Structure/function analysis of interleukin-2-toxin (DAB486-IL-2). Fragment B sequences required for the delivery of fragment A to the cytosol of target cells

We have used cassette and deletion mutagenesis to analyze the structural features of fragment B-related sequences in the fusion toxin DAB486-IL-2 (where IL-2 represents interleukin-2) that are necessary for the efficient delivery of fragment A to the cytosol of target cells. We demonstrate that whereas an intact disulfide bond between Cys461 and Cys471 may be required for the cytotoxic action of native diphtheria toxin, this bond is not required for the cytotoxic action of DAB486-IL-2. The in-frame deletion of the 97 amino acids from Thr387 to His485 of DAB486-IL-2 increases both the potency and the apparent dissociation constant (Kd) of the resulting fusion toxin for high affinity interleukin-2 receptor-bearing target cells. In contrast, the inframe deletion of either the 191 amino acids between Asp291 and Gly483 or the 85 amino acids between Asn204 and Ile290 results in a 1000-fold loss in potency. These regions contain the putative membrane-spanning regions and the amphipathic membrane surface-associating regions of fragment B, respectively. These results indicate that the efficient delivery of the ADP-ribosyltransferase from DAB486-IL-2 to the cytosol requires the membrane-associating domains of fragment B. This function has been postulated to play a role in the diphtherial intoxication of eukaryotic cells. However, unlike native diphtheria toxin, fragment B sequences distal to Thr387 do not enhance the potency of DAB486-IL-2.     

Protein engineering of diphtheria-toxin-related interleukin-2 fusion toxins to increase cytotoxic potency for high-affinity IL-2-receptor-bearing target cells

We have used site-directed insertion and point mutagenesis in an attempt to increase the cytotoxic potency and receptor-binding affinity of the diphtheria-toxin-related interleukin-2 (IL-2) fusion toxins. Previous studies have demonstrated that both the DAB486-IL-2 and DAB389-IL-2 forms of the fusion toxin consist of three functional domains: the N-terminal fragment-A-associated ADP-ribosyltransferase, the hydrophobic-membrane-associating domains, and the C-terminal receptor-binding domain of human IL-2. By insertion mutagenesis we have increased the apparent flexibility of the polypeptide chain between the membrane-associating domains and the receptor-binding domain of this fusion toxin. In comparison to DAB486-IL-2, the cytotoxic potency of the insertion mutants was increased by approximately 17-fold for high-affinity IL-2-receptor-bearing cell lines in vitro. Moreover, competitive displacement experiments using [125I]rIL-2 demonstrate that the increase in cytotoxic potency correlates with an increase in receptor-binding affinity for both the high and intermediate forms of the IL-2 receptor.     

Cellular processing of the interleukin-2 fusion toxin DAB486-IL-2 and efficient delivery of diphtheria fragment A to the cytosol of target cells requires Arg194

We have used site-directed mutagenesis to examine the role played by Arg191, Arg193, and Arg194 of the fusion toxin DAB486-IL-2 in the intoxication of high affinity interleukin-2 receptor-bearing T-lymphocytes. These arginine residues are positioned in the proteolytically sensitive 14-amino acid loop subtended by the disulfide bond between Cys187 and Cys202 in this fusion toxin. DAB486-IL-2 was formed by the genetic substitution of the native diphtheria toxin receptor binding domain with human interleukin-2 (Williams, D.P., Parker, K., Bacha, P., Bishai, W., Borowski, M., Genbauffe, F., Strom, T.B., and Murphy, J.R. (1987) Protein Eng. 1, 493-498). We demonstrate that substitution of Arg194 with Gly results in a 1000-fold loss of DAB486-IL-2 potency. Since trypsin "nicking" of the Gly194 mutant restores biologic activity, we conclude that Arg194 is required for the cellular processing of the fusion toxin which results in the release of fragment A into the cytosol.     

