Antigen detection in vivo after immunization with different presentation forms of rabies virus antigen, II. Cellular, but not humoral, systemic immune responses against rabies virus immune-stimulating complexes are macrophage dependent.

In this paper we describe the effect of depletion of splenic macrophages on the uptake, and immune response against, different formulations of rabies virus antigen. Splenic macrophages were removed by intravenous injection with clodronate liposomes. beta-propiolacton inactivated rabies virus (RV-BPL) and immune-stimulating complexes (iscom) containing these antigens were given to macrophage-depleted and control mice. In the absence of phagocytic cells in the spleen, antigen is still trapped in the red pulp and to a lesser extent in the peri-arteriolar lymphocyte sheaths (PALS) for both antigen formulations. The localization pattern in the main area of immune response induction, namely the follicles, was unaltered after macrophage depletion. Functionally, the depletion of splenic and liver macrophages had no influence on the induction of specific antibody responses in both RV-BPL or RV-iscom immunized mice, even though the latter presentation form was clearly associated with specific localization in the marginal metallophillic macrophages. In RV-BPL immunized mice, macrophage depletion had no influence on proliferative T-cell responses. However, macrophage-depleted mice that were immunized with RV-iscom showed a significant decrease in proliferative T-cell responses. These results confirm existing ideas on the spleen as a physical filter rather than an induction site for humoral responses and shed new light on the efficient role of iscoms as antigen-presenting moieties in relation to their specific in vivo localization patterns and partial macrophage dependency.     

Crucial role of marginal zone macrophages and marginal zone metallophils in the clearance of lymphocytic choriomeningitis virus infection

Macrophages play a key role in the immune defense against pathogens. They control early invasion by antigen-unspecific phagocytosis of pathogens and act as professional antigen-presenting cells to induce antigen-specific T cell responses. To investigate the involvement of particular subsets of the splenic macrophages in an antiviral immune response, we selectively depleted mice of splenic marginal zone macrophages (MZM) and marginal zone metallophils (MM) using the clodronate liposome depletion technique. MZM- and MM-depleted mice were not able to control an infection with lymphocytic choriomeningitis virus (LCMV). In these mice, LCMV spread from the spleen to peripheral organs at an early phase of infection. The virus-specific cytotoxic T lymphocyte (CTL) response was induced initially, yet was exhausted in parallel with the overwhelming virus replication. These findings suggest that MZM and MM play a crucial role in the early control of a LCMV infection by preventing immediate virus spread to peripheral organs, but are not essential for the induction of the LCMV-specific CTL response.     

Elimination of virus-specific cytotoxic T cells in the liver

Immune responses in the liver have been studied for more than three decades, raising intriguing questions but providing few definitive answers. Many observations pertaining to immunity in this organ are unexpected and some of them even contradictory: parenchymal cells in the liver are readily accessible to circulating lymphocytes and may function as antigen-presenting cells (APC), yet antigens expressed in the liver often fail to induce responses and may cause systemic tolerance. There are rare lymphocyte classes in the liver, yet reasons why these cells reside in this organ and why immune responses are often poor remain to be elucidated. Here one of the central questions in immune responses in the liver is discussed (i.e., the ability of the adaptive T-cell-mediated immune response to clear a virus infection). An attempt is made to explain the intriguing observation that non-self-antigens expressed in the liver may induce unresponsiveness. It is shown that cell-mediated immunity to a viral infection is terminated, coincident with cell death of virus-specific cytotoxic T-lymphocytes (CTL) early after infection. Death of CTL is shown to involve interaction of Fas with Fas ligand, pointing to fratricide between activated CTL. The observation that T-cell death is inhibitable by injection of interleuken-2 is interpreted to point to a mechanism involving insufficient stimulation of T cells in conjunction with a death signal by Fas. The hypothesis is put forward that antigen presentation by unconventional APC in the liver leads to T-cell activation, in turn inducing lytic activity and expression of Fas and FasL on CTL. CTL then commit fratricide, aided by insufficient cytokine production and resulting in clonal elimination of virus-specific T cells and induction of tolerance.     

