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Functional Analysis of B and T Lymphocyte Attenuator Engagement on CD4⁺ and CD8⁺ T Cells¹

Department of Immunology, The Scripps Research Institute, La Jolla, CA 92037

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
T cell activation can be profoundly altered by coinhibitory and costimulatory molecules. B and T lymphocyte attenuator (BTLA) is a recently identified inhibitory Ig superfamily cell surface protein found on lymphocytes and APC. In this study we analyze the effects of an agonistic anti-BTLA mAb, PK18, on TCR-mediated T cell activation. Unlike many other allele-specific anti-BTLA mAb we have generated, PK18 inhibits anti-CD3-mediated CD4⁺ T cell proliferation. This inhibition is not dependent on regulatory T cells, nor does the Ab induce apoptosis. Inhibition of T cell proliferation correlates with a profound reduction in IL-2 secretion, although this is not the sole cause of the block of cell proliferation. In contrast, PK18 has no effect on induction of the early activation marker CD69. PK18 also significantly inhibits, but does not ablate, IL-2 secretion in the presence of costimulation as well as reduces T cell proliferation under limiting conditions of activation in the presence of costimulation. Similarly, PK18 inhibits Ag-specific T cell responses in culture. Interestingly, PK18 is capable of delivering an inhibitory signal as late as 16 h after the initiation of T cell activation. CD8⁺ T cells are significantly less sensitive to the inhibitory effects of PK18. Overall, BTLA adds to the growing list of cell surface proteins that are potential targets to down-modulate T cell function.

	Introduction

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T cell specificity results from TCR-mediated recognition of specific Ag in conjunction with MHC on APCs (1). However, the functional outcome of this initial TCR engagement is modulated by secondary signals, which can have costimulatory or coinhibitory functions. The group of coinhibitory molecules includes CTLA-4 and programmed cell death-1 interacting with CD80 and CD86 or PD-L1 and PD-L2, respectively (reviewed in Ref.2).

We recently cloned a gene from differentiating thymocytes that encodes a member of the Ig superfamily of cell surface proteins (3). This protein, independently isolated from Th1 cells, has been named B and T lymphocyte attenuator (BTLA)³ (4). BTLA is most highly expressed by B cells, followed by T cells and APC (3), although its expression on macrophages has recently been reported to differ between mouse strains (5). The cytoplasmic tail of BTLA contains ITIM motifs, suggesting an inhibitory function for the protein. Indeed, lymphocytes from BTLA-deficient mice were found to be hyper-responsive to anti-CD3-mediated proliferation (3, 4). In contrast to CTLA-4 and programmed cell death-1, which are induced during T cell activation, BTLA is constitutively expressed on naive T cells and is further up-regulated upon T cell activation (3). Although BTLA was thought originally to be an additional member of the B7 family-recognizing T cell surface proteins, it has recently been demonstrated that herpes virus entry mediator (HVEM), a known ligand for the TNF family member LIGHT (derived from homologous to lymphotoxin, inducible expression), is the ligand for BTLA (6, 7). Like BTLA, HVEM is expressed by T and B cells although the hierarchy of expression on naive cells is reversed from that of BTLA (i.e., T>B) (8). A soluble form of HVEM has been shown to inhibit anti-CD3-induced proliferation of CD4⁺ T cells, and this effect could be reversed by anti-BTLA Ab (7). In addition, T cells from HVEM-deficient mice are hyperproliferative in response to Con A (9). Together, these data are consistent with a coinhibitory signal mediated by a BTLA-HVEM interaction.

We previously generated a panel of BTLA-specific mAb that preferentially react with the BTLA.2 allelic form of the protein (3). In this study we further characterize the functional properties of one of these Abs, PK18. This Ab has agonistic properties that allow analysis of the effects of BTLA activation and proliferation of naive CD4⁺ and CD8⁺ T cells.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Animals

C57BL/6J (B6), BALB.K, BTLA-deficient (BTLA^–/–), and AND TCR-transgenic (Tg) mice on an H-2^b background (10) were used in these studies. All animals were bred at The Scripps Research Institute and maintained under specific pathogen-free conditions. Experiments were conducted in accordance with National Institutes of Health Guidelines for the Care and Use of Animals and with an approved animal protocol from The Scripps Research Institute animal care and use committee.

