p38 mitogen-activated protein kinase (MAPK) mediates cellular responses to injurious stress and immune signaling. Among the multiple p38 isoforms, p38α is the most widely expressed in adult tissues and can be targeted by various pharmacological inhibitors. Here we investigated how p38α activation is linked to cell type-specific outputs using mouse models of cutaneous inflammation. We showed that both myeloid and epithelial p38α can signal to evoke inflammatory responses, yet the mode of skin irritation determines the cell type in which p38α serves the function. In addition, myeloid p38α induces self-limitation of acute inflammation via activation of MSK-dependent anti-inflammatory gene expression. These suggest a dual role of p38α in regulation of inflammation, and reveal a mixed potential for its inhibition as a therapeutic strategy.
Filamentous phage infection induces the synthesis of large amounts of an Escherichia coli protein, phage shock protein (Psp), the product of a previously undescribed gene. This induction is due to the phage gene IV protein, pIV, an integral membrane protein. The uninduced level of Psp is undetectable, but when induced by prolonged synthesis of pIV, it can become one of the most abundant proteins in the cell. Psp is also synthesized transiently in response to several stresses (heat, ethanol, and osmotic shock). High-level synthesis occurs only after extreme treatment. Unlike the members of the heat shock regulon, Psp induction does not require the heat shock sigma factor, sigma 32; some stimuli that elicit sigma 32-dependent heat shock proteins do not induce Psp synthesis. The level of Psp induction after extreme stress is even higher in sigma 32 mutant cells, which are unable to mount a normal heat shock response, suggesting that these parallel stress responses are interrelated.
Signaling pathways regulating the differentiation program of epidermal cells overlap widely with those activated during apoptosis. How differentiating cells remain protected from premature death, however, is still poorly defined. We show here that the phosphoinositide 3-kinase (PI3K)/Akt pathway is activated at early stages of mouse keratinocyte differentiation both in culture and in the intact epidermis in vivo. Expression of active Akt in keratinocytes promotes growth arrest and differentiation, whereas pharmacological blockade of PI3K inhibits the expression of "late" differentiation markers and leads to death of cells that would otherwise differentiate. Mechanistically, the activation of the PI3K/Akt pathway in keratinocyte differentiation depends on the activity of the epidermal growth factor receptor and Src families of tyrosine kinases and the engagement of E-cadherin-mediated adhesion. During this process, PI3K associates increasingly with cadherin-catenin protein complexes bearing tyrosine phosphorylated YXXM motifs. Thus, the PI3K signaling pathway regulates the choice between epidermal cell differentiation and death at the cross-talk between tyrosine kinases and cadherin-associated catenins.The epidermis is a self-renewing stratified epithelium in which the loss of terminally differentiated cells from its surface is balanced by cells that leave the proliferative basal layer and enter differentiation (1, 2). Because a metabolically dead cornified cell envelope is the end point of epidermal differentiation, this process may be viewed as a specialized form of programmed cell death (3). Moreover, the apoptotic program and keratinocyte differentiation share overlapping signaling effector mechanisms (4). Notably, the caspase-3 cysteine protease, an integral component of the cell death machinery, was implicated recently in embryonic keratinocyte differentiation control downstream of Notch1 (5), and activation of the related caspase-14 has been reported during adult keratinocyte differentiation (6). Nevertheless, "canonical" apoptosis and epidermal differentiation are distinct processes, with diverse execution times and biological outcomes; the former leads to the elimination of individual dead cells from tissues within hours, whereas the latter relies on the survival and synchronized maturation of whole sheets of cells over the course of weeks. Thus, an outstanding question is how keratinocytes can activate arrays of death-inducing signals during differentiation and yet remain protected from premature death.A candidate pathway for the survival of differentiating keratinocytes is the signaling module formed by the Class IA PI3K 4 and the downstream serine-threonine kinase Akt effectors (Akt/PKB-1, -2, and -3 isoforms) (7). The PI3K family is divided into three distinct classes (Class I, II, and III) based on primary structure, substrate specificity, and mode of regulation (8). Class I PI3Ks include four distinct p110 catalytic isoforms, further divided into Class IA (-␣, -, -␦) and IB (-␥); among these, p110...
