HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Zhang, M. Articles by Ashton-Rickardt, P. G. Search for Related Content PubMed PubMed Citation Articles by Zhang, M. Articles by Ashton-Rickardt, P. G.

Differential Survival of Cytotoxic T Cells and Memory Cell Precursors¹

Manling Zhang^2,*, Susan Byrne^2,*, Ni Liu^2,*, Yue Wang^2,*, Annette Oxenius and Philip G. Ashton-Rickardt^2,3,*

^* Department of Pathology, Ben May Institute for Cancer Research and Committee on Immunology, University of Chicago, Chicago, IL 60637; and Institute of Microbiology, Eidgenössische Technische Hochschule, Zurich, Switzerland

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
It is widely assumed that the development of memory CD8 T cells requires the escape of CTLs from programmed cell death. We show in this study that although serine protease inhibitor 6 (Spi6) is required to protect clonal bursts of CTLs from granzyme B-induced programmed cell death, it is not required for the development of memory cells. This conclusion is reached because memory cell precursors down-regulate both Spi6 and granzyme B, unlike CTLs, and they do not require Spi6 for survival. These findings suggest that memory CD8 T cells are derived from progenitors that are refractory to self-inflicted damage, rather than derived from fully differentiated CTLs.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Recognition of peptide Ag, presented by self-MHC (pMHC), by the TCR triggers the clonal expansion and differentiation of naive CD8 T cells into CTLs (1). CTLs kill target cells either by exocytosis of cytolytic granules or the engagement of Fas by Fas ligand (2). Exocytosis of perforin (3, 4) facilitates the entry of serine proteases called granzymes, which trigger apoptosis in target cells. Granzyme B (GrB)⁴ is required for the induction of target cell death (5, 6), through the activation of apoptotic pathways triggered by the cleavage of caspases and the induction of nuclear DNA fragmentation (7).

The clonal expansion (or clonal burst) of naive CD8 T cells into CTLs is followed by the contraction phase of the immune response, during which 90–95% of effectors are eliminated through programmed cell death (PCD) (1). Those cells that survive the contraction phase subsequently develop into memory CD8 T cells (8, 9). The memory phase can extend for the lifetime of the host (1), providing immunity as the result of both an increased precursor frequency of Ag-specific cells and improved function compared with naive cells (1). Memory cell development in which size of the clonal burst is flexible and the degree of contraction fixed, allows the generation of memory CD8 T cells proportional to the primary CTL response, while leaving space for CD8 T cell responses against new infections. Thus, 5–10% of the CTL pool survives to differentiate into memory CD8 T cells, and so clonal burst size determines the size of the memory pool (10, 11, 12, 13, 14, 15).

Studies from our laboratory (8) and other studies (9, 16) indicate that memory CD8 T cells are derived from the CTL-progenitor lineage. Therefore, to understand how memory precursors escape PCD, emphasis has been placed on understanding the pathways that control CTL survival. Effector molecules induce the PCD of CTLs and thereby play a role in determining both clonal burst size and the severity of the contraction phase. The clonal burst size of CTLs is massively increased in perforin knockout (KO) CTLs (17, 18, 19) and IFN- KO CD8 T cells fail to undergo a contraction phase (20, 21). These studies strongly suggest that PCD triggered by perforin determines clonal burst size and PCD triggered by IFN- controls the severity of the contraction phase. The expression of IL-7R (CD127) identifies a small percentage of CTLs, which have an increased likelihood of differentiating into memory CD8 T cells (22, 23). These IL-7R^high, memory precursors up-regulate protective factors, which allows them to escape PCD and differentiate into memory cells (24). However, it remains to be determined whether the biochemical pathways that control the survival of CTLs are the same as those that control the survival of memory cell precursors and the subsequent differentiation of memory CD8 T cells.

We have recently shown (25), that the clonal burst size of CTLs is determined by an endogenous inhibitor of GrB called serine protease inhibitor 6 (Spi6) (26). Spi6 protected CTLs from PCD by inactivating GrB that leaks from cytotoxic granules in the cytoplasm through the formation of complexes characteristic of a serpin: protease interaction. The survival of Spi6 KO CTLs specific for lymphocytic choriomeningitis virus (LCMV) or Listeria monocytogenes (LM) was drastically impaired due to increased GrB-mediated PCD. We made use of Spi6 KO mice to determine whether Spi6 in turn was required to promote the survival of memory cell precursors and hence development of memory CD8 T cells.

Infection with LCMV revealed a critical requirement for Spi6 in determining the clonal burst size of both primary and secondary CD8 T cell responses to L. monocytogenes and LCMV. To our surprise, despite a severely diminished clonal burst, the number of memory CD8 T cells was unaffected in Spi6 KO mice because although Spi6 was required for the survival of the majority CTLs, it was not needed by the subset of IL-7R^high memory cell precursors. The independence of memory cell precursors from Spi6 protection from GrB was because they constituted a lineage in which GrB and Spi6 were down-regulated. The resulting model of CD8 memory T cell development is one in which independence from self-inflicted damage defines the population of memory cell precursors in contrast to CTLs within the clonal burst.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Mice

C57BL/6 Spi6 KO and C57BL/6 Spi6 KO P14 TCR^+/– (Spi6 KO P14) mice have been previously described (25). C57BL/6 CD45.1 congenic mice were purchased from Taconic Farms. All mice were maintained and bred under standard specific pathogen-free conditions. All experiments with mice were performed in compliance with the University of Chicago Institutional Animal Care and Use Committee regulations.

