Sexual hormones in human skin.

The skin locally synthesizes significant amounts of sexual hormones with intracrine or paracrine actions. The local level of each sexual steroid depends upon the expression of each of the androgen- and estrogen-synthesizing enzymes in each cell type, with sebaceous glands and sweat glands being the major contributors. Sebocytes express very little of the key enzyme, cytochrome P450c17, necessary for synthesis of the androgenic prohormones dehydroepiandrosterone and androstenedione, however, these prohormones can be converted by sebocytes and sweat glands, and probably also by dermal papilla cells, into more potent androgens like testosterone and dihydrotestosterone. Five major enzymes are involved in the activation and deactivation of androgens in skin. Androgens affect several functions of human skin, such as sebaceous gland growth and differentiation, hair growth, epidermal barrier homeostasis and wound healing. Their effects are mediated by binding to the nuclear androgen receptor. Changes of isoenzyme and/or androgen receptor levels may have important implications in the development of hyperandrogenism and the associated skin diseases such as acne, seborrhoea, hirsutism and androgenetic alopecia. On the other hand, estrogens have been implicated in skin aging, pigmentation, hair growth, sebum production and skin cancer. Estrogens exert their actions through intracellular receptors or via cell surface receptors, which activate specific second messenger signaling pathways. Recent studies suggest specific site-related distribution of ERalpha and ERbeta in human skin. In contrast, progestins play no role in the pathogenesis of skin disorders. However, they play a major role in the treatment of hirsutism and acne vulgaris, where they are prescribed as components of estrogen-progestin combination pills and as anti-androgens. These combinations enhance gonadotropin suppression of ovarian androgen production. Estrogen-progestin treatment can reduce the need for shaving by half and arrest progression of hirsutism of various etiologies, but do not necessarily reverse it. However, they reliably reduce acne. Cyproterone acetate and spironolactone are similarly effective as anti-androgens in reducing hirsutism, although there is wide variability in individual responses.

What is the pathogenesis of acne?

For a long time, the mantra of acne pathogenesis debates has been that acne vulgaris lesions develop when (supposedly largely androgen-mediated) increased sebum production, ductal hypercornification, and propionibacteria come together with local inflammatory process in the unlucky affected individual. And yet, the exact sequence, precise interdependence, and choreography of pathogenic events in acne, especially the 'match that lights the fire' have remained surprisingly unclear, despite the venerable tradition of acne research over the past century. However, exciting recent progress in this--conceptually long somewhat stagnant, yet clinically, psychologically, and socioeconomically highly relevant--everyday battlefield of skin pathology encourages one to critically revisit conventional concepts of acne pathogenesis. Also, this provides a good opportunity for defining more sharply key open questions and intriguing acne characteristics whose underlying biological basis has far too long remained uninvestigated, and to emphasize promising new acne research avenues off-the-beaten-track--in the hope of promoting the corresponding development of innovative strategies for acne management.

Induction of puberty in the hypogonadal girl--practices and attitudes of pediatric endocrinologists in Europe.

