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

gammadeltaTCR ligands and lineage commitment

Two major T lymphocyte lineages--alphabeta and gammadelta T cells--develop in the thymus from common precursors. Differentiation of both lineages requires signals coming from TCRs. Development of alphabeta T cells is driven at early stages by signaling from the pre-TCR, most likely in a ligand-independent fashion, and later--by signals delivered by alphabetaTCRs binding to their ligands--classical or non-classical MHC molecules. gammadelta lineage cells likewise require TCR signaling for their differentiation. Recent work from several groups suggests that TCR signaling not only ensures the developmental progression towards alphabeta and gammadelta lineages but that signal strength instructs lineage fate: weaker TCR signal results in alphabeta and stronger--in gammadelta lineage commitment. However, as most gammadeltaTCRs remain orphan receptors, it is still debated whether strong signals from gammadeltaTCRs in development are generated in a ligand-dependent manner (as in the case of alphabetaTCRs), ligand-independent manner (as for pre-TCR) or both. Here we summarize evidence supporting a possible role for ligands in gammadelta T cell lineage commitment and the generation of gammadelta sublineages.

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.

In search of the origin of the thymus: the thymus and GALT may be evolutionarily related

The thymus is the major primary immune tissue for the production of functional T lymphocytes in vertebrates. However, its evolutionary origin is unknown. It has recently been shown that the generation of local T cells also occurs in gut-associated lymphoid tissues (GALT). This suggests that the thymus and GALT have similar functions and that they might be evolutionarily related. We discuss the possibility that the thymus may have evolved from mucosa-associated lymphoid tissues (MALT) located in the gill region in early vertebrates. Various facts supporting this proposal are summarized.

[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.

Speculation on the lineage relationships among CD4(-)8(+) gut-derived T cells and their role(s)

The thymus-independent T lymphopoietic capacity of the murine intestinal mucosa has been established. Cryptopatches have now been identified as the location of the elusive precursors for gut-derived T cells. These cryptopatch cells have been shown to give rise to intestinal T cells expressing either TCRgammadelta or TCRalphabeta. Here we discuss the role of MHC in the development and selection of gut-derived T cells. Through the analysis of iIEL selection in animals expressing a transgenic TCRalphabeta, in the presence or absence of p56(lck), we discuss lineage relationships among CD4(-)8(+) iIEL subsets, and their possible function(s).

IgA production in MHC class II-deficient mice is primarily a function of B-1a cells

Mice deficient in MHC class II expression (C2d mice) do not make antibody to protein antigens administered systemically, but their ability to produce IgA antibody to antigen administered at mucosal sites has not been described. We investigated IgA production by C2d mice and their IgA antibody response to antigen given orally. Young C2d mice had normal amounts of serum IgA, intestinal-secreted IgA and normal numbers of intestinal IgA plasma cells, compared to control C57BL/6 mice. IgA production by C2d mice increased with age. Following oral immunization with cholera toxin, C57BL/6 mice responded with IgA and IgG antibody, and had increased numbers of IgA plasma cells, but C2d mice gave no response. The Peyer's patch and mesenteric lymph node tissues of C2d mice contained very few CD4-expressing T cells. Thus, C2d mice have no typical mucosal CD4 Th cells and cannot respond to a strong oral immunogen, yet they still produced and secreted IgA. We hypothesized that B-1 lymphocytes could provide a source of IgA independent of antigen-specific T cell help. Young C2d mice had normal numbers of peritoneal B-1a cells and their frequency increased with age. To test the role of these B-1a cells, we bred C2d mice to obtain mice that had no MHC class II expression and expressed the Xid gene that confers deficiency in B-1a cells. These double-deficient mice had 10-fold less serum and secreted IgA than all other F2 littermates. We conclude that B-1a cells are essential for the majority of IgA production in C2d mice. Thus, the C2d mouse may provide a useful tool for analysis of the role of intestinal IgA provided by B-1a cells.