Loss-of-function mutations in Whn (Hfh 11), a winged-helix/forkhead transcription factor, result in the nude mouse phenotype. To determine the whn expression pattern during development, we utilized mice in which a beta-galactosidase reporter gene was placed under the control of the wild-type whn promoter by homologous recombination (M. Nehls et al., 1996, Science 272, 886-889). Sites of reporter expression were confirmed by immunohistochemical staining for Whn protein or by in situ hybridization for whn mRNA. At all developmental stages, whn expression is restricted to epithelial cells. In addition to the skin and thymus, whn is expressed in the developing nails, nasal passages, tongue, palate, and teeth. In embryonic epidermis, suprabasal cells induce whn expression at the same time that terminal differentiation markers first appear. As the epidermis matures, whn promoter activity is found primarily in the first suprabasal layer, which contains keratinocytes in the early stages of terminal differentiation. In developing and mature anagen hair follicles, whn is expressed at high levels in the postmitotic precursor cells of the hair shaft and inner root sheath. Though principally associated with terminal differentiation, whn expression is also detected in progenitor cell compartments; in the hair bulb matrix and basal epidermal layer, a small subclass of cells expresses whn, while in the outer root sheath, whn promoter activity is induced as the follicle completes its elongation. Within these compartments, rare cells exhibit both whn expression and the nuclear proliferation marker Ki-67. The results suggest that whn expression encompasses the transition from a proliferative to a postmitotic state and that whn regulates the initiation of terminal differentiation.
The recent discovery of the human coun-terpart of the hairlessmousephenotype1has helped our understandingof the molecular genetics of hair growth.But there are no reports of a defect in thehuman homologue of the best known of the'bald' mouse phenotypes, the nudemouse2.This may be because affected individualsare so gravely ill from the accompanyingimmunodeficiency that their baldness goesunnoticed. We have carried out a geneticanalysis that reveals a human homologue ofthe nudemouse.The nudemouse is characterized by acongenital absence of hair and a severeimmunodeficiency2, resulting from muta-tions in the whn(winged-helix-nude;Hfh11nu) gene, which encodes a member ofthe forkhead/winged-helix transcriptionfactor family with restricted expression inthymus and skin3. The simultaneous occur-rence of severe functional T-cell immunodeficiency, congenital alopecia and nail dys-trophy (MIM database no. 601705) in twoaffected sisters led to the recognition thatthe clinical phenotype was reminiscent ofthe nudemouse4. We therefore investigatedwhether this syndrome represents thehuman counterpart of the nudemousephenotype.We obtained DNA samples from mem-bers of the sisters' family in a small villagein southern Italy. The affected sisters wereborn with a complete absence of scalp hair (Fig. 1a), eyebrows and eyelashes and haddystrophic nails, and no thymic shadow wasevident upon X-ray examination. The firstaffected child revealed a striking impair-ment of T-cell function shortly after birth,and died at the age of 12 months. Her sisterhad similar immunological abnormalities,but bonemarrow transplantation at fivemonths of age led to full immunologicalreconstitution, although the alopecia andnail dystrophy are still present4.We performed linkage analysis usingmicrosatellite markers near the humanWHNlocus on chromosome 17, and founda lod score of 1.32, suggestive of linkage. Wethen sequenced the human WHNgene5andfound a homozygous C-to-T transition atnucleotide position 792 of the WHNcDNA(GenBank accession no. Y11739) (Fig. 1b).This leads to a nonsense mutation atresidue 255 (R255X) in exon 5, and predictsthe complete absence of functional proteinas a result of nonsense-mediated decay ofmessenger RNA.Because the proband's bonemarrowtransplant was from her brother, we exam-ined her leukocyte DNA both before andafter the graft for the presence of chi-maerism. Genotyping the proband beforethe transplant showed that her leukocyteDNA was homozygous only for the mutantallele (Fig. 1c). Four years after the transplant, we detected the haplotype specific forthe wild-type paternal WHNallele receivedfrom the brother, as well as the mutantallele, indicative of chimaerism. Genderdetermination revealed that the proband'sleukocyte DNA was genotypically XXbefore the transplant, and the brother'sDNA was XY. Afterwards, the proband'sleukocyte DNA was found to be XY (Fig.1c), providing evidence of longtermengraftment and expansion of the bone-marrow graft.The WHNgene encodes a transcriptionfactor, which is developmentally regulatedand directs cel...
