A previously unrecognized H-2D(b)-restricted peptide prominent in the primary influenza A virus-specific CD8(+) T-cell response is much less apparent following secondary challenge

Respiratory challenge of H-2(b) mice with an H3N2 influenza A virus causes an acute, transient pneumonitis characterized by the massive infiltration of CD8(+) T lymphocytes. The inflammatory process monitored by quantitative analysis of lymphocyte populations recovered by bronchoalveolar lavage is greatly enhanced by prior exposure to an H1N1 virus, with the recall of cross-reactive CD8(+)-T-cell memory leading to more rapid clearance of the infection from the lungs. The predominant epitope recognized by the influenza virus-specific CD8(+) set has long been thought to be a nucleoprotein (NP(366-374)) presented by H-2D(b) (D(b)NP(366)). This continues to be true for the secondary H3N2-->H1N1 challenge but can no longer be considered the case for the primary response to either virus. Quantitative analysis based on intracellular staining for gamma interferon has shown that the polymerase 2 protein (PA(224-233)) provides a previously undetected epitope (D(b)PA(224)) that is at least as prominent as D(b)NP(366) during the first 10 days following primary exposure to either the H3N2 or H1N1 virus. The response to D(b)NP(366) seems to continue for longer, even when infectious virus can no longer be detected, but there is no obvious difference in the prevalence of memory T cells specific for D(b)NP(366) and D(b)PA(224). The generalization that the magnitude of the functional memory T-cell pool is a direct consequence of the clonal burst size during the primary response may no longer be useful. Previous CD8(+)-T-cell immunodominance heirarchies defined largely by cytotoxic T-lymphocyte assays may need to be revised.     

Virus-specific and bystander CD8+ T-cell proliferation in the acute and persistent phases of a gammaherpesvirus infection

The cycling characteristics of CD8+ T cells specific for two lytic-phase epitopes of murine gammaherpesvirus 68 (gammaHV68) have been analyzed for mice with high or low levels of virus persistence. The extent of cell division is generally reflective of the antigen load and suggests that gammaHV68 may be regularly reactivating from latency for some months after the resolution of the acute phase of the infectious process. Although gammaHV68 infection is also associated with massive proliferation of lymphocytes that are not obviously specific for the virus, the level of "bystander-induced" cycling in a population of influenza virus-specific CD8+ T cells was generally fourfold lower than the extent of cell division seen for the antigen-driven, gammaHV68-specific response. The overall conclusion is that turnover rates substantially in excess of 5 to 10% over 6 days for CD8+ "memory" T-cell populations are likely to be reflective of continued antigenic exposure.     

Concurrent naive and memory CD8(+) T cell responses to an influenza A virus

Memory Thy-1(+)CD8(+) T cells specific for the influenza A virus nucleoprotein (NP(366-374)) peptide were sorted after staining with the D(b)NP(366) tetramer, labeled with CFSE, and transferred into normal Thy-1.2(+) recipients. The donor D(b)NP(366)(+) T cells recovered 2 days later from the spleens of the Thy-1.2(+) hosts showed the CD62L(low)CD44(high)CD69(low) phenotype, characteristic of the population analyzed before transfer, and were present at frequencies equivalent to those detected previously in mice primed once by a single exposure to an influenza A virus. Analysis of CFSE-staining profiles established that resting tetramer(+) T cells divided slowly over the next 30 days, while the numbers in the spleen decreased about 3-fold. Intranasal infection shortly after cell transfer with a noncross-reactive influenza B virus induced some of the donor D(b)NP(366)(+) T cells to cycle, but there was no increase in the total number of transferred cells. By contrast, comparable challenge with an influenza A virus caused substantial clonal expansion, and loss of the CFSE label. Unexpectedly, the recruitment of naive Thy-1.2(+)CD8(+)D(b)NP(366)(+) host D(b)NP(366)(+) T cells following influenza A challenge was not obviously diminished by the presence of the memory Thy-1.1(+)CD8(+)D(b)NP(366)(+) donor D(b)NP(366)(+) set. Furthermore, the splenic response to an epitope (D(b)PA(224)) derived from the influenza acid polymerase (PA(224-233)) was significantly enhanced in the mice given the donor D(b)NP(366)(+) memory population. These experiments indicate that an apparent recall response may be comprised of both naive and memory CD8(+) T cells.     

