Requirement for positive selection of gamma delta receptor-bearing T cells

Uncovering the mysteries of human gamma delta T cells: from origins to novel therapeutics

Gamma delta (γδ) T cells represent a unique and distinct population of lymphocytes that bridge the innate and adaptive immune responses. This functional duality positions them as one of the pivotal elements in the evolution and development of the human body's defense mechanisms. This review aims to provide a comprehensive and in-depth overview of γδ T cells, covering their origins, development, classification, and functional roles in immunology. Special attention is given to their involvement in the pathogenesis of autoimmune and cancer-related diseases-areas that remain subjects of intensive research with many unanswered questions. Additionally, this article explores the therapeutic potential of γδ T cells, which hold promise as a novel approach to treating various difficult-to-manage diseases. The review also presents an analysis of the latest clinical studies utilizing γδ T cells, emphasizing their emerging role in modern medicine. The ultimate goal of this work is to offer a holistic perspective on the current state of research on γδ T cells and their prospective applications in immunotherapy and cancer treatment, highlighting their potential to become a groundbreaking tool in future medical interventions.

Ligand recognition by the γδ TCR and discrimination between homeostasis and stress conditions

T lymphocytes comprise cells expressing either an αβ or a γδ TCR. The riddle how αβ TCRs are triggered by specific peptides presented in the context of MHC was elucidated some time ago. In contrast, the mechanisms that underlie antigen recognition by γδ TCRs are still baffling the scientific community. It is clear that activation of γδ TCRs does not necessarily depend on MHC antigen presentation. To date, diverse and largely host-cell-derived molecules have been identified as cognate antigens for the γδ TCR. However, for most γδ TCRs, the activating ligand is still unknown and many open questions with regard to physiological relevance and generalizable concepts remain. Especially the question of how γδ T cells can distinguish homeostatic from stress conditions via their TCR remains largely unresolved. Recent discoveries in the field might have paved the way towards a better understanding of antigen recognition by the γδ TCR and have made it conceivable to revise the current knowledge and contextualize the new findings.

Resolving the mystery-How TCR transgenic mouse models shed light on the elusive case of gamma delta T cells

Cutting-edge questions in αβ T cell biology were addressed by investigating a range of different genetically modified mouse models. In comparison, the γδ T cell field lacks behind on the availability of such models. Nevertheless, transgenic mouse models proved useful for the investigation of γδ T cell biology and their stepwise development in the thymus. In general, animal models and especially mouse models give access to a wide range of opportunities of modulating γδ T cells, which is unachievable in human beings. Because of their complex biology and specific tissue tropism, it is especially challenging to investigate γδ T cells in in vitro experiments since they might not reliably reflect their behavior and phenotype under physiologic conditions. This review aims to provide a comprehensive historical overview about how different transgenic mouse models contributed in regards of the understanding of γδ T cell biology, whereby a special focus is set on studies including the elusive role of the γδTCR. Furthermore, evolutionary and translational remarks are discussed under the aspect of future implications for the field. The ultimate full understanding of γδ T cells will pave the way for their usage as a powerful new tool in immunotherapy.

Role of a selecting ligand in shaping the murine γδ-TCR repertoire

Unlike αβ-T lineage cells, where the role of ligand in intrathymic selection is well established, the role of ligand in the development of γδ-T cells remains controversial. Here we provide evidence for the role of a bona fide selecting ligand in shaping the γδ-T cell-receptor (TCR) repertoire. Reactivity of the γδ-TCR with the major histocompatibility complex (MHC) Class Ib ligands, H2-T10/22, is critically dependent upon the EGYEL motif in the complementarity determining region 3 (CDR3) of TCRδ. In the absence of H2-T10/22 ligand, the commitment of H2-T10/22 reactive γδ-T cells to the γδ fate is diminished, and the specification of those γδ committed cells to the IFN-γ or interleukin-17 effector fate is altered. Furthermore, those cells that do adopt the γδ fate and mature exhibit a profound alteration in the γδTCR repertoire, including depletion of the EGYEL motif and reductions in both CDR3δ length and charge. Taken together, these data suggest that ligand plays an important role in shaping the TCR repertoire of γδ-T cells.

γδ T cells: first line of defense and beyond

γδ T cells, αβ T cells, and B cells are present together in all but the most primitive vertebrates, suggesting that each population contributes to host immune competence uniquely and that all three are necessary for maintaining immune competence. Functional and molecular analyses indicate that in infections, γδ T cells respond earlier than αβ T cells do and that they emerge late after pathogen numbers start to decline. Thus, these cells may be involved in both establishing and regulating the inflammatory response. Moreover, γδ T cells and αβ T cells are clearly distinct in their antigen recognition and activation requirements as well as in the development of their antigen-specific repertoire and effector function. These aspects allow γδ T cells to occupy unique temporal and functional niches in host immune defense. We review these and other advances in γδ T cell biology in the context of their being the major initial IL-17 producers in acute infection.

Role of Hedgehog signalling at the transition from double-positive to single-positive thymocyte

In the thymus, developing T cells receive signals that determine lineage choice, specificity, MHC restriction and tolerance to self-antigen. One way in which thymocytes receive instruction is by secretion of Sonic hedgehog (Shh) from thymic epithelial cells. We have previously shown that Hedgehog (Hh) signalling in the thymus decreases the CD4:CD8 single-positive (SP) thymocyte ratio. Here, we present data indicating that double-positive (DP) thymocytes are Hh-responsive and that thymocyte-intrinsic Hh signalling plays a role in modulating the production of CD4(+) (SP4), CD8(+) (SP8) and unconventional T-cell subsets. Repression of physiological Hh signalling in thymocytes altered the proportions of DP and SP4 cells. Thymocyte-intrinsic Hh-dependent transcription also attenuated both the production of mature SP4 and SP8 cells, and the establishment of peripheral T-cell compartments in TCR-transgenic mice. Additionally, stimulation or withdrawal of Hh signals in the WT foetal thymus impaired or enhanced upregulation of the CD4 lineage-specific transcription factor Gata3 respectively. These data together suggest that Hh signalling may play a role in influencing the later stages of thymocyte development.

