Delineation of chicken thymocytes by CD3-TCR complex, CD4 and CD8 antigen expression reveals phylogenically conserved and novel thymocyte subsets.

To further define the relationship between thymocyte subsets and their developmental sequence, multi-parameter flow cytometry was used to determine the distribution of the CD3-TCR complex and the accessory molecules CD4 and CD8 on chicken thymocytes. As in mammals, adult thymocytes could be subdivided into CD3-, CD3lo, and CD3hi staining populations. CD4 and CD8 distribution on such populations revealed the presence of CD3-CD4+CD8- and CD3-CD4-CD8+ thymocytes, putative precursors to CD4+CD8+ cells, detectable in the adult and at high frequency during ontogeny. Of particular interest was the existence of CD3lo expression on CD4+CD8- and CD4-CD8+, and in some instances, on CD4-CD8- thymocytes. Such phenotypes are not easily detectable in the mammalian thymus but were readily observed in both adult and embryonic chicken thymus from 16 days of embryogenesis. Further analysis of the TCR lineage of these CD3lo cells revealed that they were essentially all of the alpha beta TCR type. Mature CD3hi thymocytes were found within the CD4+CD8+ and CD4+CD8- and CD4-CD8+ subsets. Both alpha beta and gamma delta TCR lineage thymocytes were detected within all CD4- and CD8-defined subsets, thus identifying novel thymocyte subsets in the chicken thymus, namely alpha beta TCR+CD4-CD8- and gamma delta TCR+ CD4+CD8- cells. Hence, this analysis of chicken thymocytes, while confirming the phylogenically conserved nature of the thymus, has revealed novel T cell subsets, providing further insight into the complexity of mainstream thymocyte maturation pathways.     

A novel CD3-J11d+ subset of CD4+CD8- cells repopulating thymus in radiation bone marrow chimeras

Sequential appearance of T cell subpopulations occurs in the thymus of irradiated AKR (H-2k, Thy-1.1) mice at an early stage after transplantation with bone marrow cells of C3H/HeN (H-2k, Thy-1.2) mice. The donor-derived thymocytes were first detected on day 8 after bone marrow reconstitution. Although most of the thymocytes were CD4-CD8- cells, an appreciable level of CD4+CD8- cells was detected in the thymus at this stage. The early appearing CD4+CD8- cells were a novel subset of thymocytes that were J11d+CD3-. From day 10 to day 21 the proportion of CD4+CD8-CD3-J11d+ cells decreased while the proportion of CD4+CD8+ cells and CD4+CD8-CD3+J11d- cells increased. The CD4+CD8-CD3- cells seem to diversify to form CD4+CD8+ thymocytes after short-term culture in vitro. These results suggested the existence of a differential pathway from CD4-CD8- cells to CD4+CD8+ cells via CD4+CD8- cells in thymus.     

CD4+CD8+ thymocytes develop into CD4 or CD8 single-positive cells in athymic nude mice

A differentiation pathway from CD4+CD8+ cells to CD4+CD8- or CD4-CD8+ cells was investigated in athymic nude mice. Using fluorescence-activated cell sorter, CD4+CD8+ cells were sorted out from AKR thymocytes (H-2k, Thy-1.1) stained with two monoclonal antibodies against CD4 and CD8 (anti-L3T4 and anti-Ly-2). These CD4+CD8+ AKR thymocytes were injected i.v. into CBA or C3H nude mice (H-2k, Thy-1.2) which had received 650 rads and had been reconstituted with syngeneic nude bone marrow cells. The lymph node cells of the nude recipients at 4 wks post-thymocyte transfer were shown to contain 50% AKR-derived Thy-1.1+ cells. The majority of the Thy-1.1+ cells were found to express either CD4 or CD8 alone but not to express both CD4 and CD8. These findings indicate that CD4+CD8+ thymocytes can develop into CD4+CD8- and CD4-CD8+ single-positive cells in extrathymic tissues.     

Characterization of immature CD4+CD8-CD3- thymocytes.