IL-4 inhibits IL-2 receptor expression and IL-2-dependent proliferation of human T cells

Recent studies have shown that IL-4 can affect lymphocyte responses to IL-2. To evaluate the effects of IL-4 on T cell responses to physiologically relevant stimuli, we studied normal human T cells cultured with a low concentration of anti-CD3 mAb and IL-2 in the presence and absence of added IL-4. The addition of IL-4 to cultures of T cells stimulated with anti-CD3 mAb and IL-2 reduced the proliferative response by 49 to 59%. The inhibitory effect was observed in 3-, 5-, and 7-day cultures. Inhibition was dose-dependent with maximal inhibition at concentrations greater than or equal to 5 to 10 U/ml IL-4. IL-4-mediated inhibition occurred early during the T cell response, inasmuch as addition of IL-4 after stimulation for 24 h did not result in significant inhibition. Phenotypic analyses of cells cultured in the presence of anti-CD3 mAb, IL-2, and IL-4 suggested that the mechanism of regulation by IL-4 involves the inhibition of IL-2R expression. The proportion of both CD4+ and CD8+ cells that expressed IL-2R in response to IL-2 was diminished in the presence of IL-4, although HLA-DR levels were unaffected. Soluble IL-2R was also reduced in supernatants of cultures stimulated with anti-CD3 mAb, IL-2, and IL-4 as compared to cultures stimulated with anti-CD3 mAb and IL-2. These findings indicate that when normal human T cells are stimulated in vitro in a manner that approximates a physiologic interaction with Ag in vivo, rIL-4 provides a potent inhibitory signal to IL-2 responsive cells that is likely mediated by IL-4-induced inhibition of IL-2R expression.     

Activated T cells and monocytes have characteristic patterns of class II antigen expression

The expression of human histocompatibility class II Ag was measured on activated T cells and monocytes by quantitative mAb binding in direct two-color immunofluorescence. Monocytes activated by IFN-gamma bound an average of 2 x 10(6) DR-specific mAb, 3 x 10(5) DQ-specific mAb, and 7 x 10(5) DP-specific mAb per cell. For T cells activated by anti-CD3, a subpopulation bound 1 x 10(5) DR-specific mAb, 5 x 10(4) DQ-specific mAb and 5 x 10(4) DP-specific mAb per cell. These measurements were obtained after establishing a base line of class II Ag expression on resting B cells and monocytes. Resting B cells and those monocytes that were positive for class II Ag bound identical amounts of mAb; 3 x 10(4) DR-specific mAb, 3 x 10(3) DQ-specific mAb and 2 x 10(4) DP-specific mAb. However, most resting monocytes (75%) expressed only DR Ag. In the process of studying the expression of class II Ag on T cells, it was necessary to define and analyze the activated T cell state. Cell cultures activated with 0.3 ng/ml anti-CD3 had the highest expression of class II Ag on T cells, whereas those activated with 3.0 ng/ml anti-CD3 had the highest expression of IL-2R on T cells. Addition of IL-2 had no further effect on DR Ag expression on T cells but did up-regulate IL-2R expression. Reducing the initial monocyte concentration before activating T cells increased class II Ag expression on T cells without affecting IL-2R expression. The results obtained on T cell activation suggest that perhaps a lymphokine may be made by CD3-activated T cells which induces class II Ag expression on T cells.     

Engagement of CD14 on human monocytes terminates T cell proliferation by delivering a negative signal to T cells.

We have recently shown that engagement of the human monocytic Ag CD14 by murine mAb induces lymphocyte function-associated antigen-1/intercellular adhesion molecule-1-dependent homotypic adhesion. To determine whether CD14 plays a role in monocyte-T cell interactions, we tested the effect of anti-CD14 mAb on the proliferation of human T cells. Our results show that anti-CD14 mAb strongly inhibited T cell proliferation induced by Ag, anti-CD3 mAb, and mitogenic lectins. Inhibition by anti-CD14 mAb was epitope-dependent and required physical contact between monocytes and T cells. CD14 engagement did not affect IL-2R expression or IL-2 synthesis but induced a state of unresponsiveness that was not IL-2 specific; proliferation of anti-CD3-activated T cell blasts in response to both IL-2 and IL-4 was abrogated by addition of monocytes preincubated with anti-CD14 mAb. Inhibition of T cell proliferation after engagement of CD14 on monocytes was likely to result from delivery of a negative signal to T cells, rather than from disruption of a costimulatory monocyte-derived signal, because incubation of monocytes with anti-CD14 mAb also inhibited monocyte-independent T cell proliferation induced by PMA and ionophore. These results, together, point to a role of CD14 in the monocyte-dependent regulation of T cell proliferation.     

Anti-inflammatory action of IL-4. Negative regulation of contact sensitivity to trinitrochlorobenzene.