Immunological response of major histocompatibility complex class II-deficient (Abeta(o)) mice infected by the parasite Schistosoma mansoni

We have characterized the immunological behaviour of major histocompitibility complex (MHC) Class II molecule-deficient (Abeta(o)) mice after infection by Schistosoma mansoni. In Abeta(o) mice, morbidity developed dramatically 7 weeks after infection leading to death, despite the absence of an increase in parasite burden or of eggs trapped in the liver. Histological examination of the liver revealed the absence of a classical granulomatous reaction. Antibodies were produced only against schistosomulum antigens. Specific antibodies against adult worm (SWAP) or egg antigen (SEA) were not detected. Cytokine production (IFN-gamma and IL-4) was absent after in vitro restimulation of splenic cells from infected Abeta(o) mice with parasite antigens. Adoptive transfer of primed splenic cells (total, purified CD4+ or CD8+ T cells) failed to improve survival or to induce a granulomatous reaction in infected Abeta(o) mice. Survival, cellular and humoral responses in CD8+ T-cell-depleted Abeta(o) mice or MHC(o) mice (lacking MHC class I and II molecules) were similar to nondepleted Abeta(o) mice, suggesting that anti-schistosomula antibody production was thymo-independent. Our results demonstrate a high degree of susceptibility of Abeta(o) mice to infection and corroborate the importance of CD4+ T cells in the initiation of the granulomatous response. However, our results do not show evidence for the involvement of CD8+ T cells in response to S. mansoni infection.

Intestinal intraepithelial T lymphocytes. Our T cell horizons are expanding

The alimentary tract is an essential structure for the ingesting of nutrients from the outside, and even most primitive animals have a straight tract that runs from the mouth to the anus. We come into contact with the outside world through our skin and mucous membranes. The surface area of the enteric mucous membrane, which absorbs nutrients, is enlarge through its ciliary structure, and the enteric cavity creates by far the largest external world that we come into contact with. For instance, the enteric mucosal surface of the human gastrointestinal tract covered by a single layer of epithelial cells corresponds to the size of one-and-a-half tennis courts, and the innumerable number of epithelial cells covering this mucous surface are entirely replaced by new epithelial cells in the space of just several days. Simultaneously, the fact that 60-70% of peripheral lymphocytes are congregating in the gastrointestinal tract supports the notion that the enteric mucous membrane represents an extremely dangerous locale, where numerous harmless/precarious external antigens come in through the wide array of food we injest on a daily basis, and the literally infinite amounts of normal intestinal flora intermingled from time to time with life-threatening microbes surge across. Surprisingly, approximately one out of the five cells in the intestinal epithelium are lymphocytes, most of which are ill-defined T cells having unusual, but distinctive characteristics and situated apparently so close to external antigens in the entire body. This article deals with the information that has been accumulated mainly in the past decade concerning the development, phenotypes, and possible function of these yet unacknowledged mucosal T cells that lurk in the anatomical front of the intestine.

An opposite pattern of selection of a single T cell antigen receptor in the thymus and among intraepithelial lymphocytes

The differentiation of intestinal intraepithelial lymphocytes (IEL) remains controversial, which may be due in part to the phenotypic complexity of these T cells. We have investigated here the development of IEL in mice on the recombination activating gene (RAG)-2(-/-) background which express a T cell antigen receptor (TCR) transgene specific for an H-Y peptide presented by Db (H-Y/Db x RAG-2(-) mice). In contrast to the thymus, the small intestine in female H-Y/Db x RAG-2(-) mice is severely deficient in the number of IEL; TCR transgene+ CD8alphaalpha and CD8alphabeta are virtually absent. This is similar to the number and phenotype of IEL in transgenic mice that do not express the Db class I molecule, and which therefore fail positive selection. Paradoxically, in male mice, the small intestine contains large numbers of TCR+ IEL that express high levels of CD8alphaalpha homodimers. The IEL isolated from male mice are functional, as they respond upon TCR cross-linking, although they are not autoreactive to stimulator cells from male mice. We hypothesize that the H-Y/Db TCR fails to undergo selection in IEL of female mice due to the reduced avidity of the TCR for major histocompatibility complex peptide in conjunction with the CD8alphaalpha homodimers expressed by many cells in this lineage. By contrast, this reduced TCR/CD8alphaalpha avidity may permit positive rather than negative selection of this TCR in male mice. Therefore, the data presented provide conclusive evidence that a TCR which is positively selected in the thymus will not necessarily be selected in IEL, and furthermore, that the expression of a distinct CD8 isoform by IEL may be a critical determinant of the differential pattern of selection of these T cells.

