Purification and characterization of a monoclonal T-cell suppressor factor specific for poly(LGlu60LAla30LTyr10)

Special regulatory T-cell review: A rose by any other name: from suppressor T cells to Tregs, approbation to unbridled enthusiasm

In the early 1970s a spate of papers by research groups around the world provided evidence for a negative regulatory role of thymus-derived lymphocytes (T cells). In 1971, Gershon and Kondo published a seminal paper in Immunology entitled 'Infectious Immunological Tolerance' indicating that such negative regulation could be a dominant effect that prevented otherwise 'helpful' T cells from mediating their function. Over the next decade, suppressor T cells, as these negative regulatory cells became known, were intensively investigated and a complex set of interacting cells and soluble factors were described as mediators in this process of immune regulation. In the early 1980s, however, biochemical and molecular experiments raised questions about the interpretation of the earlier studies, and within a few years, the term 'suppressor T cell' had all but disappeared from prominence and research on this phenomenon was held in poor esteem. While this was happening, new studies appeared suggesting that a subset of T cells played a critical role in preventing autoimmunity. These T cells, eventually dubbed 'regulatory T cells', have become a major focus of modern cellular immunological investigation, with a predominance that perhaps eclipses even that seen in the earlier period of suppressor T cell ascendancy. This brief review summarizes the rise and fall of 'suppressorology' and the possibility that Tregs are a modern rediscovery of suppressor T cells made convincing by more robust models for their study and better reagents for their identification and analysis.

Binding of the two polypeptide chains of dengue virus-induced suppressor cytokine to its receptor isolated from macrophages

Dengue type 2 virus (DV)-induced suppressor cytokine (SF) is composed of two polypeptide chains (alpha and beta) and has a receptor on macrophages (M phi), which has been purified. The present study was undertaken to study the binding of the two polypeptide chains of SF to M phi and its purified receptor (SF-R) protein. It was observed that both alpha and beta-chains of SF, purified by high performance liquid chromatography (HPLC), bound to M phi cell, but only alpha-chain bound to SF-R protein. Only H-2A positive M phi bound SF. Anti-H-2Ak mAb blocked the binding of SF to M phi but had no effect on binding of SF to SF-R. Both anti-SF-antiserum and anti-SF-R-antiserum blocked the binding of SF to M phi. The binding of the beta-chain of SF to M phi was blocked by anti-H-2Ak mAb while the anti-SF-R-antiserum blocked the binding of alpha-chain on M phi. Thus, the alpha-chain of SF binds to SF-R and the beta-chain binds to H-2A determinants on M phi.

Dengue virus-induced helper cytokine has two polypeptide chains which bear different determinants

Dengue type 2 virus (DV) induces generation of a T cell helper cytokine (HF) in mouse spleen which enhances the antigen-specific antibody plaque forming cell count in syngeneic mice. The present study was undertaken to investigate the molecular structure of HF. It was observed that the activity of HF was abrogated by treatment with reducing agents such as glutathione, ouabain or dithiothreitol (DTT) which cleave disulphide bonds, separating the polypeptide chains. The two polypeptide chains could be purified by high performance liquid chromatography of DTT treated HF. The individual chains had no helper activity, but it could be restored by mixing the two. One chain of the HF bonded to the DV-antigen coupled immunosorbent column and the other to the anti-I-Ak antibody coupled column. Thus, DV-induced HF is a disulphide bonded double chain structure, one chain having antigen and the other having I-A determinants; the presence of both chains is essential for helper activity.

Molecular genetic characterization of the mRNA coding for an inducible suppressor factor specific for L-glutamic acid60-L-alanine30-L-tyrosine10

