Assessing a role for enhancer-blocking activity in gene regulation within the murine T-cell receptor alpha/delta locus.

Although situated close together within the T-cell receptor (TCR) alpha/delta locus, TCR delta and TCR alpha gene segments are controlled by two developmental stage-specific enhancers and are activated according to distinct developmental programmes. We previously used a stable transfection colony assay to identify an enhancer-blocking element, blocking element alpha/delta-1 (BEAD-1), between the TCR delta and alpha gene segments of the human TCR alpha/delta locus. We hypothesized that enhancer-blocking by BEAD-1 might be required to prevent the TCR delta enhancer from activating TCR alpha gene segment transcription and rearrangement at the double negative stage of thymocyte development. Here, we used a transfection approach to define partial enhancer-blocking activity in an analogous position of the murine TCR alpha/delta locus. To test the functional significance of this activity in vivo, we used gene targeting to delete the region from the endogenous locus. We found no perturbation of TCR delta and TCR alpha gene expression and rearrangement on targeted alleles, indicating that enhancer-blocking activity in this region is not required to maintain the developmentally distinct activation profiles of the two genes. We suggest that appropriate regulation may be achieved as a result of intrinsic biases in enhancer-promoter interactions or a developmental stage specificity to promoter function that is distinct from any additional specificity imposed by the enhancers themselves.

Chemokines have diverse abilities to form solid phase gradients.

Chemokines play critical roles in leukocyte recruitment into sites of inflammation such as rheumatoid arthritis (RA). While chemokines immobilized on endothelium (solid-phase), but not soluble chemokines, direct rolling leukocytes to firmly adhere to endothelium, soluble and solid-phase chemokine gradients may play important roles in leukocyte extravasation into the tissue. In this study, we have sought to determine (1) if chemokines can be immobilized on structures in the extravascular space, (2) the mechanisms by which chemokines may be immobilized, and (3) if different chemokines have similar potentials to form solid-phase gradients. While secreted alkaline phosphatase (SEAP)-tagged chemokines SLC (CCL21), TARC (CCL17), and RANTES (CCL5) bound to mast cells and the extracellular matrix (ECM) in RA synovium under physiologic salt conditions, MCP1 (CCL2), MIP1 alpha (CCL3), MIP1 beta (CCL4), and fractalkine (FKN, CX3CL1) fusion proteins did not detectably bind. Chemokine binding to ECM and mast cells in situ and to immobilized heparin was inhibited by high salt and glycosaminoglycans (GAGs) heparin, heparan sulfate, chondroitin sulfate, and dermatan sulfate, but not by dextran or hyaluronan, indicating that the chemokines bind to highly sulfated GAGs. Chemokine binding to synovial structures correlated strongly with avidity of chemokine binding to heparin (SLC > TARC > RANTES > MIP1 beta > MCP1 > MIP1 alpha > FKN). A RANTES mutant with decreased avidity for heparin was not able to bind to ECM or mast cells. Thus, these data indicate that chemokines can bind to ECM and mast cell granule constituents in situ via interactions with GAGs. Further, only a subset of chemokines were able to bind efficiently to structures in the extravascular space, indicating that chemokines may form different types of gradients based on their GAG binding ability and that chemotactic gradients in tissues may be quite complex.

Chemokine production by G protein-coupled receptor activation in a human mast cell line: roles of extracellular signal-regulated kinase and NFAT.

Chemoattractants are thought to be the first mediators generated at sites of bacterial infection. We hypothesized that signaling through G protein-coupled chemoattractant receptors may stimulate cytokine production. To test this hypothesis, a human mast cell line (HMC-1) that normally expresses receptors for complement components C3a and C5a at low levels was stably transfected to express physiologic levels of fMLP receptors. We found that fMLP, but not C3a or C5a, induced macrophage inflammatory protein (MIP)-1ss (CCL4) and monocyte chemoattractant protein-1 (CCL2) mRNA and protein. Although fMLP stimulated both sustained Ca(2+) mobilization and phosphorylation of extracellular signal-regulated kinase (ERK), these responses to C3a or C5a were transient. However, transient expression of C3a receptors in HMC-1 cells rendered the cells responsive to C3a for sustained Ca(2+) mobilization and MIP-1ss production. The fMLP-induced chemokine production was blocked by pertussis toxin, PD98059, and cyclosporin A, which respectively inhibit G(i)alpha activation, mitgen-activated protein kinase kinase-mediated ERK phosphorylation, and calcineurin-mediated activation of NFAT. Furthermore, fMLP, but not C5a, stimulated NFAT activation in HMC-1 cells. These data indicate that chemoattractant receptors induce chemokine production in HMC-1 cells with a selectivity that depends on the level of receptor expression, the length of their signaling time, and the synergistic interaction of multiple signaling pathways, including extracellular signal-regulated kinase phosphorylation, sustained Ca(2+) mobilization and NFAT activation.

