Gernot Herrmann

Photoaging of the skin from phenotype to mechanisms

The skin is increasingly exposed to ambient UV-irradiation thus increasing its risk for photooxidative damage with longterm detrimental effects like photoaging, which is characterized by wrinkles, loss of skin tone, and resilience. Photoaged skin displays prominent alterations in the cellular component and the extracellular matrix of the connective tissue with an accumulation of disorganized elastin and its microfibrillar component fibrillin in the deep dermis and a severe loss of interstitial collagens, the major structural proteins of the dermal connective tissue. The unifying pathogenic agents for these changes are UV-generated reactive oxygen species (ROS) that deplete and damage non-enzymatic and enzymatic antioxidant defense systems of the skin. As well as causing permanent genetic changes, ROS activate cytoplasmic signal transduction pathways in resident fibroblasts that are related to growth, differentiation, senescence, and connective tissue degradation. This review focuses on the role of UV-induced ROS in the photodamage of the skin resulting in biochemical and clinical characteristics of photoaging. In addition, the relationship of photoaging to intrinsic aging of the skin will be discussed. A decrease in the overall ROS load by efficient sunscreens or other protective agents may represent promising strategies to prevent or at least minimize ROS induced photoaging.

Saccharomyces cerevisiae LIF1: a function involved in DNA double-strand break repair related to mammalian XRCC4.

Saccharomyces cerevisiae DNA ligase IV (LIG4) has been shown previously to be involved in non‐homologous DNA end joining and meiosis. The homologous mammalian DNA ligase IV interacts with XRCC4, a protein implicated in V(D)J recombination and double‐strand break repair. Here, we report the discovery of LIF1, a S.cerevisiae protein that strongly interacts with the C‐terminal BRCT domain of yeast LIG4. LIG4 and LIF1 apparently occur as a heterodimer in vivo. LIF1 shares limited sequence homology with mammalian XRCC4. Disruption of the LIF1 gene abolishes the capacity of cells to recircularize transformed linearized plasmids correctly by non‐homologous DNA end joining. Loss of LIF1 is also associated with conditional hypersensitivity of cells to ionizing irradiation and with reduced sporulation efficiency. Thus, with respect to their phenotype, lif1 strains are similar to the previously described lig4 mutants. One function of LIF1 is the stabilization of the LIG4 enzyme. The finding of a XRCC4 homologue in S.cerevisiae now allows for mutational analyses of structure–function relationships in XRCC4‐like proteins to define their role in DNA double‐strand break repair.

Differential roles for Chk1 and FANCD2 in ATR‐mediated signalling for psoralen photoactivation‐induced senescence

Abstract:  Cellular senescence is a stress‐inducible, naturally irreversible cell cycle arrest, which is likely linked with ageing. Premature ageing of the skin is a prominent side effect of psoralen photoactivation, which is used for the treatment of various skin disorders. Previously, we have shown that DNA interstrand crosslink formation by photoactivated psoralens induces a senescent phenotype in primary fibroblasts that is mediated by Ataxia telangiectasia‐mutated and Rad3‐related (ATR) kinase. Checkpoint kinase 1 (Chk1) initiates cell cycle checkpoints, and FANCD2 is known to be involved in DNA damage‐induced S‐phase arrest and crosslink repair. In this study, we examined a role for Chk1 and FANCD2 as downstream effectors of ATR in senescence signalling. We demonstrate that Chk1 and FANCD2 are long‐lastingly activated after psoralen photoactivation. Separate and combined reduction in Chk1 and FANCD2 expression by small interfering RNA (siRNA) preceding irradiation partly prevented the initiation of the senescence‐like phenotype, whereas siRNA (Chk1 and FANCD2) transfection of senesced fibroblasts released cells from growth arrest. We observed that Chk1 and FANCD2 signal equally and additively for senescence induction, while Chk1 is predominantly responsible for maintaining persistent cell cycle arrest. In conclusion, Chk1 and FANCD2 function downstream of ATR in a non‐redundant manner for the establishment and maintenance of psoralen photoactivation‐induced senescence.

PCR-based subtractive hybridization identifies repressed genes in growth-arrested human dermal fibroblasts following combined treatment with 8-methoxypsoralen and UVA irradiation (PUVA).

To identify genes which are repressed in growth-arrested human dermal fibroblasts upon a single treatment with 8-methoxypsoralen and UVA irradiation (PUVA) we have used a PCR-based subtractive hybridization protocol resulting in cloning of four PUVA-repressed genes. Sequence analysis and homology searches identified three known genes related to growth control, lipid and connective tissue metabolism. One cDNA clone represented a novel gene. Northern blot analyses confirmed a PUVA-dependent reduction in mRNA expression in fibroblasts in vitro. The identification of growth arrest related repressed genes in PUVA-treated fibroblasts may stimulate further research addressing the causal role of these genes in the control and regulation of the postmitotic phenotype of fibroblasts on a molecular and cellular level.