Flow Cytofluorimetric Analyses.
Single cell suspensions from thymi, lymph nodes, and spleens were prepared according to standard methods. Cells were then blocked with an anti-F_cR mAb, 2.4G2, and stained with the Abs indicated in the text. Abs used in these experiments were conjugated to biotin or one of the following fluorochromes: FITC, PE, or Cy-Chrome. Ab-stained cells were analyzed on a FACScan^TM (Becton Dickinson) flow cytometer.

Proliferation Assays.
Whole lymph node cells, splenocytes, or a 1:1 mixture of lymph node or splenic T cells cultured with T cell–depleted, irradiated syngeneic splenic APCs, from wild-type (either progeny from heterozygous intercrosses or [C57BL/6 x 129] F2 mice; The Jackson Laboratory), heterozygous, or homozygous knockout (KO) mice were used in these experiments. Soluble anti-CD3 mAb (145-2C11) with or without soluble anti-CD28 mAb (PV-1) was added to wells of round-bottomed 96-well plates (Costar) at the concentrations indicated in the text. When used, final concentrations of PMA and ionomycin were 10 ng/ml and 0.5 µM, respectively. Cells (2 x 10⁵) were added to each well at a final concentration of 1 x 10⁶/ml and cultured at 37°C in DMEM supplemented with 10% FCS, penicillin/streptomycin (100 µg/ml), and 2-ME. After 40 h, individual wells were pulsed with [³H]thymidine (1 µCi/well) for 8 h, for a total duration of 48 h of stimulation. Cell contents were then harvested onto fiberglass filters, scintillation fluid was added (25 µl/well), and counts were determined using a TopCount microplate scintillation counter (Packard).

IL-2 ELISAs.
IL-2 ELISAs were performed on culture supernatants of activated cell cultures (described above). Nunc-Immuno plates (Nalge Nunc) were used for these assays. Plates were coated with an anti–IL-2 coating Ab overnight at 4°C, washed, and blocked in 2% BSA/PBS for 1 h at room temperature. Supernatants, diluted in 2% BSA/PBS, were incubated on the coated plates overnight at 4°C. The next day, plates were washed, then incubated with an anti–IL-2 detecting Ab for 1 h at room temperature. Plates were washed and incubated with a 1:5,000 dilution of streptavidin-horseradish peroxidase (Zymed), after which they were developed using TMB One-Step Substrate (Dako). Abs and IL-2 standards were all purchased from Endogen.

RNase Protection Assays.
Splenocytes from wild-type (either [C57BL/6 x 129] F2 described above, or when indicated, C57BL/6 mice), heterozygous, and homozygous KO mice were activated with the indicated concentrations of soluble anti-CD3 mAb with or without anti-CD28. At the indicated times, cells were harvested, and RNA was prepared as described above. Cytokine RNase protection assays were performed using the RiboQuant Multi-Probe RNase Protection Assay System (PharMingen) according to the manufacturer's protocol. In brief, a ³²P-labeled RNA probe was synthesized via in vitro transcription from the mCK-1 plasmid template. Aliquots of 2.5 µg of total RNA per sample were hybridized overnight at 56°C to the probe. Samples were then digested with RNase A, after which they were treated with Proteinase K and phenol/chloroform extracted. Samples were then precipitated, resuspended in 1x loading buffer, heated briefly at 90°C, and subjected to electrophoresis on a 5% denaturing polyacrylamide gel. Gels were dried, and autoradiography was performed. Densitometry on the cytokine and housekeeping gene bands was performed using a Molecular Dynamics ImageQuant^® densitometer.

