Preferential requirement of CD3{zeta}-mediated signals for development of immature rather than mature thymocytes

Antigen recognition signals by the TCR are transduced throughactivation motifs present in the cytoplasmic region of CD3 chains.In vitro analysis has suggested that the CD3 chain mediatesdifferent signals from other CD3 chains. To analyze the in vivofunction of CD3-mediated signals for T cell development, miceexpressing a mutant CD3 chain lacking all the activation motifswere generated by introducing the transgene into -knockout mice.Mature CD4⁺ single-positive (SP) thymocytes in these mice weregreater in number than in -deficient mice, and the promoteddifferentiation was indicated by the changes of CD69 and HSAphenotypes. We found that even in the absence of activationmotifs in CD3, these mature cells became functional, being ableto induce Ca²⁺ mobilization and proliferation upon stimulation.On the other hand, CD4^-CD8^- double-negative (DN) thymocytes,most of which were arrested at the CD44^-CD25⁺ stage similarlyto those in -deficient mice, could not be promoted for differentiationinto CD4⁺CD8⁺ double-positive thymocytes in these mice in spiteof the fact that the expression of the transgene in DN thymocyteswas higher than that of in wild-type mice. These results demonstratethe preferential dependence of the promotion of developmentand/or expansion of DN thymocytes rather than mature thymocytesupon the activation signals through the chain and suggest differentialrequirements of TCR signaling for mature SP and immature DNthymocyte developments in vivo.     

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.     

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.     

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.     

Thymic stroma is required for the development of human T cell lineages in vitro

Development of the T cell lineage is characterized by the homingof hematopoietic precursors to thymus, followed by their acquisitionof receptors for antigen. T cell receptors are ß or heterodimers associated with CD3 (TCR-CD3). Very early T cellprecursors in humans have been characterized as CD7+45+ cellswhich lack the T cell differentiation antigens CD1, CD2, CD3,CD4, and CD8. A phenotypically equivalent early thymocyte populationalso occurs in postnatal life, and we have previously shownthat interleukin 2 (IL2) promotes the development in vitro ofboth the ß and the T cells from these early thymocytes.Here we have analyzed the requirements of the induction of theIL2 pathway in early thymocytes, and their developmental potential.We show that: (I) thymic stromal cells, which are present inthymocyte suspensions, are necessary to induce the IL2 pathwayand the development of ß or T cell lineages fromearly thymocytes in vitro; and (II) when removed from the invivo environment, early thymocytes can develop in vitro intoTCR-CD3^– cells of the natural killer (NK) lineage. Weconclude that CD7+45+, CD1–2–3–4–8–early thymocytes are multipotential progenitors that, at least,have the capacity to develop into ß or T cell andNK lineages. The analysis of the mechanisms of generation andselection of human T and NK cell diversity, not feasible inbone marrow cultures, is now possible.     

Maturation of medullary thymic epithelium requires thymocytes expressing fully assembled CD3-TCR complexes

Unlike meduilary thymic epithelial cells (TEC) of normal mice,meduilary TEC of TCR^– SCID mice are immature and disorganized.In order to assess directly the role of TCR⁺ cells in the developmentof medullary TEC, we bred mice which co-expressed the SCID geneticdefect and transgenes encoding clonotypic TCR chains. Immunohistologicexamination revealed that meduilary thymic epithelial cellsfrom TCRß transgenic SCID mice, whose thymocytes onlyexpress TCRß chains that inefficiently associate withCD3 and , components, remained immature and disorganized. Incontrast, meduilary TEC from TCRß transgenic SCIDmice, whose thymocytes express fully assembled CD3--TCRßcomplexes were mature and organized. Interestingly, the abilityof TCRß⁺-⁺-CD3³ thymocytes to induce maturation ofmeduilary TEC appeared not to be related to the antigen specificityof the TCR as thyml from positively selecting, negatively selectingand non-selecting TCRß transgenic SCID mice all possessedinduced meduilary thymic epithelial cells. In addition, we foundthat induction of meduilary TEC cells was associated with thepresence of meduilary thymocytes, including those of the CD4-CD8-TCRß⁺phenotype. The present findings demonstrate that fully assembledCD3--TCR complexes are required to induce maturation of meduilarythymic epithelial cells and indicate that thymocyte inductionof meduilary thymic epithelial cells may result from signalingindependently of their clonotyplc chains.     