Towards a molecular understanding of the differential signals regulating alphabeta/gammadelta T lineage choice

While insights into the molecular processes that specify adoption of the alphabeta and gammadelta fates are beginning to emerge, the basis for control of specification remains highly controversial. This review highlights the current models attempting to explain T lineage commitment. Recent observations support the hypothesis that the T cell receptor (TCR) provides instructive cues through differences in TCR signaling intensity and/or longevity. Accordingly, we review evidence addressing the importance of differences in signal strength/longevity, how signals differing in intensity/longevity may be generated, and finally how such signals modulate the activity of downstream effectors to promote the opposing developmental fates.

gammadelta and alphabeta T cell lineage choice: resolution by a stronger sense of being

A common bipotent thymocyte precursor gives rise to both lineages of T cells, alphabeta and gammadelta. However, the cell intrinsic and extrinsic factors that influence alphabeta- versus gammadelta-lineage bifurcation remain controversial. gammadelta T cells play a unique and vital role in host defense, from maintaining integrity at epithelial and mucosal barriers to their newly defined role as an important innate source of interleukin-17. Although a T cell receptor (TCR)-independent fate choice may take place, emerging data supports a model in which the differential signaling capacity of alphabeta and gammadeltaTCRs play an instructional role in specifying lineage fate, with strength of signal measured by the amount of ERK/MAPK pathway activation. Here we discuss how the interplay between intrinsic TCR signals and cell extrinsic signals provided by Notch and TCR ligands help to assign and support a final lineage fate decision.

Ligand recognition during thymic development and gammadelta T cell function specification

gammadelta T cells develop in the thymus before entering the periphery. Recent work suggests that thymic development does little to constrain gammadelta T cell antigen specificities, but instead determines their effector fate. When triggered through the T cell receptor, ligand-naïve gammadelta T cells produce IL-17, ligand-experienced cells make IFN-gamma and those that are strongly self-reactive make IL-4. Importantly, gammadelta T cells are able to make cytokines immediately upon TCR engagement. These characteristics allow gammadelta T cells to initiate an acute inflammatory response to pathogens and to host antigens revealed by injury. These advances warrant a fresh look at how gammadelta T cells may function in the immune system.

Thymic maturation determines gammadelta T cell function, but not their antigen specificities

gammadelta T cells contribute uniquely to host immune defense, but how they do so remains unclear. Recent work suggests that thymic selection does little to constrain gammadelta T cell antigen specificities, but instead determines their effector fate. When triggered through the T cell receptor, ligand-experienced cells make IFNgamma, whereas ligand-naïve gammadelta T cells produce IL-17, a major initiator of inflammation. These advances warrant a fresh look at how gammadelta T cells may function in the immune system.

Thymic selection determines gammadelta T cell effector fate: antigen-naive cells make interleukin-17 and antigen-experienced cells make interferon gamma

gammadelta T cells uniquely contribute to host immune defense, but how this is accomplished remains unclear. Here, we analyzed the nonclassical major histocompatibility complex class I T10 and T22-specific gammadelta T cells in mice and found that encountering antigen in the thymus was neither required nor inhibitory for their development. But when triggered through the T cell receptor, ligand-naive lymphoid-gammadelta T cells produced IL-17, whereas ligand-experienced cells made IFN-gamma. Immediately after immunization, a large fraction of IL-17(+) gammadelta T cells were found in the draining lymph nodes days before the appearance of antigen-specific IL-17(+) *beta T cells. Thus, thymic selection determines the effector fate of gammadelta T cells rather than constrains their antigen specificities. The swift IL-17 response mounted by antigen-naive gammadelta T cells suggests a critical role for these cells at the onset of an acute inflammatory response to novel antigens.

gammadelta T-cell receptors: functional correlations

The gammadelta T-cell receptors (TCRs) are limited in their diversity, suggesting that their natural ligands may be few in number. Ligands for gammadeltaTCRs that have thus far been determined are predominantly of host rather than foreign origin. Correlations have been noted between the Vgamma and/or Vdelta genes a gammadelta T cell expresses and its functional role. The reason for these correlations is not yet known, but several different mechanisms are conceivable. One possibility is that interactions between particular TCR-V domains and ligands determine function or functional development. However, a recent study showed that at least for one ligand, receptor specificity is determined by the complementarity-determining region 3 (CDR3) component of the TCR-delta chain, regardless of the Vgamma and/or Vdelta. To determine what is required in the TCR for other specificities and to test whether recognition of certain ligands is connected to cell function, more gammadeltaTCR ligands must be defined. The use of recombinant soluble versions of gammadeltaTCRs appears to be a promising approach to finding new ligands, and recent results using this method are reviewed.

Recent insights into the signals that control alphabeta/gammadelta-lineage fate

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: alphabeta T cells and gammadelta T cells. Although there is no consensus as to the exact developmental stage where alphabeta and gammadelta T-cell lineages diverge, gammadelta T cells and precursors to the alphabeta 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 alphabeta/gammadelta 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 gammadelta development and weaker signals promote adoption of the alphabeta 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.

