Project description:Next-generation sequencing has revolutionized cancer biology by accelerating the unbiased discovery of novel mutations across human cancers. Transforming such discoveries into a conceptual framework of cancer progression requires narrowing the vast number of mutations down to the driver elements, and further reducing these to mutations that govern cancer progression as opposed to tumor initiation. By integrating next-generation RNA-sequencing (RNA-seq) with in vivo selection, we devise an approach that identifies a series of novel recurrent non-synonymous amino acid mutations that are enriched in metastatic breast cancer cells and predicted to significantly alter protein function. These mutations, found in PANX1, RBFA, REST, KRIT1 and ZSWIM6, are detected at higher frequencies in the transcriptomes of two patients’ highly metastatic sub-lines relative to their poorly metastatic parental lines. We functionally characterize the cellular and molecular roles of one of these mutations—a nonsense alteration that yields a truncated pannexin-1 (PANX11-89) plasma membrane megachannel subunit—in metastatic progression. PANX11-89 interacts with full-length PANX1 and augments PANX1 channel activity to promote the survival of cancer cells as they are mechanically deformed. Protection from deformation-induced cell death requires PANX1 channels to release ATP, which acts as a cell autonomous survival signal during mechanical stress. Functional characterization of additional nonsense and missense PANX1 mutations detected in epithelial cancers of the colon, lung, and prostate reveals that these mutants also enhance PANX1-mediated ATP release. In vivo testing of one such truncating mutation detected in a metastatic colorectal tumor also enhances early survival, dissemination and liver metastatic colonization by human colon cancer cells. Finally, pharmacological inhibition of PANX1 inhibits breast cancer metastasis, implicating PANX1 as a novel therapeutic target in cancer. Our findings reveal that ATP release through mechanosensitive PANX1 channels enables cancer cells to overcome a major metastasis suppressive barrier—deformation-induced death in the microvasculature. To systematically identify base-pair mutations present in metastatic cells that may drive cancer progression, we performed whole-transcriptome RNA-sequencing (RNA-seq) of in vivo-selected, highly metastatic human breast cancer cell sub-lines, CN-LM1A and MDA-LM2, as well as the CN34 and MDA-MB-231 parental lines from which they were derived. To minimize the false positive rate and allow for subsequent statistical analysis, we sequenced biological replicates of each cell line. Mutations conferring enhanced metastatic capacity should be enriched in the transcriptomes of highly metastatic cells relative to their less metastatic parental populations.

Project description:TNF is known to promote opening of the endothelial pannexin 1 (Panx1) membrane channel, allowing for ATP release, associated with inflammatory cell recruitment. However, there is evidence that Panx1 may be involved in the regulation of cellular inflammatory responses independent of direct ATP signalling, although the pathways have not been elucidated. We therefore examined Panx1 for roles in the control of cytokine release in human endothelial cells following treatment with TNF.

Project description:Sensing of extracellular metabolites controls CD8+ T cell function. Their accumulation can occur through export by specialized molecules, such as the release channel Pannexin-1 (Panx1). Here, we report that T cell-specific Panx1 is needed for efficient CD8+ T cell responses to viral infection and cancer. Panx1 favors both the expansion of effector CD8+ T cells and the survival of memory CD8+ T cells. Our data suggests that, while memory CD8+ T cells require Panx1 for mitochondrial function, Panx1 promotes the glycolytic pathway in effector CD8+ T cells. Panx1 promotes memory CD8+ T cell survival together with the eATP sensor P2RX7. However, Panx1 induces effector CD8+ T cells independently of eATP. Rather, we found an unexpected link between Panx1, sodium lactate export and the activation of effector CD8+ T cells. Therefore, Panx1 regulates effector and memory CD8+ T cells through export of distinct metabolites and by engaging different intracellular pathways.

Project description:Sensing of extracellular metabolites controls CD8+ T cell function. Their accumulation can occur through export by specialized molecules, such as the release channel Pannexin-1 (Panx1). Here, we report that T cell-specific Panx1 is needed for efficient CD8+ T cell responses to viral infection and cancer. Panx1 favors both the expansion of effector CD8+ T cells and the survival of memory CD8+ T cells. Our data suggests that, while memory CD8+ T cells require Panx1 for mitochondrial function, Panx1 promotes the glycolytic pathway in effector CD8+ T cells. Panx1 promotes memory CD8+ T cell survival together with the eATP sensor P2RX7. However, Panx1 induces effector CD8+ T cells independently of eATP. Rather, we found an unexpected link between Panx1, sodium lactate export and the activation of effector CD8+ T cells. Therefore, Panx1 regulates effector and memory CD8+ T cells through export of distinct metabolites and by engaging different intracellular pathways.

Project description:Pannexin 1 (Panx1) forms ATP-permeable membrane channels that play roles in the nervous system. The analysis of roles in both standard and pathological conditions benefits from a model organism with rapid development and early onset of behaviors. Such a model was developed by ablating the zebrafish panx1a gene using TALEN technology. Here, RNA-seq data of 6dpf wild type and knock-out zebrafish is reported which have been generated by gene editing of exon 4 of the panx1a gene.

Project description:Pannexin 1 (Panx1) forms ATP-permeable membrane channels that play roles in the nervous system. The analysis of roles in both standard and pathological conditions benefits from a model organism with rapid development and early onset of behaviors. Such a model was developed by ablating the zebrafish panx1a gene using TALEN technology. Here, RNA-seq data of 6dpf wild type and knock-out zebrafish is reported which have been generated by gene editing of exon 4 of the panx1a gene.

