Human γδ T Cells Express a Higher TCR/CD3 Complex Density Than αβ T Cells

The aim of our study was to compare CD3 expression on γδ T cells and αβ T cells in human patients. The antigen density of TCR and CD3 on both subsets was assessed by a quantitative method in eight patients. In parallel, we developed and validated a reliable direct tricolor staining protocol that we tested on samples from hospitalized and healthy individuals (n = 60). Our results demonstrate that human γδ T cells constitutively express approximately twofold more of the TCR/CD3 complex than αβ T cells. We suggest that this enhanced expression of the TCR/CD3 complex could contribute to the higher reactivity of γδ T cells compared to αβ T cells. These clinical laboratory results confirm the fundamental data described elsewhere. γδ T cells deserve further clinical investigations to understand their precise role in human immunity.     

Activation of uterine intraepithelial γδ T cell receptor-positive lymphocytes during pregnancy

Intraepithelial lymphocytes (IEL) of the uterus of non-pregnant sheep were analyzed by single- and two-color flow cytometry. Very few lymphocytes carrying classical B and T cell markers (CD5, surface immunoglobulin) were detected in the uterine epithelial cell suspensions and all IEL expressed the CD8 surface marker although with varying intensities. Three distinct subpopulations were identified including a major (46-56%) population of CD8⁺CD45R^?γδ T cell receptor (TcR)-negative cells and approximately equal numbers of CD8⁺CD45R+γδTcR^? and CD8⁺CD45R⁺γδTcR⁺ lymphocytes. The same three subpopulations were also present in the interplacentomal areas of the uterus of ewes at a late stage of pregnancy but there was a dramatic increase (60-70%) in the γδ TcR⁺ subpopulation. In addition, a pronounced increase in both size and granularity was observed in the IEL population of pregnant uteri and this was attributed to the γδ TcR⁺ cells. Light and electron microscopic examination of these γδ TcR⁺ IEL revealed an increase in metabolic activity and the formation of exceptionally large cytoplasmic granules and confirmed their restricted localization within the uterine epithelium close to the trophoblast. These results represent for the first time, a clear example of the activation of γδ TcR⁺ cells which is not associated with an ongoing disease process or infection, γδ TcR⁺ cells have recently been observed in the epithelium of the murine reproductive tract and were characterized by their unique homogeneous receptor structure. The present results indicate that these cells may play an important physiological role during pregnancy.     

Evidence that productive rearrangements of TCR γ genes influence the commitment of progenitor cells to differentiate into αβ or γδ T cells

Two models have been considered to account for the differentiation of γδ and αβ T cells from a common hematopoietic progenitor cell. In one model, progenitor cells commit to a lineage before T cell receptor (TCR) rearrangement occurs. In the other model, progenitor cells first undergo rearrangement of TCRγ, δ, or both genes, and cells that succeed in generating a functional receptor commit to the γδ lineage, while those that do not proceed to attempt complete β and subsequently α gene rearrangements. A prediction of the latter model is that TCRγ rearrangements present in αβ T cells will be nonproductive. We tested this hypothesis by examining Vγ2-Jγ1Cγ1 rearrangements, which are commonly found in αβ T cells. The results indicate that Vγ2-Jγ1Cγ1 rearrangements in purified αβ T cell populations are almost all nonproductive. The low frequency of productive rearrangements of Vγ2 in αβ T cells is apparently not due to a property of the rearrangement machinery, because a transgenic rearrangement substrate, in which the Vγ2 gene harbored a frame-shift mutation that prevents expression at the protein level, was often rearranged in a productive configuration in αβ T cells. The results suggest that progenitor cells which undergo productive rearrangement of their endogenous Vγ2 gene are selectively excluded from the αβ T cell lineage.     