Infections

For primary immune responses, mice were infected by either i.p. injection (2 x 10⁵ PFU) of LCMV Armstrong (27) or i.v. injection of L. monocytogenes strain DPL-1942 (10⁵ CFU), which has been engineered to express OVA and in C57BL/6 mice generates the H-2K^b-restricted peptide epitope (SIINFEKL:OVA) (28). For recall responses, no sooner than 300 days after the first infection, mice were i.v. reinfected with either the clone 13 variant of LCMV Armstrong (10⁶ PFU) (29) or L. monocytogenes DPL-1942 (10⁶ CFU), then the number of secondary effectors measured after 5 days.

Anti-Spi6 antiserum

Recombinant Spi6 was generated in the pGEX-3X expression system in Escherichia coli as a fusion protein with GST and purified to homogeneity (>90% pure), using standard procedures recommended by the manufacturer (Amersham Biosciences). Rabbits were primed with 0.35 mg of recombinant GST-Spi6 in CFA then boosted twice with 0.15 mg then finally with 0.35 mg in IFA.

Flow cytometry

The following mAbs were used: anti-CD8 (allophycocyanin-labeled), anti-CD45.2 FITC or R-PE, anti-CD44 PE, anti-IFN- PE (rat IgG1) and rat IgG1-PE isotype control, anti-IL-7R biotin (clone B12-1) then streptavidin-CyChrome (Cy5) (all from BD Pharmingen), and anti-human GrB (clone GB12) then anti-mouse IgG-allophycocyanin (both from Caltag Laboratories). H-2D^b tetramers with gp33 (KAVYNFATM) (24, 27) or H-2K^b tetramers with OVA were labeled with streptavidin-PE (Beckman Coulter) (24, 25, 27). PBLs and splenocytes were prepared and stained with tetramers and mAbs as before (24, 27). T cells were enriched by magnetic sorting with anti-thy1.2 beads before purification by FACS (MoFlo; DakoCytomation). Naive cells (CD44^lowCD8⁺) were FACS-purified from the spleens of uninfected C57BL/6 mice by staining with anti-CD8 allophycocyanin and anti-CD44 PE Abs. Apoptosis of live cells (propidium iodide-negative) was measured with YOPRO-1 dye (green fluorescence; Molecular Probes), as before (30).

Intracellular staining (ICS) for Spi6 was then detected with anti-rabbit IgG-allophycocyanin (Jackson ImmunoResearch Laboratories). To detect functional memory cells, splenocytes (5 x 10⁶/ml in 0.2 ml) were incubated with either gp33 or OVA peptides (each at 10^–7 M) for 5 h in the presence of Golgi-block and IFN- detected by ICS according to manufacturer’s instructions (BD Pharmingen).

IFN- ELISA

Serum (1 ml) was recovered by cardiac puncture and the level of IFN- determined in dilutions using a sandwich ELISA according to the manufacturer’s instructions (BD Pharmingen).

Real-time PCR

We generated cDNA (27) and performed real-time PCR (27) using primers and probes used are specific for Spi6 (serpin b9, GenBank accession number U96700) (26) GrB (accession number M12302) (5), and cyclophilin A (31) (forward 5'-CCA TCA AAC CAT TCC TTC TGT AGC-3', reverse 5'-AGC AGA GAT TAC AGG ACA TTG CG-3', probe 5'-CAG GAG AGC GTC CCT ACC CCA TCT G-3'). Data were calculated as the ratio of candidate RNA expression per amount of cyclophilin A.

Adoptive transfer

Naive CD8⁺ cells were purified (>90%) from the spleens of P14 mice (CD45.2⁺) by positively sorting with anti-CD8 magnetic beads (Miltenyi Biotec) and adoptively transferred (10⁴) by i.v. injection into C57BL/6 CD45.1 mice and after 1 day infected with LCMV.

Statistics

The significant difference was measured using a two-tailed Student’s t test.

	Results

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Spi6 determines the size of the clonal burst

Several studies have supported a linear differentiation model of memory T cell development in which memory T cells are derived from effectors (8, 9, 16, 32). Given the role played by Spi6 in protecting CTLs from self-inflicted damage (25), we examined the role of Spi6 in memory CD8 T cell development. We determined the effect of Spi6 on the maximal level of CD8 T cells (clonal burst size) by infecting Spi6 KO and wild-type B6 mice with LCMV Armstrong (27) or the attenuated DPL-1942 strain of L. monocytogenes, which had been engineered to express OVA and elicit H-2K^b-restricted peptide Ag (OVA) (28) specific CTL. To avoid the effects of persistent Ag on IFN-driven apoptosis (20), we used low doses of LCMV Armstrong (2 x 10⁵ PFU) and L. monocytogenes DPL-1942 (10⁵ CFU) that result in complete clearance in both B6 and Spi6 KO mice after 8 days. Staining PBLs with gp33/H-2D^b tetramers (Fig. 1A) revealed that the number of CTLs specific for LCMV Armstrong on day 8 was diminished (5-fold lower) in Spi6 KO mice compared with B6 controls (p = 3 x 10^–9) (Fig. 1B). Furthermore, staining with OVA/H-2K^b tetramers (Fig. 1A) showed that Spi6 KO mice harbored approximately nine times (p = 2 x 10^–11) fewer L. monocytogenes-specific CTLs at this earlier time point after infection (Fig. 1E). Staining for changes in nuclear DNA with YOPRO-1 (Fig. 1A) (24, 25, 27, 30, 33) demonstrated that the lower clonal burst size of CD8 T cells in Spi6 KO mice correlated with increased onset of PCD after LCMV (Fig. 1C) or L. monocytogenes (Fig. 1F) infection. These findings are consistent with the decrease in the clonal burst size of LCMV and L. monocytogenes-specific CTLs in the spleen of Spi6 KO mice, which in turn could be corrected by GrB deficiency (25). We conclude that our present study confirms that Spi6 determines clonal burst size by protecting CTLs from GrB-mediated apoptosis.

