Selective Expansion of Cross-Reactive Cd8+ Memory T Cells by Viral Variants

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© The Rockefeller University Press, 0022-1007/1999/11/1319/ $5.00
The Journal of Experimental Medicine, Volume 190, Number 9, November 1, 1999 1319-1328

Original Article

Selective Expansion of Cross-Reactive Cd8⁺ Memory T Cells by Viral Variants

John B.A.G. Haanen^a, Monika C. Wolkers^a, Ada M. Kruisbeek^a, and Ton N.M. Schumacher^a

^a Department of Immunology, The Netherlands Cancer Institute, Amsterdam 1066 CX, The Netherlands
The Netherlands Cancer Institute, Plesmanlaan 121, Amsterdam 1066 CX, The Netherlands.31-20-512-205731-20-512-2072

tschum{at}nki.nl

Abstract

Top
Abstract
Materials and Methods
Results
Discussion
References

The role of memory T cells during the immune response againstrandom antigenic variants has not been resolved. Here, we showby simultaneous staining with two tetrameric major histocompatibilitycomplex (MHC)–peptide molecules, that the polyclonal CD8⁺T cell response against a series of natural variants of theinfluenza A nucleoprotein epitope is completely dominated byinfrequent cross-reactive T cells that expand from an originalmemory population. Based on both biochemical and functionalcriteria, these cross-reactive cytotoxic T cells productivelyrecognize both the parental and the mutant epitope in vitroand in vivo. These results provide direct evidence that therepertoire of antigen-specific T cells used during an infectioncritically depends on prior antigen encounters, and indicatethat polyclonal memory T cell populations can provide protectionagainst a range of antigenic variants.

Key Words: influenza virus • major histocompatibility complex tetramers • peptides • C57BL mice • in vivo

The small size of the contact surface between the TCR and MHC-boundpeptide suggests that the peptide specificity in TCR–MHCinteractions is limited 1. Indeed, a large number of studieshave demonstrated that the sequence requirements for ligandrecognition by T cell clones in vitro are quite minimal 2 3 4 5.However, in certain situations, variations in CTL epitopes maylead to a total or partial loss of functional recognition bycytotoxic T cells, due to qualitatively different TCR signalingupon interaction with these altered peptide ligand–MHCcomplexes (for a review, see reference 6). Indeed, altered peptideligands have been shown to antagonize antigen-specific T cellresponses both in vitro and in vivo 7 8 9 10 11 12 13 14. These experimentshave firmly established that selected mutations in T cell epitopescan abolish productive T cell recognition. However, it is unresolvedwhether such abortive T cell responses are common upon in vivoencounter of antigen variants. In an MHC outbred population,T cell epitope mutations encountered during transient infectionsare likely to be random, and we therefore set out to examinehow a polyclonal T cell population would react to such randomantigenic variants in an in vivo model.

After infection with influenza A viruses, large numbers of influenzaA–specific cytotoxic T cells can be recovered from pulmonarytissue, lymphoid organs, and peripheral blood in mice and humans15 16 17. In C57BL/10 mice, the immunodominant CTL epitope ofinfluenza A viruses is located in the viral nucleoprotein (NP),¹amino acids 366–374. Within the TCR-exposed side chainsof the COOH-terminal region of this peptide (positions 6, 7,and 8), significant variation exists among naturally occurringinfluenza A strains. Early work from Townsend and Skehel 18showed that certain influenza A virus NP–specific T celllines can recognize viral variants in in vitro assays, but theextent and in vivo relevance of such cross-reactivity have remainedelusive. To assess the consequences of exposure to naturallyoccurring variants on T cell reactivity in an in vivo setting,we have analyzed the effects of polyclonal T cell memory, formedduring a primary influenza A virus infection, on the subsequentresponse against a series of influenza A virus variants. Todirectly visualize T cells displaying antigen receptors thatare monospecific for a certain viral variant or that cross-reactbetween different variants, we used differentially labeled oligomericpeptide–MHC class I complexes 19. Contrary to conventionalfunctional assays, such as ⁵¹Cr release, this strategy allowsfor a direct assessment of the potential for cross-recognitionof individual cells in mixed T cell populations. The resultsthus obtained show that cross-reactive memory T cells generatedduring a primary infection dominate the T cell response duringa secondary infection with a variant virus even when such cross-reactivecells are rare in the original memory T cell pool. The implicationsof these findings for peripheral T cell repertoire selectionand viral variation are discussed.