The suppressor T-cell hybridoma 1556A2.1 can be induced by the monoclonal L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT)-specific suppressor inducer 372B3.5 and soluble GAT to synthesize a disulfide-linked heterodimeric protein (GAT-TsF2), which directly suppresses a primary in vitro immune response to GAT. Induction and synthesis of the GAT-TsF2 protein is correlated with the appearance of specific mRNA, as detected by translation in vitro in a wheat germ cell-free extract of RNA isolated at various times after induction. The mRNA coding for the polypeptide chain that bears a serologically defined I-J determinant (I-J+ chain) appeared 8 hr after induction, whereas the mRNA coding for the antigen-binding chain (AB+ chain) was not detected until 16 hr after induction. The mRNAs coding for the individual chains sedimented as different species, suggesting that the two-chain factor is the product of two genes. The AB+ chain of the 1556A2.1 GAT-TsF2 was synthesized on membrane-bound polysomes, whereas the I-J+ chain was translated on free polysomes. The AB+ chain was synthesized from two independent mRNA species sedimenting at 10 S and 28 S, whereas a single 16S mRNA encoded the I-J+ chain. The in vitro translated I-J+ chain was bound by a monoclonal antibody against the I-J+ determinant of only the appropriate H-2 haplotype. These results suggest that posttranslational modification, including glycosylation, is not required for biological activity or for expression of the I-J epitope on the GAT-TsF2 molecule.

Functional and biochemical characterization of a secreted I-J(+) suppressor factor that binds to immunoglobulin

A secreted product of a T cell leukemic cell line, LH-8, was examined for its biochemical and biological properties. The factor that we have termed Immunoglobulin-Binding T cell Suppressor Factor (IgB-TsF) was shown to be suppressive for the in vitro and in vivo humoral response to a variety (but not all) antigens tested. The cell surface phenotype of the LH-8.1 subclone was M.Ig(-), Thy-1(+), L3T4(-), Lyt-2(+), FcR(-), MAC-1(-), and H-2b(+). In addition, both the cell surface and secreted factor, IgB-TsF, of LH-8.1 expressed determinants that were recognized by anti-I-Jb mAbs but not by an anti-I-Jd monoclonal. The same factor also retained an affinity for the Fc portion of approximately 30% of randomly selected, purified mAbs. This binding could be abolished if the Fab or F(ab')2 fragments of these mAb were used, but was found to be unrelated to isotype of the respective mAbs. Using subclones that expressed quantitative differences in their ability to exert suppression as sources of biosynthetically labeled IgB-TsF, we have shown the suppressor activity correlated with a single, 28 kD protein. Furthermore, comparisons of these same subclones that differ in their suppressor activity, do not show any direct correlation of this biological activity with the expression of the previously described T cell receptor genes. It also suggests that at least some suppressor cell subsets may use the same or related family of T cell receptor genes for their recognitive stage of activation as helper and cytotoxic T cell subsets, but not for their effector stage of immunologic suppression.

Identification of Igh-C-linked determinants on suppressor T cell hybrids and factors specific for L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT)

Hyperimmunization of BALB/c mice with concanavalin A-stimulated blasts from the Ig allotype-congenic strain, C.B20, results in the production of antibodies reactive with T cells in an allotype-restricted manner. Spleen cells from these hyperimmune BALB/c mice were used to generate a panel of hybridomas that secrete monoclonal antibodies, reactive, in an allotype-restricted manner, exclusively with T cells subpopulations, and in particular, reactive with suppressor T cell hybridomas and their secreted soluble factors. Two functional classes of antibodies were identified: those that react with single polypeptide-chain suppressor T cell factors (TsF1) and the suppressor T cell hybridomas that produce such factors, and those that react with two polypeptide-chain suppressor T cell factors (TsF2) and their corresponding suppressor T cell hybridomas. These two classes of antibody were used to isolate molecules from the membranes of the respective suppressor T cell hybrids that are functionally and structurally related to the secreted suppressor T cell factors, suggesting a receptor function for these molecules.

Antigen-specific T cell suppressor factor (TsF): isolation of a cDNA clone encoding for a functional polypeptide chain of phosphorylcholine-specific TsF

A cDNA library of phosphorylcholine (PC)-specific suppressor T hybridoma, 29-C-6, was constructed. By differential colony hybridization, 68 colonies were selected which hybridized with mRNA probes of two PC-specific suppressor T hybridomas, 29-C-6 and 09-M-24-8, but not with those of BW5147. A hybridization translation assay revealed that only one combination of translation products of cDNA clones, p6-1 and p6-5, showed strong PC-T cell suppressor factor (TsF) activity. Sequence analysis showed that p6-5 contained a specific cDNA sequence of about 800 base pairs (bp) while p6-1 had a 190 bp poly(A) sequence insert. When total poly(A) + RNA of 29-C-6 was hybridized with p6-1 filter alone the recovered mRNA was capable of producing PC-TsF. However, when the total poly-(A) + RNA was hybridized with a p6-1 filter combined with a p6-5 filter, the mRNA eluted from the p6-1 filter was not able to produce PC-TsF, suggesting that the depletion of p6-5 specific mRNA from p6-1-binding poly(A) + RNA led to a complete abolishment of the capability to produce PC-TsF. Furthermore, p6-5 hybridizing mRNA could successfully restore the p6-1-binding poly(A) + RNA depleted of p6-5-specific mRNA, and translation products of both RNA mixtures showed strong PC-TsF activity. These results suggest that PC-TsF is not a single polypeptide chain, but is composed of at least two distinct polypeptide chains, and also that p6-5 contains a cDNA sequence encoding for one of the polypeptide chains composing the PC-TsF molecule.

