Differential effects of NF-kappaB on apoptosis induced by DNA-damaging agents: the type of DNA damage determines the final outcome.

The transcription factor nuclear factor kappa-B (NF-kappaB) is generally regarded as an antiapoptotic factor. Accordingly, NF-kappaB activation inhibits death ligand-induced apoptosis. In contrast, ultraviolet light B (UVB)-induced apoptosis is not inhibited but even enhanced upon NF-kappaB activation by interleukin-1 (IL-1). This study was performed to identify the molecular mechanisms underlying this switch of NF-kappaB. Enhancement of UVB-induced apoptosis was always associated with increased release of tumour necrosis factor-alpha (TNF-alpha), which was dependent on NF-kappaB activation. The same was observed when UVA and cisplatin were used, which like UVB induce base modifications. In contrast, apoptosis caused by DNA strand breaks was not enhanced by IL-1, indicating that the type of DNA damage is critical for switching the effect of NF-kappaB on apoptosis. Surprisingly, activated NF-kappaB induced TNF-alpha mRNA expression in the presence of all DNA damage-inducing agents. However, in the presence of DNA strand breaks, there was no release of the TNF-alpha protein, which is so crucial for enhancing apoptosis. Together, this indicates that induction of DNA damage may have a significant impact on biological effects but it is the type of DNA damage that determines the final outcome. This may have implications for the role of NF-kappaB in carcinogenesis and for the application of NF-kappaB inhibitors in anticancer therapy.

Apoptosis induced by disruption of the actin cytoskeleton is mediated via activation of CD95 (Fas/APO-1).

Activation of the death receptor CD95 by its ligand or by UV radiation is associated with receptor clustering. The mechanism underlying this clustering is mostly unclear. Here we show that although disruption of the actin cytoskeleton by cytochalasin B (CyB) itself induces moderate apoptosis, it enhances apoptosis in HeLa cells induced either by UV radiation or an agonistic anti-CD95 antibody. CyB augments UV-induced apoptosis independently of UV-mediated DNA damage, since induction of DNA repair by exogenous DNA repair enzymes did not alter its enhancing effect. Inhibition of caspase-8, the most upstream caspase in CD95 signaling, blocked the apoptotic effect of CyB and the enhancing effect on UV- and CD95-induced apoptosis. Confocal laser scanning microscopy revealed that (i) CyB induces CD95 clustering, (ii) enhances UV-induced CD95 clustering, and (iii) CD95 clusters colocalize with disrupted actin filaments, suggesting a link between receptor clustering and actin rearrangement. Disruption of CD95 signaling by a dominant negative mutant of the signaling protein FADD protected from CyB-induced apoptosis and prevented the UV-enhancing effect. Accordingly, both the apoptotic and the enhancing effect of CyB was reduced in epidermal cells obtained from CD95 deficient mice (lpr) when compared to wild-type mice. These data suggest that disruption of the cytoskeleton causes apoptosis via activation of CD95 and enhances UV-induced apoptosis, possibly via aiding receptor clustering.

Ultraviolet radiation-induced interleukin 6 release in HeLa cells is mediated via membrane events in a DNA damage-independent way.

Evidence exists that ultraviolet radiation (UV) affects molecular targets in the nucleus or at the cell membrane. UV-induced apoptosis was found to be mediated via DNA damage and activation of death receptors, suggesting that nuclear and membrane effects are not mutually exclusive. To determine whether participation of nuclear and membrane components is also essential for other UV responses, we studied the induction of interleukin-6 (IL-6) by UV. Exposing HeLa cells to UV at 4 degrees C, which inhibits activation of surface receptors, almost completely prevented IL-6 release. Enhanced repair of UV-mediated DNA damage by addition of the DNA repair enzyme photolyase did not affect UV-induced IL-6 production, suggesting that in this case membrane events predominant over nuclear effects. UV-induced IL-6 release is mediated via NFkappaB since the NFkappaB inhibitor MG132 or transfection of cells with a super-repressor form of the NFkappaB inhibitor IkappaB reduced IL-6 release. Transfection with a dominant negative mutant of the signaling protein TRAF-2 reduced IL-6 release upon exposure to UV, indicating that UV-induced IL-6 release is mediated by activation of the tumor necrosis factor receptor-1. These data demonstrate that UV can exert biological effects mainly by affecting cell surface receptors and that this is independent of its ability to induce nuclear DNA damage.

Nuclear and cell membrane effects contribute independently to the induction of apoptosis in human cells exposed to UVB radiation.

UVB-induced DNA damage is a crucial event in UVB-mediated apoptosis. On the other hand, UVB directly activates death receptors on the cell surface including CD95, implying that UVB-induced apoptosis can be initiated at the cell membrane through death receptor clustering. This study was performed to measure the relative contribution of nuclear and membrane effects in UVB-induced apoptosis of the human epithelial cell line HeLa. UVB-mediated DNA damage can be reduced by treating cells with liposomes containing the repair enzyme photolyase followed by exposure to photoreactivating light. Addition of photolyase followed by photoreactivation after UVB reduced the apoptosis rate significantly, whereas empty liposomes had no effect. Likewise, photoreactivating treatment did not affect apoptosis induced by the ligand of CD95, CD95L. UVB exposure at 4 degrees C, which prevents CD95 clustering, also reduced the apoptosis rate, but to a lesser extent. When cells were exposed to UVB at 4 degrees C and treated with photolyase plus photoreactivating light, UVB-induced apoptosis was almost completely prevented. Inhibition of caspase-3, a downstream protease in the CD95 signaling pathway, blocked both CD95L and UVB-induced apoptosis, whereas blockage of caspase-8, the most proximal caspase, inhibited CD95L-mediated apoptosis completely, but UVB-induced apoptosis only partially. Although according to these data nuclear effects seem to be slightly more effective in mediating UVB-induced apoptosis than membrane events, both are necessary for the complete apoptotic response. Thus, this study shows that nuclear and membrane effects are not mutually exclusive and that both components contribute independently to a complete response to UVB.

