Mice lacking the CCR9 CC-chemokine receptor show a mild impairment of early T- and B-cell development and a reduction in T-cell receptor gammadelta(+) gut intraepithelial lymphocytes.

CC chemokine receptor (CCR) 9, the receptor for the CC-chemokine CCL25/thymus-expressed chemokine (TECK), is mainly expressed by thymocytes and by intraepithelial (IEL) and lamina propria lymphocytes of the small intestine. To study the biologic role of CCR9, a mouse strain was generated in which the CCR9 gene was deleted. In spite of the high level of CCR9 found in double- and single-positive thymocytes and of the expression of its corresponding ligand on thymic stromal cells, CCR9 deletion had no major effect on intrathymic T-cell development. It was noted that there was only a one-day lag in the appearance of double-positive cells during fetal ontogeny in CCR9(-/-) thymi. When tested in chemotaxis assay, thymocytes isolated from CCR9(-/-) mice failed to respond to TECK/CCL25. Taken together, these results suggest that in thymocytes, CCR9 is the only physiologic receptor for TECK/CCL25, and that it is dispensable for proper T-cell development. Bone marrow pre-pro-B cells migrate in response to TECK/CCL25, but more mature B cells do not. Consistent with this observation, it was shown that there are fewer pre-pro-B cells in CCR9(-/-) mice than in wild-type mice. However, this diminution does not appear to have a detectable effect on the generation of a normal complement of mature B cells. Finally, it was shown that in the small intestine of CCR9-deficient mice, the intraepithelial T-cell-to-epithelial cell ratio is decreased, an observation that can be accounted for by a marked diminution of the T-cell receptor gammadelta(+) compartment.

The tight interallelic positional coincidence that distinguishes T-cell receptor Jalpha usage does not result from homologous chromosomal pairing during ValphaJalpha rearrangement.

The T-cell receptor (TCR) alpha locus is thought to undergo multiple cycles of secondary rearrangements that maximize the generation of alphabeta T cells. Taking advantage of the nucleotide sequence of the human Valpha and Jalpha segments, we undertook a locus-wide analysis of TCRalpha gene rearrangements in human alphabeta T-cell clones. In most clones, ValphaJalpha rearrangements occurred on both homologous chromosomes and, remarkably, resulted in the use of two neighboring Jalpha segments. No such interallelic coincidence was found for the position of the two rearranged Valpha segments, and there was only a loose correlation between the 5' or 3' chromosomal position of the Valpha and Jalpha segments used in a given rearrangement. These observations question the occurrence of extensive rounds of secondary Valpha-->Jalpha rearrangements and of a coordinated and polarized usage of the Valpha and Jalpha libraries. Fluorescence in situ hybridization analysis of developing T cells in which TCRalpha rearrangements are taking place showed that the interallelic positional coincidence in Jalpha usage cannot be explained by the stable juxtaposition of homologous Jalpha clusters.

T cell development and T cell responses in mice with mutations affecting tyrosines 292 or 315 of the ZAP-70 protein tyrosine kinase.

After stimulation of the T cell receptor (TCR), the tyrosine residues 292 and 315 in interdomain B of the protein tyrosine kinase ZAP-70 become phosphorylated and plausibly function as docking sites for Cbl and Vav1, respectively. The two latter proteins have been suggested to serve as substrates for ZAP-70 and to fine-tune its function. To address the role of these residues in T cell development and in the function of primary T cells, we have generated mice that express ZAP-70 molecules with Tyr to Phe substitution at position 292 (Y292F) or 315 (Y315F). When analyzed in a sensitized TCR transgenic background, the ZAP-70 Y315F mutation reduced the rate of positive selection and delayed the occurrence of negative selection. Furthermore, this mutation unexpectedly affected the constitutive levels of the CD3-zeta p21 phosphoisoform. Conversely, the ZAP-70 Y292F mutation upregulated proximal events in TCR signaling and allowed more T cells to produce interleukin 2 and interferon gamma in response to a given dose of antigen. The observation that ZAP-70 Y292F T cells have a slower rate of ligand-induced TCR downmodulation suggests that Y292 is likely involved in regulating the duration activated TCR reside at the cell surface. Furthermore, we showed that Y292 and Y315 are dispensable for the TCR-induced tyrosine phosphorylation of Cbl and Vav1, respectively. Therefore, other molecules present in the TCR signaling cassette act as additional adaptors for Cbl and Vav1. The present in vivo analyses extend previous data based on transformed T cell lines and suggest that residue Y292 plays a role in attenuation of TCR signaling, whereas residue Y315 enhances ZAP-70 function.

