Abstract
Torque teno viruses (TTVs) are a group of viruses with small, circular DNA genomes. Members of this family are thought to ubiquitously infect humans, although causal disease associations are currently lacking. At present, there is no understanding of how infection with this diverse group of viruses is so prevalent. Using a combined computational and synthetic approach, we predict and identify miRNA-coding regions in diverse human TTVs and provide evidence for TTV miRNA production in vivo. The TTV miRNAs are transcribed by RNA polymerase II, processed by Drosha and Dicer, and are active in RISC. A TTV mutant defective for miRNA production replicates as well as wild type virus genome; demonstrating that the TTV miRNA is dispensable for genome replication in a cell culture model. We demonstrate that a recombinant TTV genome is capable of expressing an exogenous miRNA, indicating the potential utility of TTV as a small RNA vector. Gene expression profiling of host cells identifies N-myc (and STAT) interactor (NMI) as a target of a TTV miRNA. NMI transcripts are directly regulated through a binding site in the 3′UTR. SiRNA knockdown of NMI contributes to a decreased response to interferon signaling. Consistent with this, we show that a TTV miRNA mediates a decreased response to IFN and increased cellular proliferation in the presence of IFN. Thus, we add Annelloviridae to the growing list of virus families that encode miRNAs, and suggest that miRNA-mediated immune evasion can contribute to the pervasiveness associated with some of these viruses.
Highlights
Torque teno viruses (TTVs) belong to the family Anelloviridae and have small (,3.8 kb) circular, ssDNA genomes [1]
We demonstrate that TTVs utilize the host miRNA biogenesis machinery to produce biologically active miRNAs
To gain a functional understanding of the new TTV genes, we focus on a particular viral isolate and identify N-myc interactor (NMI) as a direct target
Summary
Torque teno viruses (TTVs) belong to the family Anelloviridae and have small (,3.8 kb) circular, ssDNA genomes [1] While these viruses are compact in their genomic size, there is a surprising amount of diversity reported in viral isolates, and the human TTVs have been phylogenetically classified into five groups [2,3,4]. Diverse viruses including some members from the Herpesvirus, Polyomavirus, and Retrovirus families have been confirmed to encode viral miRNAs [9]. While these virus families are different in many ways, they do share some commonalities including a nuclear DNA component to their replicative cycle and the ability to establish persistent infections in their hosts. Unlike most protein-based viral gene products, viral miRNAs are thought to be relatively invisible to the host immune system [8] and require minimal genomic space for their encoding
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