Attenuation of gammadeltaTCR signaling efficiently diverts thymocytes to the alphabeta lineage

The role of the T cell antigen receptor complex (TCR) in alphabeta/gammadelta lineage commitment remains controversial, in particular whether different TCR isoforms intrinsically favor adoption of a certain lineage. Here, we demonstrate that impairing the signaling capacity of a gammadeltaTCR complex enables it to efficiently direct thymocytes to the alphabeta lineage. In the presence of a ligand, a transgenic gammadeltaTCR mediates almost exclusive adoption of the gammadelta lineage, while in the absence of ligand, the same gammadeltaTCR promotes alphabeta lineage development with efficiency comparable to the pre-TCR. Importantly, attenuating gammadeltaTCR signaling through Lck deficiency causes reduced ERK1/2 activation and Egr expression and diverts thymocytes to the alphabeta lineage even in the presence of ligand. Conversely, ectopic Egr overexpression favors gammadelta T cell development. Our data support a model whereby gammadelta versus alphabeta lineage commitment is controlled by TCR signal strength, which depends critically on the ERK MAPK-Egr pathway.

Positive selection of dendritic epidermal gammadelta T cell precursors in the fetal thymus determines expression of skin-homing receptors

The role of cellular selection in the development of gammadelta T cells remains unclear. Knockout mice lacking a subset of Vgamma genes, including Vgamma3, contain abundant gammadelta T cells but are devoid of dendritic epidermal gammadeltaT cells (DETCs), which normally express an invariant Vgamma3/Vdelta1 gammadelta TCR. A rearranged Vgamma2 transgene restored DETC development, but the restored DETCs selectively expressed a unique Vdelta gene other than Vdelta1, indicating that DETC development involves TCR-based selection. In both normal and transgenic/knockout mice, specific DETC precursors in the fetal thymus were activated and expressed the IL-15 receptor beta chain, skin-homing receptors, and thymic exiting receptors. In vitro activation of irrelevant precursors also led to upregulation of the skin-homing receptor, providing an explanation for how thymic selection is coordinated with development of epidermal gammadelta T cells.

Allelic exclusion at the TCR delta locus and commitment to gamma delta lineage: different modalities apply to distinct human gamma delta subsets

Expression of a beta-chain, as a pre-TCR, in T cell precursors prevents further rearrangements on the alternate beta allele through a strict allelic exclusion process and enables precursors to undergo differentiation. However, whether allelic exclusion applies to the TCR delta locus is unknown and the role of the gamma delta TCR in gamma delta lineage commitment is still unclear. Through the analysis of the rearrangement status of the TCR gamma, delta, and beta loci in human gamma delta T cell clones, expressing either the TCR V delta 1 or V delta 2 variable regions, we show that the rate of partial rearrangements at the delta locus is consistent with an allelic exclusion process. The overrepresentation of clones with two functional TCR gamma chains indicates that a gamma delta TCR selection process is required for the commitment of T cell precursors to the gamma delta lineage. Finally, while complete TCR beta rearrangements were observed in several V delta 2 T cell clones, these were seldom found in V delta 1 cells. This suggests a competitive alpha beta/gamma delta lineage commitment in the former subset and a precommitment to the gamma delta lineage in the latter. We propose that these distinct behaviors are related to the developmental stage at which rearrangements occur, as suggested by the patterns of accessibility to recombination sites that characterize the V delta 1 and V delta 2 subsets.

T cell receptor-gamma allele-specific selection of V gamma 1/V delta 4 cells in the intestinal epithelium

Previous genetic analyses have shown that the relative representation of subsets of gammadelta intestinal intraepithelial lymphocytes (i-IELs) is influenced by genes linked to the TCRgamma, TCRdelta, and MHC loci. Here, we have analyzed V-gene use in gammadelta i-IELs from C57BL/6 (B6) and C57BL/10 (B10) mice and from their F(1) and F(2) progenies with a larger panel of Vgamma- and Vdelta-specific mAbs and have shown that the influence of TCRgamma-linked genes operates at two levels: one influencing the representation of Vgamma1 (or Vgamma7) i-IELs and other acting specifically on the Vgamma1/Vdelta4 i-IEL subset, which represents 3% and 15% of the gammadelta i-IELs in B6 and B10 mice, respectively. Analysis of mice transgenic for a rearranged Vgamma1Jgamma4Cgamma4 chain of B6 origin demonstrated that the TCRgamma-linked genes influencing the representation of the Vgamma1/Vdelta4 i-IEL subset are the structural genes of TCRgamma chains. This influence is allele specific and cell autonomous, as evidenced by the different behavior of Vgamma1/Vdelta4 cells bearing either parental allele in F(1) mice. The representation of Vgamma1/Vdelta4 cells among gammadelta thymocytes is similar in B6 and B10 mice, demonstrating that the Vdelta4 chain can pair well with both alleles of the Vgamma1Jgamma4Cgamma4 chain and strongly suggesting that a cellular selection mechanism is responsible for the observed differences. The Vgamma1-Jgamma4 junctional amino acid sequences of B6 Vgamma1/Vdelta4 i-IELs are diverse but display less variation in length than those found in similar cells from B10 mice, indicating that B6 Vgamma1/Vdelta4 cells are the target of this cellular selection event.

Deficiency in beta(2)-microglobulin, but not CD1, accelerates spontaneous lupus skin disease while inhibiting nephritis in MRL-Fas(lpr) nice: an example of disease regulation at the organ level

When mutations that inactivate molecules that function in the immune system have been crossed to murine lupus strains, the result has generally been a uniform up-regulation or down-regulation of autoimmune disease in the end organs. In the current work we report an interesting dissociation of target organ disease in beta(2)-microglobulin (beta(2)m)-deficient MRL-Fas(lpr) (MRL/lpr) mice: lupus skin lesions are accelerated, whereas nephritis is ameliorated. beta(2)m deficiency affects the expression of classical and nonclassical MHC molecules and thus prevents the normal development of CD8- as well as CD1-dependent NK1(+) T cells. To further define the mechanism by which beta(2)m deficiency accelerates skin disease, we studied CD1-deficient MRL/lpr mice. These mice do not have accelerated skin disease, excluding a CD1 or NK1(+) T cell-dependent mechanism of beta(2)m deficiency. The data indicate that the regulation of systemic disease is not solely governed by regulation of initial activation of autoreactive lymphocytes in secondary lymphoid tissue, as this is equally relevant to renal and skin diseases. Rather, regulation of autoimmunity can also occur at the target organ level, explaining the divergence of disease in skin and kidney in beta(2)m-deficient mice.

