To be or not to be a pro-T?

Immunological Phenotyping of Mice with a Point Mutation in Cdk4

Cyclin-dependent kinases (CDKs) play a crucial role in regulation of the mammalian cell cycle. CDK4 and CDK6 control the G1/S restriction checkpoint through their ability to associate with cyclin D proteins in response to growth factor signals. CDK4 deficiency in mice gives rise to a range of endocrine-specific phenotypes including diabetes, infertility, dwarfism, and atrophy of the anterior pituitary. Although CDK6 deficiency can cause thymic atrophy due to a block in the double-negative (DN) to double-positive (DP) stage of T cell development, there are no overt defects in immune cell development reported for CDK4-deficient mice. Here, we examined the impact of a novel N-ethyl-N-nitrosourea-induced point mutation in the gene encoding CDK4 on immune cell development. Mutant mice (Cdk4wnch/wnch) showed normal development and differentiation of major immune cell subsets in the thymus and spleen. Moreover, T cells from Cdk4wnch/wnch mice exhibited normal cytokine production in response to in vitro stimulation. However, analysis of the mixed bone marrow chimeras revealed that Cdk4wnch/wnch-derived T cell subsets and NK cells are at a competitive disadvantage compared to Cdk4+/+-derived cells in the thymus and periphery of recipients. These results suggest a possible role for the CDK4wnch mutation in the development of some immune cells, which only becomes apparent when the Cdk4wnch/wnch mutant cells are in direct competition with wild-type immune cells in the mixed bone marrow chimera.

CD117+CD44+ Stem T Cells Develop in the Thymus and Potently Suppress T-cell Proliferation by Modulating the CTLA-4 Pathway

BACKGROUND

CD117 is expressed on double-negative (DN; CD4^-CD8^-) cells (Nat Rev Immunol 14:529-545; 2014), but whether it is expressed in other stages and its subsequent functions are unclear. We used an improved method of flow cytometry to analyze different populations of thymocytes (Sci Rep 4:5781; 2014). The expression of CD117 and CTLA-4 were directly assayed in the early stage of thymocytes.

METHODS

Flow cytometry was used to analyze different populations of thymocytes, and T-cell proliferation assays, RT-PCR, and real-time RT-PCR were used to characterize the stem cells and examine the function of CD44⁺CD117⁺ cells.

RESULTS

In DN cells, CD117 expression was greatest on CD44⁺CD25⁺ cells (DN₂), followed by CD44⁺CD25^- (DN₁), CD44^-CD25⁺ (DN₃), and CD44^-CD25^- (DN₄) cells. In thymocytes, CD117 expression was highest in DN cells, followed by single-positive (SP; CD4 or CD8) and double-positive (DP; CD4⁺CD8⁺) cells.  Especially, CD117 expression was positively associated with CD44 and CTLA-4 expression. CTLA-4 expression was highest in DN cells, followed by SP and DP cells. CTLA-4 expression was positively associated with CD25, CD44, and Foxp3 expression. CD44⁺CD117⁺ T cells expressed more CTLA-4, which suppressed T-cell proliferation and blocked CTLA-4 to cause antibody-induced T-cell proliferation.

CONCLUSION

These results suggest that CD44⁺CD117⁺ T cells are stem cells and a specific T-cell phenotype that initially develops in the thymus, but they do not progress through DN₃ and DN₄ stages, lack a DP stage, and potently suppress T-cell proliferation and modulate the CTLA-4 pathway.

Molecular pathogenesis of T-cell leukaemia and lymphoma

T-cell acute lymphoblastic leukaemia (T-ALL) is induced by the transformation of T-cell progenitors and mainly occurs in children and adolescents. Although treatment outcome in patients with T-ALL has improved in recent years, patients with relapsed disease continue to have a poor prognosis. It is therefore important to understand the molecular pathways that control both the induction of transformation and the treatment of relapsed disease. In this Review, we focus on the molecular mechanisms responsible for disease induction and maintenance. We also compare the physiological progression of T-cell differentiation with T-cell transformation, highlighting the close relationship between these two processes. Finally, we discuss potential new therapies that target oncogenic pathways in T-ALL.

