Irwin M. Freedberg

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. Three waves of changes in gene expression can be distinguished, 0.5–2, 4–8, and 16–24 h after illumination. The first contains transcription factors, signal transducing, and cytoskeletal proteins that change cell phenotype from a normal, fast‐growing cell to an activated, paused cell. The second contains secreted growth factors, cytokines, and chemokines; keratinocytes, having changed their own physiology, alert the surrounding tissues to the UV damage. The third wave contains components of the cornified envelope, as keratinocytes enhance the epidermal protective covering and, simultaneously, terminally differentiate and die, removing a carcinogenic threat. UV also induces the expression of mitochondrial proteins that provide additional energy, and the enzymes that synthesize raw materials for DNA repair. Using a novel skin organ culture model, we demonstrated that the UV‐induced changes detected in keratinocyte cultures also occur in human epidermis in vivo.

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. Keratinocytes both produce and respond to growth factors and cytokines, especially in pathological conditions and during wound healing, when the physiology of keratinocytes is altered in a way specified by the presence of a subset growth factors and cytokines. In fact, growth factors and cytokines cause the major changes in gene expression and keratinocyte behavior in various cutaneous diseases. In some cases, such as in wound healing, these responses are highly beneficial; in others, such as in psoriasis, they are pathological. It is not clear at present which are operating in which conditions, which are important for the healing process and which are harmful. Growth factors and cytokines affect keratinocytes sometimes simultaneously, at other times individually. In this manuscript we describe the signal transduction pathways responsible for the effects of interferons, the EGF/TGF alpha family and the TNF alpha/IL-1 family of signaling molecules. We also describe the important transcription factors known to be functional in epidermis, with particular emphasis on those factors that are activated by growth factors and cytokines. Finally, we describe what is known about transcriptional regulation of keratin genes, especially those specifically expressed in pathological processes in the epidermis. We expect that the enhanced understanding of the pathways regulating gene expression in keratinocytes will identify the pharmacological targets, the signal transducing proteins and the corresponding transcription factors, used by growth factors and cytokines. This research will led to development of compounds precisely aimed at those targets, allowing us to isolate and inhibit the harmful side effects of growth factors and cytokines. Such compounds should lead to highly specific and therefore more effective treatments of the cutaneous disorders in which these pathways play significant roles.

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. These processes are regulated by growth factors and cytokines. One of the markers of activated keratinocytes is keratin K6. We used a novel organ culture system to show that tumor necrosis factor α (TNFα) induces the expression of K6 protein and mRNA in human skin. Multiple isoforms of K6 are encoded by distinct genes and have distinct patterns of expression. By having shown previously that proliferative signals, such as epidermal growth factor (EGF), induce expression of the cytoskeletal protein keratin K6b, we here demonstrate that the same isoform, K6b, is also induced by TNFα, a proinflammatory cytokine. Specifically, TNFα induces the transcription of the K6b gene promoter. By using co-transfection, specific inhibitors, and antisense oligonucleotides, we have identified NFκB and C/EBPβ as the transcription factors that convey the TNFα signal. Both transcription factors are necessary for the induction of K6b by TNFα and act as a complex, although only C/EBPβ binds the K6b promoter DNA. By using transfection, site-directed mutagenesis, and footprinting, we have mapped the site that responds to TNFα, NFκB, and C/EBPβ. This site is separate from the one responsive to EGF and AP1. Our results show that the proinflammatory (TNFα) and the proliferative (EGF) signals in epidermis separately and independently regulate the expression of the same K6b keratin isoform. Thus, the cytoskeletal responses in epidermal cells can be precisely tuned by separate proliferative and inflammatory signals to fit the nature of the injuries that caused them.

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. The DNA binding “C” domain of these receptors is essential for both ligand-dependent and -independent regulation. However, the NH-terminal “A/B” domain of T3R is not required for either mode of regulation of keratin gene expression. Furthermore, v-ErbA, an oncogenic derivative of cT3R, also activates keratin gene expression. In contrast to the previously described mechanism of gene regulation by T3R, heterodimerization with the retinoid X receptor is not essential for activation of keratin gene expression by unliganded T3R. These findings indicate that the mechanism of regulation of keratin genes by RAR and T3R differs significantly from the mechanisms described for other genes modulated by these receptors.

Evolution of keratin genes: Different protein domains evolve by different pathways

SummaryIntermediate filaments are composed of a family of proteins that evolved from a common ancestor. The proteins consist of three domains: a central, alpha-helical domain similar in all intermediate filaments, bracketed by two domains that are variable in length and structure. Within the intermediate-filament family, several subfamilies have been recognized by immunologic and nucleic acid hybridization techniques. In this paper we present the sequence of the genomic DNA coding for a 65-kilodalton human keratin and compare it with the sequences of other intermediate-filament proteins. While the central, alpha-helical domains of these proteins show homologies that indicate a common ancestor, the sequences of the variable terminal domains indicate that the variable domains evolved through a series of tandem duplications and possibly by gene-conversion mechanisms.

Disease-activated transcription factor: allergic reactions in human skin cause nuclear translocation of STAT-91 and induce synthesis of keratin K17.