Thymus-dependent modulation of Ly49 inhibitory receptor expression on NK1.1+gamma/delta T cells

Major histocompatibility complex (MHC) class I-specific inhibitory receptors are expressed not only on natural killer (NK) cells but also on some subsets of T cells. We here show Ly49 expression on gamma/delta T cells in the thymus and liver of beta2-microglobulin-deficient (beta2m-/-) and C57BL/6 (beta2m+/+) mice. Ly49C/I or Ly49A receptor was expressed on NK1.1+gamma/delta T cells but not on NK1.1-gamma/delta T cells. The numbers of NK1.1+gamma/delta T cells were significantly smaller in beta2m+/+ mice than in beta2m-/- mice with the same H-2b genetic background. Among NK1.1+gamma/delta T cells, the proportions of Ly49C/I+ cells but not of Ly49A+ cells, were decreased in beta2m+/+ mice, suggesting that cognate interaction between Ly49C/I and H-2Kb is involved in the reduction of the number of Ly49C/I+ gamma/delta T cells in beta2m+/+ mice. The frequency of Ly49C/I+ cells in NK1.1+gamma/delta T cells was lower in both lethally irradiated beta2m+/+ mice transplanted with bone marrow (BM) from beta2m-/- mice and lethally irradiated beta2m-/- mice transplanted with BM from beta2m+/+ mice than those in adult thymectomized BM-transplanted chimera mice. These results suggest that reduction of Ly49C/I+ NK1.1+gamma/delta T cells in beta2m+/+ mice is at least partly due to the down-modulation by MHC class I molecules on BM-derived haematopoietic cells or radioresistant cells in the thymus.

[gamma][delta] cells: a right time and a right place for a conserved third way of protection

The tripartite subdivision of lymphocytes into B cells, alphabeta T cells, and gammadelta cells has been conserved seemingly since the emergence of jawed vertebrates, more than 450 million years ago. Yet, while we understand much about B cells and alphabeta T cells, we lack a compelling explanation for the evolutionary conservation of gammadelta cells. Such an explanation may soon be forthcoming as advances in unraveling the biochemistry of gammadelta cell interactions are reconciled with the abnormal phenotypes of gammadelta-deficient mice and with the striking differences in gammadelta cell activities in different strains and species. In this review, the properties of gammadelta cells form a basis for understanding gammadelta cell interactions with antigens and other cells that in turn form a basis for understanding immunoprotective and regulatory functions of gammadelta cells in vivo. We conclude by considering which gammadelta cell functions may be most critical.

Antigen-driven clonal accumulation of peritoneal gammadelta T cells in vivo

How the clonality of gammadelta T cells changes in response to exogenous antigens is uncertain. Here we analyzed kinetics of Vgamma1.1 and Vgamma2 T cell clonality after intraperitoneal injection of purified protein derivatives (PPD) by the heterogeneity of the third complementarity determining region (CDR3) length in Vgamma1.1-Jgamma4-Cgamma4 and Vgamma2-Jgamma1-Cgamma1 junctions. The V-J junctions were analyzed in intrahepatic lymphocytes (IHL), spleen cells, and peritoneal exudate cells (PEC) by polyacrylamide gel electrophoresis. Gammadelta T cells expressing Vgamma1.1 and Vgamma2 genes were heterogeneous in normal mice. Accumulation of specific Vgamma1.1 T cell clones was transiently detected 7 days after the injection in PEC, but no accumulation was observed in IHL and spleen cells. The accumulated clones disappeared by 4 weeks. Transient accumulation of Vgamma2 T cell clones was also observed in PEC at the early phase after the injection. These results suggest that gammadelta T cells with specific TCR respond to PPD and temporary accumulate in the peritoneal cavity, but not in liver and spleen.

Activation and peripheral expansion of murine T-cell receptor gamma delta intraepithelial lymphocytes

BACKGROUND & AIMS

The intestinal epithelial compartment is populated by CD8(+) alpha beta and gamma delta intraepithelial lymphocytes (IELs), which monitor the integrity of the epithelial barrier. alpha beta IELs are activated by peptide antigens presented by class I major histocompatibility complex (MHC) molecules, but it is unclear how gamma delta IELs are activated.

METHODS

G8 T-cell receptor (TCR) gamma delta transgenic (Tg) mice (specific for the class I MHC alloantigen, T22/10(b)) were crossed to class I MHC-deficient beta2-microglobulin-knockout (beta2m degrees) mice, and Tg+ IELs were examined for relative yields and surface and functional phenotype.

RESULTS

Evidence for class I MHC-induced activation of Tg+ IELs was supported by the detection of 4-fold greater numbers of Tg+ IELs in G8 x beta2m+ mice that proliferated at 15-fold higher levels than IELs from G8 x beta2m degrees mice. However, expression of CD69, production of cytokine (interleukin 2 and interferon gamma), and detection of cytolytic function for IELs in G8 x beta2m degrees mice suggested that class I MHC was not required for gamma delta IEL development or maturation.

CONCLUSIONS

These results suggest that CD8(+) TCR gamma delta IELs do not require class I MHC for development but support the notion that antigens presented by class I MHC molecules are involved in the peripheral expansion and differentiation of this subset.

T-cell fate

Recent studies suggest that lineage commitment steps, which occur during T-cell differentiation, follow principles in common with fate specification in simple invertebrates. Here we review T-cell development from the perspective of developmental biology. We present models for alpha beta vs gamma delta and CD4 vs CD8 lineage commitment that are consistent with previously published and newly presented experiments.

