Analysis of T cell antigen receptors of myelin basic protein specific T cells in SJL/J mice demonstrates an {alpha} chain CDR3 motif associated with encephalitogenic T cells

Experimental autoimmune encephalomyelitis (EAE) is an animalautoimmune disease mediated by CD4⁺ T cells. Analysis of TCRexpression revealed that limited TCR elements (V^ß8.2,V2 or 4) were utilized by myelin basic protein (MBP) specificT cells In mice with H-2^U haplotype and Lewis rats. The usageof a particular ß chain complementarity determiningregion 3 (CDR3) motif has also been shown. However, It remainsunclear to what extent these observations can be extrapolated.Here we studied the TCR sequences of MBP 89–101/1-A^s specificT cell clones derived from SJL/J mice, using the polymerasechain reaction on reverse transcribed mRNA. Although the V_ßusage was less restricted than In H-2^U mice, they predominantlyutilized v_ß17a and expressed LGG or related motifsin the V_ß - D_ß - J_ß junctions.Furthermore, a single chain rearrangement between V1.1 andJBBM142 with no N region diversity was preferentially used.Concordantty, Immunization with a peptlde corresponding to the chain CDR3 was found to significantly alter the clinical courseof EAE. Comparison of the published TCR junctional regions demonstratesthat the CDR3 motifs (LGG in ß chain, CA*R*NY motifIn chains) are expressed by other encephalitogenic clones.Notably, the CA*R*NY was conserved in PL/J mice clones thatrecognize a distinct MBP–MHC determinant. It suggeststhat an antigen-independent mechanism may contribute to conservingthe a chain motif. The Implications of these observations arediscussed.     

Predominant expression of invariant V{alpha}14+ TCR {alpha} chain in NK1.1+ T cell populations

A novel T cell subset characterized by cell surface NK1.1⁺ TCRß⁺expression was investigated for its TCR usage, particularlythat of invariant V14 TCR, which was found to be preferentiallyused in peripheral CD4^–CD8^–T cells developed atextrathymic sites. We found that NK₊ ß T cell subsetsaccount for 0.4% in thymocytes, 5% in the splenic T cells and40.5% in the bone marrow T cells. Among these NK⁺ ßT cells, two distinct subsets were detected; cell surface TCRV14⁺and V14^– subpopulations. Almost all of NK⁺ ßthymocytes express V14 mRNA; however, only<20% were positive,while >80% were negative or undetectable for V14 TCR expressionon the cell surface in the thymus. Similarly,50% of NK⁺ ßT cells in spleen and bone marrow are V14⁺; as revealed by FACS.TCR repertoire analysis by nucleotide sequences on inverse PCRproducts demonstrated that most NK⁺ ß T cells expressan invariant TCR encoded by the V14J281 gene with a 1 base N-regionin all tissues. Thus, invariant V14 TCR is uniquely expressedon NK T cells, and can be a marker to distinguish NK, NK T andT cells.     

Expression of an ovalbumin-specific V{beta}8.2 TCR transgene inhibits collagen arthritis in B10.Q mice

Previous studies have illustrated the importance of T cellsbearing ß TCRs in the induction and development ofcollagen induced arthritis (CIA) in mice. However, the scopeof TCR usage in CIA has yet to be clearly defined. Given theinherent diversity of the TCR repertoire, the relative flexibilityof the arthritogenic TCR repertoire specific for type II collagen(CII) is not clear. Therefore, we chose to examine the influenceof a highly skewed TCR repertoire on CIA. Arthritis susceptibleB10.Q (H-2^q) mice were mated with C57L (H-2^b) animals expressingan ovalbuminspecific V_ß8.2 TCR transgene (Tg) andTg⁺ offspring were further backcrossed to B10.Q. HomozygousH-2^a/q, V_ß8.2 Tg⁺ mice displayed a high level of V_ß8.2⁺T cells in peripheral blood. However, expression of some endogenousV_ß TCR, such as V_ß14, was still detected.Upon immunization with bovine CII in adjuvant, V_ß8.2Tg⁺ mice were highly resistant to CIA when compared with Tg^–littermates. Analysis of sera demonstrated a marked reductionin antibody specific for homologous mouse CII as well as heterologousbovine CII in Tg⁺ animals. Interestingly, V_ß8.2 Tg⁺mice still mounted good antibody responses following immunizationwith human thyroglobulin, indicating that the skewed TCR repertoireaffected anti-CII but not antithyroglobulin responses. Thus,our findings show that constraints placed on the TCR repertoireInhibit pathogenic responses against CII and suggest that inH-2^q mice the arthritogenlc TCR repertoire bears only limitedflexibility.     