A step-wise expansion of intestinal intraepithelial T lymphocytes in association with microbial colonization is defined by sensitivity to cyclosporin A

Murine intestinal intraepithelial lymphocytes (IELs) consist of T cells bearing alpha beta-antigen receptor (alpha beta-IELs) and those bearing gamma delta-IELs). Although gamma delta-IELs outnumber alpha beta-IELs in germ-free (GF) mice, oral inoculation of fecal suspension from conventional (CV) mice into GF mice induced the increase in number of alpha beta-IELs, leaving the number of gamma delta-IELs unchanged, and the number of alpha beta-IELs reached the level of CV mice by 3 weeks after conventionalization. Expansion of alpha beta-IELs and increase in their CD44+ subset in conventionalized mice were not affected until 2 weeks after beginning of daily injection of cyclosporin A (CsA). However, further expansion of alpha beta-IELs during 2-3 weeks after conventionalization was blocked by injection of CsA. Although the relative constitution of CD4- 8-, CD4+ 8-, CD4- 8 alpha alpha+, CD4- 8 alpha beta+ and CD4+ 8+ subsets among alpha beta-IELs was comparable between control and CsA-treated groups, CsA injection resulted in the decrease in ratio of high-density fraction cells to low density fraction cells in IELs. CsA completely abrogated the expansion of T cells in peripheral lymph nodes stimulated by alloantigens in vivo, and proliferation of IELs from GF mice induced by immobilized anti-alpha beta-T-cell receptor (TCR) monoclonal antibodies (mAb) in vitro was also eliminated by CsA. These results indicate that microbial colonization-induced expansion of alpha beta-IELs is subdivided into two steps: the early phase of expansion takes place via TCR-non-mediated pathway and the late phase of expansion requires TCR-mediated signal transduction.

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.

Complexity of the mouse gut T cell immune system: identification of two distinct natural killer T cell intraepithelial lineages

Gut thymo-dependent (CD8 alpha + beta + or CD4+) or -independent (CD8 alpha + beta -) intraepithelial lymphocytes (IEL) mediate cytotoxicity following T cell receptor (TCR)-CD3 signaling, but only TCR gamma delta + and alpha beta + thymo-independent IEL show cytotoxicity of natural killer (NK) and antibody-dependent cell-mediated cytotoxicity types. Moreover, TCR alpha beta + and gamma delta + thymo-independent IEL express NK receptors, and may therefore be referred to as NK-TIEL. NK-TIEL cytotoxicity is mediated through perforin, Fas, or both pathways. In contrast to that of other NK cells, this cytotoxicity is not negatively regulated by signals delivered through the recognition of major histocompatibility complex class I molecules. Thus, gut IEL include T cell subsets with unique specificities and functions, ontogenically distinct from other T cell lineages, which may increase the antigenic repertoire diversity of the immune system participating in the defense of the epithelial barrier.