Abs and flow cytometry

BTLA-specific rat mAb PK3 (IgM), PK18 (IgG1), and mouse mAb PJ196 (IgG1) were used in these studies. The production of mAb was described previously (3). The following additional Abs were used (all from eBioscience, unless stated otherwise): FITC- or APC-conjugated anti-CD8 (clone 53-6.7), PE-conjugated anti-CD3 (clone 145-2C11), PE- or allophycocyanin-conjugated anti-CD4 (clone RM4-5), biotinylated anti-CD69 (clone 1.2F3), and allophycocyanin-conjugated anti-CD25 (clone PC61.5). Secondary staining reagents included PE-conjugated anti-rat IgM (clone G5-238; BD Pharmingen) and PE-labeled streptavidin (Biomeda). Cell surface staining was performed as described previously (3). In some instances cells were preincubated with anti-CD16/CD32 to block FcRs. For the study of T cell apoptosis, the annexin V-FITC apoptosis detection kit was used according to manufacturer’s instructions (BD Pharmingen). Briefly, T cells were washed with ice-cold PBS (Invitrogen Life Technologies), resuspended in annexin V-binding buffer (10 mM HEPES/NaOH (pH 7.4), 140 mM NaCl, and 2.5 mM CaCl₂), stained with annexin V-FITC and -propidium iodide, and assayed within 1 h by flow cytometry. As a positive control, T cell apoptosis was induced by dexamethasone (100 nM; Sigma-Aldrich). At least 20,000 viable cells were live-gated on a FACSCalibur or digital LSRII using CellQuest software (BD Biosciences) and were analyzed using FlowJo software (TriStar).

T cell preparation

All culture experiments were performed in Click’s medium (Irvine) containing 10% heat-inactivated FCS (Invitrogen Life Technologies), penicillin/streptomycin (Invitrogen Life Technologies), 200 mM glutamine, and 50 µM 2-ME (Sigma-Aldrich). In some cultures anti-CD28 (clone 37.51; eBioscience) was used at a concentration of 10 µg/ml, or recombinant murine IL-2 (eBioscience) was added at various concentrations. Cells were cultured under standard conditions at 37°C in 5% CO₂. T cells from spleens or lymph nodes were enriched by negative selection using anti-B220 (clone RA3-6B2; eBioscience), anti-A^b class II MHC (clone Y3P) Abs, and anti-rat IgG magnetic beads (Qiagen). For Ag-specific proliferation assays, AND TCR-Tg mice were used as an enriched source of naive CD4⁺ T cells. For CD4⁺ T cell enrichments anti-CD8 (clone 53-6.7; eBioscience), Ab was added to the mixture. The purity of the resultant cell populations was >95%. In some experiments, naive CD4⁺CD25^– T cells were purified by sorting on a FACSDiva or FACSAria (BD Biosciences) to a purity of >99%.

CFSE labeling

Total T cells were washed with PBS, resuspended at a density of 1 x 10⁷ cells/ml in PBS containing 2 µM CFSE (Molecular Probes), and incubated for 5 min at room temperature. Labeling was terminated by addition of FCS to a final concentration of 10%, and cells were washed once in culture medium. The frequency of CD4⁺ or CD8⁺ T cell precursors that were activated to divide was calculated as the number of CFSE⁺ cells in each division/2ⁿ, where n is the number of divisions, divided by the input number of cells.

T cell activation

A total of 1 x 10⁶ T cells/ml were cultured in 100 µl or 1 ml in 96- or 24-well, flat-bottom plates, respectively, coated with 1:1 ratios of anti-CD3 (clone 145-2C11; eBioscience) in combination with rat IgG (Jackson ImmunoResearch Laboratories), PK18, or PJ196 at the indicated total Ig concentration. In some experiments, T cells were stimulated with a combination of 50 ng/ml PMA and 500 ng/ml ionomycin (Sigma-Aldrich). For analysis of Ag-specific T cell proliferation, CD4⁺ T cells were cultured at 5 x 10⁵ cells/ml with 2 x 10⁶ cells/ml irradiated (3300 rad) BALB.K splenocytes in the presence of 100 nM pigeon cytochrome c peptide. For proliferation studies, T cells were cultured in 96-well plates for a total of 72 h and pulsed with 1 µCi/well [³H]thymidine (PerkinElmer) for the last 16 h. Cells were harvested onto glass-fiber filters (Brandel), and [³H]thymidine incorporation was determined. To analyze T cell activation markers, cultures were harvested at various times and were analyzed by flow cytometry. In other experiments, CFSE-labeled total T cells were stimulated for 72 h and then analyzed.