Epidermal keratinocytes have important immunologic functions, which is apparent during wound healing, in psoriasis, and in allergic and inflammatory reactions. In these processes, keratinocytes not only produce cytokines and growth factors that attract and affect lymphocytes but also respond to the polypeptide factors produced by the lymphocytes. Gamma interferon (IFN-gamma) is one such signaling polypeptide. Its primary molecular effect is activation of specific transcription factors that regulate gene expression in target cells. In this work, we present a molecular mechanism of lymphocyte-keratinocyte signaling in the epidermis. We have induced cutaneous delayed-type hypersensitivity reactions that are associated with an accumulation of lymphocytes. These resulted in activation and nuclear translocation of STAT-91, the IFN-gamma-activated transcription factor, in keratinocytes in vivo and subsequent induction of transcription of keratin K17. Within the promoter of the K17 keratin gene, we have identified and characterized a site that confers the responsiveness to IFN-gamma and that binds the transcription factor STAT-91. Other keratin gene promoters tested were not induced by IFN-gamma. These results characterize at the molecular level a signaling pathway produced by the infiltration of lymphocytes in skin and resulting in the specific alteration of gene expression in keratinocytes.

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. Using of inhibitors and antisense oligonucleotides, we found that in keratinocytes only UVB/UVC activate JNK, while in other cell types UVA, heat shock, and oxidative stress do as well. Keratinocytes express JNK-1 and JNK-3, which is unexpected because JNK-3 expression is considered brain-specific. In keratinocytes, ERK1, ERK2, and p38 are activated by growth factors, but not by UV. UVB/UVC in keratinocytes activates Elk1 and AP1 exclusively through the JNK pathway. JNKK1 is essential for UVB/UVC activation of JNK in keratinocytes in vitro and in human skin in vivo. In contrast, in HeLa cells, used as a control, crosstalk among signal transduction pathways allows considerable laxity. In parallel, UVB/UVC and TNFalpha activate the NFkappaB pathway via distinct mechanisms, as shown using antisense oligonucleotides targeted against IKKbeta, the active subunit of IKK. This implies a specific UVB/UVC responsive signal transduction pathway independent from other pathways. Our results suggest that in epidermal keratinocytes specific signal transduction pathways respond to UV light. Based on these findings, we propose that the UV light is not a genetic stress response inducer in these cells, but a specific agent to which epidermis developed highly specialized responses.

Purification and characterization of Aspergillus niger exo-1,4-glucosidase

A specific exo-1,4-glucosidase (1,4-alpha-D-glucan glucohydrooase, EC 3.2.1.3) from Aspergillus niger has been partially purified and subsequently characterized by biochemical, physico-chemical and optical methods. Molecular sieve chromatography yields an enzyme with maximal activity at pH 4.2-4.5 close to its isoelectric point. Reduction and carboxymethylation leads to complete loss of activity and O-acetylation of 3 of the 13 tyrosine residues results in loss of 20 % of the activity. Sodium dodecylsulfate-polyacrylamide gel electrophoresis indicates that the native enzyme consists of two major components of molecular weights 63 000 and 57 500, respectively. Small amounts of dissociated material of molecular weight 28 000 and 16 000 as well as aggregates of the order of 100 000 are also present to the extent of 2-5% of the total potein. Following reduction and carboxymethylation under forcing conditions, the bands around 60 000 diminish and the 28 000-30 000, 16 000 and aggregate bands are dominant...

Mammalian epidermal keratin Isolation and characterization of the α-helical proteins from newborn rat

Neutral buffer-insoluble proteins extracted from newborn rat epidermis with alkaline urea have been purified by chromatography on Sephadex G-150 columns run in the presence of sodium dodecyl sulfate. Two proteins with apparent molecular weights of 60 000 and 68 000, respectively have been isolated and characterized. Spectropolarimetric studies show both of them to be alpha-helical in contrast to the non-helical heavier and lighter species also solubilized with alkaline urea. The amino acid composition of the two proteins, their electrophoretic behavior and their immunological characteristics are essentially identical. Both proteins appear to be major constituents of rat epidermal tonofilaments.

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. However KGF, unlike EGF and TGF beta, allows keratinocytes to differentiate normally. With this in mind, we sought to determine whether KGF may be involved in keratinocyte differentiation through a mechanism that does not involve regulation of keratin gene expression. We transfected human epidermal keratinocytes with ten different keratin gene promoters linked to a reporter gene, and grew the transfected cells in the presence or absence of KGF. Interestingly, no significant change in keratin gene regulation was observed in the presence of KGF relative to control. The possibility that KGF influences the induction of keratin gene expression by other keratinocyte modulators, such as EGF, TGF beta and gamma interferon (IFN gamma), was also explored. In these experiments, the transformed keratinocytes were exposed simultaneously to KGF and another modulator. KGF did not significantly change the effects of EGF, TGF beta or IFN gamma on keratin gene expression. KGFs lack of ability to directly regulate keratin gene expression suggests that KGF affects keratinocyte growth and differentiation through a pathway independent of keratin gene regulation. These results illustrate that regulation of keratinocyte proliferation can be separated from the regulation of keratin gene expression.(ABSTRACT TRUNCATED AT 250 WORDS)