The management of children and adolescents with hypogonadism and in particular the induction of puberty in the hypogonadal girl is subject to controversy. Therefore, under the auspices and through organization of the Drugs and Therapeutics Committee of the European Society of Paediatric Endocrinology (ESPE), an interactive voting session and workshop was held at the 39th ESPE Annual Meeting in Brussels to discuss these topics. Common practice in Europe and attitudes of pediatric endocrinologists in Europe were questioned and recorded in the 1.5-hour program. We now report on some of the results of the questionnaires and discussions of that session to further the discussion on and knowledge of current concepts of induction of puberty in the hypogonadal girl in Europe. It became clear from the data accumulated here that the start of treatment, the aims of therapy and the modalities of how to treat the hypogonadal girl vary amongst pediatric endocrinologists in Europe. For example, a chronological age > or =11 years was considered appropriate for the start of estrogen therapy by 40.4% (out of 188 answers), while 47.8 and 7.5% felt that a chronological age > or =13 and > or =15 years respectively was appropriate. In respect to the form and route of estrogen administration, the audience was asked for their common estrogen replacement practice: 31.9% used oral 17beta-estradiol treatment, while 10% would prescribe 17beta-estradiol transdermal patches. Another 12.2% would recommend conjugated estrogens (e.g. Premarin) orally, 4.8% use oral estradiol valerate and 39.3% ethinylestradiol orally. Only 1.8% out of 229 physicians answering were undecided. In addition, counseling of patients and their families is quite variable and perceptions for example regarding potential pregnancies in affected women are also not uniform. In this report the authors do not want to provide their own personal views but rather reflect current practice in Europe. It is hoped that a more uniform picture will emerge once European and international guidelines on how to treat the girl with hypogonadism will be available and even more discussions amongst doctors from different countries have been led.

The biochemical basis for increased testosterone production in theca cells propagated from patients with polycystic ovary syndrome.

Ovarian theca cells propagated from patients with polycystic ovary syndrome (PCOS) convert steroid precursors into T more efficiently than normal theca cells. To identify the basis for increased T production by PCOS theca cells, we examined type I-V 17 beta-hydroxysteroid dehydrogenase (17 beta HSD) isoform expression in long-term cultures of theca and granulosa cells isolated from normal and PCOS ovaries. RT-PCR analysis demonstrated that theca cells express type V 17 beta HSD a member of the aldo-keto reductase (AKR) superfamily (17 beta HSDV, AKR1C3), whereas expression of type I, II, and IV 17 beta HSD, which are members of the short-chain dehydrogenase/reductase superfamily, was limited to granulosa cells. Type III 17 beta HSD, the testicular isoform, was not detected in either granulosa or theca cells. Northern and real-time PCR analyses demonstrated that 17 beta HSDV transcripts were not significantly increased in PCOS theca cells compared with normal theca cells. RT-PCR analysis revealed that theca cells also express another AKR, 20 alpha HSD (AKR1C1). Both basal and forskolin-stimulated 20 alpha HSD mRNA levels were increased in PCOS theca cells compared with normal theca cells. However, 17 beta HSD enzyme activity per theca cell was not significantly increased in PCOS, suggesting that neither AKR1C3 nor AKR1C1 contributes to the formation of T in this condition. In contrast, 17 alpha-hydroxylase/C17,20 lyase and 3 beta HSD enzyme activities were elevated in PCOS theca cells, driving increased production of T precursors. These findings indicate that 1) increased T production in PCOS theca cells does not result from dysregulation of "androgenic" 17 beta HSD activity or altered expression of AKRs that may express 17 beta HSD activity; and 2) increased synthesis of T precursors is the primary factor driving enhanced T secretion in PCOS.

Limited cooperation between peroxisome proliferator-activated receptors and retinoid X receptor agonists in sebocyte growth and development.