Synthesis and turnover of the putative T-lymphocyte antigen receptor

Cells of an antigen-specific T-cell clone, A37.4, were treated with the proteolytic enzymes trypsin or pronase to remove the T-cell antigen receptor. Removal of the receptor, analysed by surface labelling and non-reduced/reduced gel electrophoresis, stimulated the cells to synthesize new protein rapidly. New membrane protein was readily detectable within 3 h after reculture, and it was able to interact with antigen-presenting cells, since the T cells could be stimulated to produce interferon. Treatment of cells with metabolic inhibitors demonstrated that there was only a small cytoplasmic pool of protein, and de novo synthesis of mRNA was necessary for quantitative replacement of the membrane protein. The protein also required glycosylation for transport and insertion into the membrane. Despite rapid resynthesis of new receptor, when surface-labelled cells were recultured either with or without antigen-presenting cells, there was not a rapid turnover of the receptor. There was also no evidence of any loss of receptor from the membrane of antigen-stimulated cells or of any shedding of receptor into the culture medium.

Functional roles of two polypeptide chains that compose an antigen-specific suppressor T cell factor

The functional roles of the two polypeptide chains that compose the T cell suppressor factor (TsF) that mediates the antigen-specific and genetically restricted suppressor function were studied by using the heavy or light chains isolated from the conventional TsF or the 11S and 13S mRNA translation products of TsF. Either the heavy or the light chain of mRNA translation products reconstitutes the active TsF that suppresses the antibody response in an antigen-specific and genetically restricted manner when it is combined with the isolated heavy or light chain from the conventional TsF. As a consequence, the antigen-binding heavy chain mediates the antigen specificity of TsF. On the other hand, the I-J-positive light chain works as an element to determine the genetic restriction specificity. Thus, the identity of the histocompatibility between the I-J haplotypes on the light chain and the responding cell is essential for the functional expression of TsF. No genetic preference, however, was observed, in the association of the heavy and light chains of TsF.

Antigen-specific suppressor T cell interactions. II. Characterization of two different types of suppressor T cell factors specific for L-glutamic acid50-L-tyrosine50 (GT) and L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT)

We have previously reported that two types of suppressor T cell factors (TsF) specific for L-glutamic acid50-L-tyrosine50 (GT) or L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) can be distinguished based upon differences in their ability to suppress responses by allogeneic mice. Injection of GAT or GT induces a suppressor T cell subset that produces an antigen-binding, I-J+, genetically unrestricted, specific suppressor factor (TsF1). Injection of this factor plus small amounts of antigen induces a second-order suppressor T cell that produces an antigen-binding, I-J+, genetically restricted, specific suppressor factor (TsF2). In this report, we demonstrate that these two factors are also biochemically distinct. Monoclonal TsF1 molecules are composed of a single polypeptide chain that bears both the antigen-binding site and I-J determinant, whereas TsF2 molecules are composed of two disulfide-linked polypeptide chains, one of which is antigen-binding and I-J-, and the other, nonantigen-binding, I-J+. The antigen-binding chain must be added at culture initiation to achieve suppression, but the I-J+ chain can be added as late as day 3 with complete suppression observed. However, isolated chains from TsF2-producing hybridomas derived from three different haplotypes were unable to suppress immune responses when chains from heterologous TsF2 were mixed. Indirect evidence is presented that suggests that this restriction is because the chains fail to interact rather than the inability of the target cells to recognize both chains.