View larger version (29K): [in this window] [in a new window]   FIGURE 1. Altered survival of CD8 T cells in Spi6 KO mice. A, Flow cytometric analysis of B6 or Spi6 KO mice on day 8 and day 14 after infection with either LCMV Armstrong (2 x 105 PFU/mouse i.p.) or L. monocytogenes DPL-1942-OVA (105 CFU/mouse i.v.). PBLs were stained with either gp33/H-2Db or OVA/H-2Kb tetramer with anti-CD8 and the DNA dye YOPRO-1. Tetramer-positive CD8+ cells were gated and the percentage shown in each plot (upper left corner) and YORPO-1 staining displayed on histograms as the percentage of YOPRO-1high (upper right corner). B, The mean percentage ± SEM of gp33+ CD8+ cells (n = 5 mice) was measured in PBLs, and the mean percentage ± SEM YOPRO-1+ of gp33+ CD8+ (n = 5 mice) was measured on (C) day 8 or (D) day 14 after infection. B6 or Spi6 KO mice were infected with LCMV Armstrong or L. monocytogenes DPL-1942 OVA (105 CFU/mouse i.v.). E, The mean percentage ± SEM of OVA+ CD8+ cells (n = 5 mice) was measured in PBLs, and the mean percentage ± SEM of YOPRO-1+ of OVA+ CD8+ (n = 5 mice) was measured on day 7 (F) or day 15 (G) after infection. H, B6 or Spi6 KO mice were infected with LCMV Armstrong then the mean concentration ± SEM of IFN- (n = 5 mice) was measured in the serum.

After the massive increase in the number of effectors that occurs during the expansion phase, an equally dramatic decrease in the numbers of Ag-specific CD8 T cells occurs in the contraction phase (1). Eight days after the infection of B6 mice we observed contraction in the number of LCMV-specific CD8 T cells and a stable level of memory CD8 T cells after 140 days (Fig. 1B). The severity of the contraction phase was measured by comparing the level of LCMV-specific CD8 T cells on day 8 (8 ± 0.6%, n = 5) by the level after 140 days (1.2 ± 0.6%, n = 5). Thus, similar to several previous studies in B6 mice (11, 14, 24, 25), the level of residual tetramer-positive T cell population in the memory phase was 15% of the clonal burst size after LCMV infection (Fig. 1B) and 10% after L. monocytogenes infection (Fig. 1E).

In Spi6 KO mice, we observed a dramatic difference in the severity of the contraction phase. In contrast to B6 mice, there was a low or negligible loss of CD8 T cells in the contraction phase after infection with either LCMV (Fig. 1B) or L. monocytogenes (Fig. 1E). The absence of cell loss in the contraction phase meant that there was no significant difference (p = 0.1) in the level of either LCMV-specific (Fig. 1B) or L. monocytogenes-specific (Fig. 1E) CD8 T cells in the memory phase compared with the maximal clonal burst size level. This stability in the number of Spi6 KO CD8 T cells after the clonal burst correlated with a reduced proportion undergoing PCD, as evidenced by YOPRO-1 staining (Fig. 1A) on day 14 after LCMV (Fig. 1D) and L. monocytogenes (Fig. 1G) infection.

The inflammatory mediator IFN- is required for the induction of PCD of CD8 T cells in the contraction phase (20, 21). The diminished induction of PCD of LCMV-specific CD8 T cells during the contraction phase correlated with a reduction of IFN- in the serum of Spi6 KO mice during the time of the clonal burst (day 4, Spi6 KO three times lower than B6, p = 2 x 10^–5) and into the contraction phase (day 10, Spi6 KO three times lower than B6, p = 2 x 10^–5) (Fig. 1H). Because CD8 T cells are an important source of IFN- after infection (34), we conclude that the reduction in serum IFN- and PCD in the contraction phase is likely a result of the diminished clonal burst size in Spi6 KO mice.

Cell autonomous effect of Spi6 on CTL survival

Spi6 can protect DCs from granule-mediated killing by CTLs (35) and so defective priming may have caused the diminished clonal burst size in Spi6 KO mice. Therefore we determined whether the effect of Spi6 on CTL survival was specific to CD8 T cells. Spi6 KO mice were crossed with C57BL/6 P14 transgenic mice, which express a TCR specific for the gp33 peptide Ag of LCMV in the context of H-2D^b (36). Naive P14 CD8 T cells (>90% pure) from Spi6 KO and B6 mice (CD45.2⁺) were adoptively transferred into B6 CD45.1 congenic recipients, which were then infected with LCMV. Analysis of splenocytes revealed that the number of donor LCMV-specific CTLs (CD45.2⁺) from Spi6 KO mice was 7-fold lower (p = 3 x 10^–8) on day 5 by 3-fold (p = 0.01) than B6 P14 CD8 donor CTLs on day 8 (Fig. 2A). As we observed in the whole animal experiments (Fig. 1B), we observed a corresponding 2-fold increase (p = 0.04) in the proportion of donor Spi6 KO CTLs undergoing apoptosis prior during the clonal burst phase (Fig. 2B). During the contraction phase, the number of donor Spi6 KO P14 CD8 T cells was no different (p = 0.2) than the number of B6 P14 CD8 T cells (Fig. 2A). The restoration of the level of Spi6 KO P14 CD8 T cells to wild-type levels on day 25 of the contraction phase was likely due to the decrease (p = 0.02) in proportion of cells undergoing apoptosis (Fig. 2B). Therefore both the increase in apoptosis during the clonal burst and the decrease after the contraction phase is due to a cell autonomous effect of Spi6 deficiency on CD8 T cells. The expansion and contraction of Spi6 KO P14 CD8 T cells was exaggerated (Fig. 2, A and B) compared with that of endogenous Spi6 KO CD8 T cells (Fig. 1B). This effect is most likely due to an nonphysiologically high precursor frequency of TCR-transgenic CD8 T cells after adoptive transfer, which other studies have shown gives rise to exaggerated and altered kinetics of T cell expansion and contraction (37, 38). However although the adoptive transfer experiments are less physiologically relevant than those with endogenous T cells, they do point to a cell autonomous affect of Spi6 on CD8 T cell survival.

