Abstract
Hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP2) by phospholipase C-γ (PLCγ1) represents a critical step in T cell antigen receptor (TCR) signaling and subsequent thymocyte and T cell responses. PIP2 replenishment following its depletion in the plasma membrane (PM) is dependent on delivery of its precursor phosphatidylinositol (PI) from the endoplasmic reticulum (ER) to the PM. We show that a PI transfer protein (PITP), Nir3 (Pitpnm2), promotes PIP2 replenishment following TCR stimulation and is important for T cell development. In Nir3–/– T lineage cells, the PIP2 replenishment following TCR stimulation is slower. Nir3 deficiency attenuates calcium mobilization in double-positive (DP) thymocytes in response to weak TCR stimulation. This impaired TCR signaling leads to attenuated thymocyte development at TCRβ selection and positive selection as well as diminished mature T cell fitness in Nir3–/– mice. This study highlights the importance of PIP2 replenishment mediated by PITPs at ER-PM junctions during TCR signaling.
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Main
T lymphocytes play a central role in the adaptive immune response, providing protection from pathogens and malignant transformation. Upon engagement by their cognate antigens, TCRs trigger downstream signaling events that elicit robust T cell activation. Signaling by the TCR and the pre-TCR are also critically important for passage and maturation of thymocytes through development signaling checkpoints, including TCRβ selection, positive selection and negative selection. Compared with mature T cells, DP thymocytes are inherently more sensitive to low-potency ligands to elicit productive signals in response to weak interactions with self-peptide-MHC (pMHC) complexes on thymic stromal cells during positive selection1. The TCR sensitivity difference between immature and mature cells suggests the existence of TCR signaling components expressed selectively in thymocytes that influence TCR signaling during T cell development.
A key downstream feature of TCR signaling is elevation of intracellular free calcium concentration ([Ca2+]i)2. TCR-induced [Ca2+]i elevation is a consequence of the metabolism of PIP2 into inositol trisphosphate (IP3) and diacylglycerol (DAG) through the action of tyrosine-phosphorylated PLCγ1 (refs. 3,4). PIP2, an essential substrate for TCR-induced calcium signaling, only represents a minor lipid species in the inner leaflet of the PM5. Within one minute of stimulation with anti-CD3 antibodies, the level of PIP2 in human T cells can decrease by more than 50%. At the same time, TCR stimulation accelerates the production of PIP2 from its precursor PI to replenish the PM PIP2 pool6,7. To date, much of the knowledge about PIP2 homeostasis after TCR stimulation has been studied in immortalized human T cell lines. It is not clear how PM PIP2 levels are regulated in developing primary thymocytes or mature peripheral T cells.
PI is primarily synthesized in the ER and needs to be transferred to the PM for PIP2 synthesis. Membrane-associated PITPs are major regulators of PM PIP2 levels by transferring PI from the ER to the PM at ER-PM junctions, where the ER forms close contacts with the PM8. In mammalian genomes, there are three members of the membrane-associated PITP family. Nir1 (encoded by Pitpnm3) lacks the PITP domain and functions as a scaffold protein9. Both Nir2 (encoded by Pitpnm1) and Nir3 (encoded by Pitpnm2) transfer PI from the ER to the PM in response to PIP2 hydrolysis; they each have an intact N-terminal PITP domain and membrane-targeting C-terminal domains, which bind to phosphatidic acid (PA) and DAG10,11. Compared with Nir2, the C-terminal domains of Nir3 are more sensitive to DAG and PA production in the PM. Thus, Nir3 can translocate to ER-PM junctions at low DAG and PA levels in the PM generated in response to weak receptor stimulation. On the other hand, the PITP domain of Nir3 is less potent in transferring PI and replenishing PM PIP210. Nir2 and Nir3 have been demonstrated to regulate PIP2 homeostasis and [Ca2+]i elevation in response to angiotensin II receptor and histamine receptor stimulation10,12. However, their roles in TCR signaling are unknown.
Here, we study Nir3, a membrane-associated PITP conserved among all vertebrates and its involvement in the thymocyte selection. Nir3 is most highly expressed in late double-negative (DN) and DP thymocytes and is downregulated after positive selection. We show that Nir3 promotes both TCRβ selection and positive selection in thymocytes. Nir3 also promotes mature T cell survival in the periphery. Mechanistically, Nir3 is required for PIP2 replenishment and TCR-induced calcium signaling in response to weak TCR stimulation.
Results
Expression and evolution of Nir3 in T cell development
Across human tissues, Nir2 transcripts are ubiquitously expressed, whereas Nir3 transcripts are highly enriched in the thymus (Fig. 1a)13. In mouse T cell subsets, Nir3 transcripts are elevated in late DN to DP stages and are decreased in single-positive (SP) thymocytes and mature T cells. Interestingly, Nir3 transcripts are substantially elevated as thymocytes progress through TCRβ selection (DN3b) and positive selection (DP_Post). On the other hand, Nir2 transcripts are relatively low in late DN to DP stages and are elevated in more mature thymocytes and mature T cells (Fig. 1b). Moreover, we determined the relative protein abundance of Nir2 and Nir3 in mouse thymocytes and mouse peripheral T cells by immunoblot analysis with additional normalization controls in which Nir2-mCherry or Nir3-mCherry fusion proteins were ectopically expressed in HEK293 cells. Nir3 protein is more highly expressed in thymocytes, whereas Nir2 protein is more abundant in peripheral T cells (Fig. 1c,d). These data are consistent with published quantitative mass spectrometry analysis of T cell proteomes, which demonstrated Nir2 protein is more abundant than Nir3 protein in peripheral T cells14.
Given their sequence similarity and conserved domain organization, Nir2 and Nir3 likely arose as a result of a gene duplication event from a common ancestor during evolution. To investigate the evolutionary history of these two proteins, we identified orthologs across multiple animal lineages and developed a phylogenetic reconstruction analysis. From the reconstructed phylogenetic tree, we found that the most recent common ancestor (MRCA) of Nir2 and Nir3 was likely located at the base of all vertebrates (Extended Data Fig. 1). It is interesting to note that the modern adaptive immune system arose at a similar time in jawed vertebrates, concordant with the duplication and specialization of multiple gene families with prominent roles in TCR signaling, including Zap70/Syk and Lck/Lyn15. Moreover, our analysis suggests that shortly after the duplication of Nir2 and Nir3, the Nir2-like paralogs were lost in fish and many amphibians. As a result, all extant fish carry Nir3, but not Nir2, in their genomes, the origin of which is not well understood (Extended Data Fig. 1).
In humans, several single-nucleotide polymorphisms of Nir3 have been significantly associated with several immune-related diseases, including asthma, eczema, multiple sclerosis and type II diabetes by genome-wide association studies (GWAS Catalog, Supplementary Table 1). One of the Nir3 single-nucleotide polymorphisms, rs7132277 has been known as a non-MHC susceptibility locus associated with multiple sclerosis at a genome-wide significance level16. Collectively, our findings that Nir3 was separated from Nir2 at a similar time as emergence of the modern adaptive immune system and is associated with immune-related diseases in human highly suggest a role for Nir3 in T cell development and function.
Thymocyte maturation is accompanied by an increase in PIP2 levels
We have previously reported that thymocyte positive selection is accompanied by a gradual increase in both basal free intracellular calcium concentrations ([Ca2+]i) and TCR-induced [Ca2+]i, which reflects stronger TCR signaling17. Given the critical role of PIP2 in TCR-induced calcium signaling, we hypothesized that thymocyte maturation is also accompanied by an increase in PIP2 levels. To test this hypothesis, we used a PIP2-specific monoclonal antibody to examine PIP2 levels in thymocyte subsets. Relative to DP thymocytes, our analyses revealed significantly elevated PIP2 levels in SP thymocytes, with the highest PIP2 levels in CD8SP cells (Fig. 2a–c).
