Two different VH gene products make up the T-cell receptors

Development of Immature CD4+CD8+T Cells Into Mature CD4+ T Cells Requires Alpha-1 Antitrypsin as Observed by Treatment in HIV-1 Infected and Uninfected Controls

Immune cells are, by default, migratory cells that traverse tissue for the purpose of carrying out recognition and recruitment in pathologic inflammation and infection. Members of the LDL receptor family (LDL-RFMs) interact with human leukocyte elastase on the cell surface (HLE-CS) in complex with the abundant blood protein α1proteinase inhibitor (α1PI, α1-antitrypsin, Alpha-1), a process that induces internalization of aggregated functionally-related receptors, including CD4 and the T cell antigen receptor, while simultaneously promoting cellular locomotion. We sought to determine whether augmenting α1PI blood concentration would promote the locomotion of immature T cells through the thymus and generate new CD4⁺ T cells. Two small clinical trials (NCT01370018, NCT01731691, https://clinicaltrials.gov) were conducted in which HIV-1 infected and uninfected individuals were augmented with α1PI and compared with placebo-treated subjects and untreated controls. Blood cell phenotypes were monitored weekly. We found that CD4/CD8 ratio was significantly increased by α1PI augmentation in both uninfected and HIV-1 infected individuals. We found that maturation of CD4⁺CD8⁺ T cells to become immunologically competent CD4⁺ T cells was regulated by α1PI. We propose a strategy targeting HLE-CS for treating secondary immunodeficiency for which there is currently no direct treatment. Treatment to directly elevate T cells in patients with secondary immunodeficiency, including HIV disease, can be provided by alpha-1 antitrypsin augmentation or small molecules that target HLE-CS. Because individuals infected with HIV-1 produce a monoclonal antibody, 3F5, which binds to and inactivates α1PI, a process that prevents α1PI from binding to HLE-CS, thereby blocking locomotion of immature T cells through the thymus to generate CD4⁺ T cells, we further propose that HIV-1 vaccination should include induction of an antibody that binds to and blocks 3F5 activity, thereby preventing AIDS in addition to the current vaccine strategy for preventing HIV-1 infection.

T lymphocytes responding to Mls-locus antigens are Lyt-1+, 2- and I-A restricted

We have investigated primary and secondary responses of mouse splenic T cells to strong mixed lymphocyte stimulating antigens controlled by the Mls locus using MHC-identical mixtures of cells. Our studies show that strong primary Mls-locus specific responses involve recognition of self I-A antigens, since BUdR and light suicide or F1 into parent radiation bone-marrow chimeras both demonstrate a preference of unprimed F1 T cells to respond to Mls-locus antigens associated with one parent's MHC antigens. Furthermore, conventional anti-I-A antisera and monoclonal anti-I-A antibody both inhibit Mls-locus responses in an MHC-specific manner. Finally, as is typical of T cells responding to I-A antigens or to nominal antigens associated with self I-A, Mls-locus responses are mediated by Lyt-1+, 2 cells. One striking finding in these studies was the very high frequency of cells capable of responding to Mls-locus antigens, the highest being 1/300 splenic T cells. This plus evidence for recruitment during primary Mls-locus responses may account for reports of a lack of I-A restriction in secondary anti-Mls locus responses to strong Mls-locus antigens, a finding with which we concur. The possibility that these secondary responses between noncongenic strains of mice may be directed at other genetic loci is also discussed. These experiments leave open the question of the biological role of the Mls-locus and of the very large number of T cells reactive to it.

Finding the groove

Envisioning how T cells might recognize antigen presented by major histocompatibility complex molecules proved to be a formidable challenge. Pamela Bjorkman describes her journey to provide structural insights into how such recognition is achieved.

A novel MHC class II epitope expressed in thymic medulla but not cortex

The repertoire of receptors expressed by peripheral T cells is the result of two selective events that occur during intrathymic development. Positive selection expands cells able to recognize foreign peptides presented by self MHC molecules, and negative selection eliminates cells reactive to self MHC molecules and associated self peptides. Chimaera studies suggest that, at least in the case of T cells recognizing MHC class II, interaction with thymic cortical epithelial cells is responsible for the former, whereas thymic medullary cells, of bone marrow origin, mediate the latter. This view of thymic development is supported by recent morphometric analyses, showing that autoreactive cells are found in thymic cortex but not medulla. Although numerous studies have shown that MHC class II molecules are expressed in both sites, none provides any explanation for the differential selection of T cells that is observed. Here, we describe a novel MHC class II epitope which is found on cells in thymic medulla but not cortex. The antibody to this epitope reacts with about 10% of class II molecules on B cells and may be recognizing a self peptide-MHC complex. These results provide the first evidence for differential expression of class II epitopes in different tissues and are compatible with the hypothesis that different ligands, rather than different affinity thresholds for the same ligand, are involved in positive and negative selection of the T-cell repertoire.