Analysis of the individual role of the TCRzeta chain in transgenic mice after conditional activation with chemical inducers of dimerization.

Signaling through the TCR/CD3 complex plays a critical role in T-cell development and activation. Gene-targeted mice lacking particular components of this complex show arrested T-cell development in the thymus. As all TCR/CD3 components are required for efficient surface expression of the complex, it is difficult to assess the specific signaling role of each receptor component. To overcome this problem, we designed a strategy to examine the specific role(s) of individual receptor chains. A chimeric protein, containing binding domains for chemical inducers of dimerization fused to the cytoplasmic tail of TCRzeta, was generated. Activation of the chimeric receptor after stimulation with chemical dimerizers in Jurkat cells showed tyrosine phosphorylation of the TCRzeta chain chimera, recruitment of phosphorylated Zap70, and generation of NFAT in a reporter assay. Analysis of thymocytes from transgenic mice expressing this chimeric receptor showed that intracytoplasmic crosslinking of the chimera induced tyrosine phosphorylation of the protein, as well as a slow and very weak calcium mobilization response. However, this signaling did not lead to increased expression of activation markers, T-cell proliferation, or apoptosis. In addition, stimulation of thymocytes in suspension or in fetal thymic organ cultures with chemical inducers of dimerization did not lead to alterations in positive or negative selection. We conclude that signaling through the TCRzeta chain alone is not sufficient to generate downstream events leading to full T-cell activation or thymocyte selection; instead, additional CD3 components must be required to induce a functional response in primary thymocytes and peripheral T cells.

The chemokine TECK is expressed by thymic and intestinal epithelial cells and attracts double- and single-positive thymocytes expressing the TECK receptor CCR9.

Chemokines are key regulators of migration in lymphoid tissues. In the thymus, maturing thymocytes move from the outer capsule to the inner medulla and thereby interact with different types of stromal cells that control their maturation and selection. In the process of searching for molecules specifically expressed at different stages of mouse thymic differentiation, we have characterized the cDNA coding for the thymus-expressed chemokine (TECK) and its receptor CCR9. The TECK receptor gene was isolated and shown to be localized on the mouse chromosome 9F1-F4. Thymic dendritic cells have been initially thought to be a prevalent source of TECK. In contrast, our results indicate that thymic epithelial cells constitute the predominant source of TECK. Consistent with the latter distribution, the TECK receptor is highly expressed by double-positive thymocytes, and TECK can chemoattract both double-positive and single-positive thymocytes. The TECK transcript is also abundantly expressed in the epithelial cells lining the small intestine. In conclusion, the interplay of TECK and its receptor CCR9 is likely to have a significant role in the recruitment of developing thymocytes to discrete compartments of the thymus.

Pre-T cell receptor signals are responsible for the down-regulation of Syk protein tyrosine kinase expression.

Thymocyte development proceeds through two critical checkpoints that involve signaling events through two different receptors, the TCR and the pre-TCR. These receptors employ two families of protein tyrosine kinases to propagate their signals, the Src and Syk families. Genetic and biochemical evidence has shown that the Src family kinases are critical for normal T cell maturation. ZAP-70, a Syk family kinase, has similarly been implicated as a critical component in thymocyte development. Although genetic evidence has suggested that Syk is involved during thymocyte development, a definitive study of Syk expression has not been performed. In this paper we report our reanalysis of Syk expression in subpopulations of murine and human thymocytes by intracellular staining and flow cytometry using anti-Syk mAbs. Syk is expressed at increased levels during the stages in which pre-TCR signaling occurs. Furthermore, Syk is down-regulated after the pre-TCR checkpoint has been passed. Syk may play an important role in thymic development during pre-TCR signal transduction. Finally, incomplete down-regulation of Syk expression was noted in human thymocytes, offering a possible explanation for the distinct phenotypes of mice and humans deficient in ZAP-70.

Crippling of CD3-zeta ITAMs does not impair T cell receptor signaling.

We evaluated the importance of CD3-zeta ITAMs in T cell responses by breeding the P14 transgenic TCR into mice in which CD3-zeta chains lacking all or part of their ITAMs were genetically substituted for wild-type CD3-zeta chains. In contrast to the H-Y TCR, the P14 TCR permitted the development of peripheral CD8+ T cells harboring signaling-defective CD3-zeta subunits. The absence of functional CD3-zeta ITAMs did not reduce the spectrum of activation events and effector functions that constitute the normal attributes of mature CD8+ T cells. The only detectable differences were quantitative and noted only when T cells were challenged with suboptimal peptide concentrations. Therefore, the ITAMs present in the CD3-gammadeltaepsilon module are sufficient for qualitatively normal TCR signaling and those present in CD3-zeta have no exclusive role during T cell activation.

