Efficacy of an agonist of α-MSH, the palmitoyl tetrapeptide-20, in hair pigmentation.

OBJECTIVE: Hair greying (i.e., canities) is a component of chronological ageing and occurs regardless of gender or ethnicity. Canities is directly linked to the loss of melanin and increase in oxidative stress in the hair follicle and shaft. To promote hair pigmentation and reduce the hair greying process, an agonist of α-melanocyte-stimulating hormone (α-MSH), a biomimetic peptide (palmitoyl tetrapeptide-20; PTP20) was developed. The aim of this study was to describe the effects of the designed peptide on hair greying. METHODS: Effect of the PTP20 on the enzymatic activity of catalase and the production of H2 O2 by Human Follicle Dermal Papilla Cells (HFDPC) was evaluated. Influence of PTP20 on the expression of melanocortin receptor-1 (MC1-R) and the production of melanin were investigated. Enzymatic activity of sirtuin 1 (SIRT1) after treatment with PTP20 was also determined. Ex vivo studies using human micro-dissected hairs allowed to visualize the effect of PTP20 on the expression in hair follicle of catalase, TRP-1, TRP-2, Melan-A, ASIP, and MC1-R. These investigations were completed by a clinical study on 15 human male volunteers suffering from premature canities. RESULTS: The in vitro and ex vivo studies revealed the capacity of the examined PTP20 peptide to enhance the expression of catalase and to decrease (30%) the intracellular level of H2 O2 . Moreover, PTP20 was shown to activate in vitro and ex vivo the melanogenesis process. In fact, an increase in the production of melanin was shown to be correlated with elevated expression of MC1-R, TRP-1, and Melan-A, and with the reduction in ASIP expression. A modulation on TRP-2 was also observed. The pivotal role of MC1-R was confirmed on protein expression analysed on volunteer's plucked hairs after 3 months of the daily application of lotion containing 10 ppm of PTP20 peptide. CONCLUSION: The current findings demonstrate the ability of the biomimetic PTP20 peptide to preserve the function of follicular melanocytes. The present results suggest potential cosmetic application of this newly designed agonist of α-MSH to promote hair pigmentation and thus, reduce the hair greying process.

Study of gene expression alteration in male androgenetic alopecia: evidence of predominant molecular signalling pathways.

BACKGROUND: Male androgenetic alopecia (AGA) is the most common form of hair loss in men. It is characterized by a distinct pattern of progressive hair loss starting from the frontal area and the vertex of the scalp. Although several genetic risk loci have been identified, relevant genes for AGA remain to be defined. OBJECTIVES: To identify biomarkers associated with AGA. METHODS: Molecular biomarkers associated with premature AGA were identified through gene expression analysis using cDNA generated from scalp vertex biopsies of hairless or bald men with premature AGA, and healthy volunteers. RESULTS: This monocentric study reveals that genes encoding mast cell granule enzymes, inflammatory mediators and immunoglobulin-associated immune mediators were significantly overexpressed in AGA. In contrast, underexpressed genes appear to be associated with the Wnt/ß-catenin and bone morphogenic protein/transforming growth factor-ß signalling pathways. Although involvement of these pathways in hair follicle regeneration is well described, functional interpretation of the transcriptomic data highlights different events that account for their inhibition. In particular, one of these events depends on the dysregulated expression of proopiomelanocortin, as confirmed by polymerase chain reaction and immunohistochemistry. In addition, lower expression of CYP27B1 in patients with AGA supports the notion that changes in vitamin D metabolism contributes to hair loss. CONCLUSIONS: This study provides compelling evidence for distinct molecular events contributing to alopecia that may pave the way for new therapeutic approaches.

Skin delivery of hydrophilic molecules from liposomes and polysaccharide-coated liposomes.

OBJECTIVES: Liposomes are commonly used in cosmetic formulations to increase the bioavailability of active ingredients. We have previously shown that polysaccharide coating of liposomes improves their resistance to surfactants and electrolytes. In the current study, we have assessed the impact of coating on the skin penetration enhancer properties of liposomes. METHODS: The physicochemical properties of coated liposomes (Ionosomes™) were evaluated before and after encapsulation of two different hydrophilic molecules (caffeine and a hexapeptide), and compared to those observed with non-coated liposomes. Moreover, in vitro permeation experiments were performed using Franz™-modified diffusion cells, with normal human skin as membranes. RESULTS: Results showed that both coated and non-coated liposomes significantly improved the bioavailability of hydrophilic active molecules in skin, compared to reference solutions. Although liposome coating slightly reduced entrapment efficiency, the delivery of active molecules was not adversely affected by the process. In conclusion, polysaccharide coating of liposomes allows for better protection of their integrity without compromising the skin bioavailability of the active molecules that they convoy.