Structural analysis of antigen-specific Ia-bearing regulatory T-cell factors: gel electrophoretic analysis of the antigen-specific augmenting T -cell factor

An antigen-specific T-cell factor (TaF) that specifically augments the antibody response was purified and biochemically analyzed by NaDodSO4/polyacrylamide gel electrophoresis and isoelectric focusing. Biosynthetically labeled TaF was separated from the Nonidet P-40 extract of T-cell hybridoma FL10, which produces a keyhole limpet hemocyanin-specific TaF, by affinity chromatography either with antigen or with monoclonal anti-I-A antibodies. The material thus obtained was composed of two different types of molecules of molecular weights of 67,000 and 33,000 under nonreducing conditions. After reduction with dithiothreitol, all the molecules migrated to the position of molecular weight 33,000. The absorption studies with immunoadsorbents of antigen and antibodies revealed that the intact TaF is a heterodimer of two discrete polypeptide chains, one carrying a determinant detectable by a monoclonal anti-Tindd directed to an Igh-I -linked allotypic structure of T cells and being associated with the antigen-binding site and the other expressing a unique determinant controlled by the I-A subregion of murine H-2 major histocompatibility complex but being different from known class II polypeptide chains. The antigen-binding polypeptide has an isoelectric point of pH 5.6, and the I-A polypeptide has an isoelectric point of pH 6.3.

Purification and characterization of an L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT)-specific suppressor factor from genetic responder mice

A hybridoma-derived, GAT-specific suppressor T cell factor (GAT-TsFR) from responder C57BL/10 mice has been purified to apparent chemical homogeneity using reversed phase HPLC techniques. 40 l of starting material yielded approximately 880 micrograms protein with a specific activity of 28.4 X 10(3) S50 U/ng protein representing a purification factor of 4.2 X 10(6). Purified GAT-TsFR is a hydrophobic protein with a minimum molecular weight of 18,000 that is capable of forming biologically active aggregates with molecular weights of 28,000, 64,000 and approximately 84,000 and has a pI of 6.4. GAT-TsFR is a glycoprotein that binds GAT and GT, but not GA, and bears determinants encoded by the I-J subregion of the H-2 complex. This GAT-TsFR derived from an H-2b responder haplotype to GAT is compared with GAT-TsF derived from the nonresponder H-2q haplotype on the basis of biochemical and some serological properties.

RNA transcripts for I-J polypeptides are apparently not encoded between the I-A and I-E subregions of the murine major histocompatibility complex

The I-J subregion of the mouse major histocompatibility complex has been reported to encode antigenic determinants expressed by suppressor T cells. Previously, cosmid clones were obtained from mouse sperm DNA that contain all of the sequences between the I-A and I-E subregions, where I-J has been mapped genetically. However, hybridization of these sequences to RNA prepared from several I-J-positive suppressor T-cell hybridomas did not reveal the presence of a transcript. In addition, no rearrangements in this DNA were detected in the suppressor T cells that we have analyzed. Our results indicate that the I-J polypeptides are not encoded between the I-A and I-E subregions of the major histocompatibility complex. We discuss several hypotheses concerning the possible location and expression of I-J genes.

Partial purification and characterization of an antigen-specific helper factor synthesized by a T-cell continuous line

Antigen-specific factors produced by the T-cell growth factor-dependent T-cell continuous line E-9M(+) were partially purified. Gel analysis of the twice-affinity-purified eluate of a poly(Tyr,Glu)-poly(DLAla)--poly(LLys) [(T,G)-A--L] column revealed the existence of iodinated bands with molecular weights of 17,000 and 15,000, in addition to a diffuse band of high molecular weight. The specific helper activity of the E-9M(+) supernatants was associated with a precipitate from 65-75% ammonium sulfate. Gel electrophoresis of either the eluate of a (T,G)-A--L column or of the 65-75% salt precipitate indicated that in both preparations two fractions contained the biological activity of the factor, one of a high (less than 67,000) molecular weight and the other of a low (15,000-17,000) one. Culture supernatants of the internally [35S]methionine-labeled E-9M(+) line were subjected to a combined purification of sequential ammonium sulfate precipitations, followed by affinity chromatography. Polyacrylamide gel patterns obtained of the eluates of the different salt precipitates demonstrated that the 65-75% ammonium sulfate precipitate contained two 35S-labeled bands with apparent molecular weights in the range of 60,000 and 15,000, similar to the activity patterns obtained by the gel electrophoresis fractionation experiments. Thus, it is suggested that a fraction of low molecular weight preserves the antigen specificity and the helper activity of the factor produced by the T-cell line.