Differential effects of manipulating signaling in early T cell development in intestinal intraepithelial lymphocytes and thymocytes.

A pre-TCR-CD3 signal is required for the efficient maturation of CD4- CD8- thymocytes to the CD4+ CD8+ stage. This study addressed whether a similar signal is required for maturation of intestinal intraepithelial lymphocytes (IEL) that may develop extrathymically. We have shown previously that IEL from mice deficient for CD3- associated zeta chains include an immature population of CD3- CD8alphaalpha+ cells expressing cytoplasmic TCR beta chains but lacking detectable surface TCRalphabeta, CD16 and B220. Here we stimulated the appearance of such IEL in epsilon+/- zeta-/- mice by expression of an activated Lck transgene or in vivo treatment with anti-CD3epsilon. Anti-CD3epsilon treatment of RAG-deficient animals also yielded CD16- B220- IEL. In contrast, expression of a TCRbeta transgene in rag-1(-/-) mice did not stimulate the appearance of CD3- CD8alphaalpha+ CD16- B220- cells. Taken together these data indicate that although anti-CD3epsilon treatment and LckF505 assist in catalyzing a CD16+ B220+ --> CD16- B220- transition, these manipulations are not equivalent to a pre-TCR signal in IEL lymphocytes.

Differential gene expression in CD3epsilon- and RAG1-deficient thymuses: definition of a set of genes potentially involved in thymocyte maturation.

A set of 3000 mouse thymus cDNAs was analyzed by extensive measurement of expression using complex-probe hybridization of DNA arrays ("quantitative differential screening"). The complex probes were initially prepared using total thymus RNA isolated from C57BL/6 wild-type (WT), CD3epsilon- and RAG1-deficient mice. Over 100 clones displaying over- or under-expression by at least a factor of two between WT and knockout (KO) thymuses were further analyzed by measuring hybridization signatures with probes from a wide range of KO thymuses, cell types, organs, and embryonic thymuses. A restricted set of clones was selected by virtue of their expression spectra (modulation in KO thymuses and thymocytes, lymphoid cell specificity, and differential expression during embryonic thymus development), sequenced at one extremity, and compared to sequences in databases. Clones corresponding to previously identified genes (e.g., Tcrbeta, Tcf1 or CD25) showed expression patterns that were consistent with existing data. Ten distinct clones corresponding to new genes were subjected to further study: Northern blot hybridization, in situ hybridization on thymus sections, and partial or complete mRNA sequence determination. Among these genes, we report a new serine peptidase highly expressed in cortical epithelial cells that we have named thymus-specific serine peptidase (TSSP), and an acidic protein expressed in thymocytes and of unknown function that we have named thymus-expressed acidic protein (TEAP). This approach identifies new molecules likely to be involved in thymocyte differentiation and function.

Use of TCR ADV gene segments by the delta chain is independent of their position and of CD3 expression.

The CD3 signaling complex is required for cell surface expression and selection of both alphabeta and gammadelta TCR. In this study we analyzed TCRD transcripts in both wild-type and CD3-epsilon-deficient mice. We show that the repertoire of ADV segments used by the delta chain is unchanged in the latter. Not all ADV genes participate in making up the TCRD repertoire. However, their use does not depend on their distance from the other TCRD-forming segments. For example ADV12, situated at more than 870 kb from the DD region, is expressed as part of TCRD transcripts, whereas ADV8, members of which are proximal to the DD region, is not. These data suggest that the accessibility of ADV8 gene segments is differentially regulated during T cell development in the thymus. Taken together, our results suggest that TCRA and TCRD rearrangements are independently controlled, and that the absence of TCRA expression in CD3-epsilon-deficient mice is not due to a lack of accessibility of the ADV gene segments but rather to inaccessibility of the AJ gene region.

Intestinal intraepithelial lymphocytes include precursors committed to the T cell receptor alpha beta lineage.

