Dermal stiffness governs the topography of the epidermis and the underlying basement membrane in young and old human skin.

The epidermis is a stratified epithelium that forms the outer layer of the skin. It is composed primarily of keratinocytes and is constantly renewed by the proliferation of stem cells and their progeny that undergo terminal differentiation as they leave the basal layer and migrate to the skin surface. Basal keratinocytes rest on a basement membrane composed of an extracellular matrix that controls their fate via integrin-mediated focal adhesions and hemidesmosomes which are critical elements of the epidermal barrier and promote its regenerative capabilities. The distribution of basal cells with optimal activity provides the basement membrane with its characteristic undulating shape; this configuration disappears with age, leading to epidermal weakness. In this study, we present an in-depth imaging analysis of basal keratinocyte anchorage in samples of human skin from participants across the age spectrum. Our findings reveal that skin aging is associated with the depletion of hemidesmosomes that provide crucial support for stem cell maintenance; their depletion correlates with the loss of the characteristic basement membrane structure. Atomic force microscopy studies of skin and in vitro experiments revealed that the increase in tissue stiffness observed with aging triggers mechanical signals that alter the basement membrane structure and reduce the extent of basal keratinocyte anchorage, forcing them to differentiate. Genomic analysis revealed that epidermal aging was associated with mechanical induction of the transcription factor Krüppel-like factor 4. The altered mechanical properties of tissue being a new hallmark of aging, our work opens new avenues for the development of skin rejuvenation strategies.

A novel mechanism in wound healing: Laminin 332 drives MMP9/14 activity by recruiting syndecan-1 and CD44.

Re-epithelialization describes the resurfacing of a skin wound with new epithelium. In response to various stimuli including that of growth factors, cytokines and extracellular matrix (ECM), wound edge epidermal keratinocytes undergo cytoskeleton rearrangements compatible with their motile behavior and develop protrusive adhesion contacts. Matrix metalloproteinases (MMP) expression is crucial for proper cell movement and ECM remodeling; however, their deposition mechanism is unknown in keratinocytes. Here, we show that similar to cytokine IL-1ß, the precursor laminin 332 pro-migratory fragment G45 induces expression of the MMP-9 pro-enzyme, which together with MMP-14, further exerts its proteolytic activity within epithelial podosomes. This event strictly depends on the expression of the proteoglycan receptor syndecan-1 that was found in a ring surrounding the podosome core, co-localised with CD44. Our findings uncover that by directly recruiting both syndecan-1 and CD44, the laminin-332 G45 domain plays a major role in regulating mechanisms underlying keratinocyte / ECM remodeling during wound repair.

Re-epithelialization of adult skin wounds: Cellular mechanisms and therapeutic strategies.

Cutaneous wound healing in adult mammals is a complex multi-step process involving overlapping stages of blood clot formation, inflammation, re-epithelialization, granulation tissue formation, neovascularization, and remodelling. Re-epithelialization describes the resurfacing of a wound with new epithelium. The cellular and molecular processes involved in the initiation, maintenance, and completion of epithelialization are essential for successful wound closure. A variety of modulators are involved, including growth factors, cytokines, matrix metalloproteinases, cellular receptors, and extracellular matrix components. Here, we focus on cellular mechanisms underlying keratinocyte migration and proliferation during epidermal closure. Inability to re-epithelialize is a clear indicator of chronic non-healing wounds, which fail to proceed through the normal phases of wound healing in an orderly and timely manner. This review summarizes the current knowledge regarding the management and treatment of acute and chronic wounds, with a focus on re-epithelialization, offering some insights into novel future therapies.

Perlecan expression influences the keratin 15-positive cell population fate in the epidermis of aging skin.

The epidermis is continuously renewed by stem cell proliferation and differentiation. Basal keratinocytes append the dermal-epidermal junction, a cell surface-associated, extracellular matrix that provides structural support and influences their behaviour. It consists of laminins, type IV collagen, nidogens, and perlecan, which are necessary for tissue organization and structural integrity. Perlecan is a heparan sulfate proteoglycan known to be involved in keratinocyte survival and differentiation. Aging affects the dermal epidermal junction resulting in decreased contact with keratinocytes, thus impacting epidermal renewal and homeostasis. We found that perlecan expression decreased during chronological skin aging. Our in vitro studies revealed reduced perlecan transcript levels in aged keratinocytes. The production of in vitro skin models revealed that aged keratinocytes formed a thin and poorly organized epidermis. Supplementing these models with purified perlecan reversed the phenomenon allowing restoration of a well-differentiated multi-layered epithelium. Perlecan down-regulation in cultured keratinocytes caused depletion of the cell population that expressed keratin 15. This phenomenon depended on the perlecan heparan sulphate moieties, which suggested the involvement of a growth factor. Finally, we found defects in keratin 15 expression in the epidermis of aging skin. This study highlighted a new role for perlecan in maintaining the self-renewal capacity of basal keratinocytes.

