Project description:Purpose: T-cell exhaustion limits immunotherapy for the treatment of solid tumors. While immune checkpoint blockade and adoptive T cell therapy (ACT) can mediate tumor regression, their potency is often determined by tumor burden. Here, we identified tumor burden-related pathway changes that are conducive to T-cell exhaustion. We then determined if microenvironmental reprogramming via epigenetic modulation could reverse T-cell exhaustion and improve immunotherapeutic responsiveness. Experimental Design: We developed a murine syngeneic tumor model wherein an increased burden ablated therapeutic responsiveness to ACT, which corresponded with systemic induction of T cell exhaustion. Transcriptome analysis of these large tumors allowed us to characterize changes to immunosuppressive pathway expression during class I histone deacetylase inhibitor (HDACi) MS-275 treatment. We then measured the therapeutic impact of MS-275 during ACT and assessed T-cell exhaustion by transcriptome/phenotypic analysis. Results: ACT durably regressed small tumors but failed to control large tumors, which were associated with systemic T-cell exhaustion and ablation of T-cell responses. Large tumors were defined by an immunosuppressive pathway signature. MS-275 reversed this pathway signature and promoted durable regression of large tumors during ACT. Prototypical exhaustion marker Tim-3 was selectively up-regulated in transferred T cells despite displaying a reduced exhaustion signature. Instead, we observed enhanced activation-dependent signaling correlating with enrichment of the IL2-STAT5 signaling axis. Activated CD8+ T-cell responses were predominantly skewed towards terminal effector cell-like CD44+ Tim-3hi TCF1- CD127- KLRG1+ differentiation. Conclusion: Tumor burden-induced pathway changes can be reversed through epigenetic reprogramming, enabling the conversion from T-cell exhaustion to effector lineage differentiation.

Project description:Adoptive cell therapy (ACT) with tumor-specific memory T cells has shown increasing efficacy in regressing solid tumors. However, tumor antigen heterogeneity represents a longitudinal challenge for durable clinical responses due to the therapeutic selective pressure for immune escape variants. Here, we demonstrate that delivery of class I histone deacetylase inhibitor, MS-275, promotes sustained tumor regression by synergizing with ACT in a coordinated manner to enhance cellular apoptosis. We find that MS-275 alters the tumor inflammatory landscape to support antitumor immunoactivation through the recruitment and maturation of cross-presenting CD103+ and CD8+ dendritic cells and depletion of regulatory T cells. Activated endogenous CD8+ T cell responses against non-target tumor antigens was critically required for the prevention of tumor recurrence. Importantly, MS-275 alters the immunodominance hierarchy by directing epitope spreading towards endogenous retroviral tumor-associated antigen, p15E. Our data suggest that MS-275 multi-mechanistically improves epitope spreading to promote long-term clearance of solid tumors.

Project description:Phase I trial to study the effectiveness of combining MS-275 with isotretinoin in treating patients who have metastatic or advanced solid tumors or lymphomas. MS-275 may stop the growth of cancer cells by blocking the enzymes necessary for their growth. Isotretinoin may help cancer cells develop into normal cells. MS-275 may increase the effectiveness of isotretinoin by making cancer cells more sensitive to the drug. MS-275 and isotretinoin may also stop the growth of solid tumors or lymphomas by stopping blood flow to the cancer. Combining MS-275 with isotretinoin may kill more cancer cells

Project description:Transciptional profiling of Calu6 tumors comparing 4 pooled untreated tumors to 5-azacytodine or 5-azacytodine + MS-275 (combined therapy) treated tumors Three-condition experiment, untreated vs. 5-Azacytodine tumors, and untreated vs. 5-azacytodine + MS-275 tumors: 4 pooled untreated tumors; 4 5-Azacytodine treated, 4 5-Azacytodine + MS-275 treated. Study used a loop design with dye-swap.

Project description:RATIONALE: MS-275 may stop the growth of cancer cells by blocking the enzymes necessary for their growth. PURPOSE: This phase I trial is studying the side effects and best dose of MS-275 in treating patients with advanced solid tumors or lymphoma.

Project description:Immune recognition of tumor-expressed antigens by cytotoxic CD8+ T lymphocytes is the foundation of adoptive T-cell therapy. However, therapy-induced selective pressure can sculpt the antigenicity of tumors resulting in the outgrowth of variants that have lost the target antigen. Interestingly, tumor relapse resulting from adoptive memory T cell transfer and boosting oncolytic viral vaccination can be prevented using Class I histone deacetylase inhibitor, MS-275. We demonstrate that concomitant drug delivery subverts the phenotype and suppressive function of tumor-infiltrating myeloid cells and reprograms them with the cytotoxic capacity to directly eliminate antigen-negative tumor cells. By enhancing the production of IFNγ within the tumor microenvironment, our data suggest that MS-275 modifies the local cytokine landscape in favor of antitumor myeloid cell polarization.