We examined the effects of IL-4, a cytokine produced by Th2 cells, on the development of an Ag-specific, T cell-mediated inflammatory response in a hapten-induced model of contact sensitivity (CS). Intravenous administration of IL-4 was ineffective in modulating the development of CS when administered on days 0, 1, and 2 after sensitization with the hapten trinitrochlorobenzene. In contrast, such treatment significantly reduced the response when given on the day of challenge. Conversely, treatment with anti-IL-4 mAb on day 4 markedly increased the magnitude of CS but was without effect when administered on days 0, 1, and 2. These results suggest that IL-4 interferes with CS at the efferent but not the afferent limb of the response. IL-4 had no inhibitory effect on the ability of immune lymph node cells to transfer adoptively CS or their proliferation upon restimulation with hapten. However, the expression of CS by immune cells was severely curtailed in mice treated with IL-4 prior to immune cell transfer. Furthermore, IL-4 inhibited monokine (gamma-IFN inducible protein [IP-10] and TNF-alpha) expression in macrophages induced by treatment with culture supernatants from the Ag-stimulated immune lymph node cells. These results indicate that suppression of Ag-specific inflammatory CS response by IL-4 may be mediated at least in part through inhibition of cytokine production by mononuclear phagocytes infiltrating the site.     

Differential CD3/T cell antigen receptor-mediated IL-2 production in jurkat T cells. Dissociation of IL-2 response from total inositol phosphate and calcium responses

We used three anti-human anti-CD3 mAb each recognizing different surface CD3 epitopes to differentially perturb the CD3/TCR complex on the surface of Jurkat T cells. In the presence of phorbol ester, these anti-CD3 mAb triggered differential IL-2 production in Jurkat T cells, which could not be explained by differences in kinetics of IL-2 production, by differences in IL-2 adsorption caused by differential surface expression of p55 or p75 IL-2R, by effects on IL-2 secretion rather than actual synthesis, or by differential toxicities of the anti-CD3 mAb to Jurkat cells. In addition, this differential anti-CD3-induced IL-2 production could not be explained by differences in mAb isotype or in avidities of the anti-CD3 mAb for the Jurkat cells. Moreover, anti-CD3 mAb covalently immobilized onto beads also differentially induced IL-2 production in Jurkat cells, suggesting that the differential IL-2 response is not based on differential rates of anti-CD3-induced modulation of Jurkat cell surface CD3. Although differences among the anti-CD3 mAb in the initial rates of binding to Jurkat cell were observed, this was also believed unlikely to explain the differential IL-2 response. Regardless of the anti-CD3 mAb used, anti-CD3-induced total inositol phosphate (IP) production did not necessarily correlate with anti-CD3-induced IL-2 production. Nevertheless, despite the differences among the anti-CD3 mAb in inducing IL-2 production, the calcium responses were grossly similar. Taken together, these observations indicate that CD3/TCR-mediated IL-2 production in Jurkat cells can be dissociated from total IP generation, and the basis of differential CD3/TCR-mediated IL-2 production in these cells does not appear to be at the level of the initial activation-induced calcium response. These studies suggest that the nature of the CD3/TCR ligand (its physical form and/or the specific epitope it perturbs) can either directly influence intracellular events distal to the generation of IP and increase in intracellular free calcium leading to differential IL-2 production or can trigger IP-independent pathways that affect IL-2 production.     

Stimulation via the CD3 and CD28 molecules induces responsiveness to IL-4 in CD4+CD29+CD45R- memory T lymphocytes

Although both IL-2 and IL-4 can promote the growth of activated T cells, IL-4 appears to selectively promote the growth of those helper/inducer and cytolytic T cells which have been activated via their CD3/TCR complex. The present study examines the participation of CD28 and certain other T cell-surface molecules in inducing T cell responsiveness to IL-4. Purified small high density T cells were cultured in the absence of accessory cells with various soluble anti-human T cell mAb with or without soluble anti-CD3 mAb and their responsiveness to IL-4 was studied. None of the soluble anti-T cell mAb alone was able to induce T cell proliferation in response to IL-4. A combination of soluble anti-CD3 with anti-CD28 mAb but not with mAb directed at the CD2, CD5, CD7, CD11a/CD18, or class I MHC molecules induced T cell proliferation in response to IL-4. Anti-CD2 and anti-CD5 mAb enhanced and anti-CD18 mAb inhibited this anti-CD3 + anti-CD28 mAb-induced T cell response to IL-4. In addition, anti-CD2 in combination with anti-CD3 and anti-CD28 mAb induced modest levels of T cell proliferation even in the absence of exogenous cytokines. IL-1, IL-6, and TNF were each unable to replace either anti-CD3 or anti-CD28 mAb in the induction of T cell responsiveness to IL-4, but both IL-1 and TNF enhanced this response. The anti-CD3 + anti-CD28 mAb-induced response to IL-4 was exhibited only by cells within the CD4+CD29+CD45R- memory T subpopulation, and not by CD8+ or CD4+CD45R+ naive T cells. When individually cross-linked with goat anti-mouse IgG antibody immobilized on plastic surface, only anti-CD3 and anti-CD28 mAb were able to induce T cell proliferation. These results indicate that the CD3 and CD28 molecules play a crucial role in inducing T cell responsiveness to IL-4 and that the CD2, CD5, and CD11a/CD18 molecules influence this process.     