	Results

Top Abstract Materials and Methods Results Discussion References

 
RIBP Is a Novel Adaptor Protein That Interacts with Rlk and Itk.
The yeast two-hybrid system of detecting interprotein interactions was used to identify potential Rlk-binding proteins that might mediate or regulate Tec family kinase function. A cDNA encoding full-length Rlk was cloned into a yeast vector encoding the GAL4 DNA-binding domain, thus yielding a "bait" fusion protein consisting of Rlk physically linked to this DNA-binding protein. A mouse T cell lymphoma cDNA library was screened using the Rlk bait. This library consisted of "trap" cDNAs cloned into a yeast vector encoding the GAL4 transactivation domain. The T cell cDNA library was chosen as Rlk is highly expressed both in the thymus and in peripheral T cells. Two specificity criteria were used as measures of GAL4-mediated transcriptional activation: (a) histidine synthesis by the yeast, and (b) β-galactosidase synthesis. A total of 750,000 yeast colonies were screened. 86 of these colonies were identified as positive for bait–trap interaction by the first pass criterion of growth on histidine-deficient (His^–) medium supplemented with 3-aminotriazole, an inhibitor of weak endogenous histidine synthesis. Among the 86 colonies, 56 were positive for interaction with the Rlk bait fusion protein based on the second criterion of β-galactosidase synthesis (blue/white selection). The cDNA library plasmids isolated from the β-galactosidase–positive yeast colonies were subsequently transformed into bacteria to distinguish multiple trap cDNAs present within the same yeast colony during the original screening. A total of 65 unique cDNA clones were identified and subsequently retransformed into yeast. One clone, 2.3.2, was found to interact with Rlk with high specificity, and was chosen for further study.

Initial sequence analysis demonstrated that clone 2.3.2 did not represent a full-length cDNA; consequently, a mouse fetal thymic cDNA library was screened using a probe derived from the positive yeast cDNA clone. This screen yielded a full-length cDNA that was used to examine interactions with Rlk and Itk. Yeast transformed with the full-length cDNA, termed RIBP, interacted specifically with both Rlk and Itk (Fig. 1 A, bottom; nos. 2 and 6, respectively). We further examined whether the interaction of RIBP with Rlk depended on the kinase function of Rlk. An altered Rlk that contained a point mutation in the kinase domain (K309R, denoted K309R) previously shown to abolish kinase activity (our unpublished observations) was incapable of binding RIBP (Fig. 1 A, bottom; no. 4). This suggests that the bait–trap interaction is critically dependent on the functionality and activity of the tyrosine kinase domain of Rlk.

View larger version (27K): [in this window] [in a new window] [Download PPT slide]   Figure 1 Identification of an Rlk and Itk interacting protein, RIBP. (A) Yeast two-hybrid system interactions between RIBP and Itk, Rlk, or kinase-mutant Rlk (K309R). Top: Growth of bait plus trap–transformed yeast on leucine and tryptophan–deficient (–LT) medium (positive control for transformation with both constructs). Bottom: Assay for a specific bait–trap interaction. Growth of bait plus trap–transformed yeast on –LT, +3-aminotriazole (3AT, endogenous histidine synthesis inhibitor) medium. For interactions with Rlk, results are representative of 11 independent experiments. For interactions with Itk, results are representative of two independent experiments. For interactions with Rlk(K309R), results are representative of four independent experiments. (B) Western blot demonstrating association of RIBP with Itk in transfected HEK293 cells. Top: Lysates prepared from HEK293 cells transfected with the indicated constructs (top of the blot) were precleared with rat IgG on protein G beads, and subsequently, the supernatants were immunoprecipitated with rat anti-HA mAb. Immunoprecipitates and preclears were resolved by SDS-PAGE, transferred to a polyvinyldifluoride membrane, and immunoblotted with an anti-Itk antiserum. Bottom: Immunoblot from B was stripped and reprobed with mouse anti-HA to assess the amount of RIBP in the immunoprecipitates. Results are representative of three experiments. WCL, whole cell lysates. (C) Amino acid sequence homology between RIBP and TSAd. NH2 and COOH termini of a putative SH2 domain and PRR are indicated by arrows. Dots between amino acids in RIBP and TSAd indicate homology, with two dots indicating greater homology. The amino acid insertions present in the alternatively spliced forms of RIBP and TSAd are boxed with a solid line; NPXY PTB domain sequences are underlined, and YXXP and YXXV sequences, in boldface, are in boxes with dashed lines or dot-dashed lines, respectively. Putative N-myristoylation sites are in boldface and italics. The RIBP nucleotide sequence is available from EMBL/GenBank/DDBJ under accession no. AF203343.