Previously we have described (Hugo, P. et al., Int. Immunol. 1990. 2: 209) an immature CD4+CD8-CD3- thymocyte subset which is thought to be the counterpart of the CD4-CD8+CD3- subset. In this study we show that the ontogeny of these two subsets is parallel in fetal thymic organ culture. Extensive phenotypic characterization of CD4+CD8-CD3- cells reveals that they closely resemble CD4-CD8+CD3- thymocytes being: HSAhigh, Thy-1high, interleukin 2 receptor alpha chain negative, CD44-, H-2K+/-, CD5low, MEL-14low/intermediate, CD2+, LFA-1+ and MTS 35+. Finally, we show that the proportion of CD4+CD8-CD3- thymocytes is highly variable between mouse strains.     

CD4+CD8+CD3high thymocytes appear transiently during ontogeny: evidence from phenotypic and functional studies.

During T cell development thymocyte subsets emerge in a defined order, reflective of their maturational stage. In this study we determined the timing of appearance of CD4+CD8+CD3high thymocytes during in vivo and in vitro embryonic development, and thymic reconstitution after cortisone treatment. In these models, CD4+CD8+CD3high cells followed CD4+CD8+CD3low and preceded mature CD4+CD8-CD3high/CD4-CD8+CD3high thymocytes, while cortisone resistance was first seen among CD4+CD8+CD3high cells. CD4+CD8+CD3high thymocytes were also shown to display a pattern of antigen receptor-mediated calcium influx intermediate between that induced in other CD4+CD8+ cells and mature thymocytes. These results are consistent with a precursor-progeny relationship between CD4+CD8+CD3low and CD4+CD8+CD3high thymocytes, the latter developing to mature thymocytes (Hugo, P. et al., Int. Immunol. 1991. 3: 265).     

The organotin-induced thymus atrophy, characterized by depletion of CD4+ CD8+ thymocytes, is preceded by a reduction of the immature CD4- CD8+ TcR alpha beta-/low CD2high thymoblast subset.

Thymic changes in the rat induced by the thymus atrophy-inducing organotin compound di-n-butyltin dichloride (DBTC) were examined using FACS analyses. The number of CD4+CD8+ thymocytes was reduced by DBTC treatment from Day 2 onwards and reached minimum level on Days 4 and 5 after dosing. On these days the CD4-CD8- and both the CD4-CD8+ and CD4+CD8- subsets were not affected. On Day 2 we observed a reduced proportion of transferrin receptor (CD71)-positive CD4-OX44- cells, representing the cycling immature CD4-CD8+ cells, and of CD71+OX44- cells, representing the cycling CD4+CD8+ cells, but not of CD71+CD4-CD8- cells. When compared to controls, the FSChigh cell population of DBTC-treated rats contained less CD4-OX44- and OX44- cells, which were further characterized as CD2high and T-cell receptor (TcR)alpha beta- low. Moreover, fewer TcR alpha beta high cells were detected in the OX44- thymoblast subset of DBTC-treated rats. The number of CD4-CD8- thymoblasts appeared marginally decreased while the numbers of CD4+OX44+ cells, representing mature CD4+ cells, were not affected. These data indicate that DBTC causes a preferential initial depletion of immature CD4-CD8+CD2high TcR alpha beta-low thymoblasts. This initial event may result in a decreased formation of CD4+CD8+ thymoblasts and of small CD4+CD8+ thymocytes. These characteristics of the initially depleted subset indicate a specific anti-proliferative effect of DBTC and may give clues for the mechanism involved in the induction of thymus atrophy.     

'Radioresistant' CD4-CD8- intrathymic T cell precursors differentiate into mature CD4+CD8- and CD4-CD8+ T cells. Development of 'radioresistant' CD4-CD8- intrathymic T cell precursors