Materials and Methods

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Abstract
Materials and Methods
Results
Discussion
References

Animals.
C57BL/10 mice at 5–6 wk of age were obtained from theanimal department of the Netherlands Cancer Institute. Micewere handled at all times in accordance with institutional guidelines.

MHC Tetramers and Peptides.
Peptides were produced using standard g-fluorenylmethoxycarbonyl(FMOC) chemistry. Soluble fluorochrome (PE or allophycocyanin[APC])-labeled MHC tetramers were produced as described previously17 19 and stored frozen in Tris-buffered saline/16% glycerol/0.5%BSA.

Viruses and Cells.
Influenza A viruses A/NT/60/68 and A/HKx31 were provided byDr. R. Gonsalves, National Institute for Medical Research, London,UK. Influenza virus B/Lee/40 was obtained from the AmericanType Culture Collection. Mice were killed at indicated timepoints after infection, and organs were removed for furtheranalysis. Inflamed lung tissue and spleens were minced in singlechamber mesh filters. The single cell suspensions obtained weretreated with NH₄Cl solution to get rid of contaminating erythrocytes,before staining for flow cytometry purposes.

The influenza A virus (A/NT/60/68) NP–derived H-2D^b-restrictedCTL epitope, ASNENMDAM, was introduced into EL4 tumor cellsby retroviral insertion as a COOH-terminal fusion with the enhancedgreen fluorescent protein (eGFP) gene product (Wolkers, M.C.,manuscript in preparation).

Flow Cytometry.
In all instances, mononuclear cells were stained with directlylabeled mAbs or MHC tetramers. Analysis was performed on a FACSCalibur^TM(Becton Dickinson) using CELLQuest^TM software (Becton Dickinson).Before staining, propidium iodide (PI) was added to gate forPI-negative (living) lymphocytes.

Cytotoxicity Assay and MHC Monomer Competition Assay.
Cytolytic activity of sorted CD8⁺ T cells derived from inflamedpulmonary tissue was determined in a standard 5-h ⁵¹Cr-releaseassay. EL4 target cells were preincubated with peptides for1 h at 37°C. Percent specific lysis was calculated fromthe equation: [(experimental ⁵¹Cr release – spontaneous⁵¹Cr release)/maximal ⁵¹Cr release – spontaneous ⁵¹Crrelease)] x 100%.

Spleen-derived mononuclear cells were stained with anti-CD8mAb in the presence of PE-labeled MHC tetramers containing increasingconcentrations of MHC monomers. Cells were subsequently analyzedby flow cytometry.

Intracellular IFN- ${gamma}$ Staining.
Intracellular cytokine staining was performed as described 20.In brief, spleen cells were incubated with peptide (0.5 µM)for 5–6.5 h at 37°C in the presence of recombinanthuman (rh)IL-2 (50 U/ml) and Brefeldin A (0.1 µl/ml).After incubation, cells were surface stained with anti-CD8a–APCmAb (PharMingen), incubated in Cytofix/Cytoperm solution (PharMingen)for 20 min on ice, washed, and stained for intracellular cytokinewith anti–IFN- ${gamma}$ –FITC (PharMingen) or FITC-labeledisotype control antibody (PharMingen). Analyses were performedon a FACSCalibur^TM (Becton Dickinson) using CELLQuest^TM software.Isotype control antibodies resulted only in background staining(data not shown).

Peptide Immunization.
Mice were injected subcutaneously with 100 µg peptidein IFA, 4–6 wk after a primary influenza A virus infection.On days 0, 1, and 2, 100 µg anti-CD40 mAb (FGK.45) wasinjected intravenously 21. On day 10 after peptide immunization,spleen cells were used for flow cytometry analysis.

