316 Academy DOI: 10.1111/j.1610-0387.2007.06274.x CME Pathophysiology of acne Pathophysiologie der Akne Klaus Degitz, Marianne Placzek, Claudia Borelli, Gerd Plewig Department of Dermatology and Allergy, University of Munich, Germany Section Editor Prof. Dr. Michael Landthaler, Regensburg Introduction Acne is the most common skin disease [1]. In Germany, as in other Western industri- alized nations, a majority of the population has signs and symptoms of acne at least Epidemiologic data suggests up to during puberty. Epidemiologic data suggests up to 80% of individuals are affected 80% of individuals are affected. [2]. Men and women develop acne about equally. The disease has its onset at age 10–14 years and regresses by age 20–25 years. In some patients acne persists into the The clinical spectrum of acne ranges fourth or fifth decade of life (persistent acne). The clinical spectrum of acne ranges from mild manifestations up to from mild manifestations (a few comedones with occasional inflamed papulopus- severe inflammation and abscess for- tules, sometimes termed “physiologic” acne in contrast to “clinical” acne in more se- mation. vere cases) up to severe inflammation and abscess formation on the face or upper trunk (Figure 1). Several classifications exist to describe the severity of acne [1, 3]. In- dependent of its severity, acne can be a heavy emotional burden on the patient. Genetics There is a genetic predisposition to acne and the concordance rate is high among Probably several genes are involved identical twins. Little is known about specific hereditary mechanisms. Probably sev- in the predisposition for acne eral genes are involved in the predisposition for acne [4]. These include the gene for cytochrome P-450-1A1 and for steroid 21-hydroxylase, which influences androgen production in the adrenal gland. People with a XYY karyotype often display a severe course of acne. Pathogenetic factors and their clinical correlations The current concept is that acne The current concept is that acne results from several interacting pathogenetic factors. results from several interacting Among these are hormonally determined overproduction of sebum (seborrhea), fol- pathogenetic factors: seborrhea, licular hyperkeratosis (closed and open comedones), changes in microbial flora and follicular hyperkeratosis (come- immunologic processes and inflammation. The pathogenetic factors should not be dones), microbial flora, inflammatory viewed individually, as they influence each other. Seborrhea, on the one hand, and in- processes. creased keratinization of the follicular epithelium, on the other, produce a favorable environment for strong overgrowth of propionibacteria, which belong to the resident Seborrhea and follicular hyperkerato- skin flora and are non-pathogenic under normal circumstances. Metabolites of propi- sis favor overgrowth of propionibac- onibacteria induce follicular and perifollicular inflammation especially due to chemo- teria. tactic substances. The inflammatory component can be the dominant clinical feature propionibacteria induce follicular in many patients (acne papulopustulosa, Figure 2). As a result of the inflammatory and perifollicular inflammation espe- follicular changes, leukocytes can invade the follicular wall and follicular rupture may cially due to chemotactic substances. follow (Figure 3). The content of the comedo empties into the surrounding tissue. Keratin and hair components augment inflammation via a foreign body reaction, so that abscesses and fistulas as well as systemic signs of inflammation can occur (acne conglobata, Figure 1b). JDDG | 4˙2007 (Band 5) © The Authors • Journal compilation © Blackwell Verlag, Berlin • JDDG • 1610-0379/2007/0504-0316 Academy 317 Figure 1: Patient with mild (a) and severe (b) acne. Inflammation is not only the result of the pathogenetic factors seborrhea, follicular hyperkeratosis and bacterial overgrowth. Recent experimental results show that initial perifollicular inflammation promotes follicular hyperkeratosis and thus the formation of comedones [5]. Seborrhea With few exceptions (“free” sebaceous glands in the genital region and mucosa of the cheek), sebaceous glands are associated with hair follicles. Sebum is formed by disso- lution of sebocytes in the sebaceous lobules (holocrine secretion), transported to the follicle by a draining sebaceous duct and reaches the skin surface via the infundibu- The largest sebaceous glands are lum. The largest sebaceous glands are found on the face and upper trunk, i.e. regions found on the face and upper trunk, where acne preferentially occurs. Large conglomerations of sebaceous glands associ- i.e. regions where acne preferentially ated with fine hairs are characteristic for sebaceous follicles. occurs. It has been long known that sebum