Moloney murine leukemia virus tolerance in anti-CD4 monoclonal antibody-treated adult mice.

Adult mice injected with Moloney murine leukemia virus (M-MuLV) 1 day after a short term treatment with anti-CD4 mAb developed T cell lymphomas, or sarcomas when rechallenged with Moloney murine sarcoma virus (M-MSV). Neoplastic development was correlated with virus spread, as thymic and peripheral T and B lymphocytes promptly expressed M-MuLV-induced Ag after virus introduction; no virus-specific CTL generation was detected in MLTC. This failure, which was selective for M-MuLV-induced Ag, persisted throughout the life span of the mice, and was not sustained by suppressor cell activity. The frequencies of splenic virus-specific CTL precursor varied in relation to time after virus injection; in the first postinjection month, frequencies were similar to those in nonimmune control mice, while at 4 mo post-virus exposure, they showed a striking reduction. These findings indicate that a transient functional impairment of CD4+ cells at the time of retrovirus injection provided the appropriate milieu for tolerance induction in both the peripheral mature and intrathymic T cell compartments.     

T lymphocyte tolerance and early appearance of virus-induced cell surface antigens in Moloney-murine leukemia virus neonatally injected mice

Regression of Moloney-murine sarcoma virus- (M-MSV) induced sarcomas in normal adult mice is accompanied by generation of virus-specific cytotoxic T lymphocytes (CTL). However, when neonatal mice that were injected with Moloney-murine leukemia virus (M-MuLV carrier) were subsequently challenged as adults with M-MSV, the sarcomas did not regress nor did they generate CTL. This failure to produce CTL cannot be ascribed to nonspecific immunodepressive effects or to suppressor cell generation since M-MuLV carrier mice exhibit normal reactivity after allogeneic cell stimulation. Moreover, addition of M-MuLV-infected cells as the third party to cultures does not reduce activity of CTL from M-MSV immune mice. Since M-MSV and M-MuLV possess common antigens, the observed unresponsiveness was considered in relationship to induction of a T lymphocyte tolerance, which may follow introduction of foreign antigens at an early stage of development. In fact, it was observed that as early as 10 days after injection, thymus, lymph node, and spleen from M-MuLV carrier mice express virus-induced cell-surface antigens that not only are targets for M-MSV-immune CTL, but also induce in vitro a strong specific cytotoxic response. In addition, a cold target inhibition assay disclosed that the same antigens are shared by both M-MuLV infected and leukemia cells, even though they are less expressed on the surface of the former. The finding that the cytotoxicity of alloreactive lymphocytes from M-MuLV carrier mice is reduced after preincubation with M-MSV immune CTL confirms that virus infection does not bring about functional inactivation of lymphocytes. Finally, it was observed that virus antigen presence on lymphocytes from M-MuLV neonatally injected mice is closely related to subsequent leukemia development.     

Role of accessory cells in the induction of a secondary cytotoxic response to Moloney murine sarcoma virus-induced tumors

The role of Ia-positive accessory cells in the generation of a secondary cytotoxic response to tumor-associated antigens induced by Moloney murine sarcoma virus (M-MSV) was evaluated. Spleen cells from M-MSV-immune A.TL mice, depleted of accessory cells by anti-Iak serum plus C treatment and stimulated in secondary mixed leukocyte tumor cell culture (MLTC) with syngeneic Ia-negative A6ATL Moloney leukemic cells, failed to generate virus-specific cytotoxic T lymphocytes (CTL). CTL generation in Ia-depleted MLTC may be reconstituted by the addition of nonimmune Ia-positive spleen or peritoneal cells obtained not only from syngeneic A.TL but also from I-incompatible A.TH mice. This lack of restriction observed in accessory cell function is explained in terms of a nonspecific mechanism of CTL triggering mediated by soluble factors. In fact, IL 2 as well as supernatants obtained from I region-incompatible cultures consisting of M-MSV-immune, Ia-depleted A.TL spleen cells and A.TH Ia-positive cells, reconstituted secondary virus-specific CTL generation.     

