Immunomodulatory activity of SGI-110, a 5-aza-2'-deoxycytidine-containing demethylating dinucleotide.

PURPOSE: Pharmacologic DNA hypomethylation holds strong promises in cancer immunotherapy due to its immunomodulatory activity on neoplastic cells. Searching for more efficient DNA hypomethylating agents to be utilized to design novel immunotherapeutic strategies in cancer, we investigated the immunomodulatory properties of the new DNA hypomethylating agent SGI-110, that is resistant to in vivo inactivation by cytidine deaminase. EXPERIMENTAL DESIGN: Cutaneous melanoma, mesothelioma, renal cell carcinoma, and sarcoma cells were treated in vitro with SGI-110. RT-PCR, quantitative RT-PCR, quantitative methylation-specific PCR, and flow cytometric analyses were performed to investigate changes induced by SGI-110 in the constitutive immune profile of cancer cells. The recognition by gp100-specific CTL of gp100-positive melanoma cells, treated or not with SGI-110, was tested by LDH release assays. RESULTS: SGI-110 induced/up-regulated the expression of investigated cancer/testis antigens (CTA) (i.e., MAGE-A1, MAGE-A2, MAGE-A3, MAGE-A4, MAGE-A10, GAGE 1-2, GAGE 1-6, NY-ESO-1, and SSX 1-5) in all cancer cell lines studied, both at mRNA and at protein levels. Quantitative methylation-specific PCR analyses identified a hypomethylation of MAGE-A1 and NY-ESO-1 promoters in SGI-110-treated neoplastic cells, demonstrating a direct role of pharmacologic DNA demethylation in CTA induction. SGI-110 also up-regulated the expression of HLA class I antigens and of ICAM-1, resulting in an improved recognition of cancer cells by gp100-specific CTL. CONCLUSIONS: Our findings show that SGI-110 is a highly attractive therapeutic agent to comprehensively increase immunogenicity and immune recognition of neoplastic cells, and provide the scientific rationale for its clinical development to design novel chemo-immunotherapeutic approaches in cancer patients.

Epigenetically regulated clonal heritability of CTA expression profiles in human melanoma.

The intratumoral heterogeneity of cancer testis antigens (CTA) expression, which is driven by promoter methylation status, may hamper the effectiveness of CTA-directed vaccination of melanoma patients. Thus, we investigated whether the intratumoral heterogeneity of CTA expression is inherited at cellular level, or evolves throughout cellular replication, leading to a phenotypically unstable tumor cell population with reduced immunogenicity and/or able to escape immune control. Utilizing a previously characterized ex vivo clonal model of intratumoral heterogeneity of CTA expression in melanoma, Mel 313 MAGE-A3-low clone 5 (clone 5(M3-low)) and MAGE-A3-high clone 14 (clone 14(M3-high)) were sub-cloned and analyzed for CTA profile. Molecular assays demonstrated that levels of MAGE-A3 expression were highly conserved among generated sub-clones, as compared to parental clones. A similar behavior was identified for an extensive panel of other CTA investigated. Inherited levels of MAGE-A3 expression correlated with the extent of promoter methylation among clone 5(M3-low) and clone 14(M3-high) sub-clones analyzed. Treatment of clone 5(M3-low) with a DNA hypomethylating agent (DHA) resulted in an up-regulated expression of MAGE-A3, which was inherited at single cell level, being still detectable at day 60 in its sub-clones. Bisulfite sequencing demonstrated that also MAGE-A3 promoter methylation status was inherited among sub-clones generated from DHA-treated clone 5(M3-low) and strictly correlated with MAGE-A3 expression levels in investigated sub-clones. Similar results were obtained for additional CTA studied. Altogether our findings demonstrate that constitutive and DHA-modified CTA profiles of melanoma cells are clonally inherited throughout cellular replications, thus providing relevant insights to improve the effectiveness of CTA-based immunotherapy.