disease are posed as recent research questions.2–5

Compared with the adjacent healthy skin (photoexposed), the skin with melasma has an increased amount of epidermal melanin, more mature melanosomes, hypertrophied melanocytes, and prominent solar elastosis. There is also an increase in the number of vessels and mast cells, as well as increased expression of inflammatory mediators, such as iNOS, NF-Kβ, endothelin, and growth factors, such as VEGF, and growth factors derived from hepatocytes,-stem cells, fibroblasts and nerves.6 Pendulum melanocytes – basement layer melanocytes that project toward the upper dermis – and basement membrane alterations have also been described in melasma.2 There is a decrease in type I collagen associated with an increase in metalloproteinase activity (MMP 1, 2, 3, and 9).7 Some genes related to lipid metabolism are down-regulated in melasma skin and the skin barrier function is impaired.8

Sun exposure is the main risk factor for the development of melasma. Chronic photoexposure, in addition to melanogenesis, induces oxidative stress, which promotes cellular senescence.5 In addition to photoaging and intrinsic aging, melasma has a more prominent senescent phenotype in affected skin. Ultraviolet radiation (UVR)-induced early cell senescence promotes functional alterations that can trigger and perpetuate melanogenesis.9,10

Fibroblasts play a central role in pigmentation and their transition to a senescent profile promotes a modification of their autocrine and paracrine activity.10 In melasma skin, fibroblasts release more stem cell-derived factors and its epidermal receptor c-kit.11 Senescent fibroblasts can express inflammatory and melanogenic factors, which can lead to the development of melasma.3

The senescent phenotype was identified in fibroblasts with melasma more intensely than in adjacent photo exposed skin, based on the immunoexpression of p16INK4A, which may justify the stimulus for sustained skin pigmentation.9,10 However, to date, the potential for cell replication has not been explored, and the gene expression profile of these dermal fibroblasts has not been characterized regarding the growth factors and tissue repair, activation of the WNT/β-catenin (WNT) tissue growth pathway, neocollagenesis, metalloproteinase synthesis, estrogen receptors, and antioxidant mechanisms. This characterization can support pathophysiological models and treatment strategies.

This study aimed to explore the morphology, growth rate and gene expression profile of fibroblasts from facial melasma, compared to adjacent photoexposed skin.

Methods

This project was approved by the Research Ethics Council (Unesp, Botucatu-SP, number 0461-11). and all participants consented to participate.

Ten adult women with facial melasma underwent biopsy (2-mm punch, using a sterile technique) of the melasma skin on the malar region and from the adjacent, clinically normal, photoexposed skin (<2 cm of distance), laterally. The participants were untreated for the dermatosis for at least 30 days, except for the use of sunscreen.

The skin fragments were sectioned and placed in fibroblast culture, maintained in medium 106 (Gibco™) containing growth factors (LSGS Kit, Gibco™). The fibroblasts were seeded (in triplicate) at a density of 5 × 103 in a 12-well cell culture plate.

Cultured fibroblasts, from healthy and damaged skin, from five participants, were seeded at a density of 1 × 104 in a 6-well cell culture plate, and the number of cells per cm2 was evaluated after two, five and eight days, based on the evaluation of 30 fields, and compared (between topographies) by a generalized linear mixed-effects model. Sample normality was evaluated by the Shapiro-Wilk test.

Subsequently, cell senescence was evaluated using senescence β-galactosidase (SA-β-gal) staining kit (Cell Signaling Technology®), following the manufacturer's instructions. After 24 hours of cell plating, the culture medium was removed, followed by washing with PBS and the addition of fixation solution for 15 minutes at room temperature. Then, it was washed with PBS twice, followed by overnight incubation with β-galactosidase solution (Cell Signaling Technology®) at 37 °C. After the solution was removed, 70% glycerin was added.

A total of 300 cells were counted per sample. The morphology of the cultured fibroblasts and the percentage of cells labeled with cytoplasmic SA-β-gal were compared between the topographies (melasma and adjacent healthy skin).

Fibroblasts from the primary cell culture of the other five participants were submitted to a real-time PCR array (96-well plate, Custom RT2 Profiler PCR Arrays, Qiagen) to assess the expression of 39 genes associated with growth factors and tissue repair, WNT pathway activation, neocollagenesis, metalloproteinase synthesis, estrogen receptors, and antioxidant mechanisms (Table 1). Total RNA was obtained with the RNase Mini Kit (Qiagen), and the RNA reverse transcription was performed using RT2 First Strand Kit for RT-PCR (Qiagen), following the manufacturer's instructions.

