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Some viruses are prone to developing persistent infections despite the presence of virus-specific immune responses1. Identified mechanisms of persistence include mutational escape from T-cell responses, resistance to interferons, expression of cytokine decoy receptors, inhibition of the cellular antigen-presentation machinery, glycan shielding of surface glycoproteins and integration into the host's genome2,3,4,5. Virus sanctuaries—persistence of virus in extralymphatic tissues—not only complicate virus elimination, they also enable reactivation during immune suppression (for example, after organ transplantation)6. Virus persistence in certain tissues is partly restricted by the expression of specific receptors on tissue target cells; however, classical lymphotropic and/or hepatotropic viruses tend to persist in extralymphatic organs such as the kidney, brain, lungs, testes and salivary glands7,8,9,10,11,12. Persistence in these organs cannot always be explained by selective receptor expression; it also cannot be due simply to continuous virus spillover from the blood, as peripheral virus isolates differ phylogenetically from blood virus isolates and extralymphatic virus has been detected in individuals without viremia13.

Virus persistence and distribution are also shaped by innate resistance mechanisms14,15 and drug therapy16. T helper cells are known to support CD8+ T-cell responses that destroy cells infected with persisting viruses such as HIV, hepatitis C virus (HCV), cytomegalovirus (CMV) and LCMV17,18,19. However, the outcome of chronic HIV, HCV or CMV infections cannot always be predicted from T-cell responses20,21,22. Paradoxically, potent immune activation is a risk factor for end-stage disease in HIV23 and simian immunodeficiency (SIV) infections24 and has been associated with disease severity in cases of human influenza virus and severe acute respiratory syndrome (SARS)-coronavirus infection25,26. Experimental immunization with T helper epitopes has even been found to worsen the outcome of SIV infection in rhesus macaques27. We and others have recently described T helper cell–driven suppression of neutralizing antibody formation after LCMV infection28,29. These findings together indicate that potent immune activation, which is usually beneficial, can sometimes be disadvantageous. To help delineate the mechanisms that influence this equilibrium, we have investigated the roles of specific T cells and protective antibodies in enhancing or preventing the formation of extralymphatic persisting virus sanctuaries.

Results

Induction and function of CD8+ T cells depends on T helper cells

C57BL/6 mice infected with low-dose (200 plaque-forming units (PFU)) LCMV (WE strain), rapidly cleared the virus from all organs tested within 10 d (Fig. 1a). Infection of extralymphatic organs was absent or low, even at the peak of virus replication. To allow the virus to spread widely in the mouse before the onset of the CD8+ T cell–derived immune response, we transiently depleted CD8+ T cells by administering monoclonal antibodies 1 or 2 d before infection (that is, on day −2 or day −1) with LCMV-WE (standard protocol, used throughout this manuscript). Ten days after infection, mice that had been depleted of CD8+ T cells showed virus replication in all organs tested (Fig. 1a). After their initial depletion, CD8+ T cells reemerged in the blood around day 10 after infection and then expanded, peaking at day 20 after infection as assessed by fluorescence-activated cell sorting (FACS) analysis of peripheral blood (Fig. 1b). This expansion of CD8+ T cells was almost completely virus specific, as up to 80% of these CD8+ T cells were tetramer-specific for known immunodominant virus epitopes (GP33-41, GP276-284 and NP396-404) (Fig. 1c; for representative FACS plot, see Supplementary Fig. 1a online). The CD8+ T cells were mostly of a CD62Llo phenotype, indicating activation (Fig. 1d). Most CD8+ T cells expressed granzyme B, and a small fraction produced interferon-γ (IFN-γ) directly ex vivo without further restimulation (Fig. 1e; for representative FACS plots see Supplementary Fig. 1b). To determine the importance of T helper cells in CD8+ T-cell priming and proliferation in our model, we infected Cd4−/− mice with 200 PFU LCMV-WE using the standard protocol described above. Expansion of CD8+ T cells in peripheral blood, as detected by FACS, was suppressed in Cd4−/− mice (Fig. 1b). CD8+ T cells were less activated, as downregulation of the selectin CD62L was impaired (Fig. 1d). Granzyme B–expressing CD8+ T cells were also relatively reduced in the absence of T helper cells (Fig. 1e and Supplementary Fig. 1b). By contrast, adoptive transfer of naive, virus-specific T-cell receptor transgenic CD4+ T helper cells (Smarta cells30) before LCMV infection of C57BL/6 mice (C57BL/6+Smarta) enhanced CD8+ T-cell activation. CD62L downregulation and direct ex vivo granzyme B expression were both greater than in control C57BL/6 mice (Fig. 1d,e). Transfer of Smarta T helper cells augmented formation of IFN-γ by T helper cells (Supplementary Fig. 1c). At the same time that CD8+ T cells peaked in mouse blood samples, the mice lost weight (Fig. 1f) and developed hepatitis, as indicated by elevated serum bilirubin concentrations and augmented liver transaminase activity in serum (Fig. 1g,h). Both weight loss and hepatitis correlated markedly with the number of available T helper cells (Fig. 1f–h). Thus, CD8+ T-cell expansion and expression of effector functions (granzyme B and IFNγ) correlated with available T-cell help.

