Rearrangement and expression of T-cell antigen receptor genes in human T-lymphocyte tumor lines and normal human T-cell clones: evidence for allelic exclusion of Ti beta gene expression and preferential use of a J beta 2 gene segment

Targeting self-antigens through allogeneic TCR gene transfer

Adoptive transfer of T-cell receptor (TCR) genes has been proposed as an attractive approach for immunotherapy in cases where the endogenous T-cell repertoire is insufficient. While there are promising data demonstrating the capacity of TCR-modified T cells to react to foreign antigen encounter, the feasibility of targeting tumor-associated self-antigens has not been addressed. Here we demonstrate that T-cell receptor gene transfer allows the induction of defined self-antigen-specific T-cell responses, even when the endogenous T-cell repertoire is nonreactive. Furthermore, we show that adoptive transfer of T-cell receptor genes can be used to induce strong antigen-specific T-cell responsiveness in partially MHC-mismatched hosts without detectable graft versus host disease. These results demonstrate the feasibility of using a collection of "off the shelf" T-cell receptor genes to target defined tumor-associated self-antigens and thereby form a clear incentive to test this immunotherapeutic approach in a clinical setting.

T-cell receptor delta-chain can substitute for alpha to form a beta delta heterodimer

Specific monoclonal antibodies have made possible the identification of two T-cell antigen receptor (TCR) heterodimers, alpha beta TCR and gamma delta TCR. Formation of these receptors is largely separated by the preferential pairing of alpha-TCR with beta and gamma-TCR with delta, the sequential rearrangement and expression of the TCR loci during thymic development and the deletion of the delta-loci either prior to or concomitant with alpha-rearrangement in alpha beta TCR cells. Here we show that delta-TCR can substitute for alpha in pairing with beta to form a beta delta heterodimer. This receptor is expressed on the cell surface of the T-leukaemia cell line DND41 as analysed with beta- and delta-specific monoclonal antibodies. We suggest that a variety of factors including, for example, the deletion of the delta-TCR loci, can now be understood as exclusion mechanisms operating to prevent not only the formation of gamma delta receptors, but also of beta delta T-cell receptors, thereby promoting the numerically dominant alpha beta TCR lineage. Nevertheless, some developing T-cells that do not rearrange the alpha-loci may express the beta delta TCR as described here.

A susceptibility locus for multiple sclerosis is linked to the T cell receptor beta chain complex

Inheritance of T cell receptor beta chain (TCR beta) genes was analyzed in families of 40 sibling pairs concordant for the relapsing-remitting form of multiple sclerosis (MS). TCR beta haplotypes were determined by segregation analysis of polymorphic markers within the TCR beta complex. The mean proportion of TCR beta haplotypes identical by descent (IBD) inherited by MS sibling pairs was significantly increased compared with expected values (means test, p less than 0.004), whereas the distribution of haplotype sharing was random when MS patients were compared with their unaffected siblings. Furthermore, one allelic form of a TCR beta variable region gene segment was overrepresented on MS chromosomes compared with those parental chromosomes not transmitted to MS offspring both in the MS sibling pair families and in a second group of families containing only one individual affected with MS. These results demonstrate that a gene within the TCR beta complex or a closely linked locus influences susceptibility to MS.

A simple method for DNA purification from peripheral blood

A new, simple, and inexpensive method for the rapid isolation of DNA from whole blood is described. Cell nuclei are prepared by lysis of cytoplasmic membranes and DNA within the nuclear pellet is dispersed with guanidine isothiocyanate and precipitated with isopropanol. DNA prepared in this way restricts completely and results in low backgrounds of nonspecific hybridization after Southern analysis. The yields of DNA are similar to those obtained by more tedious traditional procedures. Numerous genomic DNA samples can be prepared from whole blood in 2 h, thus facilitating gene linkage or other molecular studies in which large numbers of individuals are required.

A solubilized T-cell receptor from a human leukemia cell line binds to a ligand in the absence of MHC products

A human T cell alpha beta antigen receptor from the acute lymphoblastoid leukemia line HPB-ALL (also called HPB-MLT) binds and is precipitated in detergent-solubilized form by an antigen present on the surface and secreted by several strains of the gram-positive bacterium Staphylococcus aureus. This binding is completely independent of major histocompatibility complex (MHC) antigens. Receptor/ligand binding is unique to this one cell line (i.e., clonotypic) and furthermore completely blocked by an idiotype-specific monoclonal antibody (mAb) to this receptor, but not by three different nonidiotype-specific mAbs. The nature of this interaction appears more similar to immunoglobulin/antigen binding than to T-cell receptor/antigen/MHC/accessory molecule interactions and would suggest that some T-cell receptors may not require MHC products to interact with antigen.