View larger version (9K): [in this window] [in a new window]   FIGURE 2. The effect of Spi6 on CD8 T cells is cell autonomous. P14 CD8 T cells (104) were purified from B6 or Spi6 KO mice (CD45.2+) and adoptively transferred to B6 CD45.1+ congenic mice, then the mean number of donor LCMV-specific cells (CD45.2+ gp33+ CD8+) (A) and the mean percentage ± SEM of YOPRO-1+ donor cells determined in splenocytes (n = 5 mice) (B). C, The mean concentration ± SEM of IFN- (n = 5 mice) measured in the serum of recipient mice after adoptive transfer and LCMV infection.

Spi6 and memory CD8 T cells

To examine the function of Spi6 in the development of long-term memory cells, we determined the number of memory CD8 T cells in Spi6 KO mice. We quantified LCMV and L. monocytogenes-specific memory CD8 T cells by measuring intracellular IFN- ex vivo after stimulation with peptide Ag (11, 24) (Fig. 3A). We observed no significant difference (p = 0.5) in the number of LCMV (Fig. 3B) or L. monocytogenes-specific (Fig. 3C) memory CD8 T cells in Spi6 KO mice compared with B6 controls. In addition, the number of donor Spi6 KO P14 CD8 memory T cells was the same as wild type (p = 0.4) after adoptive transfer and LCMV infection (Fig. 3D). We conclude that deficiency in Spi6, despite severely reducing clonal burst size does not decrease the number of functional memory CD8 T cells.

View larger version (46K): [in this window] [in a new window]   FIGURE 3. Spi6 and memory CD8 T cells. A, Flow cytometric analysis of spleen cells stimulated ex vivo with peptide Ag 140 days after infection of B6 or Spi6 KO mice with LCMV (i) or 365 days after infection with L. monocytogenes DPL-1942-OVA (ii). Donor CD45.2+ P14 CD8 T cells (104) from B6 or Spi6 KO mice were adoptively transferred to B6 CD45.1 recipients, infected with LCMV, then spleen cells stimulated after 150 days. The percentage of IFN-+ CD8+ cells is shown (upper left corner) for groups i and ii, and for group iii the percentage of IFN-+ CD8+ cells of the CD45.2+ population after gating is shown (upper left corner). In recall experiments, LCMV-infected mice (i and iii) were reinfected on day 320 with the clone 13 variant of LCMV Armstrong (106 PFU/mouse i.v.) and L. monocytogenes-infected mice (ii) were reinfected on day 400 with DPL-1942 OVA (106 CFU/mouse i.v). After 5 days, the percentage of recall IFN-+ CD8+ cells were determined as described. Histograms showing the mean number ± SEM (N = 5 mice) of IFN-+ CD8+ memory cells specific for LCMV (B) or L. monocytogenes (C) are represented. D, Histograms showing the mean ± SEM (n = 5 mice) number of CD45.2+ IFN-+ CD8+ cells derived from donor P14 CD8 T cells from B6 or Spi6 KO mice are shown. Histograms showing the mean number ± SEM (n = 5 mice) of IFN-+ CD8+ recall effectors specific for LCMV (E), L. monocytogenes (F), or LCMV after adoptive transfer of P14 CD8 T cells (G). For LCMV recall responses, the reinfection of recipients harboring P14 CD8 T cells was the same as intact mice in A.

Survival of memory cell precursors is independent of Spi6

The development of Spi6 KO memory CD8 T cells follows a pathway in which the size of the primary memory pool is not proportional to the size of clonal burst (Figs. 1 and 3). These findings suggest that although Spi6 protect CTLs from PCD, it does not play a role in memory cell development. To test this role we determined whether Spi6 was required for the survival of memory CD8 T cell precursors. We used the expression of IL-7R to identify the small population of CTLs (IL-7R^high) that contain the precursors of memory CD8 T cells (22, 23, 24). On d8 after LCMV infection, the percentage IL-7R^high CTLs among gp33⁺ tetramer-specific cells was higher in Spi6 KO mice (14%) than B6 controls (6%) (Fig. 4A). Analysis of Spi6 KO mice (n = 5) revealed a significant increase in percentage of IL-7R^high cells at day 8 (p = 2 x 10^–4) and day 14 (p = 0.02) in comparison to B6 mice (n = 5) after infection (Fig. 4B). However, taking into account the smaller clonal burst, the absolute number of IL-7R^high gp33⁺ CD8⁺ cells in Spi6 KO mice was no different (p = 0.3) from that of wild-type B6 mice (Fig. 4C). Although Spi6 was not required for the survival of memory cell precursors, it was required for the survival of the majority IL-7R^low population, which was reduced by 3-fold on day 8 (p = 4 x 10^–4) and day 14 (p = 0.003) (Fig. 4E). We conclude that Spi6 is required for the survival of the majority of CTLs but not the minority putative memory cell precursor population. Therefore the development of memory CD8 T cells is unaffected in Spi6 KO mice because Spi6 is not required for the survival of memory precursors.