Progenies of fetal thymocytes are the major source of CD4−CD8+ αα intestinal intraepithelial lymphocytes early in ontogeny

Present literature supports the view of an extrathymic origin for the subset of intestinal intraepithelial lymphocytes (IEL) that express the CD4^?CD8⁺ αα phenotype. This subset would include virtually all T cell receptor (TCR) γδ IEL and a portion of TCR αβ IEL. However, these reports do not exclude the possibility that some CD4^?CD8⁺ αα IEL are actually thymically derived. To clarify this issue, we examined the IEL day 3 neonatally thymectomized (NTX) mice. NTX resulted in as much as 80 % reduction in total TCR γδ IEL and in a nearly complete elimination of TCR αβ CD4^?CD8⁺ αα IEL early in ontogeny (3-to 5-week-old mice). The thymus dependency of TCR γδ IEL and TCR αβ CD4^?CD8⁺ IEL was less prominent in older mice (7- to 10-week-old mice), as the total number of these IEL increased in NTX mice, but still remained severalfold less than that in euthymic mice. Furthermore, we demonstrate, by grafting the fetal thymus of CBF1 (H-2^b/d) mice under the kidney capsule of congenitally nude athymic mice of BALB/c background (H-2^d), that a substantial number of TCR γδ IEL and TCR αβ CD4^?CD8⁺ αα IEL can be thymically derived (H-2^b+). In contrast, but consistent with our NTX data, grafting of adult thymi into nude mice generated virtually no TCR γδ IEL and relatively less TCR αβ CD4^?CD8⁺ αα IEL than did the grafting of fetal thymi. These results suggest that the thymus is the major source of TCR γδ and TCR αβ CD4^?CD8⁺ αα IEL early in ontogeny, but that the extrathymic pathway is probably the major source of these IEL later in ontogeny. A reassessment of the theory that most CD4^?CD8⁺ IEL are extrathymically derived is needed.     

Expansion of the CD4−, CD8− γδ T cell subset in the spleens of mice during non-lethal blood-stage malaria

Splenic γδ T cells (CD4^?, CD8^?) increased more that 10-fold upon resolution of either Plasmodium chabaudi adami or P. c. chabaudi infections in C57BL/6 mice compared to controls. Similarly, a 10- to 20-fold expansion of the γδ T cell population was observed in β₂-microglobulin deficient (β²-m^0.0) mice that had resolved P. c. adami, P. c. chabaudi or P. yoelii yoelii infections. In contrast, increases in the number of splenic αβ T cells in these infected mice were only two to three-fold indicating a differential expansion of the γδ T cell subset during malaria. Because nucleated cells of β₂-m^0/0 mice lack surface expression of major histocompatibility complex class I and class Ib glycoproteins, our findings suggest that antigen presentation by these glycoproteins is not necessary for the increasing number of γδ T cells. Our observation that after resolution of P. c. adami malaria, C57BL/6 mice depleted of CD8⁺ cells by monoclonal antibody treatment had lower numbers of γδ T. cells than untreated controls suggests that the demonstrated lack of CD8⁺ cells in β₂-m^0/0 mice does not contribute to the expansion of the γδ T cell population during non-lethal malaria.     

αβ Lineage-committed thymocytes can be rescued by the γδ T cell receptor (TCR) in the absence of TCR β chain

Commitment of the αβ and γδ T cell lineages within the thymus has been studied in T cell receptor (TCR)-transgenic and TCR mutant murine strains. TCRγδ-transgenic or TCRβ knockout mice, both of which are unable to generate TCRαβ-positive T cells, develop phenotypically αβ-like thymocytes in significant proportions. We provide evidence that in the absence of functional TCRβ protein, the γδTCR can promote the development of αβ-like thymocytes, which, however, do not expand significantly and do not mature into γδ T cells. These results show that commitment to the αβ lineage can be determined independently of the isotype of the TCR, and suggest that αβ versus γδ 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 TCRγ and δ gene rearrangements on αβ T cell development, we propose a model in which lineage commitment occurs independently of TCR gene rearrangement.     

Duodenal intraepithelial γ/δ T cells and soluble CD8, neopterin,and β2-microglobulin in serum of IgA-deficient subjects with or without IgG subclass deficiency