Triggering of co-mitogenic signals in T cell proliferation by anti-LFA-1 (CD18, CD11a), LFA-3, and CD7 monoclonal antibodies

Proliferative T cell responses were elicited in a comitogenic assay when purified mAb against CD 18, CD11a, LFA-3, and CD7 were immobilized onto solid plastic surfaces together with submitogenic doses of mAb against the CD3 complex. The proliferative response was associated to the production of IL-2 and to the expression of IL-2R. We explored the possibility that a second signal provided by either PMA or a Ca2+ ionofore could replace the anti-CD3 mAb in the comitogenic assay. Interestingly, our data clearly indicate that PMA but not the ionofore was capable of mediating the co-mitogenic effect in conjunction with solid-bound mAb (CDw18, CD11a, LFA-3, and CD7). We also demonstrate that the mAb (anti-CD4 and anti-CD2) which have been previously described as co-mitogenic in combination with anti-CD3 are capable of eliciting this activating signal in the presence of PMA. These data indicate that mAb to certain cell surface differentiation Ag that in soluble form inhibit T cell function such as LFA-1, LFA-3, and CD2 can under appropriate conditions induce co-mitogenic signals on T cells. Our results support the hypothesis that several cell surface differentiation Ag may participate in conjunction with the T3-Ti complex in the transmembrane signal transduction leading to T cell activation.     

Role of the LFA3-CD2 interaction in human specific B cell differentiation

We examined the role of the lymphocyte function-associated (LFA)3 molecule in human B cell response. A mAb to this molecule did not influence B cell proliferation induced by anti-mu antibody and IL. In contrast, the same mAb inhibited the specific T-dependent B cell response induced by a particulate Ag. In the same line, two anti-CD2 mAb (directed toward the T11-1 and T11-2 epitopes) inhibited this response, whether used alone or in association. These inhibitions took place at an early stage of the response, and anti-LFA3 and anti-CD2 mAb acted on B cells and T cells, respectively. In contrast, when T cell help was provided by exogenous IL-2, the B cell response was resistant to the inhibitory effect of anti-LFA3 mAb. Taken together, these results indicate that the LFA3-CD2 pair play a major role in the direct T-B interaction required for T cell help.     

Cooperation between an anti-T cell (anti-CD28) monoclonal antibody and monocyte-produced IL-6 in the induction of T cell responsiveness to IL-2

CD28 is an Ag of 44-kDa Mr that is expressed on the membrane of the majority of human T cells and that is recognized by mAb 9.3. The functional effects of mAb 9.3 on peripheral blood T cells were studied. mAb 9.3 was not mitogenic, unless it was combined with PMA. When CD28 was cross-linked after binding of mAb 9.3 to the T cell by immobilized or soluble anti-mouse IgG, T cells proliferated in response to rIL-2, provided that monocytes were also present. The additional signal required for IL-2 responsiveness after cross-linking of CD28 could also be delivered in cultures of purified T cells by a cellfree monocyte culture supernatant. Expression of IL-2R on about 10% of the T cells was demonstrated by staining with an anti-IL-2R mAb, and was found to be largely restricted to CD4+ cells. The active compound responsible for the helper signal in the monocyte culture supernatant was identified as IL-6 because purified IL-6 (but not IL-1 beta) had similar activity and because an antiserum to IL-6 (but not an antiserum to IL-1 beta) neutralized the activity of the monocyte supernatant and blocked T cell proliferation. An anti-IL-2R antibody also completely inhibited T cell proliferation induced by the combination of mAb 9.3, IL-2, and IL-6. Our results provide evidence that cross-linking of CD28 induces functional IL-2R and that this activity is dependent on a helper signal provided by monocytes, more specifically IL-6. Moreover, our results indicate that IL-6 (previously called B cell stimulatory factor-2) is active on T cells. If a natural ligand for CD28 can be identified, the mechanism of induction of IL-2 responsiveness described here might explain how T cells become nonspecifically involved in an ongoing cellular immune reaction.     