Selective failure of accessory cell function in Moloney murine leukemia virus-tolerant mice

Accessory cell activity of spleen cells from M-MuLV neonatally injected (tolerant) mice was studied to evaluate their ability to take part in in vitro CTL generation against tumor-associated antigens induced by M-MSV. In contrast with accessory cell activity in normal spleen cells, spleen cells from M-MuLV-tolerant mice are unable to reconstitute the in vitro virus-specific CTL generation of M-MSV immune, Ia-depleted spleen cells. A selective defect seems to characterize M-MuLV-tolerant mice as their spleens constitute a good source of accessory cells for alloantigen CTL generation.     

In vivo administration of interleukin-2 protects susceptible mice from Theiler's virus persistence.

In vivo administration of interleukin-2 (IL-2)-secreting tumor cells results in complete protection against persistent infection by Theiler's murine encephalomyelitis virus (TMEV) in susceptible DBA/2 mice. The IL-2-mediated protection was found to depend on the inoculum size as well as the timing of IL-2 administration. IL-2-treated and TMEV-infected mice displayed a three- to fourfold relative increase in virus-specific cytotoxic T-lymphocyte (CTL) precursors. Thus, we postulate that the persistence of TMEV infection in susceptible mice reflects limited numbers of relevant CTL precursors and their time course of induction and activation.     

An early, abundant cytotoxic T-lymphocyte response against Theiler's virus is critical for preventing viral persistence.

In genetically susceptible strains of mice, the DA strain of Theiler's virus, a picornavirus, causes a persistent infection of the white matter of the spinal cord associated with chronic demyelination. In resistant strains, on the other hand, the infection is cleared within 1 to 2 weeks. In this article, we show that Theiler's virus induces a rapid and abundant cytotoxic T lymphocyte (CTL) response in resistant C57BL/6 mice, while the response remains low throughout infection in susceptible SJL/J mice. This difference can be referred to a higher number of virus-specific CTL precursors in C57BL/6 mice. These observations indicate that the efficient induction of virus-specific CTL precursors is critical for avoiding the establishment of a persistent picornaviral infection.     

Delayed clearance of Sendai virus in mice lacking class I MHC-restricted CD8+ T cells.

The role and interdependence of CD8+ and CD4+ alpha beta-T cells in the acute response after respiratory infection with the murine parainfluenza type 1 virus, Sendai virus, has been analyzed for H-2b mice. Enrichment of CD8+ virus-specific CTL effectors in the lungs of immunologically intact C57BL/6 animals coincided with the clearance of the virus from this site by day 10 after infection. Removal of the CD4+ T cells by in vivo mAb treatment did not affect appreciably either the recruitment of CD8+ T cells to the infected lung, or their development into virus-specific cytotoxic effectors. In contrast, depletion of the CD8+ subset delayed virus clearance, although most mice survived the infection. Transgenic H-2b F3 mice homozygous (-/-) for a beta 2 microglobulin (beta 2-m) gene disruption, which lack both class I MHC glycoproteins and mature CD8+ alpha beta-T cells, showed a comparable, delayed clearance of Sendai virus from the lung. Virus-specific, class II MHC-restricted CTL were demonstrated in both freshly isolated bronchoalveolar lavage populations and cultured lymph node and spleen tissue from the beta 2-m (-/-) transgenics. Treatment of the beta 2-m (-/-) mice with the mAb to CD4 led to delayed virus clearance and death, which was also the case for normal mice that were depleted simultaneously of the CD4+ and CD8+ subsets. These results indicate that, although classical class I MHC-restricted CD8+ cytotoxic T cells normally play a dominant role in the recovery of mice acutely infected with Sendai virus, alternative mechanisms involving CD4+ T cells exist and can compensate, in time, for the loss of CD8+ T cell function.     