Cross talk among Notch3, pre-TCR, and Tal1 in T-cell development and leukemogenesis

Integrated pathways are believed to determine hematopoietic cell fate and/or neoplastic transformation. Notch signaling has been shown to regulate T-cell differentiation and leukemogenesis. However, specific target genes and molecular partners are not fully elucidated. We show that Notch3 activation sustains aberrant SCL/Tal1 overexpression and phosphorylation in mature thymocytes. Furthermore, we define the role of SCL/Tal1 as a component of an activator complex, including phosphorylated Tal1 and Sp1, that specifically enhances cyclin D1 expression and demonstrate that Tal1/Sp1 specifically co-occupy the D1 promoter in vivo, only in the presence of pre-T-cell receptor (TCR). We therefore conclude not only that cyclin D1 is a target of the Tal1/Sp1 complex, but also that Notch3-dependent activation of pre-TCR/ERK signaling regulates SCL/Tal1 function.

[Thymic nurse cells--a specialized thymic microenvironment]

<zakljucak> Vise od dve decenije nakon prvog opisa, TNC su i dalje velika nepoznanica i potrebno je jos mnogo istrazivanja pre nego sto budemo bili u mogucnosti da definisemo preciznu ulogu ovih celija u razvoju T-limfocita. Mnoga od dosadasnjih saznanja ukazuju da se timociti u kontaktu sa TNC nalaze na prekretnici u svom razvojnom putu: ili ce biti uklonjeni indukcijom apoptoze ili ce nastaviti svoj razvoj i dalje sazrevanje. Brojna pitanja su za sada bez odgovora, a medju njima su dva posebno intrigantna. Koja je razlika izmedju timocita koji se vezuju za TNC i onih koji to ne cine? Koja je razlika izmedju populacije adherentnih timocita koji su selektivno internalizovani i onih koji su iskljuceni iz procesa internalizacije? Buduca istrazivanja kretanja timocita ka, unutar i van TNC ce verujemo pruziti dragocene informacije o ovoj fazi u razvoju T-limfocita. Nezavisno od toga sta ce buducnost pokazati o pravoj ulozi TNC, jedinstven kompleks koji ove celije formiraju sa timocitima je vrlo neobican, uzbudljiv i zagonetan bioloski fenomen.

Galpha13 mediates a signal that is essential for proliferation and survival of thymocyte progenitors

G protein signaling via the Galpha12 family (Galpha12 and Galpha13) has not been well studied in T cells. To investigate whether Galpha12 and Galpha13 are involved in thymopoiesis, we expressed the regulator of G protein signaling domain of p115RhoGEF to inhibit Galpha12 and Galpha13 during thymopoiesis. Fetal thymus organ cultures seeded with p115DeltaDH-expressing progenitor cells showed impaired thymopoiesis with a block at the CD4-CD8-CD44-CD25+ (DN3) stage. Using Galpha13 or Galpha12 minigenes, we demonstrated that Galpha13, but not Galpha12, is required for thymopoiesis. T progenitor cells expressing p115DeltaDH showed reduced proliferation and increased cell death. T cell receptor stimulation of the fetal thymus organ cultures did not rescue the block. Overexpression of the antiapoptotic gene Bcl2 rescued the defect in DN3 cells and partially rescued T cell development. Therefore, Galpha13-mediated signaling is necessary in early thymocyte proliferation and survival.

Developmental Activation of the TCR α Enhancer Requires Functional Collaboration among Proteins Bound Inside and Outside the Core Enhancer