Figure 1: T helper cell–dependent CD8+ T-cell response against distributed virus.
figure 1

(a) C57BL/6 mice were depleted of CD8+ T cells at days −2 and −1 (▪) or left untreated (□) before infection with 200 PFU LCMV-WE. Organ viral titers were measured 10 d later (n = 3). (b) C57BL/6 mice (▪), C57BL/6 mice supplemented with 107 Smarta splenocytes on day −1 before infection (C57BL/6+Smarta, □) or Cd4−/− mice (•) were all transiently CD8+ T-cell depleted with monoclonal antibodies administered on days −2 and −1 before infection, then infected with 200 PFU LCMV-WE on day 0 or left uninfected (♦). CD8+ T cells in peripheral blood were monitored at the indicated time points by FACS analysis (n = 5–10). (c) Twenty days after infection of C57BL/6 mice as described above, reemerging CD8+ T cells were tested for LCMV specificity using tetramer staining for three immunodominant epitopes (GP33-41, GP276-284 and NP396-404) and FACS analysis (n = 4–9). (d,e) CD62L expression (d) or direct ex vivo granzyme B (black) and IFN-γ (gray) expression (e) of CD8+ T cells were measured by FACS 15 d (d) or 20 d (e) after infection (n = 5). (f–h) C57BL/6 mice (▪), C57BL/6+Smarta mice (□) or Cd4−/− mice (•) were infected with LCMV according to the standard protocol (n = 4–5). Mouse body weight was measured at the indicated time points (f). (g,h) 20 d after LCMV infection, serum bilirubin concentrations and serum amino liver transaminase (ALT) activity were measured (n = 5).

Delayed virus clearance in mice with potent T-cell responses

As expected, Cd4−/− mice infected with LCMV showed high viral titers in blood at all time points measured (Fig. 2a). However, virus elimination from the blood was, paradoxically, delayed in mice with high T–helper cell responses (C57BL/6+Smarta) compared with control C57BL/6 mice (Fig. 2a). The impaired virus clearance in mice with potent T-cell responses was mostly due to a failure to clear the virus from the kidneys and lungs (Fig. 2b–f). Compared to Rag1−/− mice, which are deficient in T cells and B cells, virus clearance was 1,000–10,000 times greater in the spleen and liver of C57BL/6+Smarta mice, although no significant difference was measured in the kidneys and lungs (Fig. 2b–f). The difficulty in eliminating the virus from the kidneys was still observed 50 d after infection of C57BL/6+Smarta mice, whereas virus control in the lungs and brain was comparable to that of control C57BL/6 mice at this time point (Supplementary Fig. 2a,b online). Notably, no virus could be detected in the blood at this time point (Fig. 2a). The observed site-specific virus elimination in C57BL/6+Smarta mice was not due to site-specific T helper cell responses, as T helper cell activation and function were comparable in the liver, kidneys and lungs (Supplementary Fig. 2c).

