Antibodies and Flow Cytometry Analysis.
Before antibody staining 10⁶ lymph node cells were plated in wells precoated with 5 µg/ ml goat anti–hamster IgG(H+L) followed by 5 µg/ml hamster anti-mouse CD3 (PharMingen, San Diego, CA). After 18–20 h of stimulation, cells were stained with the following antibodies: biotinylated anti-CD3 (PharMingen, San Diego, CA), biotinylated anti-CD69 (PharMingen), biotinylated anti-CD25 (PharMingen), biotinylated anti-CD62L (PharMingen), FITC-conjugated anti– TCR-/β (PharMingen), PE-conjugated anti-CD4 (GIBCO BRL, Bethesda, MD), and CD8-Red (GIBCO BRL); secondary reagent was streptavidin-FITC (Southern Biotechnology Associates, Birmingham, AL). Cells were analyzed on a FACScan^® using the CellQuest software (Becton Dickinson, Mountain View, CA). Immunoprecipitations and Western blotting were done with antibodies to the following proteins: Itk (monoclonal antibodies 7F10 and 10B2; reference 6), Tec (gift of Dr. B. Tang, St. Jude Children's Research Hospital, Memphis, TN), TCR- (Santa Cruz Biotech, Santa Cruz, CA), ZAP-70 (Santa Cruz Biotech), and PLC-1 (Santa Cruz Biotech and Upstate Biotechnology, Lake Placid, NY). Anti-phosphotyrosine antibody 4G10 was a gift from Dr. B. Druker (Oregon Health Sciences Center, Portland, OR).

TCR Stimulation and IL-2 Assays.
For T cell stimulations, 5 x 10⁴ purified CD4⁺ T cells were plated in wells precoated with goat anti–hamster antibody (5 µg/ml) followed by hamster anti– mouse CD3 (0.5 µg/ml). Where indicated, a 1:8 dilution (determined to be saturating by cell surface staining) of anti-CD28 antibody supernatant (37N.D1; a gift from Dr. J. Allison (University of California at Berkeley, Berkeley, CA; reference 20) was added. As a control, cells were also stimulated with PMA (1 ng/ ml) plus ionomycin (500 ng/ml). After 24 h of stimulation, the supernatants were assessed for IL-2 concentration using HT-2 indicator cells as previously described (21).

Calcium Flux.
5 x 10⁶/ml purified CD4⁺ cells were incubated with 3 µg/ml fluo-3, 5 µg/ml Fura-Red, 0.5% pluronic acid (Molecular Probes, Eugene, OR), and 2% FCS in RPMI for 30–50 min. Dye-loaded cells were washed twice with RPMI and left at room temperature for 30 min in the dark before use. 1.5 x 10⁶ (in 300 µl) dye-loaded cells were placed in 1 ml of serum-free RPMI and warmed to 37°C. Stimulated cells were analyzed on a FACScan^®. The mean fluorescence ratio (FL-1:FL-3) was calculated using the FACSAssistant^® program.

Immunoprecipitation and Western Blotting.
Purified CD4⁺ T cells were incubated in serum-free RPMI for 2 h at 37°C before stimulation. Cells were then washed twice, resuspended in 120 µl of RPMI containing 25 µg/ml biotinylated anti-CD3 antibody, and incubated on ice for 10 min. 50 µg/ml of streptavidin (Sigma Chemical Co.) was then added, and cells were incubated at 37°C for the indicated times; signaling was terminated by diluting the samples into 1 ml of ice-cold PBS containing 20 mM NaF and 1 mM Na₃VO₄. Cells were then lysed in lysis buffer (0.5% Brij97, 20 mM Tris, pH 8, 100 mM NaCl, 1 mM EDTA, 20 mM NaF, and 1 mM Na₃VO₄) supplemented with protease inhibitors. Immunoprecipitations were done with lysate from 3 x 10⁶ cells. Immunoprecipitated proteins were resolved by 8 or 12% SDS-PAGE, transferred to Immobilon-P membranes (Millipore, Bedford, MA), and blocked and probed as previously described (22).