Using lectin (PNA) and monoclonal antibodies for Pgp-1, IL-2R, H-2k, CD3, and F23.1 (T cell receptor V beta 8), we characterized the 'radioresistant' CD4-CD8- double negative thymocytes at an early stage after 800 rad irradiation. Most of the CD4-CD8- cells on day 8 after irradiation expressed a high level of Thy-1, H-2k, and PNA, while a small proportion of these cells were CD3+ and/or F23.1+. The appearance of Pgp-1 and IL-2R on the 'radioresistant' double negative precursors was also sequentially examined from day 5 to day 9 after irradiation. The double negative thymocytes at day 5 expressed the highest level of Pgp-1 antigens and these cells gradually decreased in number from day 7 to day 9. By contrast, IL-2R was transiently expressed on the double negative cells on the day 7 and 8 after irradiation. These results indicate that progression of thymocyte development occurred within the CD4-CD8- thymocytes after irradiation. We further examined the homing ability of the double negative 'radioresistant' intrathymic T cell precursors to the periphery by intrathymic cell transplantation method. The double negative thymocytes proliferate and differentiate into CD4+CD8+ cells and CD4+CD8- cells but few CD4-CD8+ cells in the thymus, while only CD4-CD8+ cells were detected in the peripheral lymphoid organs 14 days after intrathymic transplantation of the double negative cells in the H-2 compatible Thy-1 congenic mice. These results suggest that the 'radioresistant' intrathymic precursors differentiate and mature in the thymus and migrate to the periphery.     

Phenotypic discrimination between thymic and extrathymic CD4-CD8- and CD4+CD8+ porcine T lymphocytes

The composition of the T lymphocyte population in swine is special in that in addition to the CD4-CD8+ subpopulations, CD4-CD8- and CD4+CD8- and CD4+CD8+ subpopulations are prominent in the peripheral circulating as well as in the resident T lymphocyte pools. Since the same phenotypes are characteristic of thymic populations, it was asked whether the unusual distribution in swine may result from an emigration of thymic precursor phenotypes to the periphery. This explanation was refuted, as all thymic subpopulations were found to express CD1, albeit with differences in antigen density, whereas all extrathymic subpopulations lack CD1. The cellular distribution of CD2 in swine is without precedent among all species studied. Whereas in sheep and cattle the extrathymic CD4-CD8- subpopulation is known to entirely lack CD2 and to have a low propensity for homing to lymphoid tissues, the CD4-CD8- subpopulation in swine splits into CD2+ and CD2- subsets, both of which do reside in lymphoid tissues. While CD2+CD4-CD8- T lymphocytes are rare in the circulating pool, this subset accumulates in spleen and lymph nodes. This may indicate a role for CD2 in homing. Thus the species swine is immunologically unique, not only because of having CD1-CD2+CD4+CD8+ T lymphocytes in the periphery, but also with regard to subdivision and homing behavior of its CD4-CD8- T lymphocyte subpopulation.     

Ontogeny of a novel CD4+CD8-CD3- thymocyte subpopulation: a comparison with CD4- CD8+ CD3- thymocytes

We have studied the ontogeny of a novel thymocyte subset, CD4+CD8-CD3-. Three-colour flow cytometric analysis demonstrated that these cells constituted approximately 1% of the total thymocyte content in adult CBA mice, and were not present in lymph nodes. They were mainly blastic, cortisone-sensitive, and localized in the outer thymic cortex. During foetal life they were first observed at day 15 and reached a maximum (6%) at day 17, beyond which they decreased to the adult level. This kinetic profile was similar to that of the CD4-CD8+CD3- subpopulation, except that the CD4+CD8-CD3- cells appeared slightly earlier and their percentage was lower. Both these populations appeared after the CD4-CD8-CD3- cells but before the CD4+CD8+CD3- cells. Similar observations were made during thymic reconstitution following dexamethasone treatment. In this case, both CD4+CD8-CD3- and CD4-CD8+CD3- thymocytes disappeared 48 h after the treatment. While their absolute number increased up to 14 days post-treatment, their percentage was maximal at day 7 post-treatment and returned to normal values by day 10 post-treatment. These results argue strongly that not only the CD4-CD8+CD3- population but also the CD4+CD8-CD3- population can be considered an intermediate precursor in CBA thymuses.     

Analysis of clones derived from human CD7+CD4-CD8-CD3- thymocytes.

