Nonspecific inhibitor of contact sensitivity made by T-acceptor cells: triggering of T cells armed with antigen-specific T-suppressor factor (TsF) requires both occupancy of the major histocompatibility complex recognition site by soluble I-J product and cross-linking of the antigen recognition sites of the TsF

The phenomenon of associative recognition, i.e., the recognition of antigen together with major histocompatibility complex products (MHC) was studied in a model system. T-acceptor cells armed with antigen-specific T-suppressor factor (TsF) released a nonspecific inhibitor of the transfer of contact sensitivity when exposed to antigen together with MHC. The MHC product occurred in a KCl extract of cells and behaved genetically and serologically as I-J. Cells armed with anti-picryl or anti-"oxazolone" TsF could be triggered by the corresponding "bis-picryl-L-lysine" and "bis-oxazolone-L-lysine" together with MHC. This suggested that cross-linking of antigen recognition sites on separate molecules of TsF might be required. To investigate this possibility the bifunctional "mixed" hapten "N alpha-picryl-N epsilon-oxazolone-L-lysine," which is univalent with respect to the picryl and oxazolone haptenic groups, was synthesized. This triggered cells armed with a mixture of anti-picryl and anti-oxazolone TsF but not cells armed with either TsF alone. It was concluded that both occupancy of the I-J recognition site and the cross-linking of separate molecules of TsF was required for triggering. Moreover the hapten and the KCl extract could be given sequentially and in either order. This finding suggested that the triggering of the release of nonspecific inhibitor was due to the separate recognition of I-J and antigen and not to new antigenic determinants produced by their interaction.     

T suppressor factor activity is due to two separate molecules. The Lyt-1(-)2+I-J+ cells of mice primed with antigen make an antigen binding molecule which is only active when complemented by cofactor made by Lyt-1+2(-)I-J+ cells

Mice primed with picrylsulfonic acid (PSA) and then painted on the skin with picryl chloride produce antigen-specific T suppressor factor (TsF). In contrast unpainted primed mice fail to produce active TsF. This is not due to the absence of the antigen binding part of TsF but to the absence of a cofactor. This cofactor is (a) antigen nonspecific and occurs in potassium chloride extract of normal spleen cells. It also occurs in the 24 hr supernatant of normal cells modified by haptenisation with picryl or the unrelated NP antigen (4-hydroxy-3-nitrophenylacetyl), and in preparations of conventional TsF (PSA/PCl) from painted PSA-primed mice; (b) bears I-J determinants; and (c) is produced by Lyt-1+2(-)I-J+ cells. The antigen binding molecule occurs alone in the supernatant of PSA-primed mice. It lacks I-J determinants and has a molecular weight around 35,000 and 75,000. It is produced by Lyt-1(-)2+I-J+ cells and is only active when complemented by cofactor. However, the complementation is genetically restricted and the restriction maps to the I-J subregion of the MHC.     

Complete nucleotide and encoded amino acid sequence of a mammalian myosin heavy chain gene. Evidence against intron-dependent evolution of the rod

The complete nucleotide sequence and exon/intron structure of the rat embryonic skeletal muscle myosin heavy chain (MHC) gene has been determined. This gene comprises 24 X 10(3) bases of DNA and is split into 41 exons. The exons encode a 6035 nucleotide (nt) long mRNA consisting of 90 nt of 5' untranslated, 5820 nt of protein coding and 125 nt of 3' untranslated sequence. The rat embryonic MHC polypeptide is encoded by exons 3 to 41 and contains 1939 amino acid residues with a calculated Mr of 223,900. Its amino acid sequence displays the structural features typical for all sarcomeric MHCs, i.e. an amino-terminal "globular" head region and a carboxy-terminal alpha-helical rod portion that shows the characteristics of a coiled coil with a superimposed 28-residue repeat pattern interrupted at only four positions by "skip" residues. The complex structure of the rat embryonic MHC gene and the conservation of intron locations in this and other MHC genes are indicative of a highly split ancestral sarcomeric MHC gene. Introns in the rat embryonic gene interrupt the coding sequence at the boundaries separating the proteolytic subfragments of the head, but not at the head/rod junction or between the 28-residue repeats present within the rod. Therefore, there is little evidence for exon shuffling and intron-dependent evolution by gene duplication as a mechanism for the generation of the ancestral MHC gene. Rather, intron insertion into a previously non-split ancestral MHC rod gene consisting of multiple tandemly arranged 28-residue-encoding repeats, or convergent evolution of an originally non-repetitive ancestral MHC rod gene must account for the observed structure of the rod-encoding portion of present-day MHC genes.     