Structural Analysis and Chromosomal Location of RIBP.
Sequence and genomic analyses were performed on the RIBP gene product. RIBP contains an SH2 domain (highly homologous to the SH2 domain of Shc, 47% [data not shown]), a proline-rich region (PRR) capable of binding SH3 domains, and an NPIY substrate sequence for binding by phosphotyrosine-binding (PTB) domains 30 present within the PRR (Fig. 1 C). Further analysis of the cDNA library identified a second RIBP transcript that represented an alternatively spliced form with an 8 amino acid sequence insert (VWASQQKA). Other potentially significant amino acid sequences within RIBP include two YXXP motifs, implicated in binding the SH2 domains of rasGAP, Abl, and Crk 31, and one YXXV motif, potentially capable of binding the SH2 domain of the tyrosine phosphatase, SHP-2 32. Additionally, RIBP contains three potential sites for N-myristoylation (Fig. 1 C). These structural features and the absence of a catalytic domain suggest that RIBP functions as an adaptor protein. One adaptor protein, TSAd 33, showed extensive sequence homology to RIBP. The human TSAd protein exhibits a 68% sequence identity and a 76% sequence similarity with RIBP. The sequence homology between RIBP and TSAd was greatest within the SH2 domain, where the two proteins share an 87% sequence identity (80/92 amino acids; Fig. 1 C). Furthermore, TSAd exists in two alternatively spliced forms, similar to RIBP, with a 10 amino acid insert present in the longer form. Although these results suggested that RIBP and TSAd may be species homologues, the sequence insertions in RIBP and TSAd are in different locations within the molecules. The 10 amino acid insertion in TSAd is located within the SH2 domain, whereas the 8 amino acid insertion in RIBP is located within one of the exons in the region between the SH2 domain and the PRR (Fig. 1 C).

Genomic linkage studies of the RIBP gene were performed by Southern blot analyses of two sets of multilocus crosses (described in Materials and Methods). Digestion of DNA samples from parental mice with HindIII produced RIBP fragments of 8.6 and 2.9 kb in M. spretus and 11.0 and 10.8 kb in NFS/N. BamHI produced fragments of 12.4 and 4.0 kb in NFS/N and 16.5 kb in M. m. musculus. Inheritance of the variant fragments was compared with that of other markers previously typed in these crosses. The RIBP locus was mapped to mouse chromosome 3 (Fig. 2). Closest linkage was detected with Gba, for which no recombinants were detected in 171 mice, indicating that the genes are within 1.7 cM of one another at the upper limit of the 95% confidence interval. Similarly, no recombination was detected with Lmna in 103 mice, placing RIBP within 2.9 cM of Lmna. The RIBP gene maps to a region of mouse chromosome 3 with conserved synteny to human chromosome 1q21 3435, where both human GBA 36 and LMNA 37, as well as TSAd 33 and Shc 38, are located. Thus, the RIBP gene has a genomic localization congruent with that of the TSAd and Shc genes, supporting the possibility of gene duplication events in this region.

View larger version (9K): [in this window] [in a new window] [Download PPT slide]   Figure 2 Chromosomal localization of mouse RIBP. To the right of the map are recombination fractions between adjacent loci, with the first fraction representing data from the M. m. musculus crosses and the second from the M. spretus crosses. Numbers in parentheses are recombinational distances ± SE. The M. m. musculus crosses were not typed for D3Mit22.