Lifespan of gamma/delta T cells

Information on the turnover and lifespan of murine gamma/delta cells was obtained by administering the DNA precursor, bromodeoxyuridine (BrdU), in the drinking water and staining lymphoid cells for BrdU incorporation. For TCR-gamma/delta (Vgamma2) transgenic mice, nearly all gamma/delta thymocytes became BrdU+ within 2 d and were released rapidly into the peripheral lymphoid tissues. These recent thymic emigrants (RTEs) underwent phenotypic maturation in the periphery for several days, but most of these cells died within 4 wk. In adult thymectomized (ATx) transgenic mice, only a small proportion of gamma/delta cells survived as long-lived cells; most of these cells had a slow turnover and retained a naive phenotype. As in transgenic mice, the majority of RTEs generated in normal mice (C57BL/6) appeared to have a restricted lifespan as naive cells. However, in marked contrast to TCR transgenic mice, most of the gamma/delta cells surviving in ATx normal mice had a rapid turnover and displayed an activated/memory phenotype, implying a chronic response to environmental antigens. Hence, in normal mice many gamma/delta RTEs did not die but switched to memory cells.

Gamma delta cells regulate autoimmunity

Gamma delta cells are attractive candidates for mediators of autoimmune disease. They can expand in germ-free mice, probably through recognition of autoantigens, and gamma delta-cell-deficient mice, unlike mice deficient in alpha beta T cells or B cells, show no severe defects in the immune response to foreign antigen challenge. A capacity of gamma delta cells to effect or regulate tissue damage is also plausible, given their ready localization to tissues, and their myriad of effector functions. Added to this, attempts to reconstruct the physiological course of autoimmune diseases with only autoreactive alpha beta T cells seem invariably to fall short for lack of other unidentified players. Gamma delta cells and their putative ligands have been linked to autoimmune conditions, and recent experiments confirm that gamma delta cells play a significant role in autoimmune disease in vivo.

Virus-specific, CD8+ major histocompatibility complex class I-restricted cytotoxic T lymphocytes in lymphocytic choriomeningitis virus-infected beta2-microglobulin-deficient mice

Following infection with lymphocytic choriomeningitis virus (LCMV), normal adult mice generate virus-specific, major histocompatibility complex (MHC) class I-restricted cytotoxic T lymphocytes (CTL) which clear the virus after intraperitoneal infection or cause death following intracranial (i.c.) infection. We have investigated the response of beta2-microglobulin-deficient (beta2m-) mice of the H-2d haplotype (KOD mice) to LCMV infection. Unlike H-2b beta2m- mice, which generate CD4+ MHC class II-restricted CTL in response to LCMV, KOD mice generate high levels of CD8+ MHC class I-restricted, virus-specific CTL. These CTL are specific for the LCMV nucleoprotein epitope (residues 118 to 126) in association with the Ld class I molecule, analogous to the CTL response in wild-type mice. KOD mice are also susceptible to lethal LCM disease, with 75 to 80% of the mice dying 7 to 9 days following i.c. infection with virus. Similar to results with normal mice, lethal LCM disease in KOD mice is prevented by in vivo depletion of CD8+ T cells prior to i.c. infection. In contrast to wild-type mice, however, KOD mice cannot control LCMV and become persistently infected. Overall, these results demonstrate that beta2m is not an absolute requirement for presentation of endogenous antigen on Ld or for induction of virus-specific Ld-restricted CTL in vivo.

Alpha beta lineage-committed thymocytes can be rescued by the gamma delta T cell receptor (TCR) in the absence of TCR beta chain

Commitment of the alpha beta and gamma delta T cell lineages within the thymus has been studied in T cell receptor (TCR)-transgenic and TCR mutant murine strains. TCR gamma delta-transgenic or TCR beta knockout mice, both of which are unable to generate TCR alpha beta-positive T cells, develop phenotypically alpha beta-like thymocytes in significant proportions. We provide evidence that in the absence of functional TCR beta protein, the gamma delta TCR can promote the development of alpha beta-like thymocytes, which, however, do not expand significantly and do not mature into gamma delta T cells. These results show that commitment to the alpha beta lineage can be determined independently of the isotype of the TCR, and suggest that alpha beta versus gamma delta T cell lineage commitment is principally regulated by mechanisms distinct from TCR-mediated selection. To accommodate our data and those reported previously on the effect of TCR gamma and delta gene rearrangements on alpha beta T cell development, we propose a model in which lineage commitment occurs independently of TCR gene rearrangement.

The T cell receptor repertoire of intestinal intraepithelial gammadelta T lymphocytes is influenced by genes linked to the major histocompatibility complex and to the T cell receptor loci

Most of the gammadelta T cells in the intestinal epithelium of normal mice use the Vgamma1 or the Vgamma7 gene segments. However, the relative proportions of gammadelta intraepithelial lymphocytes expressing either the Vgamma1 or the Vgamma7 chain vary among different strains of mice whereas they are quite constant between different individuals of the same strain, suggesting that genetic factors, rather than environmental factors, are responsible for the observed differences. To analyze the genetic factors influencing the representation of different gammadelta T cell subsets in the intestinal epithelium, we used available anti-T cell antigen receptor (TCR) V region-specific mAbs against Vgamma1, Vgamma4, Vgamma7, and Vdelta4 to examine the TCR repertoire of intraepithelial gammadelta lymphocytes in a set of (C57BL/6 x DBA/2) recombinant inbred strains. Our results show that the representation of different Vgamma and Vdelta gene products among gammadelta intestinal intraepithelial lymphocytes is under a complex genetic control with a marked influence by genes closely linked to the TCRgamma, TCRdelta, and major histocompatibility complex loci.