Differential effect of transforming growth factor-{beta}1 on the activation of human naive and memory CD4+ T lymphocytes

Transforming growth factor-ß1 (TGF-ß1) canhave stimulatory or inhibitory effects on cell growth. For severalcell types, the effect of TGF-ß1 was found to correlatewith the differentiation stage of the cells and the presenceof other cytoklnes. We have studied here the influence of TGF-ß1on CD4⁺ T cell activation in relation to the differentiationstage of the cells by evaluating the effect of TGF-ß1on the prollferatlve responses of purified CD4⁺CD45RA⁺ (unprfmed)and CD4⁺CD45RO⁺ (primed) lymphocytes. Under certain conditions,TGF-ß1 exerted a co-stlmulatory effect on peripheralblood CD4⁺CD45RA⁺ T cells whereas the outgrowth of CD4⁺CD45RO⁺T cells was suppressed in any activation system tested. Theenhancement of prollferatlve responses by TGF-ß1 inTCR/CD3 or CD2 stimulated cultures of CD45RA⁺ cells involvedup-regulatlon of CD25 expression and was dependent on the presenceof exogenous IL-2 or CD28 mAbs; IL-7 driven proliferatlve responseswere suppressed by TGF-ß1. These observations wereconfirmed in experiments with purified cord blood (CB) CD4⁺T cells inasmuch as addition of TGF-ß1 caused a 2-to 7-fold increase in IL-2 driven proliferatlve responses ofthese cells. Finally we show that, in contrast to the effectof TGF-ß1 during primary stimulation of CB CD4⁺ Tcells, TGF-ß1 suppressed T cell proliferation for40% in secondary cultures of these cell. Our findings indicatethat TGF-ß1 Is a blfunctlonal regulator of CD4⁺ Tcell growth in vitro, with co-stimulatory capacities duringCD45RA⁺ T cell mediated primary responses and growth suppresslveeffects during secondary responses of CD45RO⁺ T cells.     

CD3{varepsilon}-mediated signals rescue the development of CD4+CD8+ thymocytes in RAG-2 / mice in the absence of TCR {beta} chain expression

Recent studies have shown that TCR ß chain expressioncan effect the differentiation of CD4^–CD8^– double-negative(DN) thymocytes to CD4⁺CD8⁺ double-positive (DP) thymocytes.The TCR ß chain is expressed on the surface of DPthymocytes in association with CD3, and chains, suggestinga potential role for CD3 components in this signaling process.We now report detection of a very tow level of surface expressionof CD3 on adult DN RAG-2^–/–; thymocytes. This surfaceCD3 was associated with CD3 and chains, as detected by anti-CD3immunoprecipitation analyses. Significantly, injection of anti-CD3mAb into RAG-2^–/– mice led to the accumulation ofan IL-2R^– CD2⁺ DP cell population and a nearly 100-foldincrease in thymic cellularity to essentially normal levels.Together, these data strongly indicate that TCR ßchain-mediated developmental signals are transduced by CD3 componentsand provide potential insights into mechanisms by which TCRß chain expression may effect this process.     

Herpesvirus saimiri immortalization of {alpha}{beta} and {gamma}{delta} human T-lineage cells derived from CD34+ intrathymic precursors in vitro