View larger version (26K): [in this window] [in a new window] [Download PPT slide]   Figure 3 Northern blot analysis of RIBP tissue and T cell subset expression and its induction by T cell activation. (A) Northern blot analysis of RIBP gene expression in various tissues, and in different thymocyte subsets and peripheral T cells. A blot with RNA from various tissues was probed with an oligonucleotide derived from RIBP cDNA (left). Reprobing of the blot with an oligonucleotide specific for the housekeeping gene EF demonstrated equivalent RNA loading (not shown). RIBP expression in lymph node and thymocyte subsets was assessed similarly (right). Ethidium bromide staining of the gel revealed equivalent RNA loading except for lanes 3 and 4 (not shown), which had greater amounts of RNA present. (B) Northern blot analysis of regulation of RIBP gene expression by T cell activation. Top: RIBP expression in A.E7 Th1 T cell clones (left) and PGL10 Th1 T cell clones (right) stimulated with anti-CD3 (0.1 µg/ml for A.E7, and 5.0 µg/ml for PGL10) for the indicated times. Total RNA per sample was assessed by ethidium bromide staining, and demonstrated equivalent loading (not shown). Results for regulation of RIBP expression in T cell clones are representative of a total of four experiments. Bottom: Expression of RIBP in NK cells and Th2 T cell clones.

Generation of RIBP-deficient Mice.
RIBP KO mice were generated by disrupting the RIBP gene via homologous recombination. A targeting construct was generated that replaced exons 3 and 4 (encoding the SH2 domain) with a DNA segment encoding a neo gene. The targeting construct, depicted in Fig. 4 A, was introduced into the R1 ES cell line derived from the 129/Sv mouse strain. Southern blot analyses of drug-resistant ES cells demonstrated successful targeted disruption at the RIBP locus (Fig. 4 B, top). Genomic DNA samples from control and targeted ES cells were digested with EcoRI and XhoI, resolved by gel electrophoresis, and hybridized to a 5' RIBP cDNA probe. As seen in Fig. 4 B (top left panel), probing of control digested ES cell DNA revealed bands of the predicted size (3.8 kb). In contrast, DNA from targeted ES cell clones revealed bands migrating at 5.5 kb, consistent with the replacement of the third and fourth exons with the neo cassette. Similar results were observed using a 3' RIBP cDNA probe of control versus targeted ES cell genomic DNA samples digested with Asp718 (an isoschizomer of KpnI) and XhoI (Fig. 4 B, top right panel). The neomycin-resistant ES cells (clone 2) were injected into C57BL/6 blastocysts using standard techniques 29. Chimeric mice were bred to C57BL/6 mice to establish germline transmission, and heterozygous mice were interbred to obtain homozygous KO progeny. Southern blot analyses performed on tail genomic DNA samples from the progeny demonstrated successful targeted disruption at the RIBP locus (Fig. 4 B, bottom panel). Initial studies revealed that homozygous KO mice lacked RIBP mRNA expression based on Northern blot analyses (data not shown). The lack of RIBP expression in the RIBP KO offspring was confirmed by immunoblot analyses using an RIBP-specific polyclonal antiserum. As seen in Fig. 4 C, lysates from wild-type C57BL/6 and heterozygous splenocytes activated with anti-CD3 contained significant amounts of RIBP protein migrating at 46 kD. In contrast, no RIBP protein was detected in activated T cells from homozygous RIBP-deficient animals.

Analyses of Thymic and Peripheral T Cell Populations in RIBP-deficient Mice.
RIBP KO mice did not display any gross developmental abnormalities, and a normal Mendelian distribution of RIBP KO progeny was observed. The percentages of CD4^–CD8^–, CD4⁺CD8⁺, CD4⁺CD8^–, and CD4^–CD8⁺ thymocytes did not differ between RIBP KO and wild-type (Fig. 5 A) or heterozygous (data not shown) control mice, and no significant qualitative or quantitative differences in lymph node and splenic T cell populations were evident (Fig. 5 B, and data not shown, respectively). In addition, the CD4⁺/CD8⁺ ratio in both lymph node (Fig. 5 B) and spleen (data not shown) was similar among the various groups. Moreover, no obvious differences in the sizes or cell yields of thymus, spleen, and lymph nodes isolated from RIBP KO mice were apparent compared with wild-type control mice (data not shown). These data suggest that RIBP does not have an essential role in T cell development or homeostasis of peripheral T cell populations.