DN thymocytes can be separated into four sequential developmental stages (DN1–DN4) based on their expression of CD44 and CD25 (Fig. 2d). TCRβ selection takes place at the DN3 stage, which can be further divided into the preselection DN3a stage and the postselection DN3b stage (Fig. 2e)18. Among the different DN subsets, PIP2 levels in the cells were elevated as DN thymocytes progressed though the TCRβ-selection checkpoint. The PIP2 level peaked at the DN3b stage and was slightly diminished in cells that had progressed into the DN4 stage (Fig. 2f,g).
After the DN4 stage, thymocytes upregulate CD4 and CD8 co-receptors and enter the DP stage. Throughout the DP stage, thymocytes undergoing positive selection are present in graded states of maturation, which can be visualized by cell surface levels of CD5 and TCRβ19. Subdividing DP thymocytes based on their CD5 and TCRβ levels revealed gradual elevations in PIP2 levels as thymocytes progressed though positive selection, mirroring the elevated TCRβ levels (Fig. 2h–k). The gradually elevated PIP2 levels are also consistent with previously observed elevations in basal and TCR-induced [Ca2+]i in maturing DP thymocytes17. These data supported our hypothesis that an increase in PIP2 levels is accompanied by elevated TCR expression and correlates with the basal [Ca2+]i increase during thymocyte maturation.
Nir3 promotes TCRβ selection
The high expression of Nir3 in thymocytes suggested a role for Nir3 in thymocyte development. To study Nir3 and its role in thymocyte development, a Nir3 genetic knockout (Nir3–/–) mouse was generated using CRISPR gene editing. Overall, Nir3–/– mice were healthy and fertile and born at the expected Mendelian ratios. In the thymus, a slight but statistically significant decrease in the percentage of CD4SP thymocytes was found in Nir3–/– mice, hinting at a potential defect in thymocyte development (Fig. 3a,b). In DN thymocytes, Nir3–/– mice developed fewer DN4 cells than wild-type (WT) control mice, suggesting a partial impairment of thymocyte development in the transition from the DN3 to the DN4 stage (Fig. 3c,d). At the DN3 stage, based on expression of intracellular TCRβ (icTCRβ) and the cell activation marker CD27, there were 50% fewer postselection DN3b cells in Nir3–/– mice than in WT mice (Fig. 3e,f). The Nir3–/– DN3 cells express substantially less CD27, which suggests Nir3 is an important regulator for thymocyte passage through the TCRβ-selection checkpoint (Fig. 3g).
Positive selection is impaired in Nir3 –/– mice
To study the role of Nir3 in positive selection of DP thymocytes, we subdivided DP thymocytes into five populations based on their expression of CD5 and TCRβ. Mildly decreased percentages of more mature DP subsets were observed in Nir3–/– mice compared with WT mice (Fig. 4a). To establish whether Nir3 regulates positive selection in a T cell-intrinsic manner, we performed a competitive bone marrow (BM) repopulation study. Equal numbers of BM cells from WT CD45.1/CD45.2 heterozygous mice and from Nir3–/– CD45.2 mice were adoptively transferred into lethally irradiated CD45.1 recipients. Six weeks after the cell transfer, repopulated thymi were analyzed and WT and Nir3–/– cells were identified using CD45.1 and CD45.2 congenic markers (Fig. 4b). There were roughly equal numbers of WT and Nir3–/– cells in the DP1-DP4 stages, which mirrored the 1:1 donor cell ratio. At DP5, CD4SP and CD8SP stages, the percentages of WT cells were greater than Nir3–/– cells, which suggests fewer Nir3–/– cells passed the positive selection checkpoint and transited into the DP5 stage and SP stages (Fig. 4c). These results are consistent with Nir3 playing an important role in positive selection, which occurs at the transition from DP4 to DP5 stages of thymocyte development.
It is common to find that positive selection of the normal diverse TCR repertoire is plastic enough to compensate at least partially for alterations in TCR signal strength by a repertoire shift20. TCR repertoires in Nir3–/– CD4SP and CD8SP were assessed by sampling selected V-J rearrangements of TCRα via real-time PCR. Trav13 and Trav16 segments were selected for their favored pairing with proximal Jα segments or equally usage proximal and distal Jα segments, respectively21. In CD4SP thymocytes, rearrangements of both Vα segments to Jα segments were comparable between WT and Nir3–/– cells. Yet, in Nir3–/– CD8SP thymocytes, rearrangements of both Vα segments to proximal Jα segments were markedly increased, whereas rearrangements of Trav13 to the most distal Jα2 segment was markedly reduced (Extended Data Fig. 2). Our data indicate biased selection of a different TCR repertoire in Nir3–/– mice, at least in the CD8 lineage.
To avoid the impact of repertoire shifts in diverse TCR repertoire mice, we analyzed the effect of Nir3 deficiency on thymocyte development in OT-I TCR transgenic mice (OVA pMHC reactive TCR), in which all T cells express the same transgenic TCR. We firstly noticed an increase in total thymic cellularity in Nir3–/– OT-I mice compared to WT OT-I mice (Fig. 4d). The defect in positive selection was much more pronounced in Nir3–/– OT-I mice than in Nir3–/– mice with a diverse TCR repertoire. Both the percentages and absolute numbers of CD8SP thymocytes in Nir3–/– OT-I mice were substantially lower compared with WT OT-I mice (Fig. 4e–g). Within the DP thymocytes, we observed pronounced increased DP1 and decreased DP5 cells in Nir3–/– OT-I mice compared to WT OT-I mice (Fig. 4h,i). Fixing the TCR specificity in OT-I mice better highlighted the important role for Nir3 in thymocyte development.
Role of Nir3 in agonist-selected T cell development in thymus
During development, DP thymocytes expressing self-reactive TCRs are either deleted via negative selection or diverted into alternative T cell lineages, maintaining their self-reactivity. Lineage diversion of such self-reactive thymocytes is known as agonist selection and gives rise to natural killer T (NKT) cells, thymic-derived regulatory T cells (Treg cells) and intraepithelial lymphocyte precursors (IELp’s)22. Although the environmental factors and signaling cues specifying these divergent fates remain unclear, one notion posits that intermediate TCR self-reactivities between positive and negative selection are required for agonist selection. However, recent studies have challenged this theory. TCR repertoire analysis suggested that Treg TCR repertoire may be quite broad overlapping with the conventional CD4 T cells and thymocytes undergoing negative selection23. In mice expressing a Nur77-GFP reporter, the expression of which correlates with the strength of TCR signaling, Nur77-GFP expression in thymic Treg and NKT cells is broad and largely overlapping with conventional CD4SP thymocytes24. On the other hand, studies using mice expressing OT-I TCR along with transgenic expression of the agonist ligand by medullary thymic epithelial cells (RIPmOVA mice) revealed the affinity threshold for thymic IELp development was higher than for negative selection25. Collectively, these findings suggest that the selection thresholds of TCR signaling strength in some Treg and NKT cells can be as low as the threshold for selection of conventional T cells, whereas the selection thresholds of IELp’s are much higher. Consequently, based on our observed role of Nir3 in positive selection of conventional T cells, we hypothesized that Nir3 may also regulate development of Treg and NKT cells, but not IELp’s.
Among these agonist-selected T cells, Nir3 transcripts are highly expressed in thymic NKT cells (Fig. 1b). NKT cells are a subset of T cells expressing CD1d-restricted TCRs26. NKT cells can be subdivided into NKT1, NKT2 and NKT17 cells based on different patterns of cytokine secretion27. In Nir3–/– mice, the percentages of NKT cells in CD8- thymocytes and the number of NKT cells in the thymus were lower compared with WT mice (Extended Data Fig. 3a,b). Nir3–/– NKT cells express significantly less PLZF (Extended Data Fig. 3c,d), a critical transcription factor for NKT differentiation induced by NFAT signaling28. Based on the expression levels of transcription factor PLZF and RORγt, Nir3–/– mice developed significantly fewer NKT1 and NKT2 cells but comparable numbers of NKT17 cells compared with WT mice (Extended Data Fig. 3e–g).