Herpesvirus saimiri (HVS), an agent that can infect many humancell types, has been shown to immortalize selectively TCR ß⁺CD3⁺T lymphocytes. Human T cell precursors defined as CD34⁺CD3^–CD4^–CD8^–were isolated from thymic samples and exposed to HVS in thepresence of either IL-2 or IL-7. Cultures lacking the viruswere non-viable by day 15. Test cultures, in contrast, showeda sustained proliferative activity lasting >5 months, allowingthe phenotypical and molecular analysis of the cellular progeny.In the presence of IL-7, TCR ß⁺ cells with three differentphenotypes (mainly CD4⁺CD8^–, but also CD4⁺CD8⁺ and CD4^–CD8⁺)were immortalized, whereas no TCR ⁺ cells were recovered. Kineticstudies showed that the expansion of immortalized TCR ß⁺cells was preceded by a gradual loss of CD34⁺ cells followedby a transient accumulation of two distinct cell subsets: firstCD1⁺CD4⁺CD3^– cells and then CD4⁺CD8⁺ thymocytes. Thisresembles early phenotypic changes occurring during normal intrathymicT cell development. In the presence of IL-2, in contrast, onlyTCR ⁺ cells were immortalized (mainly CD4^–CD8⁺, but alsoCD4^–CD8^–). The results show that HVS can be usedto read the CD3⁺ cellular outcome of T cell differentiationassays, including ⁺ CD4^–CD8⁺, ⁺CD4^–CD8^–, ß⁺CD4⁺CD8^–,ß⁺CD4^–CD8⁺ and ß⁺CD4⁺CD8⁺ T cells.A clear role for different cytokines (IL-2 for ⁺ cells, IL-7for ß⁺ cells) in early T cell commitment was alsoapparent.     

Phenotypic and functional assessment of intraepithelial lymphocytes bearing a 'forbidden' {alpha}{beta} TCR

Differences in the surface antigen phenotype, such as the expressionCD8 as an homodimer or the lack of Thy-1, on Intestinal Intraepitheliallymphocytes (IEL) are related, In part, to alternative differentiationpathways. The relationship of IEL lacking the pan-T cell markerCD5 to these IEL, their TCR repertoire and function has notbeen examined directly. We explored the TCR repertoire and functionof the CD5^– IEL subset In relation to the expression ofthe ‘autospecific’ V_ß6 TCR in Mls-1^a miceand to TCR. The results indicate that CD5 expression was absenton the majority of TCR IEL (96.9%) and on a significant proportionof TCR ß IEL (25.0%). Virtually all IEL In DBA/2 (Mls-1^a)mice that expressed the ‘autospecific’ V_ß6TCR were CD5^–, and this correlated with the expressionof CD8 . To assess the functional capacity of this subset ofIEL, we examined proliferation and IL-2 production in responseto TCR activation. Although CD5^– IEL proliferated in responseto anti-CD3, IEL bearing TCR V_ß6, In Mls-1^a mice,were not responsive to TCR-mediated activation. Similarly, TCR IEL were not responsive to stimulation by anti-TCR antibodies.The addition of exogenous IL-2, however, reconstituted the prollferativeresponse of both TCR IEL and the TCR V_ß6 expressingIEL. We conclude that the lack of CD5 defines a unique subsetof intraepithelial T cells expressing either TCR or ßthat Include potentially autoreactive cells that remain anergicin the absence of IL-2.     

Selection of intestinal intraepithelial lymphocyte T cell receptors: evidence for a dynamic tissue-specific process

An extensive comparison of TCRß V-reglon usage byCD8ß^-CD4⁺CD8⁺ intraepithelial lymphocytes (IEL), CD4^-CD8⁺IEL, and lymph node (LN) T cell subsets in three minor lymphocytestimulating (MIs)-disparate, MHC-ldentical mouse strains revealednovel TCR selection patterns. In cases where forbidden V regionswere expressed by CD8ß^- CD4^-CD8⁺ IEL, the same TCRswere deleted from CD8ß^– CD4⁺CD8⁺ IEL, Indicatingthat lack of CD8ß expression was not solely responsiblefor forbidden V-region expression. These results also suggestedthat CD4 may be involved in negative selection of CD4⁺CD8⁺ IELTCRs. In C57BR/cdJ (Mls-1^b2^b) mice, a major increase in V_ß3⁺CD4⁺CD8⁺IEL but not in other IEL or LN subsets was noted suggestinga subset-specific expansion of V_ß3⁺ cells. Negativeselection of V_ß14⁺ cells in only the CD4⁺CD8⁺ IELsubset further supported the existence of intestine-specificTCR selection processes. Analysis of V-reglon expression ofCD8ß⁺ and CD8ß^–CD4^–CD8⁺ IELsubsets revealed that forbidden V-region expression was notstrictly confined to the CD8ß^– subset in allcases. Overall, the data point to a dynamic, gut-specific TCRselection process that may be antigen driven.     