Table 1.

List of the 39 genes assessed in the study, and their main function in the skin.

Gene  Name  Main function (skin) 
CCL2  C-C Motif Chemokine Ligand 2  Chemokine involved in the tissue repair process 
CDH11  Cadherin 11  Related to cell adhesion and epithelial repair 
CDKN2A  Cyclin-dependent kinase inhibitor 2A  Cell response to inflammatory and neoplastic stimulus 
COL4A1  Type IV collagen  Basement membrane component 
COL7A1  Type VII collagen  Anchoring fibril component 
CSF2  Colony-stimulating factor 2  Involved in the process of epithelial repair 
DKK1  Dickkopf-related protein 1  Wnt/β-catenin cell growth pathway inhibitor 
DKK3  Dickkopf-related protein 3  Wnt/β-catenin cell growth pathway inhibitor 
EDN1  Type 1 endothelin  Induces melanogenesis and vascular proliferation 
EDN3  Type 3 endothelin  Induces melanogenesis and vascular proliferation 
ESR1  Estrogen Receptor 1 (α)  Estrogen receptor linked to the canonical pathway 
ESR2  Estrogen Receptor 2 (β)  Estrogen receptor linked to tissue repair 
FGF2  Fibroblast growth factor type 2  Tissue damage repair, mitotic for fibroblasts 
GLB1  Beta-galactosidase 1  Constitutional gene. Experiment control 
HGF  Hepatic growth factor  Tissue damage repair 
IL1A  Interleukin 1a  Primary inflammatory skin response 
IL1B  Interleukin 1b  Primary inflammatory skin response 
IL6  Interleukin 6  Primary inflammatory skin response 
MAPK14  Mitogen-activated protein kinase 14  Cell response to inflammatory stimulus 
MIF  Macrophage migration inhibitory factor  Primary inflammatory skin response 
MMP1  Matrix metalloproteinase type 1  Degradation of type I, II and III collagen 
MMP2  Matrix metalloproteinase type 2  Degradation of type IV collagen 
MMP7  Matrix metalloproteinase type 7  Extracellular matrix degradation 
MMP9  Matrix metalloproteinase type 9  Extracellular matrix degradation and angiogenesis 
NGR1  Type 1 neuregulin  Regulates melanocytic growth and skin color 
OXR1  Oxidative resistance protein type 1  Cell response to oxidative stress 
OXSR1  Oxidative stress protein type 1  Cell response to oxidative stress 
PTGS2  Cyclooxygenase type 2  Prostaglandin E2 synthesis 
SOD1  Superoxide dismutase type 1  Protects the cell from active oxygen species 
SOD2  Superoxide dismutase type 2  Induced in response to mitochondrial oxidative stress 
TIMP1  Tissue inhibitor of metalloproteinases 1  Inhibitor of collagen I, II and III degradation 
TIMP2  Tissue inhibitor of metalloproteinases 2  Inhibitor of collagen IV degradation 
TIMP3  Tissue inhibitor of metalloproteinases 3  Inhibitor of collagen and extracellular matrix degradation 
TIMP4  Tissue inhibitor of metalloproteinases 4  Inhibitor of extracellular matrix degradation 
TP53  p53 protein  UVB photoaggression marker, anti-angiogenic 
VEGFA  Vascular endothelial growth factor type A  Promoter of angiogenesis 
WIF1  Wnt inhibitory factor-1  Inhibits the Wnt/β-catenin cell growth pathway 
WNT3A  WNT family member 3A  Wnt/β-catenin canonical pathway activator 
WNT5A  WNT family member 5A  Wnt non-canonical pathway activator 

The effect size for gene expression (2-ΔΔCt) was estimated by the fold change (melasma/adjacent skin) for each participant.12 Fold changes were represented by their mean and 95%CI, estimated by 10,000 resamplings with accelerated bias correction (BCa).

Results

The main clinical and demographic data of the assessed patients are shown in Table 2.

Table 2.

Main characteristics of the ten patients with facial melasma submitted to skin biopsy on the region with malar melasma and adjacent photoexposed facial skin, whose samples were used for: growth curve, morphology and SA-β-gal evaluation, or gene expression test.