Results

Top
Abstract
Materials and Methods
Results
Discussion
References

Selective Expansion of Cross-reactive Influenza A Virus–specific T Cells.
To assess the effect of random antigen variation on the dynamicsof T cell responses in vivo, we infected mice with pairs ofinfluenza A viruses. These viruses expressed either the sameNP_366–374 epitope or epitope variants. The specificityof the resulting T cell repertoire was assessed by two-parameterMHC tetramer staining, and association of MHC tetramers to NKreceptors was ruled out through analysis of CD8b-expressingcells only. When mice are infected once or twice with eitherinfluenza virus strain A/NT/60/68 or A/PR/8/34, which differin the sequence of the immunodominant NP CTL epitope at positions7 and 8 (ASNENMDAM vs. ASNENMETM), the vast majority of theresulting NP-specific T cells selectively recognize the epitopeof the strain encountered and not that of the opposite strain(Fig. 1 A, panels 1 and 3). This dominant role of the peptideside chains at positions 7 and 8 in ligand recognition by themajority of T cells is in accord with the prominent contributionof p8 and especially p7 to the TCR-exposed surface of this peptide–MHCcomplex 22.

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Figure 1 Selective expansion of cross-reactive T cells. (A) Naive mice were infected intranasally with 10 hemagglutinin units (HAU) influenza A/NT/60/68 (H3N2; epitope: ASNENMDAM) or 200 HAU A/HKx31 (H3N2; epitope: ASNENMETM). 4–6 wk after the primary infection, mice were challenged with 200 HAU influenza A/NT/60/68 (panels 1 and 2) or A/PR/8/34 (panels 3 and 4) (H1N1; epitope: ASNENMETM). At day 10 after challenge, mice were killed and lung-infiltrating mononuclear cells were stained for CD8 and antigen-specific TCR expression using anti-CD8b mAb and MHC tetramers. Gated CD8⁺ T cells were analyzed for binding of APC-labeled MHC tetramers with the influenza A/NT/60/68 epitope and PE-labeled MHC tetramers with the influenza A/PR/8/34 epitope. Identical results are obtained when challenge is performed with influenza A 81/HO (H7N2; NP_366–374 sequence ASNENMDAM) instead of A/NT/60/68, and is therefore independent of HN subtype (not shown). Results represent the outcome of more than five experiments performed. (B) Mice were sequentially infected with influenza virus A/HKx31 and A/NT/60/68. On day 7 after the second infection, spleen cells were incubated with MHC tetramers containing the NP_366–374 epitope (ASNENMDAM) of A/NT/60/68. H-2D^b monomers complexed with ASNENMDAM ( ${blacksquare}$ ) or ASNENMETM ( ${blacktriangleup}$ ) were added in increasing amounts, and inhibition of the binding of MHC tetramers to CD8⁺ T cells was determined.

This virus strain specificity of the NP-reactive CTLs contrastssharply with the apparent lack of strain specificity duringsecondary responses against a variant strain. When mice thathad recovered from a previous infection with influenza virusstrain A/NT/60/68 are challenged with viral strain A/PR/8/34,most if not all NP^PR-reactive T cells are fully cross-reactivebetween the two NP variants (Fig. 1 A, panel 4). This phenomenonis reciprocal: in mice that have previously experienced infectionwith strain A/HKx31 (a reassortant strain with the NP gene fromA/PR/8/34), the NP-reactive T cell population that emerges uponinfection with A/NT/60/68 is fully cross-reactive between thetwo viral strains (Fig. 1 A, panel 2).

Although somewhat variable between individual mice, the extentof binding of the two MHC tetramers appears independent of theorder in which the epitopes were encountered over a large seriesof experiments. To compare the affinity for primary and secondaryantigen in a more direct manner, competition studies were performed.These experiments demonstrate that the binding of fluorochrome-labeledMHC tetramers can be inhibited by similar concentrations ofASNENMDAM- and ASNENMETM-containing monomers, indicating equalaffinity of the cross-reactive TCRs for either antigen (Fig. 1B). In addition, these data rule out the possibility of dualTCR expression 23 24 by the cross-reactive T cells, since bothMHC monomers compete for binding of ASNENMDAM-containing MHCtetramers.

