Indirect CD4+ T cell protection against mouse gamma-herpesvirus infection via interferon gamma.

CD4+ T cells play a key role in γ-herpesvirus infection control. However, the mechanisms involved are unclear. Murine herpesvirus type 4 (MuHV-4) allows relevant immune pathways to be dissected experimentally in mice. In the lungs, it colonizes myeloid cells, which can express MHC class II (MHCII), and type 1 alveolar epithelial cells (AEC1), which lack it. Nevertheless, CD4+ T cells can control AEC1 infection, and this control depends on MHCII expression in myeloid cells. Interferon-gamma (IFNγ) is a major component of CD4+ T cell-dependent MuHV-4 control. Here, we show that the action of IFNγ is also indirect, as CD4+ T cell-mediated control of AEC1 infection depended on IFNγ receptor (IFNγR1) expression in CD11c+ cells. Indirect control also depended on natural killer (NK) cells. Together, the data suggest that the activation of MHCII+ CD11c+ antigen-presenting cells is key to the CD4+ T cell/NK cell protection axis. By contrast, CD8+ T cell control of AEC1 infection appeared to operate independently. IMPORTANCE: CD4+ T cells are critical for the control of gamma-herpesvirus infection; they act indirectly, by recruiting natural killer (NK) cells to attack infected target cells. Here, we report that the CD4+ T cell/NK cell axis of gamma-herpesvirus control requires interferon-γ engagement of CD11c+ dendritic cells. This mechanism of CD4+ T cell control releases the need for the direct engagement of CD4+ T cells with virus-infected cells and may be a common strategy for host control of immune-evasive pathogens.

Glycogen Synthase Kinase 3 Inactivation Drives T-bet-Mediated Downregulation of Co-receptor PD-1 to Enhance CD8(+) Cytolytic T Cell Responses.

Despite the importance of the co-receptor PD-1 in T cell immunity, the upstream signaling pathway that regulates PD-1 expression has not been defined. Glycogen synthase kinase 3 (GSK-3, isoforms α and ß) is a serine-threonine kinase implicated in cellular processes. Here, we identified GSK-3 as a key upstream kinase that regulated PD-1 expression in CD8(+) T cells. GSK-3 siRNA downregulation, or inhibition by small molecules, blocked PD-1 expression, resulting in increased CD8(+) cytotoxic T lymphocyte (CTL) function. Mechanistically, GSK-3 inactivation increased Tbx21 transcription, promoting enhanced T-bet expression and subsequent suppression of Pdcd1 (encodes PD-1) transcription in CD8(+) CTLs. Injection of GSK-3 inhibitors in mice increased in vivo CD8(+) OT-I CTL function and the clearance of murine gamma-herpesvirus 68 and lymphocytic choriomeningitis clone 13 and reversed T cell exhaustion. Our findings identify GSK-3 as a regulator of PD-1 expression and demonstrate the applicability of GSK-3 inhibitors in the modulation of PD-1 in immunotherapy.

Indirect CD4+ T cell protection against persistent MCMV infection by NK cells requires IFNγ.

Host control of mouse cytomegalovirus (MCMV) infection of MHCII- salivary gland acinar cells is mediated by CD4+ T cells, but how they protect is unclear. Here, we show CD4+ T cells control MCMV indirectly in the salivary gland, via IFNγ engagement with uninfected, but antigen+ MHCII+ APC and recruitment of NK cells to infected cell foci. This immune mechanism renders direct contact of CD4+ T cells with infected cells unnecessary and may represent a host strategy to overcome viral immune evasion.

The Mouse Cytomegalovirus G Protein-Coupled Receptor Homolog, M33, Coordinates Key Features of In Vivo Infection via Distinct Components of Its Signaling Repertoire.