We studied the thymic Treg cell development in Nir3–/– mice and in BM chimeric mice. In both cases, Nir3–/– mice or cells develop 30%-50% fewer natural Treg cells in the thymus (Extended Data Fig. 4). In contrast, we did not observe significant changes in the frequency of IELp’s generated from WT and Nir3–/– cells in the BM chimeric mice (Extended Data Fig. 5). Overall, our data revealed the differential requirements for Nir3 during development of different subsets of agonist-selected T cells.
Lymphopenia in Nir3 –/– peripheral lymphoid organs
Compared to WT mice, Nir3–/– mice had significantly fewer cells in the spleen and inguinal lymph nodes, but a comparable number of cells in the mesenteric lymph node harvested from unimmunized 8-week-old mice (Fig. 5a–c). Fewer CD4 and CD8 T cells were identified in the spleens of Nir3–/– mice than in the spleens of WT mice (Fig. 5d). To determine whether the Nir3 deficiency led to lymphopenia in a T cell-intrinsic manner, we performed a competitive BM repopulation experiment. Six weeks after BM cell transfer, DN thymocytes of the recipient mice consisted of roughly 50% WT and 50% Nir3–/– cells, which reflected the initial 1:1 ratio of transferred BM cells. In the spleens of the recipient mice, there were significantly more WT T cells than Nir3–/– cells in both CD4 and CD8 compartments (Fig. 5e). In Nir3–/– CD4 cells, there were lower percentages of effector memory-like (TEM) cells compared to WT CD4 cells. Nir3–/– CD8 lineage T cells were composed of fewer TEM cells and central memory-like (TCM) cells compared to WT CD8 cells (Fig. 5f,g). Moreover, we studied the BM chimeras with OT-II TCR transgenics, which showed similar phenotypes compared with the polyclonal repertoire BM study. Nir3–/– OT-II BM cells generated similar numbers of preselection thymocytes, but fewer numbers of postselection thymocytes and peripheral T cells (Extended Data Fig. 6). In sum, our data revealed that Nir3 deficiency led to lymphopenia and fewer memory-like T cells in peripheral lymphoid organs.
Nir3 regulates mature T cell survival in the periphery
The positive selection blockade resulting from Nir3 deficiency may contribute to lymphopenia in the secondary lymph organs. On the other hand, a reduction in CD44hi Nir3–/– cells potentially reflects less homeostatic T cell expansion in the periphery29. To study the role of Nir3 in T cell survival in the periphery, CellTrace dye-labeled WT and Nir3–/– mature T cells were mixed and adoptively transferred into lymphoreplete WT recipient mice. Four and 10 days after the transfer, the percentages of WT CD4 and CD8 T cells were increased, suggesting a survival advantage of WT over Nir3–/– T cells (Fig. 6a). Moreover, Nir3–/– OT-I and OT-II cells showed more severe survival disadvantages in naive recipient mice compared with WT OT-I and OT-II cells, respectively (Fig. 6b). In lymphoreplete recipient mice, most of the adoptively transferred T cells had not undergone cell division, reflected by their largely undiluted CellTrace dye (Fig. 6c,d). Significantly fewer transferred Nir3–/– OT-I and OT-II cells expressed Ki67, indicating cell cycle entry, compared with WT OT-I and OT-II cells in naive recipient mice, respectively (Fig. 6c–e). We further examined the homeostatic proliferative potentials of Nir3–/– T cells in lymphopenic Tcra–/–mice. Nir3–/– OT-I and OT-II cells expressed less Ki67 compared with WT OT-I and OT-II cells (Fig. 6f–h). Our data suggest that Nir3 plays an important role in survival of mature T cells in the periphery, possibly by regulating TCR signaling in response to self-pMHC.
Nir3 promotes PIP2 replenishment following TCR stimulation
The defects in T cell development and survival in the periphery suggested a role for Nir3 in response to weak TCR stimuli. We hypothesized that Nir3 regulated the replenishment of PM PIP2 levels in T cells following TCR stimulation. Nir3–/– DP thymocytes and mature T cells have similar basal PIP2 levels with WT DP thymocytes and mature T cells, respectively (Extended Data Fig. 7). Nir3–/– T lineage cells replenished PIP2 levels significantly more slowly after soluble anti-CD3 antibody stimulation (Fig. 7a). The defect is more pronounced in DP thymocytes and CD4 T cells than CD8 T cells, possibly due to relatively high Nir3 expression in thymocytes and relatively low expression in mature CD8 cells (Fig. 1d). Because Nir2 is more abundant than Nir3 in peripheral T cells (Fig. 1d), we compared Nir2 with Nir3 for their contributions to PIP2 replenishment by delivering Nir2 siRNAs to WT and Nir3–/– T cell blasts (Extended Data Fig. 8a). PIP2 replenishment following TCR stimulation was more impaired in Nir2 knockdown cells than Nir3–/– cells, whereas PIP2 replenishment was most severely attenuated in Nir2 knockdown in Nir3–/– cells (Extended Data Fig. 8b).
We further tested the role of Nir3 in PIP2 replenishment in the PMs of mature T cells in response to immobilized anti-CD3 antibody stimulation. We stimulated Tubby-mScarlet (a PIP2 biosensor) expressing Nir3–/– OT-II cells on coverslips coated with anti-CD3 antibody. PIP2 levels were quantified by the MFI of the Tubby-mScarlet biosensor in the PMs of spreading cells on glass using total internal reflection fluorescence (TIRF) microscopy. The PIP2 levels in Nir3–/– OT-II cells were more strikingly depleted and not replenished compared with WT OT-II cells (Fig. 7b,c). Because anti-CD3 monoclonal antibody is such a potent stimulus, we stimulated the Tubby-mScarlet expressing Nir3–/– OT-I cells on coverslips coated with full (OVA), partial (T4) or weak agonist (G4) OVA pMHC tetramers. The depletion of PIP2 was more sustained and the replenishment of PIP2 levels was much slower in Nir3–/– OT-I cells than in WT OT-I cells in all three different stimulation conditions (Fig. 7d–i). During the PIP2 replenishment, we noticed that Tubby formed punctate patterns on the PMs, which suggested PIP2 synthesis is clustered, probably at sites of PI delivery at ER-PM junctions (Fig. 7b,d,f,h). Our data largely support our hypothesis that Nir3 plays an important role of PIP2 replenishment in thymocytes and mature T cells in response to TCR stimulation.
Nir3 regulates TCR downstream signaling in DP thymocytes
We assessed whether the defects in PIP2 replenishment led to impaired of TCR signaling in Nir3–/– thymocytes. In WT DP thymocytes, consistent with our previous report, peak TCR-induced [Ca2+]i elevation increases from DP1 to DP5 stages of maturation (Fig. 8)17. In Nir3–/– DP5 thymocytes, stimulation with a lower concentration of anti-CD3 antibodies (0.1μg/ml) led to more impaired [Ca2+]i elevation compared with WT DP5 thymocytes. Compared with the most mature DP5 cells, Nir3 deficiency has a greater impact on TCR-induced [Ca2+]i elevation in less mature DP1-DP4 thymocytes, which also express fewer cell surface TCR molecules and lower PIP2 levels (Fig. 8). Of note, stimulation of the thymocytes at various stages of DP development with thapsigargin or ionomycin had no differential effect since these reagents increase [Ca2+]I via mechanisms that bypass the PIP2 dependent events at the PM. Overall, our results suggested that Nir3 is critical for [Ca2+]i elevation induced by weaker TCR stimulation in thymocytes.
We next assessed whether Nir3 regulates TCR-induced Erk phosphorylation (pErk) as a consequence of PIP2 hydrolysis and the generation of DAG and its regulation of the RasGRP guanine nucleotide exchange factor30. Upon stimulation with 10 μg ml−1 anti-CD3 antibodies, Nir3–/– DP thymocytes at different maturation stages exhibited similar levels of pErk compared with WT thymocytes. However, upon stimulation with 1 μg ml−1 anti-CD3 antibodies, Nir3–/– DP thymocytes at DP4 and DP5 stages exhibited substantially less pErk compared with WT thymocytes at the same stages (Extended Data Fig. 9a). This suggests Nir3 has a greater impact in regulating the activation of the Ras/MAPK pathway in response to weak TCR stimuli rather than strong TCR stimuli in DP thymocytes.