The TCR delta enhancer (Edelta) and TCR alpha enhancer (Ealpha) play critical roles in the temporal and lineage-specific control of V(D)J recombination and transcription at the TCR alphadelta locus, working as a developmental switch controlling a transition from TCR delta to TCR alpha activity during thymocyte development. Previous experiments using a transgenic reporter substrate revealed that substitution of the 116-bp minimal Ealpha, denoted Talpha1-Talpha2, for the entire 1.4-kb Ealpha led to a premature activation of V(D)J recombination. This suggested that binding sites outside of Talpha1-Talpha2 are critical for the strict developmental regulation of TCR alpha rearrangement. We have further analyzed Ealpha to better understand the mechanisms responsible for appropriate developmental regulation in vivo. We found that a 275-bp Ealpha fragment, denoted Talpha1-Talpha4, contains all binding sites required for proper developmental regulation in vivo. This suggests that developmentally appropriate enhancer activation results from a functional interaction between factors bound to Talpha1-Talpha2 and Talpha3-Talpha4. In support of this, EMSAs reveal the formation of a large enhanceosome complex that reflects the cooperative assembly of proteins bound to both Talpha1-Talpha2 and Talpha3-Talpha4. Our data suggest that enhanceosome assembly is critical for developmentally appropriate activation of Ealpha in vivo, and that transcription factors, Sp1 and pCREB, may play unique roles in this process.

Differential expression of notch signaling-related transcripts accompanies Pro-thymocyte proliferation and phenotype transition induced by epidermal growth factor plus insulin in fetal thymus organ cultures

Thymus regression upon stressing stimuli, such as infectious diseases, is followed by organ reconstitution, paralleling its development in ontogeny. A narrow window of thymus development was here studied, encompassing the pro-T lymphoid precursor expansion during specification stages, by the use of epidermal growth factor plus insulin (INS) in murine fetal thymus organ cultures. Aiming to disclose signaling pathways related to these stages, cultured thymus lobes had their RNA extracted, for the search of transcripts differentially expressed using RNAse protection assays and reverse transcriptase-polymerase chain reactions. We found no difference that could explain INS-driven thymocyte growth, in the pattern of transcripts for death/proliferation mediators, or for a series of growth factor receptors and transcriptional regulators known as essential for thymus development. Thymocyte suspensions from cultured lobes, stained for phenotype analysis by fluorescence activated cell sorting, showed a decreased staining for Notch1 protein at cell surfaces upon INS addition. We analyzed the expression of Notch-related elements, and observed the recruitment of a specific set of transcripts simultaneous and compatible with INS-driven thymocyte growth, namely, transcripts for Notch3, for its ligand Jagged2, and for Deltex1, a mediator of a poorly characterized alternative pathway downstream of the Notch receptor.

Requirement for cyclin D3 in lymphocyte development and T cell leukemias

The D-type cyclins (cyclins D1, D2, and D3) are components of the core cell cycle machinery in mammalian cells. Cyclin D3 gene is rearranged and the protein is overexpressed in several human lymphoid malignancies. In order to determine the function of cyclin D3 in development and oncogenesis, we generated and analyzed cyclin D3-deficient mice. We found that cyclin D3(-/-) animals fail to undergo normal expansion of immature T lymphocytes and show greatly reduced susceptibility to T cell malignancies triggered by specific oncogenic pathways. The requirement for cyclin D3 also operates in human malignancies, as knock-down of cyclin D3 inhibited proliferation of acute lymphoblastic leukemias deriving from immature T lymphocytes. These studies point to cyclin D3 as a potential target for therapeutic intervention in specific human malignancies.

Regulation of T-cell receptor D beta 1 promoter by KLF5 through reiterated GC-rich motifs

Rearrangement of T-cell receptor (TCR) and immunoglobulin genes by a common V(D)J recombination machinery is regulated by developmentally specific chromatin changes at the target locus, a process associated with transcription. At the TCRbeta locus, the Ebeta enhancer and the Dbeta1 promoter regulate germline transcription originating near the TCR Dbeta1 gene segment. The Dbeta1 promoter contains 3 GC-rich motifs that bind a common set of nuclear proteins from pro-T-cell lines. Mutations that diminish the binding of nuclear proteins also diminish the activity of the Dbeta1 promoter in transcriptional reporter assays. Using a yeast one-hybrid approach, 3 Krüppel-like factors-KLF3, KLF5, and KLF6-and a novel zinc finger protein were identified in a thymus library, all of which bound the GC-rich motif in a sequence-specific manner. Of these genes, KLF5 mRNA was expressed in a restricted manner in lymphoid cells and tissues, with highest expression in pro-T-cell lines and Rag-deficient thymocytes. Antibody supershift studies and chromatin immunoprecipitation assay confirmed that KLF5 bound the Dbeta1 promoter. In reporter gene assays, KLF5 but not KLF6 efficiently transactivated the Dbeta1 promoter, whereas a dominant-negative KLF5 construct inhibited reporter expression. These data suggest that reiterated GC motifs contribute to germline TCRbeta transcription through binding of KLF5 and other Krüppel family members and that restricted expression of KLF5 may contribute to lineage-specific regulation of germline TCRbeta transcription.