Dissecting the Immune Response to Moloney Murine Sarcoma/Leukemia Virus-Induced Tumors by Means of a DNA Vaccination Approach

The intramuscular inoculation of Moloney murine sarcoma/leukemia (M-MSV/M-MuLV) retroviral complex gives rise to sarcomas that undergo spontaneous regression due to the induction of a strong immune reaction mediated primarily by cytotoxic T lymphocytes (CTL). We used a DNA-based vaccination approach to dissect the CTL response against the Gag and Env proteins of M-MSV/M-MuLV in C57BL/6 (B6) mice and to evaluate whether plasmid DNA-immunized mice would be protected against a subsequent challenge with syngeneic tumor cells expressing the viral antigens. Intramuscular DNA vaccination induced CTL against both Gag and Env proteins. A detailed analysis of epitopes recognized by CTL generated in mice inoculated with the whole virus and with the Gag-expressing plasmid confirmed the presence of an immunodominant peptide in the leader sequence of Gag protein (Gag_85–93, CCLCLTVFL) that is identical to that described in B6 mice immunized with Friend MuLV-induced leukemia cells. Moreover, CTL generated by immunization with the Env-encoding plasmid recognized a subdominant Env peptide (Env_189–196, SSWDFITV), originally described in the B6.CH-2^bm13 mutant strain. B6 mice immunized with the Gag-expressing plasmid were fully protected against a lethal tumor challenge with M-MuLV-transformed MBL-2 leukemia cells, while vaccination with the Env-expressing plasmid resulted in rejection of the tumor in 44% of the mice and in increased survival of an additional 17% of the animals. Taken together, these results indicate the existence of a hierarchy in the capacity of different structural viral proteins to induce a protective immune response against retrovirus-induced tumors.     

NK Cells Regulate CD8+ T Cell Priming and Dendritic Cell Migration during Influenza A Infection by IFN-γ and Perforin-Dependent Mechanisms

An effective immune response against influenza A infection depends on the generation of virus-specific T cells. NK cells are one of the first-line defenses against influenza A infection. We set out to delineate the role of NK cells in T cell immunity using a murine model of influenza A infection with A/PR/8/34. We show that early T cell recruitment mainly occurs in the posterior mediastinal lymph node (pMLN). Depletion of NK cells significantly impaired both dendritic cell (DC) and T cell recruitment into the pMLN. A similar reduction of T cell recruitment was observed when migration was blocked by pertussis toxin, suggesting that migration of pulmonary NK cells and DCs regulates cell recruitment to the pMLN. T cell recruitment was dependent on IFN-γ, and transfer of IFN-γ-competent naive NK cells into IFN-γ(-/-) mice restored T cell recruitment, whereas IFN-γ-deficient NK cells failed to do so. In addition, NK cell depletion reduced the uptake and transport of influenza A virus by DCs, and significantly impaired the virus-specific T cell response. Both IFN-γ(-/-) and perforin(-/-) mice showed reduced viral Ag transport by DCs, suggesting that the ability of NK cells to influence virus transport depends on IFN-γ and perforin. In summary, our data suggest that NK cells play a critical role in the initiation and shaping of the T cell response after influenza A infection.     

Failure or success in the restoration of virus-specific cytotoxic T lymphocyte response defects by dendritic cells

C57BL/6 (B6, H-2b) mice are CTL responders to both Sendai virus and Moloney leukemia virus. In the former response the H-2Kb class I MHC molecule is used as CTL restriction element, in the latter response the H-2Db molecule. B6 dendritic cells (DC) are superior in the presentation of Sendai virus Ag to CTL in comparison with B6 normal spleen cells. Con A blasts have even less capacity to present viral Ag than NSC, and LPS blasts show an intermediate capacity to present viral Ag. H-2Kb mutant bm1 mice do not generate a CTL response to Sendai virus, but respond to Moloney leukemia virus, as demonstrated by undetectable CTL precursors to Sendai virus and a normal CTL precursor frequency to Moloney virus. Compared to B6 mice, other H-2Kb mutant mice show decreased Sendai virus-specific CTL precursor frequencies in a hierarchy reflecting the response in bulk culture. The Sendai virus-specific CTL response defect of bm1 mice was not restored by highly potent Sendai virus-infected DC as APC for in vivo priming and/or in vitro restimulation. In mirror image to H-2Kb mutant bm1 mice, H-2Db mutant bm14 mice do not generate a CTL response to Moloney virus, but respond normally to Sendai virus. This specific CTL response defect was restored by syngeneic Moloney virus-infected DC for in vitro restimulation. This response was Kb restricted indicating that the Dbm14 molecule remained largely defective and that a dormant Kb repertoire was aroused after optimal Ag presentation by DC. In conclusion, DC very effectively present viral Ag to CTL. However, their capacity to restore MHC class I determined specific CTL response defects probably requires at least some ability of a particular MHC class I/virus combination to associate and thus form an immunogenic complex.     