Next, we tested the activation thresholds of Nir3–/– DP1 and DP5 thymocytes in response to agonist pMHC ligands of different potencies. Nur77 expression was used as a readout of TCR signaling strength, and CD69 upregulation was selected as an integrated activation marker31. Nir3–/– DP1 thymocytes expressed substantially less Nur77 than WT DP1 thymocytes at the basal level and after stimulation with strong (OVA) or weak peptide (G4). On the other hand, Nir3–/– DP5 thymocytes expressed comparable levels of Nur77 compared with WT DP5 thymocytes in response to full agonist peptide (OVA) stimulation, but slightly less Nur77 with positive selecting peptide Cappa1 stimulation (Extended Data Fig. 9b).
Our data demonstrate that Nir3 is involved in regulating TCR signaling in DP thymocytes and likely in both pre-TCR signaling during TCRβ-selection and in peripheral T cell tonic signaling. The accumulation of TCR signaling defects was observed at different stages of Nir3–/– thymocyte development and is likely to contribute to T cell survival defects in Nir3–/– mice. Our data also suggests that differential expression of Nir2 and Nir3, together with other calcium signaling molecules, may contribute to the TCR sensitivity difference between preselection thymocytes and mature T cells (Extended Data Fig. 10).
Discussion
Among five PITPs in the human genome, only Nir2 and Nir3 have been shown to dynamically localize at ER-PM junctions following receptor-induced PIP2 hydrolysis and to regulate PIP2 levels32. In this study, we report that Nir3, the expression of which is preferentially upregulated in preselection thymocytes, plays an important role in thymocyte development and in mature T cell survival in the periphery. Mechanistically, by transporting the precursor PI from the ER to the PM Nir3 maintains and replenishes PM PIP2 levels in response to TCR simulation by weak ligands. Rapid replenishment of PM PIP2 levels supports adequate TCR-induced calcium signaling involved in maturation, developmental checkpoints and survival.
In unstimulated thymocytes and T cells, Nir3 deficiency did not affect basal PIP2 levels. Besides nonvesicular lipid transport which is mediated by PITPs at ER-PM junctions, the ER exchanges bulk lipids with the PM through vesicular lipid transport via the Golgi apparatus33. It is more plausible that the amount of PI for maintaining basal PIP2 levels is largely transported through the vesicular transport in quiescent T cells. Compared with the slow lipid transport by vesicular traffic, which could take one hour or longer, nonvesilcular lipid transport at the ER-PM junctions is much faster and occurs over time frames of seconds or a few minutes33,34,35. In T cells, only such a rapid transfer mechanism might be required compensate for the swift PIP2 depletion in the PM induced by TCR stimulation, which makes ER-PM junctions potentially important subcellular structures for TCR-induced calcium signaling.
Following TCR stimulation, new ER-PM junctions form rapidly following the ER calcium depletion36. In addition to transferring PI, ER-PM junctions could provide docking sites for various TCR signaling molecules. For example, scaffolding proteins such as Tespa1 and SLAT could potentially contribute to the recruitment of PLCγ1 and IP3 receptors (IP3Rs) to the same macromolecular LAT signaling complex at the ER-PM junctions. This could increase signal transduction rates from PIP2 hydrolysis to ER calcium depletion37,38. Most ER-PM junctions are formed in gaps within the cortical actin mesh structure39. Our previous studies utilizing a model Csk inhibition system, have suggested that cortical actin cytoskeleton may act as a barrier to TCR signaling by sequestering activated LAT-bound PLCγ1 from its substrate PIP2 on the PM40. It is possible that TCR stimulation contributes to the formation of new or larger gaps in the cortical actin cytoskeleton via the activation of Rac/Rho GEFs and Rac/Rho GTPases41,42. Such remodeling could permit new and expanded ER-PM junctions that could promote the access of PLCγ1 to PIP2 and the consequent hydrolysis of PIP2. Hydrolysis of PIP2 and generation of DAG triggers the release of PIP5 kinases from the PM which could further enhance the actin clearing at the immune synapses43. Taken together, ER-PM junctions are potentially critical subcellular structures in T cells for calcium-mediated signal transduction. Our findings highlight the importance of Nir3 in TCR-induced calcium signaling at ER-PM junctions.
Proper TCR-induced calcium signaling is important for both TCRβ selection and positive selection in thymus. Mice carrying a point mutation in the PLCγ1 binding site of LAT (Y136F) exhibited a severe block of thymocyte development at the DN3 stage before TCRβ selection44,45. In previous reports, deleting PLCγ1 at early DP stages led to a complete block of thymocyte development at the positive selection stage46. Mice lacking both Rlk and Itk, two Tec kinases phosphorylating PLCγ1 in T cells, showed defects at both TCRβ selection and positive selection steps47. In this study, we found that PIP2 levels in thymocytes increase significantly as cells pass both TCRβ selection and positive selection. The increase of PIP2 is concordant with both basal and TCR-induced [Ca2+]i as thymocytes mature17. The increase of PIP2 can influence the TCR threshold and facilitate thymocyte passage through these selection checkpoints. Indeed, we found that thymocytes are more sensitive to weaker TCR stimulation as they approach the positive selection checkpoints. Likewise, the signaling via the pre-TCR is thought to deliver weak signaling as well. Nir3 contributes greatly to the increased sensitivity to weaker TCR stimulation in immature thymocytes.
The functional differences between Nir2 and Nir3 are mostly quantitative rather than qualitative. Nir3 has a reduced rate of PI transfer but an enhanced ability to sense PA on the PM10. These features enable Nir3 to rapidly replenish PM PIP2 levels in response to weak TCR stimulation. With its higher expression in preselection thymocytes, Nir3 appears to be an elaborately evolved gene specialized for T cell development. Such a highly specialized gene that is well suited for T cell development is not an exception and can be repeatedly found in mammalian genomes. The IP3 receptor type 2 (ITPR2) and stromal interaction molecule 2 (STIM2) are two other examples which are also involved in TCR-induced calcium signaling. IP3 receptors sense IP3 generated by PIP2 hydrolysis and release calcium from the ER lumen to the cytosol. There are three IP3 receptor subunits in the mammalian genome, ITPR1, ITPR2 and ITPR3. ITPR2 has the highest affinity to IP3 and highest expression level in preselection thymocytes, whereas ITPR3 has the least affinity to IP3 and highest expression level in mature T cells48. Moreover, STIM1 and STIM2 are the molecular sensors of the ER calcium depletion. They oligomerize upon ER calcium depletion and open the Orai calcium channels on the PM to induce store-operated calcium entry. Compared with STIM1, STIM2 is more sensitive to the depletion of ER calcium. Expression profiles of the two STIM genes during the T cell development revealed that expression of STIM2 peaks at preselection thymocytes, whereas STIM1 is dominantly expressed in mature T cells49. Like Nir2 and Nir3, the separation of IP3 receptor genes and STIM genes took place at the origin of vertebrates49,50. After 500 million years of evolution, the thymocyte expressing paralog(s) of each gene have all evolved with enhanced sensitivity for events involved in TCR signaling compared with their paralogs expressed in mature T cells. These findings suggest that an extremely sensitive calcium signaling machinery in response to weak TCR stimulation is an evolutionary adaptation for thymocyte development.
Methods
Mice
To generate Nir3–/– mice, a Nir3-targeting guide RNA that targets Cas9 to a site near in the fourth exon of Nir3 and purified Cas9 were obtained from PNA Bio INC. Purified Cas9 and Nir3-targeting gRNA were injected into C57BL/6 zygotes at the UCSF Diabetes Research Center Core. The resulting pups carrying a 98 bp deletion were genotyped by amplifying a 413 bp region flanking the targeted region (Supplementary Fig. 1). The mice were backcrossed to C57BL/6 mice for at least six generations. BoyJ (CD45.1) mice were obtained from The Jackson Laboratory (B6.SJL-Ptprca Pepcb/BoyJ). CD45.1/CD45.2 mice were generated by crossing BoyJ and C57BL/6 mice. All mice used in these studies were housed in a specific-pathogen-free facility at UCSF according to the University Animal Care Committee and National Institutes of Health (NIH) guidelines.
