Human cytomegalovirus gene expression is silenced by Daxx-mediated intrinsic immune defense in model latent infections established in vitro

In addition to productive lytic infections, herpesviruses such as human cytomegalovirus (HCMV) establish a reservoir of latently infected cells that permit lifelong colonization of the host. When latency is established, the viral immediate-early (IE) genes that initiate the lytic replication cycle are not expressed. HCMV IE gene expression at the start of a lytic infection is facilitated by the viral pp71 protein, which is delivered to cells by infectious viral particles. pp71 neutralizes the Daxx-mediated cellular intrinsic immune defense that silences IE gene expression by generating a repressive chromatin structure on the viral major IE promoter (MIEP). In naturally latently infected cells and in cells latently infected in vitro, the MIEP also adopts a similar silenced chromatin structure. Here we analyze the role of Daxx in quiescent HCMV infections in vitro that mimic some, but not all, of the characteristics of natural latency. We show that in these "latent-like" infections, the Daxx-mediated defense that represses viral gene expression is not disabled because pp71 and Daxx localize to different cellular compartments. We demonstrate that Daxx is required to establish quiescent HCMV infections in vitro because in cells that would normally foster the establishment of these latent-like infections, the loss of Daxx causes the lytic replication cycle to be initiated. Importantly, the lytic cycle is inefficiently completed, which results in an abortive infection. Our work demonstrates that, in certain cell types, HCMV must silence its own gene expression to establish quiescence and prevent abortive infection and that the virus usurps a Daxx-mediated cellular intrinsic immune defense mechanism to do so. This identifies Daxx as one of the likely multiple viral and cellular determinants in the pathway of HCMV quiescence in vitro, and perhaps in natural latent infections as well.     

Promoter-specific trans activation and repression by human cytomegalovirus immediate-early proteins involves common and unique protein domains.

trans activation of promoters by viral regulatory proteins provides a useful tool to study coordinate control of gene expression. Immediate-early (IE) regions 1 and 2 of human cytomegalovirus (CMV) code for a series of proteins that originate from differentially spliced mRNAs. These IE proteins are proposed to regulate the temporal expression of the viral genome. To examine the structure and function of the IE proteins, we used linker insertion mutagenesis of the IE gene region as well as cDNA expression vector cloning of the abundant IE mRNAs. We showed that IE1 and IE2 proteins of CMV exhibit promoter-specific differences in their modes of action by either trans activating early and IE promoters or repressing the major IE promoter (MIEP). Transient cotransfection experiments with permissive human cells revealed a synergistic interaction between the 72- and the 86-kilodalton (kDa) IE proteins in trans activating an early promoter. In addition, transfection studies revealed that the 72-kDa protein was capable of trans activating the MIEP. In contrast, the 86-kDa protein specifically repressed the MIEP and this repression was suppressed by the 72-kDa protein. Furthermore, observations based on the primary sequence structure revealed a modular arrangement of putative regulatory motifs that could either potentiate or repress gene expression. These modular domains are either shared or unique among the IE proteins. From these data, we propose a model for IE protein function in the coordinate control of CMV gene expression.     

Control of cytomegalovirus lytic gene expression by histone acetylation

Permissiveness for human cytomegalovirus (HCMV) infection is dependent on the state of cellular differentiation and has been linked to repression of the viral major immediate early promoter (MIEP). We have used conditionally permissive cells to analyze differential regulation of the MIEP and possible mechanisms involved in latency. Our data suggest that histone deacetylases (HDACs) are involved in repression of the MIEP in non-permissive cells as inhibition of HDACs induces viral permissiveness and increases MIEP activity. Non-permissive cells contain the class I HDAC, HDAC3; super-expression of HDAC3 in normally permissive cells reduces infection and MIEP activity. We further show that the MIEP associates with acetylated histones in permissive cells, and that in peripheral blood monocytes the MIEP associates with heterochromatin protein 1 (HP1), a chromosomal protein implicated in gene silencing. As monocytes are believed to be a site of viral latency in HCMV carriers and reactivated virus is only observed upon differentiation into macrophages, we propose that chromatin remodeling of the MIEP following cellular differentiation could potentially play a role in reactivation of latent HCMV.