In vivo and in vitro repertoire of CD3+CD4 CD8 thymocytes

CD4-CD8- thymocytes contain a cell subset which expresses thecomplete CD3-TCR complex (/ or /) of which the ontogeny andfiliation are unknown. One of the questions is whether thispopulation can be intrathymically selected, an obligatory stepfor the mature CD4⁺ and CD8⁺ cell differentiation pathway, orif the absence of CD4 and CD8 allows them to escape thymic selection.The repertoire of CD3 ⁺ CD4 - CD8 - (CD3 ⁺ DN) thymocytes wasanalyzed in different strains of mice with different combinationsof H-2 and Mls expression. The expression of V_ß8.1in freshly isolated CD3⁺ DN cells is the highest in Mls-l^b miceand the lowest in MIS-l^a and F₁ mice, suggesting that selectionagainst this specificity can be achieved in vivo. By contrast,a low percentage of V_ß6⁺ cells is found in all thestrains, with no correlation according to MIS expression. Invitro culture of DN thymocytes with IL-1 and IL-2 leads to theproliferation of CD3⁺ DN cells. In vitro culture amplifies thein vivo pattern of V_ß8.1 expression, while V_ß6⁺cells only expand in DN cells of 66 and 61002 Mls-l^b mice withthe same genetic background. These results show: (i) CD3⁺ DNthymic cells can be intrathymically selected but the repertoireis different from that of mature T cells; (ii) V_ß6and V_ß8.1 selection do not follow the same pattern;(iii) this repertoire can be modified by In vitro culture, towarda more mature type; and (iv) comparison of DN cell repertoireof BALBlc, BALB.D2 (congenic for MLs), and other strains ofmice suggests a multigenic control for this selection, and aninvolvement of background genes.     

Skewed T cell receptor V{alpha} repertoire among superantigen reactive murine T cells

Reactivity of murine T cells with viral or bacterial superantigensis clearly correlated with the expression of TCR V_ßdomains. Thus, T cells responding to the minor lymphocyte stimulatorylocus (Mls-1^a) or staphylococcal enterotoxin B (SEB) expresspredominantly TCR V_ß6 or V_ß8.2 respectively.We have investigated the involvement of the other major variableelement of the TCR, the V domain, in these superantigen responses.Using a panel of anti-TCR V mAbs, It is demonstrated that theTCR V repertoire among superantigen stimulated V_ß6⁺or V_ß8.2⁺ blasts (responding to Mls-1^a or SEB respectivelyin vitro) is altered in comparison with anti-CD3 stimulatedcells expressing the same V domains. Furthermore, the TCR Vrepertoire is strongly skewed in TCR V_ß8.2 transgenicmice that have undergone extensive peripheral clonal deletionafter SEB injection. These data imply that the V domain influencessuperantigen recognition by sthe TCR.     

CD38 expression on mouse T cells: CD38 defines functionally distinct subsets of {alpha}{beta} TCR+CD4 CD8 thymocytes

We have examined CD38 expression on mouse lymphocytes usingthe rat mAb NIM-R5 and demonstrate that CD38 expression is restrictedto {small tilde}8% of thymocytes. Although CD38 is absent fromthe majority of CD4+ CD8^– and CD4^–CD8⁺ T cells,we detected a strong correlation between CD36 expression andß⁺CD4^–CD8^– T cells in the thymus, withnearly 80% of ß TCR⁺CD4^–CD8^– thymocytesbeing CD38⁺. Using heat stable antigen (HSA) and CD38, we dividedß⁺CD4⁺CD8^– thymocytes into four subsets: HSA⁺CD38^–,HSA^– CD38^hi, HSA^–CD3810^low and HSA^– CD38^–.Two established characteristics of ß TCR⁺CD4CD8^–cells, bias towards Vß 8.2 TCR expression and highlevels of IL-4 production, were used to establish a possiblerelationship between the above thymocyte subsets. Our presentdata show that the HSA⁺CD38^– subset is not biased towardsVß8.2 TCR expression whereas the HSA^– CD38^–subset does show this bias (–47%). Neither of these subsetsmake IL-4 upon CD3 mediated stimulation. In contrast, the CD38⁺subsets are heavily biased toward Vß8.2 expressionand produce large amounts of IL-4 upon stimulation, particularlythe CD38^low cells. Taken together, these data suggest that thesefour subsets represent various stages of a possible differentiationpathway for ß TCR⁺ CD4^–CD8^– cells, withthe HSA⁺CD38^– subset being the most Immature while theHSA^–CD38^low subset is the most functionally mature. Thesecharacteristics support the view that ap TCR⁺CD4^–CD8^–T cells represent an independent lineage with a distinct, butas yet obscure, role in immunity     