Antibodies and reagents
Antibodies and reagents are listed in the Supplementary Table 2.
PIP2 measurements
For measurements of PIP2 in thymocytes using immunostaining, biotinylated monoclonal anti-PIP2 antibody (clone 2C11, Echelon Biosciences) was used as previously described51. Briefly, thymocytes were stained for surface markers and rapidly fixed by 4% paraformaldehyde (PFA) and 0.2% glutaraldehyde (GA) for 15 min at 20 °C. Fixed cells were then placed ice for 2 min and all subsequent staining steps were performed on ice. Cells were blocked and permeabilized for 45 min with PIPES buffer (Thermo Scientific, pH 7.0) containing 5% (v/v) normal goat serum (NGS), 50 mM NH4Cl and 0.5% saponin. 2.5 μg ml−1 anti-PIP2 antibodies were applied in PIPES buffer with 5% NGS and 0.1% saponin for 1 hour. After two washes in PIPES buffer, a 45 min incubation with fluorescent conjugated streptavidin in PIPES buffer with 5% NGS and 0.1% saponin was performed. Cells were then rinsed four times with PIPES buffer and analyzed by flow cytometry.
For measurements of dynamic changes of PIP2 at the PM during TCR stimulation, the intensity of PIP2 biosensor Tubby was monitored by TIRF microscopy in OT-I and OT-II T cells stimulated in coverslip chambers. Glass surfaces of coverslip chambers were coated with either stimulatory antibody (anti-CD3) or streptavidin (SA). Surfaces were then washed and biotinylated monomeric pMHC complexes were incubated with SA surfaces. Surfaces were then washed and used for antigen presentation. OT-I or OT-II cells resuspended in the complete media were added in chambers coated with stimulatory reagents at 37 °C. Individual immunological synapses formed on stimulatory glasses were imaged with the Nikon Ti Microscope with TIRF every 15 s for at least 4 min after cells first interacting the glasses. Areas of immunological synapses were selected based on Tubby. Tubby MFI within each synapse in each frame was normalized to the first frame after cell interacting the glasses (time 00:00). The microscopy was controlled by the NIS-Elements AR imaging software v5.41.02 and a ×100 oil dipping objective was used. The data were processed by ImageJ software v2.3.0/1.53p.
Competitive repopulations and chimeras
For competitive repopulation assays, BM harvested from the femurs and tibias from 8- to 12-week-old adults were injected intravenous into lethally irradiated (two doses of 493 rad) CD45.1 BoyJ hosts, and reconstituted thymi were analyzed 6–8 weeks later. At least 5 × 106 total BM cells were injected intravenous into each mouse. Within an experiment, all hosts were sex and age matched and were between 8 and 12 weeks old.
Peripheral T cell isolation and transfection
Splenic T cells were isolated using Dynabead untouched negative selection kit (Stemcell EasySep) and stimulated with anti-CD3 and anti-CD28 antibody coated Dynabeads (Dynabeads Mouse T-Activator CD3/CD28, ThermoFisher) in RPMI 1640 medium supplemented with 10% FCS, Hepes, 50 μM 2-Mercaptoethanol and L-glutamine (T cell media). After 48 h, Dynabeads were removed. Cells were washed twice in PBS and resuspended at 5 × 106 cells per 100 μl in Neon transfection buffer R (Invitrogen) and mixed with 20μM siRNA (Ambion/Life Technologies) before being immediately electroporated for 3 × 10 ms at 1,550 V on a Neon transfection instrument. The 100-μl transfection was then transferred directly into pre-warmed T cell media containing 10 ng ml−1 IL-7 in a flat-bottomed 24-well plate (Costar) for another 48 h. Knockdown efficiencies were assessed by immunoblots. Scrambled siRNA: Silencer Select Negative Control No. 2 siRNA (ThermoFisher); Nir2 siRNA-1: 5′-GCUCUUGUCUCCAACCUGAtt-3′; Nir2 siRNA-2: 5′-AGAGAAUCGUGGAUACCAUtt-3’. To knockdown Nir2 in peripheral T cells, Nir2 siRNA-1 and siRNA-2 were equally mixed and transfected.
OT-I co-culture
Splenocytes were used as antigen-presenting cells and were isolated from T cell-deficient mice (Tcra–/– mice). Prior to culture, red blood cells were removed using ACK lysis. Splenocytes were incubated with peptide antigens for 1 h at 37 °C. OT-I thymocytes or T cell blasts were added at a ratio of 5:1 (APC/thymocytes). Cells were cultured 3 to 4 h at 37 °C and then stained for CD69 and other surface markers (CD8α, TCRβ or Vα2) using an antibody dilution of 1:200 in FACS buffer (1x PBS, 1% BSA, 0.5 mM EDTA, 2 mM NaN3) and Fc blocking antibody (2.4G2) at 1:1,000. Washed cells were rapidly fixed by 4% paraformaldehyde for 15 min at 20 °C. Fixed cells were then permeabilized with 0.1% Triton X-100 (diluted in PBS) at 20 °C for 10 min. Anti-Nur77 antibodies were applied in FACS buffer for 30 min. After two washes in FACS buffer, upregulation of Nur77 and/or CD69 in cells were assessed by flow cytometry using a BD Fortessa and quantified using FlowJo software. The OVA peptide (SIINFEKL), its variants (T4, G4), the VSV peptide and the Cappa1 peptide (ISFKFDHL) were synthesized by Genescript.
Retroviral transduction of mouse T cells
Naive OT-I or OT-II T cells were isolated using magnetic bead-mediated negative selection (Miltenyi Biotec). Isolated T cells were cultured with mouse T-Activator (anti-CD3/anti-CD28) dynabeads and 50 U ml−1 IL-2 in a 24-well plate overnight. The retroviral supernatants were mixed with Lipofectamine, incubated at 25 °C for 20–30 min and then added into the T cell culture. The plate was wrapped in saran wrap and centrifuged at 460 g for 1 h at 25 °C. The plate was then moved to a 37 °C incubator. Expression of mScarlet was monitored using an LSR Fortessa (BD Biosciences) and samples were analyzed 24 h after transduction.
Expression of Nir2 and Nir3
The RNA expression levels of Nir2 and Nir3 across 55 human tissues were obtained from the Human Protein Atlas database (www.proteinatlas.org)52. The consensus dataset was used which consists of normalized expression levels for 55 tissue types, created by combining the HPA and GTEx transcriptomics datasets using their internal normalization pipeline. The RNA expression levels of Nir2 and Nir3 in mouse T cell subsets were determined from the ImmGen database (www.immgen.org)53,54. The ImmGen Microarray phase 1 dataset was used which consists of normalized expression levels for primary cells from 6-week-old C57BL/6 male mice.
The relative protein abundance of Nir2 and Nir3 in mouse thymocytes and mouse peripheral T cells was determined by immunoblots. Roughly equal amount of ectopically expressed Nir2-mCherry and Nir3-mCherry in HEK293 cells were loaded as normalization controls, which was confirmed by mCherry blots. The intensities of Nir2 and Nir3 protein bands of thymocytes or peripheral T cells were initially normalized by actin and subsequentially normalized by Nir2 or Nir3 bands of ectopically expressed Nir2-mcherry or Nir3-mcherry, respectively. The normalized amount of Nir2 and Nir3 in different cell subsets were further normalized to Nir2 levels in thymocytes, which were set to 1.