Project description:Pannexin 1 (Panx1) channels can be activated by alpha 1 adrenoceptor-induced pathways for the sympathetic regulation of blood pressure; however, the molecular mechanisms for this form of Panx1 channel activation remain elusive. To identify potential acetyl-lysine residue(s) of Panx1 channels that might be involved in this receptor-mediated Panx1 channel activation, we performed mass-spectrometry on Strep-tagged Panx1 proteins precipitated from the whole cell lysate of HEK293T cells after stable isotope labeling by amino acids in cell culture (SILAC). Those HEK293T cells were transiently transfected with alpha1D adrenoceptors and human Panx1-Strep, with or without phenylephrine stimulation. Equal amounts of light-labeled (control) and heavy-labeled (phenylephrine stimulated) cell lysates were pooled, and Panx1 proteins were precipitated by Strep-Tactin beads, followed by LC-MS-MS analysis. From three biological replicates, we identified a consistent, albeit modest, reduction of acetylation level at K140, following phenylephrine stimulation. Whereas the acetylation level of other lysine residues (K321, K374, K381, K409) were variable among three replicates or were unaffected by phenylephrine treatment. These results implicate Panx1 K140 as a potential regulatory site for receptor-mediated channel activation via an acetylation-deacetylation mechanism.

Project description:Dysfunctional paracrine signaling through Pannexin 1 (PANX1) channels is linked to several adult neurological pathologies and emerging evidence suggests that PANX1 plays an important role in human brain development. It remains unclear how early PANX1 influences brain development, or how loss of PANX1 alters the developing human brain. Using a cerebral organoid model of early human brain development, we find that PANX1 is expressed at all stages of organoid development from neural induction through to neuroepithelial expansion and maturation. Interestingly, PANX1 cellular distribution and subcellular localization changes dramatically throughout cerebral organoid development. During neural induction, PANX1 becomes concentrated at the apical membrane domain of neural rosettes where it co-localizes with several apical membrane adhesion molecules. During neuroepithelial expansion, PANX1-/- organoids are significantly smaller than control and exhibit significant gene expression changes related to cell adhesion, WNT signaling and non-coding RNAs. As cerebral organoids mature, PANX1 expression is significantly upregulated and is primarily localized to neuronal populations outside of the ventricular-like zones. Ultimately, PANX1 protein can be detected in all layers of a 21-22 post conception week human fetal cerebral cortex. Together, these results show that PANX1 is dynamically expressed by numerous cell types throughout embryonic and early fetal stages of human corticogenesis and loss of PANX1 compromises neuroepithelial expansion due to dysregulation of cell-cell and cell-matrix adhesion, perturbed intracellular signaling, and changes to gene regulation.

Project description:Apoptosis accounts for ~ 90% of homeostatic cell turnover in the body1. While caspase-dependent apoptosis is known to influence immune tolerance, induction of cell proliferation, and tissue regeneration2-4, how these apoptotic cells contribute to such diverse effects is less understood. Soluble factors released from apoptotic cells could be a means of ‘talking’ to healthy cells in the tissue neighborhood. While a few phagocyte-attracting ‘find-me’ signals released from apoptotic cells are known5, the larger ‘metabolite secretome’ from apoptotic cells is not yet defined. Here, via unbiased profiling of the apoptotic cell secretome, we identified 123 metabolites that are specifically released during apoptosis, while cells still retain membrane integrity. Release of ~25 of these metabolites is dependent on Pannexin 1 (Panx1) channels, which are opened by caspase-dependent cleavage during apoptosis. Interestingly, one of the Panx1-dependent metabolites from apoptotic cells is spermidine, a polyamine whose release could be, in part, due to the continued metabolic activity of dying cells. RNAseq analysis of healthy cells exposed to the apoptotic secretome revealed Panx1-dependent gene programs, including genes linked to suppression of inflammation, cell proliferation, and wound healing. Analysis of the apoptotic secretome across cell types and different apoptotic stimuli, identified a core “set” of 8 Panx1-dependent metabolites. Strikingly, a selected cocktail of these metabolites demonstrated significant immunosuppressive effects by potently reducing disease severity in an inflammatory arthritis model and a lung graft rejection model. Collectively, these data advance the concept that apoptotic cells are not ‘inert’ corpses waiting for removal by phagocytes, but rather they actively communicate with the tissue environment through their metabolite secretome, with implications in tissue inflammation.

Project description:<p>Osteocytes could release some small molecules (≤ 1 kDa) through gap junctions and hemichannels to extracellular environment, such as prostaglandin E2 (PGE2), nitric oxide (NO) and adenosine triphosphate (ATP), which play key roles in transferring signals between bone cells and other tissue cells. Connexin (Cx) 43 is the most abundant connexin in osteocytes. To further discover molecules released by osteocytes through Cx43 channels and better understand the regulatory function of Cx43 channels in osteocytes, we performed non-targeted global metabolomics analysis using liquid chromatography-tandem mass spectrometry (LC-MS/MS) on conditioned medium collected from osteocytes isolated from two transgenic mouse models with Cx43 dominant negative mutants driven by a 10 kb-DMP1 promoter: R76W (gap junctions are blocked, whereas hemichannels are promoted) and Δ130-136 (both gap junctions and hemichannels are blocked). The results revealed that several new categories of molecules, such as “fatty acyls” and “carboxylic acids and derivatives”, could be released through osteocytic Cx43 channels. In addition, alteration of Cx43 channel function affected the release of metabolites related to inflammatory reaction and oxidative stress. Pathway analysis further showed that citric acid cycle was the most differential metabolic pathway regulated by Cx43 channels. In sum, these results isolated new potential metabolites released by osteocytes through Cx43 channels, and offered a novel perspective to understand the regulatory mechanisms of osteocytes on themselves and other cells as well.</p>