Cross-reactivity Correlates with Cross-recognition.
The above results indicate that the subsequent encounter ofvariants of a T cell epitope results in the expansion of a cross-reactiveT cell population, as established by biochemical assays. Infact, this expansion inhibits the expansion of the largely strain-specificpopulation observed during a regular primary response. However,T cell recognition of ligands with similar affinities can havedrastically different functional outcomes, due to differencesin off rates of TCR–ligand interactions 25 26 27 28 29. Therefore,we examined the functional behavior of this biochemically cross-reactiveT cell population towards both the primary and the mutant epitope.The cross-reactive T cells that are observed during a recallinfluenza A virus infection lyse target cells pulsed with boththe primary and the recall antigen directly ex vivo to the sameextent over a wide range of E/T ratios, and over a range ofpeptide concentrations (Fig. 2 A).

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Figure 2 Ex vivo function of cross-reactive T cells. (A) Cytotoxic activity of cross-reactive T cells. Mice were sequentially infected with A/NT/60/68 (10 HAU) and influenza A/PR/8/34 (200 HAU) and at day 7 after infection, lung-infiltrating CD8⁺ T cells were purified by flow cytometry and directly used as effector cells in a 5-h ⁵¹Cr-release assay at the indicated E/T ratios. Top panel: targets were EL-4 cells ( ${circ}$ ), EL4 cells incubated with 100 µM of the A/NT/60/68 NP_366–374 epitope ASNENMDAM ( ${blacksquare}$ ), or the A/PR/8/34 NP_366–374 epitope ASNENMETM ( ${blacktriangleup}$ ). Bottom panel: purified CD8⁺ T cells were used as effector cells in a 5-h ⁵¹Cr-release assay at an E/T ratio of 7:1. Target cells were EL4 cells preincubated with indicated concentrations of either ASNENMDAM ( ${blacksquare}$ ) or ASNENMETM ( ${blacktriangleup}$ ). Titration of the peptide concentration to the picomolar range also results in similar lysis of both targets. (B) Intracellular IFN- ${gamma}$ staining of spleen cells. Mice were sequentially infected with A/NT/60/68 and A/PR/8/34, and on day 7 after the second infection, spleen cells were stimulated with peptides corresponding to the CTL epitopes of A/NT/60/68 and A/PR/8/34 separately or combined for 6.5 h. Subsequently, cells were stained for surface CD8 and intracellular IFN- ${gamma}$ . Numbers represent the percentage of total lymphocytes that are IFN- ${gamma}$ positive.

As an independent test of functional cross-recognition, we measuredthe ability of these cells to initiate IFN- ${gamma}$ synthesis upon stimulationwith the original or variant epitope. Since simultaneous stainingof cells with MHC tetramers and intracellular IFN- ${gamma}$ stainingis technically difficult, cells were stimulated in the presenceof the original and variant peptide separately or simultaneously(Fig. 2 B). The proportion of IFN- ${gamma}$ –positive CD8⁺ T cellsis similar in all three cases, indicating that the T cell populationsthat recognize the two epitopes are largely overlapping andtherefore cross-reactive.

We conclude that the T cell population that emerges upon encounterof an antigenic variant is biochemically cross-reactive, andthis cross-reactivity is fully reflected in their functionalbehavior.

