Project description:Melanoma is one of the solid tumor types with the highest risk of brain metastasis. However, the biology of melanoma brain metastasis and the contribution of the brain immune microenvironment to the responses to therapies remain insufficiently characterized. By using preclinical models and single-cell transcriptomics, we identify microglia, as critical regulators of melanoma biology in the brain. We show that activation of the Rela/NF-kB pathway in microglia promotes melanoma brain metastasis and that targeting this pathway elicits microglia reprogramming towards a pro-inflammatory phenotype that enhances anti-tumor immunity and reduces brain metastatic burden. Additionally, canonical and pro-inflammatory microglial markers in melanoma brain metastasis correlate with better responses to immune checkpoint inhibitors in patients and we show that Rela/NF-kB targeting improves responses to these therapies in the brain. Thus, we propose targeting Rela/NF-kB in activated microglia as a strategy to promote anti-tumor immunity and to improve the response to immune checkpoint inhibitors in melanoma brain metastasis.

Project description:Melanoma is one of the solid tumor types with the highest risk of brain metastasis. However, the biology of melanoma brain metastasis and the contribution of the brain immune microenvironment to the responses to therapies remain insufficiently characterized. By using preclinical models and single-cell transcriptomics, we identify microglia, as critical regulators of melanoma biology in the brain. We show that activation of the Rela/NF-kB pathway in microglia promotes melanoma brain metastasis and that targeting this pathway elicits microglia reprogramming towards a pro-inflammatory phenotype that enhances anti-tumor immunity and reduces brain metastatic burden. Additionally, canonical and pro-inflammatory microglial markers in melanoma brain metastasis correlate with better responses to immune checkpoint inhibitors in patients and we show that Rela/NF-kB targeting improves responses to these therapies in the brain. Thus, we propose targeting Rela/NF-kB in activated microglia as a strategy to promote anti-tumor immunity and to improve the response to immune checkpoint inhibitors in melanoma brain metastasis.

Project description:The NF-kB family of transcription factors orchestrates signal-induced gene expression in a diversity of cell types. Cellular responses to NF-kB activation are regulated at the level of cell- and signal-specificity, as well as differential use of family members (subunit specificity). Here we used time-dependent multi-omics to investigate selective functions of Rel and RelA, two closely related NF-kB proteins, in primary B lymphocytes activated via the B cell receptor. Despite large numbers of shared binding sites genome wide, Rel and RelA directed kinetically distinct cascades of gene expression in activated B cells. Single-cell RNA-Seq revealed marked heterogeneity of Rel- and RelA-specific responses and sequential binding of these factors was not a major mechanism of protracted transcription. Moreover, nuclear co-expression of Rel and RelA led to functional antagonism between the two factors. By rigorously identifying target genes of each NF-kB subunit, these studies provide insights into exclusive functions of Rel and RelA in immunity and cancer.

Project description:The NF-kB family of transcription factors orchestrates signal-induced gene expression in a diversity of cell types. Cellular responses to NF-kB activation are regulated at the level of cell- and signal-specificity, as well as differential use of family members (subunit specificity). Here we used time-dependent multi-omics to investigate selective functions of Rel and RelA, two closely related NF-kB proteins, in primary B lymphocytes activated via the B cell receptor. Despite large numbers of shared binding sites genome wide, Rel and RelA directed kinetically distinct cascades of gene expression in activated B cells. Single-cell RNA-Seq revealed marked heterogeneity of Rel- and RelA-specific responses and sequential binding of these factors was not a major mechanism of protracted transcription. Moreover, nuclear co-expression of Rel and RelA led to functional antagonism between the two factors. By rigorously identifying target genes of each NF-kB subunit, these studies provide insights into exclusive functions of Rel and RelA in immunity and cancer.

Project description:The NF-kB family of transcription factors orchestrates signal-induced gene expression in a diversity of cell types. Cellular responses to NF-kB activation are regulated at the level of cell- and signal-specificity, as well as differential use of family members (subunit specificity). Here we used time-dependent multi-omics to investigate selective functions of Rel and RelA, two closely related NF-kB proteins, in primary B lymphocytes activated via the B cell receptor. Despite large numbers of shared binding sites genome wide, Rel and RelA directed kinetically distinct cascades of gene expression in activated B cells. Single-cell RNA-Seq revealed marked heterogeneity of Rel- and RelA-specific responses and sequential binding of these factors was not a major mechanism of protracted transcription. Moreover, nuclear co-expression of Rel and RelA led to functional antagonism between the two factors. By rigorously identifying target genes of each NF-kB subunit, these studies provide insights into exclusive functions of Rel and RelA in immunity and cancer.

Project description:The NF-kB family of transcription factors orchestrates signal-induced gene expression in a diversity of cell types. Cellular responses to NF-kB activation are regulated at the level of cell- and signal-specificity, as well as differential use of family members (subunit specificity). Here we used time-dependent multi-omics to investigate selective functions of Rel and RelA, two closely related NF-kB proteins, in primary B lymphocytes activated via the B cell receptor. Despite large numbers of shared binding sites genome wide, Rel and RelA directed kinetically distinct cascades of gene expression in activated B cells. Single cell RNA-Seq revealed marked heterogeneity of Rel- and RelA-specific responses and sequential binding of these factors was not a major mechanism of protracted transcription. Moreover, nuclear co-expression of Rel and RelA led to functional antagonism between the two factors. By rigorously identifying target genes of each NF-kB subunit, these studies provide insights into exclusive functions of Rel and RelA in immunity and cancer.