Difference in capacity of Sendai virus envelope components to induce cytotoxic T lymphocytes in primary and secondary immune responses.

Studies were made on the abilities of Sendai virus envelope components to induce primary and secondary generations of virus-specific cytotoxic mouse T lymphocytes (CTL). The primary CTL response in BALB/c mice was induced by reassembled envelope particles that had fusion activity but not by envelope glycoproteins without fusion activity, although both preparations induced a humoral immune response. Reconstitution of membrane-bound envelope proteins from envelope glycoproteins with lipids restored the fusion activity and the capacity to induce CTL. Target cells susceptible to virus-specific CTL could be induced by reassembled envelope particles, but not by envelope glycoproteins or LLC-MK2 cell-grown Sendai virus, neither of which had fusion activity. On the other hand, all the viruses and envelope components tested were found to stimulate a virus-specific CTL response in the in vitro secondary generation of CTL from virus-primed spleen cells. These results suggest that Senaei virus fusion activity is involved in primary induction of the CTL response as well as in target cell formation, but that it is not essential for secondary stimulation of the CTL response.     

Virus-specific T cell response prevents lymphoma development in mice infected by intrathymic inoculation of Moloney leukaemia virus (M-MuLV).

Previous work on mice neonatally injected with Moloney-murine leukaemia virus (M-MuLV) had shown that T cell lymphoma development correlates with virus infection of lymphoreticular cells (T and B lymphocytes and macrophages) as well as with a lack of generation of virus-specific cytotoxic T lymphocytes (CTL) due to clonal deletion of CTL precursors. In the present report, viral antigen expression and T cell response in mice injected as adults with M-MuLV intrathymus (i.t.) was investigated. Only thymic and splenic T lymphocytes from these mice express virus-induced antigens since they were lysed by virus-specific CTL, and stained by anti-M-MuLV fluorescent serum. In addition, the percentage of M-MuLV-infected T cells increased with increasing post- inoculation times. However, these mice could mount a strong cellular immune response against M-MuLV-infected cells, as detected by massive mixed leucocyte tumour cell culture and by evaluation of virus- specific CTL precursor frequency. Finally, i.t. injected mice were not viraemic and did not develop lymphomas during an observation period of 12-15 months. These data, in contrast with the recent hypothesis that T cell lymphoma development depends on a chronic stimulation of virus-specific T lymphocytes, indicate that the cellular immune response is sufficient for prevention of neoplastic transformation, despite a persistent viral infection of the thymus and peripheral T lymphocytes.     

Immunogenetic analysis of cellular interactions governing the recruitment of T lymphocytes and monocytes in lymphocytic choriomeningitis virus-induced immunopathology

The Lyt2+ class I major histocompatibility complex (MHC)-restricted virus-immune T cells that induce murine lymphocytic choriomeningitis (LCM) are targeted onto radiation-resistant cells in the central nervous system of virus-infected mice. The use of appropriate bone marrow radiation chimeras as LCM virus-infected, (immunosuppressed recipients for immune T-cell transfer has established that, though bone marrow-derived cells can stimulate virus-specific cytotoxic T lymphocytes (CTL) in spleen, they do not reconstitute the barrier to T-cell recruitment from blood to cerebrospinal fluid. This is true for chimeras made up to 8 months previously, even though the inflammatory monocytes and macrophages in such chimeras are all of donor bone marrow origin. Radiation-resistant cells in the spleens of these chimeras are also still able to further stimulate virus-immune CTL. There is no requirement for H-2 compatibility between virus-immune T lymphocytes and secondarily recruited monocytes, or T cells of an inappropriate specificity. The key event in LCM immunopathology may thus be localization of T cells to the antigen-presenting endothelium in brain, leading to the secretion of mediators that promote the nonspecific recruitment of monocytes and other T cells.     