An increased gamma delta T cell population in the intestine of thymus-leukemia antigen transgenic mice

In an approach to study thymic leukemia antigen's (TL's) function, we have developed transgenic mice that express T18d on virtually all somatic cells; in such mice, we initially observed changes in T cells within the thymus and lymph nodes as well as the ability of TL to undergo recognition by splenic T cells. As phase II of our study, we now present the results on the composition of gut T cell populations which may be a better measure of TL's true function. We have demonstrated an increase in the number of gamma delta T cells as well as the increase in gamma delta T cells expressing the V gamma 2 chain. These cells appear to be both CD4 and CD8 negative. This suggests that TL may select for a subset of gamma delta T cells within the gut and bolsters earlier reports implicating an H-2T regional gene product as the major histocompatibility complex ligand for gamma delta T cells.

Fyn can partially substitute for Lck in T lymphocyte development

Lck, a Src family tyrosine kinase, transduces signals important for the development of alphabeta and gammadelta T cells. However, T cell development is only partially compromised in Lck-deficient mice, suggesting that other kinases may also transduce pre-TCR or TCR signals. One candidate is Fyn, a Src kinase coexpressed with Lck in immature and mature T cells. Here we show that T cell development is completely compromised in lck(-/-)fyn(-/-) mice. In addition, we demonstrate that expression of a gain-of-function mutant fyn(T) transgene completely restores production of immature CD4/CD8 double positive thymocytes and gammadelta T cells and improves the representation of CD4 or CD8 single positive thymocytes. These observations reveal that Fyn can subserve some Lck-like functions in T cell development.

Positive selection is not required for thymic maturation of transgenic gamma delta T cells

Previously published reports describing thymic differentiation in two TCR gamma delta transgenic mouse models have suggested that gamma delta T cells require MHC-mediated positive selection to reach full maturity. Recent studies indicate that recognition of antigen by mature gamma delta T cells is not MHC restricted, raising the issue of why developing gamma delta T cells would even require MHC-driven positive selection. Therefore, we have reinvestigated the requirements for development and selection in G8 gamma delta T cell receptor (TCR) transgenic mice. Analyses of absolute cell numbers, phenotypic subsets, and functional competence of thymic and peripheral G8 gamma delta T cells indicate that these cells can fully mature in class I MHC-deficient mice. Moreover, mixed bone marrow chimeras demonstrate that gamma delta T cells of mutant B2-microglobulin (beta 2m zero) origin are partially deleted in the presence of H-2d-bearing thymocytes (previously believed to be the haplotype mediating positive selection). We conclude that there is no requirement for class I-like molecules for the maturation/development of these transgenic gamma delta T cells and that the differences in thymocyte phenotype and number observed are, instead, attributable to effects of clonal deletion.

Selective development of T helper (Th)2 cells induced by continuous administration of low dose soluble proteins to normal and beta(2)-microglobulin-deficient BALB/c mice

Continuous administration of soluble proteins, delivered over a 10-d period by a mini-osmotic pump implanted subcutaneously, induces a long-lasting inhibition of antigen-specific T cell proliferation in lymph node cells from BALB/c mice subsequently primed with antigen in adjuvant. The decreased T cell proliferative response is associated with a down-regulation of the T helper cell (Th)1 cytokines interleukin (IL)-2 and interferon (IFN)-gamma and with a strong increase in the secretion of the Th2 cytokines IL-4 and IL-5 by antigen specific CD4+ T cells. This is accompanied by predominant inhibition of antigen-specific antibody production of IgG2a and IgG2b, rather than IgG1 isotype. Interestingly, inhibition of Th1 and priming of Th2 cells is also induced in beta(2) microglobulin-deficient BALB/c mice, indicating that neither CD8+ nor CD4+ NK1.1+ T cells, respectively, are required. The polarization in Th2 cells is stably maintained by T cell lines, all composed of CD4+/CD8- cells expressing T cell receptor for antigen (TCR) alpha/beta chains, derived from BALB/c mice treated with continuous antigen administration, indicating that they originate from Th2 cells fully differentiated in vivo. This polarization is induced in BALB/c mice by continuous administration of any protein antigen tested, including soluble extracts from pathogenic microorganisms. Priming of Th2 cells is dose dependent and it is optimal for low rather than high doses of protein. Blocking endogenous IL-4 in vivo inhibits expansion of antigen-specific Th2 cells, but does not restore IFN-gamma production by T cells from mice treated with soluble antigen-specific Th2 cells, but does not restore IFN-gamma production by T cells from mice treated with soluble antigen, indicating the involvement of two independent mechanisms. Consistent with this, Th2 cell development, but not inhibition of Th1 cells, depends on non-major histocompatibility complex genetic predisposition, since the Th2 response is amplified in BALB/c as compared to DBA/2, C3H, or C57BL/6 mice whereas tested. These findings support the hypothesis that continuous release of low amounts of protein antigens from pathogenic microorganisms may polarize the immune response toward a Th2 phenotype in susceptible mouse strains.

The enigmatic specificity of gamma delta T cells

In most scientific investigations, the study of mechanism follows the study of function. For example, alpha beta T cells were shown to be important mediators of immunity before the interaction between the T cell receptor (TCR) and peptide-MHC complexes was understood. However, sometimes the study of function follows from the study of mechanism. Research of gamma delta T cell receptors falls into this category. The gamma chain of the TCR was first cloned in 1984, which then led to the discovery of gamma delta T cells in 1985. Since then, research has focused on understanding ligands of the gamma delta TCR with the hope of better understanding the function of gamma delta T cells. An initial assumption was that gamma delta T cells, like alpha beta T cells, recognize peptides bound to MHC molecules; however, recent data indicate that gamma delta T cells are not biased towards MHC recognition in the same way as alpha beta T cells. Although there are intriguing new insights, the specificity and function of gamma delta T cells remains a mystery.