The molecular basis of MHC-restricted antigen recognition by T cells

In order to determine the contribution of the clonotypic T cell receptor (Ti) alpha beta heterodimer to the antigen/MHC specificity of mature T cells, we have transfected cloned Ti alpha and/or beta genes into either human or mouse T cells, and analyzed the transfectants for Ti-T3 expression and responses to antigen and Ia molecules. Our analysis establishes that a single receptor structure (the Ti alpha beta heterodimer) is necessary and sufficient to define the dual specificity of T cell antigen recognition and suggests that in at least certain instances Ti beta chains play a predominant role in MHC restriction specificity, raising the possibility of a "one receptor, two sites" model of T cell recognition.

The generation and selection of the T cell repertoire: insights from studies of the molecular basis of T cell recognition

The molecular basis of T cell corecognition of antigen and products of the major histocompatibility complex (MHC) was examined using the technique of DNA-mediated gene transfer. Introduction of the genes encoding the alpha and beta chains of the clonotypic molecule (Ti) of the pigeon cytochrome c-specific, I-Ek-restricted murine T cell hybridoma 2B4 into the human leukemic T cell Jurkat or its T3- variants led to the surface expression of various dimeric combinations of human and mouse Ti chains. All alpha beta dimers were associated in a 1:1 ratio with the chains of the T3 complex and all Ti-T3 complexes could transmit effective transmembrane signals for IL2 gene activation following binding and cross-linking by anti-T3 or anti-clonotypic antibodies. However, only the reconstituted mouse 2B4 alpha beta dimer mediated functional responses to antigen-presenting cells bearing the appropriate combination of antigen and Ia molecules. The fine specificity of the antigen-MHC molecule responses precisely matched that of the 2B4 T cell gene donor, establishing that the alpha beta clonotypic molecule is both necessary and sufficient to fully define the dual specificity of a T cell. This result, together with similar data from other laboratories, provides direct evidence in favor of the "single receptor" model of T cell recognition. Analysis of past experiments looking for independent recognition of antigen vs. MHC molecules led us to conclude that limitations on either formation of mixed receptor dimers or of appropriate antigen peptide-Ia molecule pairs may have limited the utility of these studies in providing an answer to this question. Therefore, additional gene transfer experiments were carried out to investigate the role of the two chains of the alpha beta heterodimer in controlling antigen vs. MHC molecule specificity. Our results showed that under conditions in which it was assured that antigen-Ia complexes formed, one could produce a receptor molecule composed of the alpha chain of one T cell hybridoma (2H10) and the beta chain of a second hybridoma (2B4) with a mixed antigen and MHC molecule specificity that could be predicted based on the specificities of the parent T cells. We discuss at length the implication of this result for the issue of single- vs. dual-site recognition models of T cell receptor function. In addition to these results looking directly at specificity of receptor molecules, we have also analyzed expression of various combinations of Ti chains. For alpha and beta, clear asymmetries in the efficiency of surface receptor expression were observed for certain pairs of chains.(ABSTRACT TRUNCATED AT 400 WORDS)

What is a T-cell clone? Effect of rIFN on T-cell clone function and T-cell receptor gene rearrangement

A T4+ proliferative, noncytotoxic cloned line acquires specific lytic function by treatment with recombinant interferon alpha or gamma. Simultaneous with the acquisition of this new cell function, a rearrangement of the T-cell receptor alpha gene occurs. These changes necessitate a revised concept of a T-cell clone regarding its T-cell receptor gene configuration and cell function.