Common to all cytomegalovirus (CMV) genomes analyzed to date is the presence of G protein-coupled receptors (GPCR). Animal models of CMV provide insights into their role in viral fitness. The mouse cytomegalovirus (MCMV) GPCR, M33, facilitates dendritic cell (DC)-dependent viremia, the extravasation of blood-borne infected DCs to the salivary gland, and the frequency of reactivation events from latently infected tissue explants. Constitutive G protein-coupled M33 signaling is required for these phenotypes, although the contribution of distinct biochemical pathways activated by M33 is unknown. M33 engages Gq/11 to constitutively activate phospholipase C ß (PLCß) and downstream cyclic AMP response-element binding protein (CREB) in vitro. Identification of a MCMV M33 mutant (M33ΔC38) for which CREB signaling was disabled but PLCß activation was preserved provided the opportunity to investigate their relevance in vivo. Following intranasal infection with MCMV M33ΔC38, the absence of M33 CREB Gq/11-dependent signaling correlated with reduced mobilization of lytically-infected DCs to the draining lymph node high endothelial venules (HEVs) and reduced viremia compared with wild type MCMV. In contrast, M33ΔC38-infected DCs within the vascular compartment extravasated to the salivary glands via a pertussis toxin-sensitive, Gi/o-dependent, and CREB-independent mechanism. In the context of MCMV latency, spleen explants from M33ΔC38-infected mice were markedly attenuated for reactivation. Taken together, these data demonstrate that key features of the MCMV life cycle are coordinated in diverse tissues by distinct pathways of the M33 signaling repertoire. IMPORTANCE G protein-coupled receptors (GPCRs) act as cell surface molecular "switches" that regulate the cellular response to environmental stimuli. All cytomegalovirus (CMV) genomes analyzed to date possess GPCR homologs with phylogenetic evidence for independent gene capture events, signifying important in vivo roles. The mouse CMV (MCMV) GPCR homolog, designated M33, is important for cell-associated virus spread and the establishment and/or reactivation of latent MCMV infection. The signaling repertoire of M33 is distinct from cellular GPCRs and little is known of the relevance of component signaling pathways for in vivo M33 function. In this report, we showed that temporal and tissue-specific M33 signaling was required to facilitate in vivo infection. Understanding the relevance of the viral GPCR signaling profiles for in vivo function will provide opportunities for future targeted interventions.

CD4+ T Cells Control Murine Cytomegalovirus Infection Indirectly.

CD4+ T cells are key to controlling cytomegalovirus infections. Salivary gland infection by murine cytomegalovirus (MCMV) provides a way to identify mechanisms. CD11c+ dendritic cells (DC) disseminate MCMV to the salivary glands, where they transfer infection to acinar cells. Antiviral CD4+ T cells are often considered to be directly cytotoxic for cells expressing major histocompatibility complex class II (MHCII). However, persistently infected salivary gland acinar cells are MHCII- and are presumably inaccessible to direct CD4 T cell recognition. Here, we show that CD4+ T cell depletion amplified infection of MHCII- acinar cells but not MHCII+ cells. MCMV-infected mice with disrupted MHCII on CD11c+ cells showed increased MHCII- acinar infection; antiviral CD4+ T cells were still primed, but their recruitment to the salivary glands was reduced, suggesting that engagement with local MHCII+ DC is important for antiviral protection. As MCMV downregulates MHCII on infected DC, the DC participating in CD4 protection may thus be uninfected. NK cells and gamma interferon (IFN-γ) may also contribute to CD4+ T cell-dependent virus control: CD4 T cell depletion reduced NK cell recruitment to the salivary glands, and both NK cell and IFN-γ depletion equalized infection between MHCII-disrupted and control mice. Taken together, these results suggest that CD4+ T cells protect indirectly against infected acinar cells in the salivary gland via DC engagement, requiring the recruitment of NK cells and the action of IFN-γ. Congruence of these results with an established CD4+ T cell/NK cell axis of gammaherpesvirus infection control suggests a common mode of defense against evasive viruses. IMPORTANCE Cytomegalovirus infections commonly cause problems in immunocompromised patients and in pregnancy. We lack effective vaccines. CD4+ T cells play an important role in normal infection control, yet how they act has been unknown. Using murine cytomegalovirus as an accessible model, we show that CD4+ T cells are unlikely to recognize infected cells directly. We propose that CD4+ T cells interact with uninfected cells that present viral antigens and recruit other immune cells to attack infected targets. These data present a new outlook on understanding how CD4+ T cell-directed control protects against persistent cytomegalovirus infection.

A Live Olfactory Mouse Cytomegalovirus Vaccine, Attenuated for Systemic Spread, Protects against Superinfection.