View larger version (17K): [in this window] [in a new window]   FIGURE 4. Spi6 ensures the survival of cytotoxic effectors but not memory cell precursors. Mice were infected with LCMV as in Fig. 1. A, Histograms from flow cytometric analysis of IL-7R expression on gated gp33+CD8+ cells either on day 8 (effectors) or day 140 (memory) after infection. The vertical broken line indicates the median level of IL-7R expression on naive CD44lowCD8+ cells. The horizontal line indicates the population of cells expressing IL-7R above (hi) and below (lo) the mean naive level. The percentage of IL-7Rhigh cells is indicated. On day 8 and day 14 after infection, the mean percentage ± SEM (n = 5 mice) of the IL-7Rhigh for gp33+CD8+ cells (B) and the IL-7Rlow of gp33+CD8+ cells (D), or the mean absolute number ± SEM (n = 5 mice) of the IL-7Rhigh for gp33+ CD8+ cells (C) and the IL-7Rhigh for gp33+ CD8+ cells (E) was determined.

To understand why the survival of memory cell precursors is independent of Spi6 we examined the expression of Spi6 in memory precursor CD8 T cells. ICS with Spi6-specific antiserum (Fig. 5) revealed that Spi6 was up-regulated by 7-fold in day-8 gp33⁺CD8⁺ CTLs from wild-type B6 mice compared with naive CD44^lowCD8⁺ cells from uninfected B6 mice (Fig. 6A). Although the level of Spi6 decreased upon differentiation into memory cells, it was retained at a level of 2-fold higher than naive. The physiological target for the suppression of PCD by Spi6 in CTLs is GrB (25, 27) and so we measured expression by ICS. As expected (9), GrB was 266-fold up-regulated in day-8 CTLs compared with naive cells and retained at a low level in memory CD8 T cells (3-fold higher than naive) (Fig. 6A). Therefore, as we have shown for mRNA levels (27), Spi6 is coordinately up-regulated in CTLs along with GrB, thereby affording protection from self-inflicted damage.

View larger version (8K): [in this window] [in a new window]   FIGURE 5. Spi6-specific antiserum. P14 CTLs from B6 or Spi6 KO mice were subjected to ICS with rabbit anti-Spi6 antiserum (1/1000 dilution) or rabbit preimmune serum (1/1000 dilution), then goat anti-rabbit IgG-allophycocyanin (1/100 dilution). The level of staining of B6 P14 CTLs with the anti-Spi6 antiserum (filled histogram) subtracted for preimmune serum staining (open histogram) is shown in top right corner and was 16 times higher than the level for Spi6 KO P14 CTL. Therefore, the anti-Spi6 antiserum was highly specific for endogenous Spi6.

View larger version (19K): [in this window] [in a new window]   FIGURE 6. Spi6 is down-regulated in CD8 memory T cell precursors. A, B6 mice were infected with LCMV then spleen cells stained and Spi6 and GrB ICS median level of staining (vertical broken line) on gp33+ CD8+ gated cells on day 8 (effectors) or day 756 (memory) after LCMV infection or in naive CD44lowCD8+ cells in uninfected mice is in each panel. B, Median fluorescence from ICS for Spi6 on naive, effector, and memory CD8 T cells. Each diamond is an individual mouse. Horizontal bar is the mean fluorescence from ICS for IL-7Rhigh (n = 5 mice, 609 ± 198) and IL-7Rlow (n = 5 mice, 679 ± 695) day 8 cells. C, Median fluorescence from ICS for GrB on naive, CTLs, and memory CD8 cells. Each diamond is an individual mouse. Horizontal bar is the mean fluorescence from ICS for IL-7Rhigh (Experiment 1, 539 ± 76) and IL-7Rlow (Experiment 2, 301 ± 134) day-8 cells. Expression of Spi6 mRNA (D) and GrB mRNA (E) in FACS purified cells measured by real-time PCR. For day-8 cells, IL-7Rlow (lo) or IL-7Rhigh (hi) cells were analyzed. The data are from two independent experiments with n = 5 () and n = 10 () mice each.

A Spi6^lowGrB^low lineage of memory cell precursors

To determine the cellular basis for the decrease in Spi6 and GrB expression in IL-7R^high memory precursors, we examined LCMV-specific CD8 T cells over time. ICS revealed the presence of a Spi6^low population as early as day 6 after infection of wild-type B6 mice, which became progressively more enriched in the IL-7R^high pool over time (Fig. 7A). Analysis of wild-type B6 mice (n = 3) showed a consistently lower proportion of Spi6^high/Spi6^low cells in the IL-7R^high memory precursor population compared with the IL-7R^low population throughout the clonal burst on day 8 (p = 0.001) and the contraction phase on day 16 (p = 0.002) (Fig. 7B). The corresponding analysis of GrB expression also revealed a GrB^low population enriched in the IL-7R^high pool (Fig. 7A), as evidenced by a significantly (p = 0.003) lower GrB^high to GrB^low ratio on day 8 (Fig. 7B). By day 12, GrB^high cells were rare in both the IL-7R^high and IL-7R^low populations (Fig. 7). The level of Spi6 and GrB expression that marked the Spi6^low (two times higher than naive level) and GrB^low (three times higher than naive level) populations was the same as that in the stable memory pool. We conclude that the reduction in Spi6 and GrB expression in memory cell precursors in the clonal burst is due to the presence of an enriched Spi6^lowGrB^low population. During the contraction phase IL-7R^highSpi6^lowGrB^low memory precursors increase in proportion presumably because they are refractory to the self-inflicted death that results in the removal of the majority IL-7R^lowSpi6^highGrB^high population.

