In vivo effects of abolishing the single canonical sumoylation site in the C-terminal region of Drosophila p53.

Using yeast two-hybrid screens we determined that Drosophila (Dm)p53 interacts with proteins involved in sumoylation (UBA2, UBC9 and PIAS) through different regions of its C-terminal domain. A K302R point mutation within a single canonical sumoylation site of Dmp53 did not abolish the observed interactions. These observations prompted us to analyze whether Dmp53 sumoylation at this site has any functional role in vivo. Genetic assays showed that deleting one copy of genes involved in sumoylation (lwr, Su(var)2-10 or smt3 heterozygosity) enhanced slightly the mutator phenotype of Dmp53. We compared the in vivo effects of wild type and K302R Dmp53 overproduced from transgenes and determined that similar levels of expression of the mutant and wild type proteins resulted in similar phenotype, and the two proteins showed similar cellular localization. The half life and the trans-activator activity of K302R mutant and wild type Dmp53 were also comparable. Lastly, by analyzing wild type and K302R Dmp53 expressed at different levels in animals and in S2 cells we detected no differences between the mobility of the mutant and wild-type protein. From these data we conclude that under normal developmental conditions the loss of SUMO modification at K302 does not affect Dmp53 function significantly.

Genes of the ecdysone biosynthesis pathway are regulated by the dATAC histone acetyltransferase complex in Drosophila.

Uncovering mechanisms that regulate ecdysone production is an important step toward understanding the regulation of insect metamorphosis and processes in steroid-related pathologies. We report here the transcriptome analysis of Drosophila melanogaster dAda2a and dAda3 mutants, in which subunits of the ATAC acetyltransferase complex are affected. In agreement with the fact that these mutations lead to lethality at the start of metamorphosis, both the ecdysone levels and the ecdysone receptor binding to polytene chromosomes are reduced in these flies. The cytochrome genes (spookier, phantom, disembodied, and shadow) involved in steroid conversion in the ring gland are downregulated, while the gene shade, which is involved in converting ecdysone into its active form in the periphery, is upregulated in these dATAC subunit mutants. Moreover, driven expression of dAda3 at the site of ecdysone synthesis partially rescues dAda3 mutants. Mutants of dAda2b, a subunit of the dSAGA histone acetyltransferase complex, do not share phenotype characteristics and RNA profile alterations with dAda2a mutants, indicating that the ecdysone biosynthesis genes are regulated by dATAC, but not by dSAGA. Thus, we provide one of the first examples of the coordinated regulation of a functionally linked set of genes by the metazoan-specific ATAC complex.

Endogenous phospholipid metabolite containing topical product inhibits ultraviolet light-induced inflammation and DNA damage in human skin.

BACKGROUND: N-palmitoylethanolamine (PEA) and organic osmolytes are endogenous components of the human epidermis and are generated from phospholipids in the stratum granulosum. PEA has been shown to exert potent antioxidant and anti-inflammatory activities. The endogenous organic osmolytes such as betaine and sarcosine control skin humidity, but have also been shown to inhibit ultraviolet (UV) light-induced oxidative stress in keratinocytes. OBJECTIVES: To investigate the effect of a PEA- and organic osmolyte-containing topical product (Physiogel AI) on the development of UV light-induced erythema, thymine dimer formation and p53 tumor suppressor gene activation, as well as intercellular adhesion molecule 1 (ICAM-1) and Ki67 expression in normal human skin. METHODS: The UV-induced erythema was measured by a spectrofluorometric method. Thymine dimers, p53, ICAM-1 and Ki67 were detected in skin biopsies using immunohistochemistry. RESULTS: Physiogel AI cream significantly inhibited the development of UV light-induced erythema and thymine dimer formation in normal human skin, but did not alter the number of Ki67+ proliferating keratinocytes and the expression of p53 and ICAM-1. CONCLUSIONS: Our results suggest that PEA and organic osmolytes might represent a new generation of compounds which suppress UV-induced photodamage.

Treatment of atopic dermatitis with the xenon chloride excimer laser.

BACKGROUND: Narrow-band ultraviolet B phototherapy is an effictive and safe treatment for atopic dermatitis. We have previously found that the 308 nm xenon chloride excimer laser was more effective than the narrow-band ultraviolet B light for the treatment of psoriasis, suggesting that ultraviolet B laser might offer advantages over narrow-band ultraviolet B. OBJECTIVE: The purpose of this study was to evaluate the therapeutic efficacy of the 308 nm excimer laser in atopic dermatitis. PATIENTS AND METHODS: Fifteen patients with atopic dermatitis (less than 20% body area involvement) were treated with a xenon chloride excimer laser (XTRAC laser, Photomedex Inc.) twice weekly. The severity of the atopic dermatitis was assessed via (i) a clinical score characterizing the intensity of erythema, infiltration, lichenification and excoriation; (ii) the quality of life, determined by means of a questionnaire; and (iii) a visual linear analogue scale, with which the patients scored the severity of their pruritus. RESULTS: After 1 month of laser therapy, the clinical scores were significantly lower than the initial values. Similar decreases were observed for the quality of life and pruritus scores. No serious or unpleasant side-effects were observed. CONCLUSION: These results suggest that the xenon chloride excimer laser is an effective and well-tolerated treatment for localized atopic dermatitis.