HLA-DR and H-2E transgenes differentially mediate TCR-specific positive selection

The use of HLA transgenic mice in models of immunity and diseaseassumes that human MHC molecules are able to contribute towardthe positive selection of the mouse TCR repertoire. As an initialstep towards analysis of this we have compared the relativeability of DR/Eß or E/Eß complexes to induceT cell receptor (TCR) positive selection in H-2Ea and HLA-DRAtransgenic mice lacking endogenous E. The results show that,like E/Eß, the hybrid DR/ß complexes arecapable of mediating positive selection of V_ß2⁺;,V_ß6⁺, and V_ß10⁺ cells. However, differenceswere found between the effects of the two transgenes. Thus,while V_ß6⁺ cells were efficiently selected in bothH-2Ea and DRA transgenic mice, positive selection of V_ß10⁺cells was less apparent in the DRA transgenic mice. Variationbetween Ea and DRA transgenic mice is consistent with the notionthat this process is dependent on differential binding of endogenouspeptides to the E/Eß and DR/Eß complexes.Furthermore, contrary to expectations, in neither set of micewas positive selection limited solely to the CD4⁺ subset. Thus,examples were found in which V_ß-specific positiveselection was confined to either the CD4⁺ or CD8⁺ subsets, andothers in which both subpopulations were concomltantly increased.In the case of V_ß2 positive selection, H-2Ea transgenicmice showed expansion of these cells in both the CD4⁺ and CD8⁺subpopulations whlle in DRA transgenic mice this occurred predominantlyin the CD8⁺ subpopulatlon.     

IL-4 producing CD4+ TCR{alpha} {beta}int liver lymphocytes: influence of thymus, {beta}2-microglobulin and NK1.1 expression

The present report describes developmental, phenotypic and functionalfeatures of unconventional CD4⁺ TCRß lymphocytes.In C57BL/6 mice, the majority of liver lymphocytes expressingintermediate intensity of TCRß (TCRß^int)are CD4⁺NK1.1⁺ and express a highly restricted TCR V_ßrepertoire, dominated by V_ß8 with some contributionby V^ß7 and V^ß2. Although these cells expressthe CD4 co-receptor, they are present in H2-l Aß (Aß)^+/–gene disruption mutants but are markedly reduced in ß₂-microglobulin(ß₂m)^–/– mutant mice and hence are ß₂mdependent. Thymocytes expressing the CD4⁺NK1.1⁺ TCR ßphenotype are also (ß₂m) contingent, suggesting thatthese two T lymphocyte populations are related. The CD4⁺NK1.1⁺TCRßlymphocytes in liver and thymus share several markers such asLFA-1⁺, CD44⁺, CD5⁺, LECAM-1^– and IL-2Rßa. TheCD4⁺NK1.1 ⁺ TCRß^int liver lymphocytes were not detectedin athymic nuinu mice. We conclude that ß₂m expressionis crucial for development of the CD4⁺NK1.1⁺ TCRß^intliver lymphocytes and that thymus plays a major role. CD4⁺ TCRß^intliver lymphocytes were also identified in NK1.1⁺ mouse strains,there lacking the NK1.1 marker. We assume that the NK1.1 moleculeis a characteristic marker of the CD4⁺TCR"^int liver lymphocytesin NK1.1⁺ mouse strains, although its expression is not obligatoryfor their development. The liver lymphocytes from +₂m^+/–,but not from +₂m^–/–mice are potent IL-4 producersin response to CD3 or TCRß engagement and the IL-4production by liver lymphocytes was markedly reduced by treatmentwith anti-NK1.1 mAb. We conclude that the CD4+NK1.1⁺ TCRß^intliver lymphocytes are capable of producing IL-4 in responseto TCR stimulation.     