The majority of T cells develop in the thymus and exhibit well characterized phenotypic changes associated with their maturation. Previous analysis of intestinal intraepithelial lymphocytes (IEL) from nude mice and a variety of experimentally manipulated models led to the view that at least a portion of these cells represent a distinct T cell population that matures extrathymically. The IEL that are postulated to mature within the intestine include both T cell receptor (TCR) alpha beta- and gamma delta-bearing subpopulations. They can be distinguished from conventional thymically derived T cells in that they express an unusual coreceptor, a CD8alpha homodimer. In addition, they can utilize the Fc receptor gamma-chain in place of the CD3-associated zeta-chain for TCR signaling and their maturation depends on the interleukin 2 receptor beta-chain. Moreover, TCRalpha beta+CD8alpha alpha+ IEL are not subject to conventional thymic selection processes. To determine whether CD3(-)CD8alpha alpha+ IEL represent precursors of T cells developing extrathymically, we examined IEL from knockout mice lacking the recombination activating gene-1 (rag-1), CD3epsilon, or both Lck and Fyn, in which thymic T cell development is arrested. CD3(-)CD8alpha alpha+CD16(+) IEL from all three mutant strains, as well as from nude mice, included cells that express pre-TCRalpha transcripts, a marker of T cell commitment. These IEL from lck-/-fyn-/- animals exhibited TCR beta-gene rearrangement. However, CD3(-)CD8alpha alpha+CD16(+) IEL from epsilon-deficient mice had not undergone Dbeta-Jbeta joining, despite normal rearrangement at the TCRbeta locus in thymocytes from these animals. These results revealed another distinction between thymocytes and IEL, and suggested an unexpectedly early role for CD3epsilon in IEL maturation.

T cell receptor gamma gene regulatory sequences prevent the function of a novel TCRgamma/pTalpha pre-T cell receptor.

Expression of a TCRgamma transgene in RAG-1-/- mice resulted in the development of a limited number of CD4+CD8+ (DP) thymocytes. In vivo treatments with anti-TCRgamma antibody enhanced the number of DP thymocytes, demonstrating that TCRgamma chains were expressed on the cell surface in the absence of delta, alpha, or beta chains. Mutations in pTalpha or CD3epsilon genes abolished transgene-induced DP cell development, indicating that TCRgamma can associate with pTalpha and CD3 to form a novel pre-TCR. With a transgene containing additional regulatory sequences, TCRgamma expression was down-regulated in DP cells, and little DP cell development occurred. Thus, the function of the endogenous TCRgamma/pTalpha is limited by the transcriptional down-regulation of TCRgamma genes that normally accompanies DP cell development.

The CD3-gammadeltaepsilon and CD3-zeta/eta modules are each essential for allelic exclusion at the T cell receptor beta locus but are both dispensable for the initiation of V to (D)J recombination at the T cell receptor-beta, -gamma, and -delta loci.

The pre-T cell receptor (TCR) associates with CD3-transducing subunits and triggers the selective expansion and maturation of T cell precursors expressing a TCR-beta chain. Recent experiments in pre-Talpha chain-deficient mice have suggested that the pre-TCR may not be required for signaling allelic exclusion at the TCR-beta locus. Using CD3-epsilon- and CD3-zeta/eta-deficient mice harboring a productively rearranged TCR-beta transgene, we showed that the CD3-gammadeltaepsilon and CD3-zeta/eta modules, and by inference the pre-TCR/CD3 complex, are each essential for the establishment of allelic exclusion at the endogenous TCR-beta locus. Furthermore, using mutant mice lacking both the CD3-epsilon and CD3-zeta/eta genes, we established that the CD3 gene products are dispensable for the onset of V to (D)J recombination (V, variable; D, diversity; J, joining) at the TCR-beta, TCR-gamma, and TCR-delta loci. Thus, the CD3 components are differentially involved in the sequential events that make the TCR-beta locus first accessible to, and later insulated from, the action of the V(D)J recombinase.

The common cytokine receptor gamma chain controls survival of gamma/delta T cells.

We have investigated the role of common gamma chain (gamma c)-signaling pathways for the development of T cell receptor for antigen (TCR)-gamma/delta T cells. TCR-gamma/delta-bearing cells were absent from the adult thymus, spleen, and skin of gamma c-deficient (gamma c-) mice, whereas small numbers of thymocytes expressing low levels of TCR-gamma/delta were detected during fetal life. Recent reports have suggested that signaling via interleukin (IL)-7 plays a major role in facilitating TCR-gamma/delta development through induction of V-J (variable-joining) rearrangements at the TCR-gamma locus. In contrast, we detected clearly TCR-gamma rearrangements in fetal thymi from gamma c- mice (which fail to signal in response to IL-7) and reduced TCR-gamma rearrangements in adult gamma c thymi. No gross defects in TCR-delta or TCR-beta rearrangements were observed in gamma c- mice of any age. Introduction of productively rearranged TCR V gamma 1 or TCR V gamma 1/V delta 6 transgenes onto mice bearing the gamma c mutation did not restore TCR-gamma/delta development to normal levels suggesting that gamma c-dependent pathways provide additional signals to developing gamma/delta T cells other than for the recombination process. Bcl-2 levels in transgenic thymocytes from gamma c- mice were dramatically reduced compared to gamma c+ transgenic littermates. We favor the concept that gamma c-dependent receptors are required for the maintenance of TCR-gamma/delta cells and contribute to the completion of TCR-gamma rearrangements primarily by promoting survival of cells committed to the TCR-gamma/delta lineage.