Proliferative responses of T cells from SJL----F1 and F1----SJL bone marrow chimeras to SJL lymphoma cells

RCS tumor cells induce marked proliferation of syngeneic SJL T cells in vivo and in vitro. Certain F1 hybrids of SJL mice give high proliferative responses to gamma-RCS, while other F1 hybrids give low responses. SJL----"non-responder" F1 and "non-responder" F1----SJL semiallogeneic bone marrow chimeras were prepared to study how the host environment affects the ability of T cells to give a proliferative response to gamma-RCS. The results indicate that T cells educated in an SJL host become responsive to RCS cells, while T cells educated in an (SJL X BALB/c)F1 host become unresponsive. This finding applies to both thymus and lymph node T cells. The unresponsiveness in F1 mice is not due to suppressor cells, since added F1 cells do not affect the proliferative response of SJL cells to gamma-RCS. Instead, it appears that RCS-specific T cells are either deleted in (SJL X BALB/c)F1 mice, or expanded in SJL mice as they develop. These findings are discussed in relation to the specificity of the responding T cells, for LPS activated syngeneic B cell blasts as well as RCS cells, and to the presence of a "leaky" thymus barrier in SJL mice for B cells.

The murine bm12 gene conversion provides evidence that T cells recognize predominantly Ia conformation

The structure of the highly polymorphic Ia dimer is the genetically determined factor that controls the immune response to foreign antigens, albeit the mechanism remains unresolved. However, it is clear that, in diverse immune responses, effector T lymphocytes require recognition of self-Ia and foreign antigenic determinants on the surface of an antigen-presenting cell or an antibody-secreting B cell. Furthermore, a single Ia molecule has been found to possess several independently acting functional domains. In this report T-cell recognition of Ia was limited to a single, defined structure by using the Ia mutant mouse strain B6.C-H-2bm12 (bm12). The Ia determinant being recognized is the site of the mutation that represents a difference in three of five amino acid residues in a hypervariable region of its beta chain. This mutation has been proposed to have resulted from a gene conversion-like event and is known to have functional importance. Recognition of the bm12 mutation site was studied here in in vitro cultures of T cells generated against Iabm12 antigens. The specificity of these alloreactive T cells was tested by using stimulator cells expressing various Ia alloantigens of known structure. Our findings provide direct genetic evidence that T cells recognize predominantly conformational determinants on Ia molecules and not their primary structure. The implications of these findings on our understanding of the genetic control of the immune response and the potential to modulate these responses in an antigen-specific way are discussed.

Fine specificity analysis of lactate dehydrogenase B-specific proliferating T cell clones: implications for the mechanism of alloreactivity

T cell clones of C57BL/6 origin which recognize porcine lactate dehydrogenase B (LDH-BP) together with the Ab molecule were characterized in terms of fine specificity for both LDH-B and self-major histocompatibility complex determinants. Using antigen-presenting cells from the Ab-mutant strain B6.C-H-2bm12 (bm12), three clonotypes could be distinguished: the first responds to LDH-BP + bm12, the second fails to respond and the third is alloreactive to bm12. The last clone exhibits additional alloreactivities to A molecules expressed in strains of H-2 haplotypes f, r, s, u, w6, w7, w16, w17 and w23. All three clonotypes give identical response patterns to a panel of 17 different dehydrogenase enzymes, and react to the same tryptic peptide of LDH-BP. Thus, these clones appear to recognize the same LDH-B epitope together with at least 3 different determinants of the Ab molecule. The data suggest that alloreactivity is more closely related to T cell specificity for self-major histocompatibility complex than to specificity for foreign antigen.

Maternal immunoregulation: interrelationship between alloreactive and anti-self plus conventional antigen T sets of cells

In a previous paper we reported early immunoregulatory mechanisms involving not only the appearance of progressive suppression but also significant increases in alloreactive T levels in paraaortic lymph nodes (PALN) and spleen, not only in allogeneic but also in syngeneic pregnancies. Taking into account the hypothesis of the superposition of the alloreactive and the anti-self plus conventional antigens T sets of cells, we investigated whether immunization with conventional antigens was able to alter alloreactive T levels. Weekly i.p. doses of rabbit red bloods cells (RRBC) in BALB/c mice resulted in a dose-dependent increase in spleen alloreactivity as determined by graft-versus-host (GvH) assays in strain combinations differing at H-2 level but not in those sharing the same H-2 with BALB/c. The increases could be significantly decreased by an anti-idiotype anti-RRBC serum. Pretreatment with i.p. weekly doses of sheep red blood cells (SRBC) before mating was able to induce dose-dependent fetal damage when the parents differed at the H-2 level. SRBC immunization in one of the uterine horns induced increases in PALN weight which were much higher in progesterone-pseudopregnant than in virgin mice; T alloreactivity was significantly increased in the draining PALN only in pseudopregnant females. These results favour the postulation of the superposition between the alloreactive and the anti-self plus conventional antigens T sets of cells and suggest a possible role for conventional fetal antigens (non H-2) in triggering immunoregulatory mechanisms operating in pregnancy.