The augmentation of tumor-specific immunity by virus help. II. Enhanced induction of cytotoxic T lymphocyte and antibody responses to tumor antigens by vaccinia virus-reactive helper T cells

The present study investigates the role of vaccinia virus-reactive helper T cells in causing enhanced induction of syngeneic tumor immunity. Vaccinia virus-reactive helper T cell activity capable of inducing the augmented generation of cytotoxic T lymphocyte (CTL) or antibody responses was generated in C3H/HeN mice by inoculating i.p. live virus. Immunization of these mice with vaccinia virus-infected syngeneic X5563 plasmacytoma or MH134 hapatoma cells led to augmented induction of immune resistance against the challenge with corresponding viable tumor cells when compared with the incidence of resistance observed in control mice not primed to vaccinia virus. In vitro cytotoxicity tests utilizing spleen cells and serum from mice which resulted in the augmented tumor resistance by virus help have revealed that spleen cells from C3H/HeN mice immune to the X5563 plasmacytoma exhibited appreciable anti-X5563 CTL activity, whereas serum from these mice failed to display any antibody response. In contrast, MH134-immune mice exhibited potent anti-MH134 antibody, but not CTL responses. Such an anti-tumor CTL or antibody response augmented by vaccinia virus-reactive helper T cells was found to be tumor specific. These results are discussed in the context of (a) the functional diversity of tumor antigens, and (b) mechanisms of virus help that are involved in various forms of augmented induction of syngeneic tumor immunity.     

Suppression of the generation of secondary virus-specific proliferative and cytotoxic T lymphocytes by suppressor cells induced during primary anti-viral sensitization in vitro

Murine spleen cells first primed with syngeneic vaccinia virus-infected peritoneal exudate cells (PEC) in vitro and then restimulated with the virus failed to give a typical virus-specific secondary cytotoxic T lymphocyte (CTL) response. In contrast, "memory' spleen cells from mice primed with the virus in vivo produced CTL after the same challenge with virus-infected PEC in vitro. In the former situation, the lack of a virus-specific secondary CTL response by in vitro primed and restimulated spleen cells seemed to be associated with the generation of suppressor cells in cultures; these cells inhibited the cytotoxic as well as proliferative secondary and tertiary responses of spleen presensitized with virus in vitro alone, or in vivo plus in vitro. Weak suppressor activity was also induced in control spleen-cell cultures from normal unprimed or virus-primed mice that were not stimulated with virus-infected cells, suggesting either a quantitative difference in the generation of suppression or, alternatively, the co-existence of virus-dependent and independent suppressor cells in the virus-stimulated cultures. Our experiments cannot conclusively establish that suppression is T-cell mediated and/or possibly natural-killer-(NK)-cell dependent. The suppressor phenomena were exerted by irradiation resistant (850 rad) lymphocytes that passed through nylon wool columns and were sensitive to treatment with anti-Thy-1 antibody plus C; but the suppressor cells were partially reactive across allogeneic barriers.     

Role of IgM antibodies versus B cells in influenza virus-specific immunity

We have compared the role of IgM antibodies with the role of B cells in control of primary influenza virus infection. Mice deficient in IgM (IgM(-/-)), but capable of producing other Igisotypes, exhibited increased pulmonary virus titers compared to wild-type mice. However, IgM(-/-) mice were less susceptible compared to B cell-deficient micro MT) mice. CD4(+) T cells from spleen and lung draining lymph nodes of infected micro MT mice showed reduced proliferation upon virus re-stimulation in vitro. Furthermore, numbers of IFN-gamma-producing CD4(+) effector T cells were reduced in the alveolar lavage (BAL) of micro MT mice but not IgM(-/-) mice. In contrast, total number of virus-specific CTL was almost comparable in BAL of micro MT and wild-type mice. Pulmonary recruitment of inflammatory macrophages and neutrophils occurred normally in both micro MT and IgM(-/-) mice. Interestingly, virus-specific IgG2a and IgG2b antibody responses were affected locally in the BAL and in the serum of IgM(-/-) mice, while IgG1 responses remained largely normal. Taken together, our data suggest a role for B cells to promote effector T cell responses and a role of both IgM and IgG antibodies in the defense against acute influenza virus infection.     

