Rearrangement and expression of T cell antigen receptor and gamma genes during thymic development

Becoming aware of γδ T cells

The discovery that B cells and αβ T cells exist was predictable: These cells gave themselves away through their products and biological effects. In contrast, there was no reason to anticipate the existence of γδ T cells. Even the accidental discovery of a novel TCR-like gene (later named γ) that did not encode TCR α or β proteins did not immediately change this. TCR-like γ had no obvious function, and its early expression in the thymus encouraged speculation about a possible role in αβ T cell development. However, the identification of human PBL-derived cell-lines which expressed CD3 in complex with the TCR-like γ protein, but not the αβ TCR, first indicated that a second T cell-type might exist, and the TCR-like γ chain was observed to co-precipitate with another protein. Amid speculation about a possible second TCR, this potential dimeric partner was named δ. To determine if the δ protein was indeed TCR-like, we undertook to sequence it. Meanwhile, a fourth TCR-like gene was discovered and provisionally named x. TCR-like x had revealed itself through genomic rearrangements early in T cell development, and was an attractive candidate for the gene encoding δ. The observation that δ protein sequences matched the predicted amino acid sequences encoded by the x gene, as well as serological cross-reactivity, confirmed that the TCR-like x gene indeed encoded the δ protein. Thus, the γδ heterodimer was established as a second TCR, and the cells that express it (the γδ T cells) consequently represented a third lymphocyte-population with the potential of recognizing diverse antigens. Soon, it became clear that γδ T cells are widely distributed and conserved among the vertebrate species, implying biological importance. Consistently, early functional studies revealed their roles in host resistance to pathogens, tissue repair, immune regulation, metabolism, organ physiology and more. Albeit discovered late, γδ T cells have repeatedly proven to play a distinct and often critical immunological role, and now generate much interest.

Immunogenetics of type 1 diabetes mellitus

Type 1 diabetes mellitus (T1DM) is an autoimmune disease arising through a complex interaction of both genetic and immunologic factors. Similar to the majority of autoimmune diseases, T1DM usually has a relapsing remitting disease course with autoantibody and T cellular responses to islet autoantigens, which precede the clinical onset of the disease process. The immunological diagnosis of autoimmune diseases relies primarily on the detection of autoantibodies in the serum of T1DM patients. Although their pathogenic significance remains uncertain, they have the practical advantage of serving as surrogate biomarkers for predicting the clinical onset of T1DM. Type 1 diabetes is a polygenic disease with a small number of genes having large effects (i.e. HLA), and a large number of genes having small effects. Risk of T1DM progression is conferred by specific HLA DR/DQ alleles [e.g., DRB1*03-DQB1*0201 (DR3) or DRB1*04-DQB1*0302 (DR4)]. In addition, HLA alleles such as DQB1*0602 are associated with dominant protection from T1DM in multiple populations. A discordance rate of greater than 50% between monozygotic twins indicates a potential involvement of environmental factors on disease development. Viral infections may play a role in the chain of events leading to disease, albeit conclusive evidence linking infections with T1DM remains to be firmly established. Two syndromes have been described in which an immune-mediated form of diabetes occurs as the result of a single gene defect. These syndromes are termed autoimmune polyglandular syndrome type I (APS-I) or autoimmune polyendocrinopathy-candidiasis-ectodermal dystrophy (APECED), and X-linked poyendocrinopathy, immune dysfunction and diarrhea (XPID). These two syndromes are unique models to understand the mechanisms involved in the loss of tolerance to self-antigens in autoimmune diabetes and its associated organ-specific autoimmune disorders. A growing number of animal models of these diseases have greatly helped elucidate the immunologic mechanisms leading to autoimmune diabetes.

Women with the Alzheimer's risk marker ApoE4 lose Aβ-specific CD4⁺ T cells 10-20 years before men

Adaptive immunity to self-antigens causes autoimmune disorders, such as multiple sclerosis, psoriasis and type 1 diabetes; paradoxically, T- and B-cell responses to amyloid-β (Aβ) reduce Alzheimer's disease (AD)-associated pathology and cognitive impairment in mouse models of the disease. The manipulation of adaptive immunity has been a promising therapeutic approach for the treatment of AD, although vaccine and anti-Aβ antibody approaches have proven difficult in patients, thus far. CD4(+) T cells have a central role in regulating adaptive immune responses to antigens, and Aβ-specific CD4(+) T cells have been shown to reduce AD pathology in mouse models. As these cells may facilitate endogenous mechanisms that counter AD, an evaluation of their abundance before and during AD could provide important insights. Aβ-CD4see is a new assay developed to quantify Aβ-specific CD4(+) T cells in human blood, using dendritic cells derived from human pluripotent stem cells. In tests of >50 human subjects Aβ-CD4see showed an age-dependent decline of Aβ-specific CD4(+) T cells, which occurs earlier in women than men. In aggregate, men showed a 50% decline in these cells by the age of 70 years, but women reached the same level before the age of 60 years. Notably, women who carried the AD risk marker apolipoproteinE-ɛ4 (ApoE4) showed the earliest decline, with a precipitous drop between 45 and 52 years, when menopause typically begins. Aβ-CD4see requires a standard blood draw and provides a minimally invasive approach for assessing changes in Aβ biology that may reveal AD-related changes in physiology by a decade. Furthermore, CD4see probes can be modified to target any peptide, providing a powerful new tool to isolate antigen-specific CD4(+) T cells from human subjects.

DNA double-strand breaks relieve USF-mediated repression of Dβ2 germline transcription in developing thymocytes

Activation of germline promoters is central to V(D)J recombinational accessibility, driving chromatin remodeling, nucleosome repositioning, and transcriptional read-through of associated DNA. We have previously shown that of the two TCRβ locus (Tcrb) D segments, Dβ1 is flanked by an upstream promoter that directs its transcription and recombinational accessibility. In contrast, transcription within the DJβ2 segment cluster is initially restricted to the J segments and only redirected upstream of Dβ2 after D-to-J joining. The repression of upstream promoter activity prior to Tcrb assembly correlates with evidence that suggests DJβ2 recombination is less efficient than that of DJβ1. Because inefficient DJβ2 assembly offers the potential for V-to-DJβ2 recombination to rescue frameshifted V-to-DJβ1 joints, we wished to determine how Dβ2 promoter activity is modulated upon Tcrb recombination. In this study, we show that repression of the otherwise transcriptionally primed 5'Dβ2 promoter requires binding of upstream stimulatory factor (USF)-1 to a noncanonical E-box within the Dβ2 12-recombination signal sequence spacer prior to Tcrb recombination. USF binding is lost from both rearranged and germline Dβ2 sites in DNA-dependent protein kinase, catalytic subunit-competent thymocytes. Finally, genotoxic dsDNA breaks lead to rapid loss of USF binding and gain of transcriptionally primed 5'Dβ2 promoter activity in a DNA-dependent protein kinase, catalytic subunit-dependent manner. Together, these data suggest a mechanism by which V(D)J recombination may feed back to regulate local Dβ2 recombinational accessibility during thymocyte development.