The differentiation of human thymocyte precursors was studied by analysis of clonal progeny of CD4-CD8-CD3- (triple negative or TN) thymocytes. Using a culture system of phytohemagglutinin, IL-2, and irradiated allogeneic lymphoid feeder cells, we found that 48% of clones (104 total) derived from TN thymocyte suspensions were TCR gamma delta cells, 12% of clones were TCR alpha beta cells, and 34% were CD16+CD3- cells. Importantly, 6% of clones were novel subsets of CD4+CD8-CD3- or CD4-CD8+CD3- thymocytes. The majority of TCR alpha beta, TCR gamma delta, and CD16+CD3- clones expressed low levels of CD4. Molecular analysis of freshly isolated TN- thymocytes prior to in vitro culture demonstrated that up to 40% of cells had TCR gamma, delta, and beta gene rearrangements, but were negative in indirect immunofluorescence assays for cytoplasmic TCR delta and beta. These data provide evidence at the clonal level for the presence of precursors of the TCR alpha beta and TCR gamma delta lineages in the human TN thymocyte pool. Moreover, a substantial proportion of freshly isolated human TN thymocytes had already undergone TCR gene rearrangement prior to in vitro culture. Whether these precursors of the TCR alpha beta and TCR gamma delta lineages mature from cells already containing TCR gene rearrangements into sTCR+ cells or differentiate in vitro from cells with TCR genes in germline configuration remains to be determined. Nonetheless, these data demonstrate that the predominant clone types that grow out of human TN thymocytes in vitro are TCR gamma delta and NK cells.     

Presence of CD4 and CD8 determinants on CD4-CD8- murine thymocytes: passive acquisition of CD8 accessory molecules

In the present study we have examined the possibility that CD4 and CD8 accessory molecules can be passively acquired by thymocytes. We initially observed that most thymocytes contained within the CD4-CD8- subset actually possess low levels of CD4 and CD8 on their cell surface. However, the detection of CD4 and CD8 on CD4-CD8- cells was dependent on the presence of other CD4+/CD8+ thymocytes which were actively synthesizing CD4 and CD8. These initial findings suggested that the appearance of CD4/CD8 on "double-negative" thymocytes was due to the passive acquisition of these accessory molecules from CD4+/CD8+ cells present within the thymus. To investigate this possibility directly, we made both in vivo and in vitro mixes of thymocytes possessing different alleles of CD8 (Ly-2.1 and Ly-2.2). Under these experimental conditions, we detected Ly-2.2 on the surface of thymocytes that were genetically Ly-2.1+ and incapable of synthesizing Ly-2.2. These data indicate that thymocytes can express cell surface CD8 molecules which they have not produced but have acquired from other cells in their environment. Thus, the present study indicates that low-level surface expression of cell surface CD4/CD8 differentiation molecules does not necessarily identify distinct thymocyte subpopulations.     

CD4+CD8+ thymocytes are susceptible to DNA fragmentation induced by phorbol ester, calcium ionophore and anti-CD3 antibody

Stimulation of murine thymocytes with phorbol ester or calcium ionophore for 18-24 h resulted in 70%-80% fragmentation of DNA into 180-200-bp multiples, followed by cell death. Experiments with fractionated subpopulations by panning or flow cytometry revealed that DNA fragmentation was selectively observed in CD4+CD8+ cells and in a portion of CD4-CD8+ cells. To investigate whether DNA cleavage is also inducible via antigen-specific receptors, thymocytes were incubated in wells precoated with anti-CD3 antibody. An approximately 20% increase of DNA fragmentation was constantly observed when unseparated thymocytes were stimulated with anti-CD3 antibody. In this anti-CD3-induced DNA degradation, CD4+CD8+ cells are probably the target cells, since (a) fetal thymocytes at day 18 of gestation were found vulnerable to anti-CD3-induced DNA cleavage and (b) flow cytometry analysis of viable cells recovered after cultivation in the anti-CD3-coated wells revealed that CD4+CD8+ cells were preferentially decreased. Further experiments with purified CD4+CD8+ cells, however, could not define a clear-cut increase of DNA fragmentation when isolated CD4+CD8+ cells were stimulated with anti-CD3 antibody. Addition of interleukin (IL) 1, IL 2, IL 3, IL 4 or interferon-gamma to the CD4+CD8+ cell cultures failed to yield a DNA cleavage similar to that of unseparated thymocytes.     

Relationships between 2H4 (CD45RA) and UCHL1 (CD45RO) expression by normal blood CD4+CD8-, CD4-CD8+, CD4-CD8dim+, CD3+CD4-CD8- and CD3-CD4-CD8- lymphocytes.