Temporal segregation of 4-1BB versus CD28-mediated costimulation: 4-1BB ligand influences T cell numbers late in the primary response and regulates the size of the T cell memory response following influenza infection

In this report, we demonstrate that CD28(-/-) mice are severely impaired in the initial expansion of D(b)/NP366-374-specific CD8 T cells in response to influenza virus infection, whereas 4-1BB ligand (4-1BBL)(-/-) mice show no defect in primary T cell expansion to influenza virus. In contrast, 4-1BBL(-/-) mice show a decrease in D(b)/NP366-374-specific T cells late in the primary response. Upon secondary challenge with influenza virus, 4-1BBL(-/-) mice show a decrease in the number of D(b)/NP366-374-specific T cells compared to wild-type mice such that the level of the CD8 T cell expansion during the in vivo secondary response is reduced to the level of a primary response, with concomitant reduction of CTL effector function. In contrast, Ab responses, as well as secondary CD4 T cell responses, to influenza are unaffected by 4-1BBL deficiency. Thus, CD28 is critical for initial T cell expansion, whereas 4-1BB/4-1BBL signaling affects T cell numbers much later in the response and is essential for the survival and/or responsiveness of the memory CD8 T cell pool.     

Profound protection against respiratory challenge with a lethal H7N7 influenza A virus by increasing the magnitude of CD8(+) T-cell memory

The recall of CD8(+) T-cell memory established by infecting H-2(b) mice with an H1N1 influenza A virus provided a measure of protection against an extremely virulent H7N7 virus. The numbers of CD8(+) effector and memory T cells specific for the shared, immunodominant D(b)NP(366) epitope were greatly increased subsequent to the H7N7 challenge, and though lung titers remained as high as those in naive controls for 5 days or more, the virus was cleared more rapidly. Expanding the CD8(+) memory T-cell pool (<0.5 to >10%) by sequential priming with two different influenza A viruses (H3N2-->H1N1) gave much better protection. Though the H7N7 virus initially grew to equivalent titers in the lungs of naive and double-primed mice, the replicative phase was substantially controlled within 3 days. This tertiary H7N7 challenge caused little increase in the magnitude of the CD8(+) D(b)NP(366)(+) T-cell pool, and only a portion of the memory population in the lymphoid tissue could be shown to proliferate. The great majority of the CD8(+) D(b)NP(366)(+) set that localized to the infected respiratory tract had, however, cycled at least once, though recent cell division was shown not to be a prerequisite for T-cell extravasation. The selective induction of CD8(+) T-cell memory can thus greatly limit the damage caused by a virulent influenza A virus, with the extent of protection being directly related to the number of available responders. Furthermore, a large pool of CD8(+) memory T cells may be only partially utilized to deal with a potentially lethal influenza infection.     

Antigen-specific CD8(+) T cells persist in the upper respiratory tract following influenza virus infection.

Because little is known about lymphocyte responses in the nasal mucosa, lymphocyte accumulation in the nasal mucosa, nasal-associated lymphoid tissue (NALT), and cervical lymph nodes (CLN) were determined after primary and heterosubtypic intranasal influenza challenge of mice. T cell accumulation peaked in the nasal mucosa on day 7, but peaked slightly earlier in the CLN (day 5) and later (day 10) in the NALT. Tetrameric staining of nasal mucosal cells revealed a peak accumulation of CD8 T cells specific for either the H-2D(b) influenza nucleoprotein epitope 366-374 (D(b)NP(366)) or the H-2D(b) polymerase 2 protein epitope 224-233 (D(b)PA(224)) at 7 days. By day 13, D(b)PA(224)-specific CD8 T cells were undetectable in the mucosa, whereas D(b)NP(366)-specific CD8 T cells persisted for at least 35 days in the mucosa and spleen. After heterosubtypic virus challenge, the accumulation of CD8 T cells in the nasal mucosa was quicker, more intense, and predominantly D(b)NP(366) specific relative to the primary inoculation. The kinetics and specificity of the CD8 T cell response were similar to those in the CLN, but the responses in the NALT and spleen were again slower and more protracted. These results indicate that similar to what was reported in the lung, D(b)NP(366)-specific CD8 T cells persist in the nasal mucosa after primary influenza infection and predominate in an intensified nasal mucosal response to heterosubtypic challenge. In addition, differences in the kinetics of the CD8 T cell responses in the CLN, NALT, and spleen suggest different roles of these lymphoid tissues in the mucosal response.     