Figure 2: Organ-specific viral persistence enhanced by potent cellular immune responses.
figure 2

(a) Viral blood titers of C57BL/6 mice (▪), C57BL/6 mice supplemented with Smarta T helper cells (C57BL/6+Smarta, □) or Cd4−/− mice infected with LCMV according to the standard protocol (•) were analyzed at the indicated time points (n = 3–5). (b–f) Twenty days after LCMV infection using the standard protocol, viral titers in the spleen (b), liver (c), brain (d), kidneys (e) and lungs (f) were measured in individual Rag1−/− mice, C57BL/6 mice and C57BL/6+Smarta mice as indicated (individual values are shown).

In summary, potent T-cell responses were apparently effective in lowering viral burden in some organs but did not clear virus from other tissues.

Virus persistence correlates with delayed antibody formation

LCMV-infected C57BL/6 mice developed measurable neutralizing antibodies by 30 d after infection (Fig. 3a). In keeping with our earlier results28, the formation of neutralizing antibodies was, paradoxically, delayed and reduced in mice supplemented with Smarta T helper cells, to a similar extent as in mice lacking CD4+ T cells (Fig. 3a). To test whether the delayed antibody formation was responsible for the observed site-specific virus persistence, we analyzed virus elimination in mice deficient in antibody formation. Aicda−/− mice lack activation-induced cytidine deaminase (AID) and therefore do not undergo immunoglobulin class switch recombination and affinity maturation, whereas other B-cell functions, including IgM responses, remain effective31. LCMV-infected Aicda−/− mice did not produce neutralizing antibodies, as shown by a neutralization assay (Fig. 3a), and also did not produce LCMV glycoprotein–specific IgG responses, as tested by ELISAs (Supplementary Fig. 4b,c online). Notably, there were only slight differences in numbers of virus-specific CD8+ T cells, distribution of epitopes, production of IFN-γ, and CD8+ T-cell cytotoxicity between Aicda−/− mice and C57BL/6 mice (Supplementary Fig. 3a–e online). Like C57Bl/6 mice supplemented with Smarta cells, the LCMV-infected Aicda−/− mice showed site-specific virus persistence, as indicated by significantly lower viral titers in the spleen and liver 30 d after infection when compared to the kidneys, lungs and brain (Fig. 3b). In contrast, RAG-deficient mice had evenly distributed high viral titers in all organs tested (Fig. 3c). Site-specific persistence was also found in Aicda−/− mice that were infected with another LCMV strain, LCMV-Armstrong (Fig. 3d), and in Aicda−/− mice infected with high doses of LCMV-WE without initial transient CD8+ T-cell depletion (Fig. 3e).

Figure 3: Site-specific viral persistence as a consequence of delayed antibody responses.
figure 3

(a) C57BL/6 mice (▪), C57BL/6 mice supplemented with transgenic virus–specific CD4+ T cells (C57BL/6+Smarta, □), Cd4−/− mice (•), Aicda−/− mice (♦) and VI10Yen mice () were depleted of CD8+ T cells on days −2 and −1, then infected with 200 PFU LCMV-WE on day 0. (a) At the indicated time points, neutralizing antibody formation was assessed by neutralization assay (n = 4–9). (b–e) Aicda−/− mice were transiently depleted of CD8+ T cells on days −2 and −1, then infected with 200 PFU LCMV-WE (b) or LCMV-Armstrong (LCMV-Arm) (d) on day 0. LCMV-WE–infected Rag1−/− mice were analyzed as a control (c). Alternatively, Aicda−/− mice that had not been transiently depleted of CD8+ T-cells were infected with 2 × 106 PFU LCMV-WE (e). Viral organ titers were measured by plaque assay 30 d (b) or 50 d (c,d,e) after infection (individual values are shown).