T-cell receptor gene rearrangement and expression in human natural killer cells: natural killer activity is not dependent on the rearrangement and expression of T-cell receptor alpha, beta, or gamma genes

To test the hypothesis that the T-cell receptor (Tcr) gamma gene encodes a natural killer (NK) cell receptor molecule, three human NK clones and fresh peripheral blood lymphocytes with NK activity from two patients with a CD16+ lymphocytosis were analyzed for rearrangements and expression of the human Tcr alpha, beta, and gamma genes. Two of the clones displayed distinct rearrangements of their Tcr beta and gamma genes and expressed mature Tcr alpha, beta, and gamma RNA. However, one of the clones and both patient samples displayed marked NK activity but failed to rearrange or express any of their Tcr genes. These findings demonstrate that human natural killer activity is not dependent on Tcr gamma gene rearrangement and expression. In addition, they confirm previous findings concerning the lack of Tcr alpha and beta gene expression in some natural killer cells. Thus, they suggest the existence of additional NK-specific recognition molecules.

T cell receptor gamma chain variable gene rearrangements in acute lymphoblastic leukemias of T and B lineage

The status of immunoglobulin and T cell receptor genes in acute lymphoblastic leukemia (ALL) of T and B lineage has been studied. Our data indicate that illegitimate gene rearrangements at immunoglobulin heavy chain (in T cell ALL), and T cell receptor beta chain (in pre-B ALL) genes are only rarely found (2 out of 30 patients). In contrast, T cell receptor gamma chain gene rearrangements, characteristically found in T-ALL, are also present in 7 of 18 patients with pre-B ALL. Several features distinguish these illegitimate T cell receptor gamma chain gene rearrangements from those in normal and leukemic T cells. V gamma genes located far upstream of the J gamma/C gamma complexes (V gamma 2, V gamma 3, V gamma 4, V gamma 5) appear to be preferentially used in normal adult peripheral blood T cells. In contrast, V gamma genes located immediately 5' to the J gamma/C gamma complexes (V gamma 8, V gamma 9, V gamma 10, V gamma 11) predominate in V gamma -J gamma recombinations observed in T-ALL and pre-B ALL. Whereas the J gamma 2 region is primarily used in T cell receptor gamma gene rearrangements observed in T-ALL, those in pre-B ALL are confined mostly to the J gamma 1 region. These data suggest a limited accessibility of the T cell receptor gamma chain gene locus for recombination processes in early stages of B cell differentiation.

Constitutive functional heterogeneity without detectable somatic mutation of antigen receptor genes in helper T cell clones: possible regulation by novel HLA class II "DY" determinants

The majority of interleukin 2-dependent HLA class II alloreactive human CD4-positive helper T-cell clones (TCC) presented the phenomenon of constitutive intraclonal heterogeneity, as reflected by limiting dilution analysis of changing frequencies of autonomously proliferative cells within the monoclonal population. Moreover, at 30-35 population doublings, these TCC lost their allospecific proliferative and helper capacity (phase I) and instead acquired strong antigen-non-specific suppressive activity (phase II). The TCR was still expressed at the same level on the cell surface. As shown by stable and identical rearrangement profiles of their T-cell receptor beta- and gamma-chain genes in both phases I and II, this constitutive change of function was probably not due to somatic mutation of the genes coding for the antigen-specific receptor. Moreover, antigen specific reactivity was retained in phase II TCC by the criterion of specifically stimulated secretion of granulocyte/macrophage colony stimulating factor. The preprogrammed intra-clonal functional flexibility is explained here by invoking a novel regulatory mechanism mediated by a fourth group of HLA class II determinants. When TCC were used as stimulators with the appropriate primed responders, it could be demonstrated that phase I autonomously proliferative non-suppressive T-helper lines failed to express certain novel lymphocyte activating determinants (LADs), whereas after their acquisition of suppressive function (phase II) these LADs were present. These stimulatory moieties appeared to represent a novel class II-like structure as established by serology, immunochemistry and functional characterization employing monoclonal antibodies to block stimulation. These operationally designated "DY" determinants are primarily and thus far exclusively involved in the induction of antigen non-specific suppressor cells. It is proposed that the intra-clonal changes of T-cell function described here are mediated by a switch in the utilization of qualitatively distinct class II-like restriction elements. The functional status of the phase I TCC can be altered by a switching over to the engagement of "DY" determinants in phase II. Thus, an autostimulatory and self-maintaining suppressive network may operate in extended inductive phases of human HLA restricted T-cell responses.

The complete primary structure of the T-cell receptor genes from an alloreactive cytotoxic human T-lymphocyte clone

The complete primary structure of the cDNAs encoding the alpha and beta chains of the T-lymphocyte receptor for antigen from a human alloreactive, cytotoxic T-cell clone, L17, is presented. Sequence analysis of these genes reveals that both are related to immunoglobulins and are composed of variable, diversity (at least in the case of the Ti beta clone), joining, and constant region sequences. Comparison of the sequence of the alpha-chain cDNA to that of previously sequenced mouse and human alpha cDNAs suggests the presence of human T-cell receptor alpha D-region sequences. Southern blot analysis confirms the finding that these cDNAs represent the functional receptor genes expressed by the L17 cytotoxic T-cell clone. The availability of these full-length T-cell receptor cDNA clones from a human T-lymphocyte clone of known antigen specificity should allow an analysis of the relationship between T-cell receptor structure and function.