Cross-reactive T Cells Are Selectively Expanded Memory T Cells.
To better understand the ontogeny of the cross-reactive T cellpopulation, we examined the kinetics and composition of thisT cell pool. The cross-reactive cytotoxic T cell populationappears 2–3 d earlier at the site of infection (i.e.,pulmonary tissue; data not shown) than the antigen-specificT cells during infection of naive mice 15 16 17, suggesting thatthese cells originate from a preexisting memory T cell population.Several studies have shown a narrowing of the antigen-specificpolyclonal TCR repertoire during recall infection, due to thepreferential outgrowth of a subpopulation of memory cells 30 31 32 33.In naive mice that are infected with influenza virus A/PR/8/34,the repertoire of NP-specific T cells involves a variety ofBV elements (Fig. 3 A). The slight preferential usage of theBV8.3 element reported previously for C57BL animals infectedwith influenza virus A/PR8/34 was not observed in these experiments34. In contrast, in A/NT/60/68-primed mice that are infectedwith influenza virus A/PR/8/34, the repertoire of A/PR/8/34-specificT cells is highly restricted (Fig. 3 A). This narrow T cellrepertoire is likely to reflect the affinity maturation observedpreviously 33 compounded by the low number of cross-reactiveT cells within the original memory population. In certain animals,the oligoclonal nature of the cross-reactive T cell populationappears to be directly visible from double-tetramer analysesof the influenza-reactive CD8⁺ T cell population. In these mice,the expanded cross-reactive T cell population appears as twoto three separate populations (an example is shown as Fig. 3B), which may reflect slightly distinct affinities for the primaryand secondary antigen.

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Figure 3 Cross-reactive cells are oligoclonal T memory cell expansions. (A) Cross-reactive CD8⁺ T cells display a restricted BV repertoire. Naive (top) or A/NT/60/68-primed mice (bottom) were infected with 10 and 200 HAU of influenza A/PR/8/34, respectively. At 7 d after infection, lung-infiltrating A/PR/8/34-specific CD8⁺ T cells were analyzed for expression of a series of BV elements by using a panel of fluorochrome-labeled anti-BV antibodies (PharMingen). Values represent the percentage of A/PR/8/34-specific CD8⁺ T cells that stain with a particular anti-BV antibody. (B) Mice were sequentially infected with influenza virus A/HKx31 and A/NT/60/68. 7 d after the second infection, mononuclear cells recovered from pulmonary tissue were stained with anti-CD8 and APC-labeled MHC tetramers with the influenza A/NT/60/68 epitope and PE-labeled MHC tetramers with the influenza A/PR/8/34 epitope, and analyzed by FACS^® analysis. The dot plot reveals three distinct populations of selectively expanded cross-reactive CD8⁺ T cells.

Specificity of Cross-reactive T Cells.
Several reports have indicated that the requirements for activatingmemory T cells differ from those for activating naive T cells,making them more susceptible to low-affinity TCR triggeringor cytokine-mediated stimulation 35 36 37 38 39. To address thepossible contribution of aspecific or more broadly reactiveT cells in the formation of the cross-reactive T cell population,influenza A/NT/60/68-primed mice were infected with the antigenicallyunrelated influenza B virus (B/Lee/40). Both at day 4 (datanot shown) and day 8 after infection (Fig. 4, panel 1), no expansionof the influenza A/NT/60/68-specific memory T cell populationis observed. This is in agreement with results by others showingthat bystander activation during an acute viral infection isminimal 20 40 41. Furthermore, the influenza A virus–specificT cells in mice that underwent sequential infections with A/NT/60/68and A/PR/8/34 do not bind peptide–MHC tetramers that containan adenovirus E1A-derived CTL epitope (Fig. 4, panel 2). Thus,the cross-reactive T cell population that expands upon infectionof primed mice does require a significant structural homologybetween two antigens that are encountered sequentially, andis specific for these two peptide–MHC complexes. Finally,selective outgrowth of cross-reactive T cells does not takeplace to an appreciable extent when the two related antigensare introduced simultaneously (Fig. 4, panel 3). This suggeststhat the selective advantage of cross-reactive cells relieson quantitative or qualitative traits of the T memory population,such as homing properties or the requirements for costimulatorysignals.