Vaccination against the betaherpesvirus, human cytomegalovirus (HCMV) is a public health goal. However, HCMV has proved difficult to vaccinate against. Vaccination against single HCMV determinants has not worked, suggesting that immunity to a wider antigenic profile may be required. Live attenuated vaccines provide the best prospects for protection, but the question remains as to how to balance vaccine virulence with safety. Animal models of HCMV infection provide insights into identifying targets for virus attenuation and understanding how host immunity blocks natural, mucosal infection. Here, we evaluated the vaccine potential of a mouse cytomegalovirus (MCMV) vaccine deleted of a viral G protein-coupled receptor (GPCR), designated M33, that renders it attenuated for systemic spread. A single noninvasive olfactory ΔM33 MCMV vaccine replicated locally, but as a result of the loss of the M33 GPCR, it failed to spread systemically and was attenuated for latent infection. Vaccination did not prevent host entry of a superinfecting MCMV but spread from the mucosa was blocked. This approach to vaccine design may provide a viable alternative for a safe and effective betaherpesvirus vaccine. IMPORTANCE Human cytomegalovirus (HCMV) is the most common cause of congenital infection for which a vaccine is not yet available. Subunit vaccine candidates have failed to achieve licensure. A live HCMV vaccine may prove more efficacious, but it faces safety hurdles which include its propensity to persist and to establish latency. Understanding how pathogens infect guide rational vaccine design. However, HCMV infections are asymptomatic and thus difficult to capture. Animal models of experimental infection provide insight. Here, we investigated the vaccine potential of a mouse cytomegalovirus (MCMV) attenuated for systemic spread and latency. We used olfactory vaccination and virus challenge to mimic its natural acquisition. We provide proof of concept that a single olfactory MCMV that is deficient in systemic spread can protect against wild-type MCMV superinfection and dissemination. This approach of deleting functional counterpart genes in HCMV may provide safe and effective vaccination against congenital HCMV disease.

Murine Cytomegalovirus MCK-2 Facilitates In Vivo Infection Transfer from Dendritic Cells to Salivary Gland Acinar Cells.

The cytomegaloviruses (CMVs) spread systemically via myeloid cells and demonstrate broad tissue tropism. Human CMV (HCMV) UL128 encodes a component of the virion pentameric complex (PC) that is important for entry into epithelial cells and cell-cell spread in vitro. It possesses N-terminal amino acid sequences similar to those of CC chemokines. While the species specificity of HCMV precludes confirmation of UL128 function in vivo, UL128-like counterparts in experimental animals have demonstrated a role in salivary gland infection. How they achieve this has not been defined, although effects on monocyte tropism and immune evasion have been proposed. By tracking infected cells following lung infection, we show that although the UL128-like protein in mouse CMV (MCMV) (designated MCK-2) facilitated entry into lung macrophages, it was dispensable for subsequent viremia mediated by CD11c+ dendritic cells (DCs) and extravasation to the salivary glands. Notably, MCK-2 was important for the transfer of MCMV infection from DCs to salivary gland acinar epithelial cells. Acinar cell infection of MCMVs deleted of MCK-2 was not rescued by T-cell depletion, arguing against an immune evasion mechanism for MCK-2 in the salivary glands. In contrast to lung infection, peritoneal MCMV inoculation yields mixed monocyte/DC viremia. In this setting, MCK-2 again promoted DC-dependent infection of salivary gland acinar cells, but it was not required for monocyte-dependent spread to the lung. Thus, the action of MCK-2 in MCMV spread was specific to DC-acinar cell interactions. IMPORTANCE Cytomegaloviruses (CMVs) establish myeloid cell-associated viremias and persistent shedding from the salivary glands. In vitro studies with human CMV (HCMV) have implicated HCMV UL128 in epithelial tropism, but its role in vivo is unknown. Here, we analyzed how a murine CMV (MCMV) protein with similar physical properties, designated MCK-2, contributes to host colonization. We demonstrate that MCK-2 is dispensable for initial systemic spread from primary infection sites but within the salivary gland facilitates the transfer of infection from dendritic cells (DCs) to epithelial acinar cells. Virus transfer from extravasated monocytes to the lungs did not require MCK-2, indicating a tissue-specific effect. These results provide new information about how persistent viral tropism determinants operate in vivo.

Olfactory Entry Promotes Herpesvirus Recombination.

