The human cytomegalovirus (CMV) proteins US28 and UL33 are homologous to chemokine receptors (CKRs). Knockout of the mouse CMV M33 protein (UL33 homologue) results in substantial attenuation of salivary gland infection/replication and reduced efficiency of reactivation from tissue explants. M33-mediated G protein-coupled signaling is critical for the salivary gland phenotype. In this report, we demonstrate that US28 and (to a lesser degree) UL33 restore reactivation from tissue explants and partially restore replication in salivary glands (compared to a signaling-deficient M33 mutant). These studies provide a novel small animal model for evaluation of therapies targeting the human CMV CKRs.Chemokine receptor (CKR) homologues and other seventransmembrane receptor (7TMR) homologues are characteristic of beta-and gammaherpesviruses and are potential therapeutic targets (7,14,16). Human cytomegalovirus (HCMV) encodes four 7TMRs: UL33 and UL78 are conserved in all betaherpesviruses, whereas US28/US27 homologues are restricted to primate betaherpesviruses.Clues to the roles of HCMV 7TMRs have come from in vivo studies of mouse and rat CMVs (MCMV and RCMV, respectively). Acute-phase replication in primary organs is followed by dissemination to secondary sites, such as salivary glands, where virus may replicate for several days, attaining high titers. Following immune clearance of productive infection, latently infected cells remain distributed in a number of organs. In the absence of M33 (UL33 homologue), MCMV failed to attain detectable levels of infectious virus in salivary glands, with similar observations for R33 of RCMV (1, 5), suggesting evolutionarily conserved functions. The mechanisms underlying salivary gland attenuation may include defects in dissemination to, initial infection of, or maintenance of productive infection within that organ. Definitive studies are lacking, but there is some evidence for attenuation at a postdissemination step; the M33-null mutant was defective for replication following direct intrasalivary gland inoculation, and the R33-null mutant was detectable in salivary glands (by PCR), similar to the wild type at early times postinfection (1, 5). We and others have demonstrated the importance of constitutive M33-induced signaling for the salivary gland phenotype (4, 15). We further demonstrated that an M33-null mutant was deficient for reactivation in an ex vivo tissue explant model (2), although whether M33 plays a specific role during the establishment of, maintenance of, or reactivation from latency is not yet known.
RNase III proteins play vital roles in processing of several types of RNA molecules and gene silencing. Recently, it has been discovered that some plant and animal viruses encode RNase III-like proteins as well. Genome sequencing of four virus species belonging to the Ascoviridae family has revealed sequence conservation of an RNase III open reading frame among the viruses. These have not been explored in ascoviruses, and therefore their role in host-virus interaction is unknown. Here, we confirmed expression of Heliothis virescens ascovirus (HvAV-3e) open reading frame 27 (orf27) that encodes an RNase III-like protein after infection and demonstrated dsRNA specific endoribonuclease activity of the encoded protein. Analysis of the expression patterns of orf27 in virus-infected insect cells and a bacterial expression system revealed autoregulation of this protein over time. Moreover, HvAV-3e RNase III was found essential for virus DNA replication and infection using RNA interference (RNAi)-mediated gene silencing. In addition, using green fluorescent protein gene as a marker, we provide evidence that RNase III is involved in the suppression of gene silencing. To our knowledge, this is the first insect virus-encoded RNase III described and shown to suppress host cell RNAi defense mechanism.
The mouse cytomegalovirus chemokine receptor homologue (CKR) M33 is required for salivary gland tropism and efficient reactivation from latency, phenotypes partially rescued by the human cytomegalovirus CKR US28. Herein, we demonstrate that complementation of salivary gland tropism is mediated predominantly by G protein-dependent signaling conserved with that of M33; in contrast, both G protein-dependent and -independent pathways contribute to the latency phenotypes. A novel M33-dependent replication phenotype in cultured bone marrow macrophages is also described.
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