Clonotypic structures involved in antigen-specific human T cell function. Relationship to the T3 molecular complex

Monoclonal antibodies were produced against a human cytotoxic T cell clone, CT8III (specificity: HLA-A3), with the view of defining clonally restricted (clonotypic) surface molecules involved in its antigen recognition function. Two individual antibodies, termed anti-Ti1A and anti-Ti1B, reacted exclusively with the CT8III clone when tested on a panel of 80 additional clones from the same donor, resting or activated T cells, B cells, macrophages, thymocytes, or other hematopoietic cells. More importantly, the two antibodies inhibited cell-mediated killing and antigen-specific proliferation of the CT8III clone but did not affect the functions of any other clone tested. This inhibition was not secondary to generalized abrogation of the CT8III clone's function, because interleukin 2 responsiveness was enhanced. To examine the relationship of the structures defined by anti-clonotypic antibodies with known T cell surface molecules, antibody-induced modulation studies and competitive binding assays were performed. The results indicated that the clonotypic structures were associated with, but distinct from, the 20,000-mol wt T3 molecule expressed on all mature T lymphocytes. Moreover, in contrast to anti-T3, anti-Ti1A and anti-Ti1B each immunoprecipitated two molecules of 49,000 and 43,000-mol wt from 131I-labeled CT8III cells under reducing conditions. The development of monoclonal antibodies to such polymorphic T cell surface structures should provide important probes to further define the surface receptor for antigen.

Human T cell hybridomas secreting immune interferon

Human T-cell hybridomas were established by hybridization of concanavalin A-stimulated human peripheral blood lymphocytes with a 6-thioguanine-resistant mutant cell line, designated SH9, derived by irradiation from a cloned human cutaneous T lymphoma line, Hut102-B2. High levels of interferon (IFN) were demonstrated in the supernatants of hybridoma L265 and its subclones. Whereas no IFN was detected in SH9 cell cultures, up to 1,330 units of IFN per ml were produced spontaneously by the hybrids. On induction with 12-omicron-tetradecanoylphorbol 13-acetate, IFN synthesis in hybridoma cultures was enhanced 8- to 16-fold. Neutralization with specific antisera and determination of antiviral activities in human and bovine cells showed that the IFN secreted by the hybridomas was immune IFN (IFN-gamma). Analysis of DNA content, karyotype, and cell surface phenotype, including T cell specific antigens and receptors, confirmed the T cell hybrid nature of L265 clones. No correlation was found in the hybridomas between IFN production and the expression of HTLV, a retrovirus released by Hut102-B2 and SH9 cells.

Differentiation of human T-lymphoid leukemia cells into cells that have a suppressor phenotype is induced by phorbol 12-myristate 13-acetate

Treatment of cultured human T-lymphoid (CEM) leukemia cells with nanomolar concentrations of phorbol 12-myristate 13-acetate (PMA) resulted in a reduction in cell growth and in the acquisition of a surface antigenic pattern that is common to both suppressor and cytotoxic T lymphocytes. This antigenic pattern was detected by OKT monoclonal antibodies. PMA treatment did not cause the expression of a cytotoxic function but rather induced the expression of a suppressor cell marker. This marker was characterized by the ability of the treated CEM cells to suppress [3H]thymidine incorporation into phytohemagglutinin-activated peripheral blood lymphocytes. After 4 days of treatment of CEM cells from either cloned or the parental cell population with 16 nM PMA, 71-98% of the cells expressed reactivity with OKT3 and OKT8 antibodies whereas reactivity with OKT4 and OKT6 was detected in less than or equal to 1-8% of the cells. The CEM cells can be divided into five groups based on the antigenic patterns of cells from randomly isolated clones. The cells from four of these groups were characterized by either low or high reactivity with each of the four OKT antibodies. The antigenic pattern of the fifth group resembled that of the parent CEM cells. The acquisition of reactivity with the OKT3 antibody in the CEM cells after PMA treatment was dependent on both time and dose and did not require cell replication. Acquisition of reactivity with OKT3 antibody also occurred after treatment with phorbol 12,13-dibutyrate but not after treatment with phorbol 13-monoacetate, phorbol 12,13-diacetate, or dimethyl sulfoxide. These results indicate that treatment of CEM cells with PMA and related agents can cause the cells to express a phenotype that resembles that of a mature suppressor T lymphocyte.