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Figure 4 Specificity of cross-reactive T cells. Panel 1: mice were sequentially infected with A/NT/60/68 (10 HAU) and influenza B/Lee/40 (125 HAU) and at day 8 after infection, lung-infiltrating lymphocytes were analyzed for binding of MHC tetramers expressing the A/NT/60/68-derived epitope, ASNENMDAM, and CD8 expression. Panel 2: mice were sequentially infected with A/NT/60/68 (10 HAU) and A/PR/8/34 (200 HAU) and at day 7 after infection, lung-infiltrating CD8⁺ T cells were analyzed for binding of APC-labeled MHC tetramers containing the ASNENMDAM peptide and PE-labeled MHC tetramers with the adenovirus E1A-derived epitope, SGPSNTPPEI. Panel 3: mice were infected with A/NT/60/68 (10 HAU) and A/HKx31 (200 HAU) simultaneously and at day 7 after infection, lung-infiltrating CD8⁺ T cells were analyzed for the presence of A/NT/60/68- and A/PR/8/34-specific T cells. In all panels, the numbers given represent the percentage of CD8⁺ T lymphocytes that stain with the indicated MHC tetramer(s).

Structural Requirements for Cross-reactivity.
To provide a first estimate of the extent of structural homologybetween two antigens that is required for the selective expansionof cross-reactive T cells, we searched the National Center forBiotechnology Information (NCBI) GenBank database for othernatural variants of the H-2D^b–restricted influenza NPepitope. Thus far, 10 variants of this epitope have been identified,7 of which contain mutations that affect TCR-exposed side chains(positions 6, 7, and 8) (reference 22, and Table ). Becauseinfluenza A virus is not a common mouse pathogen, this set ofmutants should be random with respect to T cell recognition.Synthetic peptides corresponding to these mutants were generated,and mice that had previously been exposed to influenza A/NT/60/68or A/HKx31 were challenged by subcutaneous immunization. Tocircumvent the need of helper T cells for the induction of aneffective CTL response, mice were treated with anti-CD40 mAb(FGK.45) after vaccination 21 42 43 44. These experiments establishthat in most if not all cases where influenza A virus–primedmice are confronted with antigens that contain a single mutationwithin the T cell epitope, an influenza-specific T cell populationemerges that is fully cross-reactive between the primary andsecondary antigen (Table ). This phenomenon is not only observedfor conservative substitutions, but also for more drastic aminoacid changes (e.g., Ala8 $->$ Asn). For variants that contain multiplealterations in TCR-exposed residues, cross-reactivity is observedfor some sequences (e.g., ASNENMDAM $->$ ASNENMETM), but not for others(e.g., ASNENMDAM $->$ ASNENVEAM). Both the type of mutation and thecontribution of the mutated residues to the TCR-exposed surfaceof the peptide are likely to be determining factors in thisregard. For one of the mutant epitopes (ASNENVETM), the functionalbehavior of the cross-reactive T cells was also tested. In linewith the biochemical data, intracellular IFN- ${gamma}$ staining of spleencells that were stimulated with the primary antigen (ASNENMETM)or the peptide variant used for vaccination revealed an identicalpercentage of responding cells (data not shown).

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Table 1 Sequence Requirements for Cross-reactive T Cells

In Vivo Function of Cross-reactive T Cells.
Cross-protection or the lack thereof by an epitope-specificT cell population cannot readily be tested through the use ofmutant or recombinant viral strains. Even in settings whereB cell immunity is absent, such as in µ-MT mice, it isdifficult to exclude a possible contribution of T cell responsesagainst subdominant epitopes that are conserved between theprimary and the recall strain. To circumvent these difficulties,we developed a model system in which only the T cell epitopeunder study is shared between the primary and secondary antigenencounter. The NP_366–374 CTL epitope of influenza virusstrain A/NT/60/68 was introduced into the EL4 tumor cell lineas a COOH-terminal fusion with the eGFP gene product. Althoughthe parental cell line grows progressively when injected subcutaneouslyin C57BL/10 mice, the NP epitope–expressing tumor is rejectedover a 2–3-wk time period. Furthermore, tumor rejectionis paralleled by the appearance of an NP_366–374–specificT cell population and is markedly enhanced by simultaneous infectionwith influenza virus A/NT/60/68 (Wolkers, M.C., manuscript inpreparation). Thus, the introduced NP epitope appears to functionas a bona fide (neo)tumor antigen in this setting, as recognitionof this antigen is correlated with tumor rejection.