Strong memory CD8+ T cell responses against immunodominant and three new subdominant HLA-B27-restricted influenza A CTL epitopes following secondary infection of HLA-B27 transgenic mice

We previously showed that the known HLA-B27-restricted influenza A epitope identified from human studies, NP.383-391, was recognized by CTLs following influenza A infection of transgenic (Tg) HLA-B27/H2 class I-deficient (H2 DKO) mice. Here, we examined the kinetics of the primary NP.383-391-specific response in Tg HLA-B27/H2 DKO mice at the site of respiratory infection, along with the profile of additional influenza A epitopes recognized. While the temporal kinetics of the Tg HLA-B27/NP.383-391-specific CD8+ T cell response paralleled the H2-D(b)/NP.366-374-specific response of non-Tg H2b mice, the magnitude was less. Using epitope prediction programs, we identified three novel B27-restricted influenza A epitopes, PB2.702-710, PB1.571-579, and PB2.368-376, recognized during both the primary and secondary response to infection. Although the secondary NP.383-391-specific response was dominant, PB1.571-579 and PB2.368-376 stimulated stronger proliferative expansion in memory T cells. Our results indicate a broader B27/influenza A CTL repertoire than previously known. Together with results for other HLA class I alleles, this information will become important in improving vaccine strategies for influenza A and other human pathogens.     

Reduced functional capacity of CD8+ T cells expanded by post-exposure vaccination of gamma-herpesvirus-infected CD4-deficient mice

Mice (I-A(b-/-)) that lack CD4(+) T cells remain healthy for at least three months after respiratory exposure to the murine gamma-herpesvirus 68 (gammaHV68), then succumb with symptoms of chronic wasting disease. Postexposure challenge of gammaHV68-infected I-A(b+/+) and I-A(b-/-) mice with a recombinant vaccinia virus (Vacc-p56) expressing an antigenic gammaHV68 peptide caused a massive increase in the numbers of D(b)p56-specific CD8(+) T cells. Previous experiments showed that, despite the large numbers of potential CTL effectors, there was little effect on the long-term survival of the CD4-deficient group and no diminution in the level of persistent virus shedding and latency. Comparison of the expanded CD8(+)D(b)p56(+) sets in the I-A(b+/+) and I-A(b-/-) mice indicated that these two T cell populations were not identical. More CD69(high)CD8(+) D(b)p56(+) T cells were found in the CD4-deficient mice, an effect that might be thought to reflect higher Ag load. By contrast, the mean fluorescence intensity of staining for the CD44 glycoprotein was diminished on CD8(+)D(b)p56(+) T cells from the I-A(b-/-) group, the level of CTL activity was lower on a per cell basis, and the relative prevalence of IFN-gamma(+)TNF-alpha(+) T cells detected after in vitro stimulation with the p56 peptide was decreased. Given that this experimental system provides an accessible model for evaluating postexposure vaccination protocols that might be used in diseases like HIV/AIDS, the further need is to clarify the underlying molecular mechanisms and the relative significance of lack of CD4(+) T help vs higher Ag load for these expanded CD8(+) effector populations.     

Terminal deoxynucleotidyltransferase is required for the establishment of private virus-specific CD8+ TCR repertoires and facilitates optimal CTL responses

Virus-immune CD8(+) TCR repertoires specific for particular peptide-MHC class I complexes may be substantially shared between (public), or unique to, individuals (private). Because public TCRs can show reduced TdT-mediated N-region additions, we analyzed how TdT shapes the heavily public (to D(b)NP(366)) and essentially private (to D(b)PA(224)) CTL repertoires generated following influenza A virus infection of C57BL/6 (B6, H2(b)) mice. The D(b)NP(366)-specific CTL response was virtually clonal in TdT(-/-) B6 animals, with one of the three public clonotypes prominent in the wild-type (wt) response consistently dominating the TdT(-/-) set. Furthermore, this massive narrowing of TCR selection for D(b)NP(366) reduced the magnitude of D(b)NP(366)-specific CTL response in the virus-infected lung. Conversely, the D(b)PA(224)-specific responses remained comparable in both magnitude and TCR diversity within individual TdT(-/-) and wt mice. However, the extent of TCR diversity across the total population was significantly reduced, with the consequence that the normally private wt D(b)PA(224)-specific repertoire was now substantially public across the TdT(-/-) mouse population. The key finding is thus that the role of TdT in ensuring enhanced diversity and the selection of private TCR repertoires promotes optimal CD8(+) T cell immunity, both within individuals and across the species as a whole.     