Reduction of virus sanctuaries by virus-specific B cells

To analyze whether supplemented B cells were more effective than T cells at reducing viral titers, we adoptively transferred either LCMV-specific CD8+ T cells or neutralizing LCMV-specific B cells (see Methods) 30 d after LCMV infection of Aicda−/− mice (for blood virus kinetics, see Supplementary Fig. 4a). Viral organ titers were measured 20 d later (see experimental schedule, Fig. 4a). Fifty days after LCMV infection, Aicda−/− mice without cell transfer showed the lowest viral titers in the liver and brain but had high titers in the spleen, lungs and kidneys (Fig. 4b–f). The increase in spleen viral titers at day 50 compared to day 30 is probably due to CD8+ T-cell exhaustion, which has been described to occur more rapidly in lymphoid tissue than in other organs32. Control C57BL/6 mice had almost completely cleared virus from all organs at this time point (Fig. 4b–f). LCMV-specific adoptive B-cell transfer into Aicda−/− mice was successful, as indicated by the rapid formation of LCMV glycoprotein–specific IgG (Supplementary Fig. 4b), and was associated with significantly reduced viral titers in the kidneys and a trend toward lower titers in the lungs (Fig. 4e,f). By contrast, T-cell transfer did not significantly reduce viral titers in the kidneys or lungs (Fig. 4e,f). Transfer of LCMV glycoprotein–specific neutralizing antibodies into Aicda−/− mice did not lower viral titers in the kidneys or lungs and did not induce measurable glycoprotein-specific IgG responses, implying that the antibodies were rapidly consumed by circulating virus particles (data not shown). We also analyzed LCMV-infected VI10Yen mice. In these mice, most naive B cells are specific for vesicular stomatitis virus (VSV)33. These mice did not produce LCMV-neutralizing antibodies for up to 50 d after infection (Fig. 3a); however, in contrast to AID-deficient mice, they eventually formed LCMV glycoprotein–specific IgG antibodies (Supplementary Fig. 4c). CD8+ T-cell function in infected VI10Yen mice was comparable to that in C57BL/6 mice (data not shown). Compared to those in AID-deficient mice, viral titers in the kidneys were significantly lower in VI10Yen mice, mimicking the result of virus-specific B-cell transfer (Fig. 4b–f).

Figure 4: Reduction of extralymphatic virus sanctuaries associated with LCMV glycoprotein-specific B-cell responses.
figure 4

Aicda−/− mice were transiently depleted of CD8+ T cells on days −2 and −1, then infected with 200 PFU LCMV-WE on day 0. Thirty days after infection, 1 × 107 LCMV-specific neutralizing B cells (+B cells) or LCMV-specific CD8+ T cells (+T cells) were adoptively transferred as described in the Methods. As controls, Aicda−/− mice (without), VI10Yen mice (VI10Yen) or C57BL/6 mice (C57BL/6) were infected with LCMV according to the standard protocol but did not receive further adoptive cell transfer 30 d after infection. Viral organ titers were measured 50 d after LCMV infection. (a) Experimental setup. (b–f) Viral organ titers measured 50 d after LCMV infection in spleen (b), liver (c), brain (d), kidney (e) and lung (f). Individual values are shown.

Together, these results show that the reduction of virus replication in some organs, such as the kidneys and lungs, correlates with the amount of LCMV glycoprotein–specific IgG antibodies but not with T-cell responses. Notably, B-cell transfer into Aicda−/− mice did not augment CD8+ T-cell activation and function in extralymphatic organs (Supplementary Fig. 4d–f).

Activated but exhausted CD8+ T cells in viral sanctuaries

We next investigated the mechanisms that are involved in the formation of site-specific viral sanctuaries. First, we analyzed whether the persisting extralymphatic virus population consisted of CD8+ T-cell escape variants and thus resisted T-cell attack. Fifty days after infection using the standard protocol, we isolated the virus from the kidneys of two Aicda−/− mice. We then injected 200 PFU of each kidney isolate or 200 PFU of wild-type LCMV-WE separately into naive C57BL/6 mice. Ten days later, we measured the expansion of LCMV GP33-41–specific, GP276-284–specific and NP396-404–specific CD8+ T cells by tetramer staining, finding only minimal differences (Fig. 5a). Lack of mutation was further confirmed by sequencing of one representative kidney isolate, which revealed LCMV-WE wild-type codon usage within and near the immunodominant GP276-284 epitope (data not shown).

