Lung epithelial cells are a major site of murine gammaherpesvirus persistence

Kinetic and phenotypic changes in murine lymphocytes infected with murine gammaherpesvirus-68 in vitro

Primary infection with murine gammaherpesvirus-68 (MHV-68), as with other members of the gammaherpesvirus subfamily, is characterized by a lymphoproliferative phase. MHV-68 causes acute splenomegaly and an infectious mononucleosis-like syndrome in which there is expansion of the CD8+ T cell subset. In long-term infections, MHV-68 is associated with lymphoma development. In order to elucidate the mechanisms underlying the proliferative processes, the events following infection of murine splenocytes or purified murine B lymphocytes in vitro have been examined. MHV-68 infection prolonged the viability of murine splenocytes and stimulated cellular proliferation. Unlike Epstein-Barr virus and herpesvirus saimiri, MHV-68 did not cause growth transformation. Growth transformation did not occur even when cells with a predisposition to transformation were infected or when culture conditions were selected to enhance the viability of the cells. Following MHV-68 infection, the latency-associated viral tRNAs were transcribed. However, transcription of the other known latency-associated gene, M2, was not observed. In addition, there was no evidence of productive virus replication either by staining with antibodies specific for late virus antigens or by in situ hybridization for early and late mRNAs. In contrast to Epstein-Barr virus- and herpesvirus saimiri-infected lymphocytes, where episomal genomes are seen, Gardella gel analysis indicated that the primary lymphocytes infected by MHV-68 in vitro contained only linear virus DNA. This DNA was nuclease sensitive, indicating that, while MHV-68 was efficiently uncoated, its circularization in vitro was extremely inefficient. These results are discussed in terms of the host-virus interaction.

The murine gammaherpesvirus-68 M11 protein inhibits Fas- and TNF-induced apoptosis

The murine gammaherpesvirus-68 (MHV-68) M11 gene encodes a protein predicted to have limited homology to the bcl-2 family of proteins. Unlike most of the other viral bcl-2 homologues, which have both BH1 and BH2 domains conserved with respect to bcl-2, the M11 protein has a BH1 domain, but apparently lacks a BH2 domain. Transfection of HeLa cells with an epitope-tagged MHV-68 M11 construct showed that the protein is predominantly located in the cytoplasm of cells. In HeLa cells, M11 inhibited apoptosis induced by anti-Fas antibody and by TNF-alpha. Thus, despite its limited conservation with respect to other bcl-2 family members, the MHV-68 M11 protein is a potent inhibitor of apoptosis.

Requirement for CD4+ T Cells in Vβ4+CD8+ T Cell Activation Associated with Latent Murine Gammaherpesvirus Infection

A CD8+ T cell lymphocytosis in the peripheral blood is associated with the establishment of latency following intranasal infection with murine gammaherpesvirus-68. Remarkably, a large percentage of the activated CD8+ T cells of mice expressing different MHC haplotypes express Vβ4+ TCR. Identification of the ligand driving the Vβ4+CD8+ T cell activation remains elusive, but there is a general correlation between Vβ4+CD8+ T cell stimulatory activity and establishment of latency in the spleen. In the current study, the role of CD4+ T cells in the Vβ4+CD8+ T cell expansion has been addressed. The results show that CD4+ T cells are essential for expansion of the Vβ4+CD8+ subset, but not other Vβ subsets, in the peripheral blood. CD4+ T cells are required relatively late in the antiviral response, between 7 and 11 days after infection, and mediate their effect independently of IFN-γ. Assessment of Vβ4+CD8+ T cell stimulatory activity using murine gammaherpesvirus-68-specific T cell hybridomas generated from latently infected mice supports the idea that CD4+ T cells control levels of the stimulatory ligand that drives the Vβ4+CD8+ T cells. As Vβ4+CD8+ T cell expansion also correlates with levels of activated B cells, these data raise the possibility that CD4+ T cell-mediated B cell activation is required for optimal expression of the stimulatory ligand. In addition, in cases of low ligand expression, there may also be a direct role for CD4+ T cell-mediated help for Vβ4+CD8+ T cells.