Analysis of T cell repertoire and function in mice transgenic for the human V{beta}3 TCR

We have constructed mice containing the human V_ß3TCR gene from the influenza virus haemagglutinin specific humanCD4⁺ T cell clone HA1.7. Similar cell yields were obtained fromtransgenic and non-transgenic lymphoid tissue, with normal levelsof T cells and with no unusual bias of the CD4 or CD8 subpopulations.Immunostaining and FACS analysis of transgenic thymocytes, spleen,and mesenteric lymph nodes revealed that the majority of T cellsexpressed the human V_ß3 TCR on the cell surface. Smallnumbers of cells expressing murine TCR_ßchain werealso detected. Polymerase chain reaction analysis revealed thatan extensive V TCR repertoire was used in the human V_ß3transgenic mice. Lymphocytes from the spleen and bmesentericlymph nodes of transgenic mice were assessed for functionalactivity in vitro. Isolated cells were stimulated with mitogenor superantigen, as well as directly through the TCR-CD3 complex,and their ability to proliferate and secrete lymphokines analysed.Cells from transgenic mice responded well after stimulationwith phytohaemagglutinin, concanavalin A, anti-CD3 antibody,anti-CD3 antibody with phorbol ester, and Staphylococcus aureusenterotoxin B, and also showed alloreactivity in a mixed lymphocytereaction. Minimal levels of response were detected after stimulationwith murine TCRß antibody. Together, these data suggestthat a human TCRß chain is able to associate witha murine TCR chain, to form a fully functional surface TCR-CD3complex.     

Migration pathways of CD4 T cell subsets in vivo: the CD45RC- subset enters the thymus via {alpha}4 integrin-VCAM-1 interaction

The present investigation examines the localization and migrationof purified T cell subsets in comparison with B cells, CD8 Tcells and CD4⁺CD8^– single-positive thymocytes. CD4 T cellsubsets in the rat are defined by mAb MRC OX22 ( anti-CD45RC),which distinguishes resting CD4 T cells (CD45RC⁺) from those(CD45RC^–) which have encountered antigen in the recentpast– subpopulations often referred to as ‘naive’and ‘memory’. Purified, ⁵¹Cr-labelled CD45RC⁺ CD4T cells broadly reflected the migration pattern of CD8 T cellsand B cells. Early localization to the spleen was followed bya redistribution to mesenteric lymph nodes (MLN) and cervicallymph nodes ( CLN) , B cells migrating at a slightly slowertempo. There was almost no localization of these subpopulationsto the small or large intestine [Peyer's patches (PP) excluded].In contrast, CD45RC^– CD4 T cells (indistinguishable insize from the CD45RC⁺ subset) localized in large numbers tothe intestine; they were present here at the earliest time point(0.5 h) , persisted for at least 48 h but did not accumulate,indicating a rapid exit. Numerically, localization of CD45RC^–CD4 T cells in the MLN could be accounted for entirely by afferentdrainage from the intestine. Unexpectedly, CD45RC^– CD4T cells (but not other subsets) localized and accumulated inthe thymus. In vivo treatment with mAb HP2/1 against the integrin₄ subunit inhibited almost entirely CD45RCT^– CD4 T cellmigration into the PP (98.1%), intestine (87.1%) , MLN (89.1%)and thymus (93.5%) migration into the CLN was only reduced byhalf. To distinguish between recognition of MAdCAM-1 and VCAM-1by ^4–containing integrins, recipients were treated withmAb 5F10 against rat VCAM-1. Except for the thymus and a smallreduction in CLN, localization of CD45RC^– CD4 T cellswas unaffected; entry to the thymus was almost completely blocked(92.3%) by anti-VCAM-1. The results indicated (i) that CD45RC^–CD4 T cells alone showed enhanced localization to the gut andPP, probably via ₄ß₇-MAdCAM-1 interaction; ( II) thatmany CD45RC^– cells entered nonmucosal LN independentlyof ₄ integrin or VCAM-1; and (III) that entry of mature recirculatlngCD45RC^– CD4 T cells into the thymus across thymic endothellumwas apparently regulated by ₄ integrln-VCAM-1 interaction.     