RISH III. Haplotype-sharing in immune responses

A number of hypotheses have been proposed for the reactivity of lymphocytes with allogeneic tissue. However, these hypotheses have not been generally accepted for they cannot accommodate the observation that lymphocytes from chimeras cooperate with each other. Also, only a few percent of lymphocytes react with allogeneic tissue in rejection reactions.

Expression and function of interleukin-2 receptors on immature thymocytes

T-cell differentiation represents a unique system for studying mechanisms of lymphoid development because it occurs in a segregated site, the thymus, in which distinct subpopulations of thymocytes at various stages of differentiation can be defined on the basis of the differential expression of T-cell surface antigens as well as topography. There is particular interest in thymocyte differentiation because the genotype of radioresistant thymus cells influences the specificity repertoire of the pool of T cells that mature therein: that is, the major histocompatibility complex (MHC) antigens expressed by thymus cells bias the pool of maturing T cells towards recognition of antigens in the 'context' of the products of that MHC haplotype ('thymus education'; refs 1-3). Immature T cells with affinity for thymus MHC antigens are generally thought to undergo a stage of positive selection in the thymus. Here we report that 30% of cells in the least mature adult thymocyte subpopulation yet defined, as well as 50% of immature fetal thymocytes, express receptors for interleukin-2 (IL-2, the T-cell growth factor) without in vitro induction, and will proliferate vigorously in an IL-2-dependent fashion if provided with co-stimulating mitogen.

Rearrangement and transcription of the beta-chain genes of the T-cell antigen receptor in different types of murine lymphocytes

Rearrangements of T-cell receptor beta-chain genes are usually found on both chromosomal homologues, occurring by both deletional and non-deletional mechanisms. Two constant-region (C beta) genes have been identified previously and at least one is transcribed in every helper or cytotoxic T cell tested, but the choice of C beta gene expression is not correlated with the specialized functions of these T lymphocytes. By contrast, four of five suppressor T-cell hybridomas examined have deleted all known joining (J beta) gene segments and C beta genes and therefore may have antigen receptors encoded by different T-cell receptor gene families.

A third rearranged and expressed gene in a clone of cytotoxic T lymphocytes

In addition to the two previously identified genes rearranged and expressed in a cytotoxic T-lymphocyte clone, we have identified a third gene that is also rearranged and expressed in the same clone. This new gene shows clonal diversity, codes for a polypeptide chain that contains immunoglobulin-like variable and constant domains, carries potential N-glycosylation sites and is a particularly attractive candidate for the gene that encodes the alpha-subunit of the heterodimeric antigen receptor of this T-cell clone.

The T cell receptor beta chain genes are located on chromosome 6 in mice and chromosome 7 in humans

Homologous clones that encode the beta chain of the T cell antigen receptor have been isolated recently from both murine and human cDNA libraries. These cDNA clones have been used in connection with interspecies hybrid cell lines to determine that the murine T cell receptor gene is located on chromosome 6 and the human gene on chromosome 7. In situ hybridization confirms these data and further localizes these genes to band B of chromosome 6 in the mouse and bands 7p13-21 in the human genome. The organization of the T cell antigen receptor J beta gene segments and C beta genes appears to be conserved, since very few intraspecies polymorphisms of restriction fragment length have been detected in either mouse or human DNA.

A concept of immune regulation of somatic cell differentiation

On the basis of several lines of experimental evidence a hypothesis is advanced on autoimmune regulation of somatic cell differentiation in an immunologically mature organism ("self-anti-self" hypothesis of differentiation). There are supposed to be clones of lymphocytes interacting via their antigen-recognizing receptors with autologous differentiation antigens on various target cells. This interaction would modify the genetically determined rate of cell differentiation. Some implications of the hypothesis are discussed in relation to immunological memory, tolerance etc. In particular, the new concept might imply similarity (or identity) of the genes coding for autologous differentiation antigens and those responsible for the idiotypes of antigen-recognizing lymphocyte receptors.