Perinatal exposure to Δ9-tetrahydrocannabinol triggers profound defects in T cell differentiation and function in fetal and postnatal stages of life, including decreased responsiveness to HIV antigens

Marijuana abuse is very prominent among pregnant women. Although marijuana cannabinoids have been shown to exert immunosuppression in adults, virtually nothing is known about the effects of marijuana use during pregnancy on the developing immune system of the fetus and during postnatal life. We noted that murine fetal thymus expressed high levels of the cannabinoid receptors CB1 and CB2. Moreover, perinatal exposure to Δ(9)-tetrahydrocannabinol (THC) had a profound effect on the fetus as evidenced by a decrease in thymic cellularity on gestational days 16, 17, and 18 and postgestational day 1 and marked alterations in T cell subpopulations. These outcomes were reversed by CB1/CB2 antagonists, suggesting that THC-mediated these effects through cannabinoid receptors. Thymic atrophy induced in the fetus correlated with caspase-dependent apoptosis in thymocytes. Thymic atrophy was the result of direct action of THC and not based on maternal factors inasmuch as THC was able to induce T cell apoptosis in vitro in fetal thymic organ cultures. It is noteworthy that perinatal exposure to THC also had a profound effect on the immune response during postnatal life. Peripheral T cells from such mice showed decreased proliferative response to T cell mitogen as well as both T cell and antibody response to HIV-1 p17/p24/gp120 antigens. Together, our data demonstrate for the first time that perinatal exposure to THC triggers profound T cell dysfunction, thereby suggesting that the offspring of marijuana abusers who have been exposed to THC in utero may be at a higher risk of exhibiting immune dysfunction and contracting infectious diseases including HIV.

Genetic and epigenetic regulation of Tcrb gene assembly

Vertebrate development requires the formation of multiple cell types from a single genetic blueprint, an extraordinary feat that is guided by the dynamic and finely tuned reprogramming of gene expression. The sophisticated orchestration of gene expression programs is driven primarily by changes in the patterns of covalent chromatin modifications. These epigenetic changes are directed by cis elements, positioned across the genome, which provide docking sites for transcription factors and associated chromatin modifiers. Epigenetic changes impact all aspects of gene regulation, governing association with the machinery that drives transcription, replication, repair and recombination, a regulatory relationship that is dramatically illustrated in developing lymphocytes. The program of somatic rearrangements that assemble antigen receptor genes in precursor B and T cells has proven to be a fertile system for elucidating relationships between the genetic and epigenetic components of gene regulation. This chapter describes our current understanding of the cross-talk between key genetic elements and epigenetic programs during recombination of the Tcrb locus in developing T cells, how each contributes to the regulation of chromatin accessibility at individual DNA targets for recombination, and potential mechanisms that coordinate their actions.

The center of accessibility: Dβ control of V(D)J recombination

Developmental patterning of antigen receptor gene assembly in lymphocyte precursors correlates with decondensation of the chromatin surrounding individual gene segments. Ongoing V(D)J recombination is associated with hyperacetylation of histones H3 and H4 and the expression of sterile germline transcripts across the region of recombinational accessibility. Likewise, histone acetyltransferase and SWI/SNF chromatin remodeling complexes each appear to be required for recombination, and the PHD-finger of RAG-2 preferentially associates with recombination signal sequence (RSS) chromatin that contains H3 trimethylated on lysine 4. However, the regulatory mechanisms that direct chromatin alteration and rearrangement have proven elusive, due in large part to the interdependency of individual stages in gene activation, our limited understanding of functional significance of changes to the histone code, and the difficulty of modeling recombinational accessibility in existing experimental systems. Examining Tcrb assembly in developing thymocytes, we review the central roles of RSS elements and germline promoters as foci for epigenetic reorganization of recombinationally accessible gene segments in light of recent findings and persistent questions.

Transcription-dependent mobilization of nucleosomes at accessible TCR gene segments in vivo

Accessibility of chromosomal recombination signal sequences to the RAG protein complex is known to be essential for V(D)J recombination at Ag receptor loci in vivo. Previous studies have addressed the roles of cis-acting regulatory elements and germline transcription in the covalent modification of nucleosomes at Ag receptor loci. However, a detailed picture of nucleosome organization at accessible and inaccessible recombination signal sequences has been lacking. In this study, we have analyzed the nucleosome organization of accessible and inaccessible Tcrb and Tcra alleles in primary murine thymocytes in vivo. We identified highly positioned arrays of nucleosomes at Dbeta, Jbeta, and Jalpha segments and obtained evidence indicating that positioning is established at least in part by the regional DNA sequence. However, we found no consistent positioning of nucleosomes with respect to recombination signal sequences, which could be nucleosomal or internucleosomal even in their inaccessible configurations. Enhancer- and promoter-dependent accessibility was characterized by diminished abundance of certain nucleosomes and repositioning of others. Moreover, some changes in nucleosome positioning and abundance at Jalpha61 were shown to be a direct consequence of germline transcription. We suggest that enhancer- and promoter-dependent transcription generates optimal recombinase substrates in which some nucleosomes are missing and others are covalently modified.

Promoter activity 5' of Dbeta2 is coordinated by E47, Runx1, and GATA-3

V(D)J recombination involves the stepwise assembly of B and T cell receptor genes as lymphocytes progress through the early stages of development. While the mechanisms that restrict each step in recombination to its appropriate developmental stage are largely unknown, they share many of the components that regulate transcription. For example, enhancer-dependent modifications in histone acetylation and methylation are essential for both germline transcription and rearrangement of antigen receptor genes. Promoters positioned proximal to individual D and J gene segments in Tcra, Tcrb, Tcrd, IgH, and Igk also contribute to antigen receptor gene assembly, though their effects appear more localized than those of enhancers. Tcrb assembly initiates with D-to-J joining at each of the two D-J-C gene segment clusters in DN1/2 thymocytes. DJ joints are fused with Vbeta elements to complete Tcrb recombination in DN3 cells. We have previously shown that Dbeta2 is flanked by upstream and downstream promoters, with the 5' promoter being held inactive until D-to-J recombination deletes the NFkappaB-dependent 3' promoter. We now report that activity of the 5' promoter reflects a complex interplay among Runx1, GATA-3, and E47 transcription factors. In particular, while multiple E47 and Runx1 binding sites clustered near the Dbeta2 5'RS and overlapping inr elements define the core 5'PDbeta2, they act in concert with an array of upstream GATA-3 sites to overcome the inhibitory effects of a 110bp distal polypurine.polypyrimidine (R.Y) tract. The dependence of 5'PDbeta2 on E47 is consistent with the reported role of E proteins in post-DN1 thymocyte development and V-to-DJbeta recombination.

Differential activation of dual promoters alters Dbeta2 germline transcription during thymocyte development

Ag receptor genes are assembled through somatic rearrangements of V, D, and J gene segments. This process is directed in part by transcriptional enhancers and promoters positioned within each gene locus. Whereas enhancers coordinate reorganization of large chromatin stretches, promoters are predicted to facilitate the accessibility of proximal downstream gene segments. In TCR beta locus, rearrangement initiates at two D-J cassettes, each of which exhibits transcriptional activity coincident with DJ rearrangement in CD4/CD8 double-negative pro-T cells. Consistent with a model of promoter-facilitated recombination, assembly of the DJbeta1 cassette is dependent on a Dbeta1 promoter (PDbeta1) positioned immediately 5' of the D. Assembly of DJbeta2 proceeds independent from that of DJbeta1, albeit with less efficiency. To gain insight into the mechanisms that selectively alter D usage, we have defined transcriptional regulation at Dbeta2. We find that both DJbeta cassettes generate germline messages in murine CD44+CD25- double-negative 1 cells. However, transcription of unrearranged DJbeta2 initiates at multiple sites 400-550 bp downstream of the Dbeta2. Unexpectedly, loci from which germline promoter activity has been deleted by DJ rearrangement redirect transcription to sites immediately 5' of the new DJbeta2 joint. Our analyses suggest that 3'-PDbeta2 activity is largely controlled by NF-kappaB RelA, whereas 5'-PDbeta2 activity directs germline transcription of DJbeta2 joints from initiator elements 76 bp upstream of the Dbeta2 5' recombination signal sequence. The unique organization and timing of Dbeta2 promoter activity are consistent with a model in which promoter placement selectively regulates the rearrangement potential of Dbeta2 during TCR beta locus assembly.