Identification of two binding sites in staphylococcal enterotoxin B that confer specificity for TCR V{beta} gene products

The enterotoxlns produced by Staphytococcua af1reus are potentmitogens. They stimulate T cells in an oligocional fashion thatIs dependent on the expression of particular variable regiongene elements in the ß-chaln of the TCR (V_ß).The fourth hypervarlable loop of the TCR ß-chaln Isgenerally regarded as the site of contact for both viral andmlcroblal superantigens. Recently, residues 60 and 61 of staphylococcalenterotoxin B (SEB) have been highlighted as central to theinteraction of this toxin with the TCR. We have, therefore,analysed a series of toxins with mutations at these positionsto investigate how amlno add substitutions affect the abilityof mutant toxins to stimulate both human and mouse T cells.Each of the variant toxins induced proliferation in a murineV_ß8.3 T cell clone, whereas a V_ß8.1 T cellclone only responded to native toxin. A panel of nine humanT cell clones expressing six different V_ß elements,all of which responded to native SEB, was tested for reactivityto the variant toxins. Only one V_ß19.1⁺ T cell clonewas found to be sensitive to substitution at positions 60 and61 In a manner analogous to the murine V_ß8.1 T celldone. Seml-quantitatlve analysis of the TCR V_ß expressionof human T cell lines expanded with native and mutant SEB revealedthat none of the variant toxins could stimulate T cells thatexpressed V_ß19.1. Taken together, these results suggestthat the interaction of mouse V_ß8.1 and human V_ß19.1TCRs with SEB differs from other TCRs. Sequence comparisonsof the different TCR V_ß chains indicated that residuesin the second complementarity determining region (CDR2) interactwith the 60–61 loop of SEB. Therefore, a minimum of twodistinct binding modules confer specificity to the interactionof the TCR with SEB.     

Resident CD4+ {alpha}{beta} T cells of the murine female genital tract: a phenotypically distinct T cell lineage that rapidly proliferates in response to systemic T cell activation stimuli

A population of CD4⁺ cells has been identified in the murinefemale genital tract (FGT). Phenotypic studies of FGT CD4⁺ cellsdemonstrate that they express CD3 and that the majority of thesecells are ßTCR⁺Thy-1⁺. Most of the Thy-1⁺CD4⁺ßTCR⁺ cells resemble memory T cells based on their expressionof CD44, L-selectin and CD45RB antigens. The vast majority ofThy-1⁺CD4⁺ßTCR⁺ FGT cells are CD5⁺ and all of themare B220^–. Systemic stimuli including infection with Trypanosomabrucel brucel, injection with anti-CD3, or bacterial superantigensstaphylococcal enterotoxin A or B cause a rapid accumulationof CD4+cells in the FGT exceeding that observed for CD4⁺ cellsin spleen and lymph nodes (LN). Expansion of the FGT CD4⁺ cells,which are phenotypically distinct from the splenic and LN CD4⁺T cells, is due to local proliferation rather than an influxof cells from the circulation. The CD4⁺ population in the FGTof adult nu/nu mice is dramatically reduced, indicating itsthymic dependency. In lpr/lpr mice, FGT CD4 cells do not displaychanges characteristic of splenic or LN CD4 cells in the sameanimals. These findings demonstrate that the CD4⁺ cells of themurine FGT are thymic dependent, but that they constitute aT cell lineage that phenotypically and, probably functionally,is distinct from other peripheral CD4⁺ T cell populations.     

CD2 expression on murine intestinal intraepithelial lymphocytes is bimodal and defines proliferative capacity

The CD2 molecule is normally expressed on nearly all murinelymphocytes, and is co-stimulatory in T cell activation viathe antigen receptor (TCR). A naturally occurring T lymphocytepopulation that is bimodal for CD2 expression was found in theintestinal intraepithelial lymphocytes (IEL). TCRß⁺IEL contain CD2^– and CD2⁺ cells of approximately equalproportion, while TCR⁺ IEL are predominantly CD2^–. Theproliferative response of IEL to stimulation with an anti-CD3mAb or with PMA plus ionomycin co-segregated with CD2 expression;the CD2⁺ subset proliferated vigorously under these conditionswhile the CD2^– subset was much less responsive. The respondingCD2⁺ IEL contained both TCRß⁺ and TCR⁺ cells. However,activation of the CD2^– IEL with anti-CD3 mAb resultedin only the expansion of TCR⁺ IEL, while activation with PMAplus ionomycin did not promote expansion of either the TCRß⁺or the TCR⁺ IEL. These findings parallel observations in theautoimmune lpr mouse, where massive numbers of peripheral TCRß⁺CD4^–CD8^–T cells that lack CD2 expression are also hyporesponsive tomltogenic stimulation. The apparent energy of CD2^–TCRß⁺IEL, as well as CD2^– T cells from lpr mice, demonstratesthat the absence of CD2 on TCRß⁺ T lymphocytes co-segregateswith nonresponsiveness.