The challenge of targeting metastasis.

Metastases that are resistant to conventional therapy are the major cause of death from cancer. In most patients, metastasis has already occurred by the time of diagnosis. Thus, the prevention of metastasis is unlikely to be of therapeutic benefit.

Reflections on the field of photoimmunology.

Photoimmunology evolved from experiments carried out in the 1970s on the immunology of cancer. In studying the antigenic properties of skin cancers induced in mice by UV radiation, I found that most of these tumors failed to grow when transplanted into normal, syngeneic mice but grew progressively in immunosuppressed mice. Thus, these UV-induced skin cancers were highly antigenic.

Reducing death from cancer: what will it take?

In spite of advances in cancer diagnosis and treatment, cancer remains a serious problem for most societies. It is unlikely that cancer can ever be eliminated entirely; therefore, we must continue to seek ways to reduce the incidence, morbidity, and mortality from this devastating disease. Although most cancer research is devoted to finding new treatments, there are many other obstacles to reducing death from cancer that will need to be addressed if significant progress is to be made.

p53 tumor suppressor gene: a critical molecular target for UV induction and prevention of skin cancer.

The relationship between exposure to UV radiation and development of skin cancer has been well established. Several studies have shown that UVB induces unique mutations (C-->T and CC-->TT transitions) in the p53 tumor suppressor gene that are not commonly induced by other carcinogens. Our studies have demonstrated that UV-induced mouse skin cancers contain p53 mutations at a high frequency and that these mutations can be detected in UV-irradiated mouse skin well before the appearance of skin tumors.

Repair capacity for UV light induced DNA damage associated with risk of nonmelanoma skin cancer and tumor progression.

Purpose: To examine the role of suboptimal DNA repair capacity (DRC) for UV light-induced DNA damage in the development of nonmelanoma skin cancer (NMSC) and tumor progression.

Experimental Design: We conducted a hospital-based case-control study of 255 patients with newly diagnosed NMSC [146 with basal cell carcinoma (BCC) and 109 with squamous cell carcinoma (SCC)] and 333 cancer-free controls. We collected information on demographic variables and risk factors from questionnaires, tumor characteristics from medical records, and lymphocytic DRC phenotype by the host-cell reactivation assay.

Mortality risk from squamous cell skin cancer.

Purpose: To identify nonmelanoma skin cancer patients with squamous cell carcinoma (SCC) who are at greatest risk of disease-specific mortality.

Patients And Methods: Prospectively enrolled patients with a minimum of one pathologically confirmed skin SCC lesion, definitive treatment of the SCC lesion(s) resulting in no evidence of disease, and at least 2 months of follow-up after definitive treatment were eligible for the present longitudinal analysis. They received comprehensive clinical, pathologic evaluations and follow-up for patterns of failure and mortality.

Viability of the antigen determines whether DNA or urocanic acid act as initiator molecules for UV-induced suppression of delayed-type hypersensitivity.

UV radiation suppresses the immune response, and UV-induced immune suppression contributes to UV-induced photocarcinogenesis. For UV-induced immune suppression to occur, electromagnetic energy (i.e.

Advantages of using hairless mice versus haired mice to test sunscreen efficacy against photoimmune suppressions.

We tested the hypothesis that the strain of mice used in sunscreen protection experiments may influence immune protection. Ultraviolet (UV) dose-response curves were done in the presence or absence of a sun protection factor (SPF) 15 sunscreen using SKH1:hrBR or C3H/HeN mice. SKH1:hrBR mice showed a higher sensitivity to the suppressive effects of UV radiation (50% immune suppression equal to 5.

Health effects from stratospheric ozone depletion and interactions with climate change.

The potential health effects of elevated levels of ambient UV-B radiation are diverse, and it is difficult to quantify the risks, especially as they are likely to be considerably modified by human behaviour. Nevertheless epidemiological and experimental studies have confirmed that UV radiation is a definite risk factor for certain types of cataract, with peak efficacy in the UV-B waveband. The causal link between squamous cell carcinoma and cumulative solar UV exposure has been well established.

p53 mutations in human aggressive and nonaggressive basal and squamous cell carcinomas.

Purpose: The purpose is to investigate whether aggressive basal cell carcinoma (BCC) and squamous cell carcinoma (SCC) differ from nonaggressive BCC and SCC with respect to the p53 mutation spectrum and whether specific mutations can serve as prognostic indicators of tumor aggressiveness.

Experimental Design: We analyzed 342 tissues from patients with aggressive and nonaggressive BCCs and SCCs for p53 mutations by single-strand conformation polymorphism and nucleotide sequencing.

Results: p53 mutations were detected in 33 of 50 aggressive BCCs (66%), 37 of 98 nonaggressive BCCs (38%), 28 of 80 aggressive SCCs (35%), 28 of 56 nonaggressive SCCs (50%), and 3 of 29 samples of sun-exposed skin (10%).

Systemic alteration induced in mice by ultraviolet light irradiation and its relationship to ultraviolet carcinogenesis. 1977.

Chronic irradiation of mice with ultraviolet (UV) light produces a systemic alteration of an immunologic nature. This alteration is detectable in mice long before primary skin cancers induced by UV light begin to appear. The alteration results in the failure of UV-irradiated mice to reject highly antigenic, transplanted UV-induced tumors that are rejected by unirradiated syngeneic recipients.

Inhibition of UV-induced p53 mutations and skin cancers by sunscreens: implication for skin cancer prevention.

The relationship between exposure to UVB radiation and development of skin cancer has been well established. Several studies have shown that UVB induces unique mutations (C to T and CC to TT transitions) in the p53 tumor suppressor gene that are not commonly induced by other carcinogens. Our studies have demonstrated that UV-induced mouse skin cancers contain p53 mutations at a high frequency and that these mutations can be detected in UV-irradiated mouse skin well before the appearance of skin tumors.

Mechanisms underlying UV-induced immune suppression: implications for sunscreen design.

The ultraviolet (UV) radiation present in sunlight is immune-suppressive. Recently we showed that solar-simulated UV radiation (UVA + UVB; 295-400 nm), applied after immunization, suppressed immunological memory and the elicitation of delayed-type hypersensitivity to the common opportunistic pathogen, Candida albicans. Further, we found that wavelengths in the UVA region of the solar spectrum (320-400 nm), devoid of UVB, were equally effective in activating immune suppression as UVA + UVB radiation.

Mechanisms underlying the suppression of established immune responses by ultraviolet radiation.

The ultraviolet radiation present in sunlight is immune suppressive. Recently we showed that solar-simulated ultraviolet radiation (ultraviolet A + B; 295-400 nm), applied after immunization, suppressed immunologic memory and the elicitation of delayed-type hypersensitivity to the common opportunistic pathogen, Candida albicans. Further, we found that wavelengths in the ultraviolet A region of the solar spectrum (320-400 nm), devoid of ultraviolet B, were equally effective in activating immune suppression as ultraviolet A + B radiation.