Herpesvirus genomes show abundant evidence of past recombination. Its functional importance is unknown. A key question is whether recombinant viruses can outpace the immunity induced by their parents to reach higher loads. We tested this by coinfecting mice with attenuated mutants of murid herpesvirus 4 (MuHV-4). Infection by the natural olfactory route routinely allowed mutant viruses to reconstitute wild-type genotypes and reach normal viral loads. Lung coinfections rescued much less well. Attenuated murine cytomegalovirus mutants similarly showed recombinational rescue via the nose but not the lungs. These infections spread similarly, so route-specific rescue implied that recombination occurred close to the olfactory entry site. Rescue of replication-deficient MuHV-4 confirmed this, showing that coinfection occurred in the first encountered olfactory cells. This worked even with asynchronous inoculation, implying that a defective virus can wait here for later rescue. Virions entering the nose get caught on respiratory mucus, which the respiratory epithelial cilia push back toward the olfactory surface. Early infection was correspondingly focused on the anterior olfactory edge. Thus, by concentrating incoming infection into a small area, olfactory entry seems to promote functionally significant recombination. IMPORTANCE All organisms depend on genetic diversity to cope with environmental change. Small viruses rely on frequent point mutations. This is harder for herpesviruses because they have larger genomes. Recombination provides another means of genetic optimization. Human herpesviruses often coinfect, and they show evidence of past recombination, but whether this is rare and incidental or functionally important is unknown. We showed that herpesviruses entering mice via the natural olfactory route meet reliably enough for recombination routinely to repair crippling mutations and restore normal viral loads. It appeared to occur in the first encountered olfactory cells and reflected a concentration of infection at the anterior olfactory edge. Thus, natural host entry incorporates a significant capacity for herpesvirus recombination.

A CD4+ T Cell-NK Cell Axis of Gammaherpesvirus Control.

CD4+ T cells are essential to control herpesviruses. Murid herpesvirus 4 (MuHV-4)-driven lung disease in CD4+ T-cell-deficient mice provides a well-studied example. Protective CD4+ T cells have been hypothesized to kill infected cells directly. However, removing major histocompatibility complex class II (MHCII) from LysM+ or CD11c+ cells increased MuHV-4 replication not in those cells but in type 1 alveolar epithelial cells, which lack MHCII, LysM, or CD11c. Disruption of MHCII in infected cells had no effect. Therefore, CD4+ T cells engaged uninfected presenting cells and protected indirectly. Mice lacking MHCII in LysM+ or CD11c+ cells maintained systemic antiviral CD4+ T cell responses, but recruited fewer CD4+ T cells into infected lungs. NK cell infiltration was also reduced, and NK cell depletion normalized infection between MHCII-deficient and control mice. Therefore, NK cell recruitment seemed to be an important component of CD4+ T-cell-dependent protection. Disruption of viral CD8+ T cell evasion made this defense redundant, suggesting that it is important mainly to control CD8-evasive pathogens.IMPORTANCE Gammaherpesviruses are widespread and cause cancers. CD4+ T cells are a key defense. We found that they defend indirectly, engaging uninfected presenting cells and recruiting innate immune cells to attack infected targets. This segregation of CD4+ T cells from immediate contact with infection helps the immune system to cope with viral evasion. Priming this defense by vaccination offers a way to protect against gammaherpesvirus-induced cancers.

Limited protection against γ-herpesvirus infection by replication-deficient virus particles.

The γ-herpesviruses have proved hard to vaccination against, with no convincing protection against long-term latent infection by recombinant viral subunits. In experimental settings, whole-virus vaccines have proved more effective, even when the vaccine virus itself establishes latent infection poorly. The main alternative is replication-deficient virus particles. Here high-dose, replication-deficient murid herpesvirus-4 only protected mice partially against wild-type infection. By contrast, latency-deficient but replication-competent vaccine protected mice strongly, even when delivered non-invasively to the olfactory epithelium. Thus, this approach seems to provide the best chance of a safe and effective γ-herpesvirus vaccine.

Vaccine protection against murid herpesvirus-4 is maintained when the priming virus lacks known latency genes.