Virus-specific CD8+ T cells in the liver: armed and ready to kill

Influenza A virus infection of C57BL/6 mice is a well-characterized model for studying CD8+ T cell-mediated immunity. Analysis of primary and secondary responses showed that the liver is highly enriched for CD8+ T cells specific for the immunodominant H2D(b)NP(366-374) (D(b)NP(366)) epitope. Functional analysis established that these liver-derived virus-specific CD8+ T cells are fully competent cytotoxic effectors and IFN-gamma secretors. In addition, flow cytometric analysis of early apoptotic cells showed that these influenza-specific CD8+ T cells from liver are as viable as those in the spleen, bronchoalveolar lavage, mediastinal lymph nodes, or lung. Moreover, cytokine profiles of the influenza-specific CD8+ T cells recovered from different sites were consistent with the bronchoalveolar lavage, rather than liver population, being the most susceptible to activation-induced cell death. Importantly, adoptively transferred influenza virus-specific CD8+ T cells from the liver survived and were readily recalled after virus challenge. Together, these results show clearly that the liver is not a "graveyard" for influenza virus-specific CD8+ T cells.     

Consequences of suboptimal priming are apparent for low-avidity T-cell responses

The emergence of the novel reassortant A(H1N1)-2009 influenza virus highlighted the threat to the global population posed by an influenza pandemic. Pre-existing CD8(+) T-cell immunity targeting conserved epitopes provides immune protection against newly emerging strains of influenza virus, when minimal antibody immunity exists. However, the occurrence of mutations within T-cell antigenic peptides that enable the virus to evade T-cell recognition constitutes a substantial issue for virus control and vaccine design. Recent evidence suggests that it might be feasible to elicit CD8(+) T-cell memory pools to common virus mutants by pre-emptive vaccination. However, there is a need for a greater understanding of CD8(+) T-cell immunity towards commonly emerging mutants. The present analysis focuses on novel and immunodominant, although of low pMHC-I avidity, CD8(+) T-cell responses directed at the mutant influenza D(b)NP(366) epitope, D(b)NPM6A, following different routes of infection. We used a C57BL/6J model of influenza to dissect the effectiveness of the natural intranasal (i.n.) versus intraperitoneal (i.p.) priming for generating functional CD8(+) T cells towards the D(b)NPM6A epitope. In contrast to comparable CD8(+) T-cell responses directed at the wild-type epitopes, D(b)NP(366) and D(b)PA(224), we found that the priming route greatly affected the numbers, cytokine profiles and TCR repertoire of the responding CD8(+) T cells directed at the D(b)NPM6A viral mutant. As the magnitude, polyfunctionality, and T-cell repertoire diversity are potential determinants of the protective efficacy of CD8(+) T-cell responses, our data have implications for the development of vaccines to combat virus mutants.     

Late signals from CD27 prevent Fas-dependent apoptosis of primary CD8+ T cells

The role of costimulation has previously been confined to the very early stages of the CD8+ T cell response. In this study, we demonstrate the requirement for CD27 costimulation during the later phase, but not programming of the primary CD8+ T cell response to influenza virus and reveal a novel mechanism of action for CD27 costimulation. CD27 signals, during the later phase of the primary CD8+ T cell response, prevent apoptosis of Ag-specific CD8+ T cells. Blocking CD27L (CD70) on days 6 and 8 after infection reduces the number of NP(366-374)-specific CD8+ T cells, increases their sensitivity to CD95/Fas-mediated apoptosis, and up-regulates FasL on CD4+ T cells. This reduction of NP(366-374)-specific CD8+ T cells requires the presence of CD4+ T cells and Fas signaling. Lack of CD27 signals also decreases the quality of memory CD8+ T cell responses. Memory CD8+ T cells, which express surface CD27 similar to naive cells, however, do not require CD27 costimulation during a secondary response. Thus, CD27 acts indirectly to regulate primary Ag-specific CD8+ T cell responses by preventing apoptosis of CD8+ T cells during the later phase of the primary response and is required for optimal quality of memory cells, but is not required during normally primed secondary CD8+ T cell responses.     

