The Cellular Proteins Grb2 and DDX3 Are Increased upon Human Cytomegalovirus Infection and Act in a Proviral Fashion.

While it is well established that human cytomegalovirus (HCMV) upregulates many cellular proteins and incorporates several of them into its virion, little is known about the functional relevance of such virus-host interactions. Two cellular proteins, Grb2 and DDX3, gained our interest as they appeared enriched in virion particles and this incorporation depended on the viral tegument protein pp65, suggesting a functional relevance. We therefore tested whether the level of these proteins is altered upon HCMV infection and whether they support viral replication. Immunoblotting analyses of cellular fractions showed increased levels of both proteins in infected cells with a maximum at 2 d p.i. and a reduction of the soluble Grb2 fraction. Knockdown of either gene by transfection of siRNAs reduced viral spread not only of the cell culture adapted HCMV strain TB40/E but also of recent clinical isolates. Apparently, Grb2 and DDX3 are proviral cellular factors that are upregulated in infected cells.

The human cytomegalovirus protein TRS1 inhibits autophagy via its interaction with Beclin 1.

Human cytomegalovirus modulates macroautophagy in two opposite directions. First, HCMV stimulates autophagy during the early stages of infection, as evident by an increase in the number of autophagosomes and a rise in the autophagic flux. This stimulation occurs independently of de novo viral protein synthesis since UV-inactivated HCMV recapitulates the stimulatory effect on macroautophagy. At later time points of infection, HCMV blocks autophagy (M. Chaumorcel, S. Souquere, G. Pierron, P. Codogno, and A. Esclatine, Autophagy 4:1-8, 2008) by a mechanism that requires de novo viral protein expression. Exploration of the mechanisms used by HCMV to block autophagy unveiled a robust increase of the cellular form of Bcl-2 expression. Although this protein has an anti-autophagy effect via its interaction with Beclin 1, it is not responsible for the inhibition induced by HCMV, probably because of its phosphorylation by c-Jun N-terminal kinase. Here we showed that the HCMV TRS1 protein blocks autophagosome biogenesis and that a TRS1 deletion mutant is defective in autophagy inhibition. TRS1 has previously been shown to neutralize the PKR antiviral effector molecule. Although phosphorylation of eIF2α by PKR has been described as a stimulatory signal to induce autophagy, the PKR-binding domain of TRS1 is dispensable to its inhibitory effect. Our results show that TRS1 interacts with Beclin 1 to inhibit autophagy. We mapped the interaction with Beclin 1 to the N-terminal region of TRS1, and we demonstrated that the Beclin 1-binding domain of TRS1 is essential to inhibit autophagy.

Herpesviruses and autophagy: catch me if you can!

Autophagy is an evolutionarily conserved cellular degradation pathway involving the digestion of intracellular components via the lysosomal pathway. The autophagic pathway constitutively maintains cellular homeostasis by recycling cytoplasmic organelles and proteins, but it is also stimulated by environmental stress conditions, such as starvation, oxidative stress, and the accumulation of misfolded proteins. It also acts as a cellular defense mechanism against microorganisms by contributing to both the innate and adaptive immunity, and by eliminating intracellular pathogens (xenophagy). There is growing evidence that host cells try to control Herpesvirus infections by activating the autophagic machinery. However, it is well-known that Herpesviruses are smart pathogens and several, such as HSV-1, HCMV and HHV-8, are known to have developed numerous defense strategies for evading the host's immune response. Inhibition of the antiviral autophagic mechanism has also been reported. Autophagy has also been shown to enhance the major histocompatibility complex presentation of at least two viral proteins, the EBV-encoded EBNA-1 and the HSV-1 encoded gB. In this review, we present an overview of recent advances in our understanding of the complex interplay between autophagy and Herpesviruses.

Macrophage cultures are susceptible to lytic productive infection by endothelial-cell-propagated human cytomegalovirus strains and present viral IE1 protein to CD4+ T cells despite late downregulation of MHC class II molecules.