Growth curve, morphology and SA-β-gal evaluation 
Case  Age  Phototype  Time length of melasma (years)  Family history of melasma  mMASI 
46  IV  10  Yes  9.5 
46  IV  13  Yes  8.2 
35  III  Yes  6.6 
41  IV  11  No  11.5 
38  IV  10  No  12.4 
Gene expression test
41  IV  23  No  9.9 
38  IV  17  Yes  19.2 
41  III  16  Yes  9.5 
47  III  28  Yes  7.6 
10  44  IV  No  10.1 

mMASI (modified Melasma Area Severity Index.

In all samples, cultured fibroblasts from melasma skin showed lower cell density, and the fibroblasts were morphologically less elongated, wider, and less fusiform, in addition to showing more cells labeled with SA-β-gal (mean superiority of 34%; 95%CI 4%‒63%; p < 0.05) than cultures from adjacent skin (Figs. 1 and 2). Moreover, the cell growth rate was lower for the melasma samples after eight days in culture (p < 0.01; Fig. 3).

Figure 1.

Phase-contrast microscopy showing fibroblasts from skin with facial melasma (A) and from adjacent healthy skin (B) in cell culture (SA-β-gal, ×400), showing lower cell density and less elongated (fusiform) wider morphology, in melasma.

(0.19MB).
Figure 2.

Fig. 1A magnification (×1000): senescent morphology of fibroblasts from skin with melasma, showing a higher proportion of juxtanuclear bodies (black arrow), frequent granular cytoplasmic structures (SA-β-gal+; white arrow), lipid droplets (white arrowhead), and segmented nucleoli (black arrowhead).

(0.13MB).
Figure 3.

Fibroblast growth curves (cell count per cm2) for five patients: healthy skin and skin with facial melasma. Horizontal line bar represents the mean of each sample. The data are compared longitudinally by a generalized linear mixed-effects model.

(0.09MB).

Changes in the gene expression were identified in fibroblasts isolated from melasma skin when compared to those isolated from adjacent healthy skin. The WNT3A, EDN3, ESR2, PTG2, MMP1, and SOD2 genes were up-regulated; COL4A1, CSF2, DKK3, COL7A1, TIMP4, CCL2, and CDH11 genes were down-regulated (Fig. 4).

Figure 4.

Fold change (mean Log2 and 95% CI) of the gene expression between skin with melasma and adjacent healthy skin assessed by real-time PCR array (n = 5).

(0.24MB).
Discussion

Melanogenesis is a complex process mediated by paracrine, autocrine, and environmental stimuli.13 The phenotypic changes seen in melasma skin are not primarily or solely due to epidermal alterations, as several dermal changes are evident in the affected skin when compared to adjacent healthy, photoexposed skin.14

Fibroblasts are the most common cell type in the dermis and, due to their great longevity, they accumulate damage to their cell machinery, which can result in functional and morphological alterations.10 Intrinsic aging and photoaging are associated with a decrease in fibroblast number and rate of proliferation; in this context, the comparison of the gene profile of fibroblasts originating from the skin with melasma with that of healthy adjacent photoexposed area reinforces that the gene alterations are independent of age and photoexposure.3,15

Considering the importance of dermal fibroblasts in pigmentation regulation, the modifications of their autocrine and paracrine activities can influence pigmentation disorders.10 In the present study, the loss of fusiform morphology, higher amount of cytoplasmic SA-β-gal, and lower growth rate of fibroblasts from the skin with melasma were identified. These morphological and metabolic changes support a senescent phenotype in melasma skin fibroblasts.

Senescence is a central factor in the mechanisms of aging, and the Senescence-Associated Secretory Phenotype (SASP) is known to be the main trigger of age-related phenotypes, such as wrinkles and pigmentation.16 It should be noted that there is evidence of phenotypic differences related to ethnicity and susceptibility to fibroblast senescence.17

Senescent fibroblasts secrete inflammatory cytokines and stem cell factors, which promote collagen degradation through MMP activation and have reduced mitotic potential. There is increased stromal degradation and impaired tissue repair, as evidenced in the dermis of melasma. Therefore, a mosaic structure of tissue susceptibility to senescence can be theorized for the development of melasma in the skin under environmental stimuli such as UV radiation and sex hormones.18

There was an increase in MMP1 gene expression and a decrease in collagen IV, VII (COL4A1, COL7A1), and TIMP4 expression in fibroblasts isolated from melasma skin. During the senescence process, there is a progressive increase in metalloproteinase production and a decrease in the repair process.10 Moreover, in dermal fibroblasts, α-MSH promotes the upregulation of interstitial collagenase and attenuates TGFβ1-induced collagen synthesis. Damage to the upper dermis and the basement membrane zone facilitates the transit of melanogenic factors to the basement layer. In the present study, despite a marginal implication, MMP9 showed a high fold change (>2), which, in association with the lower expression of TIMP1 and 4, suggests participation of melasma skin fibroblasts in the deficient repair of the upper dermis and angiogenesis.