Phenotypic characterization of CD3-7+ cells in developing human intestine and an analysis of their ability to differentiate into T cells

We have identified a large population of CD3(-)7(+) cells in human fetal gut. Three- and four-color flow cytometry revealed a distinct surface Ag profile on this population; the majority were negative for CD4 and CD8, whereas most of the remainder expressed the CD8alphaalpha homodimer. In contrast about half of CD3(+) cells expressed CD4 and half expressed CD8alpha. A large proportion of CD3(-)7(+) cells expressed CD56, CD94, and CD161, and whereas CD3(+) T cells also expressed CD161, they only rarely expressed CD56 or CD94. Further studies were conducted to determine whether the CD3(-)7(+) cells have the potential to differentiate into CD3(+) cells. About half of CD3(-)7(+) cells contain intracellular CD3epsilon. Rearranged TCR gamma-chains were detected in highly purified CD3(-)7(+) cells as an early molecular sign of T cell commitment, and the pattern of rearrangement with V regions spliced to the most 5' Jgamma segment is reminiscent of early thymocyte differentiation. In reaggregate thymic organ cultures, CD3(-)7(+) cells also gave rise to CD3(+) T cells. Thus, we demonstrate that the CD3(-)7(+) cells present in the human fetal gut display a distinct phenotype and are able to develop into CD3(+) T cells.

Early TCR αβ Expression Promotes Maturation of T Cells Expressing FcεRIγ Containing TCR/CD3 Complexes

In a previous study we presented data indicating that the expanded population of CD4(-)CD8(-) (DN) alphabeta T cells in TCRalpha-chain-transgenic mice was partially if not entirely derived from gammadelta T cell lineage cells. The development of both gammadelta T cells and DN alphabeta T cells is poorly understood; therefore, we thought it would be important to identify the immediate precursors of the transgene-induced DN alphabeta T cells. We have in this report studied the early T cell development in these mice and we show that the transgenic TCRalpha-chain is expressed by precursor thymocytes already at the CD3(-)CD4(-)CD8(-) (triple negative, TN) CD44(+)CD25(-) stage of development. Both by using purified precursor populations in reconstitution experiments and by analyzing fetal thymocyte development, we demonstrated that early TN precursors expressing endogenous TCRbeta-chains matured into DN alphabeta T cells at several stages of development. The genes encoding the gamma-chain of the high affinity receptor for IgE (FcepsilonRIgamma) and the CD3zeta protein were found to be reciprocally expressed in TN thymocytes such that during development the FcepsilonRIgamma expression decreased whereas CD3zeta expression increased. Furthermore, in a fraction of the transgene-induced DN alphabeta T cells the FcepsilonRIgamma protein colocalized with the TCR/CD3 complex. These data suggest that similarly to gammadelta T cells and NKT cells, precursors expressing the TCR early in the common alphabetagammadelta developmental pathway may use the FcepsilonRIgamma protein as a signaling component of the TCR/CD3 complex.

Gut cryptopatches: direct evidence of extrathymic anatomical sites for intestinal T lymphopoiesis

Athymic cytokine receptor gamma chain mutant mice that lack the thymus, Peyer's patches, cryptopatches (CP), and intestinal T cells were reconstituted with wild-type bone marrow cells. Bone marrow-derived TCR(-) intraepithelial lymphocytes (IEL) first appeared within villous epithelia of small intestine overlying the regenerated CP, and these TCR(-) IEL subsequently emerged throughout the epithelia. Thereafter, TCR(+) IEL increased to a comparable number to that in athymic mice and consisted of TCRgammadelta and TCRalphabeta IEL. In gut-associated lymphoid tissues of wild-type mice, only CP harbored a large population of c-kit(high)IL-7R(+)CD44(+)Thy-1(+/-)CD4(+/-)CD25(low/-)alpha(E) beta(7)(-)Lin(-) (Lin, lineage markers) lymphocytes that included cells expressing germline but not rearranged TCRgamma and TCRbeta gene transcripts. These findings provide direct evidence that gut CP develop progenitor T cells for extrathymic IEL descendants.

Early activation of TCR alpha gene rearrangement in fetal thymocytes

We have previously demonstrated that the onset of TCR alpha gene rearrangement is mainly restricted to the J alpha50 gene in fetal day 1delta thymocyte hybridomas. Now, J alpha50 rearrangements from fetal thymocyte hybridomas and from day 15.5 fetal thymus have been isolated and sequenced. We demonstrate that J alpha50 is rearranged to the rearranged Vdelta1 Ddelta2 gene segment. This indicates that the TCR alpha rearrangement process is initiated in fetal thymocytes far earlier than previously thought. These thymocytes have their delta genes still accessible for rearrangement and therefore, are controlled by the TCR delta enhancer (Edelta) (and/or another TCR delta specific cis-acting element). Our results further suggest that both Edelta and the TCR alpha enhancer (Ealpha) are active at the onset of alpha rearrangements or alternatively, the initial activation of the J alpha locus is controlled by Edelta. In addition, Vdelta1 Ddelta2 J alpha50 gene segments are replaced by secondary alpha rearrangements, indicating that thymocytes with the early alpha rearrangement are committed to the alphabeta lineage.

Differential Presentation of an Altered Peptide Within Fetal Central and Peripheral Organs Supports an Avidity Model for Thymic T Cell Development and Implies a Peripheral Readjustment for Activation

Altered self peptides may drive T cell development by providing avidity of interactions low enough to potentiate positive selection but not powerful enough to trigger programmed cell death. Since the peptide repertoire in both central and peripheral organs is nearly the same, interactions of these peptides with T cells in the thymus would have to be different from those taking place in the periphery; otherwise, T cell development and maturation would result in either autoimmunity or T cell deficiency. Herein, a self and an altered self peptide were delivered to fetuses, and their presentation as well as the consequence of such presentation on T cell development were assessed. The results indicate that the self peptide was presented in both central and peripheral fetal organs and that such presentation abolished T cell responses to both peptides during adult life. However, the altered peptide, although presented in vivo as well as in vitro by splenic cells, was unable to stimulate a specific T cell clone when the presenting cells were of thymic origin and allowed offspring to be responsive to both peptides. These findings indicate that central and peripheral organs accommodate selection and peripheral survival of T cells by promoting differential altered peptide presentation.