Elimination of resident macrophages from the livers and spleens of immune mice impairs acquired resistance against a secondary Listeria monocytogenes infection.

During a secondary Listeria monocytogenes infection in mice, the bacteria are eliminated more rapidly from the liver and spleen than during a primary infection. This acquired resistance against a secondary infection is dependent on T lymphocytes, which induce enhanced elimination of bacteria via stimulation of effector cells such as neutrophils, resident macrophages, exudate macrophages, and hepatocytes. The aim of the present study was to determine the role of the resident macrophages in acquired resistance against a secondary L. monocytogenes infection in mice. Mice which had recovered from a sublethal primary infection with 0.1 50% lethal dose (LD50) of L. monocytogenes intravenously (i.v.), i.e., immune mice, received a challenge of 1 LD50 of L. monocytogenes i.v. to induce a secondary infection. At 2 days prior to challenge, immune mice were given an i.v. injection of liposomes containing dichloromethylene-diphosphonate (L-Cl2MDP) to selectively eliminate resident macrophages from the liver and spleen. Control immune mice received either phosphate-buffered saline (PBS) or liposomes containing PBS (L-PBS). Treatment of mice with L-Cl2MDP effectively eliminated resident macrophages from the liver and spleen but did not affect the number of granulocytes, monocytes, or lymphocytes in peripheral blood or their migration to a site of inflammation. Phagocytosis and killing of L. monocytogenes by peritoneal exudate cells elicited with heat-killed L. monocytogenes were similar in all groups of immune mice. On day 3 of a secondary infection, the number of L. monocytogenes organisms in the livers and spleens of L-Cl2MDP-treated immune mice was 4 log10 units higher than in immune mice treated with PBS or L-PBS. The concentration of reactive nitrogen intermediates in plasma, a measure of the severity of infection, was 70-fold higher for L-Cl2MDP-treated immune mice than for PBS- or L-PBS-treated immune mice. Treatment with L-Cl2MDP significantly increased the number of inflammatory foci in the liver and spleen, decreased their size, and affected their structure. From these results, we conclude that resident macrophages are required for the expression of acquired resistance against a secondary L. monocytogenes infection in mice.     

Immune dysfunction expressed selectively on L3T4+ T cells in the tumor-bearing state

Spleen cells from normal C3H/He or BALB/c mice generate cytotoxic T-lymphocyte (CTL) responses to both trinitrophenyl (TNP)-modified syngeneic cells (TNP-self) and allogeneic cells. In contrast, cells from these strains of mice bearing a syngeneic tumor failed to induce anti-TNP-self-CTL responses, although portions of the same responding cells generated comparable anti-allo-CTL responses to those induced by normal responding cells. Although anti-allo-CTL responses were inducible from only Lyt-2+ T-cell subset of responding cells from normal or tumor-bearing mice, induction of TNP-CTL responses required the participation of L3T4+ T-cell subset as well as Lyt-2+ CTL precursors. In addition, the fact that the addition of concanavalin A-stimulated culture supernatant to cultures of responding cells from tumor-bearing mice resulted in the induction of appreciable anti-TNP-self CTL responses demonstrated the defect of L3T4+ T-cell function in the tumor-bearing state. Such a functional defect was ascribed neither to the loss of L3T4+ T cells nor to the generation of suppressor cells in spleen cells of tumor-bearing mice. It was found on one hand that in vitro stimulation of antigen-presenting cell (APC)-depleted normal responding population with TNP-self prepared from cells of normal or tumor-bearing mice produced comparable anti-TNP CTL responses. On the other hand, APC-depleted responding cells from tumor-bearing mice were unable to induce anti-TNP CTL responses under conditions in which APC-depleted normal responding cells induced an effective TNP-CTL response. These results indicate that selective impairment of L3T4+ T cell-mediated immunity is induced in the tumor-bearing state and that such an impairment is ascribed to the dysfunction of L3T4+ T cells themselves, but not of APC required for the activation of L3T4+ T-cell subset.     