Analysis of IP3 Release.
8 x 10⁶ purified CD4⁺ T cells were starved in serum-free RPMI for 1 h at 37°C before stimulation. Cells were stimulated as for immunoprecipitation studies, but at 3.2 x 10⁷/ml; signaling was terminated by adding 50 µl ice-cold 100% Trichloroacetic acid. IP3 levels were assessed using the IP3 Radioreceptor Assay Kit (NEN Life Science Products, Boston, MA) following the manufacturer's protocol. Controls included medium alone or mock-stimulated (no primary antibody) cells.

	Results and Discussion

Top Abstract Materials and Methods Results and Discussion References

 
To determine the function of Itk in T cell signaling, we generated Itk-deficient mice by gene targeting. Exons of the Itk gene encoding critical regions of the kinase domain were deleted, and replaced with the neo^R cassette (Fig. 1 a). Mice homozygous for the mutated Itk allele (Itk^–/–; see Fig. 1 b) fail to express any Itk protein in lymph nodes, spleen, or thymus (Fig. 1 c). Consistent with a previous report on Itk-deficient mice (19), T cell development is abnormal in the absence of the Itk protein. Specifically, the size and general histology of the thymus are normal, but CD4⁺ T cell maturation is diminished in Itk^–/– mice. The number of CD4⁺ T cells in peripheral lymphoid organs is reduced to 50% of that found in wild-type mice; in contrast, the number of CD8⁺ T cells is unchanged (data not shown).

To investigate the role of Itk in TCR signaling, we examined the responses of Itk^–/– CD4⁺ T cells to TCR stimulation. First, Itk^–/– lymph node cells were stimulated with plate-bound anti-CD3 antibody, and cells were assessed 18–20 h later for changes in surface marker expression. CD25 and CD69 were upregulated and CD62L (L-selectin) was downregulated after TCR stimulation on both mutant and wild-type cells (Fig. 2 a). The only difference we consistently observed was a somewhat higher degree of CD25 upregulation on Itk^+/+ cells compared with Itk^–/– cells; this difference is most likely due to the IL-2– induced increase in IL-2 receptor chain (CD25) expression, which is lacking in Itk^–/– T cells (see below). These data indicate that the TCR-dependent signaling pathways leading to changes in activation marker and adhesion molecule expression are intact in Itk^–/– T cells. Second, we examined IL-2 secretion in response to TCR stimulation. When purified CD4⁺ Itk^–/– T cells were stimulated with anti-CD3 antibody, no IL-2 could be detected in the supernatants after overnight culture (Fig. 2 b). Stimulation with anti-CD3 plus anti-CD28 antibodies, which dramatically enhances IL-2 production from wild-type cells, resulted in detectable, but still reduced, IL-2 secretion from Itk^–/– T cells. This signaling defect is proximal to the TCR, as stimulation with PMA plus ionomycin, which bypasses the early stages of TCR signaling, elicits comparable IL-2 secretion by Itk^–/– and wild-type T cells.

View larger version (20K): [in this window] [in a new window] [Download PPT slide]   Figure 2 Defective IL-2 production by Itk–/– T cells. (a) Total lymph node cells were analyzed for expression of CD25, CD69, and CD62L after 18–20 h of activation by plate-bound anti-CD3 antibody. Histogram of live gated CD4+ cells are shown. Open histograms show expression of markers when cultured in media alone; filled histograms show expression of markers after stimulation. (b) Purified CD4+ T cells were stimulated with plate-bound anti-CD3 antibody (p.b. CD3), anti-CD3 plus anti-CD28 antibodies (CD3+CD28), or PMA plus ionomycin (PMA+Iono), and analyzed for IL-2 secretion after 24 h. Graph is representative of four similar experiments.

