Chromosome 17-mediated dormancy of AT6.1 prostate cancer micrometastases.

To improve the diagnosis and treatment of cancer, an increased understanding of the molecular and cellular changes that regulate metastatic ability is required. We have recently demonstrated a prostate cancer metastasis-suppressor activity encoded by a discontinuous approximately 70-cM region of human chromosome. The presence of this region suppresses the spontaneous metastatic ability of AT6.1 rat prostatic cancer cells by greater than 30-fold (M. A. Chekmareva et al., Prostate, 33: 271-280, 1997). Interestingly, a number of potentially important genes which have been mapped to human chromosome 17, including TP53, NM23, and BRCA1, are not retained (M. A. Chekmareva et al., cited above) or are not expressed in these microcell hybrids (B. A. Yoshida et al., In Vivo, in press), which suggests the presence of a novel metastasis-suppressor gene(s) or novel function of a known gene(s) encoded by this region(s). We hypothesize that identification of the "step" in the metastatic cascade that is inhibited by the presence of the approximately 70-cM metastasis-suppressor region will facilitate the identification of candidate metastasis-suppressor genes. For a cancer cell to metastasize, it must escape from the primary tumor, enter the circulation, arrest in the microcirculation, extravasate into a tissue compartment, and grow. This suppression of spontaneous macroscopic lung metastases could be due to the inhibition of a number of steps within this cascade. Results of the current study demonstrate that AT6.1 cells containing the approximately 70-cM region (AT6.1-17-4 cells) escape from the primary tumor and arrest in the lung but are growth-inhibited unless the metastasis-suppressor region is lost. This growth inhibition seems to result from an effect of one or more genes at the metastatic site and not from a circulating angiogenesis inhibitor. Our findings suggest that the approximately 70-cM region of human chromosome 17 may encode a gene(s) that regulates the "dormancy" of AT6.1-17-4 micrometastases.

Activated calphostin C cytotoxicity is independent of p53 status and in vivo metastatic potential.

The development of novel therapeutic agents to modulate programmed cell death independent of genetic background or malignant potential is a primary goal of modern cancer therapy. In this report, the light activation- and concentration-dependent cytotoxicity of calphostin C, a photoactivatable perylenequinone, is carefully evaluated using a series of nine well-characterized human and rodent prostate cancer cell lines representing the spectrum of disease progression (e.g., variations in metastatic ability, ploidy, and tumor suppressor gene status). Treatment of these cancer cell lines with nanomolar concentrations of calphostin C in combination with increasing amounts of light exposure established a relationship between light and dose dependence of calphostin C cytotoxicity. The induction of apoptosis is rapid, as evidenced by the fact that immediately after treatment, cells exposed to calphostin C with light activation exhibit both morphological and biochemical changes consistent with apoptosis (cellular and nuclear shrinkage and chromatin condensation). For example, 78% of cells treated with 100 nM calphostin C in combination with 2 h of light activation underwent apoptosis within 24 h of treatment. DNA ladder formation could be detected within 12 h of treatment. In the absence of light activation, treatment with calphostin C at all concentrations tested had no acute or durable cytotoxic effects in any of the cell lines. Our findings demonstrate that calphostin C cytotoxicity is strictly light dependent. Furthermore, its efficacy is independent of the genetic background, p53 status, or in vivo malignant potential of a cell, making it a suitable candidate for the treatment of heterogeneous tumor cell populations.

Prostate cancer metastasis-suppressor genes: a current perspective.

Prostate cancers account for 43% of all cancers diagnosed in American men. It is estimated that in 1996, 317,000 new cases of prostate cancer were diagnosed and 41,000 men died of the disease. The challenge of treating prostate cancer lies in accurately distinguishing those histologically-localized cancers which will complete metastatic progression from those that will remain indolent. At this time, we lack appropriate histological markers to make such distinctions, therefore, it is often difficult to accurately predict the clinical course of an individual patient's disease. There is growing evidence that a critical event in the progression of a tumor cell from a non-metastatic to metastatic phenotype is the loss of function of metastasis-suppressor genes. These genes specifically suppress the ability of a cell to metastasize. Work from several groups has demonstrated that human chromosomes 8, 10, 11 and 17 encode prostate cancer metastasis suppressor activities. As a result of these efforts the first prostate cancer metastasis-suppressor gene, KAI1, was identified and mapped to the p11-2 region of chromosome 11. In subsequent studies, an additional gene encoded by the same region, CD44 was also determined to have metastasis-suppressor activity. Recent studies have shown a correlation between decreased expression of KAI1 and CD44 and an increased malignant potential of prostate cancers. It is anticipated that the identification of other metastasis suppressor genes may allow for the development of diagnostic markers useful in the clinical substaging of individual tumors. This manuscript is intended to present our perspective on the importance of these genes in the understanding of prostate cancer progression. More importantly, we present new findings from our laboratory's effort to identify the metastasis-suppressor genes encoded by human chromosome 17. Specifically we report the strategy currently being used to evaluate a series of candidate genes and the approach being utilized to pinpoint the metastasis-suppressor region on human chromosome 17.