Cellular changes and apoptosis in the spleens and peripheral blood of mice infected with blood-stage Plasmodium chabaudi chabaudi AS

Infection with blood-stage Plasmodium chabaudi chabaudi AS results in splenomegaly, peripheral leukocytosis, and a major activation of the immune system. The frequencies and absolute numbers of T-cell, B-cell, and macrophage populations in spleen and peripheral blood from P. chabaudi-infected BALB/c mice were compared and found to be significantly altered during acute infection. The kinetics of the redistribution of the different cell types in spleen and peripheral blood were different, with T and B cells appearing in the blood when their frequencies and absolute numbers in the spleen were low. The frequency and absolute number of apoptotic cells in the spleen were increased during acute P. chabaudi infection and involved both T cells, B cells, and macrophages. Both Fas and Fas-ligand expression were increased in the spleen. Taken together, our data provide new information on the complex cellular interactions that take place in the immune system during blood-stage malaria infection in a mouse model.     

Effective immunization against Bordetella pertussis respiratory infection in mice is dependent on induction of cell-mediated immunity.

A murine respiratory challenge model was used to examine the induction of cellular and humoral immune responses and their role in protection against Bordetella pertussis following immunization or previous infection. Spleen cells from mice convalescing from a B. pertussis infection exhibited extensive in vitro T-cell proliferation and secreted high levels of interleukin-2 (IL-2) and gamma interferon but not IL-4 or IL-5, a cytokine profile typical of CD4+ Th1 cells. Serum from these mice had low or undetectable anti-B. pertussis antibody levels. In contrast, mice immunized with an acellular pertussis vaccine had high levels of B. pertussis antibodies and spleen cells secreting IL-5 but not gamma interferon, a profile characteristic of CD4+ Th2 cells. Immunization with an inactivated whole-cell vaccine induced both CD4+ Th1 and serum antibody responses. After exposure to a B. pertussis respiratory challenge, the convalescent mice and those immunized with the whole-cell vaccine eliminated the bacterial infection significantly faster than mice immunized with the acellular vaccine. These findings show that the selection of antigens and their form of presentation are important in determining whether the subsequent immune response is cellular, mediated by Th1 cells, or humoral, mediated by Th2 cells. In the murine model, the induction of a Th1-mediated cellular immune response appears to be a key element in acquired immunity to a B. pertussis infection.     

Presence of a macrophage-mediated suppressor cell mechanism during cell-mediated immune response in experimental visceral leishmaniasis.

In susceptible BALB/c mice, systemic intracellular infection with Leishmania donovani provokes generation of adherent spleen cells which can suppress both mitogen- and specific-antigen-stimulated T-cell responses. To characterize the responsible suppressor cell, we irradiated (2,000 R) adherent spleen cells from L. donovani-infected mice or treated them with anti-Thy-1.2 antibody plus complement. Neither anti-T-cell treatment diminished the capacity to inhibit lymphocyte proliferative activity. In addition, as judged by morphologic and functional criteria, 80 to 90% of the adherent cells appeared to be macrophages. Four observations suggested an immunopathogenic role for these suppressor macrophages. (i) Their appearance and disappearance paralleled the establishment and resolution of L. donovani visceral infection in vivo. (ii) Suppressive effects included inhibition of production of the macrophage-activating lymphokine gamma interferon (IFN-gamma). (iii) On transfer into immune mice, suppressor macrophages impaired naturally acquired resistance to L. donovani. (iv) Inhibition of macrophage prostaglandin metabolism by indomethacin reduced suppressor activity in vitro and resulted in a 50% decrease in parasite visceral replication in vivo. In addition, prophylactic cyclophosphamide treatment inhibited the development of suppressor macrophages, and under these conditions visceral infection was rapidly controlled. These results suggested that disseminated L. donovani infection provokes a macrophage-mediated suppressor mechanism which appears to contribute to establishment of visceral leishmaniasis in a susceptible host.     