T cell receptor-dependent activation of human lymphocytes through cell surface ganglioside GT1b: implications for innate immunity.

Gangliosides form a component of the glycosphingolipid-rich membrane microdomains recently shown to play an important role in receptor signal transduction. Specific gangliosides also serve as receptors for binding and internalization of bacterial toxins. In the course of characterizing the basis of the native tetanus toxin (TTx) reactivity of a human gamma delta T cell clone, we observed that transfer of the TCR was required to impart TTx reactivity on a TCR-negative recipient T cell. However, the reconstitution of toxin reactivity could be achieved regardless of the antigen specificity of the TCR chains. Further analysis showed that the T cell recognition of native TTx was dependent on the presence of its ganglioside receptor, GT1b, on the T cell surface. Incorporation of exogenous GT1b into plasma membrane conferred TTx reactivity on otherwise non-reactive T cells provided these cells expressed the TCR. Finally, reconstitution of TCR-negative Jurkat T cells with a CD8-CD3zeta chain chimera demonstrated that the cytoplasmic region of the CD3zeta chain was sufficient to couple ganglioside-mediated TTx binding to T cell activation. These data reveal a novel mode of TCR-dependent reactivity to a bacterial toxin that could mobilize a large subset of T cells, thus representing a form of innate immunity. Given the possibility that endogenous ligands may bind to cell surface gangliosides, regulation of their levels and topology on the cell surface may constitute an immunoregulatory mechanism.

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.

Accessibility control of T cell receptor gene rearrangement in developing thymocytes. The TCR alpha/delta locus.

The joining of T cell receptor (TCR) and immunoglobulin (Ig) gene segments through the process of V(D)J recombination occurs in a lineage-specific and developmental-stage-specific way during the early stages of lymphocyte development. Such developmental regulation is thought to be mediated through the control of gene segment accessibility to the recombinase. We have studied the regulation of V(D)J recombination at the TCR alpha/delta locus, because this locus provides a fascinating model in which distinct sets of gene segments are activated at different stages of T cell development. The transcriptional enhancers Edelta and Ealpha have been implicated as critical regulators that, in conjunction with other cis-acting elements, confer region-specific and developmental-stage-specific changes in gene segment accessibility within TCR alpha/delta locus chromatin. Current work suggests that they may do so by functioning as regional modulators of histone acetylation.

Flanking nuclear matrix attachment regions synergize with the T cell receptor delta enhancer to promote V(D)J recombination.

Previous studies have identified nuclear matrix attachment regions (MARs) that are closely associated with transcriptional enhancers in the IgH, Igkappa, and T cell receptor (TCR) beta loci, but have yielded conflicting information regarding their functional significance. In this report, a combination of in vitro and in situ mapping approaches was used to localize three MARs associated with the human TCR delta gene. Two of these are located within the Jdelta3-Cdelta intron, flanking the core TCR delta enhancer (Edelta) both 5' and 3' in a fashion reminiscent of the Ig heavy chain intronic enhancer-associated MARs. The third is located about 20 kb upstream, tightly linked to Ddelta1 and Ddelta2. We have previously used a transgenic minilocus V(D)J recombination reporter to establish that Edelta functions as a developmental regulator of V(D)J recombination, and that it does so by modulating substrate accessibility to the V(D)J recombinase. We show here that the Edelta-associated MARs function synergistically with the core Edelta to promote V(D)J recombination in this system, as they are required for enhancer-dependent transgene rearrangement in single-copy transgene integrants.

Structure and function of the glycosaminoglycan binding site of chemokine macrophage-inflammatory protein-1 beta.

The ability of chemokines to bind to glycosaminoglycans (GAGs) on cell surfaces and in the extracellular matrix is thought to play a crucial role in chemokine function. We investigated the structural basis for chemokine binding to GAGs by using in vitro mutagenesis to identify amino acids of chemokine macrophage-inflammatory protein-1 beta (MIP-1 beta) that contribute to its interaction with the model GAG heparin. Among six basic residues that are organized into a single basic domain in the folded MIP-1 beta monomer, three (R18, K45, and R46) were found to contribute significantly to heparin binding. Of these, R46 was found to play a dominant role, and proved essential for the interaction of MIP-1 beta with both heparin and heparan sulfate in physiological salt. The results of this mutational analysis have implications for the structure of the MIP-1 beta-heparin complex, and a comparison of these results with those obtained by mutational analysis of the MIP-1 alpha-heparin interaction suggests a possible structural difference between the MIP-1 beta-heparin and MIP-1 alpha-heparin complexes. To determine whether GAG binding plays an important role in receptor binding and cellular activation by MIP-1 beta, the activities of wild-type MIP-1 beta and R46-substituted MIP-1 beta were compared in assays of T lymphocyte chemotaxis. The two proteins proved equipotent in this assay, arguing that interaction of MIP-1 beta with GAGs is not intrinsically required for functional interaction of MIP-1 beta with its receptor.