γ-Herpesviruses establish latent infections of lymphocytes and drive their proliferation, causing cancers and motivating a search for vaccines. Effective vaccination against murid herpesvirus-4 (MuHV-4)-driven lymphoproliferation by latency-impaired mutant viruses suggests that lytic access to the latency reservoir is a viable target for control. However, the vaccines retained the immunogenic MuHV-4 M2 latency gene. Here, a strong reduction in challenge virus load was maintained when the challenge virus lacked the main latency-associated CD8+ T-cell epitope of M2, or when the vaccine virus lacked M2 entirely. This protection was maintained also when the vaccine virus lacked both episome maintenance and the genomic region encompassing M1, M2, M3, M4 and ORF4. Therefore, protection did not require immunity to known MuHV-4 latency genes. As the remaining vaccine virus genes have clear homologs in human γ-herpesviruses, this approach of deleting viral latency genes could also be applied to them, to generate safe and effective vaccines against human disease.

Membrane association of a model CD4+ T-cell vaccine antigen confers enhanced yet incomplete protection against murid herpesvirus-4 infection.

Vaccination against γ-herpesviruses has proved difficult. CD4+ T cells are essential to contain infection, but how best to prime them and whether this can reduce viral loads remain unclear. To address these questions, we used ovalbumin (OVA) as a model antigen, delivering it with murine cytomegalovirus (MCMV) to protect mice against OVA-expressing murine herpesvirus-4 (MuHV-4). Membrane-associated OVA (mOVA) was more effective than soluble OVA, both to prime CD4+ T cells and as an effector target. It was also a better target than an OVA epitope limited to infected cells, suggesting that protective CD4+ T cells recognize infected cell debris rather than infected cells themselves. While MCMV-mOVA protected acutely against MuHV-4-mOVA, long-term protection was incomplete, even when OVA-specific CD8+ T cells and B cells were also primed. Thus, even optimized single-target vaccines may poorly reduce long-term γ-herpesvirus infections.

Murine Cytomegalovirus Spread Depends on the Infected Myeloid Cell Type.

Cytomegaloviruses (CMVs) colonize blood-borne myeloid cells. Murine CMV (MCMV) spreads from the lungs via infected CD11c+ cells, consistent with an important role for dendritic cells (DC). We show here that MCMV entering via the olfactory epithelium, a natural transmission portal, also spreads via infected DC. They reached lymph nodes, entered the blood via high endothelial venules, and then entered the salivary glands, driven by constitutive signaling of the viral M33 G protein-coupled receptor (GPCR). Intraperitoneal infection also delivered MCMV to the salivary glands via DC. However, it also seeded F4/80+ infected macrophages to the blood; they did not enter the salivary glands or require M33 for extravasation. Instead, they seeded infection to a range of other sites, including brown adipose tissue (BAT). Peritoneal cells infected ex vivo then adoptively transferred showed similar cell type-dependent differences in distribution, with abundant F4/80+ cells in BAT and CD11c+ cells in the salivary glands. BAT colonization by CMV-infected cells was insensitive to pertussis toxin inhibition of the GPCR signaling through Gi/o substrate, whereas salivary gland colonization was sensitive. Since salivary gland infection required both M33 and Gi/o-coupled signaling, whereas BAT infection required neither, these migrations were mechanistically distinct. MCMV spread from the lungs or nose depended on DC, controlled by M33. Infecting other monocyte populations resulted in unpredictable new infections.IMPORTANCE Cytomegaloviruses (CMVs) spread through the blood by infecting monocytes, and this can lead to disease. With murine CMV (MCMV) we can track infected myeloid cells and so understand how CMVs spread. Previous experiments have injected MCMV into the peritoneal cavity. MCMV normally enters mice via the olfactory epithelium. We show that olfactory infection spreads via dendritic cells, which MCMV directs to the salivary glands. Peritoneal infection similarly reached the salivary glands via dendritic cells. However, it also infected other monocyte types, and they spread infection to other tissues. Thus, infecting the "wrong" monocytes altered virus spread, with potential to cause disease. These results provide a basis for understanding how the monocyte types infected by human CMV might promote different infection outcomes.

Murine Cytomegalovirus Glycoprotein O Promotes Epithelial Cell Infection In Vivo.