Lymphocyte development in neonatal and adult c-Kit-deficient (c-KitW/W) mice

Hematopoietic stem cells and lymphocyte progenitors express the receptor tyrosine kinase c-Kit. In fetal and neonatal life, c-Kit plays a redundant role in T, and no apparant role in B cell development. In neonatal mice deficient for both c-Kit and the common gamma chain (gammac), a component of the interleukin-7 (IL-7) receptor, the thymus is alymphoid, and therefore lacks T cell receptor (TCR) beta, gamma, and delta rearrangements. Thus, a critical role for c-Kit in T cell development around birth is well established. More recently, it has become possible to examine the impact of c-Kit deficiency under conditions of steady state lymphopoiesis in adult life. Such analysis has been made possible by the identification of a viable adult c-Kit-deficient (c-KitW/W) variant, termed the Vickid mouse. The Vickid mouse arose by outcrossing c-KitW-bearing mice of the WB strain, in which lack of c-Kit is lethal, to a mixed genetic background. In adult Vickid mice, mainstream alphabeta TCR+ thymocyte development, and B cell development in the bone marrow are severely c-Kit-dependent with progressive age. Analysis of other pathways of developing T cells, i.e. CD4-CD8- (double neagative [DN]) alphabeta TCR+ and DN gammadelta TCR+ thymocytes revealed that the development of both lineages is also severely affected by lack of c-Kit. However, numbers of gammadelta TCR+ T cells decline before numbers of alphabeta TCR+ T cells in the thymus. In contrast to T and B cell development, generation of NK cells is not affected in adult c-KitW/W mice.

Developmental dissociation of T cells from B, NK, and myeloid cells revealed by MHC class II-specific chimeric immune receptors bearing TCR-zeta or FcR-gamma chain signaling domains

The T-cell receptor zeta (TCR-zeta) and FcR-gamma chains play a critical role in mediating signal transduction. We have previously described HIV glycoprotein 120 (gp120)-specific chimeric immune receptors (CIRs) in which the extracellular domain of CD4 is linked to the signaling domain of zeta (CD4zeta) or gamma (CD4gamma). Such CIRs are efficiently expressed following retroviral transduction of mature T cells and specifically redirect effector functions toward HIV-infected targets. In this report, we examine development of CD4zeta- or CD4gamma-expressing T cells from retrovirally transduced hematopoietic stem cells following bone marrow transplantation. Although CD4zeta/gamma-expressing myeloid, NK, and B cells were efficiently reconstituted, parallel development of CD4zeta/gamma-expressing T cells was blocked prior to the CD25(+)CD44(+) prothymocyte stage. In contrast, T cells expressing a signaling-defective CIR were efficiently generated. When major histocompatibility complex (MHC) class II-deficient mice were used as transplant recipients, development of CD4zeta/gamma-expressing T cells was restored. We conclude that CD4zeta/gamma signaling generated following engagement of MHC class II selectively arrests T-lineage development.

Development of alphabeta T cells in the human thymus

The thymus is the main producer of alphabeta T cells and is, therefore, crucial for a normal immune system. The intrathymic developmental pathway of human alphabeta T cells has now been delineated. The production of new T cells by the thymus decreases with age, and the thymus was thought to be redundant in adults once the peripheral T-cell pool has been formed early in life. However, recent work has shown that the thymus can function even at an advanced age. Research into the production of T cells in clinical settings that are associated with loss of T cells in the periphery has sparked renewed interest in the function of the human thymus.