Independent inhibition of IL 2 synthesis and cell proliferation by anti-Ia antibodies in mixed lymphocyte responses to Mls

Whole anti-I region antisera and monoclonal anti-Ia antibodies are capable of totally inhibiting the response of murine spleen cells to the non-H-2 Mls alloantigens. This inhibition was shown to be highly specific for the appropriate Ia and operative at the level of the stimulator cell. Both cell proliferation and interleukin (IL2) production were inhibited; however, the inhibition of cell proliferation was not due only to the inhibition of IL2 production and the inhibition of IL2 production was not solely due to the inhibition of IL1 production. We propose that both the IL2-producing cell and the proliferating cell need to "see" an intact Ia+ cell and perhaps Ia antigens in association with Mls determinants to respond.

Immunological surveillance of tumors in the context of major histocompatibility complex restriction of T cell function

The immunological surveillance hypothesis was formulated prior to the realization of the fact that an individual's effector T cells generally only see neoantigen if it is appropriately presented in the context of self MHC glycoproteins. The biological consequence of this mechanism is that T lymphocytes are focused onto modified cell-surface rather than onto free antigen. The discovery of MHC-restricted T cell recognition, and the realization that T cell-mediated immunity is of prime importance in promoting recovery from infectious processes, has thus changed the whole emphasis of the surveillance argument. Though the immunological surveillance hypothesis generated considerable discussion and many good experiments, there is no point in continuing the debate in the intellectual context that seemed reasonable in 1970. It is now much more sensible to think of "natural surveillance" and "T cell surveillance," without excluding the probability that these two systems have elements in common. We can now see that T cell surveillance probably operates well in some situations, but is quite ineffective in many others. Part of the reason for this may be that the host response selects tumor clones that are modified so as to be no longer recognized by cytotoxic T cells. The possibility that this reflects changes in MHC phenotype has been investigated, and found to be the case, for some experimental tumors. In this regard, it is worth remembering that many "mutations" in MHC genes that completely change the spectrum of T cell recognition are serologically silent. The availability of molecular probes for investigating the status of MHC genes in tumor cells, together with the capacity to develop cloned T cell lines, monoclonal antibodies to putative tumor antigens, and cell lines transfected with genes coding for these molecules, indicates how T cell surveillance may profitably be explored further in both experimental and human situations.

Efficiency of antigen presentation differs in mice differing at the Mls locus

In the mouse, potent primary in vitro proliferation of T cells can be induced by allelic variants of cell-surface glycoproteins, Ia antigens, the genes for which are located in the I region of the major histocompatibility complex (MHC) on chromosome 17. The only other potent primary proliferative response known is induced by mixing MHC-identical lymphocytes from strains that differ at the locus termed Mls (ref. 1) (for mixed lymphocyte stimulating), which has been mapped to chromosome 1. While it is relatively easy to raise antibodies against Ia antigens, and thus determine both their chemical nature and their role in T-cell stimulation, the nature of the product of the Mls locus has remained obscure. It has been proposed that the Mls locus product is a minor antigen recognized in association with self-Ia antigens, a translocated Ia-like element, or a mitogenic molecule found on the surface of antigen presenting cells (APC). Here, we demonstrate that APCs from mice carrying stimulatory Mls locus alleles present antigen more efficiently to cloned, antigen-specific, Ia-restricted T cells than APCs from mice carrying nonstimulating Mls locus alleles. We propose that the Mls locus does not encode a unique cell-surface antigen at all; we suggest instead that the T-cell proliferative response induced by Mls-locus disparate cells reflects recognition of self-Ia molecules on APCs. If our interpretation is correct, it provides further evidence both for the quantitative nature of self tolerance and for the existence of a distinct recognition site for self-Ia molecules on antigen-specific T lymphocytes.

Three T cell hybridomas do not contain detectable heavy chain variable gene transcripts

We attempted to determine whether T cells express any VH gene segments. cDNA libraries were constructed from one suppressor and two helper T cell hybridomas. Both the library construction and screening were designed to maximize detection of a wide range of VH gene segments. One screening method should detect about half of the sequenced VH genes, while the second should detect most of these genes. The probability of detecting a VH gene homologous to the probes and present at 10 copies per cell was 77% for one helper cell cDNA library, 88% for the second helper cell library, and greater than 99% for the suppressor cell library. No cDNA clones with VH gene segments were detected. From this result, we conclude that VH gene segments are not likely to encode the antigen-specific receptor in the cells we tested.

