Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Depleting the microenvironment of important nutrients such as arginine is a key strategy for immune evasion by cancer cells. Many tumors overexpress arginase but it is unclear how these cancers, but not T-cells, tolerate arginine depletion. Here, we show that tumor cells synthesize arginine from citrulline by upregulating argininosuccinate synthetase 1 (ASS1). Under arginine starvation, ASS1 transcription is induced by ATF4 and CEBPbeta binding to a previously uncharacterized enhancer within ASS1. T-cells cannot induce ASS1, despite the presence of active ATF4 and CEBPbeta, as the gene is repressed. Arginine starvation drives global chromatin compaction and repressive histone methylation which disrupts ATF4/CEBPbeta binding and target gene transcription. We find that T-cell activation is impaired in arginine-depleted conditions, with significant metabolic perturbation linked to incomplete chromatin remodeling and misregulation of key genes. Our results highlight a T-cell behavior mediated by nutritional stress, exploited by cancer cells to enable pathological immune evasion.

Project description:Depleting the microenvironment of important nutrients such as arginine is a key strategy for immune evasion by cancer cells. Many tumors overexpress arginase but it is unclear how these cancers, but not T-cells, tolerate arginine depletion. Here, we show that tumor cells synthesize arginine from citrulline by upregulating argininosuccinate synthetase 1 (ASS1). Under arginine starvation, ASS1 transcription is induced by ATF4 and CEBPbeta binding to a previously uncharacterized enhancer within ASS1. T-cells cannot induce ASS1, despite the presence of active ATF4 and CEBPbeta, as the gene is repressed. Arginine starvation drives global chromatin compaction and repressive histone methylation which disrupts ATF4/CEBPbeta binding and target gene transcription. We find that T-cell activation is impaired in arginine-depleted conditions, with significant metabolic perturbation linked to incomplete chromatin remodeling and misregulation of key genes. Our results highlight a T-cell behavior mediated by nutritional stress, exploited by cancer cells to enable pathological immune evasion.

Project description:Depleting the microenvironment of important nutrients such as arginine is a key strategy for immune evasion by cancer cells. Many tumors overexpress arginase but it is unclear how these cancers, but not T-cells, tolerate arginine depletion. Here, we show that tumor cells synthesize arginine from citrulline by upregulating argininosuccinate synthetase 1 (ASS1). Under arginine starvation, ASS1 transcription is induced by ATF4 and CEBPbeta binding to a previously uncharacterized enhancer within ASS1. T-cells cannot induce ASS1, despite the presence of active ATF4 and CEBPbeta, as the gene is repressed. Arginine starvation drives global chromatin compaction and repressive histone methylation which disrupts ATF4/CEBPbeta binding and target gene transcription. We find that T-cell activation is impaired in arginine-depleted conditions, with significant metabolic perturbation linked to incomplete chromatin remodeling and misregulation of key genes. Our results highlight a T-cell behavior mediated by nutritional stress, exploited by cancer cells to enable pathological immune evasion.

Project description:Chromatin accessibility governs the differential response of cancer and T-cells to arginine starvation

Project description:Chromatin accessibility governs the differential response of cancer and T-cells to arginine starvation (ChIP-seq)

Project description:Chromatin accessibility governs the differential response of cancer and T-cells to arginine starvation (ATAC-seq)

Project description:Chromatin accessibility governs the differential response of cancer and T-cells to arginine starvation (Illumina HumanHT-12 V4.0 beadchip)

Project description:Myeloid lineage cells use TLRs to recognize and respond to diverse microbial ligands. Although unique transcription factors dictate the outcome of specific TLR signaling, whether lineage-specific differences exist to further modulate the quality of TLR-induced inflammation remains unclear. Comprehensive analysis of global gene transcription in human monocytes, monocyte-derived macrophages, and monocyte-derived dendritic cells stimulated with various TLR ligands identifies multiple lineage-specific, TLR-responsive gene programs. Monocytes are hyperresponsive to TLR7/8 stimulation that correlates with the higher expression of the receptors. While macrophages and monocytes express similar levels of TLR4, macrophages, but not monocytes, upregulate interferon-stimulated genes (ISGs) in response to TLR4 stimulation. We find that TLR4 signaling in macrophages uniquely engages transcription factor IRF1, which facilitates the opening of ISG loci for transcription. This study provides a critical mechanistic basis for lineage-specific TLR responses and uncovers IRF1 as a master regulator for the ISG transcriptional program in human macrophages.

Project description:Treatment of advanced prostate cancer is challenging due to a lack of effective therapies. Therefore, it is important to understand the molecular mechanisms underlying therapeutic resistance in prostate cancer and to identify promising drug targets offering significant clinical advantages. Given the pivotal role of dysregulated transcriptional programs in the therapeutic response, it is essential to prioritize translational efforts targeting cancer-associated transcription factors (TFs). The present study investigated whether chromatin accessibility was associated with therapeutic resistance in prostate cancer using Assay for Transposase-Accessible Chromatin with sequencing (ATAC-seq) data. The bioinformatics analysis identified differences in chromatin accessibility between the drug response (Remission) and drug resistance (Disease) groups. Additionally, a significant association was observed between chromatin accessibility, transcriptional output and TF activity. Among TFs, forkhead box protein M1 (FOXM1) was identified as a TF with high activity and expression in the Disease group. Notably, the results of the computational analysis were validated by FOXM1 knockdown experiments, which resulted in suppressed cell proliferation and enhanced therapeutic sensitivity in prostate cancer cells. The present findings demonstrated that chromatin accessibility and TF activity may be associated with therapeutic resistance in prostate cancer. Additionally, these results provide the basis for future investigations aimed at understanding the molecular mechanisms of drug resistance and developing novel therapeutic approaches for prostate cancer.