T cell receptor-gamma, delta-expressing fetal mouse thymocytes are generated without T cell receptor V beta selection

We investigated whether fetal mouse T cell receptor (TCR) gamma delta cells have been subjected to so-called TCR beta selection at the CD25 stage of thymus development. To this end, we carried out a comparative three-color flow microfluorimetric analysis to TCR gamma delta cells developing in the fetal, neonatal and adult thymus using monoclonal antibodies to CD2, CD8, CD24, CD25 and CD44. Day-15 fetal TCR gamma delta cells were CD2+ suggesting an origin at a post-CD25 stage. Molecular analysis of TCR beta rearrangements were also carried out. Thus, by semi-quantitative polymerase chain reaction (PCR) amplification of V beta 6 and V beta 8 to J beta 2 rearrangements day-15 fetal TCR gamma delta showed extensive TCR beta rearrangements, a finding confirmed by PCR amplification from single micromanipulated cells. Finally, sequencing analysis of 104 PCR-amplified TCR VDJ beta 2 fragments showed that the majority (58%) were rearranged out of frame . Taken together, these phenotypic and molecular analyses suggest that fetal TCR gamma delta cells have not been subject to TCR beta selection.

Influence of beta 2-microglobulin expression on gamma interferon secretion and target cell lysis by intraepithelial lymphocytes during intestinal Listeria monocytogenes infection

Numerous microbial pathogens, including Listeria monocytogenes, enter the host through the intestine. Although relatively little is known about the biological functions of intestinal intraepithelial lymphocytes (i-IEL), they are generally considered a first line of defense against intestinal infections. In the mouse, the vast majority of i-IEL express the CD8 coreceptor either as a CD8 alpha/alpha homodimer or as a CD8 alpha/beta heterodimer. The CD8 receptor of T-cell receptor TcR gamma/delta i-IEL is exclusively homodimeric, whereas the CD8-expressing TcR alpha/beta i-IEL segregate into equal fractions of CD8 alpha/alpha and CD8 alpha/beta cells. We infected beta 2-microglobulin (beta 2m)+/- mice (possessing all i-IEL populations) and beta 2m -/- mutant mice (lacking all CD8 alpha/beta + i-IEL and having few CD8 alpha/alpha + TcR alpha/beta i-IEL) with L. monocytogenes per os and determined their biological functions after TcR ligation with monoclonal antibodies. Cytolytic activities of TcR alpha/beta and TcR gamma/delta i-IEL from beta 2m +/- mice were not influenced by intestinal listeriosis. Cytolytic activities of TcR alpha/beta i-IEL were impaired in uninfected beta 2m -/- mice, but this reduction was reestablished as a consequence of intestinal listeriosis. Frequencies of gamma interferon (IFN-gamma)-producing TcR alpha/beta i-IEL in uninfected beta 2m -/- mice were reduced, compared with that in their heterozygous controls. Equally low frequencies of IFN-gamma-producing TcR gamma/delta i-IEL in beta 2M +/- and beta 2m-/- mutants were found. Listeriosis increased frequencies of INF-gamma-producing TcR alpha/beta and TcR gamma/delta i-IEL in both mouse strains. Most remarkably, the proportion of IFN-gamma-producing TcR gamma/delta i-IEL was elevated 10-fold in listeria-infected beta 2M -/- mice. Our findings show that the beta 2m-independent CD8 beta- i-IEL expressing either TcR alpha/beta or TcR gamma/delta are stimulated by intestinal listeriosis independent of regional beta 2m expression. We conclude that the three major CD8+ i-IEL populations are stimulated by intestinal listeriosis and that CD8 beta- i-IEL compensate for the total lack of CD8 beta+ i-IEL in beta 2M -/- mutant mice. Hence, in contrast to the peripheral immune system, which crucially depends on CD8 alpha/beta + TcR alpha/beta lymphocytes, the mucosal immune system can rely on additional lymphocytes expressing the CD8 alpha/alpha homodimer.

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.