Budesonide, but not tacrolimus, affects the immune functions of normal human keratinocytes.

Topical immunosuppressant therapy is widely used in the treatment of inflammatory skin diseases such as psoriasis and atopic dermatitis. Besides its beneficial therapeutic effects, application of topical anti-inflammatory drugs may render the epidermis more vulnerable to invading pathogens by suppressing innate immune responses in keratinocytes, such as cytokine production and Toll-like receptor (TLR) expression. In order to evaluate and compare the immunosuppressive effects of different immunosuppressant drugs on keratinocytes, we treated lipopolysaccharide (LPS)-stimulated and -unstimulated normal human keratinocytes with the synthetic corticosteroid budesonide and the macrolide tacrolimus. The expressions of the pattern recognition receptors (PRRs) TLR2 and TLR4 were measured by quantitative RT-PCR, pro-inflammatory cytokines IL-1alpha, IL-8 and TNF-alpha were monitored by quantitative RT-PCR and by ELISA, and alterations in TLR2 protein level were measured by flow cytometry. Budesonide had a suppressive effect on both constitutive and LPS-induced IL-8 gene expression. The amount of TNF-alpha mRNA was diminished in unstimulated keratinocytes, while TLR2 mRNA expression was markedly enhanced both in unstimulated and LPS-treated cells after incubation with budesonide. This increase in TLR2 mRNA expression was also detectable at the protein level in LPS-stimulated cells. Tacrolimus had no effect on any of the examined genes. Budesonide, but not tacrolimus, significantly inhibited the NF-kappaB-dependent luciferase reporter activity in HaCaT cells after induction with LPS or TNF-alpha. Although tacrolimus and budesonide are both effective treatments in some inflammatory skin diseases, the data provided here imply differences in local therapeutic and adverse effects of these two topical immunosuppressants.

Development of a novel, simple and rapid molecular identification system for clinical Candida species.

Identification of clinical yeast isolates causing candidiasis is routinely performed by commercial yeast identification systems based on biochemical, morphological and physiological tests. These systems require 3-5 days and the proportion of identifications that are incorrect is high. Our novel and rapid molecular identification system for clinical Candida species is based on the analysis of restriction patterns obtained from PCR-generated ribosomal DNA sequences using five restriction enzymes. A software package (CandID) was designed to include a database of restriction fragment length polymorphism (RFLP) patterns for 29 Candida species. For 'in-house' validation, 122 clinical isolates that had previously identified in clinical laboratories were typed by this system. These clinical isolates were also independently re-identified by the API 20C AUX system. The ribosomal DNA RFLP database in the context of supporting analytical software allowed simple and rapid (1 work day) identification.

Altered protein acetylation in polyglutamine diseases.

Polyglutamine diseases are hereditary neurodegenerative disorders caused by the expansion of a CAG repeat in the disease gene. A dominant gain of function is associated with these expanded alleles. The resulting elongated polyglutamine repeats are thought to cause structural changes in the affected proteins, leading to aberrant interactions such as those that allow formation of extra- and intranuclear aggregates. However, self-association is not the only interaction the polyglutamine domain is capable of mediating. Many cellular proteins can be sequestered into inclusions or bound by more soluble forms of the mutant proteins. One group of proteins that binds to and whose activity may be altered by polyglutamines is Histone Acetyltransferases (HATs). HATs are responsible for the acetylation of histones and several other important proteins and this modification results in altered function of the target protein. HATs regulate cellular processes at levels as different as modifying transcriptional competence of chromosomes, temporal regulation of promoter activity and protein activation / inactivation. Recent studies show that the altered balance between protein acetylation and deacetylation may be a key process contributing to expanded polyglutamine-induced pathogenesis. The restoration of this balance is possible by the genetic or pharmacological reduction of the opposing enzyme group, i.e. the Histone Deacetylases (HDACs). Recent progress in HDAC research has made the development of inhibitors of specific HDAC family proteins possible and these compounds could be effective candidates for treatment of these devastating diseases.

Histone deacetylase inhibitors arrest polyglutamine-dependent neurodegeneration in Drosophila.

Proteins with expanded polyglutamine repeats cause Huntington's disease and other neurodegenerative diseases. Transcriptional dysregulation and loss of function of transcriptional co-activator proteins have been implicated in the pathogenesis of these diseases. Huntington's disease is caused by expansion of a repeated sequence of the amino acid glutamine in the abnormal protein huntingtin (Htt). Here we show that the polyglutamine-containing domain of Htt, Htt exon 1 protein (Httex1p), directly binds the acetyltransferase domains of two distinct proteins: CREB-binding protein (CBP) and p300/CBP-associated factor (P/CAF). In cell-free assays, Httex1p also inhibits the acetyltransferase activity of at least three enzymes: p300, P/CAF and CBP. Expression of Httex1p in cultured cells reduces the level of the acetylated histones H3 and H4, and this reduction can be reversed by administering inhibitors of histone deacetylase (HDAC). In vivo, HDAC inhibitors arrest ongoing progressive neuronal degeneration induced by polyglutamine repeat expansion, and they reduce lethality in two Drosophila models of polyglutamine disease. These findings raise the possibility that therapy with HDAC inhibitors may slow or prevent the progressive neurodegeneration seen in Huntington's disease and other polyglutamine-repeat diseases, even after the onset of symptoms.