A Cluster of Virus-Encoded MicroRNAs Accelerates Acute Systemic Epstein-Barr Virus Infection but Does Not Significantly Enhance Virus-Induced Oncogenesis
            <i>In Vivo</i>

Wahl, Angela; Linnstaedt, Sarah D.; Esoda, Caitlin N.; Krisko, John F.; Martinez-Torres, Francisco; Delecluse, Henri Jacques; Cullen, Bryan R.; García, J. Víctor

doi:10.1128/jvi.00281-13

Cited by 47 publications

(45 citation statements)

References 37 publications

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“…Although our knowledge on the function of the EBV miRNAs is limited, knockout EBV strains have indicated a role for the BHRF1 miRNAs and, to a lesser extent, for the BART miRNAs in the early phase of B-cell transformation (Feederle et al 2011;Seto et al 2010;Vereide et al 2014). Experiments in humanized mice showed that the BHRF1 miRNAs were not crucial for infection, but knockout virus did show delayed kinetics compared to the wild-type virus (Wahl et al 2013). In a xenograft mouse model, expression of the BART miRNAs appeared to provide a tumor cell growth advantage (Qiu et al 2015).…”

Section: Ebv Mirnasmentioning

confidence: 95%

Immune Evasion by Epstein-Barr Virus

Ressing

Gent

Gram

et al. 2015

Current Topics in Microbiology and Immunology

106

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Epstein-Bar virus (EBV) is widespread within the human population with over 90% of adults being infected. In response to primary EBV infection, the host mounts an antiviral immune response comprising both innate and adaptive effector functions. Although the immune system can control EBV infection to a large extent, the virus is not cleared. Instead, EBV establishes a latent infection in B lymphocytes characterized by limited viral gene expression. For the production of new viral progeny, EBV reactivates from these latently infected cells. During the productive phase of infection, a repertoire of over 80 EBV gene products is expressed, presenting a vast number of viral antigens to the primed immune system. In particular the EBV-specific CD4+ and CD8+ memory T lymphocytes can respond within hours, potentially destroying the virus-producing cells before viral replication is completed and viral particles have been released. Preceding the adaptive immune response, potent innate immune mechanisms provide a first line of defense during primary and recurrent infections. In spite of this broad range of antiviral immune effector mechanisms, EBV persists for life and continues to replicate. Studies performed over the past decades have revealed a wide array of viral gene products interfering with both innate and adaptive immunity. These include EBV-encoded proteins as well as small noncoding RNAs with immune-evasive properties. The current review presents an overview of the evasion strategies that are employed by EBV to facilitate immune escape during latency and productive infection. These evasion mechanisms may also compromise the elimination of EBV-transformed cells, and thus contribute to malignancies associated with EBV infection.

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Section: Ebv Mirnasmentioning

confidence: 95%

Immune Evasion by Epstein-Barr Virus

Ressing

Gent

Gram

et al. 2015

Current Topics in Microbiology and Immunology

106

View full text Add to dashboard Cite

show abstract

“…However, two recent in vivo studies using a humanized mouse model led to contradictory results. First, it was observed that BHRF1 miRNAs contribute to viral growth but did not play a role in EBV-mediated oncogenesis (74). Furthermore, a second study showed that although the BART miRNA cluster of the EBV M81 strain did not affect the ability of the virus to induce tumors, these viral miRNAs were able to repress B-cell tumorigenesis (75).…”

Section: Survival and Proliferation Of Latently Infected Cells And Hementioning

confidence: 98%

“…Indeed, while the absence of MuHV-4 miRNAs did not significantly affect the colonization and latency in immunocompetent mice, impairment of MuHV-4 miRNA expression reduced the virulence of MuHV-4 infection in immunocompromised IFN-γ-deficient mice, suggesting a role in promoting gammaherpesvirus-associated disease (96,97). In addition, research conducted on malignant catarrhal fever (MCF), a T-cell lymphoproliferative cattle disease induced by OvHV-2 or alcelaphine herpesvirus 1 (AlHV-1) revealed the expression of a very high number of miRNAs after propagation of LCLs and in vivo (73,74). However, the deletion from the AlHV-1 genome of 28 clustered-viral miRNAs did not alter the induction of MCF in the rabbit model (99).…”

