Bone morphogenetic protein signaling is required for RAD51-mediated maintenance of genome integrity in vascular endothelial cells.

The integrity of blood vessels is fundamental to vascular homeostasis. Inactivating mutations in the bone morphogenetic protein (BMP) receptor type II (BMPR2) gene cause hereditary vascular disorders, including pulmonary arterial hypertension and hereditary hemorrhagic telangiectasia, suggesting that BMPR2 and its downstream signaling pathway are pivotal to the maintenance of vascular integrity through an unknown molecular mechanism. Here we report that inactivation of BMPR2 in pulmonary vascular endothelial cells results in a deficit of RAD51, an enzyme essential for DNA repair and replication. Loss of RAD51, which causes DNA damage and cell death, is also detected in animal models and human patients with pulmonary arterial hypertension. Restoration of BMPR2 or activation of the BMP signaling pathway rescues RAD51 and prevents DNA damage. This is an unexpected role of BMP signaling in preventing the accumulation of DNA damage and the concomitant loss of endothelial integrity and vascular remodeling associated with vascular disorders

Acetylation of p53 stimulates miRNA processing and determines cell survival following genotoxic stress

It is widely accepted that different forms of stress activate a common target, p53, yet different outcomes are triggered in a stress-specific manner. For example, activation of p53 by genotoxic agents, such as camptothecin (CPT), triggers apoptosis, while non-genotoxic activation of p53 by Nutlin-3 (Nut3) leads to cell-cycle arrest without significant apoptosis. Such stimulus-specific responses are attributed to differential transcriptional activation of various promoters by p53. In this study, we demonstrate that CPT, but not Nut3, induces miR-203, which downregulates anti-apoptotic bcl-w and promotes cell death in a p53-dependent manner. We find that acetylation of K120 in the DNA-binding domain of p53 augments its association with the Drosha microprocessor and promotes nuclear primary miRNA processing. Knockdown of human orthologue of Males absent On the First (hMOF), the acetyltransferase that targets K120 in p53, abolishes induction of miR-203 and cell death mediated by CPT. Thus, this study reveals that p53 acetylation at K120 plays a critical role in the regulation of the Drosha microprocessor and that post-transcriptional regulation of gene expression by p53 via miRNAs plays a role in determining stress-specific cellular outcomes

How do you mend inactive tumor suppressor mutants? You glue them!

SMAD4 mutations that disrupt its interaction with SMAD3 and attenuate tumor suppression by TGF-β are major oncogenic drivers. Tang et al. (2020) report the discovery of small molecules that restore the SMAD4:SMAD3 complex and its cytostatic activity, exemplifying the therapeutic potential of fixing tumor suppressor mutants using molecular glues

How do you mend inactive tumor suppressor mutants? You glue them!

SMAD4 mutations that disrupt its interaction with SMAD3 and attenuate tumor suppression by TGF-β are major oncogenic drivers. Tang et al. (2020) report the discovery of small molecules that restore the SMAD4:SMAD3 complex and its cytostatic activity, exemplifying the therapeutic potential of fixing tumor suppressor mutants using molecular glues

Deregulation of Drosha in the pathogenesis of hereditary hemorrhagic telangiectasia.

Purpose of reviewThe TGFβ (transforming growth factor β) superfamily - a large group of structurally related and evolutionarily conserved proteins - profoundly shapes and organizes the vasculature during normal development and adult homeostasis. Mutations inactivating several of its ligands, receptors, or signal transducers set off hereditary hemorrhagic telangiectasia (HHT), a disorder that causes capillary networks to form incorrectly. Drosha, an essential microRNA-processing enzyme, also interfaces with TGFβ signal transducers, but its involvement in vascular conditions had not been tested until recently. This review summarizes current evidence that links mutations of Drosha to HHT.Recent findingsGenetic studies have revealed that rare missense mutations in the Drosha gene occur more commonly among HHT patients than in healthy people. Molecular analyses also indicated that Drosha enzymes with HHT-associated mutations generate microRNAs less efficiently than their wild-type counterpart when stimulated by TGFβ ligands. In zebrafish or mouse, mutant Drosha proteins cause the formation of dilated, leaky blood vessels deprived of capillaries, similar to those typically found in patients with HHT.SummaryRecent evidence suggests that Drosha-mediated microRNA biogenesis contributes significantly to the control of vascular development and homeostasis by TGFβ. Loss or reduction of Drosha function may predispose carriers to HHT and possibly other vascular diseases

