Epstein-Barr Virus (EBV) is an oncogenic γ-herpesvirus that capably establishes both latent and lytic modes of infection in host cells and causes malignant diseases in humans. Nuclear antigen 2 (EBNA2)-mediated transcription of both cellular and viral genes is essential for the establishment and maintenance of the EBV latency program in B lymphocytes. Here, we employed a protein affinity pull-down and LC-MS/MS analysis to identify nucleophosmin (NPM1) as one of the cellular proteins bound to EBNA2. Additionally, the specific domains that are responsible for protein-protein interactions were characterized as EBNA2 residues 300 to 360 and the oligomerization domain (OD) of NPM1. As in c-MYC, dramatic NPM1 expression was induced in EBV positively infected B cells after three days of viral infection, and both EBNA2 and EBNALP were implicated in the transactivation of the NPM1 promoter. Depletion of NPM1 with the lentivirus-expressed short-hairpin RNAs (shRNAs) effectively abrogated EBNA2-dependent transcription and transformation outgrowth of lymphoblastoid cells. Notably, the ATP-bound state of NPM1 was required to induce assembly of a protein complex containing EBNA2, RBP-Jκ, and NPM1 by stabilizing the interaction of EBNA2 with RBP-Jκ. In a NPM1-knockdown cell line, we demonstrated that an EBNA2-mediated transcription defect was fully restored by the ectopic expression of NPM1. Our findings highlight the essential role of NPM1 in chaperoning EBNA2 onto the latency-associated membrane protein 1 (LMP1) promoters, which is coordinated with the subsequent activation of transcriptional cascades through RBP-Jκ during EBV infection. These data advance our understanding of EBV pathology and further imply that NPM1 can be exploited as a therapeutic target for EBV-associated diseases.
Cardiomyocyte renewal occurs very slowly in adult mammals, and little is known of the genetic basis of cardiac regeneration. Twist is a highly conserved bHLH transcription factor responsible for Drosophila mesoderm formation during embryogenesis. Recent studies have shown that Twist protein is essential for muscle regeneration in adult Drosophila, but the potential role of Twist in the mammalian heart has not been explored. There are two Twist genes in vertebrates, Twist-1 and -2. We show that Twist-1 and -2 are expressed in epicardium and interstitial cells but not in differentiated cardiomyocytes in mice. To understand the potential function of Twist-dependent lineages in the adult heart, we generated inducible Twist2CreERT2; ROSA26-tdTomato reporter mice. By treating these mice with tamoxifen at 8 weeks of age, we observed progressive labeling of various cell types, such as epithelial cells, cardiac fibroblasts, and cardiomyocytes in the heart. We isolated Tomato-positive nonmyocytes from these mice and found that these cells can differentiate into cardiomyocytes and other cell types in vitro. Furthermore, cardiac-specific deletion of both Twist1 and Twist2 resulted in an age-dependent lethal cardiomyopathy. These findings reveal an essential contribution of Twist to long-term maintenance of cardiac function and support the concept of slow, lifelong renewal of cardiomyocytes from a Twist-dependent cell lineage in the adult heart.
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