LKB1 when associated with methylatedERα is a marker of bad prognosis in breast cancer.

Although the presence of nuclear estrogen receptor is widely used to guide breast cancer therapy, less attention has been paid to the receptor cytoplasmic signaling. Recently, we have shown that this pathway is operative in vivo and is activated in aggressive tumors representing a new potential target for breast cancer therapy. Here, we identified LKB1 as a partner of ERα and we explored its potential role in estrogen nongenomic signaling. The associations between LKB1 expression and the actors of this pathway, namely the methylated form of ERα (metERα), Src and PI3K, have been analyzed both in cultured cells and in 154 primary breast tumor samples. We found that LKB1 is a component of the cytoplasmic signaling complex in breast cell lines as well as in primary breast tumors. Moreover, an inverse correlation between the localization of LKB1 in nuclear and cytoplasmic compartments is observed. Importantly, high expression of cytoplasmic LKB1 is an independent marker of poor prognosis, associated with reduced overall survival (OS) and disease free survival (DFS). Conversely, the presence of nuclear LKB1 associates with increased OS and DFS. In conclusion, our results highlight that LKB1 expression in breast cancer appears to have opposite effects depending on its subcellular localization and may be used as a new prognostic biomarker.

The syndecan binding sequence KKLRIKSKEK in laminin α3 LG4 domain promotes epidermal repair.

Epithelialization of normal wounds occurs by an orderly series of events whereby keratinocytes migrate, proliferate, and differentiate to restore the barrier function. Keratinocyte migration is one of the most earliest and crucial event determining the efficiency of the overall wound repair process. Laminin 332, composed by the association of α3, ß3 and γ2 chains, is a major adhesion substrate for keratinocytes and is known for its role in supporting cell adhesion and migration during wound repair. The α3 chain comprises a large globular region in its carboxyl-terminal end, which consists of five homologous globular domains (LG1-LG5), known to be involved in cellular interactions. Recent findings have suggested that the α3 chain C-terminal domains LG45 may have a role to play during the epithelialization phase in wound repair. In the present study, we have analyzed whether a peptide mimicking the major heparin binding sequence KKLRIKSKEK in α3LG45 may interact with keratinocytes to promote cell adhesion and migration. In vitro experiments supported this hypothesis and revealed that the KKLRIKSKEK peptide induces human primary keratinocyte adhesion and has the ability to promote keratinocyte migration when added in the culture medium. To examine the peptide efficacy in vivo, the KKLRIKSKEK peptide was applied over partial-thickness cutaneous wounds in pigs. Compared with vehicle-treated cutaneous wounds, the peptide application significantly promoted early-stage wound healing by accelerating re-epithelialization. Additional beneficial effects such as reduced inflammatory response and decreased granulation tissue formation were also noticed in the peptide-treated wounds.

Cell surface proteoglycans syndecan-1 and -4 bind overlapping but distinct sites in laminin α3 LG45 protein domain.

Keratinocyte migration during epidermal repair depends on interactions between cellular heparan sulfate proteoglycan receptors, syndecan-1 and -4, and the C-terminal globular domains (LG45) of the extracellular matrix protein laminin 332. This study investigates the molecular basis of the binding specificity of the syndecan-1 and -4 receptors expressed by human keratinocytes. We used site-directed mutagenesis to alter a recombinant LG45 protein by substituting the most critical basic residues with glutamine. All proteins were expressed in mammalian cells, purified, and characterized biochemically. We used in vitro binding assays, including surface plasmon resonance, to examine interactions between mutated LG45 and heparan sulfates, syndecan-1 and -4. We identify a major heparin binding domain on the outer edge of a ß-strand of LG45 surrounded by a track of converging low affinity residues. This domain harbors distinctive syndecan-1 and -4 binding-specific sequences. This is the first study to demonstrate a binding specificity of two proteoglycans produced by a single cell type. In addition, we found that although syndecan-1 interacts exclusively through its glycosaminoglycan chains, syndecan-4 binding relies on both its core protein and its heparan sulfate chains. These results suggest that LG45 may trigger different signals toward keratinocytes depending on its interaction with syndecan-1 or -4.