View larger version (35K): [in this window] [in a new window] [Download PPT slide]   Figure 5 Flow cytofluorimetric analysis of T cell development and peripheral T cell subsets in RIBP KO mice. (A) Thymocyte development in RIBP KO mice. Mice used were 7–10 wk of age. Cells were stained with FITC-conjugated anti-CD8 mAb and PE-conjugated anti-CD4 mAb to distinguish double negative, double positive, and single positive populations. Staining of thymocytes pooled from three wild-type mice (WT, left) compared with thymocytes pooled from three RIBP KO mice (right). (B) Lymph node T cell subsets in RIBP KO mice. Lymph node cells from 7–10 wk old wild-type (left) and KO (right) mice were stained with the same Abs as in A, as described in Materials and Methods. Results are representative of four independent experiments.

View larger version (40K): [in this window] [in a new window] [Download PPT slide]   Figure 6 Impairment of RIBP KO T cell proliferation and IL-2 production in response to TCR-triggered activation. (A) Proliferation of T cells from RIBP heterozygous and RIBP KO mice as a function of TCR stimulus (anti-CD3). Splenocytes from heterozygous (filled symbols) or KO (open symbols) mice were stimulated with the indicated concentrations of soluble anti-CD3 alone (triangles), with or without soluble anti-CD28 added at 1.0 µg/ml (circles). Proliferation was assessed at 48 h, with a [3H]thymidine pulse added after 40 h, for an 8-h pulse duration. Results are representative of four independent experiments performed using splenocytes, and three independent experiments using purified T cells and irradiated, T cell–depleted APCs. (B) Proliferation of T cells from wild-type (WT) and RIBP KO mice in response to either anti-CD3 or PMA plus ionomycin (P+I). Proliferation was assessed as above. (C) Splenocytes from wild-type and RIBP KO mice were stimulated with 1 µg/ml of soluble anti-CD3, with or without 1 µg/ml of soluble anti-CD28. Supernatants were collected at either 6, 24, or 48 h, and the concentration of IL-2 was determined by ELISA; values listed above were obtained at 24 h. Results are representative of 11 independent experiments. (D) Splenocytes from RIBP KO or wild-type mice were activated for the indicated times with anti-CD3 with or without anti-CD28. Ab concentrations were 1 µg/ml for both mAbs. RNA prepared from cells was subsequently subjected to RNase protection assays, as described in Materials and Methods. 32P autoradiogram of RNase protection assay polyacrylamide gel. Top: IL-2 mRNA levels in wild-type and RIBP KO T cells activated for the indicated times with the stimuli listed. EL4 mRNA is a positive control for cytokine gene expression, and yeast tRNA is a negative control. Bottom: mRNA levels for the L32 housekeeping gene. Results are representative of three independent experiments.

Reduced Cytokine Production by Activated RIBP KO T Cells.
RIBP KO splenocytes were stimulated with anti-CD3 and examined for cytokine production. Consistent with the reduced proliferative response (Fig. 6A and Fig. B), a significant reduction in the amount of IL-2 in the culture supernatant was observed (Fig. 6 C). Furthermore, although CD28-mediated costimulation increased IL-2 production by both wild-type and KO T cells, the relative differences in IL-2 levels were maintained. These results were confirmed using an RNase protection assay to determine relative levels of IL-2 transcripts in activated RIBP KO versus wild-type T cells. As shown in Fig. 6 D, IL-2 mRNA was detected at 6 h in (C57BL/6 x 129) F2 wild-type T cells stimulated with anti-CD3. In contrast, little IL-2 mRNA was apparent in activated RIBP KO T cells at this time point (Fig. 6 D, lane 5 versus lane 4). Densitometry analyses revealed that IL-2 mRNA levels in RIBP KO T cells were reduced by 80% relative to wild-type cells (data not shown). Also, consistent with the reduction in supernatant levels of IL-2 (Fig. 6 C), the relative amounts of IL-2 mRNA from RIBP KO T cells activated with anti-CD3 and anti-CD28 were still significantly reduced compared with control T cells (Fig. 6 D, lane 7 versus lane 6).