Evidence of stage-specific element for germ-line transcription of the TCR alpha gene located upstream of J alpha49 locus

T cell receptor (TCR) genes are rearranged and expressed in an ordered manner during T cell development. The basic mechanism regulating this stepwise DNA alteration is poorly understood. To address this issue, we explored the presence of a stage-specific element for germ-line transcription of the TCR alpha gene which is closely associated with gene rearrangement. First, germ-line transcription of the TCR alpha gene including the first segment of the J alpha locus, J alpha49, was delayed compared to that of the TCR beta gene in both normal and TCR-transgenic (Tg) mice. Furthermore, expression of this transcript could be induced by CD3epsilon-mediated signals in recombination-activating gene (RAG)-2-deficient mice. In TCR-Tg mice, the endogenous J alpha49 germ-line transcript could not yet be observed at the CD25+ double-negative (DN) stage when the TCR alpha transgene was expressed. Of immature T cell hybridomas derived from either scid thymocytes (CD25+ DN) or immature CD8-single positive (ISP) thymocytes, only the latter hybridoma expressed the J alpha49 germ-line transcript. These data indicate that the J alpha49 germ-line transcription occurs only at a specific developmental stage. Second, to determine which elements may be regulating stage specificity, we performed transient transfection analysis with a reporter gene and demonstrated that the upstream region of the J alpha49 locus possesses promoter activity in correlation with germ-line transcription in ISP-derived but not in SCID-derived hybridomas. These results indicate that the expression of TCR alpha germ-line transcripts is regulated in a stage-specific manner by a cis-element located within the J alpha locus.

Interleukin 7 induces TCR gene rearrangement in adult marrow-resident murine precursor T cells

Rearrangement of the T cell antigen receptor genes is a complex, highly regulated process. To gain a better understanding of the extracellular factors involved in the regulation of TCR beta and gamma gene rearrangement in adult murine bone marrow-resident precursor T cells, several cytokines were tested for their ability to induce gene recombination. A selected population of C58/J bone marrow cells (Thy 1(low), CD3, CD8, B220) that is enriched for pre-T cell activity was propagated in vitro in medium supplemented with IL-3 and mast cell growth factor (MGF, also referred to as stem cell factor, Steele factor and c-kit ligand). These cytokines were required for the maintenance of pre-T cell activity in culture, but had no effect on TCR gene expression. Several additional cytokines were added to the culture medium. Of all those tested, only IL-7 induced complete rearrangement of the TCR gamma locus. Complete rearrangement of the TCR beta locus was not induced under any of the culture conditions analysed here. The bone marrow cells cultured in IL-3, MGF and IL-7 did not begin to express mature T cell proteins and maintained their in vivo progenitor potential. Furthermore, IL-7 cultured bone marrow cells were capable of differentiation in vivo into all phenotypic subpopulations of T cells, without an apparent bias toward the gammadelta lineage. The data presented here suggest that TCR gamma gene rearrangement in adult pre-T cells is regulated by IL-7, but that the TCR beta locus requires additional or alternative signals for the induction of complete rearrangement.

Restricted onset of T cell receptor alpha gene rearrangement in fetal and neonatal thymocytes

The initial T cell receptor (TCR) alpha gene rearrangements were analyzed in fetal and neonatal thymocyte hybridomas by Southern blotting. Interestingly, in 30% of all thymocyte hybridomas and in all fetal day 16 thymocyte hybridomas the most proximal J alpha 50 (psi J alpha) gene was rearranged. This rearrangement was found on one chromosome only and mostly in association with a delta rearrangement on the homologous chromosome. J alpha 50 was rearranged to multiple target genes based on the variable size of the restriction fragments. In addition, delta rearrangement was found with a concomitant alpha rearrangement in the majority of hybridomas and it was not only associated with J alpha 50 but with several other rearranged J alpha genes as well. Our results clearly demonstrate that T cell precursors are not pre-committed to either delta or alpha rearrangement but a flexible progenitor responds to multiple regulatory signals during T cell differentiation and they do not support the notion that delta rec-psi J alpha rearrangement is required for cell commitment to TCR alpha gene rearrangement.

Abrogation of the allelic exclusion in a T cell receptor beta chain gene transgenic mouse strain

The expression of endogenous T cell receptor (TcR) beta chains in a TcR beta chain gene transgenic mouse (TGM) strain was examined. Unlike many other TGM strains reported, a considerable proportion of T cells from the thymus and spleen as well as organ cultured fetal thymus from our TGM express endogenous TCR beta chains on their surface. Compatible with this was the elucidation of VDJ rearrangement of endogenous beta chain genes by PCR. Three color flow cytometric analysis of thymus cell subpopulations revealed that the expression levels of both endogenous and transgenic TcR beta genes are regulated in a maturational stage specific manner. Splenic T cells contained a several fold higher percentage of endogenous TcR beta positive cells than thymus cells, suggesting a role of TcR on T cell peripherization. V beta 6 positive cells were deleted in the TGM carrying minor lymphocyte stimulating (Mls)-la antigen, indicating that the endogenous TcR beta is functional in terms of transmitting a signal for clonal deletion.

Ly-49-independent natural killer (NK) cell specificity revealed by NK cell clones derived from p53-deficient mice

Natural killer (NK) cells are heterogeneous in their specificity and expression of cell surface molecules. In the mouse, the Ly-49A molecule is a primary determinant of NK cell specificity because of its ability to downregulate NK cell activation after physical interaction with target cell MHC class I molecules. Ly-49A is expressed on an NK cell subset, and it belongs to a family of highly related molecules that may similarly dictate major histocompatibility complex (MHC) class I-associated specificity of Ly-49A- NK cells. It is not known, however, whether murine NK cell specificity may occur independently of the Ly-49 family and target cell MHC class I molecules. Similar to the impact of cloned murine T cell lines on molecular description of T cell recognition, derivation of cloned murine NK cells should permit dissection of NK cell specificity but, to date, it has not been possible to produce such effector cells. In this study, we derived NK cell clones from mice that were homozygous for a mutation in the p53 tumor suppressor gene. The cloned cells displayed the molecular, cell surface, and functional phenotype of NK cells. Significantly, the NK cell clones displayed clonal differences in ability to kill a panel of murine tumor targets and did not lyse normal cells. Target lysis was unaffected by target cell MHC class I expression, and none of the clones expressed Ly-49A on the cell surface or transcripts for Ly-49 isoforms. Although consistent with the possibility that NK cell specificity for MHC class I molecules is mediated by the Ly-49 family of molecules, the results indicate that NK cell specificity also is regulated by a mechanism independent of target cell MHC class I and the Ly-49 family.

Southern blot analysis of T-cell receptor gene rearrangements in cynomolgus monkeys, and identification of a progenitor cell HPRT mutation

Increases in peripheral blood T-lymphocyte HPRT mutant frequency may reflect either a number of independent HPRT gene mutational events or clonal proliferation of a single HPRT mutant. Sequence analysis of HPRT mutations in conjunction with T-cell receptor (TCR) gene rearrangement pattern analysis can distinguish these possibilities. Our laboratory previously characterized a nonhuman primate model for in vivo mutation studies using the clonal HPRT mutation assay. In the present study we report the use of probes for human TCR beta and gamma genes to characterize TCR rearrangements in cynomolgus monkeys. Together, these methods were used to examine a monkey which exhibited a mean spontaneous HPRT mutant frequency (MF) of 16.4 x 10(-6), compared to the normal mean MF of 3.03 x 10(-6). The elevated MF resulted from the occurrence of a single HPRT mutation in a lymphocyte progenitor cell or stem cell, since T-cell clones isolated from the monkey exhibited a G to T transversion at base pair 539 in the HPRT coding region, and had unique rearrangements of TCR gamma along with an apparent germline TCR beta configuration. In a preliminary in vivo mutation study, the animal was treated with the investigational potent mutagen and antitumor agent adozelesin (U-73975). No increase in HPRT mutant frequency was observed. The HPRT mutant clones isolated after treatment showed rearrangement of both TCR gamma and beta genes. Possible explanations for these findings are discussed.