[Lymphocyte subpopulations in the normal cerebrospinal fluid: I. Major reports in the literature]

Data concerning the characterization of lymphocytes in the cerebrospinal fluid are reviewed, markedly those on T and B subpopulations. Special attention is given to T-lymphocyte subpopulations actually related to the immune response and to the immune regulation within the central nervous system.

Inhibition of antigen-specific T lymphocyte activation by structurally related Ir gene-controlled polymers. Evidence of specific competition for accessory cell antigen presentation

The interaction of nominal Ag with major histocompatibility complex (MHC)-restricted T cells and accessory cells was studied by analyzing the effect of structurally related antigens on the response of antigen-specific MHC-restricted T cell hybridomas. The copolymer L-glutamic acid50-L-tyrosine50 (GT) completely inhibits the response of L-glutamic acid60-L-alanine40-L-tyrosine10 (GAT)-specific, I-Ad-restricted T cell hybridomas to GAT plus accessory cells. This inhibition is specific, as hybridomas of other specificities are not inhibited under identical conditions, and is unique to the GT antigen, as other similar copolymers are not inhibitory. The inhibitory effect is reversible by adding increasing amounts of GAT. Antigen-pulsing experiments localized the inhibition to the level of antigen-presenting cell (APC). GT-prepulsed APC are not inhibitory in cell-mixing experiments and can present other antigens. GT only inhibits the nominal antigen-directed component of a GAT-specific, autoreactive hybrid's response. Together these findings suggest that GT causes inhibition by competing for GAT association at the accessory cell. GT interferes with GAT presentation by an I-Adxb F1 APC to a BALB/c, I-Ad-restricted, but not B10, I-Ab-restricted, T cell hybridoma, and GT inhibits presentation by GAT-prepulsed APC. The implications of these findings for MHC-restricted presentation of antigen are discussed.

Use of somatic cell genetics to study chromosomes contributing to antigen plus I recognition by T cell hybridomas

Keyhole limpet hemocyanin (KLH)/I region-specific T cell hybridomas have been prepared by fusing KLH/I-specific T cell blasts from mice with single pairs of metacentric chromosomes to the inducible, interleukin 2 (IL-2)-secreting T cell hybridoma FS6-14.13.AG2.1. T cell hybridomas with KLH/I receptors were identified by their ability to secrete IL-2 in response to KLH and the appropriate antigen-presenting cells. After cloning and subcloning, KLH/I reactivity was correlated with the presence or absence of metacentric chromosomes derived from the KLH/I-specific T cell blast parent. Hybridomas were identified that had lost all chromosomes 4 and 6 or 16 and 17 derived from their normal T cell parent, but retained the ability to respond to KLH/I. This suggested that products of genes on these chromosomes did not contribute to the specific portions of T cell Ag/I receptors. These gene products would include, of course, kappa and lambda chains and H-2. We did not obtain any T cell hybridomas that had lost both metacentric (8.12) chromosomes derived from T cells of the Robertsonian mouse strain Rb(8.12)5, so we could not draw any conclusions about the contributions of products of genes on these chromosomes. T cell hybridomas with KLH/I reactivity were found that contained only one metacentric (8.12) chromosome derived from this strain. Moreover, a T cell hybridoma was found that retained both metacentric (8.12) chromosomes from its normal T cell parent, but had lost KLH/I reactivity. These results suggested that neither two chromosomes 8 nor two chromosomes 12 were required for antigen/I reactivity in normal T cells and that antigen/I reactivity was controlled, at least in part, by genes mapping on chromosomes other than 8 or 12.

Autoantigens in an immunological network

An autoantigen network, consisting of all non-lymphoid cells and a subset of peripherally located autoregulatory lymphocytes, is proposed. By equilibrating a web of idiotypic stimulation (helper activity) and antiidiotypic inhibition (suppressor activity) directed at each tissue differentiation antigen, this network quantitatively limits autoantigen expression and thereby regulates the differentiation and growth homeostatic processes these autoantigens mediate. Perturbations of the network's dynamic equilibrium secondary to viral infection, somatic mutation, or interaction with environmental agents would clinically manifest themselves as autoimmune tissue destruction, benign or malignant nonlymphoid neoplasia, and lymphoproliferative disorders.

