Project description:Herpesviruses rely on host cell transcription and translation machineries for replication. Viral proteins thus function to redirect multiple cellular proteins for viral replication. In herpesvirus replicating cells, host cell gene transcription is frequently down-regulated because important transcriptional apparatuses are appropriated by viral transcription factors. Here we show that an evolutionally-shaped viral protein sequence is a great starting material for unique drug development to modulate cellular transcription. Cellular c-Myc protein (MYC) is overexpressed in over 70% of all types of cancer cells and therefore a very attractive target to control cancer cell growth. We identified a small functional peptide derived from the Kaposi's sarcoma-associated herpesvirus transactivator (K-Rta), which strongly attenuates MYC expression, reduces cell proliferation, and selectively kills cancer cells in both tissue culture and a xenograft tumor mouse model. Mechanistically, the peptide blocks promoter-enhancer interactions by preventing coactivator complex consisting of Nuclear receptor coactivator 2, p300, and SWI/SNF proteins from engaging the MYC promoter in leukemia cells. Target gene profiling with SLAM-seq suggests that the viral peptide attenuates MYC expression through a mechanism likely different from that of BET bromodomain inhibitors. Furthermore, fusing the 13 amino acids peptide with humanized anti-CD22 single chain armed the antibody drug with cell killing ability, and inhibited cell growth in soft agar. Our studies thus demonstrate the utility of the peptide sequence as a therapeutics module, which may be used to modulate MYC activity in a cell type-specific manner.

Project description:Herpesviruses rely on host cell transcription and translation machineries for replication. Viral proteins thus function to redirect multiple cellular proteins for viral replication. In herpesvirus replicating cells, host cell gene transcription is frequently down-regulated because important transcriptional apparatuses are appropriated by viral transcription factors. Here we show that an evolutionally-shaped viral protein sequence is a great starting material for unique drug development to modulate cellular transcription. Cellular c-Myc protein (MYC) is overexpressed in over 70% of all types of cancer cells and therefore a very attractive target to control cancer cell growth. We identified a small functional peptide derived from the Kaposi's sarcoma-associated herpesvirus transactivator (K-Rta), which strongly attenuates MYC expression, reduces cell proliferation, and selectively kills cancer cells in both tissue culture and a xenograft tumor mouse model. Mechanistically, the peptide blocks promoter-enhancer interactions by preventing coactivator complex consisting of Nuclear receptor coactivator 2, p300, and SWI/SNF proteins from engaging the MYC promoter in leukemia cells. Target gene profiling with SLAM-seq suggests that the viral peptide attenuates MYC expression through a mechanism likely different from that of BET bromodomain inhibitors. Furthermore, fusing the 13 amino acids peptide with humanized anti-CD22 single chain armed the antibody drug with cell killing ability, and inhibited cell growth in soft agar. Our studies thus demonstrate the utility of the peptide sequence as a therapeutics module, which may be used to modulate MYC activity in a cell type-specific manner.

Project description:Herpesviruses rely on host cell transcription and translation machineries for replication. Viral proteins thus function to redirect multiple cellular proteins for viral replication. In herpesvirus replicating cells, host cell gene transcription is frequently down-regulated because important transcriptional apparatuses are appropriated by viral transcription factors. Here we show that an evolutionally-shaped viral protein sequence is a great starting material for unique drug development to modulate cellular transcription. Cellular c-Myc protein (MYC) is overexpressed in over 70% of all types of cancer cells and therefore a very attractive target to control cancer cell growth. We identified a small functional peptide derived from the Kaposi's sarcoma-associated herpesvirus transactivator (K-Rta), which strongly attenuates MYC expression, reduces cell proliferation, and selectively kills cancer cells in both tissue culture and a xenograft tumor mouse model. Mechanistically, the peptide blocks promoter-enhancer interactions by preventing coactivator complex consisting of Nuclear receptor coactivator 2, p300, and SWI/SNF proteins from engaging the MYC promoter in leukemia cells. Target gene profiling with SLAM-seq suggests that the viral peptide attenuates MYC expression through a mechanism likely different from that of BET bromodomain inhibitors. Furthermore, fusing the 13 amino acids peptide with humanized anti-CD22 single chain armed the antibody drug with cell killing ability, and inhibited cell growth in soft agar. Our studies thus demonstrate the utility of the peptide sequence as a therapeutics module, which may be used to modulate MYC activity in a cell type-specific manner.