Essential role of the amino-terminal region of Drosha for the Microprocessor function

Summary: The ribonuclease (RNase) III enzyme Drosha enables processing of microRNA (miRNA) primary transcripts (pri-miRNAs) and control of ribosomal protein (RP) biogenesis by the Microprocessor. The extensively studied carboxyl-terminal half of Drosha is sufficient to crop pri-miRNAs in vitro, but the function of the evolutionarily conserved Drosha amino-terminal region (NTR) is unknown, despite it harboring mutations linked to a hereditary vascular disorder. Here, we provide evidence that, when replacing the endogenous Drosha, a mutant missing the NTR (ΔN-Drosha) fails to associate with endogenous pri-miRNAs and to support the expression of all miRNAs, except the miR-183 cluster. Surprisingly, Argonaute2 (Ago2) associates with and cleaves pri-miR-183 in ΔN-Drosha cells and in Drosha-depleted cells. ΔN-Drosha is also unable to inhibit RP biogenesis upon serum starvation. Thus, Drosha NTR is essential for pri-miRNA processing and RP biogenesis in vivo, and Ago2 can process the miR-183 cluster in the absence of Drosha

Essential role of the amino-terminal region of Drosha for the Microprocessor function

Summary: Drosha is a core component of the Microprocessor complex that cleaves primary-microRNAs (pri-miRNAs) to generate precursor-miRNA and regulates the expression of ∼80 ribosomal protein (RP) genes. Despite the fact that mutations in the amino-terminal region of Drosha (Drosha-NTR) are associated with a vascular disorder, hereditary hemorrhagic telangiectasia, the precise function of Drosha-NTR remains unclear. By deleting exon 5 from the Drosha gene and generating a Drosha mutant lacking the NTR (ΔN), we demonstrate that ΔN is unable to process pri-miRNAs, which leads to a global miRNA depletion, except for the miR-183/96/182 cluster. We find that Argonaute 2 facilitates the processing of the pri-miR-183/96/182 in ΔN cells. Unlike full-length Drosha, ΔN is not degraded under serum starvation, resulting in unregulated RP biogenesis and protein synthesis in ΔN cells, allowing them to evade growth arrest. This study reveals the essential role of Drosha-NTR in miRNA production and nutrient-dependent translational control

Essential role of the amino-terminal region of Drosha for the Microprocessor function.

Drosha is a core component of the Microprocessor complex that cleaves primary-microRNAs (pri-miRNAs) to generate precursor-miRNA and regulates the expression of ∼80 ribosomal protein (RP) genes. Despite the fact that mutations in the amino-terminal region of Drosha (Drosha-NTR) are associated with a vascular disorder, hereditary hemorrhagic telangiectasia, the precise function of Drosha-NTR remains unclear. By deleting exon 5 from the Drosha gene and generating a Drosha mutant lacking the NTR (ΔN), we demonstrate that ΔN is unable to process pri-miRNAs, which leads to a global miRNA depletion, except for the miR-183/96/182 cluster. We find that Argonaute 2 facilitates the processing of the pri-miR-183/96/182 in ΔN cells. Unlike full-length Drosha, ΔN is not degraded under serum starvation, resulting in unregulated RP biogenesis and protein synthesis in ΔN cells, allowing them to evade growth arrest. This study reveals the essential role of Drosha-NTR in miRNA production and nutrient-dependent translational control