Expression of cell surface antigens by suppressor T cell hybridomas. I. Comparison of phenotype and function

The phenotypic expression of cell surface markers by T cell hybridomas that elaborate suppressor factors specific for the polymers L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) or L-glutamic acid50-L-tyrosine50 (GT) has been analyzed. We found that determinants encoded by the I-J subregion of the H-2 complex were borne on the surface of these hybrid cells and on the factors they secrete, whereas I-J determinants were not expressed by the AKR thymoma fusion parent, BW5147. The level of expression of I-J determinants fluctuated widely depending upon culture conditions, but I-J products and other cell surface markers of normal T cells could be quantitatively increased, or induced to appear, by treatment of the hybridomas with chemical agents, such as dimethyl sulfoxide (DMSO) or phorbol myristate acetate (PMA). In contrast, the surface expression of the viral product gp70 was decreased by the same treatment. Using chemical induction, we typed BW5147, a group of antigen-specific suppressor T cell hybridomas, and two control hybridomas for expression of I-J, Thy-1, Lyt, and H-2K alloantigens. Also, a haplotype-specific hybridoma that produces an antigen-nonspecific factor was analyzed. The results demonstrated that BW5147 failed to express I-J or Lyt alloantigens but expressed Thy-1.1 and H-2Kk gene products. The pattern of expression of these antigens by T cell hybridomas was very complex, but three conclusions could be drawn: 1) Good correlation exists between the expression of certain I-J determinants and the ability of T cell hybridomas to produce suppressor factor. 2) The expression of Thy-1, Lyt, or H-2Kk determinants is variable, and no correlation was found between expression of these antigens and the ability to produce active suppressor factors. 3) I-Jk products contributed by the AKR thymoma fusion partner are expressed by T cell hybridomas.     

Activation or suppression of bactericidal activity of macrophages during a graft-versus-host reaction against I-A and I-J-region differences, respectively

Systemic graft-versus-host reactions (GVHR) were induced in F1 heterozygous mice by injecting 10(8) parental lymphocytes. The Anti-Thy 1.2-sensitive, T-cell mediated activation of macrophages was assessed by their increased capacity to destroy a facultative intracellular bacterium Listeria monocytogenes. The difference in MHC regions causing a GVHR that induced high levels of macrophage activation mapped to I-A. In contrast, differences at K or D, in any of the other H-2 subregions or in the non-H-2 background, including Mls alone or in combination, did not induce a GVHR leading to macrophage activation, unless these differences were combined with a difference at I-A. The numbers of parental cells needed to activate macrophages via a GVHR caused by I-A vs. non-I-A differences, varied at least 30- to 100-fold. When parental cells were injected into F1 offspring of parents differing at I-J, growth of Listeria was enhanced significantly; this negative effect on macrophages was not seen when parental combinations differing at I-A alone were compared with those differing at I-A plus I-J or I-J plus other H-2 regions.     

Insulin-specific suppressor T cell factors

Murine antibody responses to heterologous insulins are controlled by MHC-linked immune response genes. Although nonresponder mice fail to make antibody when injected with nonimmunogenic variants of insulin, we have recently shown that nonimmunogenic variants stimulate radioresistant, Lyt- 1+2- helper T cells that support secondary antibody responses. However, the helper activity can not be detected unless dominant, radiosensitive Lyt-1-2+, I-J+ suppressor T cells are removed. In this paper we report that extracts of primed Lyt-2+ suppressor T cells contain insulin-specific suppressor factors (TsF) that are capable of replacing the activity of suppressor T cells in vitro. The activity of these factors is restricted by MHC-linked genes that map to the I-J region, and immunoadsorption studies indicated that they bind antigen and bear I-J-encoded determinants. Insulin-specific TsF consists of at least two chains, one-bearing I-J and the other the antigen-binding site. Furthermore, mixing of isolated chains from different strains of mice indicates that the antigenic specificity is determined by the antigen-binding chain and the MHC restriction by the H-2 haplotype of the source of the non-antigen-binding, I-J+ chain. Moreover, mixtures containing antigen-binding chain from allogeneic cell donors and I-J+ chain from responder cell donors have activity in cultures containing responder lymphocytes. This suggests that preferential activation of suppressor T cells, rather than differential sensitivity to suppression, results in the nonresponder phenotype to insulin.     