Figure 5: T cells at sanctuary sites are activated but lack direct cytotoxicity.
figure 5

(a) Fifty days after infection using the standard protocol, virus was isolated from Aicda−/− mouse kidneys. We then injected 200 PFU of each of two isolates (□,•) from two mice into separate naive C57BL/6 mice. As a control, we used 200 PFU of wild-type LCMV-WE (▪). Ten days later, GP33-41, GP276-284 and NP396-404 tetramer-positive CD8+ T cells were measured by FACS analysis (n = 5). (b,c) Aicda−/− mice were infected with LCMV according to the standard protocol. Thirty days after infection, CD8+ T cells isolated from the liver (black), kidneys (dark gray) or lungs (light gray) were assessed for expression of the indicated activation markers (b) and for granzyme B expression (c) by FACS analysis (n = 3–4). (d) Aicda−/− mice were infected with LCMV according to the standard protocol. Thirty days after infection, CD8+ T cells isolated from the indicated organs were analyzed for cytotoxicity in a chromium-release assay. Target cells were labeled with GP33-41 peptide (▪) or unlabeled (□). Each line represents the mean and s.e.m. for one animal (chromium release measured in duplicates; n = 5–7 experiments).

Next, we compared the livers, kidneys and lungs of AID-deficient mice and found that CD8+ T-cell activation and granzyme B expression were similar in these organs (Fig. 5b,c). Numbers of virus-specific CD8+ T cells and levels of IFN-γ were also similar in the kidneys, lungs and liver (Supplementary Fig. 3b,d), suggesting that differences in CD8+ T-cell activation and function could not explain the site-specific virus persistence observed in Aicda−/− mice.

In contrast, CD8+ T-cell cytotoxicity was lower in the kidneys than in the liver and spleen (Fig. 5d). Direct cytotoxicity correlated well with the measured viral titers in kidney versus liver and spleen at the same time point (Fig. 3). Thus, although we could not demonstrate differences in the intrinsic activation and function of CD8+ T cells, the kidney CD8+ T-cell population as a whole showed low cytotoxicity, which is indicative of exhaustion and associated with high viral kidney titers.

Virus persistence at epithelial sites

We performed immunohistological analysis of kidneys 50 d after infection of mice. In Rag1−/− mice, which lack B and T cells, the virus was mainly located in the kidney tubule epithelium (Fig. 6a, i). Similar patterns of staining around the kidney tubules were observed in AID-deficient mice, either with or without transient CD8+ T-cell depletion, and in mice transfused with Smarta T cells (Fig. 6a, ii,iii). Hence, despite a T-cell response, viral distribution in the kidneys remained the same as in Rag1−/− mice. By contrast, C57BL/6 mice had already efficiently eliminated the virus from their kidneys 50 d after infection (Fig. 6a, v). Extensive infiltrations of CD8+ T cells (Fig. 6a, xiii–xviii) and CD4+ T cells (Fig. 6a, xix–xxiv) were observed in the kidneys of all mice tested (except T cell–deficient Rag1−/− mice) independently of virus distribution, confirming that insufficient T-cell recruitment was not the reason for the epithelial persistence of virus antigen in Aicda−/− mice and mice supplemented with Smarta T helper cells.

Figure 6: Viral persistence at epithelial sites.
figure 6

(a) Fifty days after LCMV infection, Rag1−/− mice, Aicda−/− mice with or without transient CD8+ T-cell depletion, C57BL/6 mice, Smarta-supplemented C57BL/6 mice (C57BL/6+Smarta) or VI10Yen mice were infected with LCMV using the standard protocol, immunohistology was used to detect LCMV nucleoprotein (VL4, i–vi), IgG (vii–xii) CD8 (xiii–xviii) and CD4 (xix–xxiv) in kidney sections (n = 2–5). (b) Aicda−/− mice were LCMV infected with LCMV according to the standard protocol. After 30 d, neutralizing antibodies (monoclonal KL25 antibodies or polyclonal neutralizing serum) or LCMV-specific B cells were adoptively transferred. Twenty days later, expression of IgG, LCMV antigen (VL4) and plasma cells (CD138) was analyzed by immunohistology as indicated. (c, i) C57BL/6+Smarta mice were infected with LCMV according to the standard protocol. Fifty days later, immunohistological staining of LCMV-nucleoprotein (VL4 antibody) was performed on sections of the distal urinary tract (one representative section is shown). (c, ii,iii) Aicda−/− mice were transiently depleted of CD8+ T cells on days −2 and −1, then infected with 200 PFU LCMV-WE on day 0. As a control, Rag1−/− mice were infected with LCMV on day 0. Fifty days after infection, immunohistological staining of LCMV-nucleoprotein (VL4 antibody) was performed on liver sections (ii) or lung sections (iii). Scale bars, 200 μm.