The role of sex hormones in cutaneous estrogen receptor β expression in melasma is well established.19 Overall, ESR2 is expressed during the repair process.20 The upper dermis and basement membrane are heavily damaged in melasma skin, compared to adjacent healthy, photoexposed skin and photoprotected skin.1,14 Moreover, estrogen, α-MSH, and HGF stimulate melanogenesis by directly binding to the melanocyte receptor and are also released during the wound healing process.21,22 These findings indicate that the chromic and unsuccessful upper dermis repair process can induce melanogenesis in melasma.

Some genes related to the Wnt/β-catenin pathway showed different behavior in fibroblasts from the skin with melasma, in relation to photoexposed adjacent skin; the DKK3 inhibitory factor was down-regulated, while WNT3A was overexpressed. WNT3A plays an important role in controlling the proliferation and differentiation of melanocyte precursors and angiogenesis. In mature melanocytes, WNT3A increases the amount of melanin and tyrosinase activity.23 The Wnt pathway is involved in the pathophysiology of melasma, and the decreased expression of the inhibitory factor DKK3 in fibroblasts may influence the epidermal activation of WNT1.4 Moreover, WNT3A is important for the tissue repair process and can be activated due to damage to the upper dermis.24

EDN3 is a 21-amino acid peptide and preferentially activates EDNRB.25 EDN3 signaling is important in the normal development of epidermal and choroidal melanocytes, acting during cell proliferation, differentiation, and survival.26 Keratinocytes exposed to ultraviolet B radiation increase EDN production and secretion, causing adjacent melanocytes to activate the melanogenic cascade. Additionally, melanocytes exposed to this same radiation have an increased expression of c-KIT and EDNRB.26 EDN3 also participates in fibroblast chemotaxis, independently of prolonging cell survival and differentiation.27

Senescent fibroblasts are associated with impaired immune responses and skin tumor suppression, but SASP can vary among tissues and stimulus types.28 CSF participates in melanocyte growth, differentiation and survival, as well as in stem cell recruitment. Keratinocytes exposed to type A UVR in vitro have a higher level of CSF.29 Moreover, IL-1 produced by keratinocytes induces fibroblasts to synthesize CSF, which promotes keratinocyte proliferation and differentiation. A decrease in CSF in senescent fibroblasts can configure a reduction in keratinocyte stimuli, which hinders damaged tissue repair.30

CCL2 is a chemokine that acts as a critical regulator of macrophage and stem cell recruitment during wound healing, cancer, and infections.31 After cell stimulation with lipopolysaccharide, there is a constitutional down-regulation of CCL2 in melanocytes from melanodermic individuals in comparison with melanocytes from individuals with a low phototype.32 The CCL2 expression profile in fibroblasts can induce the darker focal phenotype of melasma.

Proteins from the cadherin family play an important role in intercellular adhesion and extracellular matrix synthesis regulation, as well as contributing to the signaling of events that control cell homeostasis.33 In skin fibroblasts, CDH11 regulates collagen and elastin synthesis, and its down-regulation can influence a decrease in dermal repair in melasma skin.34

Superoxide dismutase (SOD) is part of the enzymatic antioxidant system and is the main enzyme responsible for scavenging oxygen free radicals through the conversion of superoxide anions into hydrogen peroxide and oxygen.35 SOD is a complex of intracellular enzymes, and the serum level of SOD is higher in patients with melasma when compared to controls, which indicates an increase in the systemic oxidative status and reinforces the use of antioxidants in the treatment of melasma.36 SOD2 is a tetrameric mitochondrial enzyme that contains manganese and is targeted to the mitochondrial intermembrane space. The increase in SOD2 identified in fibroblasts is induced by an oxidative stress environment and may be the result of multiple inflammatory cytokines; moreover, it is a characteristic phenotype in senescent fibroblasts.35,37

The fibroblast is the skin cell that contains the most PTGS. This enzyme participates in the synthesis of prostaglandin E2 (PGE2) from arachidonic acid, and PGE2 inhibits collagen production by fibroblasts in vitro.38 PTGS induction is significant in senescent cells, which increases the release of PGE2, leading to a reduction in type I collagen synthesis, vasodilation, and chemotaxis.38 In addition, PGE2 can directly induce melanogenesis and increase dendrites in melanocytes after UV irradiation.39,40 The pro-inflammatory phenotype of fibroblasts in melasma can induce damage to the upper dermis and sustained melanogenesis.