Expression of the γ/δ T cell receptor (TCR) on CD3⁺ intracpithclial lymphocytes (IELs) was studied by two-colour immunofluorescence in duodenal tissue sections from healthy (n= 6) or infection-prone (n = 7) subjects with selective IgA deficiency (IgAD), and subjects (n= 4) with combined IgAD and IgG subclass deficiency. TCRγ/δ⁺ IEL proportions in selective IgAD subjects (median 6.3%, range 1.0–41%) and in those with combined deficiency (median 4.5%, range 1±2.33%) were well within the range (0.3.38%) for histologically normal controls (n= 11), but the healthy IgAD subgroup tended to show raised TCRγ/δ⁺ IEL proportions (median 13.6%) compared with the other two subgroups. Also the number of TCRγ/δ⁺ IELs per intestinal length unit was relatively high (median 13.9/mm) in the healthy IgAD subjects, and significantly raised (P < 0.03) compared with controls (median 3.2/mm). Paired staining revealed that most TCRγ/δ⁺ IELs in both selective IgAD (98%) and combined deficiency (99%) were CD8, and a large fraction (median 84% and 63%, respectively) expressed the Vδ1/Jδ1-encoded epitope. The total number of CD3’ IELs (mostly CD8⁺) was similar to controls. IgAD subjects, and especially the healthy subgroup, had significantly increased serum concentrations of soluble CD8 (P < 0.0002), neopterin (P < 0.005), and β₂-microglobulin (P < 0.007). which was similar to our previous observations in common variable immunodeficiency, and probably reflected stimulation of cell-mediated immunity. In addition, the increased TCRγ/δ⁺ IELs might reflect a component of compensatory surface protection in the healthy IgAD subgroup.     

Expression of an avian CD6 candidate is restricted to αβ T cells,splenic CD8+ γδ T cells and embryonic natural killer cells

A candidate avian CD6 homolog is identified by the S3 monoclonal antibody. The S3 antigen exists in a phosphorylated glycoprotein form of 130 kDa and a nonphosphorylated form of 110 kDa. Removal of phosphate groups and N-linked carbohydrates indicates a 78-kDa protein core. During thymocyte differentiation, the γδ T cells do not express S3, whereas mature CD4⁺ and CD8⁺ cells of αβ lineage acquire S3 antigen. All αβ T cells in the blood and spleen express the S3 antigen at relatively high levels. In contrast, only the CD8⁺ sub-population of γδ T cells in the spleen expresses the antigen and neither αβ nor γδ T cells in the intestinal epithelium express the S3 antigen. The S3 antigen is also found on embryonic splenocytes with a phenotypic profile characteristic of avian natural killer cells. The biochemical characteristics and this cellular expression pattern imply that the S3 antigen is the chicken CD6 homolog.     

Mouse γδ TCR+NK1.1+ thymocytes specifically produce interleukin-4, are major histocompatibility complex class I independent,and are developmentally related to αβ TCR+NK1.1+ thymocytes

Mouse T cells co-expressing an αβ T cell receptor (TCR) and the NK1.1 antigen have been shown to be major interleukin (IL)-4-producing cells and could therefore regulate cell-mediated immune responses. We have identified a related subset of thymocytes co-expressing a γδ TCR and NK1.1 which also produce IL-4. Unlike αβ⁺NK1.1⁺ thymocytes, the selection of γδ⁺NK1.1⁺ thymocytes is not dependent upon β2-microglobulin (β2m)-associated class I molecule expression because these cells are present in β2m-deficient mice. This suggests that γδ⁺NK1.1⁺ T cells may regulate immune responses to a different variety of antigens. However, the development of αβ⁺NK1.1⁺ and αβ⁺NK1.1⁺ thymocytes appears to be related. Analysis of different mutant mice lacking αβ⁺NK1.1⁺ thymocytes revealed a specific increase in γδ⁺NK1.1⁺ thymocyte production when the block in αβ⁺NK1.1⁺ thymocyte differentiation occurs after β TCR rearrangement.     

CD45RA expression on γδ and αβ T cells emigrating from the fetal and postnatal thymus

We have compared the expression of CD45RA on αβ and γδ T cells emigrating from the fetal and postnatal thymus. The fetal and postnatal thymus export both CD45RA⁺ and CD45RA^- T cells. The number of γδ⁺CD45RA⁺ T cells was remarkably constant regardless of stage of ontogeny or T cell maturity. Around 5--8% of γδ thymic emigrants, thymocytes and peripheral blood lymphocytes expressed CD45RA in both fetal and postnatal animals. In contrast to γδ T cells, up to one quarter of both fetal and postnatal αβ emigrants expressed CD45RA. Post-thymic maturation of CD45RA expression on αβ emigrants, which occurred both before and after birth, appeared to be antigen independent.     