Cytomegaloviruses (CMVs) establish systemic infections across diverse cell types. Glycoproteins that alter tropism can potentially guide their spread. Glycoprotein O (gO) is a nonessential fusion complex component of both human CMV (HCMV) and murine CMV (MCMV). We tested its contribution to MCMV spread from the respiratory tract. In vitro, MCMV lacking gO poorly infected fibroblasts and epithelial cells. Cell binding was intact, but penetration was delayed. In contrast, myeloid infection was preserved, and in the lungs, where myeloid and type 2 alveolar epithelial cells are the main viral targets, MCMV lacking gO showed a marked preference for myeloid infection. Its poor epithelial cell infection was associated with poor primary virus production and reduced virulence. Systemic spread, which proceeds via infected CD11c+ myeloid cells, was initially intact but then diminished, because less epithelial infection led ultimately to less myeloid infection. Thus, the tight linkage between peripheral and systemic MCMV infections gave gO-dependent infection a central role in host colonization.IMPORTANCE Human cytomegalovirus is a leading cause of congenital disease. This reflects its capacity for systemic spread. A vaccine is needed, but the best viral targets are unclear. Attention has focused on the virion membrane fusion complex. It has 2 forms, so we need to know what each contributes to host colonization. One includes the virion glycoprotein O. We used murine cytomegalovirus, which has equivalent fusion complexes, to determine the importance of glycoprotein O after mucosal infection. We show that it drives local virus replication in epithelial cells. It was not required to infect myeloid cells, which establish systemic infection, but poor local replication reduced systemic spread as a secondary effect. Therefore, targeting glycoprotein O of human cytomegalovirus has the potential to reduce both local and systemic infections.

Murine cytomegalovirus degrades MHC class II to colonize the salivary glands.

Cytomegaloviruses (CMVs) persistently and systemically infect the myeloid cells of immunocompetent hosts. Persistence implies immune evasion, and CMVs evade CD8+ T cells by inhibiting MHC class I-restricted antigen presentation. Myeloid cells can also interact with CD4+ T cells via MHC class II (MHC II). Human CMV (HCMV) attacks the MHC II presentation pathway in vitro, but what role this evasion might play in host colonization is unknown. We show that Murine CMV (MCMV) down-regulates MHC II via M78, a multi-membrane spanning viral protein that captured MHC II from the cell surface and was necessary although not sufficient for its degradation in low pH endosomes. M78-deficient MCMV down-regulated MHC I but not MHC II. After intranasal inoculation, it showed a severe defect in salivary gland colonization that was associated with increased MHC II expression on infected cells, and was significantly rescued by CD4+ T cell loss. Therefore MCMV requires CD4+ T cell evasion by M78 to colonize the salivary glands, its main site of long-term shedding.

KSHV-TK is a tyrosine kinase that disrupts focal adhesions and induces Rho-mediated cell contraction.

Paradoxically, the thymidine kinase (TK) encoded by Kaposi sarcoma-associated herpesvirus (KSHV) is an extremely inefficient nucleoside kinase, when compared to TKs from related herpesviruses. We now show that KSHV-TK, in contrast to HSV1-TK, associates with the actin cytoskeleton and induces extensive cell contraction followed by membrane blebbing. These dramatic changes in cell morphology depend on the auto-phosphorylation of tyrosines 65, 85 and 120 in the N-terminus of KSHV-TK. Phosphorylation of tyrosines 65/85 and 120 results in an interaction with Crk family proteins and the p85 regulatory subunit of PI3-Kinase, respectively. The interaction of Crk with KSHV-TK leads to tyrosine phoshorylation of this cellular adaptor. Auto-phosphorylation of KSHV-TK also induces a loss of FAK and paxillin from focal adhesions, resulting in activation of RhoA-ROCK signalling to myosin II and cell contraction. In the absence of FAK or paxillin, KSHV-TK has no effect on focal adhesion integrity or cell morphology. Our observations demonstrate that by acting as a tyrosine kinase, KSHV-TK modulates signalling and cell morphology.

Cytomegalovirus host entry and spread.

Cytomegaloviruses (CMVs) are large, complex pathogens that persistently and systemically colonize most mammals. Human cytomegalovirus (HCMV) causes congenital harm, and has proved hard to control. One problem is that key vaccine targets - virus entry and spread in naive hosts - remain ill-defined. As CMVs predate human speciation, those of other mammals can provide new insight. Murine CMV (MCMV) enters new hosts via olfactory neurons. Like HCMV it binds to heparan, which is lacking from most differentiated apical epithelia but is displayed on olfactory neuronal cilia. It then spreads via infected dendritic cells (DCs), which migrate to draining lymph nodes (LNs), rejoin the circulation by entering high endothelial venules (HEVs), and extravasate into other tissues. This migration depends quantitatively on M33, a constitutively active viral G protein-coupled receptor (GPCR). The homologous US28 GPCR of HCMV can substitute for M33 in allowing MCMV-infected DCs to leave LNs via HEVs, so HCMV could potentially use the same route. The capacity of DCs to seed MCMV to tissues, and for other DCs to collect it for redistribution, suggest that DC recirculation chronically maintains and links diverse CMV reservoirs through lytic exchange.