Murine gammaherpesvirus 68 encodes a functional regulator of complement activation

Sequence analysis of the murine gammaherpesvirus 68 (gammaHV68) genome revealed an open reading frame (gene 4) which is homologous to a family of proteins known as the regulators of complement activation (RCA proteins) (H. W. Virgin, P. Latreille, P. Wamsley, K. Hallsworth, K. E. Weck, A. J. Dal Canto, and S. H. Speck, J. Virol. 71:5894-5904, 1997). The predicted gene 4 product has homology to other virally encoded RCA homologs, as well as to the complement-regulatory proteins decay-accelerating factor and membrane cofactor protein. Analyses by Northern blotting and rapid amplification of cDNA ends revealed that gene 4 is transcribed as a 5.2-kb bicistronic transcript of the late kinetic class. Three gammaHV68 RCA protein isoforms (60 to 65 kDa, 50 to 55 kDa, and 40 to 45 kDa) were detected by Western blotting of infected murine NIH 3T12 fibroblast cells. A soluble 40- to 45-kDa isoform was detected in the supernatants of virally infected cells. Flow cytometric analysis revealed that the gammaHV68 RCA protein was expressed on the surfaces of infected cells. Supernatants from virally infected cells contained an activity that inhibited murine complement activation as measured by inhibition of C3 deposition on activated zymosan particles. Recombinant gammaHV68 RCA protein, containing the four conserved short consensus repeats, inhibited murine C3 deposition on zymosan via both classical and alternative pathways and inhibited deposition of human C3 on activated zymosan particles. Expression of this inhibitor of complement activation, both at the cell surface and in the fluid phase, may be important for gammaHV68 pathogenesis via the inhibition of innate and adaptive immunity.

Apparent MHC-Independent Stimulation of CD8+ T Cells In Vivo During Latent Murine Gammaherpesvirus Infection

Like EBV-infected humans with infectious mononucleosis, mice infected with the rodent gammaherpesvirus MHV-68 develop a profound increase in the number of CD8+ T cells in the circulation. In the mouse model, this lymphocytosis consists of highly activated CD8+ T cells strikingly biased toward Vβ4 TCR expression. Moreover, this expansion of Vβ4+CD8+ T cells does not depend on the MHC haplotype of the infected animal. Using a panel of lacZ-inducible T cell hybridomas, we have detected Vβ4-specific T cell stimulatory activity in the spleens of MHV-68-infected mice. We show that the appearance and quantity of this activity correlate with the establishment and magnitude of latent viral infection. Furthermore, on the basis of Ab blocking studies as well as experiments with MHC class II, β2-microglobulin (β2m) and TAP1 knockout mice, the Vβ4-specific T cell stimulatory activity does not appear to depend on conventional presentation by classical MHC class I or class II molecules. Taken together, the data indicate that during latent infection, MHV-68 may express a T cell ligand that differs fundamentally from both conventional peptide Ags and classical viral superantigens.

Unraveling immunity to gamma-herpesviruses: a new model for understanding the role of immunity in chronic virus infection