Section: Survival and Proliferation Of Latently Infected Cells And Hementioning

confidence: 98%

MicroRNAs in large herpesvirus DNA genomes: recent advances

Sorel

Dewals

2016

Biomolecular Concepts

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MicroRNAs (miRNAs) are small non-coding RNAs (ncRNAs) that regulate gene expression. They alter mRNA translation through base-pair complementarity, leading to regulation of genes during both physiological and pathological processes. Viruses have evolved mechanisms to take advantage of the host cells to multiply and/or persist over the lifetime of the host. Herpesviridae are a large family of double-stranded DNA viruses that are associated with a number of important diseases, including lymphoproliferative diseases. Herpesviruses establish lifelong latent infections through modulation of the interface between the virus and its host. A number of reports have identified miRNAs in a very large number of human and animal herpesviruses suggesting that these short non-coding transcripts could play essential roles in herpesvirus biology. This review will specifically focus on the recent advances on the functions of herpesvirus miRNAs in infection and pathogenesis.

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“…These LCLs were markedly deficient in S-phase progression indicating a persistent role for these miRNAs in B-cell proliferation. In very recent studies using humanized mouse models it was discovered that the presence of an intact BHRF1 miRNA locus was required for high-level systemic virus load, but both wild-type and BHRF1 mutant viruses had the same oncogenic potential (Wahl et al, 2013). …”

Section: Mirnas and Other Non-coding Rnas Involved In Transformationmentioning

confidence: 99%

Dynamic Epstein–Barr Virus Gene Expression on the Path to B-Cell Transformation

Price

Luftig

2014

Advances in Virus Research

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Epstein-Barr Virus is an oncogenic human herpesvirus in the γ-herpesvirinae sub-family that contains a 170–180 kb double stranded DNA genome. In vivo, EBV commonly infects B and epithelial cells and persists for the life of the host in a latent state in the memory B cell compartment of the peripheral blood. EBV can be reactivated from its latent state leading to increased expression of lytic genes that primarily encode for enzymes necessary to replicate the viral genome as well as structural components of the virion. Lytic cycle proteins also aid in immune evasion, inhibition of apoptosis, and the modulation of other host responses to infection. In vitro, EBV has the potential to infect primary human B cells and induce cellular proliferation to yield effectively immortalized lymphoblastoid cell lines, or LCLs. EBV immortalization of B cells in vitro serves as a model system for studying EBV-mediated lymphomagenesis. While much is known about the steady state viral gene expression within EBV immortalized LCLs and other EBV-positive cell lines, relatively little is known about the early events after primary B-cell infection. It was previously thought that upon latent infection EBV only expressed the well-characterized latency associated transcripts found in LCLs. However, recent work has characterized the early, but transient, expression of lytic genes necessary for efficient transformation as well as delayed responses in the known latency genes. This review summarizes these recent findings that show how dynamic and controlled expression of multiple EBV genes can control the activation of B cells, entry into the cell cycle, inhibition of apoptosis, and control of innate and adaptive immune responses.

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A Cluster of Virus-Encoded MicroRNAs Accelerates Acute Systemic Epstein-Barr Virus Infection but Does Not Significantly Enhance Virus-Induced Oncogenesis In Vivo

Cited by 47 publications

References 37 publications

Immune Evasion by Epstein-Barr Virus

Immune Evasion by Epstein-Barr Virus

MicroRNAs in large herpesvirus DNA genomes: recent advances

Dynamic Epstein–Barr Virus Gene Expression on the Path to B-Cell Transformation

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