Project description:To identify differentially expressed human and viral miRNAs across a panel of B-cell lines, including several primary effusion lymphomas (PEL). Gammaherpesvirus and host cell microRNAs (miRNAs) together modulate gene expression in normal and malignant cells. Using microRNA microarrays, we determined the expression of mature viral and host cellular miRNAs in a series of B cell tumours that include Kaposi’s Sarcoma-associated herpesvirus (KSHV) infected Primary Effusion Lymphoma (PEL) and Epstein-Barr virus (EBV) infected Burkitt’s lymphoma (BL) cell lines. We show that 35 host miRNAs were constitutively expressed in all the B cell lymphomas and differences in viral miRNA expression were evident between herpesvirus positive tumour types. Furthermore, we show that in PEL, miR-221 and miR-222 expression is defective due to a lack of transcript expression rather than mutation in the miRNA encoding loci. Absence of miR-221 and miR-222 resulted in the enhanced expression of the known target gene p27 (CDKN1B) and reintroduction of miR221 in PEL reduces p27 protein expression. miRNA expression profiling of a panel of 25 B-cell line samples.

Project description:Epstein-Barr virus (EBV) Rta is a latent-lytic molecular switch evolutionarily conserved in all gamma-herpesviruses. In previous studies, doxycycline-inducible Rta was shown to potently produce an irreversible G1 arrest followed by cellular senescence in 293 cells. Here, we demonstrate that in this system the inducible Rta not only reactivates resident genome of EBV but also that of Kaposi’s sarcoma-associated herpesvirus (KSHV), to similar efficiency. However, Rta-induced senescence program was terminated by the robust viral lytic cycle replication that eventually caused cell death. Furthermore, prior to the abrupt expression of immediate-early protein (EBV BZLF1 or KSHV RTA), Rta simultaneously down-regulates cell cycle activators (c-Myc, CDK6, CCND2) and up-regulates senescence-related genes (p21, 14-3-3s). Since Rta is a viral immediate-early transcriptional activator, it is envisioned that during the initial stage of viral reactivation, Rta may engage to modulate the host transcriptome, to halt cell cycle progression, and to maintain an ideal environment for manufacturing infectious virions. Refer to individual Series. This SuperSeries is composed of the following subset Series: GSE24585: Expression profiling of host genes modulated by Epstein-Barr virus (EBV) Rta in HEK293 cells GSE24586: Expression profiling of host genes modulated by Epstein-Barr virus Rta in nasopharyngeal carcinoma cells

Project description:Kaposi's sarcoma-associated herpesvirus (KSHV) establishes a latent infection, in which most viral genes are silenced except a few latent proteins such as latency-associated nuclear antigen (LANA). In latent viral chromatin, viral genes are poised to be transcribed, and KSHV LANA plays a major role in maintaining such transcription status. In the poised chromatins, LANA recruits cellular CHD4 (Chromodomain Helicase DNA binding protein 4) and suppresses inducible viral gene promoters. The CHD4 is known to regulate cell differentiation by restricting enhancer-promoter interactions and its mutation or overexpression deregulates the host cell transcription program and therefore associates with tumorigenesis. Here, we identified a putative CHD4 inhibitor from the LANA amino acid sequence from the LANA-CHD4 interaction surface. The small peptide interacts with CHD4 at its PHD domain with 14 nM KD (dissociation constant). The introduction of the peptide into the primary effusion lymphomas induces caspase-mediated CHD4 cleavage and subsequently triggered cell apoptosis and autophagy. A series of MTT assays demonstrated that the peptide preferentially killed lymphoma and leukemia cell lines at low micromolar concentrations, while peripheral mononuclear cells or adhesion cell lines were found to be more resistant to the peptide treatment. A monocyte cell differentiation model demonstrated that pre-treatment with the peptide at a low dose substantially enhanced transitioning into M2 macrophage (by reducing CHD4 occupancies from gene promoters), and globally altered the repertories of phorbol myristate acetate target genes in U937 cells. Finally, the PEL xenograft mouse model inhibited tumor growth without measurable side effects, and PEL cells isolated from xenograft tumors showed reduced CHD4 and LANA expression with terminally differentiated phenotype. We propose that the peptide isolated from the KSHV LANA sequence is biologically active and may function as a CHD4 inhibitor.

