Project description:Cardiac pathologies are characterized by intense remodeling of the extracellular matrix (ECM) that eventually leads to heart failure. Cardiomyocytes respond to the ensuing biomechanical stress by re-expressing fetal contractile proteins via transcriptional and post-transcriptional processes, like alternative splicing (AS). Here, we demonstrate that the heterogeneous nuclear ribonucleoprotein C (hnRNPC) is upregulated and relocates to the sarcomeric Z-disk upon ECM pathological remodeling. At this site, the protein participates to the localized translation of mRNAs encoding sarcomeric proteins. Alterations in hnRNPC expression and localization can be mechanically determined and affect the AS of numerous mRNAs involved in mechanotransduction and cardiovascular diseases. We thus propose that cardiac ECM remodeling serves as a switch in RNA metabolism by directly impacting an associated regulatory protein of the spliceosome apparatus. These findings offer new insights on the mechanism of mRNAs homeostasis mechanoregulation in disease conditions.

Project description:Cardiac pathologies are characterized by intense remodeling of the extracellular matrix (ECM) that eventually leads to heart failure. Cardiomyocytes respond to the ensuing biomechanical stress by re-expressing fetal contractile proteins via transcriptional and post-transcriptional processes, like alternative splicing (AS). Here, we demonstrate that the heterogeneous nuclear ribonucleoprotein C (hnRNPC) is upregulated and relocates to the sarcomeric Z-disk upon ECM pathological remodeling. At this site, the protein participates to the localized translation of mRNAs encoding sarcomeric proteins. Alterations in hnRNPC expression and localization can be mechanically determined and affect the AS of numerous mRNAs involved in mechanotransduction and cardiovascular diseases. We thus propose that cardiac ECM remodeling serves as a switch in RNA metabolism by directly impacting an associated regulatory protein of the spliceosome apparatus. These findings offer new insights on the mechanism of mRNAs homeostasis mechanoregulation in disease conditions.

Project description:hNRNPC iCLIP

Project description:Cancer cells often co-opt post-transcriptional regulatory mechanisms to achieve pathologic expression of gene networks that drive metastasis. Translational control is a major regulatory hub in oncogenesis, however its effects on cancer progression remain poorly understood. To address this, we used ribosome profiling to compare genome-wide translation efficiencies of poorly and highly metastatic breast cancer cells and patient-derived xenografts. We developed novel regression-based methods to analyze ribosome profiling and alternative polyadenylation data, and identified HNRNPC as a translational controller of a specific mRNA regulon. Mechanistically, HNRNPC, in concert with PABPC4, binds near to poly(A) signals, thereby governing the alternative polyadenylation of a set of mRNAs. We found that HNRNPC and PABPC4 are downregulated in highly metastatic cells, which causes HNRNPC-bound mRNAs to undergo 3’ UTR lengthening and subsequently, translational repression. We showed that modulating HNRNPC expression impacts the metastatic capacity of breast cancer cells in xenograft mouse models. We also found that a small molecule, previously shown to induce a distal-to-proximal poly(A) site switching, counteracts the HNRNPC-PABPC4 driven deregulation of alternative polyadenylation and decreases the metastatic lung colonization by breast cancer cells in vivo.

Project description:Cancer cells often co-opt post-transcriptional regulatory mechanisms to achieve pathologic expression of gene networks that drive metastasis. Translational control is a major regulatory hub in oncogenesis, however its effects on cancer progression remain poorly understood. To address this, we used ribosome profiling to compare genome-wide translation efficiencies of poorly and highly metastatic breast cancer cells and patient-derived xenografts. We developed novel regression-based methods to analyze ribosome profiling and alternative polyadenylation data, and identified HNRNPC as a translational controller of a specific mRNA regulon. Mechanistically, HNRNPC, in concert with PABPC4, binds near to poly(A) signals, thereby governing the alternative polyadenylation of a set of mRNAs. We found that HNRNPC and PABPC4 are downregulated in highly metastatic cells, which causes HNRNPC-bound mRNAs to undergo 3’ UTR lengthening and subsequently, translational repression. We showed that modulating HNRNPC expression impacts the metastatic capacity of breast cancer cells in xenograft mouse models. We also found that a small molecule, previously shown to induce a distal-to-proximal poly(A) site switching, counteracts the HNRNPC-PABPC4 driven deregulation of alternative polyadenylation and decreases the metastatic lung colonization by breast cancer cells in vivo.