Tolerance of thymocytes to allogeneic I region determinants encountered prethymically. Evidence for expression of anti-Ia receptors by T cell precursors before their entry into the thymus

The present study has assessed whether precursor T cells express receptors specific for the recognition of allogeneic I region-encoded determinants before their entry into the thymus. Because the ability of thymocytes to proliferate in response to allogeneic stimulator cells was shown to primarily result from the recognition of allogeneic I region determinants, thymocytes must already express anti-Ia receptors. In contrast, the expression of anti- Ia receptors by functionally immature thymocyte precursors could not be directly assessed by mixed lymphocyte reaction reactivity. However, expression of anti-Ia receptors by thymocyte precursors could be assessed by their ability to be specifically tolerized by the allogeneic Ia determinants that they encountered during their differentiation. To determine whether T cell precursors could specifically recognize and be tolerized to allogeneic Ia determinants expressed prethymically, thymus- engrafted radiation bone marrow chimeras were constructed [A {arrow} A x B (Tx + A Thy)] such that strain A T cells would be differentiating within a syngeneic strain A thymus but would have been previously exposed to the allogeneic strain B Ia determinants of the irradiated A x B host. The strain A thymocytes from these experimental animals were indeed tolerant to the extrathymic allogeneic strain B Ia determinants expressed by the irradiated host. Such tolerance was not mediated by detectable suppression and was not explained by the presence intrathymically of extrathymic allogeneic Ia determinants. Thus, these results suggest that T cell precursors can be specifically tolerized entry into the thymus. In addition, the failure to detect the generation of thymocytes with specificity for the allogeneic Ia determinants of the irradiated host, which were not deleted prethymically, argues that novel anti-allo Ia receptor specificities are not generated intrathymically.

T cell idiotypes recognizing self-major histocompatibility complex molecules: H-2 specificity, allotype linkage, and expression on functional T cell populations

An anti-idiotypic serum (antiserum 5936, B. Rubin et al., J. Exp. Med. 1979. 150: 307) was used to demonstrate receptor sites for self-major histocompatibility complex (MHC) antigens on T lymphocytes. The antiserum was raised by injecting rabbits tolerant to mouse Ig with a B6 anti-CBA (anti-H2k) alloantibody. It recognized a large proportion of T cells from H-2k strains carrying the b, c, d or e allele at the Igh-1 locus, but only a few T cells from H-2k strains with Igh-1 alleles a, f and j. Allotype linkage of the 5936 idiotype was also demonstrated by segregation analysis. The antiserum did not recognize either H-2k B cells or T cells from other H-2 haplotypes despite the presence of a permissive Igh-1 allele. The 5936 idiotype was found to be associated with several different antigen specificities, indicating that it is not located on the binding site for foreign antigen. Furthermore, the 5936 antiserum inhibited the binding of soluble Ik antigens by H-2k, Igh-1b, T cells, and, in the presence of complement, eliminated T cells responding to different antigens in an I-Ak-restricted fashion. Collectively, the data indicate that the structure bearing the 5936 idiotype is a receptor for I-Ak antigens, expressed by strains carrying the I-Ak allele and a permissive allele at the Igh-1 locus. The relevance of this finding to the MHC-restricted recognition of antigens by T cells is discussed.

Histocompatibility antigens on astrocytoma cells

Biopsies tumour cells from astrocytoma-bearing patients were grown in primary culture for 3-5 days. Both low and high grade tumours were represented in the study. The cultured cells could be shown to express the HLA-A and -B antigens using a multispecific allo-antiserum and a rabbit anti-beta-2 microglobulin antibody. The tumour cells were negative for the HLA-DR determinants when tested with either rabbit anti-Ia-like antisera or specific anti-HLA-DR allo-antisera. They also failed to stimulate allogeneic lymphocytes in primary mixed lymphocyte-tumour cell cultures but stimulated lymphocytes primed to tumour cells in vitro. The tumour cells were also capable of stimulating autologous lymphocytes from the tumour-bearing patient in most of the combinations tested.

