Project description:Cancer immunotherapy using monoclonal antibodies (mAbs) to immune checkpoint (e.g., PD-1) has revolutionized the cancer treatments with long-term clinical benefits and being applicable to a wide range of tumors. However, a significant fraction of cancer patients does not respond to PD-1 blockade-based monotherapy. Considering the potential of combinatorial therapies in overcoming existing limitations of cancer immunotherapy, there is an increasing need to identify small-molecule modulators of immune cells capable of augmenting the effect of PD-1 blockade, leading to better cancer treatment. Although epigenetic drugs have shown potential in combination therapy, the lack of sequence specificity is a major concern. Pyrrole–imidazole polyamide (PIP), a selective DNA-binding small molecule, can guide epigenetic modulators to enable targeted gene activation. Here, we prepared and screened a library of PIPs encompassing the distinct PIPs conjugated with P300/CBP-selective bromodomain inhibitor (BI), which acts as a P300/CBP recruiter, and identified a PIP called BI-PIP-R that can trigger the targeted induction of the peroxisome proliferator-activated receptor-gamma coactivator 1 alpha/beta (PGC-1a/b), a regulator of mitochondrial activation and biogenesis. We further improved the chemical architecture of BI-PIP-R using a tri-arginine vector for better nuclear accumulation. This designer dual-functional molecule termed EnPGC-1 that enhanced mitochondrial activation, energy metabolism, proliferation of CD8+ T cells in vitro, and, in particular, enhanced oxidative phosphorylation (OXPHOS), a feature of long-lived memory T cells. Genome-wide gene analysis also suggested that EnPGC-1 and not the control compounds can regulate of T cell activation as a major biological process. EnPGC-1 also synergized with PD-1 blockade to enhance antitumor immunity and improved the survival. Together, this study represents the first example of a programmable DNA-based epigenetic drug with the potential to overcome the existing issues in cancer immunotherapy.

Project description:Artificial epigenetic switches are of increasing demand owing to the critical role of the dynamic epigenome in orchestrating genome-wide transcriptional activation. Recently, we divulged that certain epigenetically active small molecules called SAHA-PIPs containing the cell permeable pyrrole-imidazole polyamides (PIPs) as DNA recognition module and a histone deacetylases inhibitor SAHA as functional module, is capable of triggering targeted transcriptional activation of pluripotency and germ cell genes in mouse and human fibroblasts, respectively. Through microarray studies and functional analysis, here we demonstrate the first ever example about the remarkable ability of 32 different SAHA-PIPs to trigger transcriptional activation of their own unique set of genes and noncoding RNAs. QRT-PCR studies validated that certain SAHA-PIPs could induce several therapeutically important genes including KSR2 and SEMA6A to suggest its potential use as reagents capable of targeted transcriptional activation and as probe(s) to identify the functional relevance of the uncharacterized genes. Gene induction by each individual SAHA-PIP was measured after treating human dermal fibroblasts at 48 h time-point. Two libraries of SAHA-PIPs (SAHA-PIP 1-16 and 17-32) were investigated in different experiments and each experiment includes a vehicle (DMSO) treatment as a negative control.

Project description:Artificial epigenetic switches are of increasing demand owing to the critical role of the dynamic epigenome in orchestrating genome-wide transcriptional activation. Recently, we divulged that certain epigenetically active small molecules called SAHA-PIPs containing the cell permeable pyrrole-imidazole polyamides (PIPs) as DNA recognition module and a histone deacetylases inhibitor SAHA as functional module, is capable of triggering targeted transcriptional activation of pluripotency and germ cell genes in mouse and human fibroblasts, respectively. Through microarray studies and functional analysis, here we demonstrate the first ever example about the remarkable ability of 32 different SAHA-PIPs to trigger transcriptional activation of their own unique set of genes and noncoding RNAs. QRT-PCR studies validated that certain SAHA-PIPs could induce several therapeutically important genes including KSR2 and SEMA6A to suggest its potential use as reagents capable of targeted transcriptional activation and as probe(s) to identify the functional relevance of the uncharacterized genes. Gene induction by a SAHA-PIP and SAHA was measured after treating human dermal fibroblasts at 48 h time-point. Experiment includes a vehicle (DMSO) treatment as a negative control.

