Oligonucleotide N3' --> P5' thio-phosphoramidate telomerase template antagonists as potential anticancer agents.

Human telomerase is a reverse transcriptase that is expressed in essentially all cancer cells, but not in the vast majority of normal somatic cells. Therefore, the specific inhibition of telomerase activity in tumors might have significant beneficial therapeutic effects. We have designed and evaluated oligonucleotide N3' --> P5' thio-phosphoramidates as telomerase template antagonists. In biochemical cell-free assays 11-13-mer thio-phosphoramidate oligonucleotides demonstrated sequence specific and dose dependent inhibition of telomerase with pico-molar IC50 values. Optimization of the oligonucleotide sequence and length resulted in the identification of a 13-mer-oligonucleotide thio-phosphoramidate GRN163 as a drug development candidate. In cell cultures GRN163 was able to inhibit telomerase activity in the absence of cationic lipid with approximately 1 microM IC50 values. Telomerase inhibition by GRN163 produced gradual telomere shortening, followed by cellular senescence and/or apoptosis of cancer derived cell lines.

Novel short oligonucleotide conjugates as inhibitors of human telomerase.

A series of oligonucleotide conjugates were designed and synthesized as novel inhibitors of human telomerase. These compounds contain a relatively short (6-7-mer) oligonucleotide domain, with an N3'-->P5' phosphoramidate (np) or thio-phosphoramidate (nps) backbone, targeted to the template region of the RNA component of the enzyme and various pendant groups attached to either their 5'- or preferably to the 3'-termini. The most potent compounds in the series inhibited telomerase with low nM IC50 values in biochemical assays whereas the cognate oligonucleotides without the pendant groups were significantly less active having IC50 values 100-1000-fold higher.

A novel telomerase template antagonist (GRN163) as a potential anticancer agent.

Telomerase, the enzyme responsible for proliferative immortality, is expressed in essentially all cancer cells, but not in most normal human cells. Thus, specific telomerase inhibition is potentially a universal anticancer therapy with few side effects. We designed N3'-->P5' thio-phosphoramidate (NPS) oligonucleotides as telomerase template antagonists and found that their ability to form stable duplexes with the telomerase RNA subunit was the key factor for antitelomerase activity. In biochemical assays 11-13-mer NPS oligonucleotides demonstrated sequence- and dose-dependent inhibition of telomerase with IC(50) values <1 nM. Optimization of the sequence, length, and bioavailability resulted in the selection of a 13-mer NPS oligonucleotide, GRN163, as a drug development candidate. GRN163 inhibited telomerase in a cell-free assay at 45 +/- 7 pM, and in various tumor cell lines at approximately 1 nM and approximately 0.3-1.0 micro M in the presence and absence of carriers, respectively. GRN163 was competitive with telomeric primer binding, primarily because of hybridization to human telomerase RNA (hTR) component. Tumor cells treated with GRN163 in culture underwent telomere shortening, followed by cellular senescence or apoptosis after a period of time that generally correlated with initial telomere length. In a flank DU145 (prostate cancer) xenograft model, parenterally administered GRN163 caused suppression of tumor growth in the absence of gross toxicity. These data demonstrate that GRN163 has significant potential for additional development as an anticancer agent.