We have found that sebaceous epithelial cell (sebocyte) differentiation is induced by cognate ligand-agonists of either peroxisome proliferator-activated receptors (PPARs) or retinoid X receptors (RXRs). In this study, we tested the hypothesis that PPAR-RXR cooperation is used in sebocytes as was reported to occur in gene transfection systems and liposarcoma cells through PPAR-RXR heterodimerization. PPAR agonists at maximally effective concentrations were tested in combination with a specific RXR agonist (the rexinoid CD2809) at doses ranging from submaximal to maximal in a primary rat preputial cell monolayer culture system. We evaluated ligand-agonists of PPARalpha (WY-14643 = WY), PPARgamma (troglitazone = TRO), and PPARdelta,alpha (carbaprostacyclin = cPGI2). Cell differentiation was determined by analysis of lipid staining and proliferation by cell counting. The RXR agonist induced a more diffuse and granular pattern of lipid staining throughout colonies than did PPAR agonists. The PPAR ligands WY, TRO, and cPGI2 induced 37, 35, and 59% lipid-forming colonies (LFCs), respectively (P < 0.05 vs controls, which averaged 19%). Low-dose rexinoid (10(-8) M) alone exerted no significant effect but amplified the effect of cPGI2 (P < 0.05). Middose rexinoid (10(-7) M), which alone induced about 40% LFCs, had an additive effect on differentiation with WY, TRO, and cPGI2 (71, 48, and 83% LFCs respectively, P < 0.05 vs each agonist alone). Proliferation was enhanced significantly by either rexinoid or cPGI2, but there was no change in growth when the two were added together. The greater effectiveness of cPGI2 than the other PPAR agonists may be explained by the predominance of PPARdelta gene expression in cultured sebocytes, as demonstrated by RNase protection assay. These studies demonstrate that a submaximal dose of RXR agonist augmented the stimulation of sebocyte differentiation by PPAR agonists, as expected from PPAR-RXR heterodimerization. However, the evidence for PPAR-RXR cooperativity is limited. The pattern of lipid staining is compatible with an independent effect of rexinoid on sebocyte differentiation. Furthermore, since there is no enhancement of the growth-promoting effects of RXR agonist and cPGI2 when they are combined, this effect also does not appear to be mediated by PPAR-RXR interaction.

Pediatric implications in bioterrorism part II: postexposure diagnosis and treatment.

Bioterrorism is an old tactic used in warfare. The use of fatal diseases or man-made poisons to subdue others has not been limited to wartime. Trauma personnel should be aware of commonly used agents, the signs and symptoms of their exposure, and recommended treatment. Children can be victims of terrorists' acts and need special attention because of their unique response to exposure, varying dosages of medications, and lack of active immunity.

Polycystic ovary syndrome and insulin-resistant hyperinsulinemia.

In a broad sense, polycystic ovary syndrome (PCOS) may be considered to be synonymous with chronic unexplained hyperandrogenemia, which accounts for approximately 95% of hyperandrogenism in women. PCOS comprises a mosaic of classic and nonclassic forms, which may ultimately prove to have distinct genetic determinants. The hyperandrogenism appears to arise from generalized abnormal regulation (dysregulation) of steroidogenesis. This dysregulation seems to result from imbalance among the various extrinsic and intrinsic factors involved in the modulation of trophic hormone action. Hyperinsulinemia seems to be an important extrinsic factor in many cases of PCOS; it results from resistance to the effects of insulin on glucose metabolism. The elevation in insulin levels may precipitate hyperandrogenemia in genetically vulnerable individuals by unmasking latent abnormalities in the regulation of steroidogenesis. One of these may be a polycystic ovary gene that is expressed in the male as pattern baldness. Insulin also seems to be one of many factors that interact with androgen to regulate pilosebaceous unit development. Treatment of PCOS with antidiabetic insulin-lowering agents may improve ovarian function and androgen levels; it remains to be determined whether it will benefit the pilosebaceous unit manifestations of the disorder.

Diagnosis of the polycystic ovary syndrome in adolescence: comparison of adolescent and adult hyperandrogenism.

We performed gonadotropin releasing hormone agonist (GnRHag) tests on 23 consecutive hyperandrogenic girls 9.9-17.5 years of age who were referred to our pediatric endocrinology clinic with symptoms suggestive of PCOS. They were compared to contemporaneously studied groups of adult normal and hyperandrogenic women. We found that hyperandrogenic adolescents had clinical and endocrine features similar to those of hyperandrogenic adults. However, there were some noteworthy unique features of adolescent hyperandrogenism, such as presentation in mid-childhood with premature pubarche and the occasional diagnosis before the age of 10 years. Some differences between adolescents and adults were statistically significant, for example, pelvic ultrasonography was not as helpful in the diagnosis of FOH as it is in adults. Nevertheless, a number of questions about the development of the ovarian dysfunction remain to be answered. For example, we are unable to diagnose ovarian dysfunction before puberty or in early puberty, and the relationship of "physiologic adolescent anovulation" to PCOS remains to be defined.