Alveolar macrophages regulate the induction of primary cytotoxic T-lymphocyte responses during influenza virus infection.

Virus-specific cytotoxic T lymphocytes (CTL) are thought to be responsible for the eradication of respiratory influenza virus infections by direct cytolysis of virus-infected epithelial cells. In this study, we provide evidence for a role for alveolar macrophages (AM) in the regulation of pulmonary virus-specific CTL responses. Prior to infection with influenza virus, AM were selectively eliminated in vivo with a liposome-mediated depletion technique, and virus-specific CTL activities of lung and mediastinal lymph node (MLN) cells were assayed ex vivo and compared with those for normal mice. AM depletion resulted in increased primary CTL responses and changed the kinetics of the CTL response. Flow cytometric analysis of lung and MLN cells showed that the percentage of CD8+ cells was not altered after AM depletion and that lung cells from AM-depleted mice had an increased capacity to lyse virus-infected cells. Upon restimulation in vitro, virus-specific CTL activity in lung cells of normal mice was similar to that in lung cells of AM-depleted mice. Furthermore, elimination of AM resulted in increased virus titers in the lung, but virus clearance as a function of time was not affected. Our results show that AM regulate virus-specific CTL responses during respiratory influenza virus infection by removing viral particles, by downregulating the priming and activity of CTL in MLN cells, and by inhibiting the expansion of virus-specific CTL in the lung.     

Accessory cell requirements for the generation of cytolytic T lymphocytes.

A system is presented that may simplify the study of accessory cell requirements for CTL generation. Cortisone resistant (CR) thymocytes containing alloreactive CTL precursors do not respond to allogeneic tumor cells unless non-T accessory cells are added to culture. In addition, splenic T cells do not respond to allogeneic tumor cells in the absence of non-T accessory cells. These accessory cells share several properties of macrophages.     

Gamma interferon is not required for mucosal cytotoxic T-lymphocyte responses or heterosubtypic immunity to influenza A virus infection in mice

Heterosubtypic immunity (HSI) is defined as cross-protection against influenza virus of a different serotype than the virus initially encountered and is thought to be mediated by influenza virus-specific cytotoxic T lymphocytes (CTL). Since gamma interferon (IFN-gamma) stimulates cytotoxic cells, including antigen-specific CTL which may control virus replication by secretion of antiviral cytokines such as tumor necrosis factor alpha and IFN-gamma, we have investigated the mechanism of HSI by analyzing the role of IFN-gamma for HSI in IFN-gamma gene-deleted (IFN-gamma(-/-)) mice. It has been reported that IFN-gamma is not required for recovery from primary infection with influenza virus but is important for HSI. Here, we conclusively show that IFN-gamma is not required for induction of secondary influenza virus-specific CTL responses in mediastinal lymph nodes and HSI to lethal influenza A virus infection. Although T helper 2 (Th2)-type cytokines were upregulated in the lungs of IFN-gamma(-/-) mice after virus challenge, either Th1- or Th2-biased responses could provide heterosubtypic protection. Furthermore, titers of serum-neutralizing and cross-reactive antibodies to conserved nucleoprotein in IFN-gamma(-/-) mice did not differ significantly from those in immunocompetent mice. These results indicate that lack of IFN-gamma does not impair cross-reactive virus-specific immune responses and HSI to lethal infection with influenza virus. Our findings provide new insight for the mechanisms of HSI and should be valuable in the development of protective mucosal vaccines against variant virus strains, such as influenza and human immunodeficiency virus.     