We characterized and established relationships between the expression of membrane 2H4 (CD45RA) and UCHL1 (CD45RO) by enriched lymphocyte fractions prepared by selective immunomagnetic depletion of monoclonal antibody-defined populations. Cell fractions analysed in this study could be divided into two broad groups according to the presence (CD3+CD4+CD8-, CD3+CD4-CD8+, CD3+CD4-CD8dim+ and CD3+CD4-CD8-) or absence (CD3-CD4-CD8dim+ and CD3-CD4-CD8-) of the CD3 antigen. Preliminary studies confirmed a reciprocal relationship for CD45RA and CD45RO expression by major lymphoid components and further showed that the level or intensity of membrane 2H4 staining (2H4+, 2H4int and 2H4-) could be directly related to UCHL1 expression. As a reflection of their differential functions, the various CD3+ populations examined showed much greater heterogeneity in 2H4 and UCHL1 expression. CD3+CD4+CD8- cells generally showed significant proportions of 2H4+, 2H4int and 2H4- components, whereas the CD3+CD4-CD8+ population was characterized by a predominance of 2H4+ cells. The results of this current investigation further suggested a higher proportion of dual-positive (2H4+UCHL1+) cells and a much greater degree of inter-individual variation than previously suspected. In contrast to CD3+ lymphocytes, natural killer (NK) associated CD3-CD4-CD8dim+ and CD3-CD4-CD8- populations were mostly 2H4+ with only minor 2H4int components and very low expression of UCHL1. An additional observation of note was that the proportions of 2H4+ and 2H4- cells comprising the CD4+CD8- fraction in any given individual was highly correlated (P = 0.002) with the distributions of 2H4+ and 2H4- components within the CD4-CD8+ fraction. This suggests the possible existence of a common control mechanism for the acquisition of immunological memory by distinct lymphocyte populations and further indicates that individual variations in the distribution of 2H4/UCHL1 lymphocyte subpopulations may be a direct consequence of 'immunological experience' rather than age alone.     

Timing of deletion of autoreactive V{beta}6+ cells and down-modulation of either CD4 or CD8 on phenotypically distinct CD4+8+ subsets of thymocytes expressing intermediate or high levels of T cell receptor

In this paper we describe a differentiation sequence amongst adult murine thymocytes which goes from CD4+8+3lo(low) to CD4+8+3int(intermediate) to CD4+8+3hi(high) and then to mature single positive CD3hi thymocytes. Phenotypic characterization of CD4+8+3int/hi cells for a number of other surface markers is consistent with them being in transition from CD4+8+3lo phenotype to mature phenotype. The same observation was made for sensitivity towards ionomycin-mediated apoptosis. In the thymus of Mls-1a mice, where autoreactive TCR-V beta 6+ cells are negatively selected, deletion of TCR-V beta 6+ cells was first detected in the CD4+8+3int subset, and was complete by the CD4+8+3hi stage, suggesting that up-regulation of the TCR/CD3 complex is required for deletion of Mls-1a autoreactive thymocytes. No sign of apoptosis was detected among any fresh thymocyte subsets suggesting that apoptotic cells are rapidly cleared from the thymus. The CD4+8+3int/CD4+8+3hi cells are therefore populations in transit from the typical cortical thymocytes to the mature T-cells.     

Ontogeny of T cell maturation in LEC mutant rats which bear a congenital arrest of maturation from CD4+CD8+ to CD4+CD8- thymocytes.

LEC rats bear a congenital deficiency in CD4+CD8- thymocytes and peripheral CD4+ T cells, and consequently a deficiency in Th cell functions. Ontogeny of T cell maturation in normal and LEC mutant rats was, therefore, investigated. Prenatal development of thymocytes in normal rat strains, with respect to the expression of CD4/CD8 and TcR antigens, was similar to that of mice except that its kinetics was delayed by approximately 24 h. The kinetics of T cell maturation in LEC rats was comparable with that of normal rats up to day 19 of gestation, at which stage double-negative thymocytes (CD4-CD8-) developed into double positives (CD4+CD8+) through immature CD4-CD8+ subset. At day 19 of gestation in LEC as well as normal rats, double positives occupied approximately 80% of the total thymocytes, half of which were TcR-dull positive, indicating that TcR was normally rearranged and then expressed in LEC rat thymocytes. These data indicate that double negatives normally mature into at least double positives in LEC rats. Both single positives appeared after day 19 of gestation in normal rats, while in LEC rats CD4+CD8- cells did not appear, suggesting that the deficiency in CD4+CD8- cells is due to a congenital arrest of maturation from CD4+CD8+ to CD4+CD8- cells, but not due to a postnatal deletion.     

