Recent insights into the signals that control αβ/γδ-lineage fate

Summary:  During thymopoiesis, two major types of mature T cells are generated that can be distinguished by the clonotypic subunits contained within their T-cell receptor (TCR) complexes: αβ T cells and γδ T cells. Although there is no consensus as to the exact developmental stage where αβ and γδ T-cell lineages diverge, γδ T cells and precursors to the αβ T-cell lineage (bearing the pre-TCR) are thought to be derived from a common CD4⁻CD8⁻ double-negative precursor. The role of the TCR in αβ/γδ lineage commitment has been controversial, in particular whether different TCR isotypes intrinsically favor adoption of the corresponding lineage. Recent evidence supports a signal strength model of lineage commitment, whereby stronger signals promote γδ development and weaker signals promote adoption of the αβ fate, irrespective of the TCR isotype from which the signals originate. Moreover, differences in the amplitude of activation of the extracellular signal-regulated kinase- mitogen-activated protein kinase-early growth response pathway appear to play a critical role. These findings will be placed in context of previous analyses in an effort to more precisely define the signals that control T-lineage fate during thymocyte development.     

Crucial function of the pre-T-cell receptor (TCR) in TCRP selection, TCRβ allelic exclusion and αβ versus γδ lineage commitment

Summary: The analysis of T-cell receptor (TCR) βselection, TCRβ allelic exclusion and TCRβ rearrangement in γδ T cells from normal and pre-TCR-deficient mice has shown that the pre-TCR has a crucial role in T-lyinpbocyte development:

• *

  The pre-TCR is by far the most effective receptor that generates large numbers of CD4⁺8⁺ T cells with productive TCRβ rearrangements.
• *

  In the absence of the pre-TCR, TCRβ rearrangement proceeds in developing cells irrespective of whether they already contain a productive TCRβ gene.
• *

  The pre-TCR directs developing T cells to the αβ lineage because y5 T cells from pTα^-/- mice proceed much further in TCRβ rearrangement than γδ T cells from wild-type mice. It is argued that the pre-TCR commits developing T cells to the αβ lineage by an instructive mechanism, which has largely replaced an evolutionarily more ancient mechanism that involves stochastic αβ lineage commitment.

     

Development and selection of γδ T cells

Summary:  Two main lineages of T cells develop in the thymus: those that express the αβ T-cell receptor (TCR) and those that express the γδ TCR. Whereas the development, selection, and peripheral localization of newly differentiated αβ T cells are understood in some detail, these processes are less well characterized in γδ T cells. This review describes research carried out in this laboratory and others, which addresses several key aspects of γδ T-cell development, including the decision of precursor cells to differentiate into the γδ versus αβ lineage, the ordered differentiation over the course of ontogeny of functional γδ T-cell subsets expressing distinct TCR structures, programming of ordered Vγ gene rearrangement in the thymus, including a molecular switch that ensures appropriate Vγ rearrangements at the appropriate stage of development, positive selection in the thymus of γδ T cells destined for the epidermis, and the acquisition by developing γδ T cells of cues that determine their correct localization in the periphery. This research suggests a coordination of molecularly programmed events and cellular selection, which enables specialization of the thymus for production of distinct T-cell subsets at different stages of development.     

Integrated morphogen signal inputs in γδ versus αβ T-cell differentiation

Summary:  Morphogens, a class of secreted proteins that regulate gene expression in a concentration-dependent manner, are responsible for directing nearly all lineage fate choices during embryogenesis. In the thymus, morphogen signal pathways consisting of WNT, Hedgehog, and the transforming growth factor-β superfamily are active and have been implicated in various developmental processes including proliferation, survival, and differentiation of maturing thymocytes. Intriguingly, it has been inferred that some of these morphogen signal pathways differentially affect γδ and αβ T-cell development or maintenance, but their role in T-cell lineage commitment has not been directly probed. We have recently identified a modulator of morphogen signaling that significantly influences binary γδ versus αβ T-cell lineage diversification. In this review, we summarize functions of morphogens in the thymus and provide a highly speculative model of integrated morphogen signals, potentially directing the γδ versus αβ T-cell fate determination process.     