T cell receptor-triggered activation of intraepithelial lymphocytes in vitro

Intraepithelial lymphocytes (IEL) of the mouse small intestinewere examined for their potential to respond to TCR signallingin vitro. Purified IEL subsets were activated using mAbs specificfor CD3, TCRßor TCR&. Thy-1⁺IEL, regardless ofTCR type, proliferated equally well in response to anti-TCRmAb with or without exogenous IL-2. In contrast, Thy-1^–TCR, CD8^– IEL required exogenous IL-2 for proliferation.No such requirement was observed for Thy-1^– TCR& IELproliferation. IEL proliferation in the absence of added IL-2was due to an IL-2 secretion/IL-2 receptor (IL-2R) autocrinepathway, since mAbs specific for IL-2 and IL-2R inhibited IELproliferation. Thy-1⁺ CD8ß^– CD4⁺CD8⁺ IEL wereunresponsive to TCR-induced proliferation but exhibited highlevels of cytolytic activity upon TCR-triggerlng. Thy-1^–non-cytolytic IEL were induced to express Thy-1 and cytolytlcactivity following activation in vitro. In addition, the involvementof the co-stimulatory molecule CD28 in IEL activation was tested.CD28 was weakly expressed by fresh IEL and anti-CD28 mAb hadno effect on TCR-triggered proliferation. However, anti-TCRstimulation increased CD28 expression on a subset of TCRßIEL and the addition of anti-CD28 mAb resulted in increasedIL-2 production, but not in increased proliferation. Our resultsindicate that IEL, including the purported extrathymlc CD8ß^–subset, can respond to TCR-driven signals via proliferationand/or cytolytlc activity.     

Implication of the common {gamma} chain of the IL-7 receptor in intrathymic development of pro-T cells

The effects of IL-7 on the growth and differentiation of thymocyteswere analyzed using murine fetal thymua organ cultures (FTOC)in the presence of mAbs specific for the conventional IL-7 receptor(1L-7R) and for the common (c) chain. In FTOC, the developmentof CD4^–CD8^– double-negative thymocytes to CD4+CD8+double-positive (DP) and CD4+ or CD8+ single-positive (SP) cellswas not completely blocked by adding these mAbs, although cellgrowth was reduced by the treatment. To define a developingstage sensitive to the mAbs, most immature thymocytes, Pgp-1⁺c-kit cells, were cultured in the 2-deoxyguartosine treatedfetal thymus. In the presence of both mAbs in the culture, neitherDP nor SP thymocytes developed whereas either of the mAbs partiallyblocked their development. These results indicate that the Cchain is involved in early T cell development as an indispensablesubunlt of the functional IL-7 receptor complex.     

Developmentally regulated expression of the PD-1 protein on the surface of double-negative(CD4 CD8 ) thymocytes

PD-1, a member of the Ig superfamily, was previously isolatedfrom an apoptosis-induced T cell hybridoma 2B4.11 by subtractivehybridization. Expression of the PD-1 mRNA is restricted tothymus in adult mice. Using an anti-PD-1 mAb (J43), we examinedexpression of the PD-1 protein during differentiation of thymocytesin normal adult, fetal and RAG-2^-/- mice with or without anti-CD3mAb stimulation. While PD-1 was expressed only on 3–5%of total normal thymocytes, –34% of the CD4^-CD8^- double-negative(DN) fraction are PD-1⁺ cells with two distinct expression levels(low and high). PD-1^high thymocytes belonged to TCR lineagecells. In the DN compartment of the TCR ß lineage,PD-1 expression started at the low level from the CD44⁺CD25⁺stage and the majority of thymocytes expressed PD-1 at the CD44^-CD25^-stage in which thymocytes express TCR ß chains. Theanti-CD3 antibody administration augmented the PD-1 expressionas well as the differentiation of the CD44^-CD25⁺ DN cells intothe CD44^-CD25^- DN stage, not only in normal mice but also inRAG-2-deficient mice. The fraction of the PD-1^low cells in theCD4⁺CD8⁺ double-positive (DP) compartment was very small (>5%)but increased by stimulation with the anti-CD3 antibody, althoughthe total number of DP cells was drastically reduced. The resultsshow that PD-1 expression is specifically induced at the stagespreceding clonal selection.     