This study has limitations related to the small sample size and the lack of proteomic or functional assays to confirm the findings. However, the results were consistent and allowed the authors to explore, in a preliminary way, the hypothesis about the role of fibroblasts in the pathogenesis of melasma, proposing new investigations related to the pathogenesis and therapeutic strategies of melasma. The sample of patients submitted to the senescence and proliferation assay was different from the one submitted to the gene expression comparison, although the results were parallel. Finally, the investigation of fibroblasts from controls without melasma, matched by age, photoexposure pattern, photoaging, and phototype, could also elucidate the particular susceptibility of fibroblasts from individuals with melasma to senescence.

Further studies should investigate the regulatory factors of these pathways and the cytokine network between keratinocytes, melanocytes, nerves, endothelium, and fibroblasts in melasma, preferably through studies with tissue cultures, for genomic, proteomic, and functional experiments.

Conclusions

Fibroblasts from the skin with melasma showed a lower growth rate, less fusiform morphology, and greater accumulation of SA-β-gal than those from adjacent healthy photoexposed skin. Furthermore, their gene expression profile comprised pro-inflammatory, pro-melanogenic, and tissue repair deficit-related factors, which can induce damage to the upper dermis and support the focal pigmentary phenotype in melasma.

Financial support

FAPESP – number 2012/09233-5, 2012/05004-1; CNPq – number 401309/2016-9.

Authors' contributions

Ana Cláudia Cavalcante Espósito: Design and planning of the study; collection, analysis, and interpretation of data; drafting and editing of the manuscript; Critical review of the literature; Approval of the final version of the manuscript.

Gabrielli Brianezi: Design and planning of the study; collection, analysis, and interpretation of data; approval of the final version of the manuscript.

Luciane Donida Bartoli Miot: Design and planning of the study; collection, analysis, and interpretation of data; effective participation in research orientation; approval of the final version of the manuscript.

Hélio Amante Miot: Design and planning of the study; collection, analysis, and interpretation of data; statistical analysis; drafting and editing of the manuscript; critical review of the literature; critical review of the manuscript; approval of the final version of the manuscript.

Conflicts of interest

None declared.