Project description:Esophageal cancers (ECs) are highly aggressive tumors with poor prognosis and few treatment options. This study investigated the possibility of treating esophageal squamous cell carcinoma (ESCC) and esophageal adenocarcinoma (EAC) cells by inhibitors of broad and specific histone deacetylases (HDACi; SAHA, MS-275, FK228) and/or of DNMT (Azacytidine, AZA). Drug targets (HDAC1,2,3 and DNMT1) were present in non-neoplastic (HET-1A), ESCC (OE21) and EAC (OE33) cell lines. All cell lines responded to HDACi by reduced HDAC activity and increased histone acetylation as well as to AZA by up-regulation of p21. Expression of drug targets remained largely unaffected by HDACi and AZA treatment. Importantly, cell viability, apoptosis, cell cycle dynamics and DNA damage were only affected by HDACi and/or AZA in ESCC and EAC, but not the non-neoplastic cells. This was specifically seen for the combination of MS-275 and AZA, leading to enhanced cancer cell selectivity and drug efficiency. By transcriptome analyses of MS-275, AZA and MS-275/AZA treated cells, known (e.g. p21) as well as novel regulated genes significantly associated with the cellular effects post HDACi and/or AZA treatment in ESCC and EAC cells were identified. Finally, human EC tissue specimens frequently expressed the actionable drug targets HDAC1/2/3 and DNMT1. In summary, a combined HDACi (MS-275)/AZA treatment is cancer cell selective and efficient in vitro. Since the majority of ECs express the drug targets in situ, this paves the way for further investigations of HDACi/AZA treatment in esophageal cancer cells and their translation into a clinico-pathological setting. To elucidate the transcriptome response to HDAC inhibitors of normal esophageal cells and esophageal tumor cells, total RNA was isolated from non-neoplastic esophageal epithelial cells (Het1A cells) a well as from two esophageal tumor cell lines (OE21 and OE33), respectively. Cells were treated with either MS-275, Azacytidine (AZA) or in combination of both. DMSO treatment was used as control in each case. Total RNA was isolated from cells 24 h after treatment and experiments were performed in biological triplicates.

Project description:Transciptional profiling of Calu6 tumors comparing 4 pooled untreated tumors to 5-azacytodine or 5-azacytodine + MS-275 (combined therapy) treated tumors

Project description:Esophageal cancers (ECs) are highly aggressive tumors with poor prognosis and few treatment options. This study investigated the possibility of treating esophageal squamous cell carcinoma (ESCC) and esophageal adenocarcinoma (EAC) cells by inhibitors of broad and specific histone deacetylases (HDACi; SAHA, MS-275, FK228) and/or of DNMT (Azacytidine, AZA). Drug targets (HDAC1,2,3 and DNMT1) were present in non-neoplastic (HET-1A), ESCC (OE21) and EAC (OE33) cell lines. All cell lines responded to HDACi by reduced HDAC activity and increased histone acetylation as well as to AZA by up-regulation of p21. Expression of drug targets remained largely unaffected by HDACi and AZA treatment. Importantly, cell viability, apoptosis, cell cycle dynamics and DNA damage were only affected by HDACi and/or AZA in ESCC and EAC, but not the non-neoplastic cells. This was specifically seen for the combination of MS-275 and AZA, leading to enhanced cancer cell selectivity and drug efficiency. By transcriptome analyses of MS-275, AZA and MS-275/AZA treated cells, known (e.g. p21) as well as novel regulated genes significantly associated with the cellular effects post HDACi and/or AZA treatment in ESCC and EAC cells were identified. Finally, human EC tissue specimens frequently expressed the actionable drug targets HDAC1/2/3 and DNMT1. In summary, a combined HDACi (MS-275)/AZA treatment is cancer cell selective and efficient in vitro. Since the majority of ECs express the drug targets in situ, this paves the way for further investigations of HDACi/AZA treatment in esophageal cancer cells and their translation into a clinico-pathological setting.

Project description:Adoptive cell therapy (ACT) using tumor-infiltrating lymphocytes (TILs) is effective in cancer patients, yet the profiles, specificity and dynamics of tumor clonotypes remain opaque. Using single-cell RNA/TCR-sequencing, clonotypes were tracked from baseline tumors to ACT products (ACTP) and post-ACT blood and tumor samples from 13 metastatic melanoma patients (NCT03475134). Furthermore, a predictor of tumor-reactive clonotypes was derived from the transcriptomic profiles of tumor-specific or bystander clones. Patients with clinical responses had tumors enriched in tumor-reactive TILs, preferentially expanding in-vitro to generate larger and more tumoricidal products and preferentially re-infiltrating tumors post-ACT. Conversely, lack of responses was associated with tumors devoid of tumor-reactive clonotypes and with cell products mostly composed of blood-borne clonotypes. The exhaustion state characterizing intratumoral tumor-reactive TILs was attenuated during in-vitro expansion and restored after tumor re-engraftment only in responders. Thus, tumor-reactive clonotypes drive clinical response to TIL therapy, providing insight to select patients or improve TILs’ culture.