Molecular mechanisms of skin aging: state of the art

The process of skin aging in humans is complex and is induced by multiple factors, including genetic and various environmental ones. In particular, the superposition of environmental factors, such as UV irradiation on skin, results in massive wound-like morphological alterations mainly of the dermis. In sun-protected areas the most pronounced changes occur within the epidermis and affect mostly the basal cell layer. As a result, while sun-protected aged skin appears thin, finely wrinkled, and dry, photoaged skin is characterized by deep wrinkles, laxity, and roughness. Although the fundamental mechanisms are still poorly understood, a growing body of evidence points toward the involvement of multiple pathways in the generation of aged skin. Recent data obtained by expression-profiling studies and studies of progeroid syndromes (e.g., Hutchinson-Gilford progeria, Werner syndrome, Rothmund-Thomson syndrome, Cockayne syndrome, ataxia teleangiectasia, and Down syndrome) illustrate that among the most important biological processes involved in skin aging are alterations in DNA repair and stability, mitochondrial function, cell cycle and apoptosis, ubiquitin-induced proteolysis, and cellular metabolism. One of the major factors that has been proposed to play an exquisite role in the initiation of aging is the physiological hormone decline occurring with age. However, hormones at age-specific levels may not only regulate age-associated mechanisms but also regulate tumor-suppressor pathways that influence carcinogenesis. Understanding the molecular mechanisms of aging may open new strategies in dealing with the various diseases accompanying aging, including cancer.

The skin as a mirror of the aging process in the human organism--state of the art and results of the aging research in the German National Genome Research Network 2 (NGFN-2)

As our society is growing older, the consequences of aging have begun to gain particular attention. Improvement of quality of life at old age and prevention of age-associated diseases have become the main focus of the aging research. The process of aging in humans is complex and underlies multiple influences, with the probable involvement of heritable and various environmental factors. In particular, hormones are decisively involved in the generation of aging. Over time, important circulating hormones decline due to a reduced secretion of the pituitary, the adrenal glands and the gonads or due to an intercurrent disease. Among them, serum levels of growth factors and sexual steroids show significant aging-associated changes. Within the scope of the Explorative Project 'Genetic aetiology of human longevity' supported by the German National Genome Research Network 2 (NGFN-2) an in vitro model of human hormonal aging has been developed. Human SZ95 sebocytes were maintained under a hormone-substituted environment consisting of growth factors and sexual steroids in concentrations corresponding to those circulating in 20- and in 60-year-old women. Eight hundred and ninety-nine genes showed a differential expression in SZ95 sebocytes maintained under the 20- and 60-year-old hormone mixture, respectively. Among them genes were regulated which are involved in biological processes which are all hallmarks of aging. The most significantly altered signaling pathway identified was that of the transforming growth factor-beta (TGF-beta). A disturbed function of this cascade has been associated with tumorigenesis, i.e. in pancreatic, prostate, intestine, breast, and uterine cancer. Interestingly, genes expressed in signaling pathways operative in age-associated diseases such as Huntington's disease (HD), dentatorubral-pallidoluysian atrophy (DRPLA), and amyotrophic lateral sclerosis (ALS) were also identified. These data demonstrate that skin and its appendages may represent an adequate model for aging research. Hormones interact in a complex fashion, and aging may be partly attributed to the changes in their circulating blood levels. Furthermore, a disturbed hormone status may partially act towards the manifestation of neurodegenerative diseases. Thus, these results could be a basis for an integrated and interdisciplinary approach to the analysis of the aging process.

Testosterone metabolism to 5alpha-dihydrotestosterone and synthesis of sebaceous lipids is regulated by the peroxisome proliferator-activated receptor ligand linoleic acid in human sebocytes

BACKGROUND

Despite the clinical evidence that androgens stimulate sebaceous lipids, androgens in vitro have shown no similar effects. This contradiction led to the assumption that cofactors may be required for lipid regulation and peroxisome proliferator-activated receptor (PPAR) ligands were suggested to be adequate candidates.

OBJECTIVES

The influence of testosterone and linoleic acid, a PPAR ligand, as single agents and in combination with of LY191704, a 5alpha-reductase type I inhibitor, was examined on 5alpha-dihydrotestosterone (5alpha-DHT) synthesis and lipid content in human SZ95 sebocytes.

METHODS

Cell proliferation and viability were measured by the 4-methylumbelliferyl heptanoate fluorescence assay and by the Boehringer Lactate Dehydrogenase Assay kit, respectively. 5alpha-DHT enzyme-linked immunosorbent assay was used for the detection of 5alpha-DHT synthesis in cell supernatants after treatment, whereas lipid production was documented by means of the Nile red lipid microassay and fluorescence microscopy.