To examine the in vivo effects of cross-reactive T cell populations,mice that had previously been exposed to influenza virus A/NT/60/68(carrying the homologous NP epitope), A/HKx31 (reassortant ofA/PR/8/34; carrying a variant NP epitope), or an unrelated influenzaB virus were challenged with EL4-NP_366–374 tumor cells.After tumor cell injection, blood samples were taken from individualmice and the frequency of virus strain-specific and cross-reactiveCD8⁺ T cells was measured. In mice that had been infected withthe unrelated influenza B virus (Fig. 5, panel 1), tumor growthis comparable to that in uninfected mice (data not shown). Asexpected, mice that were previously exposed to influenza virusA/NT/60/68, which shares the CTL epitope with the EL4-NP_366–374tumor, showed a strong reduction in tumor growth (Fig. 5, panel1). This protection is accompanied by a massive and rapid increasein the number of A/NT/60/68-monospecific T cells, which wereapparently reactivated from the memory T cell pool by the NPepitope–expressing tumor (Fig. 5, panel 2). Importantly,intermediate tumor growth was seen in mice that had previouslybeen infected with variant virus A/HKx31 (Fig. 5, panel 1).In addition, the reduced tumor outgrowth in these mice is accompaniedby the expansion of a large population of CD8⁺ T cells, whichcross-react between the NP_366–374–expressing EL4tumor and the viral strain used for priming (Fig. 5, panel 3).These results illustrate that the presence of a structurallyrelated T cell antigen promotes the expansion of infrequentcross-reactive T cells even in the absence of any further noticeablehomology between primary and secondary challenge, and this expansionis accompanied by a significant reduction in tumor outgrowth.

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Figure 5 In vivo function of cross-reactive T cells. C57BL/10 mice (six mice per group) were infected with either A/NT/60/68 (10 HAU), A/HKx31 (100 HAU), or B/Lee/40 (125 HAU). 3 mo after the infection, all mice were injected subcutaneously with 3 x 10⁶ live EL4-NP_366–374 tumor cells. 7 d after tumor challenge, tumor size was measured and the mean diameter per mouse is plotted (panel 1). At the same time point, peripheral blood samples were taken and surface stained with anti-CD8 mAb (PharMingen) and differentially labeled MHC tetramers containing the ASNENMDAM and ASNENMETM epitopes. The percentages of A/NT/60/68-monospecific CD8⁺ T cells (panel 2) and cross-reactive CD8⁺ T cells (panel 3) are plotted for individual mice.

	Discussion

Top Abstract Materials and Methods Results Discussion References

The ability of cytotoxic T cell populations to cross-react betweendifferent viral strains was first appreciated by Townsend andSkehel in 1984 18. They showed that repeated in vitro restimulationprotocols of splenic lymphocytes derived from influenza A virus–primedmice could lead to the selection of NP-specific T cell linesthat cross-reacted between different influenza A viral strains.At that time, it was unknown whether these T cell lines cross-reactedat the level of the (variable) immunodominant NP_366–374CTL epitope, or whether shared subdominant epitopes were recognized.However, with the benefit of hindsight, these experiments canbe said to have revealed for the first time the capacity ofcytotoxic T cells to productively recognize viral variants.

In spite of the early recognition of T cell cross-reactivityin in vitro assays, the biological in vivo significance of thiscross-reactivity for the immune system to cope with viral variantshas since remained unclear. Our findings now document that priorantigen exposure dramatically affects the repertoire of T cellsused in a subsequent response to antigenic variants in vivo.The propensity for cross-reactivity between two T cell antigensappears roughly proportional to the sequence similarity betweenthe epitopes tested, and seems to be a common event for antigensthat are closely related. These cells that expand in vivo arephenotypically indistinguishable from conventional effectorT cell populations (CD44^high, CD62L^low; data not shown) andare functional ex vivo and in vivo. This process appears tobe due to the selective expansion of cross-reactive T cellspresent in the memory T cell pool, and is not dependent on sharedB or T helper epitopes between primary and recall antigen.