Lipopeptide presentation pathway in dendritic cells.

Lipopeptides are currently being evaluated as candidate vaccines in human volunteers. They elicit cytotoxic responses from CD8(+) T lymphocytes, whereas peptides without a lipidic moiety usually do not. The exact processing and presentation pathways leading to association with MHC class I molecules has not yet been defined. This is of particular interest in dendritic cells, which are required for primary T cell stimulation. We have tracked lipopeptides derived from an HLA-A2.1-restricted HIV-1 Reverse Transcriptase epitope, by N-terminal addition of an N-epsilon-palmitoyl-lysine. Entry of the lipopeptides into human monocyte-derived dendritic cells (MDC) was mediated by endocytosis, as assessed by colocalization using analogs labelled with rhodamine, and by confocal microscopy. This internalization in DC induced functional stimulation of CD8(+) T lymphocytes specific for the epitopes, quantified by Interferon-gamma ELISPOT assays. The peptide alone was not visualized inside the DC and was only presented through direct surface association to HLA-A*0201. Therefore, lipopeptides provide a model system to define precisely the cross-presentation pathways that lead exogenous proteins to associate with class I MHC molecules within dendritic cells. Using this approach, cross-presentation pathways can be better defined and vaccine lipopeptides can be further optimized for MHC class I association in human dendritic cells.

A role for MAP kinase in regulating ectodomain shedding of APLP2 in corneal epithelial cells.

We previously reported an increased secretion of amyloid precursor-like protein 2 (APLP2) in the healing corneal epithelium. The present study sought to investigate signal transduction pathways involved in APLP2 shedding in vitro. APLP2 was constitutively shed and released into culture medium in SV40-immortalized human corneal epithelial cells as assessed by Western blotting, flow cytometry, and indirect immunofluorescence. Activation of protein kinase C (PKC) by phorbol 12-myristate 13-acetate (PMA) caused significant increases in APLP2 shedding. This was inhibited by staurosporine and a PKC-epsilon-specific, N-myristoylated peptide inhibitor. Epidermal growth factor (EGF) also induced APLP2 accumulation in culture medium. Basal APLP2 shedding as well as that induced by PMA and EGF was blocked by a mitogen-activated protein kinase (MAPK) kinase inhibitor, U-0126. Our results suggest that MAPK activity accounts for basal as well as PKC- and EGF-induced APLP2 shedding. In addition, PKC-epsilon may be involved in the induction of APLP2 shedding in corneal epithelial cells.

Synthesis by chemoselective ligation and biological evaluation of novel cell-permeable PKC-zeta pseudosubstrate lipopeptides.

The ability of lipopeptides to passively cross the cell membrane opens new opportunities for the intracellular delivery of bioactive peptides. However, the production of large series of cell-permeable lipopeptides is not trivial due to their generally low solubility. We have evaluated the possibility of associating the fatty acid to the functional cargo using generally applicable ligation chemistries. To this end, we have designed an amphiphilic shuttle in which arginine residues served to solubilize the lipid part in aqueous media, during both the assembly of the lipopeptide and the cellular assays. Our model peptide, the pseudosubstrate sequence of protein kinase C-zeta (PKC-zeta), was associated to the pentapeptide Gly-Arg-Gly-Arg-Lys(Pam)-NH2 through thiazolidine, thioether, disulfide, or hydrazone linkages. The cytoplasm import of the resulting constructs was monitored through the quantification of the apoptosis specifically induced by PKC-zeta inhibition. Our observations suggested the interest of this noninvasive cellular import method to modulate the activity of an intracytoplasmic pharmacological target and showed the influence of a non-amide link created between the functional peptide and the lipidic vector: optimal results, in terms of both specific activity and low basal cytotoxicity, were obtained with the thiazolidine ligation product.

Novel hyperbranched glycomimetics recognized by the human mannose receptor: quinic or shikimic acid derivatives as mannose bioisosteres.