IL-2 ELISA

Culture supernatants were assayed for mouse IL-2 using a standard sandwich ELISA (eBioscience). Maxisorb plates (Nunc) were coated with anti-IL-2 mAb (clone JES6-1A12), and detection was performed using the corresponding biotinylated mAb. The plates were developed using streptavidin-HRP and tetramethxylbenzidine as substrate. Plates were read on a plate reader at 450 nm, and data were analyzed using Softmax software (reader and software from Molecular Devices). Samples were performed in duplicate. The assay was standardized with recombinant murine IL-2, and detection ranged from 1 to 1000 pg/ml.

Cell transfection and mutagenesis

Jurkat T cells were transfected with a construct encoding murine BTLA-yellow fluorescent protein (YFP) fusion protein (base vector pEYFP-N1; BD Clontech) by electroporation and were stained and analyzed by flow cytometry on day 2. PK18 does not stain untransfected Jurkat T cells. Site-specific mutations were made using the GeneTailor Site-Directed Mutagenesis System (Invitrogen Life Technologies) according to the manufacturer’s instructions. All mutant constructs were sequence verified (TSRI Center for Nucleic Acids Research).

	Results

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Characterization of BTLA-specific mAb

We previously generated BTLA-specific mAb by immunizing rats or mice with a recombinant soluble form of the protein (3). All Abs generated reacted preferentially with BTLA expressed on cells derived from B6, but not BALB/c, mice, the results of allelic variation in the BTLA external domain (3). We also demonstrated that coimmobilized rat anti-BTLA mAb PK18 is a potent inhibitor of anti-CD3 Ab-induced T cell proliferation (3) (Fig. 1A). Soluble anti-BTLA Ab PK18 also significantly inhibited proliferation of CD4⁺ T cells at limiting concentrations of plate bound anti-CD3 Ab (Fig. 1B). As a control, PK18 had no effect on the proliferation of CD4⁺ T cells derived from BTLA-deficient mice (Fig. 1B). The PK18-mediated inhibition of T cell proliferation is not due to altered kinetics of the response (Fig. 1C). Seven additional mAb (one rat- and six mouse-derived) had no effect on (or, in some experiments, enhanced) T cell proliferation (for example, Ab PJ196 in Fig. 1A). The inability of other anti-BTLA Abs to inhibit T cell proliferation is not due to poor binding. In fact, PJ196 stains cells brightly even at extremely low concentrations of Ab, whereas PK18 is, somewhat surprisingly, a relatively poor staining reagent (data not shown). This suggested that PK18 and other Abs, such as PJ196, might differ in the respective epitopes on BTLA recognized.

View larger version (29K): [in this window] [in a new window]   FIGURE 1. Characterization of anti-BTLA mAb. A, T cells were cultured in plates coated with equal concentrations of anti-CD3 and rat IgG (), anti-CD3 and PK18 (), or anti-CD3 and PJ196 (). Concentrations refer to total IgG. Data are expressed as the mean [3H]thymidine incorporation of triplicate cultures (±SD) minus the cpm of T cells cultured alone. B, CD4+ T cells isolated from BTLA–/– mice (top graph) or B6 mice (bottom graph) were stimulated with the indicated concentrations of plate-bound anti-CD3 in the presence of soluble rat IgG () or soluble PK18 (•) at a concentration of 60 µg/ml. Proliferation was determined by [3H]thymidine incorporation, as described in A. C, T cells were stimulated with anti-CD3 and rat IgG () or anti-CD3 and PK18 (). [3H]Thymidine incorporation was determined at the indicated times as described in A. D, Jurkat T cells were transfected with constructs encoding a fusion of the wt or mutant BTLA.2 extracellular domain and YFP. Cells were stained with PK3, PK18, or PJ196 mAb as indicated and were analyzed by flow cytometry. The histograms shown are gated on a narrow range of YFP expression. Isotype control staining is shown as thin lines. Results are representative of three experiments.