γδ T cells are secondary participants in acute graft-versus-host reactions initiated by CD4+ αβT cells

To examine the role of T cell subpopulations in an acute graft-versus-host (GVH) reaction, γδ T cells and αβ T cells expressing one of the two prototypic Vβ gene families were negatively isolated from adult blood samples and injected into allogeneic chick embryos. CD4⁺ αβ T cells expressing either Vβ1 or Vβ2 receptors were equally capable of inducing acute GVH reactions, consistent with the idea that αβ T cell alloreactivity is determined by CDR3 variability. By themselves, the γδ T cells were incapable of inducing GVH reactions. However, host γδ T cells were recruited into the donor αβ T cell-initiated lesions, where they were activated and induced to proliferate. The data suggest that γβ T cells may play a secondary role in GVH reactions.     

Helper activity of CD4+ αβ T cells is required for the avian γδ T cell response

We have studied the in vitro activation of chicken γδ T cells. Both splenic αβ and γδ T cells obtained from complete Freund's adjuvant-primed chickens proliferated in vitro when stimulated with mycobacterial sonicate or purified protein derivative of Mycobacterium tuberculosis. When CD4⁺ cells or αβ T cell receptor (TcR)-positive cells were removed, both the proliferation and the blast formation of γδ T cells in response to mycobacterial antigens were abrogated. The response was restored if supernatant from concanavalin A (Con A)-activated lymphocyte cultures (CAS) as a source of helper factors was added together with the specific antigen purified protein derivative. The CD4- or αβ TcR-depleted cells still proliferated in response to Con A, although a decrease of the response was observed. To analyze the γδ T cell response more specifically we stimulated peripheral blood cells with immobilized monoclonal antibodies against T cell receptor. Anti-γδ TcR antibody alone did not induce significant proliferation. When CAS was added together with the anti-γδ TcR monoclonal antibody, a strong proliferation of γδ T cells was observed. In contrast, both Vβ1- and Vβ2-expressing αβ T cells proliferated in vitro in response to stimulation with the relevant anti-TcR monoclonal antibody alone. Depletion of either Vβ1⁺ or Vβ2⁺ T cell subset alone had no negative effect on the proliferation or blast formation of γδ T cells stimulated with mycobacterial antigens. Taken together our results suggest that CD4⁺ αβ T cells (both Vβl- and Vβ2-expressing) play a role in the activation and response of chicken γδ T cells.     

TCR β PCR from crude preparations for restriction digest or sequencing

T cell specificity is determined by the combinatorial association of specific variable (V), diversity (D), and junctional (J) regions. Clones of T cells (clonality) can occur, in the blood or in tissue, after proliferation of activated T cells. Determining clonality in mutation assays is necessary to distinguish between mutants and mutational events. We have developed a novel approach to determine clonality among T cell isolates, using restriction digests of PCR-amplified cDNA of the T cell receptor β gene. The T cell receptor β gene was PCR-amplified by use of a consensus primer, beginning from a cell pellet of 2,000–5,000 cells or from extracted RNA. This TCR (T cell receptor) β chain PCR product can also be directly sequenced, allowing simple and easy identification of Vβ and CDR3 sequence from a small number of cells. The utility of this method is demonstrated by PCR, restriction digest, and sequencing of the TCR β cDNA from eight T cell clones isolated from 2 individuals. A clone of three identical isolates (one 3-mer) and a clone of two identical isolates (one 2-mer) were determined from restriction digests using two different enzymes. This new method is an easier and more rapid way of determining clonality than traditional methods, e.g., Southern blotting. © 1996 Wiley-Liss, Inc.     

Murine T Cell Determination of Pregnancy Outcome: I. Effects of Strain, αβ T Cell Receptor, γδ T Cell Receptor,and γδ T Cell Subsets