Control of thymus-independent intestinal intraepithelial lymphocytes by beta 2-microglobulin

Murine intestinal intraepithelial lymphocytes (i-IEL) comprise thymus-dependent cells such as T cell receptor (TcR) alpha/beta CD8 alpha/beta+ i-IEL, as well as thymus-independent ones such as TcR alpha/beta CD8 alpha/alpha+ and TcR gamma/delta CD8 alpha/alpha+ i-IEL. Whilst the development of the CD8 alpha/beta expressing i-IEL is strictly contingent on major histocompatibility complex (MHC) class I surface expression, that of CD8 alpha/alpha i-IEL appears largely MHC class I independent. We have used beta 2-microglobulin (beta 2m)-/- mutant mice lacking surface-expressed MHC class I and TcR alpha/beta CD8 alpha/beta+ i-IEL to analyze the potential impact of MHC class I on regional activation of thymus-independent i-IEL. To analyze the role of TcR gamma/delta i-IEL in regional cell interactions, these mice were treated with the anti-TcR gamma/delta mAb, GL3. Whilst numbers of TcR alpha/beta CD8 alpha/alpha i-IEL were markedly reduced in beta 2m-/- mice, those of TcR gamma/delta i-IEL were elevated. Administration of GL3 in vivo caused TcR down-modulation and functional inactivation of TcR gamma/delta i-IEL in beta 2m+/- mice. In contrast, TcR expression and functional activities of TcR gamma/delta i-IEL from beta 2m-/- mice were not impaired by GL3 treatment. The TcR alpha/beta CD8 beta- i-IEL from beta 2m-/- mice were expanded and functionally activated as a consequence of TcR gamma/delta engagement. The TcR gamma/delta i-IEL and TcR alpha/beta CD8 alpha/alpha+ i-IEL from athymic nu/nu mice which express MHC class I, but lack TcR alpha/beta CD8 alpha/beta+ i-IEL, responded to TcR gamma/delta engagement as those from the beta 2m+/- controls. In addition, the TcR gamma/delta i-IEL from TcR beta-/- and TCR beta+/- mutants were equally affected by GL3. We conclude that the absence of beta 2m renders TcR gamma/delta i-IEL resistant to TcR-mediated inactivation and promotes activation of TcR alpha/beta CD8 beta- i-IEL. The activation of TcR gamma/delta i-IEL seems to be directly controlled by beta 2m/MHC class I expression and independent from TcR alpha/beta CD8 beta+ i-IEL. Regulation of self-reactive thymus-independent i-IEL through beta 2m/ MHC class I may contribute to control of autoreactive immune responses in the intestine.

Extrathymic T cell differentiation

In the mouse, the gut mucosa is a major site of extrathymic differentiation of T cells. Recent data in this past year show that this process differs from the main thymic differentiation pathway not only in its location, but also in its use of costimulatory molecules, signal transduction modules, and mechanisms of repertoire selection. The thymus exerts an influence on the expansion of the extrathymically differentiated gut intraepithelial lymphocytes that appears to be varied in nature, including acting as a source of TCR- progenitors. All gut intraepithelial lymphocytes, whatever their extrathymic or thymic site of differentiation, have common features of activated and specialized cytotoxic cells. Other T cells may differentiate extrathymically, in particular in the liver; these later cells appear to have a very restricted, probably autoreactive repertoire, and also display natural killer cell features.

Intestinal T lymphocytes

The intestine is largely colonized by bacteria and further exposed to an immense array of ingested and shed immunogenic material. Therefore, the gut associated lymphoid tissue plays a major role in the human immune system. It may even constitute a unique immune system of its own, since it has been demonstrated to differ anatomically, phenotypically, functionally and on a molecular basis from its systemic counterpart and other peripheral lymphoid tissue. This is ultimately reflected by the observation in (transgenic) mice that intraepithelial T cells can develop independently of the thymus. Along the same lines, a rapidly growing body of evidences suggests that human bone marrow precursors can home to the gut epithelium, rearrange their T cell receptor genes and further differentiate in the mucosal micro environment. This, and other features that characterize the 'diffuse' mucosal T cell infiltrate will be discussed.

