A homolog of the variola virus B22 membrane protein contributes to ectromelia virus pathogenicity in the mouse footpad model.

Most poxviruses encode a homolog of a ~200,000-kDa membrane protein originally identified in variola virus. We investigated the importance of the ectromelia virus (ECTV) homolog C15 in a natural infection model. In cultured mouse cells, the replication of a mutant virus with stop codons near the N-terminus (ECTV-C15Stop) was indistinguishable from a control virus (ECTV-C15Rev). However, for a range of doses injected into the footpads of BALB/c mice there was less mortality with the mutant. Similar virus loads were present at the site of infection with mutant or control virus whereas there was less ECTV-C15Stop in popliteal and inguinal lymph nodes, spleen and liver indicating decreased virus spread and replication. The latter results were supported by immunohistochemical analyses. Decreased spread was evidently due to immune modulatory activity of C15, rather than to an intrinsic viral function, as the survival of infected mice depended on CD4+ and CD8+ T cells.

Characterization of a large, proteolytically processed cowpox virus membrane glycoprotein conserved in most chordopoxviruses.

Most poxvirus proteins are either highly conserved and essential for basic steps in replication or less conserved and involved in host interactions. Homologs of the CPXV219 protein, encoded by cowpox virus, are present in nearly all chordopoxvirus genera and some species have multiple copies. The CPXV219 homologs have estimated masses of greater than 200 kDa, making them the largest known poxvirus proteins. We showed that CPXV219 was expressed early in infection and cleaved into N- and C-terminal fragments that remained associated. The protein has a signal peptide and transited the secretory pathway where extensive glycosylation and proteolytic cleavage occurred. CPXV219 was located by immunofluorescence microscopy in association with the endoplasmic reticulum, Golgi apparatus and plasma membrane. In non-permeabilized cells, CPXV219 was accessible to external antibody and biotinylation. Mutants that did not express CPXV219 replicated normally in cell culture and retained virulence in a mouse respiratory infection model.

Expression profiling of the intermediate and late stages of poxvirus replication.

The double-stranded DNA genome of vaccinia virus (VACV), the prototype poxvirus, contains approximately 200 open reading frames (ORFs) that are transcribed at early, intermediate, and late stages of infection. Previous high-throughput deep RNA sequencing allowed us to map 118 VACV early genes that are expressed before viral DNA replication and 93 postreplicative genes. However, the intermediate- and late-stage postreplicative genes could not be differentiated. Here, we synchronized infections with a reversible inhibitor of DNA replication and used a VACV mutant that conditionally transcribes late genes to sequence the two classes of mRNAs. In addition, each postreplicative ORF was individually expressed under conditions that distinguished intermediate and late classes. We identified 38 VACV genes that belong to the late class and 53 that belong to the intermediate class, with some of the latter continuing to be expressed late. These data allowed us to prepare a genome-wide early, intermediate, and late transcription map. Inspection of sequences upstream of these ORFs revealed distinctive characteristics of intermediate and late promoters and suggested that some promoters have intermediate and late elements. The intermediate genes encoded many DNA binding/packaging and core-associated proteins in addition to late transcription factors; the late genes encoded many morphogenesis and mature virion membrane proteins, including those involved in entry, in addition to early transcription factors. The top-ranked antigens for CD4(+) T cells and B cells were mainly intermediate rather than late gene products. The differentiation of intermediate and late genes may enhance understanding of poxvirus replication and lead to improvements in expression vectors and recombinant vaccines.