Murine gamma-herpesvirus 68 (gammaHV68) infection is a new model for understanding how immunity and chronic gamma-herpesvirus infection inter-relate. gammaHV68 is closely related to the human Epstein-Barr virus and Kaposi's sarcoma herpesvirus and is associated with tumors, vasculitis of the great elastic arteries and splenic fibrosis. Advances in the past year have provided an even stronger foundation for believing that gammaHV68 infection of normal and mutant mice will become the pre-eminent animal model for understanding gamma-herpesvirus pathogenesis and immunity. gammaHV68 latency has been characterized employing new assays for quantitating cells carrying the gammaHV68 genome and cells that reactivate gammaHV68 and for detecting the presence of preformed infectious virus in tissues. These advances have fostered the first steps towards a molecular definition of gammaHV68 latency. It appears that gammaHV68 shares latency programs with human gamma-herpesviruses - including the loci for gene 73, v-bcl-2 and the viral homolog of the G-protein coupled receptor. This provides candidate antigens for analysis of the role of T and B cells in regulating latency. Multiple cellular reservoirs for gammaHV68 latency were uncovered with the demonstration that gammaHV68 latently infects macrophages in addition to B cells. A critical role for B cells in regulating the nature of gammaHV68 latency was discovered and the mechanism was shown to be via alteration of the efficiency of reactivation. Studies of the response of CD4(+) and CD8(+) cells during acute and chronic gammaHV68 were performed. These new studies provide key building blocks for further development of this novel and interesting model system.

Host and viral genetics of chronic infection: a mouse model of gamma-herpesvirus pathogenesis

A general association of human and primate lymphotropic herpesviruses (gamma-herpesviruses) with the development of lymphomas, as well as other tumors, especially in immunocompromised hosts, has been well documented. The lack of relevant small animal models for human gamma-herpesviruses has impeded progress in understanding the role of these viruses in the development of chronic disease. Recent research characterizing infection of inbred strains of mice with a murine gamma-herpesvirus, gamma-herpesvirus 68 (gammaHV68), is providing insights into viral and host factors involved in the establishment and control of chronic gamma-herpesvirus infection.

Lytic Cycle T Cell Epitopes Are Expressed in Two Distinct Phases During MHV-68 Infection

Murine herpesvirus-68 (MHV-68) is a type 2 γ herpesvirus that productively infects alveolar epithelial cells during the acute infection and establishes long-term latency in B cells and lung epithelial cells. In C57BL/6 mice, T cells specific for lytic cycle MHV-68 epitope p56/Db dominate the acute phase of the infection, whereas T cells specific for another lytic cycle epitope, p79/Kb, dominate later phases of infection. To further understand this response, we analyzed the kinetics of Ag presentation in vivo using a panel of lacZ-inducible T cell hybridomas specific for several lytic cycle epitopes, including p56/Db and p79/Kb. Two distinct peaks of Ag presentation were observed. The first peak was at day 6 in the mediastinal lymph nodes and correlated with the initial pulmonary lytic infection. The second peak was at day 18 in both the mediastinal lymph nodes and spleen and correlated with the peak of latent infection. Interestingly, the p56 epitope was detected only in the mediastinal lymph nodes at day 6 after infection whereas the p79 epitope was predominantly presented in the spleen at day 18, suggesting that differential epitope presentation drives the switch in T cell responses to this virus. Phenotypic analysis of APCs at day 18 postinfection revealed that dendritic cells, macrophages, and B cells all presented lytic cycle epitopes. Taken together, the data suggest that there is a resurgence of lytic cycle Ags in the spleen, which explains the kinetics and specificity of the T cell response to MHV-68.

Murine gammaherpesvirus M2 gene is latency-associated and its protein a target for CD8(+) T lymphocytes

Murine gammaherpesvirus 68 (MHV-68) infection of mice is a potential model with which to address fundamental aspects of the pathobiology and host control of gammaherpesvirus latency. Control of MHV-68 infection, like that of Epstein-Barr virus, is strongly dependent on the cellular immune system. However, the molecular biology of MHV-68 latency is largely undefined. A screen of the MHV-68 genome for potential latency-associated mRNAs revealed that the region encompassing and flanking the genomic terminal repeats is transcriptionally active in the latently infected murine B-cell tumor line S11. Transcription of one MHV-68 gene, that encoding the hypothetical M2 protein, was detected in virtually all latently infected S11 cells and in splenocytes of latently infected mice, but not in lytically infected fibroblasts. Furthermore, an epitope was identified in the predicted M2 protein that is recognized by CD8(+) T cells from infected mice and a cytotoxic T lymphocyte line that recognizes this epitope killed S11 cells, indicating that the M2 protein is expressed during latent infection and is a target for the host cytotoxic T lymphocyte response. This work therefore provides essential information for modeling MHV-68 latency and strategies of immunotherapy against gammaherpesvirus-related diseases in a highly tractable animal model.