Interleukin-1 protects transformed keratinocytes from tumor necrosis factor-related apoptosis-inducing ligand.

Tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) is a member of the tumor necrosis factor family. It induces apoptosis primarily of transformed but not of normal cells and may therefore be a promising anti-cancer drug. Studying the role of TRAIL in apoptosis of keratinocytes, we detected TRAIL transcripts and protein in both normal human keratinocytes and transformed keratinocyte cell lines HaCaT and KB. Although normal keratinocytes were resistant to TRAIL, HaCaT and KB cells underwent apoptosis following TRAIL exposure. When HaCaT and KB cells were pretreated with the pro-inflammatory cytokine interleukin-1 (IL-1), cells became resistant to TRAIL-induced apoptosis. IL-1 significantly induced activation of the transcription factor NFkappaB in transformed keratinocytes. Moreover, the proteasome inhibitor MG132, which inhibits IL-1-induced NFkappaB activation, completely prevented the protective effect of IL-1. Thus, IL-1 appears to protect transformed keratinocytes from the cytotoxic effect of TRAIL via activation of NFkappaB. These data suggest that NFkappaB activation may protect cells from TRAIL-induced apoptosis and indicate a TRAIL receptor-independent pathway, which allows cells to escape the cytotoxic effect of TRAIL. Because IL-1 is secreted by a variety of tumor cells and is also released by inflammatory cells participating in the tumor-host immune response, tumors under these conditions could become resistant to TRAIL.

Ultraviolet light induces apoptosis via direct activation of CD95 (Fas/APO-1) independently of its ligand CD95L.

Induction of apoptosis in keratinocytes by UV light is a critical event in photocarcinogenesis. Although p53 is of importance in this process, evidence exists that other pathways play a role as well. Therefore, we studied whether the apoptosis-related surface molecule CD95 (Fas/APO-1) is involved. The human keratinocyte cell line HaCaT expresses CD95 and undergoes apoptosis after treatment with UV light or with the ligand of CD95 (CD95L). Incubation with a neutralizing CD95 antibody completely prevented CD95L-induced apoptosis but not UV-induced apoptosis, initially suggesting that the CD95 pathway may not be involved. However, the protease CPP32, a downstream molecule of the CD95 pathway, was activated in UV-exposed HaCaT cells, and UV-induced apoptosis was blocked by the ICE protease inhibitor zVAD, implying that at least similar downstream events are involved in CD95- and UV-induced apoptosis. Activation of CD95 results in recruitment of the Fas-associated protein with death domain (FADD) that activates ICE proteases. Immunoprecipitation of UV-exposed HaCaT cells revealed that UV light also induces recruitment of FADD to CD95. Since neutralizing anti-CD95 antibodies failed to prevent UV-induced apoptosis, this suggested that UV light directly activates CD95 independently of the ligand CD95L. Confocal laser scanning microscopy showed that UV light induced clustering of CD95 in the same fashion as CD95L. Prevention of UV-induced CD95 clustering by irradiating cells at 10 degrees C was associated with a significantly reduced death rate. Together, these data indicate that UV light directly stimulates CD95 and thereby activates the CD95 pathway to induce apoptosis independently of the natural ligand CD95L. These findings further support the concept that UV light can affect targets at the plasma membrane, thereby even inducing apoptosis.

Transforming growth factor-alpha induces interleukin-6 in the human keratinocyte cell line HaCaT mainly by transcriptional activation.

There is ample evidence that several cytokines, including transforming growth factor-alpha (TGF-alpha), interleukin (IL)-6, and IL-8 are upregulated in psoriasis, suggesting a pathogenic role for these cytokines. The sequence of these events, however, has not been elucidated. Recently it has been reported that TGF-alpha induces IL-6 in thymocytes through posttranscriptional regulation; therefore, we were interested in whether TGF-alpha can also induce IL-6 in human keratinocytes. Thus, we stimulated the human keratinocyte cell line HaCaT with TGF-alpha and tested supernatants for IL-6 activity. TGF-alpha resulted in a significant induction of the release of IL-6. This was also confirmed by northern blot analysis, which revealed a transient increase in IL-6 mRNA. This increase was unlikely due to enhanced mRNA stability, because we could not observe induction of IL-6 -specific transcripts by TGF-alpha in the presence of actinomycin D. To determine whether IL-6 induction by TGF-alpha is transcriptionally regulated, we transfected fragments of the IL-6 upstream region, subcloned into a plasmid just upstream of the chloramphenicol acetyl transferase coding region, into HaCaT cells. A 238-bp fragment and a 123-bp fragment, both containing nuclear factor (NF)-IL-6 and NFkappaB sites, exhibited significant induction of chloramphenicol acetyl transferase activity upon treatment with TGF-alpha. Because IL-6 transcription is known to be regulated by activation of NFkappaB and NF-IL-6, we analyzed the activation of these DNA-binding proteins by electrophoretic mobility shift assays. NF-IL-6 binding to a 32P-labeled NF-IL-6 binding sequence was enhanced 20 min after TGF-alpha stimulation and returned to basal levels within 90 min, whereas NFkappaB binding activity was enhanced after 20 min and returned to normal 60 min after stimulation. We conclude that TGF-alpha induces IL-6 in HaCaT cells and, in contrast to thymocytes, may do so by transcriptional activation, possibly through activation of NFkappaB and NF-IL-6.