Double-negative thymocyte subsets in CD3 zeta chain-deficient mice: absence of HSA+CD44-CD25- cells

Double-negative (DN) thymocyte subsets were examined in mice deficient in the CD3 zeta chain (zeta-/-). The HSA+CD44-CD25- subset was found to be missing, and DN thymocytes seemed to differentiate directly from HSA+CD25+CD44- cells to double-positive (DP) cells. When fetal thymic ontogeny was examined, we found a marked difference between zeta-/- embryos and heterozygous littermates from embryonic day 17.5, in terms of CD25, CD4 and CD8 expression, and thymus size. The zeta-/- thymocytes failed to down-regulate CD25 and to expand exponentially. The cell cycle status of adult thymocyte subsets indicated that although the HSA+CD25-CD44- subset was missing, the CD25+ DN population contained normal numbers of cycling cells, and the CD25+ DP cells (which were not detectable in normal mice) contained 5-10% cells in G2/M+S. Taken together these data suggest that the CD3 zeta chain might have a specific role in the control of proliferation of DN thymocytes during T cell development. Our data clearly show that one can dissociate the signal for a CD25+ DN cell to differentiate (which occurs in the absence of CD3 zeta), from a signal to proliferate and from loss of cell surface CD25.

Abnormal deletions in the T-cell receptor delta locus of mouse thymocytes

Separate genetic elements (V, D, and J) encode the variable regions of lymphocyte antigen receptors. During early lymphocyte differentiation, these elements rearrange to form contiguous coding segments (VJ and VDJ) for a diverse array of variable regions. Rearrangement is mediated by a recombinase that recognizes short DNA sequences (signals) flanking V, D, and J elements. Signals flank both the 5' and 3' sides of each D element, thereby allowing assembly of a functional VDJ gene. However, in rearrangements involving the D delta 2 and J delta 1 elements of the mouse T-cell receptor delta (TCR delta) locus, we unexpectedly found that the D delta 2 element and a portion of its 5' signal are often deleted. Approximately 50% of recovered D delta 2 to J delta 1 rearrangements from thymocytes of adult wild-type mice showed such deletions. An additional 20% of the rearrangements contained standard D delta 2-J delta 1 coding junctions but showed some loss of nucleotides from the 5' D delta 2 signal. This loss was clearly associated with another event involving a site-specific cleavage at the 5' signal/coding border of D delta 2 and rejoining of the modified signal and coding ends. The abnormal loss of D delta 2 and a portion of the 5' D delta 2 signal was infrequently observed in D delta 2-to-J delta 1 rearrangements recovered from neonatal mice. The possible basis and significance of this age-dependent phenomenon are discussed.

Abnormal deletions in the T-cell receptor delta locus of mouse thymocytes

Separate genetic elements (V, D, and J) encode the variable regions of lymphocyte antigen receptors. During early lymphocyte differentiation, these elements rearrange to form contiguous coding segments (VJ and VDJ) for a diverse array of variable regions. Rearrangement is mediated by a recombinase that recognizes short DNA sequences (signals) flanking V, D, and J elements. Signals flank both the 5' and 3' sides of each D element, thereby allowing assembly of a functional VDJ gene. However, in rearrangements involving the D delta 2 and J delta 1 elements of the mouse T-cell receptor delta (TCR delta) locus, we unexpectedly found that the D delta 2 element and a portion of its 5' signal are often deleted. Approximately 50% of recovered D delta 2 to J delta 1 rearrangements from thymocytes of adult wild-type mice showed such deletions. An additional 20% of the rearrangements contained standard D delta 2-J delta 1 coding junctions but showed some loss of nucleotides from the 5' D delta 2 signal. This loss was clearly associated with another event involving a site-specific cleavage at the 5' signal/coding border of D delta 2 and rejoining of the modified signal and coding ends. The abnormal loss of D delta 2 and a portion of the 5' D delta 2 signal was infrequently observed in D delta 2-to-J delta 1 rearrangements recovered from neonatal mice. The possible basis and significance of this age-dependent phenomenon are discussed.

Evidence for recombinatorial hot spots at the T cell receptor J alpha locus

The complex genomic organization of the murine T cell receptor (TcR) delta-alpha region has hindered detailed studies of alpha gene rearrangement and J alpha gene usage in individual differentiating T cell precursors. We have isolated a novel set of J alpha probes which, in combination with a few restriction enzyme digests, enable a reliable, simple and nearly complete analysis and location of any rearrangement at the J alpha locus by conventional Southern blotting. The probes were used to analyze TcR alpha gene rearrangements in T cell hybridomas derived from an in vitro culture system that supports T cell differentiation of bone marrow cells. Our results indicate that J alpha genes are unequally accessible for rearrangement and two hot spots for rearrangement could be demonstrated. In addition, only a restricted set of J alpha genes was rearranged in each culture indicating that the slightly variable composition of factors can influence the recombinatorial accessibility of J alpha genes. The hot spots for rearrangement were not only limited to T cells differentiating in vitro but could also be demonstrated among functional T cell clones based on the published sequence information from isolated TcR alpha gene rearrangements. The demonstration and the location of the hot spots for rearrangement in the T cell differentiation culture system opens up the possibility to study factors and mechanisms that regulate recombinatorial accessibility of TcR alpha genes.

A role for a pre-T-cell receptor in T-cell development

Expression of a productive T-cell receptor (TCR) beta gene has profound consequences for T-cell development, preceding an increase in thymocyte number, appearance of CD4 and CD8 coreceptors and suppression of further TCR beta-gene rearrangement. Here Marcus Groettrup and Harald von Boehmer discuss the data obtained in various experimental models and describe a novel signal transducing receptor complex on pre-T cells, which may regulate the TCR beta-induced developmental changes.

A novel disulfide-linked heterodimer on pre-T cells consists of the T cell receptor beta chain and a 33 kd glycoprotein

We describe a novel signal-transducing protein complex, which consists of the T cell receptor (TCR) beta chain that is disulfide linked to a 33 kd glycoprotein and noncovalently associated with proteins of the CD3 complex on the surface of the pre-T cell line SCB.29. This 33 kd glycoprotein, provisionally designated gp33, represents neither of the known TCR chains and has escaped previous detection because it labels poorly by surface iodination. This glycoprotein is absent from the surface of mature T cell lines. A TCR beta complex with identical molecular masses before and after reduction can be immunoprecipitated from surface-iodinated large thymocytes of TCR alpha-deficient mice. The novel gp33-TCR beta complex may be entirely or partly responsible for control of early T cell development exerted by the TCR beta protein.