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.     

Requirement of IL-5 for induction of autoimmune hemolytic anemia in anti-red blood cell autoantibody transgenic mice

IL-5, IL-10 and lipopolysaccharide (LPS) are known to activateB-1 cells in vivo in normal mice and anti-red blood cell autoantibodytransgenic mice (HL mice). To assess the exact role of IL-5in proliferation and activation of peritoneal B-1 cells, weanalyzed IL-5 receptor chain-deficient HL (IL-5R^–/–x HL) mice generated by the cross between IL-5R^–/–and HL mice. In IL-5R^–/– x HL mice, Ig-producingB-1 cells in the peritoneal cavity were negligible, althoughthe total number of B-1 cells in the peritoneal cavity wereas many as 30% of that in HL mice. Moreover, LPS- or IL-10-induceddifferentiation of B-1 cells into antibody-producing cells wasseverely impaired in IL-5R^–/– x HL mice. We alsoused in vivo 5-bromo-2'-deoxyuridine labeling to estimate theproliferation of B-1 cells in IL-5R^–/– mice. Theabsence of IL-5R did not affect spontaneous proliferation ofperitoneal B-1 cells. However, induced proliferation of peritorealB-1 cells by oral administration of LPS was markedly impairedin IL-5R^–/– mice. These results suggest that IL-5is required for activation-associated proliferation of B-1 cellsbut not for their spontaneous proliferation and support theidea that IL-5 plays an important role on the induction of autoantibodyproduction from B-1 cells.     

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.     

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.     

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.     

CD4 , CD8 {gamma}/{delta} cells from normal mice respond to a syngeneic B cell lymphoma and can induce its differentiation

Lymph nodes and spleens from normal unimmunized mice containsmall numbers of CD3⁺, CD4^–, CD8^– (double negative,DN) T cells. Of these, approximately one-third express the markerLy-5(8220) in a form previously seen only on normal B cellsand a population of DN T cells found in mice genetically proneto develop autolmmunity. DN T cells proliferate when co-culturedwith a syngeneic surface Ig⁺ lymphoma, CH12. After one cycleof stimulation with CH12 almost all of the responding CD3⁺ DNcells express Ly-5(B220), suggesting that it is an activationmarker for some DN T cells. The CH12 responding population alsocontains cells with two other phenotypes, Thy-1⁺, CD4^–,CD8^–, Ly-5(B220)⁺, sIgM^–, CD3^– and Thy-i⁺,CD4⁺, CD8^–, Ly-5(B220)^–, sIgM^–, CD3⁺. TheLy-5(B220)⁺, CD3^– population is no longer found afterrepeated stimulation. While the relationship between these threepopulations is unknown, DN I cells can proliferate in the absenceof CD4⁺ or CD8⁺ cells and therefore their proliferation is notdependent on the presence of other T cells or lymphokines producedby CD4⁺ or CD8⁺ T cells. Anti-CD3 Immunoprecipitation of CH12-respondlngcells reveals at least seven different receptor proteins ofwhich five can also be precipitated with an anti-(C1/C2) monoclonalantibody. Thus at least three different TCR– heterodimersare expressed by CH12-responding T cells. The Thy-1⁺, CD4^–,CD8^–, Ly-5(B220)⁺ cells can provide help to CH12 cellsfor Ig secretion even in the absence of the nominal antigenfor the B lymphoma cells, in summary, these results demonstratethat in normal mice there is a small population of CD4^–,CD8^–, Ly-5(B220)⁺ T cells with / receptors which can providehelp for a syngeneic B cell lymphoma. Received 9 May 1989, accepted 31 May 1989.     