Oligoclonal repertoire of the CD8 alpha alpha and the CD8 alpha beta TCR-alpha/beta murine intestinal intraepithelial T lymphocytes: evidence for the random emergence of T cells

The epithelium of the small intestine in normal euthymic mice contains a large number of intraepithelial lymphocytes (IEL), some of which bear a T cell receptor alpha/beta (TCR-alpha/beta). About half of these TCR-alpha/beta IEL display the CD8 alpha alpha phenotype and the remaining have the CD8 alpha beta or the CD4 phenotypes. To examine whether TCR-alpha/beta IEL have a TCR-beta chain repertoire as diverse as that of TCR-alpha/beta lymph node lymphocytes (LNL), we used a recently described PCR technique that allows a global analysis of the TCR-beta chain repertoire. Within any given mouse, the repertoires expressed in both CD8 alpha alpha and CD8 alpha beta TCR-alpha/beta IEL populations are oligoclonal and nonoverlapping between the two subsets. The clones are largely conserved through the length of the small intestine of the same individual. However, genetically identical individuals raised under indistinguishable environmental conditions display distinct oligoclonal repertoires. Those findings indicate that few cells of CD8 alpha alpha or of the CD8 alpha beta phenotype are responsible for the repopulation of the intestinal epithelium.

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.

Intraepithelial lymphocytes and their recognition of non-classical MHC molecules

Recent studies of the TCR alpha and beta chains expressed by normal human IELs suggest that these intestinal lymphocytes are directed at a limited set of antigens, presumably on intestinal epithelial cells in view of their anatomic location. The direct sequence analysis of these cells has indicated that they are oligoclonal and cannot, therefore, be responding to the complex mixture of antigens which are present in the lumen. The abundant expression of the CD8 accessory molecule by the IELs, in addition, indicates that these putative intestinal epithelial cell antigens are presented by MHC class I or I-like molecules. The expression of CD8 also suggests that these cells function biologically in part as cytolytic T lymphocytes which is consistent with a variety of functional studies. Taken together with their expression of the CD45RO isoform, these phenotypic and functional observations suggest that iIELs are cytolytic, memory cells which are responsive to an extremely limited number of antigens bound to major histocompatibility complex (MHC) class I or class I-like molecules. Several non-polymorphic MHC class I-like molecules such as Qa, the thymus leukemia antigen (TL) and CD1 in the mouse and CD1 in human represent important candidate ligands for these oligoclonal iIELs. TL and CD1 are expressed specifically by murine intestinal epithelial cells. In humans, CD1d is constitutively expressed by intestinal epithelial cells. In addition, we have isolated iIEL T cell clones which specifically recognize members of the CD1 gene family when expressed on a transfected B cell line that lacks HLA-A and B and have shown that the proliferation of peripheral blood T cells to intestinal epithelial cells is CD1d dependent. Thus, the evidence to date strongly implicate the nonpolymorphic, class Ib molecules as novel restriction elements for unique populations of lymphocytes within the intestinal epithelium.

Differentiation and function of intestinal intraepithelial lymphocytes

Intestinal intraepithelial lymphocytes (i-IEL) are phenotypically diverse and consist of both thymically derived and extrathymically derived cells. Extrathymically derived i-IEL are clearly different from thymically derived peripheral T cells in their phenotype and repertoire selection. The major locus of differentiation of extrathymically derived i-IEL appears to be the intestinal epithelium because recombination activating gene (RAG)-1 is expressed in CD3- i-IEL. Extrathymic differentiation however does not imply independence from the thymus as athymic mice have increased numbers of CD3-CD8- and CD3-CD8 alpha alpha + i-IEL but decreased numbers of CD3+CD8 alpha alpha+ i-IEL when compared to euthymic mice. We speculate from these results that thymus-derived cytokine(s)/factor(s) may support differentiation from CD3-CD8 alpha alpha + to CD3+CD8 alpha alpha + i-IEL in the intestinal epithelium. i-IEL seem to have some role in immune surveillance because they reside at a site which may represent a first line of defense against pathogenic organisms. This idea is supported by the reports showing in vivo activation of i-IEL under conditions of intestinal infection or tumor-bearing state. In vitro analyses showed cytotoxicity and cytokine production of i-IEL but their true function(s) in vivo is(are) not well known. Clearly more analysis on the in vivo function(s) of i-IEL are needed in order to clarify the true role(s) of i-IEL.