The cell surface expression of BTLA-YFP was quite variable between individual transfected cells despite similar expression of YFP (data not shown). Whether this reflects tight regulation of cell surface transport of the BTLA protein or a property of this particular fusion protein is not known. Nevertheless, cells were gated for a narrow range of expression of YFP, and then anti-BTLA mAb staining was assessed. All 10 mutant proteins were expressed on the cell surface (i.e., at least one anti-BTLA Ab could bind at near wild-type (wt) levels), but only three had significantly reduced PK18 staining compared with cells expressing wt BTLA-YFP (Fig. 1D and data not shown). Mutation of residue 41 from BTLA.2 to BTLA.1 (P41E) completely abolished binding of PK18, whereas C85W and T45N/T47K mutations had lesser effects on Ab binding. Binding of PJ196 to mutant 45/47 was also reduced, as was binding to mutant 41, although to a somewhat lesser extent. A more modest reduction in binding of PJ196 to the 85 mutant was also observed. Staining of Ab PK3 to all three mutants is also shown for comparison, with little reduction in staining to mutants 41 and 45/47, and modest reduction in staining to mutant 85 (Fig. 1D). Together, the data indicate that PK18 and PJ196 have overlapping, but distinct, epitopes that probably account for their distinct biological activities.

Differential effects of BTLA-specific mAb on CD4⁺ and CD8⁺ T cell proliferation

To better understand the functional consequences of BTLA engagement on CD4⁺ and CD8⁺ T cells, we took advantage of the agonistic ability of the PK18 mAb. T cells were labeled with CFSE and stimulated for 3 days with anti-CD3 in combination with PK18 or control rat IgG. The CFSE profile of total T cells revealed an almost complete block of T cell proliferation, consistent with results obtained by thymidine uptake (Fig. 2A). However, when CD4⁺ and CD8⁺ T cells were individually analyzed in these assays, there was a near complete block of CD4⁺ T cell proliferation, whereas a significant proportion of CD8⁺ T cells had divided (Fig. 2A). From these data we also calculated the precursor frequency of cells that were activated to divide in these cultures (Fig. 2A). Only 2.2% of CD4⁺ precursor T cells underwent proliferation when activated by anti-CD3 in the presence of PK18, compared with 33.3% in control cultures. Moreover, the few CD4⁺ cells that did proliferate underwent a single division after anti-CD3 and PK18 stimulation, compared with up to three divisions in control cultures. In contrast, 57.9 and 28.5% of CD8⁺ precursors proliferated in the presence of anti-CD3 and rat IgG or PK18, respectively, and some cells underwent three or four divisions even in the presence of PK18.

View larger version (22K): [in this window] [in a new window]   FIGURE 2. Differential effects of BTLA engagement on CD4+ and CD8+ T cells. A, CFSE-labeled T cells were cultured in the presence of anti-CD3 and rat IgG () or anti-CD3 and PK18 (). Plate-bound Abs were used at 20 µg/ml total Ig. On day 3 of culture, cells were stained for CD4 or CD8 and were assayed by flow cytometry. The distributions of precursor cell divisions in anti-CD3 and rat IgG () or anti-CD3 and PK18 () were also calculated. One representative experiment of four is displayed. B, T cells were cultured in medium () or were stimulated for various times, as shown, with anti-CD3 (bold lines) or anti-CD3 and anti-CD28 (dotted lines). Thin lines and vertical bars indicate isotype controls. T cells were stained for CD4, CD8, and BTLA, the latter using the PK3 mAb, and were analyzed by flow cytometry. One representative experiment of three is shown.