References
[1]
A.C.C. Espósito, G. Brianezi, N.P. Souza, L.D.B. Miot, H.A. Miot.
Exploratory Study of Epidermis, Basement Membrane Zone, Upper Dermis Alterations and Wnt Pathway Activation in Melasma Compared to Adjacent and Retroauricular Skin.
Ann Dermatol., 32 (2020), pp. 101-108
[2]
A.C.C. Esposito, G. Brianezi, N.P. De Souza, D.C. Santos, L.D.B. Miot, H.A. Miot.
Ultrastructural characterization of damage in the basement membrane of facial melasma.
Arch Dermatol Res., 312 (2019), pp. 223-227
[3]
J.W. Byun, I.S. Park, G.S. Choi, J. Shin.
Role of fibroblast-derived factors in the pathogenesis of melasma.
Clin Exp Dermatol., 41 (2016), pp. 601-609
[4]
A.C.C. Esposito, G. Brianezi, N.P. Souza, L.D.B. Miot, H.A. Miot.
Exploring pathways for sustained melanogenesis in facial melasma: an immunofluorescence study.
Int J Cosmet Sci., 40 (2018), pp. 420-424
[5]
J. Shin, J.H. Kim, E.K. Kim.
Repeated exposure of human fibroblasts to UVR induces secretion of stem cell factor and senescence.
J Eur Acad Dermatol Venereol., 26 (2012), pp. 1577-1580
[6]
T. Passeron.
Melasma pathogenesis and influencing factors - an overview of the latest research.
J Eur Acad Dermatol Venereol., 27 (2013), pp. 5-6
[7]
A.Y. Lee.
Recent progress in melasma pathogenesis.
Pigment Cell Melanoma Res., 28 (2015), pp. 648-660
[8]
D.J. Lee, J. Lee, J. Ha, K.-C. Park, J.-P. Ortonne, H.Y. Kang.
Defective barrier function in melasma skin.
J Eur Acad Dermatol Venereol., 26 (2012), pp. 1533-1537
[9]
M. Kim, S.M. Kim, S. Kwon, T.J. Park, H.Y. Kang.
Senescent fibroblasts in melasma pathophysiology.
Exp Dermatol., 28 (2019), pp. 719-722
[10]
B. Bellei, M. Picardo.
Premature cell senescence in human skin: Dual face in chronic acquired pigmentary disorders.
Ageing Res Rev., 57 (2020),
[11]
H.Y. Kang, J.S. Hwang, J.Y. Lee, J.H. Ahn, J.-Y. Kim, E.-S. Lee, et al.
The dermal stem cell factor and c-kit are overexpressed in melasma.
Br J Dermatol., 154 (2006), pp. 1094-1099
[12]
K.J. Livak, T.D. Schmittgen.
Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method.
Methods., 25 (2001), pp. 402-408
[13]
G.E. Costin, V.J. Hearing.
Human skin pigmentation: melanocytes modulate skin color in response to stress.
FASEB J., 21 (2007), pp. 976-994
[14]
T. Passeron, M. Picardo.
Melasma, a photoaging disorder.
Pigment Cell Melanoma Res., 31 (2018), pp. 461-465
[15]
F. Gruber, C. Kremslehner, L. Eckhart, E. Tschachler.
Cell aging and cellular senescence in skin aging - Recent advances in fibroblast and keratinocyte biology.
Exp Gerontol., 130 (2020),
[16]
J.E. Yoon, Y. Kim, S. Kwon, M. Kim, Y.H. Kim, J.-H. Kim, et al.
Senescent fibroblasts drive ageing pigmentation: A potential therapeutic target for senile lentigo.
Theranostics., 8 (2018), pp. 4620-4632
[17]
E.A. Chang, M.L. Tomov, S.T. Suhr, J. Luo, Z.T. Olmsted, J.L. Paluh, et al.
Derivation of Ethnically Diverse Human Induced Pluripotent Stem Cell Lines.
Sci Rep., 5 (2015), pp. 15234
[18]
E. Gronniger, B. Weber, O. Heil, N. Peters, F. Stäb, H. Wenck, et al.
Aging and chronic sun exposure cause distinct epigenetic changes in human skin.
PLoS Genet., 6 (2010),
[19]
A.A. Tamega, H.A. Miot, N.P. Moco, M.G. Silva, M.E.A. Marques, L.D.B. Miot.
Gene and protein expression of oestrogen-beta and progesterone receptors in facial melasma and adjacent healthy skin in women.
Int J Cosmet Sci., 37 (2015), pp. 222-228
[20]
L. Campbell, E. Emmerson, F. Davies, S.C. Giliver, A. Krust, P. Chambon, et al.
Estrogen promotes cutaneous wound healing via estrogen receptor beta independent of its antiinflammatory activities.
J Exp Med., 207 (2010), pp. 1825-1833
[21]
K.S. Souza, T.A. Cantaruti, G.M. Azevedo Jr., D.A.A. Galdino, C.M. Rodrigues, R.A. Costa, et al.
Improved cutaneous wound healing after intraperitoneal injection of alpha-melanocyte-stimulating hormone.
Exp Dermatol., 24 (2015), pp. 198-203
[22]
S. Werner, R. Grose.
Regulation of wound healing by growth factors and cytokines.