The contribution of CD4(+) T cells to control of human cytomegalovirus (HCMV) has been shown and infected tissue macrophages might contribute to this response by antigen presentation. As shown previously, CD4(+) T cells recognize HCMV immediate-early antigen IE1 on glioblastoma cells manipulated to express MHC class II molecules. Here, the possible interference of virus-induced MHC class II downmodulation with the presentation of IE1 by natural target cells was analysed. The capacity of IE1-specific CD4(+) T-cell clones to recognize HCMV-infected monocyte-derived macrophages was tested. Various HCMV strains were used to achieve efficient infection of macrophages. Activation of CD4(+) T cells by infected macrophages was evaluated at different time points after infection. Endothelial-cell-adapted HCMV strains efficiently infected cultured human macrophages. However, the immediate-early and early phases of replication were prolonged. Infected cells entered the late replication phase only after 3 days of infection, which was associated with downmodulation of MHC class II molecules at the surface of infected cells. Strong stimulation of IE1-specific CD4(+) T cells resulted from endogenous de novo antigen production and presentation by infected macrophages during the first 3 days of virus replication, despite MHC class II downmodulation in the late replication phase. Therefore, infected macrophages are assumed to contribute to the antiviral immune response in infected organs.

Human cytomegalovirus labeled with green fluorescent protein for live analysis of intracellular particle movements.

Human cytomegalovirus (HCMV) replicates in the nuclei of infected cells. Successful replication therefore depends on particle movements between the cell cortex and nucleus during entry and egress. To visualize HCMV particles in living cells, we have generated a recombinant HCMV expressing enhanced green fluorescent protein (EGFP) fused to the C terminus of the capsid-associated tegument protein pUL32 (pp150). The resulting UL32-EGFP-HCMV was analyzed by immunofluorescence, electron microscopy, immunoblotting, confocal microscopy, and time-lapse microscopy to evaluate the growth properties of this virus and the dynamics of particle movements. UL32-EGFP-HCMV replicated similarly to wild-type virus in fibroblast cultures. Green fluorescent virus particles were released from infected cells. The fluorescence stayed associated with particles during viral entry, and fluorescent progeny particles appeared in the nucleus at 44 h after infection. Surprisingly, strict colocalization of pUL32 and the major capsid protein pUL86 within nuclear inclusions indicated that incorporation of pUL32 into nascent HCMV particles occurred simultaneously with or immediately after assembly of the capsid. A slow transport of nuclear particles towards the nuclear margin was demonstrated. Within the cytoplasm, most particles performed irregular short-distance movements, while a smaller fraction of particles performed centripetal and centrifugal long-distance movements. Although numerous particles accumulated in the cytoplasm, release of particles from infected cells was a rare event, consistent with a release rate of about 1 infectious unit per h per cell in HCMV-infected fibroblasts as calculated from single-step growth curves. UL32-EGFP-HCMV will be useful for further investigations into the entry, maturation, and release of this virus.

Dissemination of pheU- and pheV-located genomic islands among enteropathogenic (EPEC) and enterohemorrhagic (EHEC) E. coli and their possible role in the horizontal transfer of the locus of enterocyte effacement (LEE).

We have recently shown that the locus of enterocyte effacement (LEE) of the bovine enterohemorrhagic E. coli RW1374 (O103:H2) resides within a large pathogenicity island (PAI), integrated in the vicinity of the phenylalanine tRNA gene pheV. Here we describe an additional, but LEE-negative genomic island in RW1374 in the vicinity of another phenylalanine tRNA gene, pheU, the sequence of which is identical to pheV. These two genomic islands revealed identity of the left, but a relative variability of their right end sequences. To investigate the mechanism of LEE-PAI distribution in E. coli, we analysed similar junctions in the pheU/pheV loci of additional EPEC and EHEC strains the LEE location of which had not been determined before. By hybridisation of NotI restriction fragments with probes specific for LEE, pheV locus, and pheU locus, the LEE was found linked to either one of these two loci. The results agreed well with recently published phylogenetic data and indicate that in the clones of diarrheagenic E. coli (Dec) Dec 11 and Dec 12, forming the phylogenetic cluster EPEC 2, and in the strains of the most typical serotypes of the Dec 8, belonging to the phylogenetic cluster EHEC 2, the LEE was linked with pheV and not with the pheU locus as previously assumed. Sequence comparison with other pheU- and pheV-located genomic islands from different E. coli pathotypes (uropathogenic E. coli, septicemic E. coli) as well as from Shigella indicated the same structural features at the junctions. These conserved structures suggested a common DNA cassette, serving as common vehicle for horizontal gene transfer of various PAls. In addition, the elements suggest an origin from a common pheU-located ancestor and integration into the chromosome through site-specific recombination. Our results indicate that pheU/pheV-located genomic islands played an important role in the evolution of several PAls in E. coli and related pathogens.