PK18-mediated inhibition of T cell activation does not involve regulatory T cells or induction of apoptosis

It was possible that the failure of CD4⁺ T cells to proliferate in the presence of PK18 was due to the induction of cell death. However, no significant loss of cell number was observed in PK18-treated cultures (data not shown). In addition, no increase in apoptotic cells as assessed by propidium iodide/annexin V staining was observed after activation of CD4⁺ T cells for 6 h with anti-CD3 in the presence of PK18 compared with that in cells activated in control cultures (Fig. 3A). Analysis 16 h after stimulation yielded similar results (data not shown).

View larger version (16K): [in this window] [in a new window]   FIGURE 3. PK18-mediated inhibition does not involve induction of apoptosis or activation of Treg. A, T cells were activated in the presence or the absence of PK18 as described in Fig. 1. Apoptosis was measured after 6 h by propidium iodide/annexin V staining. As controls, apoptosis was also analyzed in the presence of dexamethasone or PMA and ionomycin. Bars represent the mean and SD of three independent experiments. B, Sorted CD4+CD25– T cells were activated by anti-CD3 and rat IgG () or anti-CD3 and PK18 (), and resulting proliferation was assessed as described in Fig. 1. Results are representative of three experiments.

IL-2 production, but not CD69 induction, is suppressed by BTLA engagement

Induction of proliferation is a relatively late event after T cell activation. To determine whether PK18 blocked all signals mediated by TCR engagement, we asked whether PK18 prevented the induction of other T cell activation markers. Interestingly, the induction of CD69 expression on both CD4⁺ and CD8⁺ T cells was not inhibited by PK18 (Fig. 4). In contrast, BTLA engagement led to inhibition of subsequent IL-2R (CD25) expression on both CD4⁺ and CD8⁺ T cells (Fig. 4). However, the decrease in CD25 expression was more pronounced on CD4⁺ T cells, consistent with the greater sensitivity of this population to PK18-mediated inhibition of proliferation. The increased frequency of CD25^– T cells, particularly pronounced among CD8⁺ T cells, was due to reduced proliferation in the presence of PK18 and, thus, increased frequency of unactivated cells in these cultures. Because IL-2 is necessary for T cell proliferation in vitro as well as for maintenance of IL-2R expression (12), these results suggested that the primary defect in anti-BTLA engagement could be cytokine production. Indeed, anti-CD3- and PK18-stimulated T cells showed a 80-fold reduction in IL-2 secretion compared with anti-CD3- and rat IgG-stimulated T cells (Fig. 5A).

View larger version (27K): [in this window] [in a new window]   FIGURE 4. PK18 inhibits the expression of CD25, but not CD69. T cells were stimulated, as described in Fig. 2, with anti-CD3 and rat IgG () or anti-CD3 and PK18 (bold lines). Shown is expression of CD69 or CD25 after 16 or 48 h in culture, respectively, on gated populations of CD4+ or CD8+ T cells. Vertical bars indicate isotype controls. Experiments were repeated three times.

View larger version (14K): [in this window] [in a new window]   FIGURE 5. BTLA engagement inhibits IL-2 secretion. A, Supernatants were collected 16 h after stimulation by anti-CD3 in the presence of rat IgG or PK18 (as described in Fig. 2) and were analyzed for IL-2 secretion. B, T cells were stimulated in the presence or the absence of PK18, as described in A, with the addition in some cultures of the indicated concentration of recombinant murine IL-2. Proliferation was assessed as described in Fig. 1. C, T cells were stimulated with anti-CD3 and rat IgG () or anti-CD3 and PK18 (bold lines) with the addition of recombinant murine IL-2 (800 pg/ml, high IL-2; 80 pg/ml, low IL-2). On day 2 of culture, cells were harvested, and gated populations of CD4+ and CD8+ T cells were analyzed for the expression of CD25 by flow cytometry. One representative experiment of three is shown.

