Calcium channel blockers lercanidipine and amlodipine inhibit YY1/ERK/TGF-ß mediated transcription and sensitize the gastric cancer cells to doxorubicin.

Elevated expression of YY1 is known to confer anti-apoptotic phenotype and hence is an attractive target for cancer therapeutics. In a repurpose screening, towards the identification of the inhibitors of YY1 regulated transcription in gastric cancer cells, the calcium channel blockers lercanidipine and amlodipine have been identified to inhibit YY1 more efficiently. We further probed these calcium channel blockers for their potential feature of alleviating the drug resistance in gastric cancer cells. Lercanidipine and amlodipine were found to show an enhanced effect with doxorubicin in inhibiting the growth of gastric cancer cells. While doxorubicin was identified to activate the pathways TGF-ß and ERK/MAPK, lercanidipine was found to inhibit these pathways. This being the molecular mechanism behind the identified advantage of lercanidipine and amlodipine in sensitizing gastric cancer cells to doxorubicin. In multiple cellular models from different lineages, the cells with less sensitivity to doxorubicin were found to have the inherent activation of ERK/MAPK and TGF-ß pathways. Also, we have identified that doxorubicin, in combination with any of the calcium channel blockers, could inhibit the potential of cellular proliferation and spheroid formation in gastric cancer cells. The current study shows the usefulness of lercanidipine and amlodipine for the targeted and combinatorial therapeutics of gastric cancer and specifically to improve the efficiency of doxorubicin.

Development of a cell-based pathway modulator screening system to screen the targeted cancer therapeutic candidates.

To overcome the issues of poor prognosis and to tackle the non-responsiveness to various chemotherapeutics; it is necessary to develop targeted cancer therapeutic agents. Also, it is being necessary to understand the molecular targets of the drug candidates and drugs in the context of cellular signaling pathways, to make progress towards the development of targeted cancer therapeutics. Towards addressing these, we have established a cell-based and pathway-focused drug screening system for the pathways such as MYC, E2F, WNT, ERK, NRF1/2, HIF1α, p53, YY1 and NFκB. These signaling pathways are highly dysregulated in many cancers, including gastric cancer. The developed firefly luciferase assay-based screening system in gastric cancer lineage is suitable for the screening of the massive panel of drugs, drug candidates, small molecule inhibitors, chemicals and alternate drug formulations. The developed stable cell lines have been demonstrated for their pathway activity reporting features using the corresponding pathway-specific modulators. A proof-of-concept medium throughput screening focusing on YY1 signaling pathway also revealed the connection between calcium channel blockers and YY1 signaling. The developed signaling pathway screening assay cells are valuable resource and will serve as the screening platform for screening the drug libraries towards the development of targeted cancer therapeutics.

Abacavir induces the transcriptional activity of YY1 and other oncogenic transcription factors in gastric cancer cells.

Yin Yang 1 (YY1) is a ubiquitous transcription factor with both transcriptional activating and repressing functions. Targeting YY1 is considered as a potential therapeutic strategy for several malignancies. Telomerase Reverse Transcriptase (TERT) is also considered as a potential target for cancer therapeutics. To enable the large-scale screening and identification of potential YY1 targeting drugs, a gastric cancer cell line-based drug screening assay was developed. In a YY1 targeted drug repurpose screen, abacavir sulfate, a nucleoside analog reverse transcriptase inhibitor, known to target TERT was identified to show the feature of activating YY1 mediated transcription. We further explored i) the molecular targets of abacavir, ii) activation pattern of pathways regulated by abacavir in gastric tumors, and iii) therapeutic potential of abacavir for gastric cancer cells. Oncogenic signaling pathways like MYC, HIF1-α, ERK, WNT, E2F, NFκB and NRF1/2 were also found to be highly activated by abacavir. Abacavir was found to have less impact on the viability of gastric cancer cells. Across gastric tumors, we observed the co-activation of TERT, alternative lengthening of telomere (ALT), DNA repair, and the oncogenic pathways MYC, E2F/DP1, ERK, YY1, HIF1α, and NFκB specific gene-sets, in a subset of gastric tumors. The observed connectivity among TERT, DNA repair, and multiple oncogenic pathways indicate the need for the development of combinatorial therapeutics for the gastric tumors with the activated TERT.