PROBLEM: T cells bearing αβ T cell receptor (TcR) and γδ TcR are present at the fetomaternal interface, and the latter, which express surface activation markers, can react with fetal trophoblast cell antigens. What is the role of these cells? METHOD: Using stress-abortion-prone DBA/2-mated CBA/J and abortion-resistant C57/B16 mice, αβ, γδ, and CD8^+/- T cell subsets were measured in spleen and uterine decidua. The effect of immunization against abortion and administration of anti-TcR antibody in vivo was examined. Cytokine synthesis was measured by intracellular staining of Brefeldin A-treated cells. RESULTS: Abortion-prone matings showed an unexpected accumulation of γδ T cells beginning in the peri-implantation period and this was suppressed by immunization against abortion. The immunization deleted γδ T cells producing the abortogenic cytokines, TNF-α and γ-interferon, and increased production of the anti-abortive cytokines, IL-10 and transforming growth factor-β2 (TGF-β2). Immunization also boosted the number of αβ T cells which were present in the decidua as early as 2 days after implantation. In vivo injection of GL4 (anti-δ) depleted γδ T cells producing Th1 cytokines in the peri-implantation period, and prevented abortions, whereas H57 (anti-β) decreased the number of αβ T cells and led to 100% abortions. CD8⁺ T cells present in peri-implant decidua before onset of abortions were mostly αβ TcR⁺, although some were γδ⁺. Changes in γδ and αβ T cells in pregnancy were most dramatic in uterine tissue. CONCLUSION: Although decidual γδ T cells after formation of a distinct placenta and fetus produce anti-abortive TGF-β2-like molecules and IL-10, prior events can lead to abortion. High local production of TNF-α and γ-interferon develop during the peri-implantation phase because of an excessive increase in the Th1 cytokine⁺ subset of γδ cells; these cytokines may be contributed by other tissues in decidua, and the contribution of bioactive factors by γδ T cells may augment the cytokine pool. In contrast, αβ T cells (which may be inactivated by stress that causes abortions) may mediate the anti-abortive effect of alloimmunization. Alloimmunization involves a shift from a Th1 to a Th2 pattern in the γδ T cells in decidua.     

A Subset of CD8 Memory T Cells from Old Mice Have High Levels of CD28 and Produce IFN-γ

Using carboxyfluorescein diacetate succinimidyl ester (CFSE)-tagged cells to measure proliferation in vivo, we found that only memory CD8⁺ cells from mice older than 18 months gave measurable levels of proliferation and that the proportion of memory CD8⁺ T cells able to proliferate in a nonirradiated recipient increased with age. CD8 cells that had proliferated in vivo contained higher levels of CD28 when compared to CD8 cells that had not divided. Cells with high levels of CD28 were preferentially able to divide in nonirradiated recipients. Using ex vivo intracellular staining analysis, we determined that most of the CD8⁺ T cells that were capable of dividing in vivo produced IFN-γ after isolation from recipient mice or their original host. These studies thus document the presence in aged mice of a population of CD28^hi CD8⁺ cells whose ability to proliferate in vivo without antigenic stimulation and to produce IFN-γ may be involved in immune regulation.     

CD4-negative cytotoxic T cells with a T cell receptor α/βintermediate expression in CD8-deficient mice

Targeted disruption of the CD8 gene results in a profound block in cytotoxic T cell (CTL) development. Since CTL are major histocompatibility complex (MHC) class I restricted, we addressed the question of whether CD8–/– mice can reject MHC class I-disparate allografts. Studies have previously shown that skin allografts are rejected exclusively by T cells. We therefore used the skin allograft model to answer our question and grafted CD8–/– mice with skins from allogeneic mice deficient in MHC class II or in MHC class I (MHC-I or MHC-II-disparate, respectively). CD8–/– mice rejected MHC-I-disparate skin rapidly even if they were depleted of CD4⁺ cells in vivo (and were thus deficient in CD4⁺ and CD8⁺ T cells). By contrast, CD8+/+ controls depleted of CD4⁺ and CD8⁺ T cells in vivo accepted the MHC-I-disparate skin. Following MHC-I, but not MHC-II stimulation, allograft-specific cytotoxic activity was detected in CD8–/– mice even after CD4 depletion. A population expanded in both the lymph nodes and the thymus of grafted CD8–/– animals which displayed a CD4^?8^?3^intermediateTCRα/β^intermediate phenotype. Indeed its T cell receptor (TCR) density was lower than that of CD4⁺ cells in CD8–/– mice or of CD8⁺ cells in CD8+/+ mice. Our data suggest that this CD4^?8^?T cell population is responsible for the CTL function we have observed. Therefore, MHC class I-restricted CTL can be generated in CD8–/– mice following priming with MHC class I antigens in vivo. The data also suggest that CD8 is needed to up-regulate TCR density during thymic maturation. Thus, although CD8 plays a major role in the generation of CTL, it is not absolutely required.     