RESULTS

Testosterone promoted 5alpha-DHT synthesis (P < 0.001), whereas linoleic acid increased sebaceous lipids (P < 0.001). The combination of testosterone and linoleic acid exhibited a synergistic effect on the synthesis of 5alpha-DHT (P < 0.01 vs. testosterone) and sebaceous lipids (P < 0.01 vs. linoleic acid). Furthermore, LY191704 reduced 5alpha-DHT and sebaceous lipid levels (P < 0.01 and P < 0.001 in comparison with testosterone/linoleic acid, respectively). Cell proliferation and viability remained unchanged under treatment with all compounds tested.

CONCLUSIONS

These data suggest a catalytic effect of PPAR ligands on cellular testosterone activation by 5alpha-reduction and the importance of the latter for the regulation of sebaceous lipids.

William J. Cunliffe Scientific Awards. Characteristics and pathomechanisms of endogenously aged skin

The skin, being in direct contact with several environmental factors (e.g. UV irradiation), does not only undergo endogenous aging, which has to do with the 'biological clock' of the skin cells per se, but also exogenous aging. While exogenous skin aging has been extensively studied, the pathomechanisms of endogenous skin aging remain far less clear. Endogenous skin aging reflects reduction processes, which are common in internal organs. These processes include cellular senescence and decreased proliferative capacity, decrease in cellular DNA repair capacity and chromosomal abnormalities, loss of telomeres, point mutations of extranuclear mtDNA, oxidative stress and gene mutations. As a consequence, aged skin in nonexposed areas shows typical characteristics including fine wrinkles, dryness, sallowness and loss of elasticity. Recent data have illustrated that lack of hormones occurring with age may also contribute to the aging phenotype. Improvement of epidermal skin moisture, elasticity and skin thickness, enhanced production of surface lipids, reduction of wrinkle depth, restoration of collagen fibers and increase of the collagen III/I ratio have been reported after hormone replacement therapy or local estrogen treatment in postmenopausal women. Furthermore, an in vitro model of endogenous skin aging consisting of human SZ95 sebocytes which were incubated under a hormone-substituted environment illustrated that hormones at age- and sex-specific levels were able to alter the development of cells by regulating their transcriptome. In conclusion, among other factors the hormone environment plays a distinct role in the generation of aged skin.

Age-specific hormonal decline is accompanied by transcriptional changes in human sebocytes in vitro

The importance of hormones in endogenous aging has been displayed by recent studies performed on animal models and humans. To decipher the molecular mechanisms involved in aging we maintained human sebocytes at defined hormone-substituted conditions that corresponded to average serum levels of females from 20 (f20) to 60 (f60) years of age. The corresponding hormone receptor expression was demonstrated by reverse transcription-polymerase chain reaction (RT-PCR), Western blotting and immunocytochemistry. Cells at f60 produced significantly lower lipids than at f20. Increased mRNA and protein levels of c-Myc and increased protein levels of FN1, which have been associated with aging, were detected in SZ95 sebocytes at f60 compared to those detected at f20 after 5 days of treatment. Expression profiling employing a cDNA microarray composed of 15 529 cDNAs identified 899 genes with altered expression levels at f20 vs. f60. Confirmation of gene regulation was performed by real-time RT-PCR. The functional annotation of these genes according to the Gene Ontology identified pathways related to mitochondrial function, oxidative stress, ubiquitin-mediated proteolysis, cell cycle, immune responses, steroid biosynthesis and phospholipid degradation - all hallmarks of aging. Twenty-five genes in common with those identified in aging kidneys and several genes involved in neurodegenerative diseases were also detected. This is the first report describing the transcriptome of human sebocytes and its modification by a cocktail of hormones administered in age-specific levels and provides an in vitro model system, which approximates some of the hormone-dependent changes in gene transcription that occur during aging in humans.

A toll-like receptor 2-responsive lipid effector pathway protects mammals against skin infections with gram-positive bacteria

flake (flk), an N-ethyl-N-nitrosourea-induced recessive germ line mutation of C57BL/6 mice, impairs the clearance of skin infections by Streptococcus pyogenes and Staphylococcus aureus, gram-positive pathogens that elicit innate immune responses by activating Toll-like receptor 2 (TLR2). Positional cloning and sequencing revealed that flk is a novel allele of the stearoyl coenzyme A desaturase 1 gene (Scd1). flake homozygotes show reduced sebum production and are unable to synthesize the monounsaturated fatty acids (MUFA) palmitoleate (C(16:1)) and oleate (C(18:1)), both of which are bactericidal against gram-positive (but not gram-negative) organisms in vitro. However, intradermal MUFA administration to S. aureus-infected mice partially rescues the flake phenotype, which indicates that an additional component of the sebum may be required to improve bacterial clearance. In normal mice, transcription of Scd1-a gene with numerous NF-kappaB elements in its promoter--is strongly and specifically induced by TLR2 signaling. Similarly, the SCD1 gene is induced by TLR2 signaling in a human sebocyte cell line. These observations reveal the existence of a regulated, lipid-based antimicrobial effector pathway in mammals and suggest new approaches to the treatment or prevention of infections with gram-positive bacteria.