B cells regulate murine gammaherpesvirus 68 latency

The dynamics of the establishment of, and reactivation from, gammaherpesviruses latency has not been quantitatively analyzed in the natural host. Gammaherpesvirus 68 (gammaHV68) is a murine gammaherpesvirus genetically related to primate gammaherpesviruses that establishes a latent infection in infected mice. We used limiting dilution reactivation (frequency of cells reactivating gammaHV68 in vitro) and limiting dilution PCR (frequency of cells carrying gammaHV68 genome) assays to compare gammaHV68 latency in normal (C57BL/6) and B-cell-deficient (MuMT) mice. After intraperitoneal (i.p.) inoculation, latent gammaHV68 was detected in the spleen, bone marrow, and peritoneal cells. Both B-cell-deficient and C57BL/6 mice established latent infection in peritoneal cells after either i.p. or intranasal (i.n.) inoculation. In contrast, establishment of splenic latency was less efficient in B-cell-deficient than in C57BL/6 mice after i.n. inoculation. Analysis of reactivation efficiency (reactivation frequency compared to frequency of cells carrying gammaHV68 genome) revealed that (i) regardless of route or mouse strain, splenic cells reactivated gammaHV68 less efficiently than peritoneal cells, (ii) the frequency of cells carrying gammaHV68 genome was generally comparable over the course of infection between C57BL/6 and B-cell-deficient mice, (iii) between 28 and 250 days after infection, cells from B-cell-deficient mice reactivated gammaHV68 10- to 100-fold more efficiently than cells from C57BL/6 mice, (iv) at 7 weeks postinfection, B-cell-deficient mice had more genome-positive peritoneal cells than C57BL/6 mice, and (v) mixing cells (ratio of 3 to 1) that reactivated inefficiently with cells that reactivated efficiently did not significantly decrease reactivation efficiency. Consistent with a failure to normally regulate chronic gammaHV68 infection, the majority of infected B-cell-deficient mice died between 100 and 200 days postinfection. We conclude that (i) B cells are not required for establishment of gammaHV68 latency, (ii) there are organ-specific differences in the efficiency of gammaHV68 reactivation, (iii) B cells play a crucial role in regulating reactivation of gammaHV68 from latency, and (iv) B cells are important for controlling chronic gammaHV68 infection.

Quantitative analysis of the acute and long-term CD4(+) T-cell response to a persistent gammaherpesvirus

The murine gammaherpesvirus 68 (MHV-68) replicates in respiratory epithelial cells, where it establishes a persistent, latent infection limited predominantly to B lymphocytes. The virus-specific CD4(+) T-cell response in C57BL/6 mice challenged intranasally with MHV-68 is detected first in the mediastinal lymph nodes and then in the cervical lymph nodes and the spleen. The numbers of MHV-68-specific CD4(+) T cells generated in congenic mice homozygous for disruption of the beta2-microglobulin gene tended to be higher, indicating that the absence of the CD8(+) set in this group resulted in a compensatory response. The peak frequency within the splenic CD4(+) T-cell population may reach 1:50 in the acute response; it then drops to 1:400 to 1:500 within 4 months and stays at that level in the very long term. Sorting for L-selectin (CD62L) expression established that all virus-specific CD4(+) T cells were initially CD62Llow, with >80% maintaining that phenotype for the next 14 months. The overall conclusion is that MHV-68-specific CD4(+) T cells remain activated (CD62Llow) and at a stable frequency in the face of persistent infection.