Should we treat genetic syndromes?

With the greater availability of GH due to the development of recombinant human GH, GH therapy has expanded well beyond the original FDA indication for GHD. We examine the NCGS database, comparing data for FDA-approved indications with data for "other" conditions to see whether such expanded use is warranted. Although statistical analyses are of questionable validity because of the small size of some subpopulations and other factors discussed herein, certain trends emerge from the data captured by NCGS. We conclude that many clinical syndromes characterized by short stature are responsive to GH, at least in the short term. For many such syndromes, responsiveness is of the same magnitude as that seen in Turner's syndrome and, occasionally, GHD. If responsiveness to GH is the most important criterion for GH therapy, these "other" conditions warrant an open-minded, prospective evaluation.

Role of hormones in pilosebaceous unit development.

Androgens are required for sexual hair and sebaceous gland development. However, pilosebaceous unit (PSU) growth and differentiation require the interaction of androgen with numerous other biological factors. The pattern of PSU responsiveness to androgen is determined in the embryo. Hair follicle growth involves close reciprocal epithelial-stromal interactions that recapitulate ontogeny; these interactions are necessary for optimal hair growth in culture. Peroxisome proliferator-activated receptors (PPARs) and retinoids have recently been found to specifically affect sebaceous cell growth and differentiation. Many other hormones such as GH, insulin-like growth factors, insulin, glucocorticoids, estrogen, and thyroid hormone play important roles in PSU growth and development. The biological and endocrinological basis of PSU development and the hormonal treatment of the PSU disorders hirsutism, acne vulgaris, and pattern alopecia are reviewed. Improved understanding of the multiplicity of factors involved in normal PSU growth and differentiation will be necessary to provide optimal treatment approaches for these disorders.

Economic links between cardiovascular groups and hospitals: a new approach.

Recent regulatory developments complicate the process of aligning the interests of cardiovascular groups with their hospital partners. However, the need for alignment has never been greater. Declining revenues make it essential that physicians and hospitals cooperate in every way to reduce cost while at the same time preserving value to patients. The CIB Joint Venture concept described in this article provides a low-risk option that is worth consideration.

Expression of 17 beta-hydroxysteroid dehydrogenase type 5 in human ovary: a pilot study.

OBJECTIVE: Conversion of androstenedione to testosterone, the most potent androgen secreted by the ovary, is carried out by androgenic 17 beta-hydroxysteroid dehydrogenase (17 beta-HSD) activity. The molecular basis for this is unclear. We tested the hypothesis that type 5 17 beta-HSD (17 beta-HSD5) is responsible for testosterone formation from androstenedione in the human ovary. METHODS: We used primers specific for each type of 17 beta-HSD to identify quantitatively and directly sequence the polymerase chain reaction products of a human ovary library. RESULTS: 17 beta-HSD1, 17 beta-HSD4, and 17 beta-HSD5 were detected in the library lysate, but not 17 beta-HSD2 or 17 beta-HSD3. 17 beta-HSD5 was the predominant androgenic form of 17 beta-HSD expressed in human ovary. CONCLUSION: These data suggest that 17 beta-HSD5 may play a major role in testosterone biosynthesis by the human ovary. Further investigation of the regulation of 17 beta-HSD5 gene expression is warranted with regard to ovarian testosterone secretion in normal and abnormal states of ovarian function, such as polycystic ovary syndrome.

The role of specific retinoid receptors in sebocyte growth and differentiation in culture.

