The Addition of Tumor Necrosis Factor plus Beta Interferon Induces a Novel Synergistic Antiviral State against Poxviruses in Primary Human Fibroblasts

ABSTRACT Tumor necrosis factor (TNF) and members of the interferon (IFN) family have been shown to independently inhibit the replication of a variety of viruses. In addition, previous reports have shown that treatment with various combinations of these antiviral cytokines induces a synergistic antiviral state that can be significantly more potent than addition of any of these cytokines alone. The mechanism of this cytokine synergy and its effects on global gene expression, however, are not well characterized. Here, we use DNA microarray analysis to demonstrate that treatment of uninfected primary human fibroblasts with TNF plus IFN-β induces a distinct synergistic state characterized by significant perturbations of several hundred genes which are coinduced by the individual cytokines alone, as well as the induction of more than 850 novel host cell genes. This synergy is mediated directly by the two ligands, not by intermediate secreted factors, and is necessary and sufficient to completely block the productive replication and spread of myxoma virus in human fibroblasts. In contrast, the replication of two other poxviruses, vaccinia virus and tanapox virus, are only partially inhibited in these cells by the synergistic antiviral state, whereas the spread of both of these viruses to neighboring cells was efficiently blocked. Taken together, our data indicate that the combination of TNF and IFN-β induces a novel synergistic antiviral state that is highly distinct from that induced by either cytokine alone.

Complete Genomic Sequence and Comparative Analysis ofthe Tumorigenic Poxvirus Yaba Monkey TumorVirus

ABSTRACT The Yatapoxvirus genus of poxviruses is comprised of Yaba monkey tumor virus (YMTV), Tanapox virus, and Yaba-like disease virus (YLDV), which all have the ability to infect primates, including humans. Unlike other poxviruses, YMTV induces formation of focalized histiocytomas upon infection. To gain a greater understanding of the Yatapoxvirus genus and the unique tumor formation properties of YMTV, we sequenced the 134,721-bp genome of YMTV. The genome of YMTV encodes at least 140 open reading frames, all of which are also found as orthologs in the closely related YLDV. However, 13 open reading frames found in YLDV are completely absent from YMTV. Common to both YLDV and YMTV are the unusually large noncoding regions between many open reading frames. To determine whether any of these noncoding regions might be functionally significant, we carried out a comparative analysis between the putative noncoding regions of YMTV and similar noncoding regions from other poxviruses. This approach identified three new gene poxvirus families, defined as orthologs of YMTV23.5L, YMTV28.5L, and YMTV120.5L, which are highly conserved in virtually all poxvirus species. Furthermore, the comparative analysis also revealed a 40-bp nucleotide sequence at approximately 14,700 bases from the left terminus that was 100% identical in the comparable intergene site within members of the Yatapoxvirus, Suipoxvirus, and Capripoxvirus genera and 95% conserved in the Leporipoxvirus genus. This conserved sequence was shown to function as a poxvirus late promoter element in transfected and infected cells, but other functions, such as an involvement in viral replication or packaging, cannot be excluded. Finally, we summarize the predicted immunomodulatory protein repertoire in the Yatapoxvirus genus as a whole.