A role for CD147 in thymic development

We have previously identified a mAb that binds to a molecule expressed preferentially on the surface of cycling thymocytes. In this study the molecule recognized by this mAb has been identified in the mouse as CD147 (basigin) by expression cloning. We show that CD147 expression correlates with cycling of immature thymocytes even in the absence of TCRbeta selection and that ligation of this molecule on immature fetal thymocytes inhibits their further development into mature T cells.

Expression of Notch ligands, Jagged1, 2 and Delta1 in antigen presenting cells in mice

Notch1 is indispensable for T cell development. It is anticipated that Notch1 and other Notch receptors expressed on the surface of thymic T cell precursors are activated by ligands present on environmental cells, including antigen presenting cells (APCs), and involved in positive and negative selections. Notch receptors on peripheral T cells may also be activated by ligands on APCs. Here, we examined the expression pattern of three Notch ligands, Jagged1, 2 and Delta1 in APCs by an immunofluorescence cell staining method and a reverse transcriptase-polymerase chain reaction (RT-PCR) method. Peritoneal macrophages were strongly positive for Jagged1 staining. In contrast, macrophages separated from spleen and dendritic cells (DCs) separated from spleen and thymus showed positive staining for all the three ligands at a similar intensity. An analysis by RT-PCR revealed that peritoneal and splenic macrophages and splenic and thymic DCs, show a distinct pattern in Notch ligand expression. These findings may represent that expression of various Notch ligands in APCs has a physiological relevance in each organ.

The upstream enhancer is necessary and sufficient for the expression of the pre-T cell receptor alpha gene in immature T lymphocytes

The expression of the pre-T cell receptor alpha (pTa) gene occurs exclusively in immature T lymphocytes and is regulated by poorly defined mechanisms. We have analyzed the role of the upstream enhancer in pTa expression using conventional and bacterial artificial chromosome (BAC) reporter transgenes. The deletion of the enhancer completely abolished the expression of pTa BAC reporter in transgenic mice. Conversely, the combination of pTa enhancer and promoter targeted transgenes specifically to immature thymocytes, recapitulating the expression pattern of pTa. The core enhancer is conserved between mice and humans and contains a critical binding site for the transcription factor c-Myb. We also show that pTa promoter contains a conserved tandem E box site activated by E protein, HEB. These data establish the enhancer as a critical element regulating pTa gene expression and identify additional targets for c-Myb and E proteins in T cell development.

Delineation of intrathymic T, NK, and dendritic cell (DC) progenitors in fetal and adult rats: demonstration of a bipotent T/DC intermediate precursor

We previously published study results stating that the early rat fetal liver contains a high frequency of T/dendritic cells (DCs), but rarely T/NK bipotent common progenitors. Now, by using xenogenic rat/SCID mouse fetal thymic organ cultures, we extend these observations to the thymus, in which conflicting data have been published in human and mouse. On the one hand, enriched adult intrathymic CD45+CD2- triple negative for CD8, CD4, and CD3 Ag cell progenitors, which contained both rearranged TCRbeta chain and pre-Talpha chain transcripts, completely lacked NKR-P1A expressing cells, and upon limiting dilution conditions, generated T- and T/DC-containing lobes, but no T/NK or NK ones were found. On the other hand, the CD45+CD2- triple negative for CD8, CD4, and CD3 Ags cell population obtained from 15- and 16-day-old fetal rat thymus can be divided into NKR-P1A- and NKR-P1A(low) cell subpopulations that differ in several aspects. Both cell subsets expressed pre-TCRalpha chain transcripts, but only the former contained fully rearranged TCRbeta chain transcripts. Upon limiting dilution, T cell-committed progenitors were only found in the NKR-P1A- cell population, whereas NK-committed progenitors were present in the NKR-P1A(low) population. More importantly, bipotential T/NK progenitors were very rare and were found only in the NKR-P1A(low) cell population, whereas bipotential T/DC progenitors, only previously suggested in the adult mouse thymus, were observed frequently in the NKR-P1A-CD2- cell subpopulation. Our results demonstrate, therefore, that a common intrathymic T/DC intermediate represents the main T cell developmental pathway in rat thymus.

