Browsing by Subject "UVB"

Now showing 1 - 4 of 4
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    Estrogen receptor involvement in the response of human keratinocytes to ultraviolet B irradiation
    (2014) Farrington, Daphne L.; Spandau, Dan F.; Harrington, Maureen A.; Nakshatri, Harikrishna
    The signaling mechanisms involved in UVB-induced skin cancer are complex and although the scope of this work is inherently limited in focus, the findings may provide insight into how estrogen receptor signaling impacts cell growth, senescence, and apoptosis to protect keratinocytes. Additional signaling due to E2-activation of the estrogen receptor may provide back-up or redundant pathways in response to UVB.
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    How Wounding via Lasers Has Potential Photocarcinogenic Preventative Effects via Dermal Remodeling
    (Springer Verlag, 2016-09) Krbanjevic, Aleksandar; Travers, Jeffrey B.; Spandau, Dan F; Dermatology, School of Medicine
    As the incidence of non-melanoma skin cancer (NMSC) is increasing, there is a growing need to identify effective preventive strategies. A recently proposed hypothesis states that NMSC photocarcinogenesis is tightly linked to insufficient insulin growth factor-1 expression by agglomerated senescent fibroblasts in geriatric dermis. This paucity of IGF-1 expression in senile skin allows basal keratinocytes to mitotically propagate their UVB-altered genome and potentially initiate an actinic neoplasm. Here we review the role of the dermal microenvironment in NMSC pathogenesis, describe the impact of fibroblast senescence on this process and discuss how laser-induced dermal wounding can be effectively used to prevent NMSC development in geriatric patients.
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    Human keratinocytes utilize the integrated stress response to adapt to environmental stress
    (2017-06) Collier, Ann E.; Spandau, Dan F.; Wek, Ronald C.; Travers, Jeffrey B.; Turchi, John J.; Turner, Matthew J.
    Human skin, consisting of the outer epidermis and inner dermis, serves as a barrier that protects the body from an onslaught of environmental stresses. Keratinocytes in the stratified epidermis undergo sequential differentiation that consists of multiple layers of cells differing in structure and function. Therefore, keratinocytes must not only combat environmental stress, but need to undergo massive changes in gene expression and morphology to form a proper barrier. One mode by which cells cope with stress and differentiation is through phosphorylation of the α subunit of eukaryotic initiation factor 2 (eIF2α-P), which causes global inhibition of protein synthesis coincident with preferential translation of select gene transcripts. Translational repression allows stressed cells to conserve energy and prioritize pro-survival processes to alleviate stress damage. Since eIF2α kinases are each activated by distinct types of stress, this pathway is referred to as the Integrated Stress Response (ISR). We sought to identify the roles of the ISR in the keratinocyte response to the stresses associated with differentiation and ultraviolet B (UVB) irradiation. In this thesis, we show that both general and gene-specific translational control in the ISR are activated following differentiation or UVB irradiation of human keratinocytes. ISR deficiency through genetic modifications or pharmacological interventions caused severe divergence from the appropriate keratinocyte response to differentiation or UVB. Differentiation genes were selectively translated by eIF2α-P, and inhibition of the ISR diminished their induction during differentiation. Furthermore, loss of the eIF2α kinase GCN2 (EIF2AK4) adversely affected the ability of keratinocytes to stratify in three dimensional cultures. Our analysis also revealed a non-canonical ISR response following UVB irradiation, in which downstream factors ATF4 (CREB2) and CHOP (DDIT3/GADD153) were poorly expressed due to repressed transcription, despite preferential translation in response to eIF2α-P. The ISR was cytoprotective during UVB and we found that eIF2α-P was required for a UVB induced G1 arrest, cell fate determination, and DNA repair via a mechanism involving translational control of human CDKN1A (p21 protein) transcript variant 4 mRNA. Collectively, this thesis describes novel roles for the ISR in keratinocyte differentiation and response to UVB, emphasizing the utility of targeting translational control in skin disease therapy.
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    The peroxisome proliferator-activated receptor γ antagonist, GW9962, alters UVB-induced inflammatory responses, apoptosis, and delayed hyperproliferation
    (2009-01-16T17:25:58Z) Martel, Kellie Clay; Konger, Raymond L.; Travers, Jeffrey B.; Spandau, Dan F, 1957-
    It has recently been shown that the gamma subtype of the peroxisome proliferator-activated receptor (PPARγ) is a target of ultraviolet B (290-320 nm; UVB) irradiation, and that PPARγ activation is necessary for full UVB-induced cyclooxygenase-2 (COX-2) induction. However, the biological significance of PPARγ activation in cutaneous photobiology is unknown. Acute UVB irradiation results in a characteristic series of events in the epidermis which includes: an initial edema response and subsequent inflammation, COX-2 induction, apoptosis, and a delayed hyperproliferative response. Therefore, the regulatory role of PPARγ activation was examined in this acute photoresponse using a topical application of the potent, irreversible PPARγ antagonist, GW9962. GW9662 was applied to the epidermis of SKH1 hairless albino mice at increasing doses (0.01-1.0mM) prior to UVB irradiation. The photobiological responses were examined through RT-PCR, skin thickness measurements, and immunohistochemistry, at 24 and 72 hours after UVB-irradiation. At the highest dose, GW9622 significantly inhibited UVB-induced inflammation, as measured by COX-2 induction at both 24 and 72 hrs. Inflammation assessed by skin thickness measurements indicated that lower doses mildly increased inflammation at 72 hrs, but suppressed inflammation at the highest dose. In contrast, GW9662 treatment dose dependently augmented UVB-induced apoptosis at 24 hours, while affecting the delayed hyperproliferative response at 72 hours in an inverse dose-response manner. The results from this study suggest that PPARγ is a key regulator of these photobiological responses. Because these responses are well known to be involved in tumor development and progression, this study also suggests a potential role for PPARγ in UVB-induced skin cancers.