In recent years, several groups have studied the impact of epitopevariants on antigen-specific T cell responses (for reviews,see references 6, 45, and 46). These variant epitopes were generallyisolated as immune escape variants, or were identified in invitro assays by their aberrant recognition by T cell clones.These selected antigen variants function as either partial agonistsor antagonists of antigen-specific T cell responses not onlyin vitro but also in vivo. We sought to examine whether thistype of T cell antagonism or partial agonism is a common phenomenonwhen a polyclonal T cell repertoire is confronted with antigenicvariation. To this purpose, we studied the development of antigen-specificT cell repertoires after encounter of random natural variantsof influenza A viruses. We conclude that during such encounters,the T cell repertoire generally reacts with the outgrowth ofa T cell population for which the variant epitope is a fullagonist. The TCRs encoded by these T cells bind with equal affinityto MHC molecules complexed with wild-type and variant epitopes.Furthermore, the functional capacity of this T cell populationtowards target cells expressing the original or the variantantigen is indistinguishable both in vitro and in vivo.

How do these data fit in with previous observations that mutationsin T cell epitopes can lead to CTL escape by the virus? Duringchronic HIV and HBV infections 10 11, and also in a murine lymphocyticchoriomeningitis virus (LCMV) model 12, the mechanism that wehave identified apparently does not operate efficiently. Intheory, this could be due to the type of amino acid changesin the T cell epitopes involved. However, examination of thetype of mutations in the T cell epitopes in those cases andthe mutations studied here does not point towards obvious differences(not shown). Alternatively, the impaired ability to react toemerging antigenic variants in those settings may be due toalterations at the T cell level. Specifically, repetitive antigen-specificT cell stimulation results in a narrowing of the reactive Tcell repertoire 33. Indeed, the antigen-specific T cell expansionsobserved during chronic HIV infection are oligoclonal 47. Itmay be hypothesized that for such restricted antigen-specificT cell populations, a single antigenic variant could antagonizea substantial part of the antigen-specific T cell response,and it will be a challenge to test this notion in a direct manner.

Why do cross-reactive T cells dominate the response againstantigenic variants over the largely strain-specific responseobserved normally during a primary T cell response? The cross-reactiveT cells that we have identified appear to originate from thepreexisting memory T cell pool, and naive and memory T cellsdiffer both in quantitative and qualitative terms. Specifically,even though cross-reactive cells are infrequent in the originalmemory pool, these cells may still outnumber the strain-specificT cells that—due to their specificity—failed toget activated in the primary response. In addition, the activationrequirements of memory T cells are less stringent than thoseof naive T cells 38 48 49. This is reflected in a lessened requirementboth for costimulatory signals and for prolonged antigenic stimulation.Finally, the ability of memory T cells to enter peripheral tissuesmay promote the early encounter of viral antigens 50. Indirectevidence for functional T cell cross-reactivity during subsequentviral infections has been obtained previously. Experiments byWelsh and colleagues 51 have suggested that a measure of heterologousimmunity may occur even for apparently unrelated viruses. Althoughin that case the antigenic determinants involved were not identifiedand cross-reactive cells were of low avidity, these resultsdo suggest that the selective expansion of cross-reactive memoryT cells could be a more general phenomenon.

We conclude that a polyclonal T cell repertoire responds tothe encounter of random variants by the expansion of memoryT cells that are best fit for the recognition of the variantantigen. These findings suggest that random mutations in T cellepitopes are unlikely to result in CTL escape, and that a polyclonalT cell memory population can provide protection not only againstthe index sequence, but also against a swarm of related sequences.

Acknowledgments

The authors would like to thank Mireille Toebes and Marjo vanPuijenbroek for preparation of MHC tetramers and technical assistance,Helmut Kessels for peptide synthesis, Drs. G. Rimmelzwaan andA. Osterhaus (Erasmus University, Rotterdam, The Netherlands)for growing and titrating the various influenza strains, andmembers of the Kruisbeek and Schumacher labs for discussions.

Submitted: 9 July 1999
Revised: 19 August 1999
Accepted: 23 August 1999

1used in this paper: APC, allophycocyanin; HAU, hemagglutininunit(s); NP, nucleoprotein; PI, propidium iodide

References

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References

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