Project description:Artificial epigenetic switches are of increasing demand owing to the critical role of the dynamic epigenome in orchestrating genome-wide transcriptional activation. Recently, we divulged that certain epigenetically active small molecules called SAHA-PIPs containing the cell permeable pyrrole-imidazole polyamides (PIPs) as DNA recognition module and a histone deacetylases inhibitor SAHA as functional module, is capable of triggering targeted transcriptional activation of pluripotency and germ cell genes in mouse and human fibroblasts, respectively. Through microarray studies and functional analysis, here we demonstrate the first ever example about the remarkable ability of 32 different SAHA-PIPs to trigger transcriptional activation of their own unique set of genes and noncoding RNAs. QRT-PCR studies validated that certain SAHA-PIPs could induce several therapeutically important genes including KSR2 and SEMA6A to suggest its potential use as reagents capable of targeted transcriptional activation and as probe(s) to identify the functional relevance of the uncharacterized genes. Gene induction by a SAHA-PIP and SAHA was measured after treating human dermal fibroblasts at 48 h time-point. Experiment includes a vehicle (DMSO) treatment as a negative control.

Project description:G-protein-gated inward rectifying potassium channels (GIRKs) require Gβγ subunits and phosphorylated phosphatidylinositides (PIPs) for gating. Although studies have provided insight into these interactions, the mechanism of how these events are modulated by Gβγ and the binding affinity between PIPs and GIRKs remains poorly understood. Here, native ion mobility mass spectrometry is employed to directly monitor small molecule binding events to mouse GIRK2. GIRK2 binds the toxin tertiapin Q and PIPs selectively and with significantly higher affinity than other phospholipids. A mutation in GIRK2 that causes a rotation in the cytoplasmic domain, similarly to Gβγ-binding to the wild-type channel, revealed differences in the selectivity towards PIPs More specifically, PIP isoforms known to weakly activate GIRKs have decreased binding affinity. Additionally, denaturing mass spectrometry and tryptic digest liquid chromatography mass spectrometry analysis was performed to confirm phosphorylation to GIRK2.

Project description:Anti-PD-1 (aPD1) immunotherapy likely affects other immune cells including follicular helper CD4 T cells (Tfh) involved in germinal center (GC) responses. Little is known, however, about the effects of anti-PD-1 immunotherapy on non-cancer immune responses in humans. To investigate this question, we examined the impact of aPD1 immunotherapy for cancer on the Tfh-B cell axis responding to unrelated viral antigens. Following influenza vaccination, a subset of adults receiving aPD1 had more robust circulating Tfh (cTfh) responses than adults not receiving immunotherapy, and cTfh responses correlated with plasmablasts. PD-1 pathway blockade also resulted in transcriptional signatures of increased cellular proliferation in cTfh and responding B cells compared to controls.

Project description:The ability to modulate immune-inhibitory pathways using checkpoint blockade antibodies such as PD-1, PD-L1, and CTLA-4 represents a significant breakthrough in cancer therapy in recent years. This has driven interest in identifying small-molecule-immunotherapy combinations to increase the proportion of responses. Murine syngeneic models, which have a functional immune system, represent an essential tool for pre-clinical evaluation of new immunotherapies. However, immune response varies widely between models and the translational relevance of each model is not fully understood, making selection of an appropriate pre-clinical model for drug target validation challenging. Utilizing RNAseq transcriptomic profiling, we have characterised the changes in gene regulatory pathways and immune populations in CT26 mice after treatment with the combination of anti-PD-L1 and anti-CTLA-4 antibodies. At day 7 post tumor implant, the pathways analysis of differentially expressed genes indicated an enrichment for migration of leukocytes in response to inflammation and communication between innate and adaptive immune cells. Similarly, analysis of upstream regulators suggested that lipopolysaccharide, IL-1B, TNF, IFNG, and NFKB1A pathways associated with inflammation were activated. At day 14, pathways related T-helper cell signalling pathways were upregulated. In addition, upstream regulators of the lipopolysaccharide and IFNG pathway, as well STAT1 and IL21 pathway were enriched, indicative of innate and adaptive immune response to inflammation.