To further analyze virus elimination, we carried out immunohistological analysis of kidneys from VI10Yen mice, which had low but still detectable viral titers 50 d after infection (Fig. 4). In these mice, the virus was found mainly in the kidney interstitial space, rather than in epithelial cells. (Fig. 6a, vi). IgG staining in these mice localized to the same interstitial sites, supporting the idea that virus-antibody immune complexes form there (Fig. 6a, xii). Interstitial IgG deposition was also found in C57BL/6 mice, implying that interstitial IgG deposition remained after virus elimination (Fig. 6a, xi). As expected, IgG staining was not detectable in infected Rag1−/− mice and Aicda−/− mice (Fig. 6a, vii–ix). When LCMV-neutralizing IgG was injected into infected Aicda−/− mice IgG deposits were found mostly in kidney glomeruli, but usually not in the interstitial space surrounding the LCMV-infected epithelia (Fig. 6b), and LCMV kidney titers remained unchanged (data not shown). Thus, virus elimination from kidneys correlated with the formation of interstitial IgG deposits, presumably produced by kidney-infiltrating B cells. Plasma cells could easily be found within kidneys in immunohistological analyses (Fig. 6b). Kidney plasma cells were also observed in Aicda−/− mice and C57BL/6 mice, whereas IgG deposition between kidney tubules was absent in Aicda−/− mice (Fig. 6b).

Virus was also detected in the lower urinary tract, where the epithelium is built of multiple cell layers. There, the virus was detected mainly in the upper cell layer (Fig. 6c), consistent with virus propagation in the urinary tract tubular system. Histological analysis of lung sections revealed similar virus sanctuaries in the bronchiolar epithelium in Rag1−/− mice and Aicda−/− mice, indicating that lung epithelia might show resistance to T-cell attack similar to that seen in kidney epithelia (Fig. 6c). By contrast, in Aicda−/− mice, which had low liver viral titers, the virus was found mainly in the Kupffer cell compartment of the liver, whereas virus was detected in liver hepatocytes in Rag1−/− mice (Fig. 3b and Fig. 6c).

Discussion

Our experimental data mimic the paradoxical clinical finding that potent immune activation is sometimes a risk factor for viral persistence and severe disease. CD8+ T cells, supported by helper T cells, efficiently cleared the virus from some organs but not other organs. Virus was particularly persistent in the kidneys and lungs, but more efficiently cleared from the liver and spleen. We speculate that site-specific viral persistence develops as a consequence of overactivated and exhausted T-cell responses combined with slow induction of virus-specific neutralizing antibodies. Such a combination is typical for several chronic human virus infections34. B cell–deficient mice with primed T cells specific for γ-herpesvirus do not eliminate the virus from the lungs, but do eliminate it from all other organs, upon reinfection35. In addition, X-linked lymphoproliferative disease is similarly characterized by an overreactive cellular immune response combined with slow induction and low levels of virus-specific antibodies; this combination might lead to fatal outcomes of Epstein-Barr virus (EBV) infection in humans and of LCMV infection in mice36. In our model of infection by LCMV, the CD8+ T-cell response against distributed viral antigen was strengthened by the help of CD4+ T cells, as shown previously18. Similar findings exist for SIV and other persisting viruses17,19.

We found that the presence of virus-specific IgG responses was associated with virus clearance and with changes in virus distribution from epithelial cells to the interstitial space. Other models of persistent virus infection have similarly proposed that B-cell responses are associated with virus elimination37,38. Histological analysis showed that T cells efficiently infiltrated virus-infected epithelia, in a pattern reminiscent of 'autoreactivity' (for example, interstitial nephritis, bronchiolitis or Sjögren-like disease, which might convert into overt autoimmune disease). Although we did not detect CTL-escape variants at extralymphatic sites up to 50 d after infection, the observed colocalization of CD8+ T cells with the virus might eventually create sites conducive to the formation of CTL-escape mutants40. Lymphomas associated with chronic viral infection, which often arise in extralymphatic tissues, could be a consequence of ongoing extralymphatic immune responses. Together, our findings might explain why chronic virus infections, lymphomas and autoimmunity have been described as forming a triple association40.

