Project description:Ribosome biogenesis has emerged as a potential target for cancer therapy. We have characterize a new biological activity of the antimalarial drug amodiaquine as a inhibitor of ribosome biogenesis. Interestingly, amodiaquine retains the autophagy inhibitory activity of its analog chloroquine, but in addition, displays properties of the ribosome biogenesis inhibitor BMH-21. We performed a RNAseq analysis to identify shared and unique mechanisms of action among these drugs. Gene expression was profiled in U2OS cell line, using 24 samples divided in 4 treatment groups: Untreated, Amodiaquine, Chloroquine and BMH-21, incubated with compounds for 12 hours.

Project description:We simultaneously characterized alterations of both ribosome quality and quantity in high grade adult-type diffuse glioma. Unexpectedly, we uncovered that glioblastomas display the most prominent defects in ribosomal RNA chemical modifications (quality) while astrocytomas and oligodendrogliomas rather exhibit changes in ribosome biogenesis (quantity). Moreover, glioma cell lines exhibit distinct responses to clinically evaluated RNA Pol I inhibitors, CX5461 and BMH-21. This study highlights theranostic opportunities provided by the ribosome field to improve the management of glioma patients.

Project description:Immune checkpoint blockade (ICB) has significantly improved the prognosis of cancer patients, but the majority experience limited benefit, evidencing the need for new therapeutic approaches. Upregulation of sialic acid-containing glycans, termed hypersialylation, is a common feature of cancer-associated glycosylation, driving disease progression and immune escape via the engagement of Siglec-receptors on tumor-infiltrating immune cells. Here, we show that tumor sialylation correlates with distinct immune states and reduced survival in human cancers. The targeted removal of Siglec-ligands in the tumor microenvironment, using an antibody-sialidase conjugate, enhances anti-tumor immunity and halts tumor progression in several mouse tumor models. Using single-cell RNA sequencing, we reveal desialylation mechanistically to repolarize tumor-associated macrophages (TAMs) and identify Siglec-E on TAMs as the main receptor for hypersialylation. Finally, we show genetic and therapeutic desialylation, as well as loss of Siglec-E, to synergize with ICB. Thus, therapeutic desialylation represents a novel immunotherapeutic approach, shaping macrophage phenotypes and augmenting the adaptive anti-tumor immune response.

Project description:Despite recent therapeutic progress, advanced melanoma remains lethal for many patients. The composition of the immune tumor microenvironment (TME) has decisive impacts on disease outcome and therapy response. High dimensional analyses of patient samples provide insight on the composition and heterogeneity of the immune TME. Macrophages are known for their cancer-supportive role, but the underlying mechanisms are incompletely understood, and experimental in vivo systems are needed to test the functional properties of these cells. We characterize a humanized mouse model, reconstituted with a human immune system and a human melanoma, in which: (1) human macrophages support metastatic spread of the tumor; and (2) tumor-infiltrating macrophages have a specific transcriptional signature that faithfully represents the transcriptome of macrophages from patient melanoma samples and is associated with shorter survival. This model complements patient sample analyses, enabling the elucidation of fundamental principles in melanoma biology, and the development and evaluation of candidate therapies.

Project description:Tumor-associated macrophages contribute to tumor pathogenesis and represent an attractive therapeutic target. We report that the proprotein convertase PC1/3 inhibits the TLR4 Myd88-pathway induced in macrophages by the anti-cancer agent Taxol. Thus, PC1/3 knock-down in these cells exacerbates the TLR4 MyD88-dependent pathway triggered by Taxol. In PC1/3 knock-down macrophages, Taxol drives the secretion of pro-inflammatory cytokines, inhibits STAT3 signaling and counteracts tumor-supportive activities, thus inhibiting viability, growth and invasion of glioblastoma cells. Proteomic analyses indicate that their secretomes are characterized by a unique protein profile supporting a specific paracrine anti-tumoral effect. These findings unravel the potential value of a new therapeutic strategy combining PC1/3 inhibition and activation of the TLR4 MyD88-dependent pathway to switch intra-tumoral macrophages toward an anti-tumoral immunophenotype.

Project description:hCINAP is essential for human 18S rRNA processing and ribosome assembly. hCINAP is highly expressed in human cancers and promotes cancer cell growth. To connect the role of hCINAP in ribosome biogenesis and tumor growth, genome-wide polysome profiling was performed to detect the regulation of hCINAP on ribosome assembly and translation control. The results showed taht hihgly expressed hCINAP promotes ribosome biogenesis and selectively modulates cancer-associated translatome to promote malignancy. This result provides important insights into the molecular mechanism underlying the role of hCINAP in tumorigenesis.

Project description:The objective of this study was to determine the effect of a small-molecule Pol I inhibitor, BMH-21, on rRNA synthesis in vivo. NET-seq was performed to determine the Pol I occupancy after BMH-21 treatment, as compared to vehicle-treatment (phosphate buffer control). Our findings suggest that BMH-21 treatment reduces Pol I occupancy on the rDNA template. Additionally, BMH-21 induces repositioning of Pol I in AT-rich rDNA regions that are directly upstream from GC-rich regions. This study suggests that BMH-21 is a powerful inhibitor of transcription by Pol I, and gives a potential mechanism of action for this inhibitor in vivo.