In addition to a reduction in IL-2 levels, a pronounced decrease in IFN- production was observed in RIBP KO T cells (Fig. 7 A). As was the case for IL-2, this reduction in IFN- production correlated with decreased IFN- mRNA levels (Fig. 7 B), suggesting that RIBP affects lymphokine production at the level of transcription and/or mRNA stabilization. Little IFN- mRNA was observed in anti-CD3–activated RIBP KO T cells relative to wild-type T cells; densitometry revealed that this was a >90% reduction (Fig. 7 B; densitometry data not shown). However, anti-CD28 costimulation did restore the IFN- decrease observed in RIBP KO T cells, suggesting that this defect may be an indirect consequence of the reduced activation and IL-2 production. Finally, despite the reductions in IL-2 and IFN- production by RIBP KO T cells, no significant reduction in IL-4 production was observed (Fig. 7 C). In fact, in some experiments, activated RIBP KO splenocytes produced more IL-4 than did control splenocytes. Thus, the lack of RIBP appears to more profoundly affect the ability of T cells to produce Th1-type cytokines than Th2-type cytokines.

View larger version (31K): [in this window] [in a new window] [Download PPT slide]   Figure 7 Demonstration of defective IFN- induction and normal IL-4 induction by activated RIBP KO T cells. (A) ELISA determination (see Fig. 6 C) of IFN- production by RIBP KO T cells. Results are representative of at least three independent experiments. (B) 32P autoradiogram of RNase protection assay polyacrylamide gel, as described in the legend to Fig. 6 D. Stimulation conditions are also as described for Fig. 6 D. Top: IFN- mRNA levels in wild-type (WT) and RIBP KO T cells activated for the indicated times with the stimuli listed. EL4 mRNA is a positive control for cytokine gene expression, and yeast tRNA is a negative control. Bottom: mRNA levels for the L32 housekeeping gene. Results are representative of three independent experiments. (C) IL-4 production by activated control and RIBP KO T cells. Supernatants (see Fig. 6 C and 7 A) were collected at 48 h and assessed for IL-4 by ELISA. Results are representative of at least three independent experiments.

	Discussion

Top Abstract Materials and Methods Results Discussion References

RIBP is a complex adaptor protein. The gene encodes a PRR that may bind SH3 domain–containing proteins such as other Src family kinases and other adaptor proteins. In addition, a tyrosine-phosphorylated NPIY sequence present in RIBP may bind PTB domain–containing proteins such as Shc. Proteins such as Shc have been implicated in TCR signal transduction via interactions with ZAP-70 43 and Cbl, an adaptor which is thought to negatively regulate ZAP-70 activation 4445 and binds to the SH3 domain of Itk. The tyrosine-based protein binding motifs present in RIBP (YXXP and YXXV) may bind the SH2 domains of rasGAP, Abl, Crk, and SHP-2, molecules previously shown to regulate T cell signal transduction. Finally, RIBP contains an SH2 domain that may be involved in binding to other phosphotyrosine-containing proteins. In this regard, preliminary results indicate that the SH2 domain of RIBP is required for interaction with Rlk, whereas the PRR and tyrosine-based protein binding motifs are unnecessary (our unpublished observations).

The molecular mechanisms that link RIBP, Rlk, and Itk, to the proximal event of TCR ligation are unclear. The finding that Lck coexpression augments the association of RIBP with Itk is consistent with a role for RIBP in the regulation of TCR signal transduction. Tyrosine phosphorylation of Itk, catalyzed by Lck or Fyn, is required for optimal Itk kinase activity 4647, and consequently, T cell activation. Phosphorylation of Itk occurs at Y511, a residue in the activation loop of the kinase domain of Itk 48. Thus, RIBP could be functionally coupled to TCR engagement, as its binding to Itk is enhanced by the activity of this CD4/CD8 coreceptor–associated Src family kinase in vitro.