View larger version (28K): [in this window] [in a new window]   FIGURE 7. Memory cell precursors are enriched for Spi6lowGrBlow CD8 T cells. A, B6 mice were infected with LCMV then spleen cells stained and Spi6 and GrB ICS on gp33+CD8+ cells gated for IL-7Rlow (blue) or IL-7Rhigh (red) expression after designated number of days (d) after infection. The percentage of Spi6low or Spi6high and GrBlow or GrBhigh (vertical bar) is indicated. B, Mean ratio ± SEM (n = 3 mice) of the percentages of Spi6high to Spi6low or GrBhigh to GrBlow of IL-7Rhigh cells (•) or IL-7Rlow cells () over time after infection.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

View larger version (9K): [in this window] [in a new window]   FIGURE 8. Spi6 is required for the clonal burst but not the development of memory cells. In wild-type CTLs Spi6 suppresses the activity of GrB in the cytoplasm and prevents the death of CTLs thus maintaining the size of the CD8 T cell clonal burst (outer circle). IFN- produced by the CD8 T cell clonal burst causes death and cell loss during the contraction phase. GrB induces the death of CTLs in Spi6 KO mice reducing the size of the clonal burst but also the production of IFN-. This result manifests in negligible cell loss in the contraction phase. Within the clonal burst is a subpopulation of IL-7Rhigh memory cells precursors that have low expression of GrB and Spi6 and so their survival is unaffected in Spi6 KO mice. Therefore, the size of the memory precursor and primary memory pool in Spi6 KO mice is the same as in wild-type mice.

The linear differentiation model of memory T cell development predicts that memory T cells at some point are derived from CTLs (8, 9, 16, 32). The enrichment of the IL-7R^high population with CD8 T cells with reduced GrB expression seems to suggest that memory precursors are not fully differentiated effectors. However, the expression level of GrB and Spi6 in memory precursors is still twice that of naive CD8 T cells and equivalent to memory CD8 T cells (Figs. 6 and 7). In addition, memory CD8 T cells express the gene encoding the Fas ligand cytotoxic molecule at a higher level than bona fide CTLs reinforcing the view that memory cells are within the cytotoxic cell lineage (24). Therefore, the precursors of memory cells are more likely a subset of GrB^lowSpi6^low effectors rather than a true non-CTL-activated CD8 T cell.

Additional evidence that argues against the parallel development of Grb^lowSpi6^low memory precursors and GrB^high Spi6^high CTLs comes from the analysis of GrB expression throughout CD8 T cell expansion and contraction after LCMV infection. Although there is a discrete population of GrB^low cells as early as day 6 after LCMV infection, the proportion of these cells decreases on day 8, then increases sharply during the contraction phase on day 12 and day 16 (Fig. 7A). Therefore, we do not think that the GrB^low population we propose as memory cell precursors represents a lineage of noneffectors that differentiate into memory cell in parallel lineage to effectors because if this were so we would expect the proportion to increase from day 6 to day 8. Rather, it would seem likely that the development of the Spi6^lowGrB ^low memory precursor population is due to the down-regulation of GrB after day 8 preferentially in IL-7R^high cells and the possible enrichment for GrB by escape from PCD. Because lowered Spi6 expression would serve no conceivable advantage for CTLs avoiding PCD, we propose that it is actively down-regulated in IL-7R^highGrB^low cells. Examination of the expression of the perforin effector molecule in TCR transgenic CTLs in vitro did not reveal an equivalent perforin^low population (8). This may be because perforin^low memory cell precursors may only develop under the same conditions that produced GrB^low cells, that is to say in vivo activation by infection from a physiological level of naive precursors that express endogenous TCRs. Our findings with CD8 T cells are consistent with those with Th1 CD4 T cells, which indicate that memory cells are derived from effectors that express low levels of IFN- (41).

In summary, we provide evidence that the development of memory CD8 T cells requires the suppression of biochemical pathways distinct from those that control the size of the clonal burst of CTLs. An attractive strategy to provide immunity to some viruses is to enhance CTL function by protection from PCD. Our findings give a molecular explanation for the independence of memory cell development from survival factors that govern clonal burst size and in turn predict that successful vaccines that give rise to long-term memory will do more that just protect CTLs from death.

	Acknowledgments

 
We thank R. Welsh for high titer stocks of LCMV Armstrong, C.-R. Wang for help with L. monocytogenes infections, D. Tharpe for help in preparing the manuscript, and L. Simpson for critical reading and comments.

	Disclosures

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
The authors have no financial conflict of interest.

	Footnotes

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ This work was supported by the National Institutes of Health Grant AI45108 (to P.G.A.-R.).

² Current address: Department of Immunology, Division of Medicine, Imperial College London, Hammersmith Campus, Du Cane Road, W12 0NN London, U.K.

³ Address correspondence and reprint requests to Dr. Philip G. Ashton-Rickardt at the current address: Department of Immunology, Division of Medicine, Imperial College London, Hammersmith Campus, Du Cane Road, W12 0NN London, U.K. E-mail address: p.ashton-rickardt{at}imperial.ac.uk

⁴ Abbreviations used in this paper: GrB, granzyme B; PCD, programmed cell death; LCMV, lymphocytic choriomeningitis virus; ICS, intracellular staining; Spi6, serine protease inhibitor 6; KO, knockout.

Received for publication August 11, 2006. Accepted for publication January 5, 2007.