Antigen-specific suppression in genetic responder mice to L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT). Characterization of conventional and hybridoma-derived factors produced by suppressor T cells from mice injected as neonates with syngeneic GAT macrophages

Spleen cells from C57BL/10 mice injected with syngeneic B10 L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT)-pulsed macrophages (GAT-M phi) within 18 h of birth were unable to respond to soluble GAT, GAT-methylated bovine serum albumin, or B10 GAT-M phi as adults. Spleen cells from these neonatally treated mice responded at control levels to GAT presented in allogeneic M phi and to sheep erythrocytes. Partially purified T cells from these neonatally treated mice suppressed responses by syngeneic virgin, but not primed, spleen cells in an antigen-specific manner and acted during the early phases of the response. These responder GAT-specific suppressor T cells (GAT-TSR) were sensitive to anti-Thy-1 + C and 500-rad irradiation and have the phenotype Ly-1-2+, I-J+; GAT-TSR cells can only suppress responses by spleen cells syngeneic with the GAT-TSR cells at the I-J subregion of H-2. Restimulation of these Ts cells with syngeneic GAT-M phi induces an antigen-specific suppressor factor within the supernatant fluid. The factor, GAT-TsFR, is a glycoprotein with a molecular weight between 48,000 and 63,000, as determined by gel filtration chromatography using isotonic buffers; it bears serologically detectable determinants encoded by the I-J subregion of the H-2 complex, has an antigen-binding site for GAT and L-glutamic acid50-L-tyrosine50, and shares idiotypic determinants with anti-GAT antibodies. The presence of GAT-TsFR in the first 36 h of in vitro culture is required for significant suppression. Furthermore, only responses by spleen cell syngeneic with the cells producing GAT-TsFR at the I-J subregion are suppressed. The fusion of GAT-TsFR-producing cells with BW5147 resulted in generation of two hybridomas with properties and characteristics identical to those of the conventional GAT-TsFR with one exception: conventional and hybridoma 372.D6.5 GAT-TsFR only suppress responses by spleen cells of the I-Jb haplotype, whereas suppression mediated by the second hybridoma GAT-TsFR (372.B3.5) is genetically unrestricted. These hybridoma GAT-TsFR are compared with nonresponder GAT-Ts factor (GAT-TsF) and these responder and nonresponder GAT-TsF are considered in the context of suppressor pathways.

A molecular map of the immune response region from the major histocompatibility complex of the mouse

A stretch of 200 kilobases (kb) of DNA from the I region of the mouse major histocompatibility complex has been cloned and characterized. It contains the genes for the biochemically defined class II proteins E alpha, E beta and A beta. DNA blot analyses suggest that the I region may contain only 6-8 class II genes. Correlation of our molecular map with the genetic map of the I region confines two of the five I subregions, I-J and I-B, to less than 3.4 kb of DNA at the 3' end of the E beta gene where a hotspot for recombination has been observed. Indeed, the I-A and I-E subregions may be contiguous. If so, the I-B and I-J subregions are not encoded in the I region between the I-A and I-E subregions.

Cell-free translation of a biologically active, antigen-specific suppressor T cell factor

In vitro synthesis of an antigen-specific T cell suppressor factor (TsF) has been accomplished by using partially purified poly(A)-containing RNA in a rabbit reticulocyte lysate cell-free translation system. The poly(A)-containing mRNA was isolated from a cloned T cell hybridoma that constitutively produces a TsF specific for the synthetic polypeptide antigen poly-(LGlu60LAla30LTyr10) (GAT). The RNA was fractionated by size and translated in vitro. The 16S RNA fraction stimulated synthesis of a biologically active protein that specifically suppressed both the GAT-specific antibody response by spleen cells in vitro and the proliferation response to GAT by lymph node T cells from GAT-primed mice. Further, the suppressor factor had a binding site for GAT, a determinant encoded by the I subregion of the major histocompatibility complex (MHC), and an apparent Mr 19,000 estimated by functional assays on protein separated by NadodSO4/polyacrylamide gel electrophoresis. These results indicate that virtually no posttranslational modifications (other than proteolytic cleavage) are necessary to obtain biologically active TsF. Hence, the presence of carbohydrate or other chemical groups does not contribute to either the serological properties of GAT-TsF or its biological properties.