An in vivo cytotoxicity threshold for influenza A virus-specific effector and memory CD8(+) T cells

Influenza A virus infection of C57BL/6 (B6) mice is characterized by prominent CD8(+) T cell responses to H2D(b) complexed with peptides from the viral nucleoprotein (NP(366), ASNENMETM) and acid polymerase (PA(224), SSLENFRAYV). An in vivo cytotoxicity assay that depends on the adoptive transfer of peptide-pulsed, syngeneic targets was used in this study to quantitate the cytotoxic potential of D(b)NP(366)- and D(b)PA(224)-specific acute and memory CD8(+) T cells following primary or secondary virus challenge. Both T cell populations displayed equivalent levels of in vivo effector function when comparable numbers were transferred into naive B6 hosts. Cytotoxic activity following primary infection clearly correlated with the frequency of tetramer-stained CD8(+) T cells. This relationship looked, however, to be less direct following secondary exposure, partly because the numbers of CD8(+)D(b)NP(366)(+) T cells were greatly in excess. However, calculating the in vivo E:T ratios indicated that in vivo lysis, like many other biological functions, is threshold dependent. Furthermore, the capacity to eliminate peptide-pulsed targets was independent of the differentiation state (i.e., primary or secondary effectors) and was comparable for the two T cell specificities that were analyzed. These experiments provide insights that may be of value for adoptive immunotherapy, where careful consideration of both the activation state and the number of effector cells is required.     

Addition of a prominent epitope affects influenza A virus-specific CD8+ T cell immunodominance hierarchies when antigen is limiting

A reverse genetics strategy was used to insert the OVA peptide (amino acid sequence SIINFEKL; OVA(257-264)) into the neuraminidase stalk of both the A/PR8 (H1N1) and A/HKx31 (H3N2) influenza A viruses. Initial characterization determined that K(b)OVA257 is presented on targets infected with PR8-OVA and HK-OVA without significantly altering D(b) nucleoprotein (NP)366 presentation. There were similar levels of K(b)OVA257- and D(b)NP366-specific CTL expansion following both primary and secondary intranasal challenge. Interestingly, while variable, the presence of the immunodominant K(b)OVA257-specific response resulted in diminished D(b) acidic polymerase224- and K(b) basic polymerase subunit 1(703)-, but not D(b)NP366-specific responses and didn't alter endogenous influenza A virus-specific immunodominance hierarchies. However, challenging PR8-OVA-primed mice with HK-OVA via the i.p. route, and thereby limiting Ag dose, led to a reduction in the magnitude of all the influenza A virus-specific responses measured. A similar reduction in CTL response to native epitopes was also seen following primary respiratory HK-OVA infection of mice that received substantial numbers of K(b)OVA257-specific TCR transgenic T cells. Thus, during the course of infection, the generation of individual virus-specific CTL responses is independently regulated. However, in cases in which Ag is limiting, or high precursor frequency, the presence of immunodominant CTL responses can impact on the magnitude of other specific populations. Therefore, depending on both the size of the T cell precursor pool and the mode of Ag presentation, the addition of a major epitope can diminish the size of endogenous, influenza-specific CD8+ T cell responses, although never to the point that these are totally compromised.     

Diminished primary and secondary influenza virus-specific CD8(+) T-cell responses in CD4-depleted Ig(-/-) mice

Optimal expansion of influenza virus nucleoprotein (D(b)NP(366))-specific CD8(+) T cells following respiratory challenge of naive Ig(-/-) microMT mice was found to require CD4(+) T-cell help, and this effect was also observed in primed animals. Absence of the CD4(+) population was consistently correlated with diminished recruitment of virus-specific CD8(+) T cells to the infected lung, delayed virus clearance, and increased morbidity. The splenic CD8(+) set generated during the recall response in Ig(-/-) mice primed at least 6 months previously showed a normal profile of gamma interferon production subsequent to short-term, in vitro stimulation with viral peptide, irrespective of a concurrent CD4(+) T-cell response. Both the magnitude and the localization profiles of virus-specific CD8(+) T cells, though perhaps not their functional characteristics, are thus modified in mice lacking CD4(+) T cells.     

