Pharmacodynamic study of disulfiram in men with non-metastatic recurrent prostate cancer.

BACKGROUND: Preclinical drug screens identified disulfiram as a potent in vitro inhibitor of prostate cancer (PCa) cell growth. Although many mechanisms for its anticancer activity have been proposed, tumor suppressor gene re-expression through promoter demethylation emerged as one of the more plausible. METHODS: We conducted an open-label, dose escalation trial of disulfiram in men with non-metastatic recurrent PCa after local therapy. Dose escalation occurred if a demethylating 'response' (that is, 10% decrease in peripheral blood mononuclear cell (PBMC) global 5-methyl cytosine (5(me)C) content) was observed in <3 patients in cohort 1. Cohorts 1 and 2 received disulfiram 250 mg and 500 mg daily, respectively. The primary end point was the proportion of subjects with a demethylation response. Secondary end points included the rate of PSA progression at 6 months, changes in PSA doubling time and safety/tolerability. RESULTS: Changes in global 5(me)C content were observed in two of nine patients (22.2%) in cohort 1 and 3 of 10 (30.0%) in cohort 2. Only five subjects were on trial for 6 months, all were in cohort 1 and all had PSA progression by 6 months. No changes in PSA kinetics were observed in either cohort. Disulfiram was poorly tolerated with six patients experiencing grade 3 adverse events (three per cohort). Three of the responders displayed pretreatment instability in their 5(me)C content. CONCLUSIONS: A minority of patients had transient global PBMC demethylation changes. Instability in 5(me)C may limit the reproducibility of these findings, limiting our ability to confirm our hypothesis. Given the toxicities and no clinical benefits, further development of disulfiram should not be pursued in this population.

Overexpression of ribosomal RNA in prostate cancer is common but not linked to rDNA promoter hypomethylation.

Alterations in nucleoli, including increased numbers, increased size, altered architecture and increased function are hallmarks of prostate cancer cells. The mechanisms that result in increased nucleolar size, number and function in prostate cancer have not been fully elucidated. The nucleolus is formed around repeats of a transcriptional unit encoding a 45S ribosomal RNA (rRNA) precursor that is then processed to yield the mature 18S, 5.8S and 28S RNA species. Although it has been generally accepted that tumor cells overexpress rRNA species, this has not been examined in clinical prostate cancer. We find that indeed levels of the 45S rRNA, 28S, 18S and 5.8S are overexpressed in the majority of human primary prostate cancer specimens as compared with matched benign tissues. One mechanism that can alter nucleolar function and structure in cancer cells is hypomethylation of CpG dinucleotides of the upstream rDNA promoter region. However, this mechanism has not been examined in prostate cancer. To determine whether rRNA overexpression could be explained by hypomethylation of these CpG sites, we also evaluated the DNA methylation status of the rDNA promoter in prostate cancer cell lines and the clinical specimens. Bisulfite sequencing of genomic DNA revealed two roughly equal populations of loci in cell lines consisting of those that contained densely methylated deoxycytidine residues within CpGs and those that were largely unmethylated. All clinical specimens also contained two populations with no marked changes in methylation of this region in cancer as compared with normal. We recently reported that MYC can regulate rRNA levels in human prostate cancer; here we show that MYC mRNA levels are correlated with 45S, 18S and 5.8S rRNA levels. Further, as a surrogate for nucleolar size and number, we examined the expression of fibrillarin, which did not correlate with rRNA levels. We conclude that rRNA levels are increased in human prostate cancer, but that hypomethylation of the rDNA promoter does not explain this increase, nor does hypomethylation explain alterations in nucleolar number and structure in prostate cancer cells. Rather, rRNA levels and nucleolar size and number relate more closely to MYC overexpression.

[CpG island hypermethylation of the DNA. Perspectives of a molecular biomarker for prostate cancer]. / CpG-Insel-Hypermethylierung der DNA. Perspektiven eines molekularen Biomarkers für das Prostatakarzinom.

The exact classification of clinically significant versus insignificant prostate cancer displays one of major problems in current urological practice. Using novel molecular biomarkers, we are trying to decrease overdiagnosis of insignificant cancer. CpG island hypermethylation as a common epigenetic event is a well-recognized phenomenon during carcinogenesis. We have shown that hypermethylation at several gene loci distinguishes between benign and malignant forms of prostatic disorders. Furthermore using tests in cancer tissue and serum samples, one can draw prognostic conclusions and predict biochemical failure following radical prostatectomy with curative intent.

An equilibrium model of endothelial cell adhesion via integrin-dependent and integrin-independent ligands.

Endothelial cell adhesion can be enhanced by supplementing integrin-mediated adhesion via fibronectin with the high-affinity avidin-biotin system in which biotin is covalently linked to membrane proteins and avidin binds to biotinylated surfaces (Bhat et al. J Biomed Mater Res 1998;41:377-85). An equilibrium model was extended to explain detachment of spreading cells following exposure to flow for this two ligand system. The two different receptor-ligand systems were treated as springs in parallel in which the equilibrium dissociation constant was a function of the separation distance of the cell from the surface. Flow experiments were performed to measure the endothelial cell adhesion strength as a function of the extent of biotinylation of the endothelium. Surfaces contained adsorbed fibronectin, avidin or both ligands. The contact area between the cell membrane and substrate was measured using total internal reflection fluorescence microscopy. Estimates of the unstressed dissociation constant for fibronectin and avidin were determined from data for adhesion strength and contact area of each ligand separately. Using these unstressed equilibrium constants, the model predicted, with reasonable accuracy, the strength of endothelial cell adhesion to surfaces containing fibronectin and avidin. The results indicate that as the extent of biotinylation increases, the avidin-biotin system contributes a larger fraction of the total adhesion strength but the maximum contribution of the avidin-biotin system is less than 50%. The magnitude of the affinity constant and force per bond for the avidin-biotin system are consistent with detachment by extraction of receptors from the cell. The resulting increase in the adhesion strength on surfaces with both avidin-biotin and fibronectin is due to the increase in contact area and the larger number of bonds formed.