	References

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 

1. Sprent, J., C. D. Surh. 2002. T cell memory. Annu. Rev. Immunol. 20: 551-579. [Medline]
2. Kagi, D., F. Vignaux, B. Ledermann, K. Burki, V. Depraetere, S. Nagata, H. Hengartner, P. Golstein. 1994. Fas and perforin pathways as major mechanisms of T cell-mediated cytotoxicity. Science 265: 528-530. [Abstract/Free Full Text]
3. Podack, E. R., J. D. Young, Z. A. Cohn. 1985. Isolation and biochemical and functional characterization of perforin 1 from cytolytic T-cell granules. Proc. Natl. Acad. Sci. USA 82: 8629-8633. [Abstract/Free Full Text]
4. Kagi, D., B. Ledermann, K. Burki, P. Seiler, B. Odermatt, K. J. Olsen, E. R. Podack, R. M. Zinkernagel, H. Hengartner. 1994. Cytotoxicity mediated by T cells and natural killer cells is greatly impaired in perforin-deficient mice. Nature 369: 31-37. [Medline]
5. Heusel, J. W., R. L. Wesselschmidt, S. Shresta, J. H. Russell, T. J. Ley. 1994. Cytotoxic lymphocytes require granzyme B for the rapid induction of DNA fragmentation and apoptosis in allogeneic target cells. Cell 76: 977-987. [Medline]
6. Revell, P. A., W. J. Grossman, D. A. Thomas, X. Cao, R. Behl, J. A. Ratner, Z. H. Lu, T. J. Ley. 2005. Granzyme B and the downstream granzymes C and/or F are important for cytotoxic lymphocyte functions. J. Immunol. 174: 2124-2131. [Abstract/Free Full Text]
7. Russell, J. H., T. J. Ley. 2002. Lymphocyte-mediated cytotoxicity. Annu. Rev. Immunol. 20: 323-370. [Medline]
8. Opferman, J. T., B. T. Ober, P. G. Ashton-Rickardt. 1999. Linear differentiation of cytotoxic effectors into memory T lymphocytes. Science 283: 1745-1748. [Abstract/Free Full Text]
9. Kaech, S. M., S. Hemby, E. Kersh, R. Ahmed. 2002. Molecular and functional profiling of memory CD8 T cell differentiation. Cell 111: 837-851. [Medline]
10. Hou, S., L. Hyland, K. W. Ryan, A. Portner, P. C. Doherty. 1994. Virus-specific CD8⁺ T-cell memory determined by clonal burst size. Nature 369: 652-654. [Medline]
11. Murali-Krishna, K., J. D. Altman, M. Suresh, D. J. D. Sourdive, A. J. Zajac, J. D. Miller, J. Slansky, R. Ahmed. 1998. Counting antigen-specific CD8 T cells: a reevaluation of bystander activation during viral infection. Immunity 8: 177-187. [Medline]
12. Butz, E. A., M. J. Bevan. 1998. Massive expansion of antigen-specific CD8⁺ T cells during an acute virus infection. Immunity 8: 167-175. [Medline]
13. Busch, D. H., I. M. Pilip, S. Vijh, E. G. Pamer. 1998. Coordinate regulation of complex T cell populations responding to bacterial infection. Immunity 8: 353-362. [Medline]
14. Badovinac, V. P., B. B. Porter, J. T. Harty. 2002. Programmed contraction of CD8⁺ T cells after infection. Nat. Immunol. 3: 619-626. [Medline]
15. Homann, D., L. Teyton, M. B. Oldstone. 2001. Differential regulation of antiviral T-cell immunity results in stable CD8+ but declining CD4⁺ T-cell memory. Nat. Med. 7: 913-919. [Medline]
16. Jacob, J., D. Baltimore. 1999. Modelling T-cell memory by genetic marking of memory T cells in vivo. Nature 399: 593-597. [Medline]
17. Kagi, D., B. Odermatt, T. W. Mak. 1999. Homeostatic regulation of CD8⁺ T cells by perforin. Eur. J. Immunol. 29: 3262-3272. [Medline]
18. Spaner, D., K. Raju, B. Rabinovich, R. G. Miller. 1999. A role for perforin in activation-induced T cell death in vivo: increased expansion of allogeneic perforin-deficient T cells in SCID mice. J. Immunol. 162: 1192-1199. [Abstract/Free Full Text]
19. Badovinac, V. P., S. E. Hamilton, J. T. Harty. 2003. Viral infection results in massive CD8⁺ T cell expansion and mortality in vaccinated perforin-deficient mice. Immunity 18: 463-474. [Medline]
20. Badovinac, V. P., A. R. Tvinnereim, J. T. Harty. 2000. Regulation of antigen-specific T cell homeostasis by perforin and interferon-. Science 290: 1354-1357. [Abstract/Free Full Text]
21. Badovinac, V. P., B. B. Porter, J. T. Harty. 2004. CD8⁺ T cell contraction is controlled by early inflammation. Nat. Immunol. 5: 809-817. [Medline]
22. Madakamutil, L. T., U. Christen, C. J. Lena, Y. Wang-Zhu, A. Attinger, M. Sundarrajan, W. Ellmeier, M. G. von Herrath, P. Jensen, D. R. Littman, H. Cheroutre. 2004. CD8-mediated survival and differentiation of CD8 memory T cell precursors. Science 304: 590-593. [Abstract/Free Full Text]
23. Kaech, S. M., J. T. Tan, E. J. Wherry, B. T. Konieczny, C. D. Surh, R. Ahmed. 2004. Selective expression of the interferon 7 receptor identifies effector CD8 T cells that give rise to long-lived memory cells. Nat. Immunol. 4: 1191-1198.
24. Liu, N., T. Phillips, M. Zhang, Y. Wang, J. T. Opferman, R. Shah, P. G. Ashton-Rickardt. 2004. Serine protease inhibitor 2A is a protective factor for memory T cell development. Nat. Immunol. 5: 919-926. [Medline]