production in the sebocytes is regulated by It has been long known that sebum androgens. Acne patients generally display increased sebum production (seborrhea). production in the sebocytes is regu- Eunuchs produce less sebum due to androgen deficiency and do not develop acne. lated by androgens. Figure 3: Inflammatory lesion with rupture of the follicular wall. From [1]. Figure 2: Acne papulopustulosa. JDDG | 4˙2007 (Band 5) 318 Academy Table 1: Plasma concentrations (nmol/l) and relative androgenic strength of androgens in adults. According to [15]. Relative M W androgenic strength Dehydroepiandrosterone sulfate 1300–6800 1300–6800 1 Androstenedione 3.0–5.0 3.5–7.0 2 Testosterone (1-2% free) 10–35 < 3.5 20 Dihydrotestosterone 0.87–2.6 0.17–1.0 60 Androgens, sebum production and acne are closely associated at certain ages. In the first months of life temporarily increased androgen production leads to excess sebum and occasionally to acne of the newborn (acne neonatorum). After regression of early androgen production, little sebum is produced in childhood and acne is almost never observed. At an age of 8–10 years, the adrenal glands and later the gonads start pro- ducing androgens. This results in enlargement of the sebaceous glands, increased se- The main sources of androgens are bum production and acne in teenagers. The main sources of androgens are the adre- the adrenal glands and gonads. nal glands and gonads, even though the skin itself is capable of synthesizing androgens. Androgens reach their target organs via the blood stream, affect gender differentiation, and promote musculoskeletal growth. In the skin they stimulate sebum production in sebocytes. The primary androgen regulating sebum production is dehydroepiandrosterone sul- fate (DHEA-S). It is the androgen with the highest sebum concentration, being about equal in men and women (Table 1). DHEA-S is only a weak androgen, but sebocytes possess all necessary enzymes capable of intracellularly metabolizing DHEA-S into more potent androgens (Figure 4). After uptake in a cell, testosterone and dihy- drotestosterone bind to a cytoplasmic androgen receptor, wander into the nucleus and bind there to specific gene sequences. Binding of the androgen-receptor complex affects the reading rate of the target genes. This results in an increased proliferation of sebaceous glands and increased sebum production; the responsible genes have not yet been identified. In sebocyte cultures, testosterone and dihydrotestosterone stimulate cell proliferation and lipid synthesis, to a higher degree in sebocytes from the face than in those from the legs [6]. In most patients with seborrhea, In most patients with seborrhea, increased sebum production occurs despite normal increased sebum production occurs serum levels of androgens. Increased sensitivity of sebocytes towards androgens is the despite normal serum levels of presumed cause. Special importance is attributed to the enzyme 5␣-reductase, which androgens. converts testosterone into the more potent dihydrotestosterone. Two isoenzymes of 5␣-reductase with differing biochemical characteristics exist. Only isoenzyme 1 is strongly expressed in sebocytes and is thus potentially important for physiological se- bum production, but also for the pathogenesis of acne. Cyproterone acetate, which is Seborrhea and acne are not only efficacious in treating acne, inhibits 5␣-reductase. It is probable, nonetheless, that its observed in the presence of normal effect is based on its antagonistic binding to the intracellular androgen receptor, as in- blood levels of androgens, but also as hibition of type 1 5␣-reductase alone does not improve acne [7]. Seborrhea and acne a result of elevated androgen levels. are not only observed in the presence of normal blood levels of androgens, but also as a result of elevated androgen levels. Elevated serum levels of androgen can occur in Frequent causes of hyperandrogene- polycystic ovarian syndrome, androgen-producing tumors (e.g. adrenal adenomas, mia are polycystic ovarian syndrome ovarian tumors such as hilar cell tumor) as well as congenital adrenal hyperplasia, and congenital adrenal hyperplasia. which results from enzyme disturbances in the adrenal gland and is not quite so rare Seborrhea and acne can be caused in its milder forms [8] (Table 2). Seborrhea and acne can be caused not only by en- not only by endogenous dogenous but also by exogenously administered androgens. This might be iatrogenic also by exogenously administered during provocation of premature epiphyseal closure to treat excessively tall stature or androgens during substitution treatment of hypogonadism, but also due to androgenic anabolic JDDG | 4˙2007 (Band 5) Academy 319 Figure 4: Androgen metabolism
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