Retinoic acid derivatives (retinoids) exert their pleiotropic effects on cell development through specific nuclear receptors, the retinoic acid receptors and retinoid X receptors. Despite recent progress in understanding the cellular and molecular mechanisms of retinoid activity, it is unknown which of the retinoid receptor pathways are involved in the specific processes of sebocyte growth and development. In this study, we investigated the roles of specific retinoid receptors in sebocyte growth and differentiation, by testing the effects of selective retinoic acid receptor and retinoid X receptor ligands at concentrations between 10-10 M and 10-6 M in a primary rat preputial cell monolayer culture system. Cell growth was determined by number of cells and colonies, and cell differentiation by analysis of lipid-forming colonies. All-trans retinoic acid and selective retinoic acid receptor agonists (CD271 = adapalene, an RAR-beta,gamma agonist; CD2043 = retinoic acid receptor pan-agonist; and CD336 = Am580, an RAR-alpha agonist) caused significant decreases in numbers of cells, colonies, and lipid-forming colonies, but with an exception at high doses of all-trans retinoic acid (10-6 M), with which only a small number of colonies grew but they became twice as differentiated as controls (42.2 +/- 4.0% vs 22.6 +/- 2.7%, mean +/- SEM, lipid-forming colonies, p < 0.01). Furthermore, the RAR-beta,gamma antagonist CD2665 antagonized the suppressive effects of all-trans retinoic acid, adapalene, and CD2043 on both cell growth and differentiation. In contrast, the retinoid X receptor agonist CD2809 increased cell growth slightly and lipid-forming colonies dramatically in a clear dose-related manner to a maximum of 73.7% +/- 6.7% at 10-6 M (p < 0. 001). Our data suggest that retinoic acid receptors and retinoid X receptors differ in their roles in sebocyte growth and differentiation: (i) retinoic acid receptors, especially the beta and/or gamma subtypes, mediate both the antiproliferative and antidifferentiative effects of retinoids; (ii) retinoid X receptors mediate prominent differentiative and weak proliferative effects; (iii) the antiproliferative and antidifferentiative effects of all-trans retinoic acid are probably mediated by retinoic acid receptors, whereas its differentiative effect at high dose may be mediated by retinoid X receptors via all-trans retinoic acid metabolism to 9-cis retinoic acid, the natural ligand of retinoid X receptors.

Peroxisome proliferator-activated receptors and skin development.

PPARs are nuclear hormone receptors. PPAR subtypes (alpha, gamma, delta, the latter a xPPARbeta homologue) were initially investigated in skin because of their known role in regulating lipid metabolism. Studies adding specific PPAR ligand activators to cultured skin or skin cells are compatible with the concepts that PPARalpha activation mediates early lipogenic steps common to the function of both skin epidermal cells (keratinocytes) and sebaceous cells (sebocytes), PPARgamma activation plays a unique role in stimulating sebocyte lipogenesis, and PPARdelta activation may contribute to lipid biosynthesis in both sebocytes and keratinocytes under certain circumstances. Epidermal keratinocytes appear to express small amounts of PPARalpha and PPARdelta mRNA and a trace of PPARgamma mRNA which is up-regulated with differentiation. Sebocytes express all subtypes; PPARgamma gene expression excedes that in epidermis. The emerging data on PPAR protein expression suggests that epidermis normally expresses predominantly PPARalpha, while sebocytes express more PPARgamma than PPARalpha. These expression patterns may change during hyperplasia, differentiation and inflammation. Gene disruption studies in mice are compatible with a contribution of PPARalpha to skin barrier function, suggest that PPARgamma is necessary for sebocyte differentiation, and indicate that PPARdelta can ameliorate inflammatory responses in skin. PPARs appear to play a role in keratinocyte synthesis of the lipids that they export to the intercellular space to form the skin permeability barrier. They also appear to be important for sebocyte formation of the intracellular fused lipid droplets that constitute the holocrine secretion of the sebaceous gland. In addition, they may play roles in keratinocyte growth and differentiation and the inhibition of skin inflammation by diverse mechanisms not necessarily related to fat metabolism.