T cell receptor beta chain dimers on immature thymocytes from normal mice

During T cell development the T cell receptor (TCR) beta chain is expressed before the TCR alpha chain. Experiments in TCR beta transgenic severe combined immune deficiency (SCID) mice have shown that the TCR beta protein can be expressed on the cell surface of immature thymocytes in the absence of the TCR alpha chain and that the TCR beta protein controls T cell development with regard to cell number, CD4/CD8 expression and allelic exclusion of the TCR beta chain. Subsequent experiments have shown that on the surface of thymocytes from TCR beta transgenic SCID mice the TCR beta protein can be expressed in a monomeric and dimeric form whereas only the dimeric form was found on the surface of a TCR beta-transfected, immature T cell line. The results presented here show that normal thymocytes from 16-day-old fetuses likewise express only the dimeric form and that the monomeric form on the surface of thymocytes from transgenic mice results from glycosyl phosphatidylinositol linkage. Our results show for the first time that under physiological conditions a TCR beta dimer can be expressed on the cell surface without the TCR alpha chain.

T cell receptor-beta mRNA splicing: regulation of unusual splicing intermediates

The expression of functional T cell receptor-beta (TCR-beta) transcripts requires the activation of programmed DNA rearrangement events. It is not clear whether other mechanisms dictate TCR-beta mRNA levels during thymic ontogeny. We examined the potential role of RNA splicing as a regulatory mechanism. As a model system, we used an immature T cell clone, SL12.4, that transcribes a fully rearranged TCR-beta gene but essentially lacks mature 1.3-kb TCR-beta transcripts in the cytoplasm. Abundant TCR-beta splicing intermediates accumulate in the nucleus of this cell clone. These splicing intermediates result from inefficient or inhibited excision of four of the five TCR-beta introns; the only intron that is efficiently spliced is the most 5' intron, IVSL. The focal point for the regulation appears to be IVS1C beta 1 and IVS2C beta 1, since unusual splicing intermediates that have cleaved the 5' splice site but not the 3' splice site of these two introns accumulate in vivo. The block in 3' splice site cleavage is of interest since sequence analysis reveals that these two introns possess canonical splice sites. A repressional mechanism involving a labile repressor protein may be responsible for the inhibition of RNA splicing since treatment of SL12.4 cells with the protein synthesis inhibitor cycloheximide reversibly induces a rapid and dramatic accumulation of fully spliced TCR-beta transcripts in the cytoplasm, concomitant with a decline in TCR-beta pre-mRNAs in the nucleus. This inducible system may be useful for future studies analyzing the underlying molecular mechanisms that regulate RNA splicing.

T cell receptor-beta mRNA splicing: regulation of unusual splicing intermediates

The expression of functional T cell receptor-beta (TCR-beta) transcripts requires the activation of programmed DNA rearrangement events. It is not clear whether other mechanisms dictate TCR-beta mRNA levels during thymic ontogeny. We examined the potential role of RNA splicing as a regulatory mechanism. As a model system, we used an immature T cell clone, SL12.4, that transcribes a fully rearranged TCR-beta gene but essentially lacks mature 1.3-kb TCR-beta transcripts in the cytoplasm. Abundant TCR-beta splicing intermediates accumulate in the nucleus of this cell clone. These splicing intermediates result from inefficient or inhibited excision of four of the five TCR-beta introns; the only intron that is efficiently spliced is the most 5' intron, IVSL. The focal point for the regulation appears to be IVS1C beta 1 and IVS2C beta 1, since unusual splicing intermediates that have cleaved the 5' splice site but not the 3' splice site of these two introns accumulate in vivo. The block in 3' splice site cleavage is of interest since sequence analysis reveals that these two introns possess canonical splice sites. A repressional mechanism involving a labile repressor protein may be responsible for the inhibition of RNA splicing since treatment of SL12.4 cells with the protein synthesis inhibitor cycloheximide reversibly induces a rapid and dramatic accumulation of fully spliced TCR-beta transcripts in the cytoplasm, concomitant with a decline in TCR-beta pre-mRNAs in the nucleus. This inducible system may be useful for future studies analyzing the underlying molecular mechanisms that regulate RNA splicing.

Aging in the T lymphocyte compartment. A developmental view

A decline in the capacity of bone marrow cells to differentiate to T lymphocytes was found when cells from young and old donors were seeded onto an alymphoid fetal thymus. A step-by-step analysis of cell-cell interactions of the lymphohemopoietic cells and the thymic stroma indicated an effect of age on a variety of cell differentiation parameters. These included a decrease in the affinity of bone marrow cells to the stroma, and in their capacity to compete with the thymic lymphoid resident cells on colonization of the thymus. There was a significant decrease in the ability of cells of old donors to replicate sequentially within the thymic microenvironment. There was a reduced capacity of bone marrow cells from aging mice to express a developmental preference after seeding onto a syngeneic fetal thymus in a mixture with cells from allogeneic donors. We addressed the question whether the aging thymus contains increased levels of immature cells that fail to differentiate in the involuted thymic microenvironment by seeding thymocytes from young and old donors onto the fetal thymic stroma. The values of T cells that developed from the old donor inoculum were lower under these conditions. Our studies suggest that at least some of the manifestations of aging in the T cell compartment are related to developmentally programmed events in the lymphohemopoietic cell compartment.

Molecular analysis of a pro-T cell clone transformed by Abelson-murine leukemia virus, displaying progressive gamma delta T cell receptor gene rearrangement and surface expression

We present a molecular analysis of T cell differentiation in a set of clones derived from in vitro Abelson murine leukemia virus (A-MuLV) infection of fetal liver cells. The parental clone had partial rearrangement of the beta and gamma loci and spontaneously displayed progressive rearrangement of V gamma genes during in vitro culture. Further differentiation of these clones leading to delta gene rearrangement and CD4 expression, then CD8, CD3 and T cell receptor gamma delta chain surface expression was obtained after intrathymic transfer followed by in vitro co-culture with thymic tissue. These A-MuLV clones, therefore, appear to represent a powerful model system for studying the early molecular events of T cell development at the clonal level.

Exposure to tetrachlorodibenzo-p-dioxin (TCDD) alters fetal thymocyte maturation

We previously reported that thymic atrophy and reduced thymic cellularity associated with prenatal exposure to 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) in mice are characterized by quantitative alerations in the number of thymocytes expressing CD4 and CD8 surface antigens. In the present study, these observations have been extended to establish the specific thymocyte maturation processes affected by TCDD through an examination of cell size distributions, alpha beta and gamma delta T cell receptor (TCR) expression, peanut agglutinin (PNA) binding, and J11d marker analysis in murine thymocytes exposed prenatally to TCDD. Pregnant mice were administered vehicle, 1.5 or 3.0 micrograms/kg body wt TCDD by gavage on gestational Days (gd) 6-14. Flow cytometry analysis of gd 18 fetal thymocytes revealed a reduction in the number of small CD4+CD8+ double positive (DP) and PNA+, small thymocytes in the TCDD-exposed groups. The large cell population was reduced by TCDD to approximately 70% of control values. There was also a significant shift in TCR expression of thymocytes with a decrease in alpha beta TCR and a concommitant increase in gamma delta TCR expression from TCDD-exposed fetuses. The CD4-CD8+J11d+ thymocytes were increased in TCDD-treated mice while the more mature CD4-CD8+J11d- thymocyte numbers were similar to controls. Taken together, these data indicate that TCDD inhibits thymocyte maturation at the transition phase between the CD4-CD8+J11d+ phenotype and the DP/J11d+ thymocytes.

