T cell-derived IL-3 induces the production of IL-4 by non-B, non-T cells to amplify the Th2-cytokine response to a non-parasite antigen in Schistosoma mansoni-infected mice.

We describe a novel amplification mechanism underlying the increased early IL-4 production observed in Schistosoma mansoni-infected mice in response to a non-parasite Ag, sperm whale myoglobin (SwMb). Earlier studies have shown that splenic Fc epsilon R+ non-B, non-T (NBNT) cells from schistosome-infected mice secrete IL-4 after stimulation with parasite Ag. We now demonstrate that purified NBNT cells from SwMb-immunized S. mansoni-infected mice do not respond directly to SwMb, but produce IL-4 in response to IL-3. Accordingly, we show that the early SwMb-specific IL-4 response of spleen cells (SC) from immunized infected mice is dependent on IL-3 and on CD4+ T cells. Thus, most of the early SwMb-induced IL-4 from SC of infected mice appears to be produced by NBNT cells triggered by IL-3 synthesized by SwMb-specific CD4+ T cells. IL-3-induced IL-4 production was also observed in purified NBNT cells from immunized uninfected mice, but the frequency and/or IL-4-producing capacity of splenic IL-3-responsive cells was found to be 8 to 16 times higher in immunized infected animals. IL-4 production by purified CD4+ cells from immunized infected mice was also seen after SwMb stimulation, but this response showed slower kinetics than those of total SC, was IL-3-independent, and on average threefold greater than that by CD4+ cells from immunized uninfected controls. Thus, increased SwMb-induced IL-4 production in immunized S. mansoni-infected mice results from direct synthesis by CD4+ T cells, as well as their stimulation via IL-3 of an expanded population of NBNT cells. The latter pathway may serve as an amplification loop for Th2-cytokine responses.

Molecular area involved in the in-vitro dimerization of the murine p55 IL-2 receptor.

In order to study structure-function relationships of the M(r) 55,000 subunit of the murine IL-2R (p55 IL-2R) by epitope mapping, we have expressed the p55 IL-2R molecule in a cell-free translation system. Under these in vitro conditions, we detected the expected p55 IL-2R polypeptide initiated at Met 1 and, in addition, two internally initiated molecules at Met 64 and Met 105. In this report we describe that from such a mixture, containing three molecular species of p55 IL-2R, mAb 135D5 immunoprecipitated the polypeptide initiated at Met 105 although this N-terminally truncated form of p55 IL-2R does not contain its epitope located between amino acids 72-88. This observation can be taken as a further evidence for the formation of p55 IL-2R dimers. Finally, we identified the region implicated in the formation of p55 IL-2R dimers close to the transmembrane region of the molecule.

IL-4 plays a dominant role in the differential development of Tho into Th1 and Th2 cells.

We have analyzed the evolution of the pattern of lymphokine secretion by Th cell lines specific for either the synthetic terpolymer Glu60Ala30Tyr10 (GAT) or killed bacillus Calmette Guérin. When cultured in the presence of exogenous rIL-2 as a growth factor, GAT-specific Th cell lines secreted mainly IL-4, whereas bacillus Calmette Guérin-specific lines produced predominantly IL-2. However, culturing in the presence of rIL-4 or of anti-IL-4 mAb and rIL-2 led to the establishment of Th2-like and Th1-like lines, respectively, regardless of their Ag specificity. Inasmuch as we show that the proliferative response of mature Th1 and Th2 cells was identical in the presence of IL-4, these results indicate that IL-4 influences the development of Th cell subsets. To understand the mode of IL-4 action, we isolated immature GAT-specific Tho clones able to secrete IL-2 and IL-4. Two types of Tho cells were isolated: ThoA cells that secreted IL-2 and IL-4, but not IFN-gamma, and ThoB cells that secreted IL-2, IL-4, and IFN-gamma. We show for the first time that such cells are indeed Th precursors able to differentiate into Th1 or Th2 cells. We demonstrate that IL-4 positively and negatively controls the differentiation of Tho cells into Th2 and Th1 cells, respectively. When cultured in rIL-4, Tho cells stop secreting IL-2 and IFN-gamma, but maintain IL-4 secretion. Moreover, endogenous IL-4 produced by Tho cells has similar effects: when cultured in rIL-2 alone, Tho cells either keep their immature phenotype or become Th2 cells, but do not become Th1 cells. In contrast, neutralization of secreted IL-4 completely prevents the differentiation of Tho into Th2 cells, but permits the development of Th1 cells. The presence of exogenous IFN-gamma does not affect the development of Tho into Th1 and Th2 cells, because it does not modify either mode of IL-4 action. However, it influences the ratio between the two types of Tho cells: when IL-4 is neutralized, added IFN-gamma can induce IFN-gamma secretion by ThoA cells and thereby facilitate their passage into ThoB cells. Taken together, our results demonstrate that IL-4, in addition to mediating T cell growth, is a principal factor that controls the differential development of Tho cells into Th1 and Th2 cells.

