Secretion of HLA-A and -B antigens via an alternative RNA splicing pathway.

Human class I major histocompatibility antigens (HLA-A, -B and -C) are integral membrane protein heterodimers, which are anchored in the membrane via a stretch of hydrophobic amino acids near the carboxyl terminus of the heavy chain. It has previously been shown that a mutagenized cell line secretes a water soluble form of the HLA-A2 antigen, due to a pattern of RNA splicing that removes exon 5 (encoding the transmembrane hydrophobic amino acids) from mature, HLA-A2--encoding transcripts. The present study was undertaken to assess whether a similar process might be operative in nonmutagenized cells. It is shown that water soluble class I molecules (primarily HLA-A24) are secreted by the T leukemic cell line HPB-ALL, and that alternative splicing removes exon 5 from a fraction of HLA-A24--encoding transcripts. It is further shown that class I molecules are secreted, possibly in an allele-specific fashion, from a variety of tumor cells and normal cells. The possible relationship between these findings and previous reports of HLA-A and -B antigens in human serum is discussed.

Endocytosis and recycling of the T3-T cell receptor complex. The role of T3 phosphorylation.

An assay has been developed to assess the dynamics of cell surface glycoproteins, in which neuraminidase digestion of intact cells is used to determine the fate of cell surface molecules initially labelled via lactoperoxidase-catalyzed iodination. This approach has been used to demonstrate the constitutive endocytosis and recycling of the T3-T cell receptor (T CR) complex on the human T leukemic cell line HPB-MLT. Stable populations of both phosphorylated and nonphosphorylated forms of the T3 gamma peptide have been identified in these cells. Whereas the former are constitutively endocytosed, the latter appear to be excluded from this pathway. The results presented indicate that T3 gamma phosphorylation may control the endocytosis and recycling of the T3-TCR complex on this cell line.

Enhancer-dependent and -independent steps in the rearrangement of a human T cell receptor delta transgene.

The rearrangement and expression of T cell receptor (TCR) gene segments occurs in a highly ordered fashion during thymic ontogeny of T lymphocytes. To study the regulation of gene rearrangement within the TCR alpha/delta locus, we generated transgenic mice that carry a germline human TCR delta minilocus that includes V delta 1, V delta 2, D delta 3, J delta 1, J delta 3, and C delta segments, and either contains or lacks the TCR delta enhancer. We found that the enhancer-positive construct rearranges stepwise, first V to D, and then V-D to J. Construct V-D rearrangement mimics a unique property of the endogenous TCR delta locus. V-D-J rearrangement is T cell specific, but is equivalent in alpha/beta and gamma/delta T lymphocytes. Thus, either there is no commitment to the alpha/beta and gamma/delta T cell lineages before TCR delta gene rearrangement, or if precommitment occurs, it does not operate directly on TCR delta gene cis-acting regulatory elements to control TCR delta gene rearrangement. Enhancer-negative mice display normal V to D rearrangement, but not V-D to J rearrangement. Thus, the V-D to J step is controlled by the enhancer, but the V to D step is controlled by separate elements. The enhancer apparently controls access to J delta 1 but not D delta 3, suggesting that a boundary between two independently regulated domains of the minilocus lies between these elements. Within the endogenous TCR alpha/delta locus, this boundary may represent the 5' end of a chromatin regulatory domain that is opened by the TCR delta enhancer during T cell development. The position of this boundary may explain the unique propensity of the TCR delta locus to undergo early V to D rearrangement. Our results indicate that the TCR delta enhancer performs a crucial targeting function to regulate TCR delta gene rearrangement during T cell development.

Temporal and lineage-specific control of T cell receptor alpha/delta gene rearrangement by T cell receptor alpha and delta enhancers.