Heterogeneity within medullary-type TCRalphabeta(+)CD3(+)CD4(-)CD8(+) thymocytes in normal mouse thymus

The functional maturation process of medullary-type CD4(-)CD8(+) [CD8 single-positive (SP)] thymocytes remains largely uncharacterized. We describe a phenotypic analysis of CD8 SP medullary-type thymocytes and find a remarkable heterogeneity within this thymic cell population. While mature CD8(+) T cells in the periphery are relatively homogeneous (TCRalphabeta(+)CD3(+)Qa-2(+) HSA(-)3G11(-)6C10(-)CD69(-)), CD8 SP medullary-type thymocytes contain discrete subpopulations that can be identified by differential expression of several cell-surface markers. We have identified at least six discrete subpopulations in the subset of TCRalphabeta(+)CD3(+) CD8 SP cells in the thymus. According to the expressed phenotypes, a linear developmental pathway is predicted among these CD8 SP subpopulations as follows: 6C10(+)CD69(+)HSA(hi)3G11(+)Qa-2(-) --> 6C10(-)CD69(+)HSA(hi/int)3G11(+)Qa-2(-) --> 6C10(-)CD69(-)HSA(int)3G11(+)Qa-2(-) --> 6C10(-)CD69(-)HSA(lo)3G11(+)Qa-2(-) --> 6C10(-)CD69(-)HSA(-/lo)3G11(-)Qa-2(-) --> 6C10(-)CD69(-)HSA(-/lo)3G11(-)Qa-2(+). This study provides a framework for understanding CD8 SP T cell maturation in the thymic medulla.     

The acquisition of CD4 and CD8 during the differentiation of early thymocytes in short-term culture

Subpopulations of thymocytes known to represent early stages of T cell development were isolated from the adult mouse thymus, and their ability to differentiate during short periods of culture was assessed by their acquisition of surface CD4 and CD8. Virtually all cells of the most mature of the CD4-CD8- thymocyte subpopulations (other surface markers CD3- HSA++ IL-2R-Pgp-1-) and of the immature CD4-CD8+ thymocyte subpopulation (other surface markers also CD3- HSA++ IL-2R- Pgp-1-) became CD4+CD8+ in less than 1 day of culture without added stimuli or growth factors. This suggested they had already received signals initiating CD4 and CD8 acquisition. However, stimulation of these precursor cells with phorbyl ester and ionomycin prevented this acquisition of CD4 and CD8. No distinct CD4-CD8+ intermediate was detected as the CD4-CD8- cells became CD4+CD8+ in the non-stimulated cultures, thus questioning the assumption that these three groups of cells are sequential steps in one lineage. In contrast to this pre-programmed acquisition of CD4 and CD8, the less mature CD4-CD8- IL-2R+ subpopulation did not progress to the CD4+CD8+ stage in culture, although it is able to develop further on intrathymic transfer. It is likely that this subpopulation represents a control point requiring specific differentiation signals for further development.     

Intrathyroidal lymphocyte subsets, including unusual CD4+ CD8+ cells and CD3loTCR alpha beta lo/-CD4-CD8- cells, in autoimmune thyroid disease.

Intrathyroidal lymphocyte subsets were analysed in 13 euthyroid patients with autoimmune thyroid disease by two-colour flow cytometry and compared with subsets in peripheral blood. In both Graves' and Hashimoto's diseases, proportions of intrathyroidal CD5- B cells were higher than in peripheral blood. The numbers of such cells were correlated with serum levels of anti-thyroid microsomal antibodies. Proportions of T cells bearing alpha beta chains of T cell receptors (TCR alpha beta+ T; T alpha beta) and CD16+CD57+ natural killer (NK) cells were lower in the thyroid, but proportions of CD3hiTCR alpha beta-TCR gamma delta+ (T gamma delta) cells were not different. Proportions of CD4+Leu-8- helper T cells and CD4+CD57+ germinal centre T cells were higher and proportions of CD4+Leu-8+ suppressor-inducer T cells and CD8+CD57+ or CD8+CD11b+ suppressor T cells were lower than in the blood in both diseases. Proportions of CD5+ B cells were high in Graves' disease, and proportions of CD8+CD11b- cytotoxic T cells were high in Hashimoto's disease. Unexpectedly, CD4+CD8+ cells and CD3loTCR alpha beta lo/-CD4-CD8- cells were present in thyroid tissues of both diseases. These findings suggest that: (i) an imbalance in the numbers of regulatory T cells and of NK cells that had appeared in the thyroid resulted in the proliferation of CD5- B cells, which were related to thyroid autoantibody production; (ii) CD5+ B cells and cytotoxic T cells are important for the different pathological features in Graves' and Hashimoto's diseases, respectively; and (iii) intrathyroidal CD4+CD8+ cells and CD3loTCR alpha beta lo/-CD4-CD8- cells may be related to the pathogenesis of autoimmune thyroid disease.     