Macrophages are the major reservoir of latent murine gammaherpesvirus 68 in peritoneal cells

B cells have previously been identified as the major hematopoietic cell type harboring latent gammaherpesvirus 68 (gammaHV68) (N. P. Sunil-Chandra, S. Efstathiou, and A. A. Nash, J. Gen. Virol. 73:3275-3279, 1992). However, we have shown that gammaHV68 efficiently establishes latency in B-cell-deficient mice (K. E. Weck, M. L. Barkon, L. I. Yoo, S. H. Speck, and H. W. Virgin, J. Virol. 70:6775-6780, 1996), demonstrating that B cells are not required for gammaHV68 latency. To understand this dichotomy, we determined whether hematopoietic cell types, in addition to B cells, carry latent gammaHV68. We observed a high frequency of cells that reactivate latent gammaHV68 in peritoneal exudate cells (PECs) derived from both B-cell-deficient and normal C57BL/6 mice. PECs were composed primarily of macrophages in B-cell-deficient mice and of macrophages plus B cells in normal C57BL/6 mice. To determine which cells in PECs from C57BL/6 mice carry latent gammaHV68, we developed a limiting-dilution PCR assay to quantitate the frequency of cells carrying the gammaHV68 genome in fluorescence-activated cell sorter-purified cell populations. We also quantitated the contribution of individual cell populations to the total frequency of cells carrying latent gammaHV68. At early times after infection, the frequency of PECs that reactivated gammaHV68 correlated very closely with the frequency of PECs carrying the gammaHV68 genome, validating measurement of the frequency of viral-genome-positive cells as a measure of latency in this cell population. F4/80-positive macrophage-enriched, lymphocyte-depleted PECs harbored most of the gammaHV68 genome and efficiently reactivated gammaHV68, while CD19-positive, B-cell-enriched PECs harbored about a 10-fold lower frequency of gammaHV68 genome-positive cells. CD4-positive, T-cell-enriched PECs contained only a very low frequency of gammaHV68 genome-positive cells, consistent with previous analyses indicating that T cells are not a reservoir for gammaHV68 latency (N. P. Sunil-Chandra, S. Efstathiou, and A. A. Nash, J. Gen. Virol. 73:3275-3279, 1992). Since macrophages are bone marrow derived, we determined whether elicitation of a large inflammatory response in the peritoneum would recruit additional latent cells into the peritoneum. Thioglycolate inoculation increased the total number of PECs by about 20-fold but did not affect the frequency of cells that reactivate gammaHV68, consistent with a bone marrow reservoir for latent gammaHV68. These experiments demonstrate gammaHV68 latency in two different hematopoietic cell types, F4/80-positive macrophages and CD19-positive B cells, and argue for a bone marrow reservoir for latent gammaHV68.

Three distinct regions of the murine gammaherpesvirus 68 genome are transcriptionally active in latently infected mice