γδ T-Cell Precursor-Derived CD4− CD8−αβ T Cells Retain γδ Cell Function

We have previously shown that some of the DNαβ⁺ T cells arising in TcRα-chain transgenic mice are of γδ T cell origin, based on phenotypic data and on their status of TcR gene rearrangements. In the present report we investigated the impact of αβ TcR expression on the functional programme of the mature γδ precursor-derived DNαβ⁺ T cells. Our results demonstrate that both their proliferative capacity and their cytokine production profile are similar to that of γδ T cells. Furthermore, both transgenic DNαβ⁺ T cells and DNγδ⁺ T cells up-regulate CD8α expression after activation, but, in contrast to CD4⁺αβ T cells, are unable to induce proliferation of naive B cells. Thus, our results suggest that the effector functions of mature T cells are determined independently of the TcR isotype, probably at an early stage of differentiation, and thereby have important implications for current models of T-cell lineage commitment.     

Antigen recognition by γδ T cells

Summary:  γδ T cells contribute to host immune competence uniquely. This is most likely because they have distinctive antigen-recognition properties. While the basic organization of γδ T-cell receptor (TCR) loci is similar to that of αβ TCR loci, there is a striking difference in how the diversity of γδ TCRs is generated. γδ and αβ T cells have different antigen-recognition requirements and almost certainly recognize a different set of antigens. While it is unclear what most γδ T cells recognize, the non-classical major histocompatibility complex class I molecules T10 and T22 were found to be the natural ligands for a sizable population (0.2–2%) of murine γδ T cells. The recognition of T10/T22 may be a way by which γδ T cells regulate cells of the immune system, and this system has been used to determine the antigen-recognition determinants of γδ T cells. T10/T22-specific γδ T cells have TCRs that are diverse in both V gene usage and CDR3 sequences. Their Vγ usage reflects their tissue origin, and their antigen specificity is conferred by a motif in the TCR δ chain that is encoded by V and D segments and by P-nucleotide addition. Sequence variations around this motif modulate affinities between TCRs and T10/T22. That this CDR3 motif is important in antigen recognition is confirmed by the crystal structure of a γδ TCR bound to its ligand. The significance of these observations is discussed in the context of γδ T-cell biology.     

Skin γδ T-cell functions in homeostasis and wound healing

Summary:  There is a resident population of T cells found in murine skin that expresses an invariant Vγ3Vδ1 T-cell receptor (TCR), and these cells are significantly different from lymphoid γδ T cells and αβ T cells in terms of ontogeny, tissue tropism, and antigen receptor diversity. These dendritic epidermal T cells are derived from fetal thymic precursor cells, are in constant contact with neighboring epidermal cells, and express a monoclonal γδTCR only found in the skin. Skin γδ T cells have been shown to play unique roles in tissue homeostasis and during tissue repair through local secretion of distinct growth factors including keratinocyte growth factors and insulin-like growth factor-1. In this review, we discuss evidence supporting a role for cross talk between skin γδ T cells and keratinocytes that contributes to the maintenance of normal skin and wound healing.     

γδ and αβ T Cells are Equally Susceptible to Apoptosis

Gamma/delta TCR bearing T lymphocytes represent a T-cell subset whose functional relevance remains unclear. Nevertheless these T cells may play a role in the early immune reponse against bacteria. Until now the regulatory mechanisms on this response have not been investigated. The study described here evaluated the immunoregulatory effects of Interleukin-10 on γ/δ and α/β TCR-positive T-cell clones and freshly isolated peripheral-blood mononuclear cells (PBMC). IL-10 has been shown previously to inhibit lectin and antigen-induced proliferation and cytokine production by α/β T cells. The results outlined below show that rhIL-10 strongly inhibits lectin-induced production of IFN-γ, TNF-α. IL-2, and to a lesser degree proliferation and IL-4 production of both T-cell subsets. As IL-10 did not inhibit proliferation but at the same time strongly suppressed cytokine production in various experiments, the hypothesis that it could function as a growth factor for human T cells as has been described for murine thymoeytes was tested. The data demonstrate that, although the γ/δ T-cell clones tested do not produce IL-10 they can use it as a growth factor in combination with IL-2, IL-4 or alone. Furthermore, IL-10 has the same properties on human α/β T-cell clones and PBMC. In summary, it is shown that IL-10 has pleiotropic effects on γ/δ and α/β TCR⁺ T cells by inhibiting lectin-induced cytokine production and by acting as a growth factor for these cells alone or in combination with IL-2 or IL-4.     

A retrospective on the requirements for γδ T-cell development

Summary:  Since the discovery of γδ T cells two decades ago, considerable effort has been made to understand their developmental program, their antigen specificity, and their contribution to the immune response. In this review, we focus on what is known about γδ T-cell development and on the advances that have been made in determining which genes are required. In addition, we compare the genetic requirements for αβ and γδ T-cell development with the hope of gaining a better picture of the signaling pathways that govern the development of γδ lineage cells.     

