Differential roles for Chk1 and FANCD2 in ATR-mediated signalling for psoralen photoactivation-induced senescence.

Cellular senescence is a stress-inducible, naturally irreversible cell cycle arrest, which is likely linked with ageing. Premature ageing of the skin is a prominent side effect of psoralen photoactivation, which is used for the treatment of various skin disorders. Previously, we have shown that DNA interstrand crosslink formation by photoactivated psoralens induces a senescent phenotype in primary fibroblasts that is mediated by Ataxia telangiectasia-mutated and Rad3-related (ATR) kinase. Checkpoint kinase 1 (Chk1) initiates cell cycle checkpoints, and FANCD2 is known to be involved in DNA damage-induced S-phase arrest and crosslink repair. In this study, we examined a role for Chk1 and FANCD2 as downstream effectors of ATR in senescence signalling. We demonstrate that Chk1 and FANCD2 are long-lastingly activated after psoralen photoactivation. Separate and combined reduction in Chk1 and FANCD2 expression by small interfering RNA (siRNA) preceding irradiation partly prevented the initiation of the senescence-like phenotype, whereas siRNA (Chk1 and FANCD2) transfection of senesced fibroblasts released cells from growth arrest. We observed that Chk1 and FANCD2 signal equally and additively for senescence induction, while Chk1 is predominantly responsible for maintaining persistent cell cycle arrest. In conclusion, Chk1 and FANCD2 function downstream of ATR in a non-redundant manner for the establishment and maintenance of psoralen photoactivation-induced senescence.

Pyoderma gangrenosum following cardiac surgery.

Pyoderma gangrenosum appeared in multiple incision sites after coronary bypass surgery.

Conserved interactions of the splicing factor Ntr1/Spp382 with proteins involved in DNA double-strand break repair and telomere metabolism.

The ligation of DNA double-strand breaks in the process of non-homologous end-joining (NHEJ) is accomplished by a heterodimeric enzyme complex consisting of DNA ligase IV and an associated non-catalytic factor. This DNA ligase also accounts for the fatal joining of unprotected telomere ends. Hence, its activity must be tightly controlled. Here, we describe interactions of the DNA ligase IV-associated proteins Lif1p and XRCC4 of yeast and human with the putatively orthologous G-patch proteins Ntr1p/Spp382p and NTR1/TFIP11 that have recently been implicated in mRNA splicing. These conserved interactions occupy the DNA ligase IV-binding sites of Lif1p and XRCC4, thus preventing the formation of an active enzyme complex. Consistently, an excess of Ntr1p in yeast reduces NHEJ efficiency in a plasmid ligation assay as well as in a chromosomal double-strand break repair (DSBR) assay. Both yeast and human NTR1 also interact with PinX1, another G-patch protein that has dual functions in the regulation of telomerase activity and telomere stability, and in RNA processing. Like PinX1, NTR1 localizes to telomeres and associates with nucleoli in yeast and human cells, suggesting a function in localized control of DSBR.

Mitochondrial electron transport chain activity is not involved in ultraviolet A (UVA)-induced cell death.

Ultraviolet A (UVA), the long wavelength part of the sun's ultraviolet radiation, elicits its harmful effects through production of reactive oxygen species. In this study, we have tested the hypothesis that the mitochondrial electron transport chain, the main source of reactive oxygen species in cells, importantly contributes to UVA-induced cell damage. Model cell lines completely lacking a mitochondrial electron transport chain (rho(0)-cells) were not protected against UVA-induced cell death. Also, primary human fibroblasts and keratinocytes with induced depletion of electron transport chain activity were not better protected against UVA-induced cell death. On the other hand, diphenyleneiodonium and resiniferatoxin, inhibitors of plasma membrane oxidases, protected primary human fibroblasts against UVA, as potently as the lipid peroxidation chain breaker Trolox. These data indicate that plasma membrane electron transport systems, but not the mitochondrial electron transport chain, play a major role in UVA-induced cell death.

Senescence of human fibroblasts after psoralen photoactivation is mediated by ATR kinase and persistent DNA damage foci at telomeres.

Cellular senescence is a phenotype that is likely linked with aging. Recent concepts view different forms of senescence as permanently maintained DNA damage responses partially characterized by the presence of senescence-associated DNA damage foci at dysfunctional telomeres. Irradiation of primary human dermal fibroblasts with the photosensitizer 8-methoxypsoralen and ultraviolet A radiation (PUVA) induces senescence. In the present study, we demonstrate that senescence after PUVA depends on DNA interstrand cross-link (ICL) formation that activates ATR kinase. ATR is necessary for the manifestation and maintenance of the senescent phenotype, because depletion of ATR expression before PUVA prevents induction of senescence, and reduction of ATR expression in PUVA-senesced fibroblasts releases cells from growth arrest. We find an ATR-dependent phosphorylation of the histone H2AX (gamma-H2AX). After PUVA, ATR and gamma-H2AX colocalize in multiple nuclear foci. After several days, only few predominantly telomere-localized foci persist and telomeric DNA can be coimmunoprecipitated with ATR from PUVA-senesced fibroblasts. We thus identify ATR as a novel mediator of telomere-dependent senescence in response to ICL induced by photoactivated psoralens.

Complete remission of Merkel cell carcinoma of the scalp with local and regional metastases after topical treatment with dinitrochlorbenzol.

Merkel cell carcinoma (MCC) is a highly aggressive tumor with a high percentage of recurrence, metastatic spread, and mortality. Treatment of metastasized MCC is not standardized and prognosis of metastasized MCC is often poor. Current protocols recommend surgery, adjuvant radiation therapy, and often lymph node dissection to prevent recurrences. A few sporadic reports of spontaneous regression of MCC suggest a so far not yet characterized role and potential of the immune system in controlling this tumor. We describe a 69-year-old man with extended inoperable MCC of the scalp including multiple local and regional metastases who responded with complete remission to 4 weekly treatments of topically applied immune-modulating dinitrochlorbenzol. Together with subsequent irradiation, remission has now lasted for more than 1 year.

Human dermal fibroblasts escape from the long-term phenocopy of senescence induced by psoralen photoactivation.

We have previously shown that following psoralen photoactivation (PUVA treatment) human dermal fibroblasts undergo long-term growth arrest as well as morphological and functional changes reminiscent of cellular senescence [ 1 ]. In the absence of molecular data on what constitutes normal senescence, it has been difficult to decide whether these PUVA-induced changes reflect cellular senescence or rather a mimic thereof. We herein report that PUVA-induced growth arrest, the senescent phenotype with long-term induction of senescence-associated beta-galactosidase, as well as increased expression of matrix metalloprotease-1 are fully reversible at days 100 to 130 post PUVA treatment in four independently tested fibroblast strains. The late returning growth capacity in PUVA-treated fibroblasts is not due to immortalization, as shown by continued lack of telomerase activity, accelerated telomere shortening, and a decrease in overall growth rates in fibroblasts in their regrowing phase post PUVA treatment. Lack of anchorage-independent growth additionally suggests that the cells are also not tumorigenically transformed. Collectively, our data suggest that PUVA-induced changes do not fully reflect replicative senescence but rather represent a long-term transient phenocopy of senescence. The model reported here is particularly suited to elucidating mechanisms underlying long-term transient growth arrest, the related functional changes, and the release of cells thereof.