The program(s) of gene expression operating during murine gammaherpesvirus 68 (gammaHV68) latency is undefined, as is the relationship between gammaHV68 latency and latency of primate gammaherpesviruses. We used a nested reverse transcriptase PCR strategy (sensitive to approximately one copy of gammaHV68 genome for each genomic region tested) to screen for the presence of viral transcripts in latently infected mice. Based on the positions of known latency-associated genes in other gammaherpesviruses, we screened for the presence of transcripts corresponding to 11 open reading frames (ORFs) in the gammaHV68 genome in RNA from spleens and peritoneal cells of latently infected B-cell-deficient (MuMT) mice which have been shown contain high levels of reactivable latent gammaHV68 (K. E. Weck, M. L. Barkon, L. I. Yoo, S. H. Speck, and H. W. Virgin, J. Virol. 70:6775-6780, 1996). To control for the possible presence of viral lytic activity, we determined that RNA from latently infected peritoneal and spleen cells contained few or no detectable transcripts corresponding to seven ORFs known to encode viral gene products associated with lytic replication. However, we did detect low-level expression of transcripts arising from the region of gene 50 (encoding the putative homolog of the Epstein-Barr virus BRLF1 transactivator) in peritoneal but not spleen cells. Latently infected peritoneal cells consistently scored for expression of RNA derived from 4 of the 11 candidate latency-associated ORFs examined, including the regions of ORF M2, ORF M11 (encoding v-bcl-2), gene 73 (a homolog of the Kaposi's sarcoma-associated herpesvirus [human herpesvirus 8] gene encoding latency-associated nuclear antigen), and gene 74 (encoding a G-protein coupled receptor homolog, v-GCR). Latently infected spleen cells consistently scored positive for RNA derived from 3 of the 11 candidate latency-associated ORFs examined, including ORF M2, ORF M3, and ORF M9. To further characterize transcription of these candidate latency-associated ORFs, we examined their transcription in lytically infected fibroblasts by Northern analysis. We detected abundant transcription from regions of the genome containing ORF M3 and ORF M9, as well as the known lytic-cycle genes. However, transcription of ORF M2, ORF M11, gene 73, and gene 74 was barely detectable in lytically infected fibroblasts, consistent with a role of these viral genes during latent infection. We conclude that (i) we have identified several candidate latency genes of murine gammaHV68, (ii) expression of genes during latency may be different in different organs, consistent with multiple latency programs and/or multiple cellular sites of latency, and (iii) regions of the viral genome (v-bcl-2 gene, v-GCR gene, and gene 73) are transcribed during latency with both gammaHV68 and primate gammaherpesviruses. The implications of these findings for replacing previous operational definitions of gammaHV68 latency with a molecular definition are discussed.

Non-antigen-specific B-cell activation following murine gammaherpesvirus infection is CD4 independent in vitro but CD4 dependent in vivo

The murine gammaherpesvirus MHV-68 multiplies in the respiratory epithelium after intranasal inoculation, then spreads to infect B cells in lymphoid germinal centers. Exposing B cells to MHV-68 in vitro caused an increase in cell size, up-regulation of the CD69 activation marker, and immunoglobulin M (IgM) production. The infectious process in vivo was also associated with increased CD69 expression on B cells in the draining lymph nodes and spleen, together with a rise in total serum Ig. However, whereas the in vitro effect on B cells was entirely T-cell independent, evidence of in vivo B-cell activation was minimal in CD4(+) T-cell-deficient (I-Ab-/-) or CD4(+) T-cell-depleted mice. Furthermore, the Ig present at high levels in serum was predominantly of the IgG class. Surprisingly, the titer of influenza virus-specific serum IgG in previously immunized mice fell following MHV-68 infection, suggesting that there was relatively little activation of memory B cells. Thus, CD4(+) T cells seemed both to amplify a direct viral activation of B cells in lymphoid tissue and to promote new Ig class switching despite a lack of obvious cognate antigen.

Virus-specific CD8(+) T cell numbers are maintained during gamma-herpesvirus reactivation in CD4-deficient mice

The murine gamma-herpesvirus 68 replicates in epithelial sites after intranasal challenge, then persists in various cell types, including B lymphocytes. Mice that lack CD4(+) T cells (I-Ab-/-) control the acute infection, but suffer an ultimately lethal recrudescence of lytic viral replication in the respiratory tract. The consequences of CD4(+) T cell deficiency for the generation and maintenance of murine gamma-herpesvirus 68-specific CD8(+) set now have been analyzed by direct staining with viral peptides bound to major histocompatibility complex class I tetramers and by a spectrum of functional assays. Both acutely and during viral reactivation, the CD8(+) T cell responses in the I-Ab-/- group were no less substantial than in the I-Ab+/+ controls. Indeed, virus-specific CD8(+) T cell numbers were increased in the lymphoid tissue of clinically compromised I-Ab-/- mice, although relatively few of the potential cytotoxic T lymphocyte effectors were recruited back to the site of pathology in the lung. Thus the viral reactivation that occurs in the absence of CD4(+) T cells was not associated with any exhaustion of the virus-specific cytotoxic T lymphocyte response. It seems that CD8(+) T cells alone are insufficient to maintain long-term control of this persistent gamma-herpesvirus.