γδ intraepithelial lymphocytes drive tumor necrosis factor-α responsiveness to intestinal iron challenge: relevance to hemochromatosis

Summary: The dependence of intestinal epithelial cell (IEC) growth and differentiation on intraepithelial lymphocytes (IELs) expressing the gamma/delta (γδ) T-cell receptor (TCR), suggested a potential role for γδ⁺ IELs in the regulation of iron absorption. We therefore examined the levels of hepatic iron and the IEL cytokine responses in C57BL/6J control and class I and TCR knockout lines (placed on a C57BL/6J genetic background) following the administration of supplemental dietary iron. The highest level of liver iron was found in the β2-microglobulin knockout (β2m^-/-) mice followed by the TCR-δ knockout (TCRδ^-/-) animals. TCR-α knockout (TCRα^-/-) and control animals did not differ in their iron levels. Liver iron loading correlated inversely with rhe ability of the mice to generate an IEL tumor necrosis factor (TNE)-α response. These observations suggest a model in which IEC iron loading is communicated to IELs via the HFE class I protein. The result of this communication is the initiation of TNE-α release by γδ⁺ IELs (sustained by macrophages and dendritic cells) contributing to the upregulation of ferritin expression and possibly to the normal maintenance of the IEC apoptotic pathway.     

The αβ T Cell Receptor Clustering Upon Superantigen/MHC Recognition

Antigen recognition by T cells is the key event for the antigen specific immune responses to be triggered. This recognition is initiated by the binding of the T cell receptor (TCR) to antigen peptide/major histocompatibility complex (MHC) on the surface of the antigen presenting cells. TCR on most of the T cells is a heterodimer composed of α and β chains which are associated with CD3 γδε as well as ζ chains, the signal transmission molecules. The dynamics of this TCR complex upon antigen/MHC recognition, however, has not been well understood. In this paper the authors analyse the configuration of TCR complex on T cells from a TCR β chain gene transgenic mouse (TGM) strain. Unlike many other TGM strains reported, a considerable proportion of T cells from this TGM expresses both transgene-encoded (Vβ3) and endogenous TCR β chains on their surface. By immunoprecipitation and immunoblotting analysis of T cells stimulated with a superantigen, staphylococcal enterotoxin B (SEB), the authors found that Vβ3 was coprecipitated with Vβ8, demonstrating the clustering of TCR αβ upon superantigen/MHC recognition.     

Accessibility control of variable region gene assembly during T-cell development

Summary: T-cell development is a complex and ordered process that is regulated in part by the progressive assembly and expression of antigen receptor genes. T cells can be divided into two lineages based on expression of either an αβ or γδ T-cell antigen receptor (TCR), The genes that encode the TCR β and y chains lie in distinct loci, whereas the genes that encode the TCR a and S chains he in a single locos (TCR α/δ locus). Assembly of TCR variable region genes is mediated by a site-specific recombination process that is common among all lymphocytes. Despite the common nature of this process, recombination of TCR genes is tightly regulated within the context of the developing T cell. TCR β, γ and δ variable region genes are assembled prior to TCR α variable region genes. Furthermore, assembly of TCR β variable region genes is regulated within the context of allelic exclusion. The regulation of rearrangement arid expression of genes within the TCR α/δ locus presents a complicated problem. TCR α and δ variable region genes are assembled at different stages of T-cell development, and fully assembled TCR α and δ variable region genes must be expressed in distinct hneages of T cells, αβ and γδ. respectively We have developed several experimental approaches lo assess the role of cis-acting elements in regulating recombination and expression of TCR genes. Here we describe these approaches and discuss our analyses of the regulation of accessibility of the TCR β and TCR α/δ foci during T-cell development.     

A Highly Conserved Phenylalanine in the α, β-T Cell Receptor (TCR) Constant Region Determines the Integrity of TCR/CD3 Complexes