Interleukin-1 and interleukin-6 synergize in preparing resting murine B cells to respond to anti-mu: correlation with c-myc expression.

We demonstrate that stimulation with interleukin (IL)-1 and IL-6 prepares high-density B cells to enter the S phase more promptly in response to subsequent stimulation with anti-mu F(ab')2. The stimulatory effect of IL-1 and IL-6 is compared to the one described for IL-4. In contrast to IL-4, preculture in IL-1 and IL-6 does not induce an increase in cell volume or in expression of class II major histocompatibility complex antigens on resting B cells. Similarly, the expression of the p55 subunit of the IL-2 receptor and of the transferrin receptor was not detected on resting B cells stimulated with IL-1 and IL-6. However, the stimulatory effect of IL-1 and IL-6 is correlated with an increased expression of c-myc proto-oncogene mRNA in resting murine B cells.

Immunochemical characterization of antigenic domains on human IL-2: spatially distinct epitopes are associated with binding to the p55 and p70 subunits of IL-2 receptor.

We have isolated and characterized 8 mAb against human rIL-2. All recognize nonglycosylated rIL-2 in liquid phase with similar affinities (Kd approximately 1 nM). Based on the epitopes of the IL-2 molecule that they recognize and their pattern of reactivity against glycosylated and non-glycosylated IL-2, they have been classified into four groups. The first group of anti-IL-2 mAb (2C4, 19B11 and 12C2) inhibits IL-2 binding to p70 IL-2R, while the second one (16F11, 18E1 and 2A4) prevents its binding to p55 IL-2R. These two groups neutralize IL-2 activity in a T cell proliferation assay equally well, due to their similar inhibition of IL-2 binding to high affinity IL-2R. Two mAb, 3H9 and 17F4, recognize separate epitopes on IL-2 molecule, are poor inhibitors of IL-2 binding, and they are inefficient in the neutralization of its biological activity; they have been assigned to the third and fourth groups, respectively. These results show that mAb from the first and second group recognize two epitopes of the human IL-2 molecule which probably overlap the p70 IL-2R and p55 IL-2R binding sites, respectively. In addition, these areas together form the high affinity IL-2R binding site. The two mAb from the third and fourth group recognized epitopes of IL-2 not directly involved in IL-2 binding to its receptor. All eight mAb anti-human IL-2 recognize murine IL-2 and with the exception of one, 17F4 mAb are also able to neutralize it in a T cell proliferation assay. The relationship between the structure and the function of the IL-2 molecule is discussed.

Structure-function study of the p55 subunit of murine IL-2 receptor by epitope mapping.

Using a cell-free translation system we have expressed the Mr 55,000 subunit of the murine IL-2R (p55 IL-2R), which binds IL-2 with low affinity (Kd = 10 nM). Mutants and truncated forms of p55 IL-2R have been used to map the epitopes recognized by three anti-p55 IL-2R mAb: 135D5, 7D4, and 2E4. The mAb 135D5 inhibits IL-2 binding to p55 IL-2R and recognizes an epitope located between amino acids 64 to 125. This epitope can be mimicked by a synthetic peptide corresponding to the region defined by residues 72 to 88. However, the mAb 7D4 and 2E4 do not affect the IL-2 binding to p55 IL-2R. These mAb recognize an epitope of p55 IL-2R lying between residues 125 to 212 that can be mimicked with a peptide corresponding to amino acids 188 to 208. A strong correlation emerged between the experimental results on epitope mapping and predictions of potential antigenicity of murine p55 IL-2R. In addition, we described two internal initiation sites of p55 IL-2R mRNA under the in vitro conditions used leading to the production of significant amounts of N-terminal truncated p55 IL-2R proteins.