Differential activation requirements for virgin and memory T cells

Most studies of the activation requirements for T cells have used either T cell lines or populations of normal T cells that consist of a mixture of virgin and Ag-primed T cells. These two subpopulations of T cells can now be distinguished in humans by their reactivity with mAb. The anti-CD45R antibody HB10 identifies virgin T cells (T degrees) that are non-reactive to recall Ag and relatively poor at providing help for B cell differentiation. Conversely, memory T cells (T') that can react to recall Ag and enhance Ig production are non-reactive with anti-CD45R, but can be identified with the UCHL1 antibody. We have used these antibodies to separate the T degrees and T' populations and examine their activation requirements. On activation CD45R+ cells rapidly began to lose the CD45R Ag and express the UCHL1 Ag in increased amounts, whereas the UCHL1+ cells retained this phenotype. Both populations responded to PHA in the presence of monocytes, but when triggered by an antibody to CD3 only the T' cells were induced to express IL-2R, produce IL-2, and to proliferate. The T degrees population of cells remained relatively quiescent by all of these parameters. However, anti-CD3 stimulation conditioned the T degrees cells for IL-2 responsiveness, inasmuch as the addition of rIL-2 resulted in significant IL-2R expression and proliferation. When the CD4+ T degrees and CD4+ T' subpopulations were isolated and examined in the same assays similar results were obtained. The data indicate that fundamental differences exist in the triggering requirements for T degrees and T' cells.     

The 2H4 (CD45R) antigen is selectively decreased in multiple sclerosis lesions

To analyze expression of the 2H4 (CD45R) Ag on inflammatory cells in the central nervous system immune response, immunohistochemical staining with a panel of anti-T cell mAb was performed on central nervous system tissues from 12 patients with multiple sclerosis (MS) and 8 patients with viral encephalitis. Only rare cells were stained with anti-2H4 in MS plaques, plaque edges, and adjacent white matter, whereas 2H4+ cells were more numerous in viral encephalitis (p less than 0.001). By contrast, no quantitative differences were found between MS plaque edges and viral encephalitis with anti-4B4 (helper-inducer function associated), anti-CD4, anti-CD3, and anti-IL-2R mAb, although there were fewer CD8+ cells in MS (p less than 0.01). These data indicate that the 2H4 Ag is selectively decreased and, because it is associated with suppressor-inducer function of CD4+ cells, that there may be a defect in the down-regulation of the in situ immune response in MS.     

Activation requirements of newborn thymic gamma delta T cells.

We have analyzed the requirements for the induction of proliferative responses by thymic CD4-CD8- gamma delta T cells. Enriched populations of CD4-CD8- thymocytes from newborn mice, purified by negative selection with anti-CD4, anti-CD8, and anti-TCR alpha beta mAbs were found to contain approximately 20% gamma delta T cells that were p55IL-2R-. When these cells were cultured with a panel of lymphokines (IL-1, -2, -4, and -7), a small response was observed to some of the cytokines tested individually; however, combinations of certain lymphokines (IL-1 + 2, IL-1 + 7, and IL-2 + 7) were found to induce significant proliferation and the selective outgrowth (75-90%) of gamma delta T cells. These cells were IL-2R+, remained CD4-, yet expressed variable levels of CD8. A limited analysis with specific anti-V gamma and V delta mAb suggested that there had not been a selective expansion of preexisting V gamma 2, V gamma 3, or V delta 4 populations in response to the stimulatory lymphokine combinations. Thymic CD4-CD8- gamma delta T cells were unresponsive to stimulation with immobilized anti-pan gamma delta mAb alone. However, in the presence of immobilized anti-pan gamma delta mAb and IL-1, IL-2, or IL-7, but not IL-4, a vigorous proliferative response was observed. Phenotypic analysis showed that 80 to 95% of the proliferating cells were polyclonally expanded gamma delta T cells, expressed the p55IL-2R, and the majority remained CD4-CD8-. Blocking studies with anti-IL-2R mAb showed that stimulation with anti-pan gamma delta + IL-1, but not anti-pan gamma delta + IL-7 was dependent on endogenously produced IL-2. Collectively, these studies suggest that the activation requirements of newborn thymic gamma delta T cells differ markedly from alpha beta T cells in that gamma delta T cells 1) respond to combinations of cytokines in the absence of TCR cross-linking, 2) can respond to TCR cross-linking in the presence of exogenous cytokines, 3) but are unable to activate endogenous cytokine production solely in the presence of TCR cross-linking.     