CD28 costimulation partially overcomes inhibition of T cell activation and proliferation by BTLA engagement

CD28 costimulation is a strong enhancer of IL-2 production in T cells (13) and thus might be expected to overcome PK18 inhibition. At low concentrations of anti-CD3, PK18 was still inhibitory, even in the presence of CD28 (Fig. 6A). However, at higher concentrations of anti-CD3, addition of CD28 costimulation restored T cell proliferation to near normal levels even in the presence of PK18 (Fig. 6A). Similar results were found when tracking individual divisions of CFSE-labeled CD4⁺ and CD8⁺ T cells stimulated with saturating amounts of anti-CD3 (Fig. 6B). Under these conditions, CD28 costimulation was also able to restore CD25 expression on CD4⁺ and CD8⁺ T cells activated in the presence of PK18 (Fig. 6C). As expected, the addition of anti-CD28 increased IL-2 production in these cultures 50-fold (Figs. 5A and 6D). Thus, the ability of anti-CD28 to overcome PK18 inhibition mirrors that observed after adding high concentrations of exogenous IL-2 (Fig. 5C). However, even in the presence of costimulation and a high concentration of anti-CD3, the presence of PK18 caused a nearly 13-fold reduction in IL-2 secretion (Fig. 6D). Thus, CD28-mediated costimulation does not ablate the inhibitory signal initiated by BTLA engagement.

View larger version (13K): [in this window] [in a new window]   FIGURE 6. Effects of costimulation on BTLA engagement. A, T cells were activated by anti-CD3 and rat IgG () or anti-CD3 and PK18 () in the presence of anti-CD28, and proliferation was analyzed as described in Fig. 1. B, CFSE-labeled T cells were stimulated as described in Fig. 2 with anti-CD3 and rat IgG () or anti-CD3 and PK18 () in the presence of anti-CD28. On day 3, cells were stained for CD4 or CD8 and were analyzed by flow cytometry. C, T cells were cultured with anti-CD3 and rat IgG () or anti-CD3 and PK18 (bold lines) in the presence of anti-CD28. On day 2 of culture, cells were harvested, and gated populations of CD4+ and CD8+ T cells were analyzed for the expression of CD25 by flow cytometry. D, IL-2 secretion was assayed in the supernatants of overnight cultures activated as described in B. E, Proliferation of AND TCR-Tg CD4+ T cells cultured in the presence of BALB.K APCs and specific peptide Ag with the indicated amount of soluble PK18 () or control rat IgG () was measured by [3H]thymidine uptake as described in Fig. 1A. Each graph represents one representative experiment of three.

BTLA signal can inhibit proliferation of preactivated T cells

Our results demonstrated that BTLA engagement at the time of initial TCR activation was a potent inhibitor of aspects of T cell activation. However, the fact that CD69 induction was not affected by PK18 raised the possibility that the inhibitory effect of BTLA engagement might be a relatively late event. Thus, we isolated naive CD4⁺ T cells from B6 mice, stimulated them overnight with plate-bound anti-CD3, and then transferred the cells to fresh plates coated with additional anti-CD3 in combination with PK18 or rat IgG. Surprisingly, PK18 was able to inhibit CD4⁺ T cell proliferation even after an initial overnight activation with anti-CD3, similar to the inhibition observed for cells exposed to PK18 for the entire culture period (Fig. 7).

View larger version (26K): [in this window] [in a new window]   FIGURE 7. Proliferation in preactivated T cells can be blocked by a secondary BTLA signal. CD4+ T cells isolated from B6 mice were stimulated overnight with a titration of anti-CD3 and transferred to a new plate coated with the indicated concentrations of anti-CD3 and rat IgG (•) or anti-CD3 and PK18 (). As controls, untransferred CD4+ T cells cultured in the presence of anti-CD3 and rat IgG () or anti-CD3 and PK18 () are shown. Data are displayed as the mean [3H]thymidine incorporation of triplicate cultures (±SD) minus the cpm of T cells cultured alone. Two independent experiments gave similar results.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

We were able to take advantage of the fact that PK18 preferentially binds the allele expressed in B6 mice, but not that in BALB mice (3), to perform initial epitope-mapping studies. Binding of PK18 to BTLA.2, but not BTLA.1, is critically dependent on residue 41, because the P41E substitution completely abolished Ab binding. Other Abs, for example, PK3, bound to the position 41 mutant at wt levels, indicating that the inability of PK18 to bind the mutant was not caused by a lack of surface expression. In addition, the binding of PK3 to mutant 41 indicates that other epitopes on the protein were not grossly distorted. The replacement of the proline at this position with a glutamic acid is likely to alter the local structure of the protein, but might also prevent Ab binding due to the addition of the negative charge.