Immunoregulatory role of Ig isotypes. II. Activation of cells that block induction of contact sensitivity responses by antibodies of IgG2a and IgG2b isotypes

The influence that the isotype of Ag-specific antibody has on the induction of contact hypersensitivity (CS) has been investigated. Injection (i.v.) of mice with haptenated peritoneal exudate cells (PEC) pretreated with anti-hapten mAb of the IgG2a and IgG2b isotypes results in the activation of Ag-specific afferent acting Ts cells (Ts-aff). These suppressor cells are not generated when animals are injected with anti-hapten antibodies of other isotypes. The Ts-aff cells function to inhibit the generation of CS responses when injected into naive animals. Suppression is due to the induction of both Lyt-1+,2- I-J+ and Lyt-1-,2+ I-J+ T cells, both of which adhere to the lectin Vicia villosa. Attachment of both TNP and 4-ethoxymethylene-2-phenyloxazolone haptens to the same PEC, followed by treatment with an IgG2a anti-TNP antibody, generates Ts-aff cells specific for both 4-ethoxymethylene-2-phenyloxazolone and TNP. The MHC haplotype of the PEC is irrelevant, as allogeneic PEC will also induce Ts-aff cells when injected by using an identical protocol. Ts-aff cells cannot be generated in B cell-depleted mice, nor does the Ts-aff cells generated in normal mice suppress CS responses in B cell-depleted mice. These results show that Ag-antibody complexes bound on the surface of a PEC can induce potent afferent suppression in vivo. A possible general role for antibody isotypes in directing regulatory activities is discussed.     

In vitro analysis of allogeneic lymphocyte interaction. III. Generation of a helper allogeneic effect factor (AEF) across an I-J subregion disparity.

Allogeneic effect factors (AEF) were produced across an I-J subregion incompatibility. The helper activity of these AEFs is H-2 restricted since they help B cells only of the stimulator haplotype and of other haplotypes that carry the same I-J subregion gene(s) as the stimulator haplotype. Immunoadsorption studies demonstrate that they consist of I-J determinants derived initially from the GVHR host and MLR stimulator cells and not the GVHR donor and MLR responder cells used to generate AEF. It is postulated that the genetic restriction of AEF helper activity is mediated in part by the ability of the GVHR activated donor T cells to acquire, in vivo, recipient T cell and/or macrophage derived I-J determinants. Cellular adsorption studies indicate that AEF helper activity may be adsorbed by B cells, but neither T cells nor macrophages, of the stimulator haplotype. The results suggest that an I-J-positive AEF interacts with an I-J subregion controlled complementary recognition structure on a target B cell and, after antigenic stimulation, activates that B cell to IgG antibody synthesis.     

Regulation of the immune response to tumor antigen. IV. Tumor antigen-specific suppressor factor(s) bear I-J determinants and induce suppressor T cells in vivo.

The nature and function of suppressor factor(s) elaborated by suppressor T cells in response to certain chemically induced tumors have been further defined. Thus, suppressor factor(s) specific for the S1509a methylchol-anthrene-induced fibrosarcoma have been shown to bear determinants encoded by the I-J subregion of the murine MHC since suppressive activity is removed by passage of the factor through an immunoadsorbent composed of anti-I-Jk coupled to Sepharose. No loss of activity was observed after passage of factor through control columns composed of normal mouse globulin. Furthermore, activity could be recovered from the relevant immunoadsorbent by elution with high salt. The administration of crude suppressor factor(s) to normal animals for 4 days resulted in the development of a population of suppressor cells that act in a manner analogous to the suppressor cell population used for production of factor. These factor-induced suppressor cells are T cells and exhibit an antigen specificity similar to that displayed by the tumor-induced suppressor cells. Thus, tumor-specific suppressor factor(s) bear I-J determinants and are capable of inducing the appearance of suppressor T cells in the nontumor-bearing host, which may then act in a specific manner to limit host responsiveness to tumor antigen.     