Induction of mouse p55 interleukin-2 receptor gene expression by IL-2 and IL-4 and characterization of its transcription initiation sites.

Two murine T cell lines (C30.1 and Line 1) were used to study the expression of the p55 interleukin-2 receptor gene. C30.1 is an IL-2-dependent T cell line that can be stimulated for a short period of time by IL-4. Line 1 cells are propagated in IL-4 but they also proliferate in response to IL-2. In both cell lines stimulation by IL-2 leads to a strong induction of p55 IL-2 receptor mRNA while stimulation by IL-4 leads only to a very moderate increase in expression of this mRNA. The induction of p55 IL-2 receptor mRNA by IL-4 is comparable to that of beta-actin mRNA. These data confirm that IL-2 upregulates p55 IL-2 receptor gene expression while IL-4, which also activates T cells, does not lead to specific induction of this gene. We have also determined the transcription initiation sites utilized by the p55 IL-2 receptor gene in C30.1 and Line 1 cells. Seven sites were identified, one of which predominates. Resting cells, or cells stimulated with IL-2 or IL-4, display the same pattern of transcription site utilization.

IL-2-dependent proliferation of murine T cells requires expression of both the p55 and p70 subunits of the IL-2 receptor.

An IL-4-dependent T cell clone (LD8) was isolated from the murine IL-2-dependent cytotoxic T cell line C30.1. This clone has lost the capacity to proliferate in response to IL-2 after long-term culture in IL-4. LD8 cells express the p70, but not the p55, subunit of the IL-2R on their cell surface. The number of p70 IL-2R molecules on LD8 cells is comparable with the number of high-affinity IL-2R on the parental C30.1 cell line. LD8 cells can efficiently internalize IL-2 through the p70 IL-2R subunit. Following stimulation by IL-2, LD8 cells up-regulate p70 IL-2R mRNA, but do not express p55 IL-2R mRNA. IL-2-dependent proliferation of LD8 cells was reconstituted after introduction and expression of a human p55 IL-2R cDNA. To further investigate the role of p70 IL-2R, we have measured IL-2-induced proliferation of C30.1 cells in the presence of three anti-p55 IL-2R mAb (5A2, PC61, and 7D4) that recognize different epitopes. Under the experimental conditions used, the combination of anti-p55 IL-2R mAb prevents the formation of high-affinity IL-2R, but does not affect the binding of IL-2 to p70 IL-2R or IL-2 internalization. However, these three mAb inhibit proliferation of C30.1 cells even in the presence of IL-2 concentrations sufficient to saturate p70 IL-2R. Together these results demonstrate that p70 IL-2R alone is not sufficient to transmit IL-2-induced growth signals and that formation of p55-p70 IL-2R complex is required for IL-2-dependent proliferation of murine T cells.

Immunoactive products of human placenta (III): Characterization of an inhibitor affecting lymphocyte proliferation.

We have investigated the effects of supernatants from human placenta explant cultures on lymphokine dependent T cell proliferation using mainly the CTLL-2 reference murine cell line. A profound, dose dependent, inhibition of both IL-2 and IL-4-dependent cell proliferation was observed. In addition, supernatants from human placental cultures inhibited B cell proliferation, IL-5-driven proliferation of B13 cells, and IL-6-induced proliferation of 7TD.1. Conversely, the supernatants from human placental cultures enhance the growth of human embryonic fibroblasts. Characterization of the material by HPLC yielded a 68-70 kDa peak at pH 7.4, but the peak activity was at a smaller molecular weight (20-25 kDa) if pH 2.9 acetic acid, KC1 buffer was used. The same fractions were inhibitory for IL-2 and IL-4 driven proliferation of CTLL-2 cells. We conclude that the substances tested are acting as a general growth inhibitor for lymphocytes.

Activation by IL-2, but not IL-4, up-regulates the expression of the p55 subunit of the IL-2 receptor on IL-2- and IL-4-dependent T cell lines.