Contribution of double-negative thymic precursors to CD8alpha alpha (+) intraepithelial lymphocytes of the gut in mice bearing TCR transgenes

Using male and female RAG(-/-) mutant mice expressing TCR transgenes specific for MHC class I- or II-presented HY peptides, we performed quantitative and phenotypic comparisons between the TCR(+) lymphocytes present in the lymphoid organs and the gut mucosa in euthymic versus athymic (nude) animals. These comparisons suggest that only a minority of the TCR(+) CD8alpha alpha (+) intraepithelial lymphocytes (IEL) of the transgenic euthymic mice originate from hematopoietic precursors acquiring a TCR in the gut wall, while a majority of these CD8alpha alpha(+) IEL appear to be of thymic origin (as were all TCR(+) CD8alpha beta (+) or CD4(+) in any location); these last cells are released from the thymus as double-negative thymocytes, which are at a more immature stage (CD44(+)CD25(+)) in female mice than in males (CD44(-)). In view of previous observations that in non-transgenic athymic mice the CD8alpha alpha (+) TCR(+) IEL populations are also markedly reduced quantitatively, the possibility of a thymic contribution to these ontogenically peculiar populations may also exist in normal mice. At which stage of differentiation such precursors might leave the thymus of normal adult mice remains to be explored.

Distinct BMI-1 and EZH2 expression patterns in thymocytes and mature T cells suggest a role for Polycomb genes in human T cell differentiation

BMI-1 and EZH2 Polycomb-group (PcG) proteins belong to two distinct protein complexes involved in the regulation of hematopoiesis. Using unique PcG-specific antisera and triple immunofluorescence, we found that mature resting peripheral T cells expressed BMI-1, whereas dividing blasts were EZH2(+). By contrast, subcapsular immature double-negative (DN) (CD4(-)/CD8(-)) T cells in the thymus coexpressed BMI-1 and EZH2 or were BMI-1 single positive. Their descendants, double-positive (DP; CD4(+)/CD8(+)) cortical thymocytes, expressed EZH2 without BMI-1. Most EZH2(+) DN and DP thymocytes were dividing, while DN BMI-1(+)/EZH2(-) thymocytes were resting and proliferation was occasionally noted in DN BMI-1(+)/EZH2(+) cells. Maturation of DP cortical thymocytes to single-positive (CD4(+)/CD8(-) or CD8(+)/CD4(-)) medullar thymocytes correlated with decreased detectability of EZH2 and continued relative absence of BMI-1. Our data show that BMI-1 and EZH2 expression in mature peripheral T cells is mutually exclusive and linked to proliferation status, and that this pattern is not yet established in thymocytes of the cortex and medulla. T cell stage-specific PcG expression profiles suggest that PcG genes contribute to regulation of T cell differentiation. They probably reflect stabilization of cell type-specific gene expression and irreversibility of lineage choice. The difference in PcG expression between medullar thymocytes and mature interfollicular T cells indicates that additional maturation processes occur after thymocyte transportation from the thymus.

Molecular determinants of TCR expression and selection

The process of T cell development in the thymus is tightly regulated, being dependent on the integration of signals required for thymocyte maturation and survival. Rearrangements, expression and signaling of TCR genes play an indispensable role in this developmental program. Recent advances have provided insights into the molecular mechanisms that regulate TCR repertoire formation at the level of alphabeta versus gammadelta T cell fate and CD4(+) versus CD8(+) lineage determination.

Notch1 regulates maturation of CD4+ and CD8+ thymocytes by modulating TCR signal strength

Notch signaling regulates cell fate decisions in multiple lineages. We demonstrate in this report that retroviral expression of activated Notch1 in mouse thymocytes abrogates differentiation of immature CD4+CD8+ thymocytes into both CD4 and CD8 mature single-positive T cells. The ability of Notch1 to inhibit T cell development was observed in vitro and in vivo with both normal and TCR transgenic thymocytes. Notch1-mediated developmental arrest was dose dependent and was associated with impaired thymocyte responses to TCR stimulation. Notch1 also inhibited TCR-mediated signaling in Jurkat T cells. These data indicate that constitutively active Notch1 abrogates CD4+ and CD8+ maturation by interfering with TCR signal strength and provide an explanation for the physiological regulation of Notch expression during thymocyte development.