View larger version (25K): [in this window] [in a new window] [Download PPT slide]   Figure 3 Defective calcium flux response after TCR stimulation of Itk–/– T cells. Purified CD4+ T cells were stimulated and monitored for 600 s after gating on live cells. The intracellular calcium concentration is plotted as the FL1/FL3 ratio over time. (a) Calcium response after CD3 cross-linking. 500 ng/ ml ionomycin was added as a control at 500 s to assess the efficiency of dye loading. (b) Calcium response after CD3 cross-linking in the presence of extracellular EGTA (0.5 mM) sufficient to chelate the calcium present in the RPMI media (0.4 mM). Extracellular calcium was added back to a final concentration of 0.5 mM free Ca2+ midway through the experiment. (c) Intracellular calcium elevation in response to 1 µM thapsigargin (Tg). Extracellular EGTA was added midway through the experiment. (d) Thapsigargin (Tg)- induced calcium elevation in the presence of EGTA (0.5 mM). Solid lines, control (Itk+/+ and Itk+/–) cells; dashed lines, Itk–/– cells.

To determine whether the depletion of intracellular calcium stores is competent to induce the opening of plasma membrane calcium channels, wild-type and mutant T cells were treated with the drug thapsigargin. Thapsigargin, a specific inhibitor of the Ca²⁺-ATPase in the endoplasmic reticulum membrane, prevents the uptake of cytosolic calcium and results in a leak that depletes intracellular calcium stores and triggers calcium entry (28, 29). In contrast to anti-CD3 antibody cross-linking, thapsigargin treatment initiates a substantial calcium influx in both wild-type and mutant T cells, demonstrating that store-operated calcium entry is normal in Itk^–/– T cells (Fig. 3 c). It is possible that distinct depletion-sensitive signaling pathways are induced depending on the mechanism of store depletion; however, we favor a model in which the channel-operating calcium stores are depleted to a lesser extent in the Itk^–/– cells. This latter hypothesis is consistent with the reduced production of IP3 observed after TCR stimulation of Itk^–/– T cells (see below).

In the presence of extracellular EGTA, thapsigargin induces similar levels of calcium elevation in mutant and wild-type T cell (Fig. 3 d), suggesting that the sizes of the thapsigargin-sensitive intracellular calcium stores are similar in both cell types. Notably, the thapsigargin-stimulated calcium release observed in these naive T cells is unexpectedly small, yet capable of stimulating calcium influx. In light of this result, it is surprising that the large calcium release observed upon TCR stimulation in Itk-deficient T cells fails to trigger calcium influx. This apparent contradiction could be explained in at least three ways. First, the extent of calcium elevation in the presence of thapsigargin may be a poor measure of store depletion, as rates of store refilling may differ between wild-type and Itk^–/– T cells. Second the similar extent of store release observed between wild-type and Itk^–/– cells may underestimate the actual difference in total calcium released if the rate at which calcium is cleared from the cyotosol increases as the concentration of cytosolic calcium increases; this phenomenon has been documented previously in T cells (30). Third, it is possible that the thapsigargin-sensitive intracellular stores are a distinct and small subset of the TCR-coupled intracellular calcium stores, and are uniquely competent to trigger calcium influx in response to depletion. In this latter case, Itk would be required to couple the TCR to these specific channel-operating calcium stores.

It should be noted that the amplitude of the thapsigargin-induced calcium elevation is always slightly diminished in Itk-deficient T cells (Fig. 3 c). When purified cell populations are gated to exclude contaminating CD4^– cells, the same difference is observed (data not shown); therefore, this difference is not due to disparities in the purities of the CD4⁺ T cell preparations from mutant and wild-type lymph nodes. The absence of Itk could affect peak intracellular calcium levels by multiple mechanisms, potentially reducing the frequency of calcium channel opening, decreasing the electrochemical gradient driving calcium entry, or by facilitating the upregulation of the plasma membrane calcium pump. At present we do not know which, if any, of these mechanisms result in the reduction in maximum intracellular calcium levels induced by thapsigargin.

