Meir Krupsky

The Expression of Three Genes in Primary Non ^ Small Cell Lung Cancer Is Associated with Metastatic Spread to the Brain

Purpose: Brain metastases affect 25% of patients with non–small cell lung cancer (NSCLC). We hypothesized that the expression of genes in primary NSCLC tumors could predict brain metastasis and be used for identification of high-risk patients, who may benefit from prophylactic therapy. Experimental Design: The expression of 12 genes was measured by real-time quantitative reverse transcriptase PCR in 142 frozen NSCLC tissue samples. Univariate and multivariate Cox regression analysis was used to analyze the correlation between gene expression and the occurrence of brain metastasis. Immunohistochemistry on independent samples was used to verify the findings. Results: A score based on the expression levels of three genes, CDH2 (N-cadherin), KIFC1, and FALZ, was highly predictive of brain metastasis in early and advanced lung cancer. The probability of remaining brain metastasis–free at 2 years after diagnosis was 90.0 ± 9.5% for patients with stage I/stage II tumors and low score compared with 62.7 ± 12% for patients with high score (P < 0.01). In patients with more advanced lung cancer, the brain metastasis–free survival at 24 months was 89% for patients with low score compared with only 37% in patients with high score (P < 0.02). These results were confirmed by immunohistochemical detection of N-cadherin in independent cohort of primary NSCLC. Conclusions: The expression levels of three genes in primary NSCLC tumors may be used to identify patients at high risk for brain metastasis who may benefit from prophylactic therapy to the central nervous system.

Reduced Repair of the Oxidative 8-Oxoguanine DNA Damage and Risk of Head and Neck Cancer

An increasing number of studies indicate that reduced DNA-repair capacity is associated with increased cancer risk. Using a functional assay for the removal of the oxidative DNA lesion 8-oxoguanine by the DNA-repair enzyme 8-oxoguanine DNA glycosylase 1 (OGG1), we have previously shown that reduced OGG activity is a risk factor in lung cancer. Here, we report that OGG activity in peripheral blood mononuclear cells from 37 cases with squamous cell carcinoma of the head and neck (SCCHN) was significantly lower than in 93 control subjects, frequency matched for age and gender. Retesting of OGG activity 3 to 4 years after diagnosis and successful treatment of 18 individuals who recovered from the disease showed that OGG activity values were similar to those determined at diagnosis, suggesting that reduced OGG activity in case patients was not caused by the disease. Logistic regression analysis indicated that the adjusted odds ratio (OR) associated with a unit decrease in OGG activity was statistically significantly increased [OR, 2.3; 95% confidence interval (95% CI), 1.5-3.4]. Individuals in the lowest tertile of OGG activity exhibited an increased risk of SCCHN with an OR of 7.0 (95% CI, 2.0-24.5). The combination of smoking and low OGG was associated with a highly increased estimated relative risk for SCCHN. These results suggest that low OGG is associated with the risk of SCCHN, and if confirmed by additional epidemiologic studies, screening of smokers for low OGG activity might be used as a strategy for the prevention of lung cancer and SCCHN.

Sil overexpression in lung cancer characterizes tumors with increased mitotic activity

Sil (SCL interrupting locus) was cloned from the most common chromosomal rearrangement in T-cell acute lymphoblastic leukemia. It is an immediate early gene whose expression is associated with cell proliferation. Sil protein levels are tightly regulated during the cell cycle, reaching peak levels in mitosis and disappearing on transition to G1. A recent study found Sil to be one of 17 genes whose overexpression in primary adenocarcinomas predicts metastatic spread. We hypothesized that Sil might have a role in carcinogenesis. To address this question, we utilized several approaches. Using a multitumor tissue array, we found that Sil protein expression was increased mostly in lung cancer, but also at lower levels, in a subset of other tumors. Microarray gene expression analysis and immunohistochemistry of lung cancer samples verified these observations. Sil gene expression in lung cancer correlated with the expression of several kinetochore check-point genes and with the histopathologic mitotic index. These observations suggest that overexpression of the Sil gene characterizes tumors with increased mitotic activity.

Repair of the oxidative DNA damage 8-oxoguanine as a biomarker for lung cancer risk

DNA repair has a major role in suppressing the rate of accumulation of mutations. Therefore, variations in DNA repair are likely to play an important role in determining cancer risk. While there is compelling evidence that defects in DNA repair cause high predisposition to several hereditary cancers, there is a paucity of data on the role of DNA repair in sporadic cancers. We present our approach of using functional DNA repair tests, rather than gene polymorphism, to study the potential of DNA repair enzymes to serve as biomarkers for lung cancer risk. We have previously developed a functional DNA repair blood test for the enzymatic repair of the oxidative DNA lesion 8-oxoguanine, and found that reduced OGG activity is a risk factor in non-small cell lung cancer. Moreover the combination of smoking and low OGG activity was associated with a greatly increased lung cancer risk (Paz-Elizur et al, JNCI 95 (2003) 1312-1319). The use of OGG activity as a potential biomarker for lung cancer risk is validated in collaboration with the M. D. Anderson Cancer Center, under the sponsorship of the Associate Members Program of the Early Detection Research Network (EDRN, NCI, NIH).

Novel molecular targets for risk identification: DNA repair enzyme activities

DNA is continuously damaged by environmental agents and by intracellular byproducts of metabolism [1,2]. If left unrepaired, this DNA damage will cause mutations due to miscoding during replication, thereby increasing cancer risk [1,3]. Therefore, DNA repair is expected to be a major mechanism that protects organisms against cancer. Indeed, in several hereditary diseases that cause high predisposition to cancer, the mutated genes associated with the disorder encode defective DNA repair proteins [3].