Physiol Rev., 83 (2003), pp. 835-870
[23]
H. Guo, K. Yang, F. Deng, Y. Xing, Y. Li, X. Lian, et al.
Wnt3a inhibits proliferation but promotes melanogenesis of melan-a cells.
Int J Mol Med., 30 (2012), pp. 636-642
[24]
T.J. Park, M. Kim, H. Kim, S.Y. Park, K.-C. Park, J.-P. Ortonne, et al.
Wnt inhibitory factor (WIF)-1 promotes melanogenesis in normal human melanocytes.
Pigment Cell Melanoma Res., 27 (2014), pp. 72-81
[25]
N. Bondurand, S. Dufour, V. Pingault.
News from the endothelin-3/EDNRB signaling pathway: Role during enteric nervous system development and involvement in neural crest-associated disorders.
Dev Biol., 444 (2018), pp. S156-S169
[26]
S. Terazawa, G. Imokawa.
Signaling Cascades Activated by UVB in Human Melanocytes Lead to the Increased Expression of Melanocyte Receptors, Endothelin B Receptor and c-KIT.
Photochem Photobiol., 94 (2018), pp. 421-431
[27]
A.J. Peacock, K.E. Dawes, A. Shock, A.J. Gray, J.T. Reeves, G.J. Laurent.
Endothelin-1 and endothelin-3 induce chemotaxis and replication of pulmonary artery fibroblasts.
Am J Respir Cell Mol Biol., 7 (1992), pp. 492-499
[28]
R. Wallis, H. Mizen, C.L. Bishop.
The bright and dark side of extracellular vesicles in the senescence-associated secretory phenotype.
Mech Ageing Dev., 189 (2020),
[29]
E. Bastonini, D. Kovacs, M. Picardo.
Skin Pigmentation and Pigmentary Disorders: Focus on Epidermal/Dermal Cross-Talk.
Ann Dermatol., 28 (2016), pp. 279-289
[30]
B. Russo, N.C. Brembilla, C. Chizzolini.
Interplay Between Keratinocytes and Fibroblasts: A Systematic Review Providing a New Angle for Understanding Skin Fibrotic Disorders.
Front Immunol., 11 (2020), pp. 648
[31]
S. Ohgo, S. Hasegawa, Y. Hasebe, H. Mizutani, S. Nakata, H. Akamatsu.
Senescent dermal fibroblasts enhance stem cell migration through CCL2/CCR2 axis.
Exp Dermatol., 24 (2015), pp. 552-554
[32]
I. Tam, A. Dzierzega-Lecznar, K. Stepien.
Differential expression of inflammatory cytokines and chemokines in lipopolysaccharide-stimulated melanocytes from lightly and darkly pigmented skin.
Exp Dermatol., 28 (2019), pp. 551-560
[33]
M. Yulis, D.H.M. Kusters, A. Nusrat.
Cadherins: cellular adhesive molecules serving as signalling mediators.
J Physiol., 96 (2018), pp. 3883-3898
[34]
S. Row, Y. Liu, S. Alimperti, S.K. Agalwal, S.T. Andreadis.
Cadherin-11 is a novel regulator of extracellular matrix synthesis and tissue mechanics.
J Cell Sci., 129 (2016), pp. 2950-2961
[35]
I.N. Zelko, T.J. Mariani, R.J. Folz.
Superoxide dismutase multigene family: a comparison of the CuZn-SOD (SOD1), Mn-SOD (SOD2), and EC-SOD (SOD3) gene structures, evolution, and expression.
Free Radic Biol Med., 33 (2002), pp. 337-349
[36]
V. Choubey, R. Sarkar, V. Garg, S. Kaushik, S. Ghunawat, S. Sonthalia.
Role of oxidative stress in melasma: a prospective study on serum and blood markers of oxidative stress in melasma patients.
Int J Dermatol., 6 (2017), pp. 939-943
[37]
N. Treiber, P. Maity, K. Singh, F. Ferchiu, M. Wlaschek, K. Scharffetter-Kochanek.
The role of manganese superoxide dismutase in skin aging.
Dermatoendocrinol., 4 (2012), pp. 232-235
[38]
Y. Li, D. Lei, W.R. Swindell, W. Xia, S. Weng, J. Fu, et al.
Age-Associated Increase in Skin Fibroblast-Derived Prostaglandin E2 Contributes to Reduced Collagen Levels in Elderly Human Skin.
J Invest Dermatol., 135 (2015), pp. 2181-2188
[39]
C. Fu, J. Chen, J. Lu, L. Yi, X. Tong, L. Kang, et al.
Roles of inflammation factors in melanogenesis (Review).
Mol Med Rep., 21 (2020), pp. 1421-1430
[40]
R.J. Starner, L. Mcclelland, Z. Abdel-Malek, A. Fricke, G. Scott.
PGE(2) is a UVR-inducible autocrine factor for human melanocytes that stimulates tyrosinase activation.
Exp Dermatol., 19 (2010), pp. 682-684

Study conducted at the Department of Dermatology and Radiotherapy, Faculty of Medicine, Universidade Estadual Paulista, Botucatu, SP, Brazil.

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