Of the nine additional BTLA.2 mutants (encompassing 10 aa changes), only two, the substitution at position 85 and the double substitution at positions 45 and 47, had any effect on binding of PK18. Another allele-specific mAb, PJ196, which lacks inhibitory activity, was also affected to varying degrees by substitutions at these same positions. Substitution at 85 had a small effect on binding of PJ196, whereas mutants 41 and 45/47 had significantly greater effects on binding. Overall, however, the rank order of binding of PK18 and PJ196 to these mutants differed (for PK18 mutants, 41<45/47 and 85; for PJ196, 45/47<41<<85), consistent with overlapping, but distinct, epitopes recognized by the two Abs. Given that PJ196 is a better binder to cells than PK18 (data not shown), it seems likely that the dramatic difference in biological activity between these two mAb is due to the relatively subtle differences in the epitopes bound.

These data should be helpful in producing and screening for additional Abs that have agonist function. In an Ig fold, residues 41, 45, and 47 would be predicted to be on a solvent-exposed face of the protein (data not shown). Whether this region of BTLA is also involved in binding to HVEM, and whether there could be allelic differences in that binding, remain to be determined. Interestingly, two BTLA.2-specific Abs generated by Murphy et al. (5) appear to recognize epitopes distinct from that of PK18 or PJ196, although substitution at position 85 (our numbering) does eliminate binding of one of their Abs.

When assessed by uptake of thymidine, PK18 was found to be a potent inhibitor of T cell proliferation. However, single-cell analysis of cell division by CFSE staining revealed that CD4⁺ T cells were more susceptible to the inhibitory effects of PK18 than were CD8⁺ T cells. Similarly, PK18 also inhibited CD25 up-regulation on both CD4⁺ and CD8⁺ T cells, but the inhibition was again more pronounced on CD4⁺ T cells. Resting CD4⁺ T cells express modestly higher levels of BTLA than do CD8⁺ T cells (3) (Fig. 2B). Moreover, as shown in this study, BTLA is up-regulated with faster kinetics on activated CD4⁺ compared with CD8⁺ T cells. Thus, we cannot rule out that differences in expression may be one factor in the increased susceptibility of CD4⁺ T cells to PK18-mediated inhibition. Alternatively, CD8⁺ T cells may be intrinsically less sensitive to the inhibitory effects of PK18, especially during their initial phase of proliferation, which may be IL-2 independent (14). We have seen similar results using a soluble form of HVEM (data not shown); thus, it is unlikely that these results are peculiar to the PK18 mAb.

Soluble PK18 also inhibited the proliferation of CD4⁺ T cells at limiting concentrations of plate-bound anti-CD3 (Fig. 1B). This was somewhat surprising, because it was previously reported that BTLA phosphorylation, and thus presumably signaling, requires co-cross-linking with the TCR (4). In these latter experiments, T cell hybridomas overexpressing a Myc-tagged version of BTLA lacking the external domain were treated with anti-Myc and anti-CD3 Abs and cross-linked with a cross-reactive secondary Ab. Whether the lack of the BTLA external domain or the use of hybridoma cells affected the requirement for co-cross-linking in this system is not known. A soluble recombinant form of the BTLA receptor HVEM, however, was also reported to inhibit T cell proliferation induced by limiting concentrations of plate-bound anti-CD3 Ab, similar to the activity of PK18 (15, 16). Thus, PK18 appears to be a good mimic of the BTLA ligand.

We have found that BTLA engagement by PK18 is a potent inhibitor of IL-2 secretion. However, the addition of exogenous IL-2 at a concentration that is normally produced in these cultures was not able to rescue proliferation or CD25 expression on T cells activated in the presence of PK18. Thus, BTLA engagement has additional IL-2-independent inhibitory effects on T cell activation. In contrast to the effects on cytokine secretion, PK18 had no effect on the induction of CD69, indicating that BTLA engagement does not prevent initial activation of the T cell, but modifies the consequence of such activation. That BTLA might function as a response modifier is also supported by kinetic studies of susceptibility to a PK18-mediated inhibitory signal (see below). Although IL-2 is a potent mediator of initial T cell proliferation in vitro, IL-2 may play a role in vivo in subsequent phases of T cell clonal expansion and as a development of effector function in addition to its effects on T_regs (reviewed in Ref.17).