Project description:Prostaglandins (PGs) are inflammatory mediators. Aspirin-like non-steroidal anti-inflammatory drugs (NSAIDs) inhibit cyclooxygenase (COX), an initiating enzyme of PG biosynthesis1. Daily use of aspirin-like drugs lowers the risk of cancer death not only prophylactically but therapeutically suggesting critical roles of PGs in cancer. However, general mechanisms by which PGs contribute to progression of a wide variety of human cancers remain elusive. Here, using scRNAseq analysis comparing immune cells infiltrating human tumors and a syngeneic mouse tumor, we have dissected this issue. We found that in human tumors, COX is dominantly expressed in infiltrating myeloid cells, and, among PG receptors, PGE receptor EP4 and to a less extent EP2 are expressed in both T cells and myeloid cells. DEG analysis between PTGER4hi and PTGER4lo CD8+ T cells indicates downregulation of IL-2-STAT5 signaling, oxidative phosphorylation, glycolysis and Myc targets in EP4hi CD8+ T cells, as revealed by suppressed expression of IL-2 receptor subunit gene and genes of OXPHOS, glycolytic enzymes and ribosomal proteins (RPs). Similar downregulation of OXPHOS, glycolytic enzymes and RP genes is found in PTGER4hi myeloid cells. Notably, such downregulation of OXPHOS and RP genes was found in immune cells infiltrating LLC1 mouse tumor, and reversed by treatment of tumor-bearing mice with EP2 and EP4 antagonists. In vitro in CD8+ T cells, EP4 is induced upon TCR activation and PGE2 acts on EP4, downregulates Il2ra expression and suppresses expression of Myc and PGC-1, thereby impairing both mitochondria and glycolysis as well as ribosome biogenesis in these cells. Similarly, EP4 is induced upon activation in macrophages and PGE2 downregulates Myc and OXPHOS pathwaysin these cells irrespective of other stimuli. These results demonstrate that PGE2 shapes immunosuppressive tumor microenvironment by hampering bioenergetic metabolism and ribosome biogenesis in infiltrating immune cells via EP4 receptor.

Project description:Prostaglandins (PGs) are inflammatory mediators. Aspirin-like non-steroidal anti-inflammatory drugs (NSAIDs) inhibit cyclooxygenase (COX), an initiating enzyme of PG biosynthesis1. Daily use of aspirin-like drugs lowers the risk of cancer death not only prophylactically but therapeutically suggesting critical roles of PGs in cancer. However, general mechanisms by which PGs contribute to progression of a wide variety of human cancers remain elusive. Here, using scRNAseq analysis comparing immune cells infiltrating human tumors and a syngeneic mouse tumor, we have dissected this issue. We found that in human tumors, COX is dominantly expressed in infiltrating myeloid cells, and, among PG receptors, PGE receptor EP4 and to a less extent EP2 are expressed in both T cells and myeloid cells. DEG analysis between PTGER4hi and PTGER4lo CD8+ T cells indicates downregulation of IL-2-STAT5 signaling, oxidative phosphorylation, glycolysis and Myc targets in EP4hi CD8+ T cells, as revealed by suppressed expression of IL-2 receptor subunit gene and genes of OXPHOS, glycolytic enzymes and ribosomal proteins (RPs). Similar downregulation of OXPHOS, glycolytic enzymes and RP genes is found in PTGER4hi myeloid cells. Notably, such downregulation of OXPHOS and RP genes was found in immune cells infiltrating LLC1 mouse tumor, and reversed by treatment of tumor-bearing mice with EP2 and EP4 antagonists. In vitro in CD8+ T cells, EP4 is induced upon TCR activation and PGE2 acts on EP4, downregulates Il2ra expression and suppresses expression of Myc and PGC-1, thereby impairing both mitochondria and glycolysis as well as ribosome biogenesis in these cells. Similarly, EP4 is induced upon activation in macrophages and PGE2 downregulates Myc and OXPHOS pathwaysin these cells irrespective of other stimuli. These results demonstrate that PGE2 shapes immunosuppressive tumor microenvironment by hampering bioenergetic metabolism and ribosome biogenesis in infiltrating immune cells via EP4 receptor.

Project description:Cancer cells rely on ATP-citrate lyase (Acly)-derived acetyl-CoA for lipid biogenesis and proliferation, marking Acly as promising therapeutic target. However, inhibitors may have side effects on tumor-associated macrophages (TAMs). TAMs are innate immune cells abundant in the tumor microenvironment (TME) and play central roles in tumorigenesis, progression and therapy response. Since macrophage Acly deletion was previously shown to elicit macrophages with a potential anti-tumor phenotype in vivo, we hypothesized that Acly targeting may elicit anti-tumor responses in macrophages, whilst inhibiting cancer cell proliferation. Here, we used a myeloid-specific knockout model to validate that absence of Acly decreases IL-4-induced macrophage activation. Using two distinct tumor models, we demonstrate that Acly deletion slightly alters tumor immune composition and TAM phenotype in a tumor type-dependent manner without affecting tumor growth. Together, our results indicate that targeting Acly in macrophages does not have detrimental effects on myeloid cells.