In the present study, we have investigated the importance of a phenylalanine (phe¹⁹⁵) in the Tcr-Cα region on Tcr-α, β/CD3 membrane expression. An exchange of phe¹⁹⁵ with a tyrosine residue does not affect Tcr/CD3 membrane expression; however, exchange with aspartic acid, histidine or valine prohibit completely Tcr/CD3 membrane expression. This seems to be due to a lack of interaction between mutated Tcr-α, β/CD3-γɛ, δɛ complexes and ζ₂ homodimers. The Tcr-Cα region around phe¹⁹⁵ seems together with the same region in the Tcr-Cβ region to constitute an interaction site for ζ₂ homodimers. The presence of phe¹⁹⁵ on both Tcr-Cα and Tcr-Cβ causes high avidity interaction with ζ₂ homodimers, whereas his¹⁹⁵ in both Tcr-Cγ and Tcr-Cδ results in an apparently lower avidity interaction with ζ₂ homodimers. It is suggested that the phe¹⁹⁵ region (on β-strand F) and eventually adjacent aromatic amino acid residues on β-strand B region may play an important role in Tcr-α, β/CD3 membrane expression, in Tcr-α, β/CD3 competition with Tcr-γ, δ/CD3 complexes for ζ₂ homodimers and in the control of formation of 'mixed' Tcr heterodimers.     

Vδ1+ Gamma/Delta T Lymphocytes Infiltrating Human Lung Cancer Express the CD8α/α Homodimer

Murine γ/δ T lymphocytes localize to different epithelial tissues and are phenotypically distinct from peripheral γ/δ T cell-populations in that they show limited TCR diversity, express the CD8 α/α homodimer and lack the CD8β chain. In humans, a compartmentalization of γ/δ cells sharing similar phenotypic features has been documented to date only in the case of intestinal epithelium. In the present study we show that about half of Vδ1⁺ (as well as Vδ1⁻Vδ2⁻) γ/δ lymphocytes, which can be selectively expanded from human lung cancers, coexpress the CD8α/α homodimer. The accumulation of intraepithelial CD8⁺γ/δ⁺ lymphocytes might then be a more general phenomenon, possibly as a result of common mechanisms operating at those sites.     

Structure of the T-Cell Receptor in a Tiαβ, Tiγδ Double Positive T-Cell Line

The multichain T-cell receptor is composed of at least six different polypeptide chains. The clonotypic Ti heterodimer (Tiαβ or Tiγδ) is non-covalently associated with the CD3 chains (CD3γδɛζ). The exact number of subunits constituting the T-cell receptor is still not known. It has been suggested that each T-cell receptor contains two Ti dimers. To gain insight into the structure of the T-cell receptor we constructed a Tiαβ, Tiγδ double positive T-cell line which contained four functional Ti chains (Tiαβ, β, γ, and δ). The data demonstrated an absence of Ti dimers containing mixtures of chains other than the typical Tiαβ and Tiγδ combinations. Furthermore, by co-modulation experiments we demonstrated that the Tiαβ and the Tiγδ dimers were not expressed in the same T-cell receptor. Our data indicate that the T-cell receptor does not contain two Ti dimers.     

Small Cytoplasmic Antigens from Pseudomonas aeruginosa Stimulate γδ T Lymphocytes

γδ T lymphocytes respond to different bacterial antigens and transformed cells. The antigenic molecules responsible for this activity have been studied extensively in antigenic preparations from Mycobacterium . We describe here the in vitro effect of Pseudomonas aeruginosa on γδ T lymphocytes and the properties of the implicated compounds. We found a preferential γδ T-cell expansion when we used heat-treated P. aeruginosa preparations and a dose-dependent inhibition of proliferation of peripheral blood mononuclear cells (PBMC) when non-heat-treated antigens were studied. This expansion corresponded to a Vγ9-positive subpopulation. In contrast to αβ T lymphocytes, the highest stimulatory activity was restricted to very small cytosolic compounds. This activity was protease resistant and phosphatase sensitive and always dependent on interleukin (IL)-2 or αβ T-cell activation. We concluded that the antigenic molecules from P. aeruginosa that activated γδ T lymphocytes were small, non-peptidic, phosphorylated compounds, similar to those previously described from Mycobacterium .     

Human γδ T Cells Produce the Protease Inhibitor and Antimicrobial Peptide Elafin

Human γδ T cells rapidly secrete pro-inflammatory cytokines in response to T cell receptor-dependent recognition of pyrophosphates produced by many bacteria and parasites. In further support of an important role of γδ T cells in the immune defence against infection, human γδ T cells have been shown to produce the antimicrobial peptide LL37/cathelicidin. In this study, we have investigated whether γδ T cells can produce additional antimicrobial peptides. To this end, we have screened human γδ T cell clones by RT-PCR for mRNA expression of a broad range of antimicrobial peptides. While α-defensins were absent and β-defensins (HBD1) present only in rare γδ T cell clones, elafin mRNA was induced by supernatant of Pseudomonas aeruginosa grown under static conditions. Elafin is a protease inhibitor that also displays antimicrobial activity. Constitutive intracellular expression of elafin was demonstrated by flow cytometry and Western blot analysis. Furthermore, trappin-2 (pre-elafin) could be immunoprecipitated in cell lysates but also in the supernatant of γδ T cells stimulated by Ps. aeruginosa supernatant. Taken together, our studies reveal a novel effector function of γδ T cells which might be important for local immune defence.     