The role of macrophages in the induction and regulation of immunity elicited by exogenous antigens

Different delivery vehicles may target to different antigen presenting cells (APC) because of their composition, size and/or physical properties. In this study, we examined the priming of cytotoxic T lymphocyte (CTL) responses to a soluble exogenous protein in vivo, using various delivery vehicles. In addition, we determined the role of macrophages as APC in vivo for each of these delivery vehicles by comparing the induction of antigen-specific CTL and serum antibodies in normal and macrophage-depleted mice. Influenza A virus-derived virosomes, liposomes and monophosphoryl lipid A/squalene (MPL/SQ) efficiently induced antigen-specific CTL as well as antibody responses, of which virosomes proved to be the most efficient inducers. In mice that were immunized with cell-associated antigen, strong CTL responses but no antigen-specific antibodies were detectable, while aluminium hydroxide and aluminium phosphate elicited antigen-specific antibodies but no CTL responses. Eli mination of macrophages in vivo before immunization abrogated CTL responses induced with liposomes and MPL/SQ, but did not affect induction of antigen-specific CTL with virosomes or cell-associated antigen. Importantly, serum antibody levels were not altered after macrophage depletion, regardless of the delivery vehicle used, suggesting that in the absence of macrophages, other APC may phagocytose the exogenous antigens for major histocompatibility complex (MHC) class II processing and presentation. These results suggest that soluble exogenous antigens delivered in different carrier systems may be processed differently by different APC in vivo for MHC class I- or class II-restricted presentation.     

Differential regulation of innate and adaptive immune responses in viral encephalitis

Viral encephalitis is a global health concern. The ability of a virus to modulate the immune response can have a pivotal effect on the course of disease and the fate of the infected host. In this study, we sought to understand the immunological basis for the fatal encephalitis following infection with the murine coronavirus, mouse hepatitis virus (MHV)-JHM, in contrast with the more attenuated MHV-A59. Distinct glial cell cytokine and chemokine response patterns were observed within 3 days after infection, became progressively more polarized during the course of infection and with the infiltration of leukocytes. In the brain, MHV-JHM infection induced strong accumulation of IFNβ mRNA relative to IFNγ mRNA. This trend was reversed in MHV-A59 infection and was accompanied by increased CD8 T cell infiltration into brain compared to MHV-JHM infection. Increased apoptosis appeared to contribute to the diminished presence of CD8 T cells in MHV-JHM-infected brain with the consequence of a lower potential for IFNγ production and antiviral activity. MHV-JHM infection also induced sustained mRNA accumulation of the innate immune response products interleukin (IL)-6 and IL-1. Furthermore, high levels of macrophage-inflammatory protein (MIP)-1α, MIP-1β, and MIP-2 mRNA were observed at the onset of MHV-JHM infection and correlated with a marked elevation in the number of macrophages in the brain on day 7 compared to MHV-A59 infection. These observations indicate that differences in the severity of viral encephalitis may reflect the differential ability of viruses to stimulate innate immune responses within the CNS and subsequently the character of infiltrating leukocyte populations.     