Thymocytes and RelB-dependent medullary epithelial cells provide growth-promoting and organization signals, respectively, to thymic medullary stromal cells.

The thymic medulla is composed of distinct epithelial cell subsets, defined in this report by the reactivity of two novel antibodies, 95 and 29, raised against mouse thymic epithelial cell lines. These antibodies were used to probe the development of medulla in wild-type or mutant thymuses. In CD3 epsilon-deficient mice where thymocyte maturation is arrested at the CD4- CD8- stage, few scattered 95+ and 29+ epithelial cells are found. When few mature thymocytes develop as in CD3- zeta/eta mice, expansion and organization of 95+ but not 29+ cells, becomes detectable. In RelB-deficient mice, T cell maturation proceeds normally but negative selection is inefficient due to the lack of thymic medulla and dendritic cells. Strikingly, 29+ epithelial cells are absent and 95+ medullary epithelial cells are scattered throughout the thymus, intermingling with CDR1+ cortical epithelium. In chimeric mice lacking only dendritic cells, the corticomedullary junction persists and both 95+ and 29+ epithelial cells are localized in the medulla. These results suggest that two types of signals are required for development of thymic medulla. A growth signal depends upon the presence of maturing thymocytes, but organization of the thymic medulla requires the presence of activated 29+ medullary epithelial cells.

The single positive T cells found in CD3-zeta/eta-/- mice overtly react with self-major histocompatibility complex molecules upon restoration of normal surface density of T cell receptor-CD3 complex.

CD3-zeta/eta-deficient mice have small thymuses containing cells that show a profound reduction in the surface levels of T cell receptors and terminate their differentiation at the CD4+CD8+ stage. Rather unexpectedly, CD3- or very low single positive T cells accumulate over time in the spleen and lymph nodes of CD3-zeta/eta-deficient mice after a process dependent on MHC expression. Fusion of these peripheral T cells with a CD3-zeta-positive derivative of the BW5147 TCR-alpha-/beta- thymoma resulted in hybridomas that do express an heterogeneous set of T cell receptor alpha/beta dimers at their surface and at density comparable to those found in hybridomas derived from wild-type peripheral T cells. We have investigated the specificities of these T cell receptors using spleen cells from congenic and mutant mouse strains, and showed that the majority of them readily recognized self-MHC class I or class II molecules. These results demonstrate that by increasing the density and/or output of the T cell receptors expressed in peripheral T cells, one can confer them with the capacity to respond to normal density of self-MHC molecules.

Replacement of pre-T cell receptor signaling functions by the CD4 coreceptor.

An important checkpoint in early thymocyte development ensures that only thymocytes with an in-frame T cell receptor for antigen beta (TCR-beta) gene rearrangement will continue to mature. Proper assembly of the TCR-beta chain into the pre-TCR complex delivers signals through the src-family protein tyrosine kinase p56lck that stimulate thymocyte proliferation and differentiation to the CD4+CD8+ stage. However, the biochemical mechanisms governing p56lck activation remain poorly understood. In more mature thymocytes, p56lck is associated with the cytoplasmic domain of the TCR coreceptors CD4 and CD8, and cross-linking of CD4 leads to p56lck activation. To study the effect of synchronously inducing p56lck activation in immature CD4-CD8- thymocytes, we generated mice expressing a CD4 transgene in Rag2-/- thymocytes. Remarkably, without further experimental manipulation, the CD4 transgene drives maturation of Rag2-/- thymocytes in vivo. We show that this process is dependent upon the ability of the CD4 transgene to bind Lck and on the expression of MHC class II molecules. Together these results indicate that binding of MHC class II molecules to CD4 can deliver a biologically relevant, Lck-dependent activation signal to thymocytes in the absence of the TCR-alpha or -beta chain.

Functions of TCR and pre-TCR subunits: lessons from gene ablation.

Recent gene-targeting experiments have highlighted the existence of checkpoints that ensure that alpha beta T cells do not complete intrathymic differentiation if they have not attained certain landmark events. These 'proofreading' mechanisms operate by way of the pre-TCR and TCR complexes, which are sequentially expressed during T-cell development. These complexes are likely to signal via their associated CD3 subunits. By activating intracellular effectors, the CD3 subunits probably modulate gene expression profiles and drive the maturing alpha beta T cells through a precise developmental sequence.