Sequence alignments and analysis
Potential orthologues for Nir2 and Nir3 were derived from the InterPro Scan database employing the following procedure. Using human protein sequences as inputs (UniProt ID’s O00562 and Q9BZ72 for Nir2 and Nir3 respectively), a list of orthologues for each protein across species was obtained, stretching as far as sponges, a lineage at the base of animalia that diverged nearly ~1,000 million years ago from Homo sapiens. Subsequently, from each of these lists, sequences were filtered to remove sequences with outlier lengths (<750 or >1,750 amino acids), present originally due to paralogs of Nir1 as well as other isoforms of PITP-domain-containing proteins. When multiple orthologs were present for a single species, an annotated reference sequence was chosen if available, otherwise, the isoform with closest similarity to the human Nir2/Nir3 protein was retained. A joint sequence list was created, removing duplicates of orthologs in the same species and reflecting an underlying absence of one of the Nir2/Nir3 proteins.
MAFFT was used to construct a multiple sequence alignment for this list of sequences. TrimAI was used to trim for regions with more than 20% gaps and the trimmed multiple sequence alignment was used as input for phylogenetic reconstruction by maximum likelihood analyses through FastTree MP. The initial alignment covered over 750 sequences across 600 species and Phylogenetic Diversity Analyzer was used to generate a subsampled sequence list that simultaneously preserved tree features but with an emphasis on the vertebrate lineage with select but well-spaced outgroups including chordates, invertebrates and sponges (totally 200 sequences). This subsampled list was subsequently aligned, trimmed, and a tree was generated as described above, and annotated manually using the ITOL website.
Phospho-Erk staining
Cells were stimulated in RPMI and fixed by adding BD Fixation/Permeabilization solution (1:1 ratio, PFA-based fixation reagent, BD Biosciences) and incubating for 10 min at 20 °C. Cells were pelleted and rinsed with FACS buffer (PBS supplemented with 2% FBS and 2 mM EDTA). Cells were then placed on ice and ice-cold 90% methanol was added to permeabilize the cells for 45 min. Cells were then rinsed three times with FACS buffer and resuspended in staining solution (anti-phospho-Erk 1:100 in FACS buffer). Cells were stained for either 1 h at 20 °C or overnight at 4 °C. Cells were rinsed three times and stained with anti-Rabbit PE antibody (1:100 in FACS buffer) for 30 min at 20 °C. Cells were rinsed twice and analyzed by flow cytometry using a LSR Fortessa controlled by BD FACSDiva v8.0.1 software and quantification performed using FlowJo software.
Calcium assays
Cells were loaded with the Indo1-AM (1.5 μM, Invitrogen) for 30 min at 37 °C in RPMI with 10% fetal bovine serum, washed, surface stained and kept on ice in RPMI. Cells were warmed to 37 °C for 5 min before stimulation. Changes in Indo1 fluorescence in cells were recorded using a FlexStation or a LSR Fortessa controlled by BD FACSDiva v8.0.1 software. FACS data were exported from FlowJo in CSV format and analyzed with an R script (https://github.com/richard02050411/Calcium-Flux-FACs/blob/master/R-code). Graphs were generated using Graphpad Prism software.
Quantification and statistical analysis
Statistical analysis was applied to biologically replicates for each experiment. No statistical methods were used to pre-determine sample sizes, but our sample sizes are similar to those reported in previous publications55,56,57. Data distribution was assumed to be normal but this was not formally tested. No randomization was used in experiments. In animal experiments, age matched animals were allocated based on their genotypes. In cell stimulation experiments, cells with the same genotype were pooled together and equally allocated into different groups before treatments. Data collection and analysis were not performed blind to the conditions of the experiment. The numbers of independent experiments performed with similar results are indicated in the figure legends. No animals or data points were excluded from the analyses in all experiments. All statistical analyses of experiments were performed using two-tailed Student t-tests, One-way or two-way ANOVA with multiple comparisons. GraphPad Prism 8 Software (GraphPad Software) was used for data analysis and representation. All bar graphs show means with overlaid scatter dots, or error bars (indicating s.e.m.), to show the distribution of the data, as indicated in each figure legend.
Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Data availability
RNA expression profiles of Nir2 and Nir3 in human tissues and mouse T cell populations are available on the Human Protein Atlas (https://www.proteinatlas.org/) and Immunological Genome Project (https://www.immgen.org/), respectively. Source data are provided with this paper.
Code availability
Increase of free cytoplasmic calcium was analyzed with an R script, which is available at GitHub (https://github.com/richard02050411/Calcium-Flux-FACs/blob/master/R-code).
References
Davey, G. M. et al. Preselection thymocytes are more sensitive to T cell receptor stimulation than mature T cells. J. Exp. Med. 188, 1867–1874 (1998).
Smith-Garvin, J. E., Koretzky, G. A. & Jordan, M. S. T cell activation. Annu Rev. Immunol. 27, 591–619 (2009).
Weiss, A., Koretzky, G., Schatzman, R. C. & Kadlecek, T. Functional activation of the T-cell antigen receptor induces tyrosine phosphorylation of phospholipase C-gamma 1. Proc. Natl Acad. Sci. USA 88, 5484–5488 (1991).
Imboden, J. B. & Stobo, J. D. Transmembrane signalling by the T cell antigen receptor. Perturbation of the T3-antigen receptor complex generates inositol phosphates and releases calcium ions from intracellular stores. J. Exp. Med. 161, 446–456 (1985).
Tuosto, L., Capuano, C., Muscolini, M., Santoni, A. & Galandrini, R. The multifaceted role of PIP2 in leukocyte biology. Cell. Mol. Life Sci. 72, 4461–4474 (2015).
Inokuchi, S. & Imboden, J. B. Antigen receptor-mediated regulation of sustained polyphosphoinositide turnover in a human T cell line. Evidence for a receptor-regulated pathway for production of phosphatidylinositol 4,5-bisphosphate. J. Biol. Chem. 265, 5983–5989 (1990).
Zaru, R., Berrie, C. P., Iurisci, C., Corda, D. & Valitutti, S. CD28 co-stimulates TCR/CD3-induced phosphoinositide turnover in human T lymphocytes. Eur. J. Immunol. 31, 2438–2447 (2001).
Chang, C. L., Chen, Y. J. & Liou, J. ER-plasma membrane junctions: Why and how do we study them? Biochim. Biophys. Acta, Mol. Cell. Res. 1864, 1494–1506 (2017).
Quintanilla, C. G. et al. Nir1 constitutively localizes at ER-PM junctions and promotes Nir2 recruitment for PIP2 homeostasis.Mol. Biol. Cell 33, br2 (2022).
Chang, C. L. & Liou, J. Phosphatidylinositol 4,5-Bisphosphate Homeostasis Regulated by Nir2 and Nir3 Proteins at Endoplasmic Reticulum-Plasma Membrane Junctions. J. Biol. Chem. 290, 14289–14301 (2015).
Chang, C. L. et al. Feedback regulation of receptor-induced Ca2+ signaling mediated by E-Syt1 and Nir2 at endoplasmic reticulum-plasma membrane junctions. Cell Rep. 5, 813–825 (2013).
Kim, Y. J., Guzman-Hernandez, M. L., Wisniewski, E. & Balla, T. Phosphatidylinositol-phosphatidic acid exchange by Nir2 at ER-PM contact sites maintains phosphoinositide signaling competence. Dev. Cell 33, 549–561 (2015).
Lev, S. et al. Identification of a novel family of targets of PYK2 related to Drosophila retinal degeneration B (rdgB) protein. Mol. Cell. Biol. 19, 2278–2288 (1999).
Howden, A. J. M. et al. Quantitative analysis of T cell proteomes and environmental sensors during T cell differentiation. Nat. Immunol. 20, 1542–1554 (2019).
Flajnik, M. F. & Kasahara, M. Origin and evolution of the adaptive immune system: genetic events and selective pressures. Nat. Rev. Genet. 11, 47–59 (2010).
International Multiple Sclerosis Genetics, C. Analysis of immune-related loci identifies 48 new susceptibility variants for multiple sclerosis. Nat. Genet. 45, 1353–1360 (2013).
Ross, J. O. et al. Distinct phases in the positive selection of CD8+ T cells distinguished by intrathymic migration and T-cell receptor signaling patterns. Proc. Natl Acad. Sci. USA 111, E2550–E2558 (2014).