Patterns of membrane TcR alpha beta and TcR gamma delta chain expression by normal blood CD4+CD8-, CD4-CD8+, CD4-CD8dim+ and CD4-CD8- lymphocytes.

Enriched CD4+CD8-/CD4-CD8-, CD4-CD8+/CD4-CD8- and CD4-CD8- cell suspensions were prepared from normal peripheral blood by selective immunomagnetic depletion of monoclonal antibody-defined lymphocyte populations. Subsequent examination of these modified cell fractions by two-colour flow cytometry provided a means of determining the expression of membrane T-cell receptor (TcR)alpha beta and TcR gamma delta chains by both major (CD4+ and CD8+) and minor (CD3+CD4-CD8dim+ and CD3+CD4-CD8-) lymphocyte subpopulations. Normal CD4+CD8- lymphocytes were almost invariably (greater than 99%) TcR alpha beta+, whereas lymphocytes expressing membrane CD8, which could be further subdivided according to differences in fluorescent staining intensity into CD3+CD4-CD8+, CD3+CD4-CD8dim+ and CD3-CD4-CD8dim+ components, were characterized by distinct differences in patterns of TcR chain expression. In contrast to CD3+CD4-CD8+ cells, which were predominantly (99%) TcR alpha beta+, CD3+CD4-CD8dim+ lymphocytes showed a significant proportion (33%) of TcR gamma delta+ cells (natural killer-associated CD3-CD4-CD8dim+ cells were uniformly TcR-). The highest proportion (62%) of TcR gamma delta+ cells was associated with the CD3+CD4-CD8- fraction, but these studies also revealed that a significant minority of this population was TcR alpha beta+. Despite some evidence for normal inter-individual variation, further analysis of membrane CD8 fluorescent intensities confirmed clear differential relationships for TcR alpha beta and TcR gamma delta chain expression.     

Spontaneous clustering of Thy-1 antigens on CD4+ CD8+ thymocytes lacking TCR engagement by MHC/peptide complexes

While much is known concerning CD4+ CD8+ thymocytes positively or negatively selected through interaction of their TCR with self peptides bound to self-MHC molecules, little is known of the majority of CD4+ CD8+ thymocytes lacking this interaction. We developed a monoclonal antibody (mAb) 1D11, the ligand of which (1D11-L) is expressed on 60-70% of CD4+ CD8+ thymocytes but not on other subsets of thymocytes and peripheral T cells. 1D11-L expression on CD4+ CD8+ thymocytes reversely correlates with their TCR engagement, in vitro and in vivo. In addition, 1D11-L+ CD4+ CD8+ thymocytes were more susceptible than 1D11-L- CD4+ CD8- thymocytes to apoptosis. We also found that T lineage cells other than CD4+ CD8+ thymocytes and a Thy-1-expressing fibroblast cell line became positive for 1D11-L by cross-linking their Thy-1 antigens with anti-Thy-1 mAb but not with their Fab fragment, suggesting that 1D11 recognizes multimerized Thy-1 antigens. Confocal laser scanning microscopy revealed that Thy-1 antigens as well as 1D11-L are clustered on some CD4+ CD8+ thymocytes but not on the other subsets of thymocytes. Taken together, we suggest that clustering of Thy-1 antigens spontaneously and specifically occurs on CD4+ CD8+ thymocytes lacking TCR engagement by MHC/peptide complexes.