γδ T cells: firefighters or fire boosters in the front lines of inflammatory responses

Summary:  Intradermal inoculation of cloned self-reactive αβ T cells into the footpads of mice induced cutaneous graft-versus-host disease (GVHD), and after recovery from GVHD, the epidermis became resistant to subsequent attempts to induce GVHD. Resistance to GVHD was not induced in the epidermis of T-cell receptor δ-deficient (TCRδ^−/−) mice that lacked γδ T cells bearing canonical Vγ5/Vδ1⁺γδTCRs, known as dendritic epidermal T cells (DETCs), and resistance was restored by reconstitution of these mutant mice with precursors of Vγ5⁺ DETCs. Pulmonary infection by Cryptococcus neoformans induced an increase of γδ T cells in the lung, and in comparison with wildtype mice, TCRδ^−/− mice eliminated C. neoformans more rapidly and synthesized more interferon-γ in the lung. In the mouse small intestine, the absence of γδ T cells is associated with a reduction in epithelial cell turnover and downregulation of the expression of major histocompatibility complex class II molecules. The protective role of γδ T cells was verified in a dextran sodium sulfate-induced inflammatory bowel disease (IBD) model, whereas in a spontaneous model of IBD, γδ T cells were involved in the exacerbation of colitis in TCRα^−/− mice. Taken together, in addition to the homeostatic regulation of epithelial tissues, γδ T cells appear to play a pivotal role in the modification of inflammatory responses induced in many organs containing epithelia.     

Experimental Human Plasmodium Falciparum Infections: Longitudinal Analysis of Lymphocyte Responses with Particular Reference to γδ T Cells

The kinetics of the γδ T-cell response was analysed in the context of the overall haematological response in subjects experimentally infected with sporozoites of Plasmodium falciparum . Numbers of γδ and αβ T cells and NK cells declined markedly during infection to reach minimum values 12–13 days post-infection when the patients were ill. This decline commenced from the beginning of the erythrocytic cycle and well before parasites could be detected microscopically and clinical symptoms developed. Platelet numbers also declined. In vivo activation of γδ T cells was evident with sequential up-regulation of the activation markers CD69 and HLA-DR. γδ T cell numbers were highest after treatment with the majority being CD4⁻CD8⁻, HLA-DR⁺ and showing reduced CD45RA expression. Contrary to some published observations γδ T-cell percentages remained within the normal range. Little evidence of up-regulation of activation or memory markers was observed in the αβ T-cell population. In vitro proliferative responses to malaria antigen which involve γδ T cells were lost as the infection progressed and the lymphocyte count declined but these could be restored with the addition of exogenous IL-2 to cultures. The authors findings are consistent with a protective and/or immunomodulatory role for γδ T cells in malaria.     

Interleukin-2 (IL-2) Receptor α, β and γ Subunit Expression as a Function of B-Cell Lineage Ontogeny: the Use of IL-2-PE664Glu to Characterize Internalization via IL-2 Receptor Subunits

Interleukin-2 (IL-2) is a pluripotent cytokine which plays a crucial role in the immune system response. Although the IL-2/IL-2 receptor (IL-2R) system has been well characterized in cells of the T lineage it is less known in B lymphocytes. The authors therefore studied the expression of the IL-2Rα, β and γ subunits in human B-cell lines at different stages of maturation, by the polymerase chain reaction technique. The authors found that the α and β subunits are expressed in the final stages of B-cell lineage maturation, whereas the γ subunit is constitutively expressed during B-lymphocyte differentiation. The results indicate that the IL-2/IL-2R system, most probably, does not have a role in the early stages of B-cell differentiation, but may be involved only in the final stages of B-cell lineage ontogeny. Moreover, the ability of the different forms of IL-2R to internalize the IL-2 ligand was investigated, using the chimeric protein IL-2-PE66^4Glu. Cell lines bearing the αγ, βγ and αβγ forms of IL-2R were inhibited by the chimeric protein, while those bearing the γ subunit alone did not respond to the chimera. Thus, internalization of IL-2 is most likely mediated via the αγ form of the IL-2R, as shown here for the first time, as well as through the βγ and αβγ IL-2R forms. However, IL-2 cannot be internalized through the IL-2R γ subunit alone.