Raloxifene and ICI182,780 increase estrogen receptor-alpha association with a nuclear compartment via overlapping sets of hydrophobic amino acids in activation function 2 helix 12.

The basis for the differential repressive effects of antiestrogens on transactivation by estrogen receptor-alpha (ERalpha) remains incompletely understood. Here, we show that the full antiestrogen ICI182,780 and, to a lesser extent, the selective ER modulator raloxifene (Ral), induce accumulation of exogenous ERalpha in a poorly soluble fraction in transiently transfected HepG2 or stably transfected MDA-MB231 cells and of endogenous receptor in MCF7 cells. ERalpha remained nuclear in HepG2 cells treated with either compound. Replacement of selected hydrophobic residues of ERalpha ligand-binding domain helix 12 (H12) enhanced receptor solubility in the presence of ICI182,780 or Ral. These mutations also increased transcriptional activity with Ral or ICI182,780 on reporter genes or on the endogenous estrogen target gene TFF1 in a manner requiring the integrity of the N-terminal AF-1 domain. The antiestrogen-specific effects of single mutations suggest that they affect receptor function by mechanisms other than a simple decrease in hydrophobicity of H12, possibly due to relief from local steric hindrance between these residues and the antiestrogen side chains. Fluorescence anisotropy experiments indicated an enhanced regional stabilization of mutant ligand-binding domains in the presence of antiestrogens. H12 mutations also prevent the increase in bioluminescence resonance energy transfer between ERalpha monomers induced by Ral or ICI182,780 and increase intranuclear receptor mobility in correlation with transcriptional activity in the presence of these antiestrogens. Our data indicate that ICI182,780 and Ral locally alter the ERalpha ligand binding structure via specific hydrophobic residues of H12 and decrease its transcriptional activity through tighter association with an insoluble nuclear structure.

Tamoxifen and raloxifene differ in their functional interactions with aspartate 351 of estrogen receptor alpha.

The bulky side chains of antiestrogens hinder folding of the ligand binding domain (LBD) of estrogen receptors (ERs) into a transcriptionally active conformation. The presence of a tertiary amine in the side chain of raloxifene, which interacts with a negatively charged residue in helix H3 of the ER LBD [Asp351 in human (h)ERalpha], is important for antiestrogenicity in animal and cellular models. To better understand the molecular basis of the differential activity of tamoxifen and raloxifene, we have examined the influence of tertiary amine substituents and of mutations at position 351 in hERalpha on the activity profiles of tamoxifen derivatives. Results obtained in several cellular model systems suggest that the degree of antagonist activity of tamoxifen derivatives does not strictly correlate with the basicity of the side chain but depends on an optimal spatial relationship between the tertiary amine of these antiestrogens and the negative charge at position 351. Although altering the position of the negative charge at residue 351 (mutation D351E) had little effect on transcriptional activity in the presence of tamoxifen, it drastically increased the partial agonist activity of a tamoxifen derivative with improved antagonist activity as well as that of raloxifene. Our results suggest that contrary to raloxifene, tamoxifen and most of its derivatives do not interact with Asp351 in an optimal manner, although this can be improved by modifying tertiary amine substituents.

Gene therapy of the typical multidrug resistance phenotype of cancers: a new hope?

The multidrug resistance (MDR) phenotype of cancers has generated a large amount of research, owing to its constant fatal clinical outcome. Many studies have focused on the discovery of chemomodulators; however, in spite of this huge effort, the side effects that these products induce, and their additive toxicity when used in the presence of anticancer drugs, have led to the disaffection of the pharmaceutical industry and possibly slowed down research in pharmacological modulation. New tools developed using molecular biology techniques have opened the way for gene therapy and given birth to new therapeutic hopes. However, these discoveries and especially their clinical applications have slowed due to a lack of knowledge of the systems that finely regulate the MDR genes. This weakness explains why, to date, no general review has focused on the possibilities of gene therapy of MDR derived form the strategic options now available. Based on molecular foundations and recent fundamental discoveries, we seek to inform clinicians of the therapeutic hopes for chemoresistant tumors brought about by potent and specific new tools such as transcriptional decoys, interfering RNAs, etc. After describing the causes and mechanisms of MDR, we critically review these new strategies and their corresponding clinical trials.