To analyze the regulation of gene rearrangement at the T cell receptor (TCR) alpha/delta locus during T cell development, we generated transgenic mice carrying a human TCR delta gene minilocus. We previously showed that the presence of the TCR delta enhancer (E delta) within the J delta 3-C delta intron was required to activate a specific step (V-D to J) of transgene rearrangement, and that rearrangement was activated equivalently in the precursors of alpha beta and gamma delta T cells. To further explore the role of transcriptional enhancers in establishing the developmental pattern of gene rearrangement at the TCR alpha/delta locus, we substituted the TCR alpha enhancer (E alpha) in place of E delta within the transgenic minilocus. We found that V-D-J rearrangement of the E alpha+ minilocus was restricted to the alpha beta T cell subset. Further, we found that although V-D-J rearrangement of the E delta+ minilocus was initiated in the fetal thymus by day 14.5, V-D-J rearrangement of the E alpha+ minilocus did not occur until fetal day 16.5. Finally, whereas V-D-J rearrangement of the E delta+ minilocus is essentially completed within the triple negative population of postnatal thymocytes, V-D-J rearrangement of the E alpha+ minilocus is only initiated late within this population. Since the properties of minilocus rearrangement under the control of E delta and E alpha parallel the properties of V delta-D delta-J delta and V alpha-J alpha rearrangement at the endogenous TCR alpha/delta locus, we conclude that these enhancers play an important role in orchestrating the developmental program of rearrangements at this locus.

Regulation of T cell receptor delta gene rearrangement by c-Myb.

Developmental activation of VDJ recombination at the T cell receptor (TCR) delta locus is controlled by an intronic transcriptional enhancer (E delta). Transcriptional activation by E delta is dependent on c-Myb. To determine whether c-Myb plays a role in the activation of TCR-delta gene rearrangement, we compared VDJ recombination in transgenic mice carrying two versions of a human TCR-delta gene minilocus recombination substrate. One includes a wild-type E delta, whereas the other carries an E delta with a mutation that abrogates c-Myb binding. We demonstrate that an intact Myb binding site is necessary for efficient rearrangement of the minilocus substrate, suggesting that c-Myb plays a crucial role in activating VDJ recombination at the endogenous TCR-delta locus.

Developmental regulation of VDJ recombination by the core fragment of the T cell receptor alpha enhancer.

The role of T cell receptor alpha enhancer (E alpha) cis-acting elements in the developmental regulation of VDJ recombination at the TCR alpha/delta locus was examined in transgenic mice containing variants of a minilocus VDJ recombination substrate. We demonstrate that the 116-bp T alpha 1,2 core enhancer fragment of the 1.4-kb E alpha is sufficient to activate the enhancer-dependent step of minilocus rearrangement, and that within T alpha 1,2, intact binding sites for TCF/LEF and Ets family transcription factors are essential. Although minilocus rearrangement under the control of the 1.4-kb E alpha initiates at fetal day 16.5 and is strictly limited to alpha beta T cells, we find that rearrangement under the control of T alpha 1,2 initiates slightly earlier during ontogeny and occurs in both gamma delta and alpha beta T cells. We conclude that the core fragment of E alpha can establish accessibility to the recombinase in developing thymocytes in vivo in a fashion that is dependent on the binding of TCF/LEF and Ets family transcription factors, but that these and other factors that bind to the E alpha core cannot account for the precise developmental onset of accessibility that is provided by the intact E alpha. Rather, our data suggests a critical role for factors that bind E alpha outside of the core T alpha 1,2 region in establishing the precise developmental onset of TCR alpha rearrangement in vivo.

HLA-A2 mutants immunoselected in vitro. Definition of residues contributing to an HLA-A2-specific serological determinant.