The mannose receptor mediates the internalization of a wide range of molecules or microorganisms in a pattern recognition manner. Therefore, it represents an attractive entry for specific drug, gene, or antigen delivery to macrophages and dendritic cells. In an attempt to design novel effective synthetic mannose receptor ligands, quinic and shikimic acid were selected as putative mannose mimics on the basis of X-ray crystallographic data from the related rat mannose-binding lectin. As the mannose receptor preferentially binds to molecules displaying several sugar residues, fluorescein-labeled cluster quinic and shikimic acid derivatives with valencies of two to eight were synthesized. Their mannose receptor mediated uptake was assayed on monocyte-derived human dendritic cells by cytofluorimetric analysis. Mannose-receptor specificity was further assessed by competitive inhibition assays with mannan, by confocal microscopy analysis, and by expression of the mannose receptor in transfected Cos-1 cells. Constructs derived from both quinic and shikimic acid were efficiently recognized by the mannose receptor with an optimum affinity for the molecules with a valency of four. As a result, commercially available quinic and shikimic acids appear as stable mannose bioisosteres, which should prove valuable tools for specific cell delivery.

Endocytosis of an HIV-derived lipopeptide into human dendritic cells followed by class I-restricted CD8(+) T lymphocyte activation.

CD8(+) T lymphocytes, which are major immune effectors, require primary stimulation by dendritic cells (DC) presenting MHC class I molecule-bound epitopes. Sensitization to exogenous protein epitopes that are not synthesized in DC, such as cross-priming, is obtained through pathways leading to their association with MHC class I. To follow class I-restricted pathways in human DC, we have tracked a lipopeptide derived from the conserved HLA-A*0201-restricted HIV-1 reverse transcriptase 476-484 epitope, by N-terminal addition of an Nepsilon-palmytoyl-lysine. Indeed, lipopeptides elicit cytotoxic responses from CD8(+) T lymphocytes, whereas peptides without a lipid moiety do not. The lipopeptide and its parent peptide were labeled unequivocally by rhodamine to study their entry into immature monocyte-derived human DC by confocal microscopy. The lipid moiety induced endocytosis of the lipopeptide, assessed by rapid entry into vesicles, colocalization with Dextran-FITC and dependence on energy. Internalization occurred even when actin filaments were depolymerized by Cytochalasin B. This internalization induced functional stimulation of specific CD8(+) T lymphocytes in IFN-gamma ELISPOT assays. The peptide alone was not visualized inside the DC and was presented through direct surface association to HLA-A*0201. Therefore, lipopeptides are a unique opportunity to define precisely the pathways that lead exogenous proteins to associate with MHC class I molecules in DC. The results will also be useful to design lipopeptide vaccines.

Structural diversity of human class II histocompatibility molecules induced by peptide ligands.

SDS-PAGE analyses of stable HLA-DR1 complexes indicate that the binding of T cell epitopes can lead to multiple conformational variants. Whereas short T epitopes (<14-mer) induce complexes with apparent MW ranging from 47 to 57 kDa, longer peptides form generally high mobility complexes (44-45 kDa). The generation of HLA-DR1 conformational variants appears dependent on core peptide residues fitting inside the groove but can additionally be attributed to the presence of N- and C-terminal flanking residues (PFRs) acting as a complementary mechanism. These PFRs can jointly affect major histocompatibility complex class II conformation and stability, supporting the existence of alternative contacts at a distance from the classical binding site.

Extension of HLA-A*0201-restricted minimal epitope by N epsilon-palmitoyl-lysine increases the life span of functional presentation to cytotoxic T cells.

The delineation of the minimal requirements for efficient delivery of functional cytotoxic epitopes into APC could be a step toward the definition of "minimal length" lipopeptides for the modulation of CTL activity. Several analogues of the HLA-A*0201-restricted HIV-1 polymerase (pol476-484) minimal cytotoxic epitope were obtained by modifying P0, P1, or P10 positions by a single N epsilon-palmitoyl-lysine residue. The use of fluorescent derivatives confirmed the cell-permeating activities and suggested that a P0- and a P1-modified lipopeptide possessing ionizable extremities fulfills the structural requirements for MHC loading. The expressions of HLA-peptide complexes at the surface of TAP-deficient cells incubated with the parent epitope or lipopeptide derivatives were compared, in terms of intensity and stability. Both lipopeptides induced a considerably prolonged expression of conformationally correct complexes, which were dependent on the integrity of the exocytosis pathway, suggesting a dynamic mechanism of formation or reloading of the complexes from an intracellular pool. The agonistic activities of the different HLA-peptide complexes were evaluated using two independent T cell lines from HIV-infected donors. We report that a lipodecapeptide obtained by N-terminal addition of a N epsilon-palmitoyl-lysine to the pol476-484 epitope was able to increase the life span of functional presentation to cytotoxic T cells specific for the parent peptide.