Murine cytomegalovirus disseminates independently of CX3CR1, CCL2 or its m131/m129 chemokine homologue.

Cytomegaloviruses (CMVs) use myeloid cells to move within their hosts. Murine CMV (MCMV) colonizes the salivary glands for long-term shedding, and reaches them via CD11c+ infected cells. A need to recruit patrolling monocytes for systemic spread has been proposed, based on poor salivary gland infection in fractalkine receptor (CX3CR1)-deficient mice. We found no significant CX3CR1 dependence of salivary gland infection. CCL2 and the viral m131/m129 chemokine homologue were also redundant for acute MCMV spread, arguing against a need for inflammation or infection to recruit additional monocytes to the entry site. M131/m129 promoted salivary gland infection, but only after the initial seeding of infected cells to this site. Our data support the idea that MCMV disseminates by infecting and mobilizing tissue-resident dendritic cells.

Antibody arrests γ-herpesvirus olfactory super-infection independently of neutralization.

Protecting against persistent viruses is an unsolved challenge. The clearest example for a gamma-herpesvirus is resistance to super-infection by Murid herpesvirus-4 (MuHV-4). Most experimental infections have delivered MuHV-4 into the lungs. A more likely natural entry site is the olfactory epithelium. Its protection remains unexplored. Here, prior exposure to olfactory MuHV-4 gave good protection against super-infection. The protection was upstream of B cell infection, which occurs in lymph nodes, and showed redundancy between antibody and T cells. Adding antibody to virions that blocked heparan binding strongly reduced olfactory host entry - unlike in the lungs, opsonized virions did not reach IgG Fc receptor+ myeloid cells. However, the nasal antibody response to primary infection was too low to reduce host entry. Instead, the antibody acted downstream, reducing viral replication in the olfactory epithelium. This depended on IgG Fc receptor engagement rather than virion neutralization. Thus antibody can protect against natural γ-herpesvirus infection before it reaches B cells and independently of neutralization.

Gammaherpesvirus Colonization of the Spleen Requires Lytic Replication in B Cells.

Gammaherpesviruses infect lymphocytes and cause lymphocytic cancers. Murid herpesvirus-4 (MuHV-4), Epstein-Barr virus, and Kaposi's sarcoma-associated herpesvirus all infect B cells. Latent infection can spread by B cell recirculation and proliferation, but whether this alone achieves systemic infection is unclear. To test the need of MuHV-4 for lytic infection in B cells, we flanked its essential ORF50 lytic transactivator with loxP sites and then infected mice expressing B cell-specific Cre (CD19-Cre). The floxed virus replicated normally in Cre- mice. In CD19-Cre mice, nasal and lymph node infections were maintained; but there was little splenomegaly, and splenic virus loads remained low. Cre-mediated removal of other essential lytic genes gave a similar phenotype. CD19-Cre spleen infection by intraperitoneal virus was also impaired. Therefore, MuHV-4 had to emerge lytically from B cells to colonize the spleen. An important role for B cell lytic infection in host colonization is consistent with the large CD8+ T cell responses made to gammaherpesvirus lytic antigens during infectious mononucleosis and suggests that vaccine-induced immunity capable of suppressing B cell lytic infection might reduce long-term virus loads.IMPORTANCE Gammaherpesviruses cause B cell cancers. Most models of host colonization derive from cell cultures with continuous, virus-driven B cell proliferation. However, vaccines based on these models have worked poorly. To test whether proliferating B cells suffice for host colonization, we inactivated the capacity of MuHV-4, a gammaherpesvirus of mice, to reemerge from B cells. The modified virus was able to colonize a first wave of B cells in lymph nodes but spread poorly to B cells in secondary sites such as the spleen. Consequently, viral loads remained low. These results were consistent with virus-driven B cell proliferation exploiting normal host pathways and thus having to transfer lytically to new B cells for new proliferation. We conclude that viral lytic infection is a potential target to reduce B cell proliferation.