Expression of an olfactomedin-related gene in rat hair follicular papilla cells.

Follicular papilla (FP) cells, but not their closely related dermal fibroblasts, can maintain hair growth suggesting cell type-specific molecular signals. To define the molecular differences between these two cell types, we generated a subtraction complementary DNA (cDNA) library highly enriched in FP-specific cDNA. Differential screening identified FP-1 as the most abundant cDNA sequence in this subtraction library.

Specificity in stress response: epidermal keratinocytes exhibit specialized UV-responsive signal transduction pathways.

UV light, a paradigmatic initiator of cell stress, invokes responses that include signal transduction, activation of transcription factors, and changes in gene expression. Consequently, in epidermal keratinocytes, its principal and frequent natural target, UV regulates transcription of a distinctive set of genes. Hypothesizing that UV activates distinctive epidermal signal transduction pathways, we compared the UV-responsive activation of the JNK and NFkappaB pathways in keratinocytes, with the activation of the same pathways by other agents and in other cell types.

Palmoplantar keratoderma of Sybert.

A 13-year-old boy and a 7-year-old boy, who are brothers, presented with a life-long history of erythema, hyperkeratosis, and desquamation of the hands and feet. Symptoms improved with the use of topical glucocorticoids and keratolytics. PPK of Sybert is characterized by palmoplantar hyperkeratosis with transgrediens, autosomal dominant inheritance, and the absence of associated systemic features.

Osteopontin gene is expressed in the dermal papilla of pelage follicles in a hair-cycle-dependent manner.

Hair follicle formation and maintenance involve intimate interactions between follicular epithelial cells and a group of specialized mesenchymal cells known as the dermal papilla. Using the random primer polymerase chain reaction, we have identified an approximately 1.4 kb osteopontin mRNA that is present in large quantities in cultured rat vibrissa dermal papilla cells but undetectable in cultured rat skin fibroblasts.

Preserving medical dermatology. A colleague lost, a call to arms, and a plan for battle.

Change within dermatology as a clinical discipline is expected and inevitable. However dermatology may change as a medical specialty in the new millennium, there will still be patients with medical dermatologic disease whose optimal care will depend on skin disease specialists' having the highest level of training and experience in medical dermatology. Dermatologists who have subspecialized in medical dermatology will provide the role models for new generations of dermatologists, perform the patient-oriented research, and care for the more complicated patients.

Rays and arrays: the transcriptional program in the response of human epidermal keratinocytes to UVB illumination.

The epidermis, our first line of defense from ultraviolet (UV) light, bears the majority of photodamage, which results in skin thinning, wrinkling, keratosis, and malignancy. Hypothesizing that skin has specific mechanisms to protect itself and the organism from UV damage, we used DNA arrays to follow UV-caused gene expression changes in epidermal keratinocytes. Of the 6,800 genes examined, UV regulates the expression of at least 198.

Keratins and the keratinocyte activation cycle.

In wound healing and many pathologic conditions, keratinocytes become activated: they turn into migratory, hyperproliferative cells that produce and secrete extracellular matrix components and signaling polypeptides. At the same time, their cytoskeleton is also altered by the production of specific keratin proteins. These changes are orchestrated by growth factors, chemokines, and cytokines produced by keratinocytes and other cutaneous cell types.

Interleukin-1 induces transcription of keratin K6 in human epidermal keratinocytes.

Keratinocytes respond to injury by releasing the proinflammatory cytokine interleukin-1, which serves as the initial "alarm signal" to surrounding cells. Among the consequences of interleukin-1 release is the production of additional cytokines and their receptors by keratinocytes and other cells in the skin. Here we describe an additional effect of interleukin-1 on keratinocytes, namely the alteration in the keratinocyte cytoskeleton in the form of the induction of keratin 6 expression.

The dermatology-industry interface: defining the boundaries.

Support from industry has become an important factor in the growth of the dermatologic profession. However, the relationship creates inevitable conflicts of interest. This article explores these potential conflicts, including (1) giving and receiving of gifts, (2) conduct of clinical trials, (3) appearance of advertisements in professional journals, (4) continuing medical education programs and educational grants to societies and departments, and (5) drug sampling.

Inflammatory versus proliferative processes in epidermis. Tumor necrosis factor alpha induces K6b keratin synthesis through a transcriptional complex containing NFkappa B and C/EBPbeta.

Epidermal keratinocytes respond to injury by becoming activated, i.e. hyperproliferative, migratory, and proinflammatory.

Epidermal signal transduction and transcription factor activation in activated keratinocytes.