The development of functionally responsive T cells

The work reviewed in this article separates T cell development into four phases. First is an expansion phase prior to TCR rearrangement, which appears to be correlated with programming of at least some response genes for inducibility. This phase can occur to some extent outside of the thymus. However, the profound T cell deficit of nude mice indicates that the thymus is by far the most potent site for inducing the expansion per se, even if other sites can induce some response acquisition. Second is a controlled phase of TCR gene rearrangement. The details of the regulatory mechanism that selects particular loci for rearrangement are still not known. It seems that the rearrangement of the TCR gamma loci in the gamma delta lineage may not always take place at a developmental stage strictly equivalent to the rearrangement of TCR beta in the alpha beta lineage, and it is not clear just how early the two lineages diverge. In the TCR alpha beta lineage, however, the final gene rearrangement events are accompanied by rapid proliferation and an interruption in cellular response gene inducibility. The loss of conventional responsiveness is probably caused by alterations at the level of signaling, and may be a manifestation of the physiological state that is a precondition for selection. Third is the complex process of selection. Whereas peripheral T cells can undergo forms of positive selection (by antigen-driven clonal expansion) and negative selection (by abortive stimulation leading to anergy or death), neither is exactly the same phenomenon that occurs in the thymic cortex. Negative selection in the cortex appears to be a suicidal inversion of antigen responsiveness: instead of turning on IL-2 expression, the activated cell destroys its own chromatin. The genes that need to be induced for this response are not yet identified, but it is unquestionably a form of activation. It is interesting that in humans and rats, cortical thymocytes undergoing negative selection can still induce IL-2R alpha expression and even be rescued in vitro, if exogenous IL-2 is provided. Perhaps murine thymocytes are denied this form of rescue because they shut off IL-2R beta chain expression at an earlier stage or because they may be uncommonly Bcl-2 deficient (cf. Sentman et al., 1991; Strasser et al., 1991). Even so, medullary thymocytes remain at least partially susceptible to negative selection even as they continue to mature.(ABSTRACT TRUNCATED AT 400 WORDS)

Clonal analysis of peripheral T cell precursors in lpr mice

MRL/Mp-lpr/lpr mice develop massive lymphadenopathy characterized by expansion of an unusual population of T cells with the Thy 1+, CD3+, CD4-, CD8- (double negative) phenotype. The role these cells play in accelerating the autoimmune syndrome seen in these mice is unknown. In order to better understand the origin of the expanded population of T cells, we have derived a panel hybridomas from double negative lpr lymph node cells. Surprisingly, eleven of twelve hybridomas selected for the absence of surface CD4 and CD8 do not express CD3. Six of eleven confirmed to have inherited the MRL T cell receptor locus have rearrangement at that locus, suggesting commitment to a T cell lineage. Only hybridoma 2.4, which expresses CD3, responds to ConA, anti-CD3 monoclonal antibody, and induces antibody production. The presence of CD3-, CD4-, CD8- T cells in the periphery of lpr mice confirms aberrant T cell development in these mice and suggests an intrinsic cell defect which is expressed early in lymphopoiesis.

Production of a monoclonal antibody strongly reacting with immature thymic T lymphocytes and its immunohistological application

A monoclonal antibody Th-5 has been produced against mouse immature thymic lymphocytes and employed to study the process of T cell differentiation in the thymus. Immunohistologically, Th-5 positive thymic T lymphocytes were first found at Day 12 of gestation. They increased in number as well as staining intensity until Day 18 of gestation and decreased thereafter. Th-5 antigen expression was not seen in lymphoid cells in the fetal liver. In the newborn thymus, lymphocytes in the subcapsular layer were still strongly positive, while other cortical lymphocytes became moderately positive for Th-5. Th-5 positiveness was more pronounced in the medulla than in the cortex in the thymus of young adult mice. The staining pattern of Th-5 in the thymus was apparently different from those with other T cell markers (Thy-1, CD3, CD4, CD5, CD8) including J11d, Pgp-1, IL-2R, and 3A10 (TCR gamma delta). Flow cytometric analyses showed that the expression of Th-5 was mostly associated with the Thy-1 antigen. However, the fluorescent intensity of Th-5 gradually declined with ontogenic development of the thymus, and the molecular size of the antigen was approximately 100 kDa, which is different from Thy-1 antigen (25-30 kDa). Considering these findings, the strong expression of Th-5 could be one of the markers of immature thymic T lymphocytes in the early phase of the ontogenic development.

Binding of thymic factors to the conserved decanucleotide promoter element of the T-cell receptor V beta gene is developmentally regulated and is absent in SCID mice

The gene segments encoding the beta chain of the T-cell antigen receptor undergo rearrangement in a precise developmental order: a D beta gene segment joins to a J beta gene segment prior to the rearrangement of a V beta gene segment to join the D/J beta fusion. Current evidence suggests that the rearrangement of V beta is restricted to T cells, whereas D-to-J beta rearrangements may occur in both B and T cells. Thus, the T-cell specificity seems to be regulated by the V beta coding region or its 5' flanking sequence. In support of this hypothesis, evidence is provided for thymus-specific factors that bind a highly conserved 10-base-pair (decamer) sequence that is an essential promoter element in mouse and human V beta genes. The presence of decamer-binding activities was assayed by gel mobility-shift analysis using protein extracts from thymus, spleen, and nonlymphoid organs of adult mice. Two shifted complexes, designated T2 and T3, were seen only when the decamer was incubated with extracts from thymus. When extracts from mice of various gestational ages were tested for decamer-binding activity, one of the thymus-specific complexes, T2, was first detected at day 16; this coincides with the time of initial activation of the V beta locus. No decamer-binding activity was detected in extracts prepared from the thymuses of SCID (severe combined immunodeficiency) mice, which characteristically fail to rearrange these genes. Moreover, neither T2 nor T3 was detectable with extracts from spleen or from two T-cell lines that express the beta chain; this suggests that the presence of these two complexes is not absolutely required for transcription of the T-cell receptor beta locus. We conclude that there are tissue-specific and developmentally regulated factors that form complexes with the decamer sequence 5' of V beta; these may represent initiation factors that control the activation of germ-line T-cell receptor V beta genes for transcription and/or rearrangement.

T-lymphocyte development in scid mice is arrested shortly after the initiation of T-cell receptor delta gene recombination

Scid mice lack functional lymphocytes because they carry a mutation that impairs rearrangement of immunoglobulin and T-cell receptor (TCR) genes. Rearrangement of TCR delta, but not gamma and beta genes, was routinely observed in DNA of scid thymocytes and thymocyte hybridomas. TCR delta gene rearrangements appeared to involve D delta 1, D delta 2, and J delta 1 elements only; rearrangement of elements upstream of D delta 1 (e.g., V delta 1) was not observed, and transcripts corresponding to fully assembled TCR delta genes (VDJ delta or VDDJ delta) were not detected in RNA from scid thymocytes. These findings suggest that D delta 1, D delta 2, and J delta 1 may be among the first TCR gene elements to undergo recombination and that scid T-lineage cells are developmentally arrested during or shortly after this stage of differentiation. One class of TCR delta recombination fragments (D delta 2-J delta 1) was amplified by the polymerase chain reaction (PCR) and cloned, and the recombination junctions were sequenced. Most fragments showed normal coding joints. Interestingly, five of seven coding joints that lacked N insertions showed evidence of recombination between short stretches (2-3 bp) of homologous sequence. As discussed, the general absence of V delta-, J gamma-, and J beta-associated rearrangements, despite the occurrence of normal D delta 2-J delta 1 rearrangements, raises the possibility that the scid mutation may cause premature cessation of TCR gene recombination and thereby arrest early T-cell development.