The HLA-A2-specific mouse monoclonal antibody BB7.2 plus complement has been used to immunoselect variant clones of the lymphoblastoid cell line T5-1 (HLA-A1, -A2, -B8, and -B27). Members of one class of variant clones appear to express cell surface HLA-A2 molecules that display reduced reactivity with the selecting antibody, but normal or near normal reactivities with some other HLA-A2-specific monoclonal antibodies and human alloantisera. The HLA-A2 heavy chains derived from two of these variant clones were characterized by comparative double-label tryptic peptide mapping in conjunction with microsequence analysis. These heavy chains were found to carry distinct mutations in the same peptide in the molecule. We conclude that residues within this short segment of the polypeptide contribute to an HLA-A2-specific serological determinant.

Regulation of T cell receptor delta gene rearrangement by CBF/PEBP2.

We have analyzed transgenic mice carrying versions of a human T cell receptor (TCR)-delta gene minilocus to study the developmental control of VDJ (variable/diversity/joining) recombination. Previous data indicated that a 1.4-kb DNA fragment carrying the TCR-delta enhancer (E(delta)) efficiently activates minilocus VDJ recombination in vivo. We tested whether the transcription factor CBF/PEBP2 plays an important role in the ability of E(delta) to activate VDJ recombination by analyzing VDJ recombination in mice carrying a minilocus in which the deltaE3 element of E(delta) includes a mutated CBF/PEBP2 binding site. The enhancer-dependent VD to J step of minilocus rearrangement was dramatically inhibited in three of four transgenic lines, arguing that the binding of CBF/PEBP2 plays a role in modulating local accessibility to the VDJ recombinase in vivo. Because mutation of the deltaE3 binding site for the transcription factor c-Myb had previously established a similar role for c-Myb, and because a 60-bp fragment of E(delta) carrying deltaE3 and deltaE4 binding sites for CBF/PEBP2, c-Myb, and GATA-3 displays significant enhancer activity in transient transfection experiments, we tested whether this fragment of E(delta) is sufficient to activate VDJ recombination in vivo. This fragment failed to efficiently activate the enhancer-dependent VD to J step of minilocus rearrangement in all three transgenic lines examined, indicating that the binding of CBF/PEBP2 and c-Myb to their cognate sites within E(delta), although necessary, is not sufficient for the activation of VDJ recombination by E(delta). These results imply that CBF/PEBP2 and c-Myb collaborate with additional factors that bind elsewhere within E(delta) to modulate local accessibility to the VDJ recombinase in vivo.

A distinct wave of human T cell receptor gamma/delta lymphocytes in the early fetal thymus: evidence for controlled gene rearrangement and cytokine production.

The rearrangement and expression of human T cell receptor (TCR)-gamma and -delta gene segments in clonal and polyclonal populations of early fetal and postnatal human TCR-gamma/delta thymocytes were examined. The data suggest that the TCR-gamma and -delta loci rearrange in an ordered and coordinated fashion. Initial rearrangements at the TCR-delta locus join V delta 2 to D delta 3, and initial rearrangements at the TCR-gamma locus join downstream V gamma gene segments (V gamma 1.8 and V gamma 2) to upstream J gamma gene segments associated with C gamma 1. These rearrangements are characterized by minimal junctional diversity. At later times there is a switch at the TCR-delta locus such that V delta 1 is joined to upstream D delta gene segments, and a switch at the TCR-gamma locus such that upstream V gamma gene segments are joined to downstream J gamma gene segments associated with C gamma 2. These rearrangements are characterized by extensive junctional diversity. Programmed rearrangement explains in part the origin of discrete subpopulations of peripheral blood TCR-gamma/delta lymphocytes that have been defined in previous studies. In addition, cytokine production by early fetal and postnatal TCR-gamma/delta thymocyte clones was examined. Fetal thymocyte clones produced significant levels of IL-4 and IL-5 following stimulation, whereas postnatal thymocyte clones did not produce these cytokines. Thus, these cell populations may represent functionally distinct subsets as well.

Diversity and organization of human T cell receptor delta variable gene segments.