Intrauterine growth retardation associated with maternal uniparental disomy for chromosome 6 unmasked by congenital adrenal hyperplasia.

We report the first case of maternal uniparental disomy for chromosome 6 (UPD6mat) ascertained through congenital adrenal hyperplasia (CAH), which arose because of reduction to homozygosity of an autosomal recessive mutation. This case suggests that UPD6mat is associated with intrauterine growth retardation (IUGR). A case of paternal UPD (involving only the short arm of chromosome 6) ascertained as CAH has previously been reported, but was not stated to have IUGR. Our patient was born with IUGR followed by extraordinarily good catch-up growth. She had a history of a marked lag in motor development. She presented at 2.65 y of age with pubarche of 3 mo duration, clitoral enlargement, and an advanced bone age. Simple virilizing CAH was diagnosed by elevations of plasma 17-hydroxyprogesterone and testosterone. Mutation analysis showed that the CAH was due to homozygosity for the 1172N exon 4 mutation. When parental DNA was examined, the mother was found to be heterozygous for the uncommon exon 4 mutation, while the father had no detectable mutations. DNA microsatellite analysis was subsequently performed on the patient and parents using polymorphic markers spanning the entire chromosome 6. Seven markers were informative for inheritance of a single maternal allele and absence of paternal alleles in the proband. Analysis of microsatellite markers from other chromosomes confirmed biparental inheritance at these loci. This combination of findings is diagnostic of UPD6mat. The only other reported case of UPD6mat was discovered serendipitously when genotyped for renal transplantation; this patient had a history of IUGR. Since both cases of UPD6mat had IUGR, the phenotype appears to include IUGR as well as the potential to unmask an autosomal recessive trait.

Growth hormone and insulin-like growth factors have different effects on sebaceous cell growth and differentiation.

Several observations suggest that GH stimulates sebaceous gland growth and development. Therefore, we studied the effects of GH and insulin-like growth factors (IGFs), alone and with androgen, on sebaceous epithelial cell (sebocyte) growth and differentiation in vitro. The rat preputial cell culture model system was used to judge differentiation (induction of lipid-forming colonies, LFCs) and DNA synthesis. GH increased sebocyte differentiation. At a dose of 10(-8) M in the presence of micromolar insulin, GH was 3.8 times more potent than IGF-I (38.1+/-4.2%, SEM, vs. 10+/-1.5% LFCs) and 6 times more potent than IGF-II (6+/-0.5% LFCs). IGF-I 10(-8) M alone stimulated a similar amount of differentiation as insulin 10(-6) M, although it was less effective than insulin in augmenting the effect of GH on differentiation. GH had no effect on sebocyte uptake of 3H-thymidine at doses up to 10(-6) M. On the other hand, IGF-I was the most potent stimulus of DNA synthesis (168% of control; P < 0.001 vs. all others). IGF-II 10(-8) M stimulated 3H-thymidine incorporation similarly to insulin 10(-6) M. In the presence of insulin, dihydrotestosterone (DHT) 10(-6) M induced 31.4+/-1.7% LFCs, and there was a tendency of DHT and GH to interact in promoting differentiation. When insulin was omitted from the system, differentiation was decreased overall, but GH +/- DHT slightly improved differentiation. The IGFs had no effect on the response to DHT. DHT decreased DNA synthesis by 40%, an effect unaltered by GH or IGFs. These results suggest that GH and IGFs have different functions in sebaceous cell growth and differentiation: GH stimulated differentiation beyond that found with IGFs or insulin, yet had no effect on DNA synthesis, a parameter stimulated most potently by IGF-I. While GH augmented the effect of DHT on differentiation, the IGFs had no effect on the response of DHT. These data indicate that GH may in part act directly on sebocytes rather than indirectly through IGF production. These data are consistent with the concept that increases in GH and IGF production contribute in complementary ways to the increase in sebum production during puberty and in acromegaly.