We have investigated the effects of IL-2 and IL-4 on different parameters of T cell activation using three T cell lines. The Th cell line L14 and the cytotoxic T cell line C30.1, both grown in IL-2-containing medium, and a line derived from C30.1 cells (line 1) cultured in IL-4 for a prolonged period were studied. All three cell lines could be activated with IL-2 or IL-4. T cell stimulation by either IL-2- or IL-4-induced identical patterns of cell size enlargement and transferrin receptor expression. However, only IL-2 up-regulated cell-surface expression of the p55 subunit of the IL-2R (p55 IL-2R) as measured by flow cytometry and RIA. This difference was also reflected by the accumulation of soluble p55 IL-2R in the culture medium. No significant increase in expression of membrane or soluble forms of p55 IL-2R was detected after IL-4 stimulation. mAb specific for p55 IL-2R which block IL-2-induced T cell growth did not affect IL-4-mediated T cell proliferation indicating that p55 IL-2R is not involved in IL-4-mediated T cell growth. Analysis of IL-4R expression performed on line 1 using biotinylated IL-4 revealed that IL-4, but not IL-2, is capable of increasing IL-4R expression. Together these results suggest that during IL-2- or IL-4-induced T cell proliferation, each lymphokine specifically up-regulates its own receptor.

IL-4, but not IL-5, can act synergistically with B cell activating factor (BCAF) to induce proliferation of resting B cells.

B cell activating factor (BCAF) was initially identified in the supernatant of the murine T helper cell clone 52-3 (52-3 SN) because of its ability to promote activation and proliferation of resting B cells in the absence of any other costimulus. In this paper, we show that 52-3 T helper cells also secrete IL-4 and IL-5 and we have analyzed the influence of these two lymphokines on B cell proliferation induced by BCAF-containing 52-3 SN. Using the neutralizing anti-IL-4 monoclonal antibody 11B11, we observed partial inhibition of B cell proliferation. 52-3 SN free of IL-4 prepared using an immunoabsorbent column was still able to induce significant B cell proliferation. Although recombinant IL-4 alone does not induce B cell proliferation, it increased the proliferation induced by IL-4-free 52-3 SN. Kinetic studies showed that IL-4 is required at the start of B cell cultures in order to exert optimal synergistic effects. In contrast, anti-IL-5 monoclonal antibody NC17 did not affect the B cell proliferative activity of 52-3 SN whether or not IL-4 was present. When 52-3 SN was tested on dextran-sulfate-activated B cells, IL-5 and BCAF activities were detected but only the IL-5 activity was neutralized by monoclonal antibody NC17. These results demonstrate that (i) BCAF-containing SN can induce proliferation of resting B cells independently of IL-4 and IL-5, and (ii) IL-4, but not IL-5, can act synergistically with BCAF to induce B cell proliferation.

Loss of antigen recognition and impaired cytolytic function in most hybrids between cytotoxic T cells and BW5147.

In this paper we demonstrate that the generation of cytotoxic T-cell hybridomas (CTH) that retain classically H-2 restricted and antigen-specific lytic activity is not generally feasible by fusion of cytotoxic T cells (CTL) with the AKR thymoma BW5147. However, CTH that express a nonspecific lytic activity are readily generated, as revealed by lectin-dependent assays. We analyse several such hybridomas for the nature of their lytic activity and for the expression of various function-associated T-cell molecules. We show that the lytic activity retained by CTH is atypical in that only P815 mastocytoma cells, and no other tumour targets, are lysed in the presence of phytohaemagglutinin (PHA). However, in other respects this lytic activity resembles that of normal CTL: it requires cellular contact, results in a reduction of the viability of the target cells, and is sensitive to both EDTA and low temperature. Lytic CTH express low amounts of T-cell antigen receptor (TCR), whereas non-lytic CTH have no detectable TCR on their surface. Most CTH, lytic or non-lytic, fail to express Lyt 2. We conclude that the loss of antigen specificity in CTH is due to reduced expression of T-cell antigen receptor as well as of other functionally relevant molecules. We further conclude from this work that a search for a better fusion partner may be indicated to facilitate the reliable production of cytotoxic T-cell hybridomas.

Involvement of the T cell antigen receptor and of Lyt-2 in the cytotoxic function of aged killer (AK) T cells.