25. Zhang, M., S. M. Park, Y. Wang, R. Shah, N. Liu, A. E. Murmann, C. R. Wang, M. E. Peter, P. G. Ashton-Rickardt. 2006. Serine protease inhibitor 6 protects cytotoxic T cells from self-inflicted injury by ensuring the integrity of cytotoxic granules. Immunity 24: 451-461. [Medline]
26. Sun, J., L. Ooms, C. H. Bird, V. R. Sutton, J. A. Trapani, P. I. Bird. 1997. A new family of 10 murine ovalbumin serpins includes two homologs of proteinase inhibitor 8 and two homologs of the granzyme B inhibitor (proteinase inhibitor 9). J. Biol. Chem. 272: 15434-15441. [Abstract/Free Full Text]
27. Phillips, T., J. T. Opferman, R. Shah, N. Liu, C. J. Froelich, P. G. Ashton-Rickardt. 2004. A role for the granzyme B inhibitor serine protease inhibitor 6 in CD8⁺ memory cell homeostasis. J. Immunol. 173: 3801-3809. [Abstract/Free Full Text]
28. Pope, C., S. K. Kim, A. Marzo, D. Masopust, K. Williams, J. Jiang, H. Shen, L. Lefrancois. 2001. Organ-specific regulation of the CD8 T cell response to Listeria monocytogenes infection. J. Immunol. 166: 3402-3409. [Abstract/Free Full Text]
29. Ahmed, R., A. Salmi, L. D. Butler, J. M. Chiller, M. B. A. Oldstone. 1984. Selection of genetic variants of lymphocytic choriomeningitis virus in spleens of persistently infected mice: role in suppression of cytotoxic T lymphocyte response and viral persistence. J. Exp. Med. 60: 521-540.
30. Opferman, J. T., B. T. Ober, R. Narayanan, P. G. Ashton-Rickardt. 2001. Suicide induced by cytolytic activity controls the differentiation of memory CD8⁺ T lymphocytes. Int. Immunol. 13: 411-419. [Abstract/Free Full Text]
31. Medhurst, A., D. C. Harrison, S. J. Read, C. A. Campbell, M. J. Robbins, M. N. Pangalos. 2000. The use of TaqMan RT-PCR assays for semiquantitative analysis of gene expression in CNS tissues and disease models. J. Neurosci. Methods 98: 9-20. [Medline]
32. Hu, H., G. Huston, D. Duso, N. Lepak, E. Roman, S. L. Swain. 2001. CD4⁺ T cell effectors can become memory cells with high efficiency and without further division. Nat. Immunol. 2: 705-710. [Medline]
33. Idziorek, T., J. Estaquier, F. De Bels, J.-C. Ameisen. 1995. YOPRO-1 permits cytofluorometric analysis of programmed cell death (apoptosis) without interfering with cell viability. J. Immunol. Methods 185: 249-258. [Medline]
34. Schroder, K., P. J. Hertzog, T. Ravasi, D. A. Hume. 2004. Interferon-: an overview of signals, mechanisms and functions. J. Leukocyte Biol. 75: 163-189. [Abstract/Free Full Text]
35. Medema, J. P., D. H. Schuurhuis, D. Rea, J. van Tongeren, J. de Jong, S. A. Bres, S. Laban, R. E. M. Toes, M. Toebes, T. N. M. Schumacher, et al 2001. Expression of the serpin serine protease inhibitor 6 protects dendritic cells from cytotoxic T lymphocyte-induced apoptosis: differential modulation by T helper type 1 and type 2 cells. J. Exp. Med. 194: 657-667. [Abstract/Free Full Text]
36. Pircher, H., D. Moskophidis, U. Rohrer, K. Burki, H. Hengartner, R. M. Zinkernagel. 1990. Viral escape by selection of cytotoxic T cell-resistant virus variants in vivo. Nature 346: 629-633. [Medline]
37. Hataye, J., J. J. Moon, A. Khoruts, C. Reilly, M. K. Jenkins. 2006. Naive and memory CD4⁺ T cell survival controlled by clonal abundance. Science 312: 114-116. [Abstract/Free Full Text]
38. Marzo, A. L., K. D. Klonowski, A. Le Bon, P. Borrow, D. F. Tough, L. Lefrancois. 2005. Initial T cell frequency dictates memory CD8⁺ T cell lineage commitment. Nat. Immunol. 6: 793-799. [Medline]
39. Zajac, A. J., J. M. Dye, D. G. Quinn. 2003. Control of lymphocytic choriomeningitis virus infection in granzyme B deficient mice. Virology 305: 1-9. [Medline]
40. Cannarile, M. A., N. A. Lind, R. Rivera, A. D. Sheridan, K. A. Camfield, B. B. Wu, K. P. Cheung, Z. Ding, A. W. Goldrath. 2006. Transcriptional regulator Id2 mediates CD8⁺ T cell immunity. Nat. Immunol. 7: 1317-1325. [Medline]
41. Wu, C. Y., J. R. Kirman, M. J. Rotte, D. F. Davey, S. P. Perfetto, E. G. Rhee, B. L. Freidag, B. J. Hill, D. C. Douek, R. A. Seder. 2002. Distinct lineages of Th1 cells have differential capacities for memory cell generation in vivo. Nat. Immunol. 3: 852-858. [Medline]

This article has been cited by other articles:

				D. Usharauli and T. Kamala Brief Antigenic Stimulation Generates Effector CD8 T Cells with Low Cytotoxic Activity and High IL-2 Production J. Immunol., April 1, 2008; 180(7): 4507 - 4513. [Abstract] [Full Text] [PDF]

				S. Sarkar, V. Kalia, W. N. Haining, B. T. Konieczny, S. Subramaniam, and R. Ahmed Functional and genomic profiling of effector CD8 T cell subsets with distinct memory fates J. Exp. Med., March 17, 2008; 205(3): 625 - 640. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Zhang, M. Articles by Ashton-Rickardt, P. G. Search for Related Content PubMed PubMed Citation Articles by Zhang, M. Articles by Ashton-Rickardt, P. G.