TCR-induced calcium responses in T cells are initiated by the second messenger, IP3. IP3 is generated by the PLC-mediated hydrolysis of the membrane phospholipid, phosphatidylinositol 4,5-bisphosphate (PIP2). After PIP2 cleavage, IP3 diffuses through the cytoplasm and binds to IP3 receptors, inducing the release of calcium from internal stores (for review see reference 31). In addition, IP3 is thought to play a role in the subsequent calcium signal that causes the opening of the plasma membrane calcium channels (32). Therefore, we assessed the levels of IP3 generated after TCR stimulation of wild-type and Itk^–/– T cells (Fig. 4 a). In wild-type cells, IP3 levels begin to rise by 45 s after TCR stimulation, remain at peak levels between 1 and 2 min, and return to basal levels by 5 min (Fig. 4 a and data not shown). In contrast, no significant increase in IP3 levels over background can be detected in Itk^–/– T cells at any time point (Fig. 4 and data not shown). Parekh et al. have demonstrated that calcium release can be triggered by IP3 concentrations 50-fold below those required to trigger calcium influx (32). The minimal calcium-releasing doses of IP3 identified by Parekh are at the limit of detection of our assay system, and it is likely that TCR stimulation in Itk^–/– T cells actually induces small amounts of IP3 that activate calcium release without triggering calcium influx. It is unclear why this threshold effect exists. As proposed by Parekh et al., it could result either from a low affinity IP3-receptor present on a specialized channel-coupled calcium store, or from the need for IP3 concentrations sufficient to allow diffusion to outpace the catabolism of IP3 (32).

View larger version (41K): [in this window] [in a new window] [Download PPT slide]   Figure 4 Reduced PLC-1 phosphorylation and IP3 production by activated Itk–/– T cells. (a) Purified CD4+ T cells from wild-type (WT) and Itk–/– (KO) mice were incubated in the presence (+stimulation) or absence (mock) of anti-CD3 antibody for 1.5 min; cell lysates were prepared and analyzed for IP3 levels. A value obtained from medium in the absence of cells is shown (medium). Averages and standard deviations were calculated from two to three independent experiments. (b) Purified CD4+ T cells from wild-type (+/+) and Itk–/– (–/–) mice were stimulated by anti-CD3 antibody cross-linking. PLC-1, CD3, and ZAP-70 were immunoprecipitated from the cell lysates and immunoblotted for phosphotyrosine (n = 3). In the case of PLC-1, the membrane was reprobed to detect the immunoprecipitated protein.

Here we demonstrate that Itk^–/– T cells have a defect in TCR signaling that leads to reduced IL-2 secretion after TCR cross-linking. Although we have not ruled out additional signaling defects in Itk^–/– T cells, the impaired influx of calcium across the plasma membrane is likely to be responsible for the loss of TCR-induced IL-2 production. Since calcium influx enables the sustained increases in cytoplasmic calcium required for transcription factor activation (23–25), this defect could explain the inability of Itk^–/– T cells to secrete IL-2. As calcium release from intracellular stores appears normal in the Itk^–/– T cells, these data suggest that Itk might be involved in the signaling pathways coupling store depletion to calcium influx. However, we found this explanation unlikely because thapsigargin induces calcium influx in the absence of Itk. This finding suggests that a functional depletion-sensing pathway can be decoupled from calcium release. Defective coupling could result from impaired PLC-1 activation in Itk^–/– T cells by at least two mechanisms. The dramatically reduced production of IP3 after TCR stimulation in Itk^–/– T cells could fail to trigger a low affinity IP3 receptor on a channel-operating subset of intracellular calcium stores, while fully activating calcium release from the remaining stores. Alternatively, the low levels of IP3 produced in the Itk^–/– T cells could fail to deplete intracellular calcium stores to the extent required to trigger calcium influx. In this case, we would be forced to conclude that the observed store release is a poor measure of actual store depletion, either because we are underestimating release in the wild-type T cells, or because the rates at which the stores refill differ between the wild-type and Itk^–/– T cells. We believe that this is the first demonstration that the TCR-induced influx of extracellular calcium can be uncoupled from the TCR-induced release of intracellular calcium, while preserving functional, depletion-sensitive calcium influx mechanisms. Thus, these experiments suggest that Itk^–/– T cells will provide an interesting model system for detailed studies of the precise mechanisms regulating intracellular calcium levels.