Megan G. Lowery scite author profile

In temperate lakes, asynchronous cycles in surface water temperatures and incident ultraviolet (UV) radiation expose aquatic organisms to damaging UV radiation at different temperatures. The enzyme systems that repair UV-induced DNA damage are temperature dependent, and thus potentially less effective at repairing DNA damage at lower temperatures. This hypothesis was tested by examining the levels of UV-induced DNA damage in the freshwater crustacean Daphnia pulicaria in the presence and absence of longer-wavelength photoreactivating radiation (PRR) that induces photoenzymatic repair (PER) of DNA damage. By exposing both live and dead (freeze-killed) Daphnia as well as raw DNA to UV-B in the presence and absence of PRR, we were able to estimate the relative importance and temperature dependence of PER (light repair), nucleotide excision repair (NER, dark repair), and photoprotection (PP). Total DNA damage increased with increasing temperature. However, the even greater increase in DNA repair rates at higher temperatures led net DNA damage (total DNA damage minus repair) to be greater at lower temperatures. Photoprotection accounted for a much greater proportion of the reduction in DNA damage than did repair. Experiments that looked at survival rates following UV exposure demonstrated that PER increased survival rates. The important implication is that aquatic organisms that depend heavily on DNA repair processes may be less able to survive high UV exposure in low temperature environments. Photoprotection may be more effective under the low temperature, high UV conditions such as are found in early spring or at high elevations.

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FANCM and FAAP24 Maintain Genome Stability via Cooperative as Well as Unique Functions

Wang

Leung

Jiang

et al. 2013

Molecular Cell

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SUMMARY The DNA remodeling enzyme FANCM and its DNA-binding partner, FAAP24, constitute a complex involved in the activation of Fanconi Anemia (FA) DNA damage response mechanism, but neither gene has distinct patient mutants. In this study, we created isogenic models for both FANCM and FAAP24 and investigated their integrated functions in DNA damage response. We found that FANCM and FAAP24 coordinately facilitate FA pathway activation and suppress sister chromatid exchange. Importantly, we show that FANCM and FAAP24 possess non-overlapping functions such that FAAP24 promotes ATR-mediated checkpoint activation particularly in response to DNA crosslinking agents, whereas FANCM participates in recombination-independent interstrand crosslink repair by facilitating recruitment of lesion incision activities which requires its translocase activity. Our data suggest that FANCM and FAAP24 play multiple while not fully epistatic roles in maintaining genomic integrity.

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Modularized Functions of the Fanconi Anemia Core Complex

et al. 2014

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SUMMARY The Fanconi Anemia (FA) core complex provides the essential E3 ligase function for the FA pathway activation through the spatially defined FANCD2 ubiquitination. Of the seven FA gene products forming the core complex, FANCL possesses a RING domain with demonstrated E3 ligase activity. The other six components have no clearly defined roles. Through epistatic analyses, we identified three functional modules in the FA core complex: a catalytic module consisting of FANCL, FANCB, and FAAP100 is absolutely required for the E3 ligase function; the FANCA-FANCG-FAAP20 module and the FANCC-FANCE-FANCF module provide non-redundant and ancillary functions supporting the chromatin and DNA damage association of the catalytic module. Disruption of the catalytic module renders total loss of the core complex function whereas loss of any ancillary module component does not. Our work revealed the roles of several FA gene products with previously undefined functions and a modularized assembly of the FA core complex.

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Identification of a Non-Dividing Subpopulation of Mouse and Human Epidermal Cells Exhibiting High Levels of Persistent Ultraviolet Photodamage

Mitchell

Volkmer

Breitbart

et al. 2001

Journal of Investigative Dermatology

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The distribution and persistence of cyclobutane pyrimidine dimers were investigated in mouse skin after chronic and acute exposures to ultraviolet-B radiation. We found that DNA damage accumulated in response to chronic irradiation and persisted in a unique set of epidermal cells located at the basal layer. Treatment with a tumor promoter caused the heavily damaged epidermal cells to divide and p53-immunopositive clusters to form within 24 h suggesting that these cells may be progenitors of the mutant p53 clusters associated with actinic keratoses and squamous cell carcinomas. In contrast to low fluence chronic irradiation, daily treatment with a higher fluence of ultraviolet-B produced extensive hyperplasia and considerably reduced penetration of photodamage. Exposure of chronically irradiated skin to an acute "sunburn dose" of ultraviolet-B also produced significant epidermal hyperplasia and resulted in complete loss of heavily damaged basal cells within 4 d postirradiation. The occurrence and distribution of cyclobutane dimers in human skin correlated well with putative sunlight exposure and resembled that observed in ultraviolet-B-irradiated mice. Heavily damaged basal cells were observed at various sites, including those receiving sporadic sunlight exposure, suggesting that these cells may play an important role in carcinoma formation in humans.

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Effects of Chronic Exposure to Ultraviolet B Radiation on DNA Repair in the Dermis and Epidermis of the Hairless Mouse

Mitchell

Byrom

Chiarello

et al. 2001

Journal of Investigative Dermatology

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It has previously been shown that chronic exposure to low fluences of ultraviolet B radiation reduced DNA repair capacity in mouse skin. In this study we now extend this to examine the concentration dependence and tissue dependence of this phenomenon. We found that (6-4) photoproducts were repaired considerably faster than cyclobutane dimers and that the kinetics for photoproduct removal were comparable in the dermis and epidermis. Chronic ultraviolet B irradiation significantly reduced the initial rate and extent of DNA repair. After low daily doses of ultraviolet B (6-4) photoproduct repair was most affected and after high daily doses the repair of both cyclobutane and (6-4) dimers was reduced. Whereas cyclobutane dimer repair was most affected in the dermis, reduced (6-4) photoproduct repair was observed in both tissues. The deleterious effects of chronic ultraviolet exposure were sustained for a considerable time after the chronic treatment ended.

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Megan G. Lowery

Molecular response to climate change: temperature dependence of UV‐induced DNA damage and repair in the freshwater crustacean Daphnia pulicaria

FANCM and FAAP24 Maintain Genome Stability via Cooperative as Well as Unique Functions

Modularized Functions of the Fanconi Anemia Core Complex

Identification of a Non-Dividing Subpopulation of Mouse and Human Epidermal Cells Exhibiting High Levels of Persistent Ultraviolet Photodamage

Effects of Chronic Exposure to Ultraviolet B Radiation on DNA Repair in the Dermis and Epidermis of the Hairless Mouse

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