RIBP may bind to both Itk and Rlk, raising the question as to its physiological partner and the relationship of its binding specificity to the functional deficit evident in RIBP KO T cells. The expression pattern of RIBP suggests that its physiological binding partner may be Itk in the periphery. Previous studies have shown that Rlk is highly expressed in resting T cells, but downregulated after T cell activation. In contrast, Itk gene expression is upregulated after T cell activation, similar to RIBP. Furthermore, the phenotype observed in RIBP KO T cells more closely resembles the phenotype of Itk-deficient T cells, which display diminished proliferation and IL-2 production in response to TCR ligation. In contrast, Rlk KO T cells have only minor deficits in TCR-mediated T cell activation 39. However, there are circumstances when the binding of RIBP to Rlk may be physiologically relevant. For instance, both RIBP and Rlk are expressed in thymocytes. Although we have not identified any profound changes in T cell development in the RIBP KO or Rlk KO mice (our unpublished observations, and reference 39, respectively), there may be subtle, as yet unidentified effects of this interaction in the thymus. Moreover, both Rlk and RIBP are expressed in NK cells, and may play a role in this lymphocyte subset. In fact, recent evidence indicates that Itk and Rlk have overlapping functions in T cell activation, as mice deficient in both kinases have more severely diminished peripheral T cell function than mice deficient in either kinase alone 39. Thus, further biochemical and breeding studies to generate RIBP/Itk and RIBP/Rlk double-KO mice will be needed in order to determine the differential effects of RIBP on the functions of Itk versus Rlk. It is important to emphasize that the functional impairment present in RIBP KO T cells was not as severe as that observed in Rlk/Itk double-KO T cells. There are two possible reasons for these findings. First, there may be functional homologues of RIBP that can partially compensate for the absence of RIBP in KO T cells. Second, not all of the intracellular effects on TCR signaling that Rlk and Itk mediate may require RIBP or any putative homologues.

The fact that CD28-mediated costimulation partially compensates for the severely diminished proliferative response to TCR/CD3-mediated T cell activation in RIBP KO mice (Fig. 6 A) suggests that the RIBP KO T cells are capable of responding to the CD28-mediated costimulatory signal. Interestingly, Itk has been reported to be both a positive and negative regulator of CD28-mediated T cell activation. On the one hand, Itk is physically associated with CD28 after T cell activation 49, and Jurkat T cells expressing CD28 cytoplasmic tail mutants incapable of recruiting Itk are suppressed in their ability to produce IL-2. However, Littman and colleagues demonstrated that T cells from Itk-deficient mice were hyperresponsive to CD28 costimulation 15. Therefore, it remains to be determined in what context, if any, RIBP is involved in CD28 signal transduction.

Finally, the results of this study support a role for RIBP in the regulation of Th cell subset differentiation. IL-2 and IFN- production were both significantly reduced in activated RIBP KO T cells (Fig. 6 and Fig. 7), whereas IL-4 production was unaffected (Fig. 7 C). Such a selective impairment in IFN- and IL-2 production suggests that RIBP may act in signaling pathways that promote Th1 differentiation. The lack of RIBP may reduce TCR-mediated signal strength via impairment of Itk and/or Rlk function, resulting in a selective loss of Th1 differentiation, as suggested by Bottomly and colleagues 50. This may occur by generating decreased TCR signals that drive Th2 skewing. In fact, both Itk and Rlk have been implicated in T cell differentiation (Schaeffer, E., personal communication). Also, Rlk is selectively expressed in Th1-type T cells. These results may explain, at least in part, the finding that RIBP selectively affects Th1-type cytokine production.

In conclusion, we have identified and functionally characterized a novel T cell adaptor molecule involved in the regulation of responses to T cell activation stimuli, specifically proliferation and lymphokine production. This adaptor, RIBP, appears to function in TCR/CD3-mediated signal transduction, consistent with previously reported data regarding its binding partners, the Tec tyrosine kinases Rlk and Itk. The binding of RIBP to Itk and Rlk may provide important biochemical links of these two important kinases with other components in the T cell activation machinery. Further molecular studies will be needed to determine the specific sites of action of RIBP within various T cell signal transduction pathways.