Ultraviolet (UV) light induces specific mutations in the cellular and skin genome such as UV-signature and triplet mutations, the mechanism of which has been thought to involve translesion DNA synthesis (TLS) over UV-induced DNA base damage. Two models have been proposed: "error-free" bypass of deaminated cytosine-containing cyclobutane pyrimidine dimers (CPDs) by DNA polymerase η, and error-prone bypass of CPDs and other UV-induced photolesions by combinations of TLS and replicative DNA polymerases--the latter model has also been known as the two-step model, in which the cooperation of two (or more) DNA polymerases as misinserters and (mis)extenders is assumed. Daylight UV induces a characteristic UV-specific mutation, a UV-signature mutation occurring preferentially at methyl-CpG sites, which is also observed frequently after exposure to either UVB or UVA, but not to UVC. The wavelengths relevant to the mutation are so consistent with the composition of daylight UV that the mutation is called solar-UV signature, highlighting the importance of this type of mutation for creatures with the cytosine-methylated genome that are exposed to the sun in the natural environment. UVA has also been suggested to induce oxidative types of mutation, which would be caused by oxidative DNA damage produced through the oxidative stress after the irradiation. Indeed, UVA produces oxidative DNA damage not only in cells but also in skin, which, however, does not seem sufficient to induce mutations in the normal skin genome. In contrast, it has been demonstrated that UVA exclusively induces the solar-UV signature mutations in vivo through CPD formation.
Space flight produces an extreme environment with unique stressors, but little is known about how our body responds to these stresses. While there are many intractable limitations for in-flight space research, some can be overcome by utilizing gene knockout-disease model mice. Here, we report how deletion of Nrf2, a master regulator of stress defense pathways, affects the health of mice transported for a stay in the International Space Station (ISS). After 31 days in the ISS, all flight mice returned safely to Earth. Transcriptome and metabolome analyses revealed that the stresses of space travel evoked ageing-like changes of plasma metabolites and activated the Nrf2 signaling pathway. Especially, Nrf2 was found to be important for maintaining homeostasis of white adipose tissues. This study opens approaches for future space research utilizing murine gene knockout-disease models, and provides insights into mitigating space-induced stresses that limit the further exploration of space by humans.
We recently reported the kinetics of mutation induction by UVB in the skin epidermis and dermis of transgenic Muta trade mark mice [Ikehata and Ono, Mutat Res 508:41-47, 2002]. In the present study we determined the complete DNA sequence of the lacZ transgene in 208 mutants isolated from the dermis and epidermis of UVB-irradiated and control mice. The resulting mutation patterns for the dermis and epidermis were similar, although two CC-->TT tandem substitutions, one of the signature mutations for UV insult, were detected only among the UVB-induced epidermal mutants. The spectra of the UVB-induced and control mutations were both dominated by C-->T transitions (83% and 62%); however, the C-->T transitions from irradiated mice occurred almost exclusively in dipyrimidine sites, while those from control mice preferred CpG sites. Thus, the mutation spectrum detected for the irradiated skin tissues was different from the background spectrum and UV-specific, confirming the utility of the transgenic system for UVB-induced mutation studies in vivo. An analysis of the bases adjacent to the mutated cytosines from irradiated mice revealed that the dipyrimidine sites preferred for UVB-induced mutation were 5'-TC-3' > 5'-CC-3' > 5'-CT-3'. Among mutants from irradiated mice, C-->T transitions were recovered frequently at dipyrimidine sites associated with CpG. We showed that CpG sites in the lacZ transgene of Muta trade mark mice were heavily methylated in both the epidermis and dermis. Thus, CpG methylation could contribute to the UVB-induced recurrent or hotspot mutations in the mammalian genome.
We studied the kinetics of mutation induction in skin epidermis and dermis of UVA-irradiated transgenic Muta mice and analyzed the sequence changes in 80 lacZ transgene mutants from the irradiated epidermis. The mutant frequency increased linearly in both the epidermis and dermis up to 240 kJ/m2 UVA, twice as efficiently in the epidermis as in the dermis, without provoking any inflammatory reactions in the exposed skin. The 83 mutations detected in the UVA-exposed epidermis were dominated by C-->T transitions (88%), found almost exclusively at dipyrimidine sites, and specified by four occurrences of CC-->TT tandem substitutions, suggesting that UV-specific photoproducts induced in DNA have a major role in the genotoxicity. No T-->G transversions, which have been considered as a UVA signature mutation, and few mutations suggesting the relevance of oxidative damage were recovered in the present study. An analysis of the bases adjacent to the mutated cytosines revealed that the 3'-cytosine of dipyrimidine sites is the preferred target of UVA-induced C-->T transition. Moreover, C-->T transitions were induced at dipyrimidine sites associated with CpG much more frequently by UVA than by UVB, forming hotspots at several of these sites. These results suggest that UVA contributes more to the formation of recurrent or hotspot mutations at methylated CpG sites in the mammalian genome than UVB, since methylation of the CpG motif is observed entirely in the lacZ transgenes and is known to enhance the formation of cyclobutane pyrimidine dimers by longer wavelength UV.
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