Mechanism of recovery from acute virus infection. VIII. Treatment of lymphocytic choriomeningitis virus-infected mice with anti-interferon-gamma monoclonal antibody blocks generation of virus-specific cytotoxic T lymphocytes and virus elimination

In acutely infected mice the lymphocytic choriomeningitis (LCM) virus multiplies to high titers in essentially all tissues. Around day 6, virus clearance sets in, which has previously been shown to be mediated by CD8+ cytotoxic T lymphocytes (CTL), probably by releasing (or inducing other cells to release) anti-viral cytokines. To ascertain whether interferon-gamma plays a role, infected mice were injected once i.v. with monoclonal antibody known to neutralize this lymphokine, and the effect this had on both termination of the infection and development of LCM virus-specific CTL was determined. Administration 1 day after infection blocked virus elimination from spleen and liver and decreased the generation of CTL; also, limiting dilution analysis revealed absence of activation of CTL precursors. In contrast, when the antibody was given 3 days after or 1 day before the virus, neither clearance nor generation of CTL was measurably affected. Furthermore, the antiviral effect of immune spleen cells after their transfer into infected recipients was not altered by treatment of the latter with monoclonal antibody. We conclude that in the generation of LCM virus-specific CTL an early event is dependent on constitutively produced interferon-gamma; when its activity is blocked, CTL do not mature, resulting in the mouse's inability to terminate the infection.     

T-Cell Effector Function and Unresponsiveness in the Murine Lymphocytic Choriomeningitis Virus Infection

When the virus dose is increased from 10(2) (low dose) to 10(4) LD50 (high dose) a fatal lymphocytic choriomeningitis virus (LCMV) infection is changed into a subclinical one, and a selective virus-specific delayed-type hypersensitivity (DTH) unresponsiveness is induced, while the cytotoxic T-cell response remains essentially unchanged. When low-dose spleen effectors were transferred intravenously into intracerebrally infected high-dose mice, fatal LCM disease occurred, which means that infected central nervous system target structures in these animals are sensitive to virus-specific T cells. When low-dose cells were transferred to intravenously infected high-dose mice, these animals regained their TD function (the effect of T cells mediating DTH). Since this indicates that the survival of intracerebrally infected high-dose mice is intimately linked with the absence of virus-specific DTH reactivity, a search for T suppressor (TS) activity in these animals was performed by transferring high-dose spleen cells to lethally (intracerebrally) infected low-dose recipients. In this way we obtained an afferent suppression, which was not H-2 restricted, but was abrogated when the spleen cells were pretreated with neutralizing anti-LCMV serum, indicating a suppressive effect of virus transferred with the infected cells. When tolerance induction was attempted with virus alone, a potentially fatal immune reaction could be altered to unresponsiveness (i.e. survival) as late as 4 days after an otherwise lethal infection with LCMV. The results indicate that the maturation of the virus-specific TD response is sensitive to large amounts of virus antigen. We conclude that this impairment and the resulting DTH unresponsiveness is due to a clonal deletion or anergy rather than to the effect of TS cells, and that the TD effector function is critical to the development of fatal LCM disease.     

Myeloid marker expression on antiviral CD8+ T cells following an acute virus infection

CD11b, CD11c, and F4/80 are normally used to define dendritic cell and/or macrophage populations. In this study, the expression of all three markers was observed on CD8(+) T cells following infection of mice with several distinct viruses. Using lymphocytic choriomeningitis virus as a model virus, it was found that relatively more CD11b(+)CD8(+) and CD11c(+)CD8(+) T cells were present in the periphery than in primary lymphoid organs; in contrast, the F4/80(+)CD8(+) T cell population was more prevalent in the spleen. All three myeloid markers were detected on virus-specific CTL. The expression of CD11b and CD11c on CD8(+) T cells correlated with their level of CTL activity, whereas the F4/80(+)CD8(+) T cell population increased after the peak of the CTL response but did not have higher CTL activity. These data suggest that there is a differential induction of CD11b, CD11c, and F4/80 on virus-specific CD8(+) T cells following an acute virus infection.