Project description:The NF-kB family of transcription factors orchestrates signal-induced gene expression in a diversity of cell types. Cellular responses to NF-kB activation are regulated at the level of cell- and signal-specificity, as well as differential use of family members (subunit specificity). Here we used time-dependent multi-omics to investigate selective functions of Rel and RelA, two closely related NF-kB proteins, in primary B lymphocytes activated via the B cell receptor. Despite large numbers of shared binding sites genome wide, Rel and RelA directed kinetically distinct cascades of gene expression in activated B cells. Single-cell RNA-Seq revealed marked heterogeneity of Rel- and RelA-specific responses and sequential binding of these factors was not a major mechanism of protracted transcription. Moreover, nuclear co-expression of Rel and RelA led to functional antagonism between the two factors. By rigorously identifying target genes of each NF-kB subunit, these studies provide insights into exclusive functions of Rel and RelA in immunity and cancer.

Project description:microRNA-7-5p (miR-7-5p) is an established tumor suppressor in multiple cancer types and inhibits growth and invasion by suppressing expression and activity of the epidermal growth factor receptor (EGFR) signaling pathway. While melanoma is not typically driven by EGFR signaling, expression of miR-7-5p is reduced in metastatic tumors compared to primary melanoma. Here, we investigated the biological and clinical significance of miR-7-5p in melanoma. Our results showed that augmenting miR-7-5p expression in vitro markedly reduced tumor cell viability, colony formation and induced cell cycle arrest. Furthermore, ectopic expression of miR-7-5p reduced migration and invasion of melanoma cells in vitro and reduced melanoma lung colonizationmetastasis in vivo. To investigate the mechanism underlying this effect, we used cDNA microarray analysis to identify a subset of putative miR-7-5p target genes associated with melanoma and metastasis. Of these, we confirmed nuclear factor kappa B (NF-κB) subunit RelA, as a novel direct target of miR-7-5p in melanoma cells, such that miR-7-5p suppresses NF-κB activity to decrease expression of canonical NF-κB target genes, including IL-1a, IL-6 and IL-8. Importantly, the effects of miR-7-5p on melanoma cell growth, cell cycle, migration and invasion were recapitulated by RelA knockdown. Finally, analysis of gene array datasets from multiple melanoma patient cohorts revealed an association between elevated RelA expression and poor survival, further emphasizing the clinical significance of RelA and its downstream signaling effectors.. Taken together, our data suggest that miR-7-5p replacement therapy might have clinical utility in melanoma to inhibit the metastatic process, in part through its inactivation of RelA/NF-kB signaling. Total RNA was extracted from WM266-4 cells transfected with miR-NC or miR-7-5p precursor molecules (30 nM) for 24 h, using Qiazol reagent (Qiagen).

Project description:The canonical NF-kB module induces nuclear translocation of RelA heterodimers from the latent cytoplasmic complexes. RelA directs inflammatory immune responses against microbial entities. However, aberrant RelA activity also triggers destructive inflammation, including those associated with inflammatory bowel disease (IBD). What provokes this pathological RelA activity remains unclear. As such, the noncanonical NF-kB pathway activates RelB heterodimers and mediates immune organogenesis. Because NF-kB-activating pathways are interlinked, we asked if noncanonical NF-kB signaling exacerbated intestinal inflammation. Our investigation revealed recurrent engagement of the noncanonical pathway in human IBD. In a mouse model of chemical colitis, the noncanonical NF-kB signaling gene Nfkb2 aggravated inflammation by amplifying the RelA activity induced in intestinal epithelial cells. Our mechanistic studies clarified that noncanonical signaling augmented the abundance of latent RelA complexes leading to hyperactive canonical NF-kB response in the colitogenic gut. In sum, latent dimer homeostasis appears to link noncanonical NF-kB signaling to RelA-driven inflammatory pathologies.

Project description:Adaptive immunity and the five vertebrate NF-kB/Rel family members first appeared in cartilaginous fish, suggesting that NF-kB family expansion allowed the acquisition of new functions to regulate adaptive immune responses. Transcriptome profiling revealed that, even in macrophages, the NF-kB family member, c-Rel, most potently regulates a cytokine gene linked to adaptive immunity, Il12b, with limiting roles at key regulators of innate immunity. Neofunctionalization of c-Rel to regulate Il12b depends on its unique DNA-binding properties, which we examined using structural, biochemical, functional, and genomic approaches. Among our findings was functional c-Rel homodimer binding to motifs with little resemblance to canonical NF-kB motifs. To determine whether c-Rel’s unique binding properties drove c-Rel-RelA divergence, we compared binding properties in various vertebrate species. c-Rel-RelA binding properties diverged in mammals and amphibians but were comparable in earlier vertebrates, suggesting that divergent DNA binding emerged relatively late during vertebrate evolution to support increasing complexity of adaptive immune regulation.