Previous studies of the human TCR-delta gene identified a single commonly used V delta segment, denoted V delta 1. To better understand the extent of the human TCR-delta V gene repertoire, TCR-delta transcripts and gene rearrangements were examined in a new panel of cloned human TCR-gamma/delta lymphocytes. Through this analysis we identified and determined the structures of two new V delta segments, denoted V delta 2 and V delta 3. These V delta segments are different from previously characterized V alpha segments, supporting the notion that the human V delta and V alpha repertoires are distinct. Examination of V gamma gene segment usage in these cells reveals that the V delta 2 gene segment is used in conjunction with the V gamma 2 gene segment. Blot hybridization indicates that the V delta 2 gene segment lies between V delta 1 and D delta-J delta-C delta, and within 100 kb of the latter. Analysis of genomic clones indicates that the V delta 3 gene segment lies in an inverted orientation, approximately 2 kb 3' of C delta. This implies that rearrangement of V delta 3 to D delta-J delta-C delta occurs by inversion. Together with previous mapping studies, these results indicate that human V delta segments are dispersed, rather than clustered, within the TCR-alpha/delta locus. The analysis of rearrangements in polyclonal thymocyte DNA suggests that there may be a limited number of additional V delta gene segments yet to be characterized.

Identification of putative human T cell receptor delta complementary DNA clones.

A novel T cell receptor (TCR) subunit termed TCR delta, associated with TCR gamma and CD3 polypeptides, was recently found on a subpopulation of human T lymphocytes. T cell-specific complementary DNA clones present in a human TCR gamma delta T cell complementary DNA library were obtained and characterized in order to identify candidate clones encoding TCR delta. One cross-hybridizing group of clones detected transcripts that are expressed in lymphocytes bearing TCR gamma delta but not in other T lymphocytes and are encoded by genes that are rearranged in TCR gamma delta lymphocytes but deleted in other T lymphocytes. Their sequences indicate homology to the variable, joining, and constant elements of other TCR and immunoglobulin genes. These characteristics, as well as the immunochemical data presented in a companion paper, are strong evidence that the complementary DNA clones encode TCR delta.

A role for histone acetylation in the developmental regulation of VDJ recombination.

VDJ recombination is developmentally regulated in vivo by enhancer-dependent changes in the accessibility of chromosomal recombination signal sequences to the recombinase, but the molecular nature of these changes is unknown. Here histone H3 acetylation was measured along versions of a transgenic VDJ recombination reporter and the endogenous T cell receptor alpha/delta locus. Enhancer activity was shown to impart long-range, developmentally regulated changes in H3 acetylation, and H3 acetylation status was tightly linked to VDJ recombination. H3 hyperacetylation is proposed as a molecular mechanism coupling enhancer activity to accessibility for VDJ recombination.

A T cell-specific transcriptional enhancer within the human T cell receptor delta locus.

The T cell antigen receptor (TCR) delta gene is located within the TCR alpha locus. A T cell-specific transcriptional enhancer, distinct from the TCR alpha enhancer, has been identified within the J delta 3-C delta intron of the human T cell receptor delta gene. This enhancer activates transcription from the V delta 1 and V delta 3 promoters as well as from heterologous promoters. Enhancer activity has been localized to a 250-bp region that contains multiple binding sites for nuclear proteins. Thus, transcriptional control of the TCR delta and TCR alpha genes is mediated by distinct regulatory elements.

Structurally divergent human T cell receptor gamma proteins encoded by distinct C gamma genes.

The human T cell receptor (TCR) gamma polypeptide occurs in structurally distinct forms on certain peripheral blood T lymphocytes. Complementary DNA clones representing the transcripts of functionally rearranged TCR gamma genes in these cells have been analyzed. The expression of a disulfide-linked and a nondisulfide-linked form of TCR gamma correlates with the use of the C gamma 1 and C gamma 2 constant-region gene segments, respectively. Variability in TCR gamma polypeptide size and disulfide linkage is determined by the number of copies and the sequence of a repeated segment of the constant region. Thus C gamma 1 and C gamma 2 are used to generate structurally distinct, yet functional, T3-associated receptor complexes on peripheral blood lymphocytes. Tryptic peptide mapping suggests that the T3-associated TCR gamma and delta peptides in the nondisulfide-linked form are distinct.