Cell Surface Expression of I-A Products Is Required for Contact Sensitivity Induction by Trinitrophenyl-Coupled Epidermal Cells

Trinitrophenyl (TNP)-coupled epidermal cells (EC) injected subcutaneously (s.c.) were more capable of inducing contact sensitivity (CS) to 2, 4, 6-trinitro-1-chlorobenzene (TNCB) than similarly substituted spleen cells (TNP-SC). Furthermore, the intravenous (i.v.) or intraperitoneal (i.p.) injection of TNP-EC also induced CS responses, whereas the i.v. or i.p. injection of TNP-SC failed to induce them. Treatment of mice with cyclophosphamide (Cy; 50 mg/kg) or anti I-J serum allowed animals injected with TNP-SC i.v. to develop significant CS responses, suggesting that Cy-sensitive and I-J positive regulatory cells were involved in the induction of unresponsiveness by the i.v. injection of TNP-SC. Mapping studies of the major histocompatibility gene complex (MHC) region demonstrated that identity at the I-A subregion alone between EC donor and recipient mice was sufficient for the induction of CS by TNP-EC given i.v. Blocking experiments using antisera in the absence of complement indicated that I-A subregion-encoded antigens on the surface of TNP-EC apparently are involved in the induction of CS, and are not simply phenotypic markers on the surface of accessory cells.     

Mechanism of action of a T suppressor factor (TsF) in contact sensitivity: the T cell target for TsF activity in adoptive transfer of immunity is not effector cell

The passive transfer of contact sensitivity (CS) by immune cells into normal animals requires the interaction of two distinct Ly-1+ T cells, one which is Vicia villosa lectin (VV)-nonadherent, the other which adheres to VV. Functional deletion of either cell type abrogates the adoptive transfer of CS into normal animals, whereas VV-nonadherent cells alone can transfer CS into animals pretreated with cyclophosphamide (Cy). An antigen-specific T suppressor factor, designated TNP-TsF, inhibits the transfer of CS into normal adoptive recipients. TNP-TsF mediates its suppressive activity by inducing an I-J+ subfactor (designated I-J2) from the assay population by the interaction of PC1-F (a TNP-binding subfactor of TNP-TsF) with antigen-primed Ly-2+ T cells. This I-J+ subfactor then complements TNBS-F (an antigen-nonbinding subfactor of TNP-TsF) to form an antigen-nonspecific effector molecule which suppresses DTH responses in an antigen-nonspecific fashion. We report here that TNP-TsF suppresses the adoptive transfer of CS into normal animals but not into animals pretreated with Cy. TNBS-F + I-J2, the effector complex of TNP-TsF, also suppresses the transfer of CS into normal but not Cy-treated animals. When the Ly-1 immune cells were separated into VV-adherent and -nonadherent populations, the TNBS-F + I-J2 suppressor complex suppressed the functional activity of the VV-adherent cell population, but not the VV-nonadherent cells. This suppressive activity correlates with the need for VV-adherent cells in the transfer of CS into normal but not Cy-treated recipients. When an I-J+ molecule (I-J1) from an SRBC-specific TsF was used in place of I-J2 to form a suppressor complex with TNBS-F, this TNBS-F + I-J1 TsF suppressed the transfer of CS into both normal and Cy-treated recipients. This difference in functional suppressive activity correlated with a difference in target cell specificity: TNBS-F + I-J1 suppressed the VV-nonadherent TDTH cell, whereas TNBS-F + I-J2 suppressed the VV-adherent T cell of CS. Immune cells which are transferred under conditions which do not require the VV-adherent cell for transfer are not suppressed by TNBS-F + I-J2 or TNP-TsF, but are suppressed by the TNBS-F + I-J1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Contribution of myosin rod protein to the structural organization of adult and embryonic muscles in Drosophila

Myosin rod protein (MRP) is a naturally occurring 155 kDa protein in Drosophila that includes the myosin heavy chain (MHC) rod domain, but contains a unique 77 amino acid residue N-terminal region that replaces the motor and light chain-binding domains of S1. MRP is a major component of myofilaments in certain direct flight muscles (DFMs) and it is present in other somatic, cardiac and visceral muscles in adults, larvae and embryos, where it is coexpressed and polymerized into thick filaments along with MHC. DFM49 has a relatively high content of MRP, and is characterized by an unusually disordered myofibrillar ultrastructure, which has been attributed to lack of cross-bridges in the filament regions containing MRP. Here, we characterize in detail the structural organization of myofibrils in adult and embryonic Drosophila muscles containing various MRP/MHC ratios and in embryos carrying a null mutation for the single MHC gene. We examined MRP in embryonic body wall and intestinal muscles as well as in DFMs with consistent findings. In DFMs numbers 49, 53 and 55, MRP is expressed at a high level relative to MHC and is associated with disorder in the positioning of thin filaments relative to thick filaments in the areas of overlap. Embryos that express MRP in the absence of MHC form thick filaments that participate in the assembly of sarcomeres, suggesting that myofibrillogenesis does not depend on strong myosin-actin interactions. Further, although thick filaments are not well ordered, the relative positioning of thin filaments is fairly regular in MRP-only containing sarcomeres, confirming the hypothesis that the observed disorder in MRP/MHC containing wild-type muscles is due to the combined action between the functional behavior of MRP and MHC myosin heads. Our findings support the conclusion that MRP has an active function to modulate the contractile activity of muscles in which it is expressed.     