Analysis of Murine CD8+ T-Cell Clones Specific for the Dengue Virus NS3 Protein: Flavivirus Cross-Reactivity and Influence of Infecting Serotype

Serotype-cross-reactive dengue virus-specific cytotoxic T lymphocytes (CTL) induced during a primary dengue virus infection are thought to play a role in the immunopathogenesis of dengue hemorrhagic fever (DHF) during a secondary dengue virus infection. Although there is no animal model of DHF, we previously reported that murine dengue virus-specific CTL responses are qualitatively similar to human dengue virus-specific CTL responses. We used BALB/c mice to study the specificity of the CTL response to an immunodominant epitope on the dengue virus NS3 protein. We mapped the minimal H-2K^d-restricted CTL epitope to residues 298 to 306 of the dengue type 2 virus NS3 protein. In short-term T-cell lines and clones, the predominant CD8⁺ CTL to this epitope in mice immunized with dengue type 2 virus or vaccinia virus expressing the dengue type 4 virus NS3 protein were cross-reactive with dengue type 2 or type 4 virus, while broadly serotype-cross-reactive CTL were a minority population. In dengue type 3 virus-immunized mice, the predominant CTL response to this epitope was broadly serotype cross-reactive. All of the dengue virus-specific CTL clones studied also recognized the homologous NS3 sequences of one or more closely related flaviviruses, such as Kunjin virus. The critical contact residues for the CTL clones with different specificities were mapped with peptides having single amino acid substitutions. These data demonstrate that primary dengue virus infection induces a complex population of flavivirus-cross-reactive NS3-specific CTL clones in mice and suggest that CTL responses are influenced by the viral serotype. These findings suggest an additional mechanism by which the order of sequential flavivirus infections may influence disease manifestations.     

Heteroduplex analysis of the RNA of clone 3 Moloney murine sarcoma virus.

Heteroduplex analysis of the RNA isolated from purified virions of clone 3 Moloney murine sarcoma virus (M-MSV) hybridized to cDNA's from Moloney murine leukemia virus (M-MLV) and clone 124 M-MSV shows that the main physical component of clone 3 RNA is missing all or most of the 1.5-kilobase (kb) clone 124 M-MSV specific sequence denoted beta s (S. Hu et al. Cell 10:469--477, 1977). This sequence is either deleted in clone 3 RNA or substituted by a very short (0.3-kilobase) sequence. In other respects, clone 3 and clone 124 RNAs show the same heteroduplex structure relative to M-MLV. Since beta s is believed to contain the src gene(s) of clone 124 RNA, this result leaves as an unresolved question the nature of the src gene(s) of the clone 3 M-MSV RNA complex.     

Virus-specific CD8+ T-cell responses in mice transgenic for a T-cell receptor beta chain selected at random.

The consequences of severely limiting the T-cell receptor (TCR) repertoire available for the response to intranasal infection with an influenza A virus or with Sendai virus have been analyzed by using H-2k mice (TG8.1) transgenic for a TCR beta-chain gene (V beta 8.1D beta 2J beta 2.3C beta 2). Analyzing the prevalence of V beta 8.1+ CD8+ T cells in lymph node cultures from nontransgenic (non-TG) H-2k controls primed with either virus and then stimulated in vitro with the homologous virus or with anti-CD3 epsilon showed that this TCR is not normally selected from the CD8+ T-cell repertoire during these infections. However, the TG8.1 mice cleared both viruses and generated virus-specific effector cytotoxic T lymphocytes (CTL) and memory CTL precursors, though the responses were delayed compared with the non-TG controls. Depletion of the CD4+ T-cell subset had little effect on the course of influenza virus infection but substantially slowed the development of the Sendai virus-specific CTL response and virus elimination in both the TG8.1 and non-TG mice, indicating that CD4+ helpers are promoting the CD8+ T-cell response in the Sendai virus model. Even so, restricting the available T-cell repertoire to lymphocytes expressing a single TCR beta chain still allows sufficient TCR diversity for CD8+ T cells (acting in the presence or absence of the CD4+ subset) to limit infection with an influenza A virus and a parainfluenza type 1 virus.     

Human virus-specific CD8+ CTL clones revert from CD45ROhigh to CD45RAhigh in vivo: CD45RAhighCD8+ T cells comprise both naive and memory cells.