Aged killer (AK) T cells are antigen-independent, IL-2-requiring variants of antigen-dependent CTL clones that have lost their original antigen specificity and have acquired, instead, specific cytotoxicity for P815 target cells. In this report we study whether AK cells use a similar or a different target cell recognition system than that of bona fide CTL. To this end, we selected from a cloned AK line variants that are partially or completely deficient in specific target recognition and/or in cytotoxic function, and analyzed these variants for expression of the T cell antigen receptor and of Lyt-2. Variants were selected from the prototype AK line (Cl 96) with specific, as well as lectin-facilitated, cytotoxicity for P815 tumor cells. Variants could be grouped into four types with increasing degrees of functional deficiency, which correlated with loss of T cell receptor and/or loss of Lyt-2. In short, loss of Lyt-2 was reflected in loss of specific target recognition, and loss of the T cell antigen receptor was reflected in loss of all cytotoxic activity. We conclude from these results that both Lyt-2 and the T cell antigen receptor are required for specific target cell recognition and the T cell antigen receptor is, in addition, required for cytotoxic function. Moreover, since AK cells express a somatically acquired specificity that differs from that of their clonal precursors, it appears that cytotoxic T cells may change their antigen receptor from one specificity to another during tissue culture.

Hapten-specific cytotoxic T cell clones undergo somatic variation of their antigen recognition specificity.

Two experimental systems have demonstrated somatic variation of antigen recognition specificity of long-term cytotoxic T cell (CTL) clones. System 1 used CTL clone BT7.4.1 with strict specificity for Kb/TNP, which had been continuously cultured for 15 months in the presence of H-2b/TNP stimulator cells and interleukin 2. Upon removal of the TNP antigen from the cultures, 99% of the clone cells within about 10 cell divisions lost their ability to grow in the presence of antigen and interleukin 2 (lethal variants). Of the surviving 1%, about 60% retained the ability to lyse target cells in the presence of lectins but only 12% could be considered as "wild type" BT7.4.1 cells, i.e. they still specifically lysed H-2b/TNP-bearing target cells. The majority of the growing cells, thus, had to be considered as specificity loss variants. Several specificity loss variants were established in culture and were shown to express membrane-bound T cell "receptor" heterodimer similar to their TNP-specific ancestor, BT7.4.1. Principally the same types of variants were generated in cultures growing in the presence of TNP antigen, although in quantitatively reduced numbers. Under these conditions the specific stimulator cells appeared to impose a significant selective advantage for "wild type" CTL since even after 15 months the cultures fully retained their specificity for the nominal antigen. In system 2, the development of cytolytic fine specificity of a panel of 42 individual Kb/TNP-specific CTL clones was followed over a period of 8 months of in vitro culture. At the beginning of the test, 37 of these clones exhibited significant cross-reactivity for lysis of H-2k/TNP target cells. This number of cross-reactive clones continuously diminished with time and dropped to only 4 clones after 8 months in culture. All 42 clones retained their original Kb/TNP specificity and after losing their reactivity for H-2k/TNP usually showed no decrease but rather an increase in their cytotoxic activity towards Kb/TNP target cells. Loss of H-2k/TNP cross-reactivity was not accompanied by loss of Lyt-2 or of LFA-1 surface antigens or by loss of sensitivity of the cytotoxicity to inhibition by anti-Lyt-2 or by anti-LFA-1 antibody. We conclude from these observations that in vitro cultivated CTL clones, at least those of C57BL/6 anti-TNP-C57BL/6 specificity, are not stable in terms of their antigen recognition specificity.(ABSTRACT TRUNCATED AT 400 WORDS)

Preliminary crystallographic study of the complex between the Fab fragment of a monoclonal anti-lysozyme antibody and its antigen.

Preliminary crystallographic data are given for the complex between the Fab fragment of a monoclonal anti-lysozyme antibody and its antigen. This crystalline complex was found by screening a number of Fab-lysozyme complexes prepared from monoclonal anti-lysozyme antibodies produced by hybrids of BALB/c immune spleen cells with a non-secreting mouse hybrid myeloma line. The complex crystallizes in the monoclinic space group P21 with a = 55.5 (+/- 0.1) A, b = 143.5 (+/- 0.3) A, c = 49.1 (+/- 0.1) A, beta = 120 degrees 20' (+/- 10'). X-ray photographs show reflections extending to a resolution of 2.7 A. The crystals are suitable for high-resolution X-ray diffraction studies.