Serologic heterogeneity in I-J determinants associated with functionally distinct T cell regulatory factors

Information transfer among regulatory T cell subsets is mediated by biologically active T cell factors. Many of these factors are comprised of two molecules: one that binds antigen, and another that is I-J+ and determines the self recognition capability of the factor (I-J molecule). In the in vitro response to sheep red blood cells, we used three functionally distinct I-J+ factors to study the relationship between polymorphic I-J determinants and the biological activity of these factors. Our study shows that several monoclonal I-J antibodies react with I-J molecules associated with T suppressor-inducer factor (TsiF) and T suppressor-effector factor (TseF), but not with T contrasuppressor inducer factor (TcsiF). In contrast, a different set of monoclonal I-J reagents reacts with TcsiF but not TsiF or TseF. Finally, some monoclonal I-J antibodies distinguish between I-J molecules associated with TsiF and TseF. Thus anti-I-J reagents differentially react with I-J determinants on regulatory factors, and this differential pattern of reactivity correlates with the functional activity of the factors. The possible relationship between I-J heterogeneity and the biological function of I-J molecules in regulation is discussed.     

ERVK9, transposons and the evolution of MHC class I duplicons within the alpha-block of the human and chimpanzee

The genomic sequences within the alpha-block (approximately 288-310 kb) of the human and chimpanzee MHC class I region contains ten MHC class I genes and three MIC gene fragments grouped together within alternating duplicated genomic segments or duplicons. In this study, the chimpanzee and human genomic sequences were analyzed in order to determine whether the remnants of the ERVK9 and other retrotransposon sequences are useful genomic markers for reconstructing the evolutionary history of the duplicated MHC gene families within the alpha-block. A variety of genes, pseudogenes, autologous DNA transposons and retrotransposons such as Alu and ERVK9 were used to categorize the ten duplicons into four distinct structural groups. The phylogenetic relationship of the ten duplicons was examined by using the neighbour joining method to analyze transposon sequence topologies of selected Alu members, LTR16B and Charlie9. On the basis of these structural groups and the phylogeny of the duplicated transposon sequences, a duplication model was reconstructed involving four multipartite tandem duplication steps to explain the organization and evolution of the ten duplicons within the alpha-block of the chimpanzee and human. The phylogenetic analysis and inferred duplication history suggests that the Patr/HLA-F was the first MHC class I gene to have been fixed and not required as a precursor for further duplication within the alpha-block of the ancestral species.     

T cell subsets regulating antibody responses to L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) in virgin and immunized nonresponder mice

T cell subsets from virgin and immunized mice, which are Ir gene controlled nonresponders to GAT, which regulate antibody responses to GAT have been characterized. Virgin nonresponder B10.Q B cells develop GAT-specific antibody responses to GAT, B10.Q GAT-M phi, and GAT-MBSA when cultured with virgin or GAT-primed Lyt-1+, I-J-, Qa1- B10.Q helper T cells. Virgin T cells are radiosensitive, whereas immune T cells are radioresistant (750 R); qualitatively identical helper activity is obtained with T cells from mice immunized with soluble GAT, B10.Q GAT-M phi, and GAT-MBSA. Responses to GAT and GAT-M phi are not observed when virgin or GAT-primed Lyt-1+, I-J+, Qal+ T cells are added to culture of virgin or GAT-primed Lyt-1+, I-J-, Qa1- helper T cells and virgin B cells; the GAT-specific response to GAT-MBSA is intact. The Lyt-1+, I-J+, Qa1+ T cells from mice primed with GAT, GAT-M phi, and GAT-MBSA were qualitatively identical in mediating this suppression. Virgin Lyt-2+ T cells have no suppressive activity alone or with virgin Lyt-1+, I-J+, Qa1+ T cells, whereas responses to GAT, GAT-M phi, and GAT-MBSA are suppressed in cultures of GAT-primed helper T cells containing GAT-primed Lyt-2+ T cells (with or without GAT-primed Lyt-1+, I-J+, Qa1+ T cells). Suppression of responses to GAT-MBSA in cultures of GAT-M phi-primed helper T cells requires both GAT-M phi-primed Lyt-1+, I-J+, Qa1+ T cells and Lyt-2+ T cells; the Lyt-1+, I-J+, Qa1+ T cells appear to function as inducer cells in this case. In cultures containing GAT-MBSA-primed helper T cells, either GAT-MBSA-primed Lyt-1+, I-J+, Qa1+ or Lyt-2+ T cells suppress responses to GAT and GAT-M phi; under no circumstances are responses to GAT-MBSA suppressed by GAT-MBSA-primed regulatory T cells. This regulation of antibody responses to GAT by suppressor T cells is discussed in the context of the involvement of suppressor T cells in responses to antigens under Ir control, and of the evidence that nonresponsiveness to GAT is not due to a defect in the T cell repertoire, but rather is due to an imbalance in the activation of suppressor vs helper T cells.     