In conclusion, the successful and complete elimination of a distributed persistence-prone viral infection requires efficient interplay between cellular and neutralizing humoral responses. Whereas T-cell responses can effectively clear the virus from both lymphatic and more 'solid' extralymphatic organs such as the liver, IgG responses are especially needed in organs with tubular epithelial microanatomy, such as the kidneys and lungs. The relative contributions of these two adaptive arms of the immune system also regulate immunopathological disease mediated by chronic inflammation. Thus, boosting of T-cell responses alone might not reduce virus persistence41 and might eventually induce immunopathology or autoimmunity36. Our results indicate that virus replication, tropism and sanctuary formation depend on the specific virus and on organ anatomy and physiology, but also on the induction, kinetics and efficacy of different adaptive immune effector mechanisms.

Methods

Mice.

All mice were bred and maintained under specific pathogen–free conditions, and experiments were performed in accordance with institutional and Swiss national guidelines. Animal care protocols were approved by the animal experiment committe of Zürich, Switzerland.

Cd4−/−, VI10Yen–B-cell transgenic, TgH(KL25)–B-cell transgenic, 318–T-cell transgenic, Smarta1–T-cell transgenic, Rag1−/− and Aicda−/− mice all have a C57BL/6 genetic background. All mice were purchased from the Institute for Labortierkunde, Faculty of Veterinary Medicine, University Zürich-Irchel.

Virus.

LCMV strains WE and Armstrong (Arm) were originally gifts (see Acknowledgments) and were propagated on L929 or BHK21 cells. Mice were infected with 2 × 102 or 2 × 106 PFU of LCMV injected intravenously as indicated.

Detection of viral and neutralizing antibody titers.

LCMV viral titers were detected by a plaque-forming assay on MC57 fibroblasts as described42. Detection of neutralizing activity against LCMV in mouse sera has also been described42. Briefly, neutralizing activity against LCMV-WE was measured in a plaque-reduction assay. The neutralizing titer was defined as the log2 dilution that caused a half-maximal reduction in plaques, with the reduction being measured in comparison to the number of plaques formed by similar amounts of the virus incubated with control sera from uninfected mice or medium alone. A titer of <1 indicates no detectable neutralization at an initial serum predilution of 1:10.

In vivo depletion of CD8+ T cells.

Cell depletions were performed using rat monoclonal antibodies specific for CD8 (YTS 169.4) as described28. The hybridomas were initially obtained from H. Waldmann. We injected 200 μl of purified CD8+ T cell–depleting antibodies intraperitoneally on days −2 and −1 before LCMV infection. The efficiency of depletion was always confirmed by FACS analysis of peripheral blood cells using fluorescein isothiocyanate (FITC)-, phycoerythrin (PE)-, or allophycocyanin (APC)-labeled CD8-specific antibodies (Pharmingen).

Markers of liver injury.

We measured serum activity of alanine aminotransferase (ALT) as a marker of hepatocellular injury and total serum bilirubin concentrations using the serum multiple analyser (Ektachem DTSCII, Johnson and Johnson) or the Roche Modular Analytics Analyser with pyridoxal phosphate (Roche).

Adoptive cell transfer.

Aicda−/− mice were transiently depleted of CD8+ T cells and infected with LCMV by the standard protocol, as described in Results. After 30 d, either 1 × 107 MACS-sorted naive CD8+ T cells from LCMV-specific T-cell receptor–transgenic mice (318 mice) or in vivo CD8+ T cell–depleted naive TgHKL25 splenocytes (from LCMV-specific B cell–knock-in mice33) were adoptively transferred. Immunohistology and measurement of organ viral titers and CD8+ T-cell function were performed 20 d later.

LCMV-neutralizing monoclonal antibodies (KL25, 1.5 mg) or polyclonal LCMV-neutralizing hyperimmune serum (200 μl) were transfused intravenously as a control 30 d after LCMV infection of Aicda−/− mice.

LCMV-glycoprotein GP1-specific IgG measurements.

The detection of LCMV-glycoprotein GP-1–specific IgG by ELISA has been described28.

Fluorescence-activated cell sorting analysis of T-cell activation.