Comitogenic effect of solid-phase immobilized anti-1F7 on human CD4 T cell activation via CD3 and CD2 pathways

We have recently developed a mAb, anti-1F7, which defines a family of structures found to include the molecule recognized by anti-Ta1 (CD26). In this paper, we demonstrated that binding of 1F7 by solid-phase immobilized anti-1F7 mAb but not anti-Ta1 mAb has a comitogenic effect by inducing proliferation of human CD4+ T lymphocytes in conjunction with submitogenic doses of anti-CD3 or anti-CD2. The proliferative response induced via the CD3-1F7 or CD2-1F7 pathways is associated with the IL-2 autocrine pathway, including IL-2 production. IL-2R expression and anti-IL-2R (Tac) inhibition. Furthermore, solid-phase immobilization of anti-1F7 but not anti-Ta1 acts in conjunction with submitogenic doses of PMA to mediate a comitogenic effect in the absence of anti-CD3 or anti-CD2, leading to CD4+ T cell proliferation. PMA treatment, in the meantime, leads to enhanced expression of 1F7 on the T cell surface. Despite its functional association with both pathways of activation, however, the 1F7 structure is not comodulated with the CD3/TCR complex nor the CD2 molecule. These findings thus suggest that the CD26 Ag is involved in CD3 and CD2-induced human CD4+ T cell activation.     

IL-6 is an accessory signal in the alternative CD2-mediated pathway of T cell activation

Recent studies have demonstrated that IL-1 and IL-6 are synergistic accessory signals for activation of T cells. In this study, highly purified human T cells were cultured with either a stimulating pair of anti-CD2 mAb or with immobilized anti-CD3 mAb. Monocytes, a cellfree monocyte culture supernatant or IL-1 were required for anti-CD2-stimulated T cell proliferation, and they each strongly enhanced anti-CD3-induced T cell growth. IL-6 was synergistic with IL-1 as a helper factor for T cell growth after activation via CD2, but we could not demonstrate any effect of IL-6 in the CD3 pathway. The mechanism of the synergistic helper activity of IL-1 and IL-6 on T cell activation in the CD2 pathway was further examined. IL-1 (but not IL-6) was required for induction of IL-2 production. Both IL-1 and IL-6 enhanced IL-2R (p55) expression and the proliferative response to IL-2. T cell proliferation after stimulation with anti-CD2 and IL-1 or IL-1/IL-6 proceeded through an autocrine IL-2-dependent pathway. Moreover we found that, in the absence of IL-1, IL-6 still supported a transient and limited proliferation of anti-CD2- (but not of anti-CD3-) stimulated T cells, which apparently was independent of the autocrine growth factors IL-2 or IL-4. Our data suggest that IL-6 is important as an accessory signal for T cell growth in the CD2 pathway of T cell activation.     

Role of a thymic stromal cell clone in inducing the stage-specific differentiation of various subpopulations of double negative thymocytes

The monolayer of a thymic stromal cell clone termed MRL104.8a induced the differentiation of adult double negative (DN) thymocytes (CD3-4-8-) through a CD3-4-8+ intermediate into CD3- (or dull) 4+8+ stages. DN thymocytes were separated into three subpopulations depending on their cell-surface expression of Pgp-1 and IL-2R, namely, Pgp-1+IL-2R-, Pgp-1-IL-2R+, and Pgp-1-IL-2R-. The present study investigated the requirements of the MRL104.8a monolayer for inducing the differentiation of these DN thymocyte subpopulations. The following were revealed: i) the MRL104.8a monolayer failed to induce the differentiation of a Pgp-1+IL-2R- subpopulation; ii) whereas a Pgp-1-IL-2R+ subpopulation did not express either CD4 or CD8 Ag when cultured in medium, culturing this subpopulation on the thymic stromal cell monolayers resulted in the expression of CD8 but not CD4 Ag; and iii) a Pgp-1-IL-2R- DN subpopulation obtained through less extensive treatments with anti-CD4 and anti-CD8 antibodies in the presence of C before sorting procedures spontaneously differentiated into double positive cells in medium. In contrast, most of DN cells with the same phenotype obtained through extensive anti-CD4 and -CD8 treatments before sorting failed to express CD4 and/or CD8 Ag in medium but could differentiate through a CD3-4-8+ into more mature stages only when they were cultured on the thymic stromal monolayer. These results indicate differential requirements of thymic stromal cells for the differentiation of various DN subpopulations with qualitatively distinct phenotypes and different magnitudes (very low vs almost zero levels) of CD4/CD8 expression.