Carpenter, A. C. & Bosselut, R. Decision checkpoints in the thymus. Nat. Immunol. 11, 666–673 (2010).
Saini, M. et al. Regulation of Zap70 expression during thymocyte development enables temporal separation of CD4 and CD8 repertoire selection at different signaling thresholds. Sci. Signal 3, ra23 (2010).
Fischer, A. & Malissen, B. Natural and engineered disorders of lymphocyte development. Science 280, 237–243 (1998).
Rupp, L. J., Chen, L., Krangel, M. S. & Bassing, C. H. Molecular analysis of mouse T cell receptor alpha and beta gene rearrangements. Methods Mol. Biol. 1323, 179–202 (2016).
Stritesky, G. L., Jameson, S. C. & Hogquist, K. A. Selection of self-reactive T cells in the thymus. Annu Rev. Immunol. 30, 95–114 (2012).
Hsieh, C. S., Lee, H. M. & Lio, C. W. Selection of regulatory T cells in the thymus. Nat. Rev. Immunol. 12, 157–167 (2012).
Moran, A. E. et al. T cell receptor signal strength in Treg and iNKT cell development demonstrated by a novel fluorescent reporter mouse. J. Exp. Med. 208, 1279–1289 (2011).
Kurd, N. S. et al. Factors that influence the thymic selection of CD8alphaalpha intraepithelial lymphocytes. Mucosal Immunol. 14, 68–79 (2021).
Gapin, L., Matsuda, J. L., Surh, C. D. & Kronenberg, M. NKT cells derive from double-positive thymocytes that are positively selected by CD1d. Nat. Immunol. 2, 971–978 (2001).
Engel, I. & Kronenberg, M. Transcriptional control of the development and function of Valpha14i NKT cells. Curr. Top. Microbiol Immunol. 381, 51–81 (2014).
Seiler, M. P. et al. Elevated and sustained expression of the transcription factors Egr1 and Egr2 controls NKT lineage differentiation in response to TCR signaling. Nat. Immunol. 13, 264–271 (2012).
Sprent, J. & Surh, C. D. Normal T cell homeostasis: the conversion of naive cells into memory-phenotype cells. Nat. Immunol. 12, 478–484 (2011).
Kortum, R. L., Rouquette-Jazdanian, A. K. & Samelson, L. E. Ras and extracellular signal-regulated kinase signaling in thymocytes and T cells. Trends Immunol. 34, 259–268 (2013).
Ashouri, J. F. & Weiss, A. Endogenous Nur77 is a specific indicator of antigen receptor signaling in human T and B cells. J. Immunol. 198, 657–668 (2017).
Chang, C. L. & Liou, J. Homeostatic regulation of the PI(4,5)P2-Ca(2+) signaling system at ER-PM junctions. Biochim. Biophys. Acta 1861, 862–873 (2016).
Maxfield, F. R. & Mondal, M. Sterol and lipid trafficking in mammalian cells. Biochem. Soc. Trans. 34, 335–339 (2006).
Saheki, Y. & De Camilli, P. Endoplasmic reticulum-plasma membrane contact sites. Annu. Rev. Biochem. 86, 659–684 (2017).
Kaplan, M. R. & Simoni, R. D. Intracellular transport of phosphatidylcholine to the plasma membrane. J. Cell Biol. 101, 441–445 (1985).
Wu, M. M., Buchanan, J., Luik, R. M. & Lewis, R. S. Ca2+ store depletion causes STIM1 to accumulate in ER regions closely associated with the plasma membrane. J. Cell Biol. 174, 803–813 (2006).
Fos, C., Becart, S., Canonigo Balancio, A. J., Boehning, D. & Altman, A. Association of the EF-hand and PH domains of the guanine nucleotide exchange factor SLAT with IP(3) receptor 1 promotes Ca(2)(+) signaling in T cells. Sci. Signal 7, ra93 (2014).
Liang, J. et al. Tespa1 regulates T cell receptor-induced calcium signals by recruiting inositol 1,4,5-trisphosphate receptors. Nat. Commun. 8, 15732 (2017).
Hsieh, T. S., Chen, Y. J., Chang, C. L., Lee, W. R. & Liou, J. Cortical actin contributes to spatial organization of ER-PM junctions. Mol. Biol. Cell 28, 3171–3180 (2017).
Tan, Y. X. et al. Inhibition of the kinase Csk in thymocytes reveals a requirement for actin remodeling in the initiation of full TCR signaling. Nat. Immunol. 15, 186–194 (2014).
Burkhardt, J. K., Carrizosa, E. & Shaffer, M. H. The actin cytoskeleton in T cell activation. Annu Rev. Immunol. 26, 233–259 (2008).
Tybulewicz, V. L. & Henderson, R. B. Rho family GTPases and their regulators in lymphocytes. Nat. Rev. Immunol. 9, 630–644 (2009).
Gawden-Bone, C. M. et al. PIP5 kinases regulate membrane phosphoinositide and actin composition for targeted granule secretion by cytotoxic lymphocytes.Immunity 49, 427–437 (2018).
Aguado, E. et al. Induction of T helper type 2 immunity by a point mutation in the LAT adaptor. Science 296, 2036–2040 (2002).
Sommers, C. L. et al. A LAT mutation that inhibits T cell development yet induces lymphoproliferation. Science 296, 2040–2043 (2002).
Fu, G. et al. Phospholipase C{gamma}1 is essential for T cell development, activation, and tolerance. J. Exp. Med. 207, 309–318 (2010).
Andreotti, A. H., Schwartzberg, P. L., Joseph, R. E. & Berg, L. J. T-cell signaling regulated by the Tec family kinase, Itk. Cold Spring Harb. Perspect. Biol. 2, a002287 (2010).
Iwai, M., Michikawa, T., Bosanac, I., Ikura, M. & Mikoshiba, K. Molecular basis of the isoform-specific ligand-binding affinity of inositol 1,4,5-trisphosphate receptors. J. Biol. Chem. 282, 12755–12764 (2007).
Collins, S. R. & Meyer, T. Evolutionary origins of STIM1 and STIM2 within ancient Ca2+ signaling systems. Trends Cell Biol. 21, 202–211 (2011).
Alzayady, K. J. et al. Tracing the evolutionary history of inositol, 1, 4, 5-trisphosphate receptor: Insights from analyses of Capsaspora owczarzaki Ca2+ release channel orthologs. Mol. Biol. Evol. 32, 2236–2253 (2015).
Hammond, G. R., Schiavo, G. & Irvine, R. F. Immunocytochemical techniques reveal multiple, distinct cellular pools of PtdIns4P and PtdIns(4,5)P(2). Biochem. J. 422, 23–35 (2009).
Uhlen, M. et al. Proteomics. Tissue-based map of the human proteome. Science 347, 1260419 (2015).
Heng, T. S. & Painter, M. W., Immunological Genome Project, C. The Immunological Genome Project: networks of gene expression in immune cells. Nat. Immunol. 9, 1091–1094 (2008).
Painter, M. W. et al. Transcriptomes of the B and T lineages compared by multiplatform microarray profiling. J. Immunol. 186, 3047–3057 (2011).
Lu, W., Skrzypczynska, D. M. & Weiss, A. Acute Csk inhibition hinders B cell activation by constraining the PI3 kinase pathway. Proc. Natl Acad. Sci. USA 118, e2108957118 (2021).
Lu, W. et al. The microRNA miR-22 inhibits the histone deacetylase HDAC4 to promote T(H)17 cell-dependent emphysema. Nat. Immunol. 16, 1185–1194 (2015).
You, R. et al. Nanoparticulate carbon black in cigarette smoke induces DNA cleavage and Th17-mediated emphysema. Elife 4, e09623 (2015).
