Project description:Background: Cellular RNA binding proteins (RBPs) have multiple roles in post-transcriptional control, and some have been shown to bind DNA. However, the global localization and the general chromatin-binding ability of RBPs have not been well-characterized and remain undefined in hematopoietic cells. Results: We first provided a full view of RBPs’ distribution pattern in nucleus and screened for chromatin-enriched RBPs (Che-RBPs) in different human cells. Subsequently, by generating ChIP-seq, CLIP-seq and RNA-seq datasets and conducting combined analysis, the transcriptional regulatory potential of certain hematopoietic Che-RBPs were predicted and from which quaking (QKI5) emerged as a potential transcriptional activator during monocytic differentiation. QKI5 was over-represented in gene promoter regions, independent of RNA or transcription factors. Furthermore, promoter-occupied QKI5 activated the transcription of several critical monocytic differentiation-associated genes, including CXCL2, IL16 and PTPN6. Finally, we showed that the differentiation-promoting activity of QKI5 is largely dependent on CXCL2, irrespective of its RNA-binding capacity. Conclusions: Our study indicates that Che-RBPs are versatile factors that orchestrate gene expression in different cellular contexts, and identifies QKI5, a classic RBP regulating RNA processing, as a novel transcriptional activator during monocytic differentiation.

Project description:microRNAs (miRNAs) accomplish a remarkable variety of biological functions. Their expression is tightly controlled, and the final production of a miRNA is dependent on the cooperation of multiple mechanisms and their net effect. Here we show that miR-124-1 is transcriptionally activated during erythroid differentiation by GATA-1, however its post-transcriptional processing is attenuated. We found that QKI5 binds to a distal QKI response element (QRE) embedded in the primary transcript of miR-124-1 (pri-124-1) and modulates Microprocessor function by direct association with DGCR8. Strikingly, Microprocessor recruitment to pri-124-1 is disrupted upon RNAi-mediated depletion of QKI5, consistent with the decrease in mature miR-124. Moreover, addition of QKI5 increases the conversion efficiency of pri-124-1 in cell-free extracts. For erythropoiesis, the decreased QKI5 leads to attenuated Microprocessor-mediated processing of pri-124-1, which confers the exquisite miRNA abundance necessary for development. This regulation also gives rise to a unique miRNA signature required for normal erythropoiesis. Thus, this QKI5-regulated miRNA processing may represent a common paradigm for erythroid development, and specifically, it may serve as a post-transcriptional fault security to prevent misexpression of certain miRNAs, that is essential for the establishment of particular gene expression patterns during development. Two samples are analyzed: K562 cells transduced with GFP lentivirus; and K562 cells transduced with QKI5-overexpressing lentivirus.

Project description:microRNAs (miRNAs) accomplish a remarkable variety of biological functions. Their expression is tightly controlled, and the final production of a miRNA is dependent on the cooperation of multiple mechanisms and their net effect. Here we show that miR-124-1 is transcriptionally activated during erythroid differentiation by GATA-1, however its post-transcriptional processing is attenuated. We found that QKI5 binds to a distal QKI response element (QRE) embedded in the primary transcript of miR-124-1 (pri-124-1) and modulates Microprocessor function by direct association with DGCR8. Strikingly, Microprocessor recruitment to pri-124-1 is disrupted upon RNAi-mediated depletion of QKI5, consistent with the decrease in mature miR-124. Moreover, addition of QKI5 increases the conversion efficiency of pri-124-1 in cell-free extracts. For erythropoiesis, the decreased QKI5 leads to attenuated Microprocessor-mediated processing of pri-124-1, which confers the exquisite miRNA abundance necessary for development. This regulation also gives rise to a unique miRNA signature required for normal erythropoiesis. Thus, this QKI5-regulated miRNA processing may represent a common paradigm for erythroid development, and specifically, it may serve as a post-transcriptional fault security to prevent misexpression of certain miRNAs, that is essential for the establishment of particular gene expression patterns during development.

Project description:Nuclear fractionation reveals chromatin-enriched RNA binding proteins and transcriptional regulatory activity of QKI5 during monocytic differentiation

Project description:Mouse brains at E14.5 wild-type were subjected to HITS-CLIP to identify Qki5-binding positions on RNA.

Project description:A global screening identifies chromatin-enriched RNA-binding proteins and the transcriptional regulatory activity of QKI5 during monocytic differentiation

Project description:We performed QKI5 co-immunoprecipitation followed by MS analysis to identify QKI5-interacting proteins in THP-1 cells.

Project description:Che-1 is a RNA Polymerase II binding protein involved in the regulation of gene transcription. Che-1 emerges as an important adaptor that connects transcriptional regulation, cell-cycle progression, checkpoint control, and apoptosis. We have observed that Che-1 depletion sensitizes cells to chemotherapy. We used microarrays analysis to investigate classes of genes regulated by Che-1. Total RNA was extracted from control and Che-1 depleted HCT 116 cells 48 hours after transient transfection of siRNA.

Project description:Che-1 is a RNA Polymerase II binding protein involved in the regulation of gene transcription. Che-1 emerges as an important adaptor that connects transcriptional regulation, cell-cycle progression, checkpoint control, and apoptosis. We have observed that Che-1 depletion sensitizes cells to chemotherapy. We used microarrays analysis to investigate classes of genes regulated by Che-1.

Project description:Multiple myeloma is a hematological neoplasm of plasma cells characterized by an abnormal production of immunoglobulins. Che-1/AATF (Che-1) is an RNA binding protein involved in transcription regulation and highly expressed in this malignancy. In order to better characterize its functions in this type of disease, we performed co-immunoprecipitation experiments coupled with a mass-spec analysis by using total MM Kms27 cell lysates. From this analysis we were able to identify more than 600 proteins significantly enriched in Che-1 precipitates. As expected from its role in ribosomal RNA maturation, the Che-1 interactome contains numerous proteins involved in pre-rRNA processing and several ribosomal proteins. Notably, among other proteins interacting with Che-1, we identified many essential components of the paraspeckle which play an important role in the regulation of gene expression.