AKT delays the early-activated apoptotic pathway in UVB-irradiated keratinocytes via BAD translocation.

Upon irradiation with a high dose of UVB, keratinocytes undergo apoptosis as a protective mechanism. In previous work, we demonstrated the existence of an early-activated UVB-induced apoptotic pathway in growth factor-depleted human keratinocytes, which can be substantially delayed by the exclusive supplementation of IGF-1. We now show that in human keratinocytes, IGF-1 inhibits the onset of UVB-triggered apoptosis through a transcriptional independent, AKT-mediated mechanism, involving BAD serine 136 phosphorylation. Our results show that the early UVB-induced apoptosis in growth factor-depleted human keratinocytes is exclusively triggered through the mitochondrial pathway. It is accompanied by BAX translocation, cytochrome c release, and procaspase-9 cleavage, but not by procaspase-8 or BID cleavage. In human keratinocytes, IGF-1 supplementation inhibits these events in a transcription-independent manner. Both IGF-1 supplementation and the transduction of a membrane-targeted form of AKT result in a shift of the BH3-only protein BAD from the mitochondria to the cytoplasm, paralleled by an increase of AKT-specific Ser136 phospho-BAD bound to 14-3-3zeta protein. These data indicate that AKT-induced BAD phosphorylation and its subsequent cytoplasmic sequestration by 14-3-3zeta is a major mechanism responsible for the postponement of UVB-induced apoptosis in human keratinocytes.

A low UVB dose, with the potential to trigger a protective p53-dependent gene program, increases the resilience of keratinocytes against future UVB insults.

One protein central in the response of human keratinocytes to ultraviolet B damage is p53. By transactivating genes involved in either cell cycle arrest or DNA repair, p53 has a leading role in the recovery from this damage. Considering this role, we wished to investigate whether the triggering of a p53-dependent gene program by repetitive ultraviolet B (UVB) exposure can induce an adaptive response in human skin cells. In particular, we examined two p53-target genes, p21/WAF1 and p53R2, with a crucial role in p53-induced cell cycle arrest and p53-induced DNA repair respectively. Exposure to a mild UVB dose was able to induce an adaptive response in human keratinocytes, leading to increased survival of cells that maintain their capacity to repair DNA damage upon exposure to apoptotic doses of UVB. Our study indicates that this adaptation response is only achieved if the interval between subsequent UVB insults allows sufficient time for the p53-induced protective gene program to be induced. Our results also demonstrate that small but quickly recurring UVB exposures are as harmful as one intense, continual exposure to UVB irradiation. Future research will be oriented toward investigating alternative ways to induce an adaptive response without pre-exposing the cells to UV.

AKT status controls susceptibility of malignant keratinocytes to the early-activated and UVB-induced apoptotic pathway.

In previous work, we have described an early-activated and ultraviolet B (UVB)-induced apoptotic pathway in human keratinocytes, which can be completely inhibited by AKT activation. We now compared this response of primary human keratinocytes with the response of two p53-mutated squamous cell carcinoma (SCC)-derived cell lines (A431 and A253) to an apoptotic UVB dose. In these cell lines, both the basal AKT phosphorylation status and the apoptotic response to UVB diverged strongly from the response of healthy primary keratinocytes. Even more, a remarkable correlation was found between the two. Although a constitutive dual phosphorylation of AKT rendered the A253 SCC cell line completely resistant to the early-activated and UVB-induced apoptotic pathway, deficient T308 phosphorylation of AKT in the SCC cell line A431 led to a greatly augmented sensitivity to the early-activated, UVB-induced apoptotic pathway. These results indicate that the preservation of a healthy AKT pathway is essential for a wild-type UVB-induced apoptotic response in skin, and suggest that AKT-mediated dysregulation of the early-activated apoptotic response to UVB is an important event in the oncogenic transformation of keratinocytes.

A synthetic superoxide dismutase/catalase mimetic (EUK-134) inhibits membrane-damage-induced activation of mitogen-activated protein kinase pathways and reduces p53 accumulation in ultraviolet B-exposed primary human keratinocytes.

Salen-manganese complexes exhibit powerful superoxide dismutase and catalase activity, with pharmacologic efficacy in several oxidative-stress-associated disease models. Ultraviolet (UV) B not only induces direct DNA damage, but also generates oxidative stress. EUK-134, a salen-manganese complex, might therefore confer a direct protection against UVB-induced oxidative stress and consequently alleviate UVB-damage-induced signal transduction. We investigated the effect of EUK-134 on the UVB-induced accumulation and stabilization of the p53 protein. p53 plays a central role in the UVB response, both as sensor of UVB damage and as a mediator of a protective response. Cells treated with EUK-134 before UVB irradiation showed a significantly lower accumulation of the p53 protein in a concentration-dependent fashion. Furthermore, EUK-134 severely reduced N-terminal phosphorylation of p53. The extracellular signal-regulated kinase ERK and the stress-activated kinases JNK and p38 have been implicated in the UVB-induced N-terminal phosphorylation and accumulation of p53. Pre-treatment with EUK-134 inhibited the UVB-induced activation of these mitogen-activated protein kinase (MAPK) pathways. We hypothesize that EUK-134, by direct protection of the membrane from UVB-induced oxidative damage, reduces oxidative stress induced MAPK signaling and consequently lowers the level of p53 induction. The protection conferred by EUK-134 resulted in a significant increase in cell survival following UVB irradiation.

Insulin-like growth factor-1-mediated AKT activation postpones the onset of ultraviolet B-induced apoptosis, providing more time for cyclobutane thymine dimer removal in primary human keratinocytes.

Insulin-like growth factor-1 (IGF-1) acts as a potent survival factor in numerous cell lines, primarily through activation of the AKT signaling pathway. Although some targets of this pathway have known anti-apoptotic functions, its relationship with the improved survival of cells after exposure to environmental stresses, including UVB, remains largely unclear. We report that in growth factor-deprived keratinocytes, IGF-1 significantly and consistently delayed the onset of UVB-induced apoptosis by >7 h. This delay allowed IGF-1-supplemented keratinocytes to repair significantly more cyclobutane thymine dimers than their growth factor-deprived counterparts. This increase in cyclobutane thymine removal resulted in enhanced survival if the amount of DNA damage was not too high. To increase cell survival after UVB irradiation, IGF-1 supplementation was required only during this initial time period in which extra repair was executed. Finally, we show that IGF-1 mediated this delay in the onset of UVB-induced apoptosis through activation of the AKT signaling pathway. We therefore believe that the AKT signaling pathway increases cell survival after a genotoxic insult such as UVB irradiation not by inhibiting the apoptotic stimulus, but only by postponing the induction of apoptosis, giving the DNA repair mechanism more time to work.