Direct evidence of cytoplasmic delivery of PKC-alpha, -epsilon and -zeta pseudosubstrate lipopeptides: study of their implication in the induction of apoptosis.

Protein kinases C (PKC) are serine/threonine kinase enzymes involved in the mechanism of cell survival. Their pseudosubstrate sequences are autoinhibitory domains, which maintain the enzyme in an inactive state in the absence of allosteric activators, thus representing an attractive tool for the modulation of different PKC isoforms. Here, we report the use of palmitoylated modified PKC-alpha, -epsilon, and -zeta pseudosubstrate peptides, and determine their intracellular distribution together with their respective PKC isoenzymes. Finally, we propose that the differential distribution of the peptides is correlated with a selective induction of apoptosis and therefore argues for different involvement of PKC isoforms in the anti-apoptotic program.

IFN-gamma-derived lipopeptides: influence of lipid modification on the conformation and the ability to induce MHC class II expression on murine and human cells.

Two truncated analogues of a previously identified lipopeptide agonist toward the IFN-gamma receptor were synthesized in an attempt to determine the minimal compound able to induce expression of MHC class II molecules on murine and human cells and to study the role of the lipid tail. Circular dichroism studies were used to probe the induced conformationnal changes. Our results indicate at least a double role for the lipid modification that contributes to the stabilization of helical organization of the associated peptide and to its passive delivery into the cytoplasm. The persistence of biological activity in a truncated peptide of half of the residues present in the lead compound suggests that the lipid tail could also contribute to the stabilization of the peptide-receptor binding through additional hydrophobic interactions. This study allowed to readjust the minimal requirements for intracellular IFN-gamma receptor stimulation. More generally, we suggest that lipidated analogues of functional peptides could be utilized for intracellular target validation in the drug discovery process.

Unrestricted agonist activity on murine and human cells of a lipopeptide derived from IFN-gamma.

We describe the isolation of a synthetic agonist of IFN-gamma (L-mIFN-gamma-CT) active on mouse and human cells. Its biological activity is the result of the ability of the C-terminal extremity of murine IFN-gamma to interact with the intracellular part of IFNgamma-R and the observation that the modification of peptides by a palmitic acid enables their cytoplasmic delivery. L-mIFN-gamma-CT stimulated murine cells exhibited an increase in MHC class II molecules and FcgammaRII/III expression and conferred protection against viral lysis. Unresponsiveness to L-mIFN-gamma-CT of cells recovered from IFNgamma-R alpha-chain knockout mice indicated the involvement of IFNgamma-R in the biological activities observed. Induction of VCAM-1, ICAM-1, and HLA-DR expression on human cells stimulated with L-mIFN-gamma-CT demonstrated an abrogation of species specificity. These results describe the development of a new synthetic agonist of IFN-gamma, which substitutes for the native cytokine in any IFN-gamma responsive cells, by acting intracellularly on IFN-gammaR.

Assessing delivery of lipopeptides into the cytoplasm of intact cells by a functional assay based on PKC inhibition. I. The Jurkat model.

We have developed a functional assay to verify the delivery into the cytoplasm of a 14-amino acid hydrophilic peptide, modified by the incorporation of a palmitoyl-lysine residue into the N- or C-terminal end. This assay is based on the use of a pseudo-substrate sequence for the protein kinase C (PKC) isoenzymes of alpha and beta for the quantification of PKC-mediated tumor necrosis factor (TNF) secretion after T-cell activation by phorbol ester and anti-CD3 MAb. This cellular assay is simple, and it allows for a rapid and comparative study of several peptides. The lipidic analogues of the pseudo-substrate peptide were able to inhibit TNF secretion in intact-activated Jurkat cells, with an EC50 in the 40-60 microM range, whereas the unmodified peptide was not active. Two control lipopeptides were also inactive, demonstrating that the palmitoyl-lysine group had no effect by itself. This study confirms that the modification of a relatively long peptide by the insertion of a palmitoyl-lysine into the N- or C-terminal end is sufficient to allow entry into intact cells.