A genetic polymorphism of the complement component factor B in chickens not linked to the Major Histocompatibility Complex (MHC)

The complement component factor B in chickens exhibits a genetic polymorphism with three common phenotypes, F, F/S, and S. These phenotypes segregate in flocks of chickens homozygous for the MHC (B complex) of the chicken. Furthermore, a genetic analysis has shown that the described factor B polymorphism is not linked to the B complex. It is not known whether the molecular basis for this polymorphism is due to the existence of allelic forms of the structural gene or to some posttranslational modifications, but the finding is discussed in view of the, close linkage of factor B polymorphism with the MHC of all mammalian species investigated so far.     

Activation of acceptor-suppressor hybridoma with antigen-specific suppressor T cell factor of two-chain type: requirement of the antigen- and the I-J-restricting specificity

The molecular mechanisms of activation of immunoregulatory T cells were characterized by using two complementary suppressor T cell hybridoma systems: the KLH-specific monoclonal suppressor factor (KLH-TsF), and the inducible acceptor-suppressor hybridoma line with anti-idiotypic receptor for KLH-TsF. It was demonstrated that the identity of the KLH specificity and genetic specificity was required for the TsF-acceptor interaction. These specificities were found to be mediated by the two polypeptide chains of TsF: KLH-binding, Ct-bearing heavy chain and I-J+ light chain. These two chains were essential for stimulation of the acceptor hybridoma. The results were also confirmed by the findings that the mixture of the 11S and 13S mRNA translation products reconstituted the active TsF to stimulate the acceptor hybridoma. Furthermore, the genetic restriction observed was found to be mediated by the I-J+ light chain and to be governed by the gene linked to the H-2 complex but not to the Igh genes. The gene controlling the restriction specificity was strongly suggested to be in the intra-H-2 complex, but not outside of the H-2 complex.     

Ly-1 inducer and Ly-1,2 acceptor T cells in the feedback suppression circuit bear an I-J-subregion controlled determinant

An I-J-subregion controlled determinant is expressed on Ly-1 inducer and Ly-1,2 acceptor T cells in the feedback suppression circuit. Ly-1 T cells absorb the I-J antibody reactive with the Ly-1,2 acceptor T cell, suggesting that both inducer and acceptor T cells have the same I-J determinant. Since less than 10 percent of Ly-1 or Ly-1,2 T cells are killed by anti-I-J plus complement treatment, the I-J determinant demarcates functionally distinct subsets of both the Ly-1 and Ly-1,2 T-cell sets. This I-J determinant is not expressed on a detectable number of Ly-1 helper T cells which induce B lymphocytes to produce anti-sheep red cell antibody in tissue culture.     

NF-X, a transcription factor implicated in MHC class II gene regulation

The X box has been shown in several assay systems to be a critical element of MHC class II gene promoters. Several X box-binding activities have been discovered in nuclear extracts from a variety of cell lines. The critical question is: which of these are responsible for mediating X box function? This report provides a further characterization of NF-X, a highly specific X box-binding activity we described previously. The cell-type distribution, structural features, and binding site characteristics of NF-X are analyzed in detail, to facilitate comparison with other reported activities. Most importantly, the functional relevance of NF-X is assessed by scanning mutagenesis, and the results indicate that this complex is indeed involved in regulating MHC class II gene expression. With these data in mind, the relationship between NF-X and RF-X, an X box-binding activity reported to be absent in patients with severe combined immunodeficiency, is discussed.