Mutations in the winged-helix nude (whn) gene result in the nude mouse and rat phenotypes. The pleiotropic nude phenotype which affects the hair, skin, and thymus suggests that whn plays a pivotal role in the development and/or maintenance of these organs. However, little is known about whn function in these organs. We show here that in skin whn is specifically expressed in epithelial cells and not the mesenchymal cells, and using a hair reconstitution assay, we demonstrate that the abnormal nude mouse hair development is attributable to a functional defect of the epithelial cells. Examination of nude mouse primary keratinocytes in culture revealed that these cells have an increased propensity to differentiate in an abnormal fashion, even under conditions that promote proliferation. Furthermore, nude mouse keratinocytes displayed a 100-fold increased sensitivity to the growth-inhibitory/differentiation effects of the phorbol ester TPA. In parallel with these findings, we directly show that whn functions as a transcription factor that can specifically suppress expression of differentiation/TPA-responsive genes. The region of Whn responsible for these effects was mapped to the carboxy-terminal transactivating domain. These results establish whn as a key regulatory factor involved in maintaining the balance between keratinocyte growth and differentiation. The general implications of these findings for an epithelial self-renewal model will be discussed.[Key Words: Whn; transcriptional factor; nude mouse; keratinocytes] Received June 3, 1996; revised version accepted July 12, 1996.The skin and its appendage, the hair follicle, provide excellent models for the study of the complex control mechanisms involved in organ morphogenesis and homeostasis. The formation and maintenance of the epidermis and the hair follicle, both self-renewing struc-
The phage shock protein (psp) operon of Escherichia coli is strongly induced in response to heat, ethanol, osmotic shock, and infection by filamentous bacteriophages. The operon contains at least four genes--pspA, pspB, pspC, and pspE--and is regulated at the transcriptional level. We report here that psp expression is controlled by a network of positive and negative regulatory factors and that transcription in response to all inducing agents is directed by the or-factor r s4. Negative regulation is mediated by both PspA and the r heat shock proteins. The PspB and PspC proteins cooperatively activate expression, possibly by antagonizing the PspA-controlled repression. The strength of this activation is determined primarily by the concentration of PspC, whereas PspB enhances but is not absolutely essential for PspC-dependent expression. PspC is predicted to contain a leucine zipper, a motif responsible for the dimerization of many eukaryotic transcriptional activators. PspB and PspC, though not necessary for psp expression during heat shock, are required for the strong psp response to phage infection, osmotic shock, and ethanol treatment. The psp operon thus represents a third category of transcriptional control mechanisms, in addition to the r 32-and erE-dependent systems, for genes induced by heat and other stresses.[Key Words: Phage shock protein; stress response; heat shock; cr54; filamentous bacteriophage; leucine zipper] Received June 20, 1991; revised version accepted August 15, 1991.Exposure to certain adverse environmental conditions, such as high temperature, causes all organisms to coordinately and vigorously induce the synthesis of a specific set of proteins called the heat shock proteins (HSPs; for reviews, see Lindquist and Craig 1988;Gross et al. 1990). This phenomenon, the heat shock response, is the product of perhaps the best conserved and most universal genetic network. Similarities in this response between prokaryotes and eukaryotes include the sequences of certain HSPs (e.g., the 90-, 70-, and 60-kD HSP families), the treatments that stimulate the response (e.g., heat, ethanol, heavy metal ions), and the large, rapid increases in heat shock gene transcription that follow environmental challenge. In Escherichia coli, previous work in several laboratories identified at least two mechanisms of transcriptional control for heat shock gene expression. Most of the detected heat shock genes (-17)
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