In the area of biology, many laboratories around the world are dissecting and characterizing signal transduction mechanisms and transcription factors responsive to various growth factors and cytokines, in various cell types. However, because of the differences in systems used, it is not clear whether these systems coexist, whether they interact meaningfully, and what their relative roles are. Epidermal keratinocytes are the perfect cell type in which to integrate this knowledge, because in these cells these mechanisms are known to be relevant.

Specific organization of the negative response elements for retinoic acid and thyroid hormone receptors in keratin gene family.

Retinoic acid and thyroid hormone are important regulators of epidermal growth, differentiation, and homeostasis. Retinoic acid is extensively used in the treatment of many epidermal disorders ranging from wrinkles to skin cancers. Retinoic acid and thyroid hormone directly control the transcription of differentiation-specific genes including keratins.

Transcriptional control of K5, K6, K14, and K17 keratin genes by AP-1 and NF-kappaB family members.

The expression of keratins K5 and K14 is restricted to the basal layers of the healthy epidermis, whereas the expression of K6 and K17 is induced in response to proliferative and inflammatory signals, respectively. The control of keratin expression occurs primarily at the transcriptional level. We studied the effects of transcription factors of the AP-1 and NF-kappaB families on the expression of those four keratin genes.

Regulation of epidermal expression of keratin K17 in inflammatory skin diseases.

Keratin K17, the myoepithelial keratin, is expressed in psoriasis but is not present in healthy skin. Psoriasis is associated with production of gamma interferon (IFN gamma), which induces the expression of keratin K17 by activating transcription factor STAT1. Our hypothesis states that the induction of K17 is specific for the inflammatory reactions associated with high levels of IFN gamma and activation of STAT1.

Close linkage of the two keratin gene clusters in the human genome.

Mapping studies of functional keratin genes in the human genome have localized most of the acidic keratin genes to chromosome 17q12-q21 and the basic keratin genes to chromosome 12q11-q13. Within the acidic keratin locus two clusters were identified, one containing the genes for K15 and K19, the other the genes for K14, K16, and K17. The relative positions and the distance between the two clusters have not been determined previously.

Codominant regulation of keratin gene expression by cell surface receptors and nuclear receptors.

Epidermal keratinocytes are subject to a large variety of signals that modulate their differentiation in health and their activation in disease. Hormones and vitamins, which act via nuclear receptors, affect the differentiation process, whereas growth factors and cytokines, which act via cell surface receptors, affect keratinocyte activation and related events. Using expression of keratin genes as markers for keratinocyte phenotype, we examined the interaction between the nuclear receptor and cell surface receptor pathways.

Novel regulation of keratin gene expression by thyroid hormone and retinoid receptors.

Expression of keratin proteins, markers of epidermal differentiation and pathology, is uniquely regulated by the nuclear receptors for retinoic acid (RAR) and thyroid hormone (T3R) and their ligands: it is constitutively activated by unliganded T3R, but it is suppressed by ligand-occupied T3R or RAR. This regulation was studied using gel mobility shift assays with purified receptors and transient transfection assays with vectors expressing various receptor mutants. Regulation of keratin gene expression by RAR and T3R occurs through direct binding of these receptors to receptor response elements of the keratin gene promoters.

Characterization of nuclear protein binding sites in the promoter of keratin K17 gene.

Keratin K17, while not present in healthy skin, is expressed under various pathological conditions, including psoriasis and cutaneous allergic reactions. The regulatory circuits involved in transcription of the human keratin K17 gene are poorly understood. To begin an analysis of the molecular mechanisms that regulate K17 gene transcription, we have studied the interactions between the nuclear proteins and the promoter region of the human K17 gene.

Message of nexin 1, a serine protease inhibitor, is accumulated in the follicular papilla during anagen of the hair cycle.

A group of specialized mesenchymal cells located at the root of the mammalian hair follicle, known as the follicular or dermal papillary cells, are involved in regulating the hair cycle, during which keratinocytes of the lower follicle undergo proliferation, degeneration and regrowth. Using the arbitrarily primed-PCR approach, we have identified a 1.3 kb messenger RNA that is present in large quantities in cultured rat follicular papillary cells, but not in skin fibroblasts.

Keratinocyte growth factor and keratin gene regulation.

Keratinocyte growth factor (KGF) is a stromally derived paracrine mitogen that belongs to the fibroblast growth factor (FGF) family. It is secreted by dermal fibroblasts and specifically promotes keratinocyte proliferation. We have recently shown that epidermal growth factor (EGF) and transforming growth factor beta (TGF beta), modulators of keratinocyte proliferation, regulate expression of specific keratin genes.