Polycomb group (PcG) proteins are key epigenetic regulators of hematopietic stem cell (HSC) fate. The PcG members Ezh2 and Ezh1 are important determinants of embryonic stem cell identity, and the transcript levels of these histone methyltransferases are inversely correlated during development. However, the role of Ezh1 in somatic stem cells is largely unknown. Here we show that Ezh1 maintains repopulating HSCs in a slow-cycling, undifferentiated state, protecting them from senescence. Ezh1 ablation induces significant loss of adult HSCs, with concomitant impairment of their self-renewal capacity due to a potent senescence response. Epigenomic and gene expression changes induced by Ezh1 deletion in senesced HSCs demonstrated that Ezh1-mediated PRC2 activity catalyzes monomethylation and dimethylation of H3K27. Deletion of Cdkn2a on the Ezh1 null background rescued HSC proliferation and survival. Our results suggest that Ezh1 is an important histone methyltransferase for HSC maintenance.
Recent evidence shows increased and decreased expression of Ezh2 in cancer, suggesting a dual role as an oncogene or tumour suppressor. To investigate the mechanism by which Ezh2-mediated H3K27 methylation leads to cancer, we generated conditional Ezh2 knock-in (Ezh2-KI) mice. Here we show that induced Ezh2 haematopoietic expression increases the number and proliferation of repopulating haematopoietic stem cells. Ezh2-KI mice develop myeloproliferative disorder, featuring excessive myeloid expansion in bone marrow and spleen, leukocytosis and splenomegaly. Competitive and serial transplantations demonstrate progressive myeloid commitment of Ezh2-KI haematopoietic stem cells. Transplanted self-renewing haematopoietic stem cells from Ezh2-KI mice induce myeloproliferative disorder, suggesting that the Ezh2 gainof-function arises in the haematopoietic stem cell pool, and not at later stages of myelopoiesis. At the molecular level, Ezh2 regulates haematopoietic stem cell-specific genes such as Evi-1 and ntrk3, aberrantly found in haematologic malignancies. These results demonstrate a stem cell-specific Ezh2 oncogenic role in myeloid disorders, and suggest possible therapeutic applications in Ezh2-related haematological malignancies. Most low GC Gram-positive bacteria possess an essential walKR two-component system (TCS) for signal transduction involved in regulating cell wall homoeostasis. Despite the well-established intracellular regulatory mechanism, the role of this TCS in extracellular signal recognition and factors that modulate the activity of this TCS remain largely unknown. Here we identify the extracellular receptor of the kinase 'WalK' (erWalK) as a key hub for bridging extracellular signal input and intracellular kinase activity modulation in Staphylococcus aureus. Characterization of the crystal structure of erWalK revealed a canonical Per-Arnt-Sim (PAS) domain for signal sensing. Single amino-acid mutation of potential signal-transduction residues resulted in severely impaired function of WalKR. A small molecule derived from structure-based virtual screening against erWalK is capable of selectively activating the walKR TCS. The molecular level characterization of erWalK will not only facilitate exploration of natural signal(s) but also provide a template for rational design of erWalK inhibitors.
Hematopoietic stem cells (HSCs) are defined by their exclusive capacity to both self-renew and to give rise to multipotent progenitors (MPPs) that in turn differentiate into the mature blood cell lineages. The tumor suppressor p53, in addition to its role in the regulation of the cell cycle, plays an important role in HSC self-renewal, although it has not fully resolved. Here we report that in super-p53 mice (sp53), which carry one extra gene dose of p53, the miR-33 is downregulated in HSCs and highly expressed in MPPs. Transplantation assays of miR-33-transduced sp53 HSC results in a significant acquisition of repopulating capacity and a decrease of recipients survival. Moreover, high levels of miR-33 represses the endogenous level of p53 protein in murine embryonic fibroblasts (MEFs), leads both to neoplastic transformation and anchorage independent growth of MEFs, and displays a decrease of apoptotic response using tumor-derived cell lines. Accordingly, we demonstrate that miR-33-mediated downregulation of p53 is dependent on the binding of miR-33 to two conserved motifs in the 3'UTR of p53. Together, these data show that the miR-33 modifies HSC repopulating efficiency of sp53 mice by impairing the p53 function. Defining the role of miR-33 in controlling the HSC self-renewal through p53 may lead to the prevention and treatment of hematopoietic disorders.
Preservation of hematopoietic hierarchy requires a constant and reciprocal interplay between chromatin-specific epigenetic regulators and lineage-modifying transcription factors. The polycomb member Bmi1 is a key factor in hematopoietic stem cell (HSC) maintenance, but its specific physiological role in subsequent hematopoietic lineage-specific commitments is unclear. Here, we generated conditional Bmi1 knockout (Bmi1-KO) mice. Selective ablation of Bmi1 in the hematopoietic system induced extensive upregulation of Ikaros and concomitant Ikaros-dependent lymphoid-lineage transcriptional priming, which is marked by their loss of H2A ubiquitination and increased H3K4 trimethylation in Bmi1-KO long-term HSCs (LT-HSCs). Removal of Ikaros in Bmi1-null LT-HSCs significantly diminished the hematopoietic defects seen in conditional Bmi1-KO mice. These alterations resulted in recovering the Bmi1-KO exhausted quiescent stem-cell pool, whereas the block in Bmi1-KO lymphoid-progenitor differentiation was rescued, allowing the development of mature lymphoid cells. Together, our results indicate that Ikaros is a critical Bmi1 target in vivo that prevents premature lineage specification of HSCs.
It is increasingly evident that non-coding RNAs play a significant role in tumour development. However, we still have a limited knowledge of the clinical significance of long non-coding RNAs (lncRNAs) in lung cancer. The FENDRR is a long coding RNA (also named FOXF1-AS1) located in the vicinity of the protein-coding gene FOXF1 at 16q24.1 chromosomal region. The present study aimed to define the clinic pathological significance of the long-non-coding RNA FENDRR in lung adenocarcinomas. FENDRR expression measured by quantitative PCR was found significantly downregulated (p<0.001) in lung adenocarcinoma samples in comparison with their normal adjacent tissues (n=70). RNA in situ hybridization (RNA-FISH) corroborated independently the down-regulation of FENDRR. Interestingly, the expression of FENDRR correlated positively (p<0.001) with the expression of its protein-coding neighbor gene FOXF1. Additionally, FOXF1 expression was also found downregulated in adenocarcinomas compared to normal samples (p<0.001) and its expression was significantly correlated with overall survival alone (p=0.003) or in combination with FENDRR expression (p=0.01). In conclusion, our data support that FENDRR and FOXF1 expression is decreased in lung adenocarcinoma and should be considered as new potential diagnostic/prognosis biomarkers.
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