Co-expression of CD8α in CD4+ T cell receptor αβ+ T cells migrating into the murine small intestine epithelial layer

We investigated the surface phenotype of CD3⁺CD4⁺ T cell receptor (TCR) αβ⁺ T cells repopulating the intestinal lymphoid tissues of C.B-17 scidlscid (severe-combined immunodeficient; scid) (H-2^d, L^d+) mice. CD4⁺ CD8^? T cells were cell sorter-purified from various secondary and tertiary lymphoid organs of congenic C.B-17 +/+ (H-2^d, L^d+) or semi-syngeneic dm2 (H-2^d, L^d?) immunocompetent donor mice. After transfer of 10⁵ cells into young scid mice, a mucosa-homing, memory CD44^hi CD45RB^lo CD4⁺ T cell population was selectively engrafted. Large numbers of single-positive (SP) CD3⁺ CD2⁺ CD28⁺ CD4⁺ CD^8? T cells that expressed the α₄ integrin chain CD49d were found in the spleen, the mesenteric lymph nodes, the peritoneal cavity and the gut lamina propria of transplanted scid mice. Unexpectedly, large populations of donor-type doublepositive (DP) CD4⁺ CD8α⁺ CD8β^? T cells with high expression of the CD3/TCR complex appeared in the epithelial layer of the small intestine of transplanted scid mice. In contrast to SP CD4⁺ T cells, the intraepithelial DP T cells showed low expression of the CD2 and the CD28 co-stimulator molecules, and of the α₄ integrin chain CD49d, but expressed high levels of the α_IEL integrin chain CD103. The TCR-Vβ repertoire of DP but not SP intraepithelial CD4⁺ T cells was biased towards usage of the Vβ6 and Vβ8 viable domains. Highly purified populations of SP and DP CD4⁺ T cell populations from the small intestine epithelial layer of transplanted scid mice had different abilities to repopulate secondary scid recipient mice: SP CD4⁺ T cells repopulated various lymphoid tissues of the immunodeficient host, while intraepithelial DP CD4⁺ T cells did not. Hence, a subset of CD3⁺ CD4⁺ TCRαβ⁺ T cells apparently undergoes striking phenotypic changes when it enters the microenvironment of the small intestine epithelial layer.     

The nature of the signals regulating CD8 T cell proliferative responses to CD8α+ or CD8α− dendritic cells

The CD8α^?-expressing dendritic cells (DC) of mouse spleen have been shown to be poor inducers of interleukin (IL)-2 production by CD8 T cells when compared to the CD8^? DC. As a consequence, CD8 T cells give a more prolonged proliferative response to CD8^? DC than to CD8⁺ DC. The possible mechanisms underlying these functional differences in DC subtype have been investigated. Inadequate co-stimulation did not underlie the poor T cell response to allogeneic CD8⁺ DC. Equivalent levels of B7-1 (CD80) and B7-2 (CD86) were found on the two DC subtypes and co-stimulator assays did not reveal any functional differences between them. Although CD8⁺ DC were found to die more rapidly in culture than CD8^? DC, this did not explain their reduced stimulatory ability. Neither prolonging DC survival in culture nor renewing the stimulator cells by repeated addition of freshly isolated DC had any significant effect on the T cell responses. Furthermore, later addition to the cultures of DC of the opposite type to the initiating DC did not reverse or eliminate the differential response to the initiating DC. The role of DC-derived soluble factors was examined by addition to the cultures of supernatants derived from freshly isolated or stimulated DC of the opposite type. This neither enhanced the poor stimulatory capacity of CD8⁺ DC nor inhibited the stimulation by CD8^? DC. Furthermore, addition of a series of cytokines that might have been produced by the DC did not eliminate the differences in T cell proliferation. Only the addition to the cultures of the growth factors IL-2 and IL-4 overcame the stimulatory difference between the two DC populations, confirming that the difference in T cell proliferative responses was a consequence of differences in induced cytokine production. The difference in the response of CD8 T cells to CD8⁺ and CD8^? DC is therefore determined by direct DC-T cell contact during the earliest stages of the culture and involves an undetermined and possibly new signaling system.