cAMP-mediated regulation of melanocyte genomic instability: A melanoma-preventive strategy.

Malignant melanoma of the skin is the leading cause of death from skin cancer and ranks fifth in cancer incidence among all cancers in the United States. While melanoma mortality has remained steady for the past several decades, melanoma incidence has been increasing, particularly among fair-skinned individuals. According to the American Cancer Society, nearly 10,000 people in the United States will die from melanoma this year. Individuals with dark skin complexion are protected damage generated by UV-light due to the high content of UV-blocking melanin pigment in their epidermis as well as better capacity for melanocytes to cope with UV damage. There is now ample evidence that suggests that the melanocortin 1 receptor (MC1R) is a major melanoma risk factor. Inherited loss-of-function mutations in MC1R are common in melanoma-prone persons, correlating with a less melanized skin complexion and poorer recovery from mutagenic photodamage. We and others are interested in the MC1R signaling pathway in melanocytes, its mechanisms of enhancing genomic stability and pharmacologic opportunities to reduce melanoma risk based on those insights. In this chapter, we review melanoma risk factors, the MC1R signaling pathway, and the relationship between MC1R signaling and DNA repair.

Mismatch recognition protein MutSbeta does not hijack (CAG)n hairpin repair in vitro.

CAG repeats form stable hairpin structures, which are believed to be responsible for CAG repeat expansions associated with certain human neurological diseases. Human cells possess an accurate DNA hairpin repair system that prevents expansion of disease-associated CAG repeats. Based on transgenic animal studies, it is suggested that (CAG)(n) expansion is caused by abnormal binding of the MutSbeta mismatch recognition protein to (CAG)(n) hairpins, leading to hijacking mismatch repair function during (CAG)(n) hairpin repair. We demonstrate here that MutSbeta displays identical biochemical and biophysical activities (including ATP-provoked conformational change, ATPase, ATP binding, and ADP binding) when interacting with a (CAG)(n) hairpin and a mismatch. More importantly, our in vitro functional hairpin repair assays reveal that excess MutSbeta does not inhibit (CAG)(n) hairpin repair in HeLa nuclear extracts. Evidence presented here provides a novel view as to whether or not MutSbeta is involved in CAG repeat instability in humans.