Characterization of the typical multidrug resistance profile in human uveal melanoma cell lines and in mouse liver metastasis derivatives.

Uveal melanoma is the most common intraocular malignancy. To study its biology, stable cell lines provide a useful tool, but these are very difficult to obtain. A stable and rapidly growing human choroidal melanoma cell line composed of pure epithelioid cells was established and maintained for at least 4 years. In vivo transplantation into BALB/cByJ nude mice induced vascularized tumours at the injection sites. Interestingly, two of three cases produced a liver metastasis. Other uveal melanoma cell lines displaying different morphological aspects were also obtained. To avoid the bias due to uncertain immunologically based staining approaches, several methods were juxtaposed to establish the multidrug resistance (MDR) profile. All the uveal melanomas studied expressed significant levels of the MDR-related MDR1, MRP1 (MDR-related protein 1) and LRP/MVP (lung resistance protein/major vault protein) messenger RNAs (mRNAs), produced their corresponding proteins and were able to functionally extrude daunomycin. When compared with the established MEWO skin melanoma cell line, our data showed that both primary and metastatic uveal melanomas intrinsically expressed the typical MDR phenotype, which precludes the use of any anticancer drugs known to be substrates of MDR-related proteins to treat the disease. Moreover, it appears that the metastasizing process does not change the status of the MDR phenotype.

Major cytogenetic aberrations and typical multidrug resistance phenotype of uveal melanoma: current views and new therapeutic prospects.

Uveal melanoma is the most frequent intra-ocular cancer. The recent development of new chromosome-related technologies have permitted the elucidation of both the cytogenetics and the natural history of this disease. Fifty to 60% of uveal melanomas are linked to a monosomy 3, which appears as an early and determinant event in tumor progression. Tumors with this anomaly have a very poor prognosis. Recent work suggests that this category of uveal melanoma represents a distinct pathologic entity from that associated with normal disomy 3. Chromosome 6 aberrations probably constitute a second entry point into the process of cancerogenesis, while gains in 8q seem to appear later in the natural history of uveal melanomas due to their higher frequency in larger tumors. Other anomalies will be reviewed. In spite of significant improvements in the local treatment of uveal melanoma, many patients die due to tumor metastasis. This disease is characterized by a constitutive chemoresistance whose typical multidrug resistance phenotype (MDR) is particularly complex since different combinations of several resistance proteins are simultaneously produced. Regulation of the expression of these proteins is a research priority, increasingly so as gene therapy-dependent chemosensitization strategies expand. Therefore, the development and improvement of methods to determine the chemoresistance profile become a crucial objective today in the therapeutic strategies against uveal melanoma.

Control of P-glycoprotein activity by membrane cholesterol amounts and their relation to multidrug resistance in human CEM leukemia cells.

P-glycoprotein (P-gp) is the most well-known ATP-binding cassette (ABC) transporter involved in unidirectional substrate translocation across the membrane lipid bilayer, thereby causing the typical multidrug resistance (MDR) phenotype expressed in many cancers. We observed that in human CEM acute lymphoblastic leukemia cells expressing various degrees of chemoresistance and where P-gp was the sole MDR-related ABC transporter detected, the amount of esterified cholesterol increased linearly with the level of resistance to vinblastine while the amounts of total and free cholesterol increased in a nonlinear way. Membrane cholesterol controlled the ATPase activity of P-gp in a linear manner, whereas the P-gp-induced daunomycin efflux decreased nonlinearly with the depletion of membrane cholesterol. All these elements suggest that cholesterol controls both the ATPase and the drug efflux activities of P-gp. In addition, in CEM cell lines that expressed increasing levels of elevated chemoresistance, the amount of P-gp increases to a plateau value of 40% of the total membrane proteins and remained unvaried while the amount of membrane cholesterol increased with the elevation of the MDR level, strongly suggesting that cholesterol may be directly involved in the typical MDR phenotype. Finally, we showed that the decreased daunomycin efflux by P-gp due to the partial depletion of membrane cholesterol was responsible for the efficient chemosensitization of resistant CEM cells, which could be totally reversed after cholesterol repletion.