Expression of diverse and functional TCR gamma and Ig heavy chain transcripts in fetal liver cells cultured with interleukin-7

We have previously shown that specific T cell receptor (TCR) gamma V regions genes (V gamma 4 and V gamma 6) are rearranged and expressed by murine fetal liver (FL) cells cultured with IL-7. The present studies determined that the sequences of the TCR V region gene transcripts expressed in response to IL-7 included diverse and functional sequences expressed by thymocyte and peripheral V gamma 4+ and V gamma 6+ T cells, indicating that the IL-7-induced expression of these genes is functionally relevant and mimics normal in vivo developmental events of gamma delta T cells. We found that more than 50% of these TCR transcripts had N region diversity. The presence of N region diversity indicates that these TCR rearrangements took place in vitro, presumably in response to IL-7, because fresh (uncultured) FL cells do not produce detectable terminal deoxynucleotidyl transferase (TdT) mRNA or protein. We also found that 100% of immunoglobulin (Ig) VH7183-JH4 transcripts from FL cells cultured with IL-7 had N region diversity at the V-DJ region, while only 40% of Ig VH7183-JH4 transcripts from FL cells cultured in the absence of IL-7 had N region diversity at this region. FL cell cultures supplemented for 7 days with IL-7 had increased TdT mRNA and protein levels. However, since 1-day culture of FL cells with or without IL-7 resulted in induction of expression of TdT, IL-7 probably does not directly stimulate TdT expression, but increases the development and expansion of TdT+ lymphoid cells. These findings implicate IL-7 as a regulator of the molecular signals involved in controlling TCR gamma rearrangement and diversity, and provide an in vitro system for studying the regulation of TdT and N region diversity in B and T lymphoid progenitors by environmental signals.

Increased gamma-delta T-lymphocyte response to Mycobacterium bovis BCG in major histocompatibility complex class I-deficient mice

Mice with a homologous deletion of the beta 2-microglobulin gene (beta 2m-) are deficient in class I major histocompatibility complex molecules (MHC) and consequently are deficient in CD8+ T cells. These beta 2m- mutant mice control the intraperitoneal growth of an avirulent vaccine strain of mycobacteria, Mycobacterium bovis BCG, after intraperitoneal infection similarly to normal mice. We show that beta 2m- mice have an increased gamma-delta (gamma delta) T-cell response after infection with live avirulent mycobacteria. beta 2m- mice have an earlier and more sustained rise in the proportion of intraperitoneal gamma delta T cells, averaging 17% of T cells, compared with 6% in normal mice, at 28 days after infection. Compared with the population in normal mice, gamma delta T cells in the spleens of beta 2m- mice averaged a higher proportion of the total T-cell population of the spleen on days 5, 8, and 14 after intraperitoneal infection. These data document the kinetics of gamma delta T cells reactive to mycobacterial antigens in vivo without class I MHC restriction and support a role for class I MHC and CD8+ T cells in the in vivo regulation of gamma delta T cells.

TCR gamma delta cells: mysterious cells of the immune system

Gamma delta cells participate in pathogenic infections and autoimmune conditions, yet, almost a decade after their discovery, little is known regarding their TCR repertoire or effector functions. Unlike MHC-restricted antigen recognition employed by TCR alpha beta cells, TCR gamma delta cells can recognize whole unprocessed antigens in an MHC- independent manner. The nature of positive and negative selection used to shape the repertoire of TCR gamma delta cells is unclear, especially in the nonlymphoid tissues where these cells predominate. While TCR gamma delta cells express an activated phenotype and are present in pathological conditions, their roles in immunological protein is unknown. This review will focus on our efforts to study these issues of TCR gamma delta biology.

Activation and function of gamma delta T cells

T-cell receptor gene rearrangements in gamma delta T cells have been the subject of intense molecular investigations. This year, much has been learned about the mechanisms controlling this process. However, the specificity and function of gamma delta T cells still remains enigmatic. The application of molecular technology including the availability of mutant mice lacking defined T-cell populations and immunologically relevant surface proteins is beginning to provide answers as well as some surprises.

Development of murine pre-T cells into gamma delta T-cell receptor bearing cells

Murine T cells bearing the gamma delta T-cell receptor (gamma delta TCR) are the major lymphocyte subset in the thymus early in fetal development, and postnatally they are the major population of T cells in the epithelia of nonlymphoid tissues including the intestine, skin, tongue, lung, and reproductive organs. The site of origin of gamma delta T-cell precursors (pre-T cells) changes during fetal development, reflecting the sites of active hematopoiesis. In addition, the pattern of expression of specific gamma delta TCR variable (V) region genes changes during fetal and neonatal development, and is unique in different epithelial tissues postnatally. We herein review the literature describing these developmental changes and provide a model for the developmental pathways of murine gamma delta T cells.

Antigens recognized by gamma delta T cells

Recent evidence demonstrates the important role played by gamma delta T cells in resistance to infections. Despite this, in most cases the antigens recognized by the responding gamma delta T cells are unknown. Antigen recognition by some gamma delta T-cell populations may not require the participation of either MHC class I or class II molecules. In other cases, evidence exists for the participation of MHC-encoded molecules, particularly non-classical class I molecules.

Intrathymic differentiation of V gamma 3 T cells

Whereas there is considerable information on the phenotypic and functional maturation of T cell receptor (TCR) alpha/beta thymocytes, comparatively little is known of the maturational processes that affect development of TCR-gamma/delta thymocytes. One class of gamma/delta T cells, those bearing the V gamma 3 gene product, are generated only during the early fetal stages of thymic development, and then migrate to the skin. Here we examine the intrathymic differentiation of these V gamma 3+ cells. The earliest V gamma 3 cells to appear in the thymus expressed low levels of TCR (V gamma 3low) and high levels of heat stable antigen (HSA). Over the next few days, V gamma 3+ thymocytes appeared which expressed high levels of TCR (V gamma 3high) and very low levels of HSA. The antigens CD5, CD45RB, and MEL14 were also differentially expressed on V gamma 3low versus V gamma 3high thymocytes, but the shift in expression was the opposite as compared with immature and mature TCR-alpha/beta thymocytes. Transfer experiments of sorted V gamma 3low/HSAhigh thymocytes to SCID thymic lobes showed that these cells were indeed the precursors of V gamma 3high/HSAlow thymocytes. The phenotype of the V gamma 3high thymocytes was similar to that of the postthymic V gamma 3+ cells found in the skin of adult mice. The differentiation of V gamma 3low in V gamma 3high thymocytes was also observed in fetal thymic organ culture. Addition of cyclosporin A (CsA) to these cultures had little effect on the appearance of V gamma 3low/HSAhigh cells, but blocked the appearance of V gamma 3high/HSAlow cells. These results show that, like alpha/beta T cells, V gamma 3+ thymocytes differentiate from TCRlow precursors to cells with a mature phenotype and that CsA inhibits this transition.