CTL recognition of a protective immunodominant influenza A virus nucleoprotein epitope utilizes a highly restricted Vbeta but diverse Valpha repertoire: functional and structural implications

To investigate protective immunity conferred by CTL against viral pathogens, we have analyzed CD8(+) T cell responses to the immunodominant nucleoprotein epitope (NP(366-374)) of influenza A virus in B6 mice during primary and secondary infections in vivo. Unlike the highly biased TCR Vbeta repertoire, the associated Valpha repertoire specific for the NP(366-374)/D(b) ligand is quite diverse. Nonetheless, certain public and conserved CDR3alpha clonotypes with distinct molecular signatures were identified. Pairing of public Valpha and Vbeta domains creates an alphabeta TCR heterodimer that binds efficiently to the NP(366-374)/D(b) ligand and stimulates T cell activation. In contrast, private TCRs, each comprising a distinct alpha chain paired with the same public beta chain, interact very differently. Molecular dynamics simulation reveals that the conformation and mobility of the shared Vbeta CDR loops are governed largely by the associated Valpha domains. These results provide insight into molecular principles regarding public versus private TCRs linked to immune surveillance after infection with influenza A virus.     

A simple mathematical model helps to explain the immunodominance of CD8 T cells in influenza A virus infections

Understanding immunodominance, the phenomenon of epitope-specific T cells expanding in an often distinctly hierarchical fashion, is important for the design of T-cell-based intervention strategies. Several recent studies have investigated immunodominance of H-2D(b)-restricted CD8(+) T cells specific for the nucleoprotein NP366 and acid polymerase PA224 epitopes during influenza A virus infection of C57BL/6 mice. CD8(+) T cells specific for these two epitopes are codominant during primary infection; NP366 dominates during secondary infection. While a number of explanations for this observation have been proposed, none of them can fully account for all the observed data. In this article, we use a simple mathematical model to explain the seemingly inconsistent data. We show that the dynamic interactions between CD8(+) T cells and antigen presentation lead to a situation where CD8(+) T cells are limiting during the initial response whereas antigen is limiting in the secondary response. This "numbers game" between antigen and CD8(+) T cells can reproduce the observed immunodominance of the NP336- and PA224-specific CD8(+) T cells, thereby explaining the reported experimental data.     

Quantification of repertoire diversity of influenza-specific epitopes with predominant public or private TCR usage

The H-2Db-restricted CD8 T cell immune response to influenza A is directed at two well-described epitopes, nucleoprotein 366 (NP366) and acid polymerase 224 (PA224). The responses to the two epitopes are very different. The epitope NP366-specific response is dominated by TCR clonotypes that are public (shared by most mice), whereas the epitope PA224-specific response is private (unique within each infected animal). In addition to being public, the NP366-specific response is dominated by a few clonotypes, when T cell clonotypes expressing the Vbeta8.3 element are analyzed. Herein, we show that this response is similarly public when the NP366+Vbeta4+ CD8 T cell response is analyzed. Furthermore, to determine whether these features resulted in differences in total TCR diversity in the NP366+ and PA224+ responses, we quantified the number of different CD8 T clonotypes responding to each epitope. We calculated that 50-550 clonotypes recognized each epitope in individual mice. Thus, although the character of the response to the two epitopes appeared to be different (private and diverse vs public and dominated by a few clonotypes), similar numbers of precursor cells responded to both epitopes and this number was of similar magnitude to that previously reported for other viral CD8 T cell epitopes. Therefore, even in CD8 T cell responses that appear to be oligoclonotypic, the total response is highly diverse.     

Compromised influenza virus-specific CD8(+)-T-cell memory in CD4(+)-T-cell-deficient mice

The primary influenza A virus-specific CD8(+)-T-cell responses measured by tetramer staining of spleen, lymph node, and bronchoalveolar lavage (BAL) lymphocyte populations were similar in magnitude for conventional I-A(b+/+) and CD4(+)-T-cell-deficient I-A(b-/-) mice. Comparable levels of virus-specific cytotoxic-T-lymphocyte activity were detected in the inflammatory exudate recovered by BAL following challenge. However, both the size of the memory T-cell pool and the magnitude of the recall response in the lymphoid tissues (but not the BAL specimens) were significantly diminished in mice lacking the CD4(+) subset. Also, the rate of virus elimination from the infected respiratory tract slowed at low virus loads following challenge of na?ve and previously immunized I-A(b-/-) mice. Thus, though the capacity to mediate the CD8(+)-T-cell effector function is broadly preserved in the absence of concurrent CD4(+)-T-cell help, both the maintenance and recall of memory are compromised and the clearance of residual virus is delayed. These findings are consistent with mathematical models that predict virus-host dynamics in this, and other, models of infection.