Project description:Kaposi's sarcoma-associated herpesvirus (KSHV) establishes a latent infection, in which most viral genes are silenced except a few latent proteins such as latency-associated nuclear antigen (LANA). In latent viral chromatin, viral genes are poised to be transcribed, and KSHV LANA plays a major role in maintaining such transcription status. In the poised chromatins, LANA recruits cellular CHD4 (Chromodomain Helicase DNA binding protein 4) and suppresses inducible viral gene promoters. The CHD4 is known to regulate cell differentiation by restricting enhancer-promoter interactions and its mutation or overexpression deregulates the host cell transcription program and therefore associates with tumorigenesis. Here, we identified a putative CHD4 inhibitor from the LANA amino acid sequence from the LANA-CHD4 interaction surface. The small peptide interacts with CHD4 at its PHD domain with 14 nM KD (dissociation constant). The introduction of the peptide into the primary effusion lymphomas induces caspase-mediated CHD4 cleavage and subsequently triggered cell apoptosis and autophagy. A series of MTT assays demonstrated that the peptide preferentially killed lymphoma and leukemia cell lines at low micromolar concentrations, while peripheral mononuclear cells or adhesion cell lines were found to be more resistant to the peptide treatment. A monocyte cell differentiation model demonstrated that pre-treatment with the peptide at a low dose substantially enhanced transitioning into M2 macrophage (by reducing CHD4 occupancies from gene promoters), and globally altered the repertories of phorbol myristate acetate target genes in U937 cells. Finally, the PEL xenograft mouse model inhibited tumor growth without measurable side effects, and PEL cells isolated from xenograft tumors showed reduced CHD4 and LANA expression with terminally differentiated phenotype. We propose that the peptide isolated from the KSHV LANA sequence is biologically active and may function as a CHD4 inhibitor.

Project description:We and others have proposed that coactivator binding inhibitors, which block the interaction of estrogen receptor and steroid receptor coactivators, may represent a potential class of new breast cancer therapeutics. The development of coactivator binding inhibitors has been limited, however, because many of the current molecules which are active in in vitro and biochemical assays are not active in cell-based assays. Our goal in this work was to prepare a coactivator binding inhibitor active in cellular models of breast cancer. To accomplish this, we used molecular dynamics simulations to convert a high-affinity stapled peptide with poor cell permeability into R4K1, a cell-penetrating stapled peptide. R4K1 displays high binding affinity for estrogen receptor ɑ, inhibits the formation of estrogen receptor/coactivator complexes, and distributes throughout the cell with a high percentage of nuclear localization. R4K1 represses native gene transcription mediated by estrogen receptor ɑ and inhibits proliferation of estradiol-stimulated MCF-7 cells. Using RNA-Seq, we demonstrate that almost all of the effects of R4K1 on global gene transcription are estrogen receptor-associated. This chemical probe provides a significant proof-of-concept for preparing cell-permeable stapled peptide inhibitors of the estrogen receptor/coactivator interaction.

Project description:Epstein-Barr virus (EBV) Rta is a latent-lytic molecular switch evolutionarily conserved in all gamma-herpesviruses. In previous studies, doxycycline-inducible Rta was shown to potently produce an irreversible G1 arrest followed by cellular senescence in 293 cells. Here, we demonstrate that in this system the inducible Rta not only reactivates resident genome of EBV but also that of Kaposi’s sarcoma-associated herpesvirus (KSHV), to similar efficiency. However, Rta-induced senescence program was terminated by the robust viral lytic cycle replication that eventually caused cell death. Furthermore, prior to the abrupt expression of immediate-early protein (EBV BZLF1 or KSHV RTA), Rta simultaneously down-regulates cell cycle activators (c-Myc, CDK6, CCND2) and up-regulates senescence-related genes (p21, 14-3-3s). Since Rta is a viral immediate-early transcriptional activator, it is envisioned that during the initial stage of viral reactivation, Rta may engage to modulate the host transcriptome, to halt cell cycle progression, and to maintain an ideal environment for manufacturing infectious virions. This SuperSeries is composed of the SubSeries listed below.

Project description:To identify differentially expressed human and viral miRNAs across a panel of B-cell lines, including several primary effusion lymphomas (PEL). Gammaherpesvirus and host cell microRNAs (miRNAs) together modulate gene expression in normal and malignant cells. Using microRNA microarrays, we determined the expression of mature viral and host cellular miRNAs in a series of B cell tumours that include Kaposi’s Sarcoma-associated herpesvirus (KSHV) infected Primary Effusion Lymphoma (PEL) and Epstein-Barr virus (EBV) infected Burkitt’s lymphoma (BL) cell lines. We show that 35 host miRNAs were constitutively expressed in all the B cell lymphomas and differences in viral miRNA expression were evident between herpesvirus positive tumour types. Furthermore, we show that in PEL, miR-221 and miR-222 expression is defective due to a lack of transcript expression rather than mutation in the miRNA encoding loci. Absence of miR-221 and miR-222 resulted in the enhanced expression of the known target gene p27 (CDKN1B) and reintroduction of miR221 in PEL reduces p27 protein expression.