Over-expression of CD3{varepsilon} transgenes blocks T lymphocyte development

We have reported previously that mice carrying >30 copiesof the human CD3 transgene completely lose their T lymphocytesand NK cells (36). Here we demonstrate by immunohistology thatin the most severely immunodeficient mouse, tg26, the thymusis very small, has sizeable vacuoles and does not contain recognizableT lymphocytes except for a small percentage of Thy- 1⁺ cellsand B cells. Cell surface phenotyping and TCR and -ßrearrangement studies confirm that the arrest in T lymphocytedevelopment precedes the arrest in rag-1^null, rag-2^null andTCRß^null mice. Since the T cell progenitors in whichthe arrest occurred were absent in the transgenic mice, indirectapproaches were taken to examine the causes of the block inT cell development. Analyses of 12 independently establishedmutant mouse lines, generated with five different transgenicconstructs, revealed that the severity of the abrogation inT cell development was dependent on the number of copies oftransgenes. Since the number of transgene copies generally correlatedwith the levels of expression of the transgenic CD3 proteins,we concluded that over-expression of the CD3 protein was thelikely cause of the block in T lymphocyte development. The Tcell immunodeficiency was caused by either the human or themurine CD3 protein. Since transgene coded mRNAs were found insignificantly higher quantities than endogenous CD3 mRNAs infetal thymi on days 13 and 14 of gestation, over-expressiontook place very early in development, probably prematurely.Over-expression of the CD3 transgene in thymocyte precursorsmay therefore affect T lymphocyte development in the absenceof TCR and possibly in the absence of the other CD3 proteins.More importantly, over-expression of the CD3 protein in thymocytesof mice with a low copy number of transgenes had a significanteffect on late thymic development Over-expression of the CD3protein in immature thymocytes mimicked the effects caused byexposure of CD4^–; CD8^– thymocytes to anti-CD3 treatment:apoptosis and lack of TCRß expression. We thereforespeculate that in the homozygous tg26 animals the arrest inT cell development was caused by excessive signal transductionevents rather than by a toxic effect of the transgenic protein.     

Emigration of selected subsets of {gamma}{delta}+ T cells from the adult murine thymus

Cells bearing the form of the TCR make up only 1–3% ofT cells in the adult murine thymus and peripheral lymphold organs.Evidence from studies of nude mice suggests that the developmentof at least some T cells is thymus dependent; however, untilnow it has not been directly demonstrated that cells are exportedfrom the thymus. In this paper we have used the technique oflabelling thymocytes in vivo with FITC, followed by flow cytometrlcanalysis to trace cells emigrating from the thymus to the spleen.Using this approach we have been able to demonstrate for thefirst time that T cells are exported from the adult murinethymus to the spleen. We also demonstrate that the cells emigratingto the spleen are a selected subset of thymocytes being heatstable antigen positive, Thy-1⁺, and expressing low levels ofCD44 (Pgp-1). In addition, investigation of TCR V; gene usageamong adult ⁺ thymocytes, recent emigrants, and spleen cells,indicated a selective emigration of cells expressing certainVgenes.     

CD4+Thy1- thymocytes with a Th-type 2 cytokine response

We have identified a small subset of CD3⁺, CD4⁺, CD8^–thymocytes that do not express Thy1 (CD90). This Thy1^–subset represents 1–3.7% of the total number of thymocytesin a naive mouse. CD4⁺Thy1^– thymocytes express high levelsof CD3, intermediate to high levels of heat-stable antigen (HSA),and low levels of CD25, CD45RB, CD69, CD44 and CD62L. They producehigh titers of IL-4 and no IFN- upon stimulation in vitro, aresponse characteristic of T_h2 cells. In the thymi of mice infectedneonatally with a high dose of the retrovirus Cas-Br-E MuLV,the frequency of CD4⁺Thy1^– cells increased ~10-fold. High-dosevirus infection resulted in decreased HSA and increased CD44expression on CD4⁺Thy1^– cells relative to cells from naivemice. CD4⁺Thy1^– cells from high-dose infected mice alsosecreted IL-4 and not IFN- upon in vitro stimulation. We previouslyreported that infection of newborn mice with a high dose ofmurine retrovirus results in the induction of a non-protectiveanti-viral T_h2 T cell response; CD4⁺Thy1^– thymocytes witha T_h2-like cytokine profile may play a role in determining thecytokine bias of this anti-viral response.