The mismatched nucleotides encoded in vaccinia virus flip-and-flop hairpin telomeres serve an essential role in virion maturation.

Poxvirus genomes consist of a linear duplex DNA that ends in short inverted and complementary hairpin structures. These elements also encode loops and mismatches that likely serve a role in genome packaging and perhaps replication. We constructed mutant vaccinia viruses (VACV) where the native hairpins were replaced by altered forms and tested effects on replication, assembly, and virulence. Our studies showed that structure, not sequence, likely determines function as one can replace an Orthopoxvirus (VACV) hairpin with one copied from a Leporipoxvirus with no effect on growth. Some loops can be deleted from VACV hairpins with little effect, but VACV bearing too few mismatches grew poorly and we couldn't recover viruses lacking all mismatches. Further studies were conducted using a mutant bearing only one of six mismatches found in wild-type hairpins (SΔ1Δ3-6). This virus grew to ~20-fold lower titers, but neither DNA synthesis nor telomere resolution was affected. However, the mutant exhibited a particle-to-PFU ratio 10-20-fold higher than wild-type viruses and p4b/4b core protein processing was compromised, indicating an assembly defect. Electron microscopy showed that SΔ1Δ3-6 mutant development was blocked at the immature virus (IV) stage, which phenocopies known effects of I1L mutants. Competitive DNA binding assays showed that recombinant I1 protein had less affinity for the SΔ1Δ3-6 hairpin than the wild-type hairpin. The SΔ1Δ3-6 mutant was also attenuated when administered to SCID-NCR mice by tail scarification. Mice inoculated with viruses bearing wild-type hairpins exhibited a median survival of 30-37 days, while mice infected with SΔ1Δ3-6 virus survived >70 days. Persistent infections favor genetic reversion and genome sequencing detected one example where a small duplication near the hairpin tip likely created a new loop. These observations show that mismatches serve a critical role in genome packaging and provide new insights into how VACV "flip and flop" telomeres are arranged.

Deciphering the Immunomodulatory Capacity of Oncolytic Vaccinia Virus to Enhance the Immune Response to Breast Cancer.

Vaccinia virus (VACV) is a double-stranded DNA virus that devotes a large portion of its 200 kbp genome to suppressing and manipulating the immune response of its host. Here, we investigated how targeted removal of immunomodulatory genes from the VACV genome impacted immune cells in the tumor microenvironment with the intention of improving the therapeutic efficacy of VACV in breast cancer. We performed a head-to-head comparison of six mutant oncolytic VACVs, each harboring deletions in genes that modulate different cellular pathways, such as nucleotide metabolism, apoptosis, inflammation, and chemokine and interferon signaling. We found that even minor changes to the VACV genome can impact the immune cell compartment in the tumor microenvironment. Viral genome modifications had the capacity to alter lymphocytic and myeloid cell compositions in tumors and spleens, PD-1 expression, and the percentages of virus-targeted and tumor-targeted CD8+ T cells. We observed that while some gene deletions improved responses in the nonimmunogenic 4T1 tumor model, very little therapeutic improvement was seen in the immunogenic HER2/neu TuBo model with the various genome modifications. We observed that the most promising candidate genes for deletion were those that interfere with interferon signaling. Collectively, this research helped focus attention on the pathways that modulate the immune response in the context of VACV oncolytic virotherapy. They also suggest that the greatest benefits to be obtained with these treatments may not always be seen in "hot tumors."

The vaccinia virus K7 protein promotes histone methylation associated with heterochromatin formation.

It has been well established that many vaccinia virus proteins suppress host antiviral pathways by targeting the transcription of antiviral proteins, thus evading the host innate immune system. However, whether viral proteins have an effect on the host's overall cellular transcription is less understood. In this study we investigated the regulation of heterochromatin during vaccinia virus infection. Heterochromatin is a highly condensed form of chromatin that is less transcriptionally active and characterized by methylation of histone proteins. We examined the change in methylation of two histone proteins, H3 and H4, which are major markers of heterochromatin, during the course of viral infection. Using immunofluorescence microscopy and flow cytometry we were able to track the overall change in the methylated levels of H3K9 and H4K20. Our results suggest that there is significant increase in methylation of H3K9 and H4K20 during Orthopoxviruses infection compared to mock-infected cells. However, this effect was not seen when we infected cells with Leporipoxviruses. We further screened several vaccinia virus single and multi-gene deletion mutant and identified the vaccinia virus gene K7R as a contributor to the increase in cellular histone methylation during infection.

The acidic C-terminus of vaccinia virus I3 single-strand binding protein promotes proper assembly of DNA-protein complexes.

The vaccinia virus I3L gene encodes a single-stranded DNA binding protein (SSB) that is essential for virus DNA replication and is conserved in all Chordopoxviruses. The I3 protein contains a negatively charged C-terminal tail that is a common feature of SSBs. Such acidic tails are critical for SSB-dependent replication, recombination and repair. We cloned and purified variants of the I3 protein, along with a homolog from molluscum contagiosum virus, and tested how the acidic tail affected DNA-protein interactions. Deleting the C terminus of I3 enhanced the affinity for single-stranded DNA cellulose and gel shift analyses showed that it also altered the migration of I3-DNA complexes in agarose gels. Microinjecting an antibody against I3 into vaccinia-infected cells also selectively inhibited virus replication. We suggest that this domain promotes cooperative binding of I3 to DNA in a way that would maintain an open DNA configuration around a replication site.