Immunochemical proof that a novel rearranging gene encodes the T cell receptor delta subunit.

The T cell receptor (TCR) delta protein is expressed as part of a heterodimer with TCR gamma, in association with the CD3 polypeptides on a subset of functional peripheral blood T lymphocytes, thymocytes, and certain leukemic T cell lines. A monoclonal antibody directed against TCR delta was produced that binds specifically to the surface of several TCR gamma delta cell lines and immunoprecipitates the TCR gamma delta as a heterodimer from Triton X-100 detergent lysates and also immunoprecipitates the TCR delta subunit alone after chain separation. A candidate human TCR delta complementary DNA clone (IDP2 O-240/38), reported in a companion paper, was isolated by the subtractive library approach from a TCR gamma delta cell line. This complementary DNA clone was used to direct the synthesis of a polypeptide that is specifically recognized by the monoclonal antibody to TCR delta. This complementary DNA clone thus corresponds to the gene that encodes the TCR delta subunit.

Extensive junctional diversity of rearranged human T cell receptor delta genes.

The human T cell receptor delta (TCR delta) gene encodes one component of the TCR gamma delta-CD3 complex found on subsets of peripheral blood and thymic T cells. Human TCR delta diversity was estimated by characterizing rearrangements in TCR gamma delta cell lines and determining the structures of complementary DNA clones representing functional and nonfunctional transcripts in these cell lines. One V delta segment and one J delta segment were identified in all functional transcripts, although a distinct J delta segment was identified in a truncated transcript. Further, one D delta element was identified, and evidence for the use of an additional D delta element was obtained. Thus human TCR delta genes appear to use a limited number of germline elements. However, the apparent use of two D delta elements in tandem coupled with imprecise joining and extensive incorporation of N nucleotides generates unprecedented variability in the junctional region.

c-Myb and core-binding factor/PEBP2 display functional synergy but bind independently to adjacent sites in the T-cell receptor delta enhancer.

A T-cell-specific transcriptional enhancer lies within the J delta 3-C delta intron of the human T-cell receptor delta gene. We have previously shown that a 30-bp element, denoted delta E3, acts as the minimal TCR delta enhancer and that within delta E3, adjacent and precisely spaced binding sites for core-binding factor (CBF/PEBP2) and c-Myb are essential for transcriptional activity. These data suggested that CBF/PEBP2 and c-Myb synergize to mediate transcriptional activity but did not establish the molecular basis for synergy. In this study, we have examined in detail the binding of CBF/PEBP2 and c-Myb to delta E3. We found that CBF/PEBP2 and c-Myb could simultaneously occupy the core site and one of two overlapping Myb sites within delta E3. However, equilibrium binding and kinetic dissociation experiments suggest that the two factors bind to delta E3 independently, rather than cooperatively. This was found to be true by using isoforms of these factors present in extracts of transfected COS-7 cells, as well as the natural factors present in nuclear extracts of the Jurkat T-cell line. We further showed that CBF/PEBP2 and c-Myb provide unique transactivation functions, since the core-Myb combination cannot be substituted by dimerized core or Myb sites. We propose that spatially precise synergy between CBF/PEBP2 and c-Myb may result from the ability of the two factors to form a composite surface that makes unique and stereospecific contacts with one or more additional components of the transcriptional machinery.

Regulation of the T-cell receptor delta enhancer by functional cooperation between c-Myb and core-binding factors.