Acknowledgements
We thank J. Zikherman for her constructive suggestions regarding this paper. We thank M. Krangel and A. Naik for their valuable consultations of methodology for TCR repertoire analysis. We thank A. Roque for animal husbandry, J. Mueller and W. Lo for irradiation of mice, UCSF Parnassus Flow Cytometry Core for maintaining FACSArias instruments and services, the Gladstone transgenic core facility for generating Nir3–/– mice, W. Lo for testing gRNA in EL4 cells and NIH Tetramer Core Facility for providing the H-2Kb OVA tetramers. This work was supported by in part by the Howard Hughes Medical Institute, the NIH (grants NIAID R37 AI114575 (A.W.), NIGMS R01 GM 144479 (J.L.) and NIAMS K01 AR065481 (B.B.A.)) and DRC Center Grant P30 DK063720 (UCSF Parnassus Flow Cytometry Core, UCSF Diabetes Center).
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Contributions
W.L., Y.A.H. and A.W. conceived the project and designed experiments. B.B.A. created the Nir3–/– mice. W.L. and Y.A.H. performed experiments and analyzed data. W.L. and K.S. designed and performed the phylogenetic study. B.B.A. and J.L. assisted with data interpretation and experimental design. W.L. and A.W. wrote the manuscript. A.W. supervised the study.
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The authors declare no competing interests.
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Nature Immunology thanks Leslie Berg, Yousang Gwack and Yinming Liang for their contribution to the peer review of this work. Primary Handling Editor: Laurie A. Dempsey, in collaboration with the Nature Immunology team. Peer reviewer reports are available.
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Extended data
Extended Data Fig. 1 Evolution of Nir2 and Nir3.
The tree indicates the reconstructed phylogenetic relationships between the Nir2 and Nir3 proteins with an emphasis on vertebrate lineages. The most recent common ancestor of these orthologs is represented with a star at the base of vertebrates. See Methods for details on sequence analysis.
Extended Data Fig. 2 Altered Vα-Jα rearrangements in Nir3–/– mice.
Rearrangement of selected Vα segments to different Jα segments in CD4SP and CD8SP thymocytes were assessed by SYBR Green-qPCR with normalization to Cd14. N = 4 mice. Data are shown as the mean ± s.e.m. and are representative of two independent experiments. P values were determined using a two-tailed Student’s t-test.
Extended Data Fig. 3 Decreased thymic NKT cells in Nir3–/– mice.
(a) Representative staining of NKT cells gated as TCRβint, CD1d-PBS-57 tetramer+ cells in live, CD8-negative thymocytes from WT and Nir3–/– thymus. (b) Absolute numbers of thymic NKT cells in the WT and Nir3–/– mice. (c) NKT cell subsets were gated as PLZFlo RORγt- (NKT1), PLZFhi RORγt- (NKT2) and PLZFint RORγt+ (NKT17). (d) PLZF expression levels in total WT and Nir3–/– NKT cells. (e-g) Absolute numbers of the NKT cell subsets in WT and Nir3–/– mice. N = 5 mice. Data are shown as the mean ± s.e.m. and are representative of two independent experiments. P values were determined using a two-tailed Student’s t-test.
Extended Data Fig. 4 Decreased thymic Treg cells in Nir3–/– mice.
CD25 + Foxp3+ Treg cells were gated from CD4SP thymocytes in WT and Nir3–/– mice (a) or bone marrow chimera mice (b). Representative flow plots (left) and quantification (right) of percentages of Treg cells were shown. WT and Nir3–/– donor cells recovered from the same recipient mouse were connected with lines (b). N = 5 mice. Data are shown as the mean ± s.e.m. and are representative of at least 2 independent experiments. P values were determined using a two-tailed Student’s t-test.
Extended Data Fig. 5 Nir3 is dispensable for IELp development.
Bone marrow cells from CD45.1/CD45.2 Nir3 sufficient mice (WT) and CD45.2 Nir3–/– mice (Nir3–/–) were mixed at a 1:1 ratio and adoptively transferred into CD45.1 hosts for six weeks. (a) DN NKT cells and IEL precursors (IELp) are gated from DN thymocytes. (b) The percentages of WT and Nir3–/– cells in each subset were quantified. N = 5 mice. Data are shown as the mean ± s.e.m. and are representative of 2 independent experiments. P values were determined using a two-tailed Student’s t-test.
Extended Data Fig. 6 Impaired development of Nir3–/– OT-II transgenic T cells.
Bone marrow cells from CD45.1/CD45.2 Nir3 sufficient (WT) OT-II mice and CD45.2 Nir3–/– OT-II mice were mixed at 1:1 ratio and adoptively transferred into CD45.1 hosts. 6 weeks after the transfer, WT OT-II and Nir3–/– OT-II thymocytes at each development stage and splenic T cells were identified by congenic CD45 markers. The percentages of WT OT-II cells and Nir3–/– OT-II cells in each stage were quantified. TN, T naive; TEM, T effector memory-like. N = 8 mice. Data are shown as the mean ± s.e.m. and are pooled from 2 independent experiments. P values were determined using a two-tailed Student’s t-test.
Extended Data Fig. 7 Nir3 is dispensable for maintaining PIP2 levels in quiescent T cells.
PIP2 levels on DP thymocytes (DP), CD4 (CD4 T) and CD8 (CD8 T) splenic T cells were measured by flow cytometry. N = 4 mice. Data are shown as the mean ± s.e.m. and are representative of two independent experiments.
Extended Data Fig. 8 Nir2 regulates PIP2 replenishment in mature T cells.
Wildtype (WT) and Nir3–/– CD3 + T cells were stimulated with bead-bound anti-CD3 and anti-CD28 antibodies for 3 days, transfected with scramble (Scr) or Nir2 siRNAs and rested in IL-7 containing media for 2 days. (a) Nir2 protein levels were assessed by immunoblots 2 days post transfection. (b) Cells were stimulated with 10μg/ml anti-CD3 antibodies (clone 2c11). PIP2 abundances at indicated time points were assessed by flow cytometry. The data are shown as the mean ± s.e.m. N = 3. Data are representative of two independent experiments.
Extended Data Fig. 9 Nir3 modulates Erk and Nur77 activation induced by weak TCR stimulation.
(a) WT or Nir3–/– DP thymocytes were stimulated with indicated amount of anti-CD3 at 0 min. Erk phosphorylation were assessed by flow cytometry. N = 3. The data are shown as the mean ± s.e.m. (b) WT or Nir3–/– OT-I DP1 and DP5 thymocytes were sorted by flow cytometry and co-cultured with full agonist (OVA), weak agonist (G4), positive selecting (Cappa1) and non-binding (VSV) peptide variants. After 3 hours, Nur77 expression and the percentage of thymocytes expressing CD69 were measured. N = 4. The data are shown as the mean ± s.e.m. with fitted curve (three parameters). Data are representative of two independent experiments.
Extended Data Fig. 10 Proposed Model.
In immature thymocytes, Nir3, IP3R2 and STIM2 are predominantly expressed. Upon weak TCR stimulation from self pMHC complex on thymic stromal cells, a small fraction of PIP2 is cleaved by PLCγ1 which generates limited amounts of PA at the ER-PM junctions. Nir3 is recruited to the junctions and transfers PI to the PM which is important for PIP2 replenishment. The whole Nir3-IP3R2-STIM2 circuit is critical for the sustained TCR signaling upon weak TCR stimuli. In mature T cells. Nir2, IP3R3 and STIM1 are major components of the SOCE pathway. The low sensitivity of the Nir2-IP3R3-STIM1 contributes to the non-responsiveness of mature T cells to weak TCR stimuli. Upon strong TCR stimulation from foreign peptide-MHC ligands, a large amount of PIP2 is metabolized which produces increased PA at the ER-PM junctions. Both Nir2 and Nir3 are recruited to the junctions in tandem. Nir2 transfers PI more efficiently than Nir3. Nir2 is the main PI transfer protein and Nir3 is less required for the PIP2 replenishment in this context.
Supplementary information
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Lu, W., Helou, Y.A., Shrinivas, K. et al. The phosphatidylinositol-transfer protein Nir3 promotes PI(4,5)P2 replenishment in response to TCR signaling during T cell development and survival. Nat Immunol 24, 136–147 (2023). https://doi.org/10.1038/s41590-022-01372-2
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DOI: https://doi.org/10.1038/s41590-022-01372-2
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