Tolerance of thymic cytotoxic T lymphocytes to allogeneic H-2 determinants encountered prethymically: evidence for expression of anti-H-2 receptors prior to entry into the thymus

This study has assessed the possibility that anti-H-2 receptors are expressed on T-cell precursors prior to their entry into the thymus. Parental strain A thymus was transplanted into either normal or thymectomized (A x B)F1 mice which were then irradiated and reconstituted with strain A bone marrow. The cells repopulating the engrafted strain A thymus were shown to be of donor bone marrow origin. Thus, strain A thymocytes were differentiating within a syngeneic thymus, after exposure to allogeneic strain B major histocompatibility complex (MHC) determinants of the irradiated F1 host. The cells repopulating the engrafted thymus were assessed for their ability to generate alloreactive cytotoxic T lymphocyte responses and were found to be specifically tolerant to allogeneic strain B MHC determinants. This tolerance existed in the absence of detectable suppression and in the absence of detectable strain B MHC determinants intrathymically. These data are most consistent with the concept that precursor T cells express anti-MHC receptors prior to their entry into the thymus and that exposure to MHC determinants prethymically results in their functional inactivation.

HLA antigens on glioma cells from short term cultures

Biopsied tumor cells from astrocytoma-bearing patients were grown in primary culture for 3-5 days. Both low and high grade tumors were represented in the study. The cultured cells could be shown to express the HLA-A and -B antigens using a multispecific allo-antiserum and a rabbit anti-beta-2 microglobulin antibody. The tumor cells were negative for the HLA-DR determinants when tested with either a rabbit anti-Ia-like antisera or specific anti-HLA-DR allo-antisera. They also failed to stimulate allogeneic lymphocytes in primary mixed lymphocyte-tumor cell cultures but moderately stimulated autologous lymphocytes from the tumor-bearing patient in most of the combinations tested.

Immune response gene function correlates with the expression of an Ia antigen. II. A quantitative deficiency in Ae:E alpha complex expression causes a corresponding defect in antigen-presenting cell function

A series of experiments were performed to explore the role of complementing major histocompatability complex (MHC)-linked immune response Ir genes in the murine T cell proliferative response to the globular protein antigen pigeon cytochrome c. The functional equivalence of I-E-subregion-encoded, structurally homologous E(a) chains from different haplotypes bearing the serologic specificity Ia.7 was demonstrated by the complementation for high responsiveness to pigeon cytochrome c of F(1) hybrids between low responder B 10.A(4R) (I-A (k)) or B 10.S (I-A(8)) mice and four low responder E(a)- bearing haplotypes. Moreover, this Ir gene function correlated directly with both the ability of antigen-pulsed spleen cells from these same F(1) strains to stimulate pigeon cytochrome c-primed T cells from B10.A or B10.S(9R) mice, and with the cell surface expression of the two-chain Ia antigenic complex, A(e):E(a), bearing the conformational or combinatorial determinant recognized by the monoclonal anti-Ia antibody, Y-17. The B 10.PL strain (H-2(u)), which expresses an Ia.7-positive I-E- subregion-encoded E(a) chain, failed to complement with B10.A(4R) or B10.S mice in the response to pigeon cytochrome c. However, (B10.A(4R) x B10.PL)F(1) and (B10.S x B10.PL)F(1) mice do express A(k)(e):E(u)(a) and A(8)(e):E(u)(a) on their cell surface, although in reduced amounts relative to A(k,s)(e):E(k,d,p,r)(a) complexes found in corresponding F(1) strains. This quantitative difference in Ia antigen expression correlated with a difference in the ability to present pigeon cytochrome c to B 10.A and B 10.S(9R) long-term T cell lines. Thus, (B10.A(4R) x B10.PL)F(1) spleen cells required a 10-fold higher antigen dose to induce the same stimulation as (B10.A(4R) x B10.D2)F(1) spleen cells. In addition, the monoclonal antibody, Y-17, which reacts with A(e):E(a) molecules of several strains, had a greater inhibitory effect on the proliferative response to pigeon cytochrome c of B10.A T cells in the presence of (B10.A(4R) X B10.PL)F(1) spleen cells than in the presence of (B10.A(4R) X B10.D2)F(1) spleen cells. These functional data, in concert with the biochemical and serological data in the accompanying report, are consistent with the molecular model for Ir gene complementation in which appropriate two-chain Ia molecules function at the antigen-presenting cell (APC) surface as restriction elements. Moreover, they clearly demonstrate that the magnitude of the T cell proliferative response is a function of both the concentration of nominal antigen and of the amount of Ia antigen expressed on the APC. Finally, the direct correlation of a quantitative deficiency in cell surface expression of an Ia antigen with a corresponding relative defect in antigen-presenting function provides strong independent evidence that the I-region-encoded Ia antigens are the products of the MHC-linked Ir genes.