It has been generally believed that human CD8+ memory cells are principally found within the CD45ROhigh population. There are high frequencies of CD8+ memory CTL specific for the human CMV tegument phosphoprotein pp65 in PBMC of long-term virus carriers; the large population of memory CTL specific for a given pp65 peptide contains individual CTL clones that have greatly expanded. In this study, we found high frequencies of pp65 peptide-specific memory CTL precursors in the CD45ROhighCD45RA- population, but also appreciable frequencies in the CD45RAhigh subpopulation. Because the majority of CD8+ T cells in PBMC are CD45RAhigh, more of the total pp65-specific memory CTL pool is within the CD45RAhigh than in the CD45ROhigh compartment. Using clonotypic oligonucleotide probes to quantify the size of individual pp65-specific CTL clones in vivo, we found the CD45RAhigh population contributed 6- to 10-fold more than the CD45ROhigh population to the total virus-specific clone size in CD8+ cells. During primary CMV infection, an individual virus-specific CTL clone was initially CD45ROhigh, but after resolution of infection this clone was detected in both the CD45ROhigh and the CD45RAhigh populations. We conclude that CD45RA+ human CD8+ T cells do not solely comprise naive cells, but contain a very significant proportion of memory cells, which can revert from the CD45ROhigh to CD45RAhigh phenotype in vivo.     

The role of IL-2 and T4+ cells in the generation of human influenza virus-specific CTL activity

Stimulation of human peripheral blood lymphocytes (PBL) with influenza A virus leads to the generation of virus-specific cytotoxic T lymphocyte (CTL) activity as well as natural killer (NK)-like activity. In this study, we show that exogenous IL-2 augments the in vitro generation of virus-specific CTL activity, only when added some days after the initiation of the culture. Apparently, the endogenously produced IL-2 can be a limiting factor in the in vitro generation of CTL activity. The increase of influenza virus-specific CTL activity after addition of exogenous IL-2 does not affect the restriction pattern of the CTL response. So, the preferential use of certain HLA antigens as restriction elements is not due to a limiting amount of endogenously produced IL-2. Depletion of T4+ cells completely abrogates the generation of virus-specific CTL activity. Addition of exogenous IL-2 to T4+-cell-depleted cultures fully restores the generation of HLA-restricted virus-specific CTL activity. We conclude that in the in vitro generation of virus-specific CTL activity in bulk cultures of human PBL the sole function of T4+ cells in human virus-specific CTL generation is the production of IL-2, no cognitive cell interaction of T8+ CTL precursors with T4+ cells is required, and in bulk cultures T8+ cells themselves are not able to produce sufficient amounts of IL-2 to ascertain the maturation of virus-specific CTL precursors into cytolytic T cells. Finally, we show that exogenous IL-2 also has a stimulatory effect on the NK-like or lymphokine-activated killer activity, which is always concomitantly induced in virus-specific CTL generation cultures, but has no influence on the levels of IFN produced in such cultures.     

In Situ Evolution of Virus-Specific Cytotoxic T Cell Responses in the Lung

Cytotoxic T cells (CTL) play a critical role in the clearance of respiratory viral infections, but they also contribute to disease manifestations. In this study, we infected mice with a genetically modified pneumonia virus of mice (PVM) that allowed visualization of virus-specific CTL and infected cells in situ. The first virus-specific T cells entered the lung via blood vessels in the scattered foci of PVM-infected cells, which densely clustered around the bronchi at day 7 after infection. At this time, overall pulmonary virus load was maximal, but the mice showed no overt signs of disease. On days 8 to 9, T cells gained access to the infected bronchial epithelium and to the lung interstitium, which was associated with a reduction in the number of virus-infected cells within the initial clusters but could not prevent further virus spread throughout the lung tissue. Interestingly, recruitment of virus-specific CTL throughout the parenchyma was still ongoing on day 10, when the virus infection was already largely controlled. This also represented the peak of clinical disease. Thus, disease was associated with an exuberant T cell infiltration late in the course of the infection, which may be required to completely eliminate virus at residual foci of infection. PVM-induced immunopathology may thus result from the need to generate widespread T cell infiltrates to complete the elimination of virus-infected cells in a large organ like the lung. This experimental model provides the first insights into the spatiotemporal evolution of pulmonary antiviral T cell immunity in vivo.