Project description:Immunotherapy has opened hitherto unknown possibilities to treat cancer. Whereas some cancer types (e.g. melanoma) can be efficiently treated, others lack measurable positive effects (e.g. PDAC). Moreover, stratification of responders/non-responders is only possible in some cancer types (e.g. melanoma). Hepatocellular carcinoma (HCC) has a dismal prognosis, limited treatment options and survival benefit, and represents a potential cancer entity for successful immunotherapy. Here, we investigated NASH-triggered HCC in the context PD-1-targeted immunotherapy. Using flow cytometry, single cell RNA sequencing, immunohistochemistry and mass spectrometric analyses, we found a progressive increase of CD8+PD-1+ effector T-cells with a unique profile of exhaustion and activation markers rising with murine and human NASH severity. Notably, late-stage HCC treatment with PD-1-targeted immunotherapy enhanced hepatic carcinogenesis in mice. Dissecting potential mechanisms of action during tumor-initiation and -progression we analyzed the effects of PD-1-targeted immunotherapy at HCC initiation. PD-1-targeted immunotherapy induced a pro-tumorigenic environment, enhanced necro-inflammation and increased NAFLD-activation score (NAS), leading to increased liver cancer incidence, tumor number and nodule size. In contrast, anti-CD8 or anti-CD8/anti-NK1.1 treatment reduced NAS and abrogated the development of liver cancer, thus identifying CD8+PD-1+ T-cells as drivers of liver cancer in NASH-triggered HCC. Increased apoptotic signaling, STAT3 phosphorylation and hepatic proliferation were detected in intra-tumoral liver tissue upon PD-1-targeted immunotherapy. In line, PD-1-/- mice challenged with a NASH diet displayed early onset of hepatocarcinogenesis, corroborating the pro-tumorigenic role of absent or reduced PD-1. Mechanistically PD-1-targeted immunotherapy mainly affected hepatic abundance of CD8+PD-1+ T-cells, instead of altering the quality of Tox+CXCR6+ expressing CD8+PD-1+TNF+CD39+Gzmb+ T-cells found in NASH livers, leading to an aggressive, pro-tumorigenic liver environment. Single-cell mapping of human NASH-, borderline NASH- or unaffected livers corroborated our preclinical NASH results. Moreover, in human NASH livers a correlation of hepatic CD8+, PD-1+, TNF+ T-cells with fibrosis and NASH severity was observed. Accordingly, HCC patients with NASH etiology display a sharp increase in intra- and peri-tumoral CD8+ PD-1+ T-cells. In a cohort of 65 patients recruited across 6 centers in Germany and Austria, patients with NAFLD/NASH-driven HCC responded worse to PD-1-targeted immunotherapy by Nivolumab or Pembrolizumab compared to non-NAFLD patients. This resulted in significant reduced overall survival, in trends of faster disease progression and reduced progression free survival. Histological analysis of livers derived from HCC patients treated with PD-1-targeted immunotherapy displayed high levels of intra and peri-tumoral CD8+ PD-1+ T-cells and Ki67+ hepatocytes. Taken together, these data indicate that PD-1-targeted immunotherapy induces immune-related adverse effects in NAFLD/NASH-driven HCC through CD8+PD-1+ T-cells. Our data call for stratification of HCC patients subjected to PD-1-targeted immunotherapy, with NAFLD being a negative predictor.

Project description:Exercise training (ExT) has shown antitumor effects in many preclinical cancer models. In the present study, we utilize MC38 and CT26 cells, which represent MSI and MSS colorectal carcinomas respectively, to study the effects and mechanisms of ExT alone or in combination with PD-1 based immunotherapy. Using treadmill running and PD-1/PD-L1 blockade, we demonstrated that post-implant exercise training has broad anticancer activities in murine models of CRC. Specifically, in MSI CRC models, ExT induces beneficial metabolic and immunological adaptations, leading to a more significant inhibition in tumors treated with PD-1/PD-L1 blockade, suggesting a genotype-directed combinatory therapy for the subgroup of CRC patients. Moreover, ExT might be a safe and alternative anticancer strategy for cancers resistant to the PD-1 based immunotherapy, such as patients with MSS CRC tumors.

Project description:Co-stimulatory receptors such as GITR play key roles in regulating the effector functions of T cells. Agonistic anti-GITR antibodies have been investigated as a cancer immunotherapy with demonstrated efficacy in pre-clinical models. In human clinical trials, however, GITR agonist antibodies have shown limited therapeutic effect which may be due to a suboptimal receptor clustering-mediated signaling. To overcome this potential limitation, a rational protein engineering approach is needed to optimize GITR agonist-based immunotherapies. Here we show a novel bispecific molecule consisting of an anti-PD-1 antibody fused with a multimeric GITR ligand (anti-PD-1-GITR-L) that induces a PD-1-dependent and FcγR-independent GITR clustering, resulting in an enhanced activation, proliferation, and memory differentiation of primed antigen-specific GITR+PD-1+ T cells. The anti-PD-1-GITR-L bispecific is a PD-1 directed GITR-L construct that has a different mechanism of action (MoA) than the co-administration of anti-PD-1 plus GITR-L and demonstrated a dose-dependent immunologically driven tumor growth inhibition in syngeneic, genetically engineered and xenograft humanized mouse tumor models. Combination of anti-PD-1-GITR-L with TGFβ inhibition or chemotherapy (gemcitabine), respectively, resulted in tumor remission in immunogenically cold and checkpoint blockade resistant mouse models. Dose-dependent correlations between target saturation and Ki67 and TIGIT up-regulation on memory T cells have been observed following a single dose of anti-PD-1-GITR-L bispecific in mice and non-human primates. Anti-PD-1-GITR-L thus represents a novel bispecific approach for directing GITR agonism for cancer immunotherapy.