CD28-mediated costimulation lowers the threshold of T cell activation (18), potently enhances IL-2 production (13, 19) and IL-2R expression (20), and promotes progression through the cell cycle (21). At limiting concentrations of anti-CD3, PK18 was inhibitory even in the presence of anti-CD28. CD28 costimulation was able to counteract the inhibitory effects of PK18 on cell division in the presence of high concentrations of anti-CD3. Even under these conditions, however, IL-2 production was significantly inhibited by PK18. These findings are consistent with the ability of APC that coexpress HVEM and CD80 to inhibit the proliferation of TCR-Tg CD4⁺ T cells in response to low, but not high, concentrations of antigenic peptide (6). Similarly, high concentrations of PK18 can inhibit Ag-specific T cell responses (Fig. 6D). This inhibitory effect was due to binding of PK18 to the T cell, because we used APC that would not be targeted by PK18. Thus, BTLA engagement under the limiting conditions of costimulation or TCR activation that may occur in vivo may deliver an inhibitory signal. In the presence of anti-CD3, -CD28, and -PK18, the remaining IL-2 produced was probably sufficient to induce T cell proliferation to near control levels, because similar concentrations of exogenously added IL-2 rescued the proliferation of T cells activated in the presence of PK18. It is also possible that the ability of CD28 costimulation to regulate progression through the cell cycle in an IL-2-independent manner (22) plays a role in counteracting the inhibitory effects of BTLA engagement on cell division.

BTLA up-regulation occurs over several days after T cell activation. CD28-mediated costimulation increased the frequency of cells that up-regulated BTLA, but did not alter these kinetics. Because the production of cytokine is a relatively early event, the ability of PK18 to modify this response suggests that BTLA engagement on naive T cells before up-regulation of the cell surface protein can still deliver an inhibitory signal. Nevertheless, up-regulation of BTLA in vivo may be an important factor in making T cells more susceptible to BTLA-mediated inhibition. Interestingly, the BTLA ligand HVEM, also expressed by naive T cells, is down-regulated with similar kinetics as those of BTLA up-regulation (9) (data not shown). This might suggest that a BTLA-HVEM interaction is unlikely to autonomously regulate T cell function.

Because PK18 failed to block CD69 up-regulation, we asked whether BTLA engagement on preactivated CD4⁺ T cells would still be inhibitory. Surprisingly, cell proliferation was inhibited when CD4⁺ T cells were exposed to PK18 as late as 16 h after initial culture with anti-CD3. Intravital imaging has recently shown that during the first hours of initial CD4⁺ T cell activation, serial short-lived interactions with APC bearing cognate peptide are sufficient to up-regulate CD69 (23). Subsequent phases associated with more stable T cell-APC contacts appear to be required for induction of cytokine and subsequent cell division. The fact that inhibitory signals mediated by BTLA can be temporally separated from initial TCR activation raises the possibility that BTLA engagement during this secondary phase of T cell-APC interaction could modify the outcome of the T cell response.

	Acknowledgments

 
We thank Parinaz Aliahmad for critically reading this manuscript, and Alan Saluk, Cheryl Kim, and Kurt Van Gust for excellent technical assistance with cell sorting.

	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 National Institutes of Health Grant AI31231. This is Manuscript 17365-IMM from The Scripps Research Institute.

² Address correspondence and reprint requests to Dr. Jonathan Kaye, Department of Immunology IMM-8, The Scripps Research Institute, 10550 North Torrey Pines Road, La Jolla, CA 92037. E-mail address: jkaye{at}scripps.edu

³ Abbreviations used in this paper: BTLA, B and T lymphocyte attenuator; HVEM, herpes virus entry mediator; LIGHT, derived from homologous to lymphotoxin, inducible expression; Tg, transgenic; T_reg, regulatory T cell; YFP, yellow fluorescent protein; wt, wild type.

Received for publication April 28, 2005. Accepted for publication August 19, 2005.

	References

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