A T-cell-specific transcriptional enhancer lies within the J delta 3-C delta intron of the human T-cell receptor (TCR) delta gene. The 30-bp minimal enhancer element denoted delta E3 carries a core sequence (TGTGGTTT) that binds a T-cell-specific factor, and that is necessary but not sufficient for transcriptional activation. Here we demonstrate that the transcription factor c-Myb regulates TCR delta enhancer activity through a binding site in delta E3 that is adjacent to the core site. Both v-Myb and c-Myb bind specifically to delta E3. The Myb site is necessary for enhancer activity, because a mutation that eliminates Myb binding abolishes transcriptional activation by the delta E3 element and by the 370-bp TCR delta enhancer. Transfection of cells with a c-Myb expression construct upregulates delta E3 enhancer activity, whereas treatment of cells with an antisense c-myb oligonucleotide inhibits delta E3 enhancer activity. Since intact Myb and core sites are both required for delta E3 function, our data argue that c-Myb and core binding factors must cooperate to mediate transcriptional activation through delta E3. Efficient cooperation depends on the relative positioning of the Myb and core sites, since only one of two overlapping Myb sites within delta E3 is functional and alterations of the distance between this site and the core site disrupt enhancer activity. Cooperative regulation by c-Myb and core-binding factors is likely to play an important role in the control of gene expression during T-cell development.

Identification of an essential site for transcriptional activation within the human T-cell receptor delta enhancer.

A T-cell-specific transcriptional enhancer was previously identified within the J delta 3-C delta intron of the human T-cell receptor (TCR) delta gene, and seven distinct binding sites for nuclear factors (delta E1 to delta E7) were defined by DNase I footprinting. In this study, we conducted a detailed functional analysis of the various cis-acting DNA sequence elements of the enhancer and show that a 60-bp fragment encompassing delta E3 and delta E4 displays potent enhancer activity, as judged by its ability to activate transcription from the V delta 1 promoter. We show that the interaction of nuclear factors with the delta E3 site is essential for enhancer activity. This element displays significant activity in the absence of additional segments of the enhancer. Further, methylation interference and in vitro mutagenesis identify a site within delta E3 that mediates the binding of two nuclear factors (NF-delta E3A and NF-delta E3C) and that is required for significant transcriptional activation by the enhancer. NF-delta E3C is ubiquitous and may be identical to a previously characterized microE3-binding factor. NF-delta E3A is preferentially expressed in T lymphocytes, and we suggest that this factor may play the dominant role in transcriptional activation through the delta E3 site. This factor interacts with the sequence TGTGGTTT, a motif that is also found within the enhancers of additional TCR and CD3 genes. Nuclear factor binding to delta E4 is also analyzed. One of three specific complexes formed with a delta E4 probe appears to be T-cell specific.

Cooperation among multiple transcription factors is required for access to minimal T-cell receptor alpha-enhancer chromatin in vivo.

To understand the molecular basis for the dramatic functional synergy between transcription factors that bind to the minimal T-cell receptor alpha enhancer (Ealpha), we analyzed enhancer occupancy in thymocytes of transgenic mice in vivo by genomic footprinting. We found that the formation of a multiprotein complex on this enhancer in vivo results from the occupancy of previously identified sites for CREB/ATF, TCF/LEF, CBF/PEBP2, and Ets factors as well as from the occupancy of two new sites 5' of the CRE site, GC-I (which binds Sp1 in vitro) and GC-II. Significantly, although all sites are occupied on a wild-type Ealpha, all sites are unoccupied on versions of Ealpha with mutations in the TCF/LEF or Ets sites. Previous in vitro experiments demonstrated hierarchical enhancer occupancy with independent binding of LEF-1 and CREB. Our data indicate that the formation of a multiprotein complex on the enhancer in vivo is highly cooperative and that no single Ealpha binding factor can access chromatin in vivo to play a unique initiating role in its assembly. Rather, the simultaneous availability of multiple enhancer binding proteins is required for chromatin disruption and stable binding site occupancy as well as the activation of transcription and V(D)J recombination.