Single-cell suspensions of the different organs were prepared. Cells were then incubated with fluorescent antibodies specific for PD-1 (PE-labeled, eBioscience), CD69 and CD62L (FITC-labeled, both BD Pharmingen), counterstained with fluorescent CD8-specific antibodies (APC-labeled, BD Pharmingen) and analyzed using a FACSCalibur system (BD Pharmingen). For CD4+ T-cell activation, antibodies to CD69, CD62L and CXCR3 (BD Pharmingen) were used.

For intracellular cytokine staining and T-cell restimulation, splenocytes were incubated for 5 h with or without LCMV peptide (1 μM) or PMA (50 ng ml−1) and ionomycin (500 ng ml−1) for 6 h in RPMI medium supplemented with 10% FBS, β-mercaptoethanol and 5 μg ml−1 brefeldin A (Sigma-Aldrich). The cells were then harvested, washed once in PBS with 4% FBS and 12.5 mM EDTA, and stained with PE- or APC-conjugated CD8-specific antibodies or PE-labeled antibodies specific for CD4 (BD Pharmingen). After washing, cells were fixed with 4% paraformaldehyde in PBS for 10 min, then permeabilized using PBS with 4% FBS, 12.5 mM EDTA and 0.1% saponin (Sigma-Aldrich). For intracellular cytokine staining, cells were incubated with PE-conjugated granzyme B–specific antibody (Caltag) or APC-labeled IFN-γ–specific antibody (BD Pharmingen) for 30 min at 4 °C. After washing twice with permeabilization buffer, we resuspended the cells in PBS with 4% FBS and 12.5 mM EDTA and analyzed them using a FACSCalibur system (BD Pharmingen).

In vivo cytotoxicity.

In vivo cytotoxicity was assayed using C57BL/6 splenocytes incubated for 1 h with or without LCMV-derived MHC class I GP276-284 peptide and labeled for 10 min with 5 μg ml−1 carboxyfluorescein diacetate succinimidylester from Molecular Probes (CFSEhigh, peptide-labeled splenocytes) or 0.5 μg ml−1 CFSE (CFSElow, unlabeled splenocytes). We injected 107 cells of each fraction intravenously into AID-deficient or control C57BL/6 mice 50 d after LCMV infection using the standard protocol described in Results. The number of CFSE-positive cells remaining in blood 12 h later was determined by FACS analysis. Specific cytotoxicity was calculated from the cell counts of LCMV-infected (memory) and noninfected (naive) mice under each treatment, as 1 – (CFSEhighmemory/CFSElowmemory)/(CFSEhighnaive/CFSElownaive), and expressed as a percentage.

51Cr-release cytotoxicity assay.

We performed 51Cr release assays as described43. Single-cell preparations of organs were prepared and lymphocytes separated by gradient centrifugation (Lympholyte, Cedarlane). Threefold dilutions of effector cells with a starting effector/target ratio of 100:1 were analyzed.

Immunohistology.

Histological analysis was performed on snap-frozen tissue sections stained with rat monoclonal antibodies against LCMV-nucleoprotein (VL4), CD8 (53-6.7), IgG (mixture of rat anti-mouse IgG1, IgG2a/b and IgG3) or CD138. Monoclonal antibodies were detected with goat anti-rat (Caltag) and alkaline phosphatase-labeled donkey anti-goat (Jackson ImmunoResearch) secondary antibodies, which we visualized by using naphthol 6-bromo-2-hydroxy-3-naphtholic acid 2-methoxy anilide (AS-BI) phosphate and new fuchsin as a substrate. The enzyme reaction yielded a red reaction product. Kidney sections were stained in some experiments with goat anti-rat secondary antibody (Caltag), followed by donkey anti-goat labeled with horseradish peroxidase. Incubation with 3-amino-9-ethylcarbazole (AEC) in the presence of H2O2 yielded a brown reaction product. Sections were counterstained with hemalum.

Statistical analysis.

Data are presented as mean ± s.e.m. or as single values (median value visualized as a horizontal line). Values in treatment groups were analyzed for significant differences using a one-way analysis of variance followed by a Tukey least-significant difference test. For statistical analysis, organ viral titers below detection limits were set to 101.5 PFU.

Note: Supplementary information is available on the Nature Medicine website.