Multidrug-resistant cancer cells contain two populations of P-glycoprotein with differently stimulated P-gp ATPase activities: evidence from atomic force microscopy and biochemical analysis.

Considerable interest exists about the localization of P-gp (P-glycoprotein) in DRMs (detergent-resistant membranes) of multidrug resistant cancer cells, in particular concerning the potential modulating role of the closely related lipids and proteins on P-gp activity. Our observation of the opposite effect of verapamil on P-gp ATPase activity from DRM and solubilized-membrane fractions of CEM-resistant leukaemia cells, and results from Langmuir experiments on membrane monolayers from resistant CEM cells, strongly suggest that two functional populations of P-gp exist. The first is located in DRM regions: it displays its optimal P-gp ATPase activity, which is almost completely inhibited by orthovanadate and activated by verapamil. The second is located elsewhere in the membrane; it displays a lower P-gp ATPase activity that is less sensitive to orthovanadate and is inhibited by verapamil. A 40% cholesterol depletion of DRM caused the loss of 52% of the P-gp ATPase activity. Cholesterol repletion allowed recovery of the initial P-gp ATPase activity. In contrast, in the solubilized-membrane-containing fractions, cholesterol depletion and repletion had no effect on the P-gp ATPase activity whereas up to 100% saturation with cholesterol induced a 58% increased P-gp ATPase activity, while no significant modification was observed for the DRM-enriched fraction. DRMs were analysed by atomic force microscopy: 40-60% cholesterol depletion was necessary to remove P-gp from DRMs. In conclusion, P-gp in DRMs appears to contain closely surrounding cholesterol that can stimulate P-gp ATPase activity to its optimal value, whereas cholesterol in the second population seems deprived of this function.

New invMED1 element cis-activates human multidrug-related MDR1 and MVP genes, involving the LRP130 protein.

The MDR1 gene is a key component of the cytotoxic defense network and its overexpression results in the multidrug resistance (MDR) phenotype. However, the molecular mechanisms that regulate the MDR1 gene and coordinate multiple MDR-related genes expression are poorly understood. In a previous study, we identified a new 12 bp cis-activating region in the 5'-flanking region of the human MDR1 gene, which we called inverted MED1. In the present study, we characterized the precise binding element, which we named invMED1, and revealed the presence of the LRP130 protein as the nuclear factor. Its binding intensity increases with the endogenous MDR1 geneexpression and with the MDR level of CEM leukemia cells. Interestingly, the LRP130 level did not vary with the chemoresistance level. We observed the involvement of LRP130 in the transcriptional activity of the MDR1 gene promoter, and moreover, in that of the MDR-related, invMED1-containing, MVP gene promoter. We used siRNAs and transcriptional decoys in two unrelated human cancer cell lines to show the role of the invMED1/LRP130 couple in both MDR1 and MVP endogenous genes activities. We showed that invMED1 was localized in the -105/-100 and -148/-143 regions of the MDR1 and MVP gene promoters, respectively. In addition, since the invMED1 sequence is primarily located in the -160/-100 bp region of mammalian MDR-related genes, our results present the invMED1/LRP130 couple as a potential central regulator of the transcription of these genes.

Growth-stimulatory and transcriptional activation properties of raloxifene in human endometrial Ishikawa cells.

Raloxifene (Ral) has estrogenic activity in bone and cardiovascular tissues, but is antiestrogenic in breast and has limited uterotrophic activity in mice. Here we report that Ral stimulates the growth of human endometrial Ishikawa tumors implanted in the mammary fat pad of nude ovariectomized mice. In cultured Ishikawa cells, Ral has agonist effects on transcription mediated by the progesterone receptor, an endogenous estrogen target gene, and on expression of reporter genes containing estrogen response elements (EREs). Both Ral and tamoxifen (Tam), but not estradiol, stimulated transcription mediated by the activator protein 1 at micromolar concentrations. However, this effect correlated with induction of cellular death at high concentrations of Ral or Tam and was not observed at lower concentrations. Our results suggest that Ral has stimulatory effects in Ishikawa cells on both cellular growth and gene transcription, and that EREs can mediate some of these effects.