Project description:The purpose of this experiment was to compare differences in Alu-exon inclusion in cells depleted of hnRNPC, Upf1, or both.

Project description:HNRNPC plays an important role in HCC metastasis, HNRNPC knockdown by specific shRNA (HNRNPC-shRNA) significantly inhibited the migration and invasion of MHCC97H cells, while HNRNPC overexpression exerted the opposite effect. To elucidate the mechanisms by which HNRNPC facilitated HCC metastasis, we performed microarray analysis to compare the transcription profiling between the MHCC97H-shcontrol and MHCC97H-shHNRNPC cells.

Project description:Elevated expression of RNA binding protein HNRNPC has been reported in cancer cells, while the essentialness and functions of HNRNPC in tumors were not clear. We showed that repression of HNRNPC in the breast cancer cells MCF7 and T47D inhibited cell proliferation and tumor growth. Our computational inference of the key pathways and extensive experimental investigations revealed that the cascade of interferon responses mediated by RIG-I was responsible for such tumor-inhibitory effect. Interestingly, repression of HNRNPC resulted in accumulation of endogenous double-stranded RNA (dsRNA), the binding ligand of RIG-I. These up-regulated dsRNA species were highly enriched by Alu sequences and mostly originated from pre-mRNA introns that harbor the known HNRNPC binding sites. Such source of dsRNA is different than the recently well-characterized endogenous retroviruses that encode dsRNA. In summary, essentialness of HNRNPC in the breast cancer cells was attributed to its function in controlling the endogenous dsRNA and the down-stream interferon response. This is a novel extension from the previous understandings about HNRNPC in binding with introns and regulating RNA splicing.

Project description:To define and compare the interactomes of the RNA binding protein HNRNPC in poorly vs. efficiently metastatic breast adenocarcinoma cells, we carried out immunoprecipitation of endogenous HNRNPC from parental MDA-MB231 cells vs. its highly metastatic isogenic derivate, the MDA-MB231-LM2 cells. We used a non-specific MOUSE IgG IP from each line as control. Each IP was performed in triplicate, and analysed by LC-MS/MS, on a Thermo Q-Exactive-plus instrument.

Project description:Endogenous double-stranded RNA is prevented from activating the cytosolic antiviral receptor MDA5 by adenosine-to-inosine editing by ADAR. Consequently, CRISPR/cas9 targeting ADAR in the human monocytic cell line THP-1 induces a spontaneous MDA5-dependent interferon response. This response is synergistically enhanced by concomitant CRISPR/cas9 targeting of hnRNPC. For this study, cas9 transgenic THP-1 were nucleofected with combinations of control gRNA, ADAR gRNA or hnRNPC gRNA to elucidate the basis for synergistic interferon-stmulated gene induction by combined ADAR and hnRNPC targeting. As a control for interferon-stimulated gene induction, IFN-alpha treated THP-1 were included, as well. To investigate potential interferon inducing mechanisms, we quantified gene expression, intron expression as well as the expression of regions rich in adenosine-to-inosine editing clusters. In a second part, nuclear vs cytosolic distribution of RNA rich in adenosine-to-inosine clusters was investigated by sequencing of total RNA or RNA from cytosolic and nuclear extracts of ADAR and/or hnRNPC targeted cells. In the first part of the study, STING-deficient, cas9 transgenic THP-1 were nucleofected with combinations of control, GFP-targeting, ADAR-targeting or hnRNPC-targeting gRNA and cells collected for total RNA extraction on days three, four and five after nucleofection. In addition, another control-nucleofected sample was treated on day 3 for 24 h. The experiment was repeated three times leading to three replicates per condition. In the second part, WT cas9-transgenic THP-1 were nucleofected with combinations of control, ADAR-targeting or hnRNPC-targeting gRNA and cells were either collected for total RNA extraction or separated into digitonin-soluble (cytosolic) and digitonin-resistant (nuclear and mitochondrial) compartments and then RNA extracted. The experiment was repeated twice leading to two replicates per condition. Differential gene expression analysis confirmed synergistic induction of interferon-stimulated genes. RNA-seq analysis demonstrated dysregulation of Alu-containing introns in hnRNPC-deficient cells via utilization of unmasked cryptic splice sites, including introns containing ADAR-dependent A-to-I editing clusters or regions enriched in editing clusters (ECRs) in general. These putative MDA5 ligands showed reduced editing in the absence of ADAR, providing a plausible mechanism for the combined effects of hnRNPC and ADAR. Part 2 of the study confirmed cytosolic access of a subset of ECRs to the cytosol.