Analysis of intraepithelial lymphocytes from major histocompatibility complex (MHC)-deficient mice: no evidence for a role of MHC class II antigens in the positive selection of V delta 4+ gamma delta T cells

Three-color flow cytometric analysis was carried out with intraepithelial lymphocytes from mice deficient in expression of major histocompatibility complex (MHC) antigens. These experiments were done to address the possible role of MHC class II molecules in the positive selection of V delta 4+ gamma delta T cells. By analyzing mice deficient MHC class II antigens alone or in combination with MHC class I antigens, no evidence was found for positive selection of V delta 4+ cells among CD8 alpha + or CD4-CD8- subpopulations of gamma delta T cell receptor-positive cells. Because V delta 4+, CD8 alpha + cells were reported to be positively selected on I-Ek and hybrid I-Ek/b molecules, class II-deficient animals were crossed with I-Ek transgenic mice and progeny examined for V delta 4 expression. Again, no evidence for positive selection was found. Interestingly, in MHC class I-deficient animals, the total number of gamma delta T cells was about twofold higher than in control and MHC class II-deficient mice and the proportion of V delta 4-expressing cells was correspondingly decreased. Taken together, these results cast doubt on a major role for conventional MHC antigens in shaping the gamma delta T cell repertoire of intraepithelial lymphocytes.

Requirement for tyrosine kinase p56lck for thymic development of transgenic gamma delta T cells

The Src-related protein tyrosine kinase p56lck is essential for antigen-specific signal transduction and thymic maturation of T cells that have an alpha beta T cell receptor (TCR), presumably by physical association with CD4 or CD8 molecules. To evaluate the requirement for p56lck in the development of T cells that have gamma delta TCRs, which generally do not express CD4 or CD8, p56lck mutant mice were bred with TCR gamma delta transgenic mice. Few peripheral cells that carried the transgenes could be detected in p56lck-/- mice, although 70 percent of thymocytes were transgenic. Development of transgenic gamma delta+ thymocytes was blocked at an early stage, defined by interleukin-2 receptor alpha expression. However, extrathymic development of CD8 alpha alpha+ TCR gamma delta+ intestinal intraepithelial lymphocytes appeared to be normal. Thus, p56lck is crucial for the thymic, but not intestinal, maturation of gamma delta T cells and may function in thymic development independently of CD4 or CD8.

Phenotypic and functional analysis of positive selection in the gamma/delta T cell lineage

Recent evidence suggests that T cells expressing gamma/delta antigen receptors (T cell receptor [TCR]) are subject to positive selection during development. We have shown that T cells expressing a class I major histocompatibility complex (MHC)-specific gamma/delta TCR transgene (tg) are not positively selected in class I MHC-deficient, beta 2-microglobulin (beta 2m) gene knockout mice (tg+ beta 2m-). In this report, we examine phenotypic and functional parameters of gamma/delta positive selection in this transgenic model system. TCR-gamma/delta tg+ thymocytes of mature surface phenotype (heat stable antigen-, CD5hi) were found in beta 2m+ but not in beta 2m- mice. Moreover, subsets of tg+ thymocytes with the phenotype of activated T cells (interleukin [IL]2R+, CD44hi, or Mel-14lo) were also present only in the beta 2m+ mice. Cyclosporine A, which blocks positive selection of TCR-alpha/beta T cells, also inhibited gamma/delta tg+ T cell development. These results support the idea that positive selection of TCR-gamma/delta requires active TCR-mediated signal transduction. Whereas tg+ beta 2m+ thymocytes produced IL-2 and proliferated when stimulated by alloantigen, TCR engagement of tg+ beta 2m- thymocytes by antigen induced IL-2R expression but was uncoupled from the signal transduction pathway leading to IL-2 production and autocrine proliferation. Overall, these results demonstrate significant parallels between gamma/delta and alpha/beta lineage development, and suggest a general role for TCR signaling in thymic maturation.

Gamma delta T-cell development

Gamma delta T cells consist of multiple lineages of cells with distinct antigen receptor repertoires, tissue localization and function. Recent evidence suggests that the ordered appearance of these sublineages during development is a result of programmed rearrangement of V gamma-gene segments. It appears that the T-cell receptor repertoire, at least of the gamma delta T cells with invariant receptors, is the result of site-directed rearrangement and cellular selection does not play a major role.

Ordered rearrangement of variable region genes of the T cell receptor gamma locus correlates with transcription of the unrearranged genes

T cell receptor V gamma genes rearrange to the J gamma 1 gene segment in a highly ordered fashion during development. We demonstrate a striking correlation between the pattern of expression of unrearranged V gamma genes and the timing of their rearrangement. Thus, the increases in V gamma 2 rearrangements, and decreases in V gamma 3 and V gamma 4 rearrangements observed during development are paralleled by increasing or decreasing levels of the corresponding unrearranged V gene transcript. We also provide evidence that both the V gamma 3 and V gamma 4 genes are accessible in mature V gamma 3+ cells, but that the V gamma 4 gene may be inaccessible in the progenitors of V gamma 3 cells. The results suggest that regulated local accessibility of the chromatin surrounding V gamma genes is responsible for ordered V gamma gene rearrangement during development.