A novel form of CD4 (L3T4) mRNA in the murine fetal liver results in cell-surface expression of the L3T4 antigen

The expression of the L3T4 antigen during ontogeny in the murine fetal liver has been investigated in parallel by northern blot analysis and cytofluorometry. The L3T4 gene is transcribed in the murine fetal liver in two polyadenylated mRNA species with the size of 3.5 kb and 3.7 kb. Whereas the 3.5-kb mRNA is expressed from days 13 to 18 of gestation, expression of the 3.7-kb mRNA is found only from days 16 to 18 of gestation and thus appears to be developmentally regulated. Immunofluorescent staining of fractionated fetal liver cells from days 12 to 18 of gestation with the anti-L3T4 antibody (GK1.5) provides evidence that cell-surface expression of the L3T4 antigen on a subset of lympho-haematopoietic cells in the murine fetal liver is the product of a novel form of L3T4 mRNA with the size of 3.5 kb.

Interleukin 1-induced maturation of progenitor thymocytes

Regulation of thymocyte development was assessed by culturing purified CD4-CD8- thymocytes with cytokines. Sorted CD3-CD4-CD8- adult thymocytes responded to the combination of interleukin (IL) 1 plus IL 2 without additional mitogens or co-mitogens with both cellular proliferation and cell surface expression of the T cell receptor (TcR)/CD3 complex. IL2 alone induced neither proliferation nor cell surface TcR/CD3 expression. IL1 alone was sufficient to induce cell surface TcR/CD3 without proliferation. Prior to stimulation with cytokines, the progenitor CD4-CD8- thymocytes accumulated TcR beta and CD3 gamma, delta, epsilon and zeta mRNA but TcR alpha mRNA was not detectable. Stimulation with IL 1 led to a dramatic induction of TcR alpha mRNA without an increase in the other transcripts. These studies suggest that IL 1 regulates the differentiation status of immature adult thymocytes. Nuclear run-on studies suggested that the increase in TcR alpha mRNA accumulation induced by cytokines might result from post-transcriptional accumulation.

Murine thymic nurse cell clone supports the growth of fetal thymocytes in the presence of interleukin 2

To investigate the role of thymic nurse cells (TNC) in activation and differentiation of fetal CD4-CD8- (double-negative) thymocytes, we have co-cultured murine fetal thymocytes (14-15 days of gestation) with an established murine TNC clone. We show here that TNC induced the growth of the fetal double-negative thymocytes in the presence of recombinant interleukin 2 (rIL2). Activated fetal thymocytes markedly formed lymphocyte-TNC complexes and proliferated extensively after 5 days in the co-culture. The activated fetal thymocytes in this co-culture condition remained double negative after 10 days in culture. None of them gave rise to phenotypically and functionally competent lymphocytes during this period. TNC alone and the supernatant of TNC had no effect on activation. The presence of both TNC and rIL2 was necessary for the growth of fetal thymocytes in our system. The proliferation of fetal thymocytes was inhibited by a monoclonal antibody against mouse IL2 receptors (IL2R). The fetal thymocytes could be maintained further in this co-culture condition. The prolonged cultivation of fetal thymocytes resulted in the establishment of the fetal thymocyte line and its several clones. CD4 single-positive cells of activated fetal thymocytes first appeared 14 days after the onset of culture and their number increased, whereas CD8+ cells or CD4CD8 double-positive cells were not observed. These results indicate that fetal CD4-CD8- thymocytes underwent phenotypic change after long periods of culture. All established clones of fetal thymocytes are CD4 single positive showing lymphocyte-TNC interactions but do not express CD3 complex. Northern blot analysis detected mRNA for the gamma T cell receptor, but no messages for the delta, alpha or beta T cell receptor. Chemical cross-linking of 125I-labelled IL2 revealed that the 90-kDa band (presumably considered to be the IL2R beta chain) was clearly present in IL2-responsive fetal clones, whereas freshly isolated day 14-15 fetal thymocytes lacked the band. Taken together, TNC might be involved in the differentiation and/or expansion of murine fetal thymocytes by inducing IL2R beta chain, which forms the functional IL2R together with IL2R alpha chain and CD4, one of the T cell accessory molecules, on the cell surface through direct cell-cell interaction.

Towards an integrated view of thymopoiesis

One prediction from the complex series of steps in intrathymic T-cell differentiation is that to regulate it the stroma controlling the process must be equally complex: the attraction of precursors, commitment to the T-cell lineage, induction of T-cell receptor (TCR) gene rearrangement, accessory molecule expression, repertoire expansion, major histocompatibility complex (MHC) molecule-based selection (positive and negative), acquisition of functional maturity and migratory capacity must all be controlled. In this review, Richard Boyd and Patrice Hugo combine knowledge of T-cell differentiation with thymic stromal cell heterogeneity to offer an integrated view of thymopoiesis within the thymic microenvironment.

Gamma/delta T cells and alpha/beta T cells differ in their developmental patterns of receptor expression and modulation requirements

Measurement of the cell surface levels of gamma/delta (TcR 1) and alpha/beta (TcR 2) T cell receptors in the chicken revealed that thymocyte subpopulations that express these receptor isotypes differ remarkably in their rates of receptor acquisition. Whereas TcR 1 expression was relatively high (greater than 10(4) sites per cell) beginning on day 12 of embryonic life, the initial levels of TcR 2 expression on embryonic thymocytes were relatively low (approximately 10(3) sites per cell) when first measurable on day 15, and increased gradually as a function of T cell maturation. In peripheral tissues, the TcR 1 cells also expressed higher receptor levels than did the TcR 2 cells, but the difference was only 2-3-fold. The TcR 2 receptors on immature T cells could be easily modulated by receptor cross-linkage, very much like immunoglobulin receptors on immature B cells. While the TcR 2 receptor modulation occurred within minutes, TcR 1 receptor modulation required several hours for completion, even in the embryonic thymus. The data indicate very different developmental programs for TcR 1 and TcR 2 expression, and suggest fundamental differences in clonal selection modes for the two T cell subpopulations.

Expression of T cell receptor V gamma 5 in the adult thymus of irradiated mice after transplantation with fetal liver cells

T cell receptor (TcR) gamma/delta displays limited diversity and its diversity is distinct in different stages of ontogeny and in different anatomical sites. The V gamma 5 and V delta 1 gene products are preferentially expressed on the early fetal thymocytes and on Thy-1+ dendritic epidermal cells, whereas the V gamma 4 and V delta 5 gene products are abundantly expressed on the adult thymocytes. To elucidate whether the developmentally ordered appearance of thymocytes expressing TcR gamma/delta is dependent on the source of T cell precursors or is controlled by the thymic environment where T cells develop, we compared the expression of V gamma 5 on the early-appearing thymocytes between irradiated mice after transplantation with fetal liver (FL) cells and those after transplantation with bone marrow (BM) cells. Sequential appearance of thymocyte subpopulations was observed in the thymus of radiation FL chimeras similar to that seen in radiation BM chimeras. A substantial number of thymocytes bearing V gamma 5 appeared in the thymus at the early stage of radiation FL chimeras, whereas few, if any, of such V gamma 5-bearing thymocytes were detected in the thymus at any stage of radiation BM chimeras. These results suggested that the ordered expression of V gamma repertoire may depend on the origin of the T cell precursors but not on the thymic environment.