A developmental switch from TCR delta enhancer to TCR alpha enhancer function during thymocyte maturation.

V(D)J recombination and transcription within the TCR alpha/delta locus are regulated by three characterized cis-acting elements: the TCR delta enhancer (Edelta), TCR alpha enhancer (Ealpha), and T early alpha (TEA) promoter. Analysis of enhancer and promoter occupancy and function in developing thymocytes in vivo indicates Edelta and Ealpha to be developmental-stage-specific enhancers, with Edelta "on" and Ealpha "off" in double-negative III thymocytes and Edelta "off" and Ealpha "on" in double-positive thymocytes. Edelta downregulation reflects a loss of occupancy. Surprisingly, Ealpha and TEA are extensively occupied even prior to activation. TCR delta downregulation in double-positive thymocytes depends on two events, Edelta inactivation and removal of TCR delta from the influence of Ealpha by chromosomal excision.

Enhancer-blocking activity within the DNase I hypersensitive site 2 to 6 region between the TCR alpha and Dad1 genes.

Although tightly linked, the TCR alpha and delta genes are expressed specifically in T lymphocytes, whereas the Dad1 gene is ubiquitously expressed. Between TCR alpha and Dad1 are eight DNase I hypersensitive sites (HS). HS1 colocalizes with the TCR alpha enhancer (Ealpha) and is T cell-specific; HS2, -3, -4, -5, and -6 map downstream of HS1 and are tissue-nonspecific. The region spanning HS2-6 was reported to display chromatin-opening activity and to confer copy number-dependent and integration site-independent transgene expression in transgenic mice. Here, we demonstrate that HS2-6 also displays enhancer-blocking activity, as it can block an enhancer from activating a promoter when located between the two in a chromatin-integrated context, and can do so without repressing either the enhancer or the promoter. Multiple enhancer-blocking elements are arrayed across HS2-6. We show that HS2-6 by itself does not activate transcription in chromatin context, but can synergize with an enhancer when located upstream of an enhancer and promoter. We propose that HS2-6 primarily functions as an insulator or boundary element that may be critical for the autonomous regulation of the TCR alpha and Dad1 genes.

Developmental regulation of V(D)J recombination at the TCR alpha/delta locus.

The T-cell receptor (TCR) alpha/delta locus includes a large number of V, D, J and C gene segments that are used to produce functional TCR delta and TCR alpha chains expressed by distinct subsets of T lymphocytes. V(D)J recombination events within the locus are regulated as a function of developmental stage and cell lineage during T-lymphocyte differentiation in the thymus. The process of V(D)J recombination is regulated by cis-acting elements that modulate the accessibility of chromosomal substrates to the recombinase. Here we evaluate how the assembly of transcription factor complexes onto enhancers, promoters and other regulatory elements within the TCR alpha/delta locus imparts developmental control to VDJ delta and VJ alpha rearrangement events. Furthermore, we develop the notion that within a complex locus such as the TCR alpha/delta locus, highly localized and region-specific control is likely to require an interplay between positive regulatory elements and blocking or boundary elements that restrict the influence of the positive elements to defined regions of the locus.

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.

Enhancer control of local accessibility to V(D)J recombinase.

We have studied the role of transcriptional enhancers in providing recombination signal sequence (RSS) accessibility to V(D)J recombinase by examining mice carrying a transgenic human T-cell receptor (TCR) delta gene minilocus. This transgene is composed of unrearranged variable (Vdelta and Vdelta2), diversity (Ddelta3), joining (Jdelta1 and Jdelta3), and constant (Cdelta) gene segments. Previous data indicated that with the TCR delta enhancer (Edelta) present in the Jdelta3-Cdelta intron, V(D)J recombination proceeds stepwise, first V to D and then VD to J. With the enhancer deleted or mutated, V-to-D rearrangement is intact, but VD-to-J rearrangement is inhibited. We proposed that Edelta is necessary for J segment but not D segment accessibility and that J segment inaccessibility in the enhancerless minilocus resulted in the observed V(D)J recombination phenotype. In this study, we tested this notion by using ligation-mediated PCR to assess the formation of recombination-activating gene (RAG)-dependent double-strand breaks (DSBs) at RSSs 3' of Ddelta3 and 5' of Jdelta1. In five lines of mice carrying multicopy integrants of constructs that either lacked Edelta or carried an inactivated Edelta, the frequency of DSBs 5' of Jdelta1 was dramatically reduced relative to that in the wild type, whereas the frequency of DSBs 3' of Ddelta3 was unaffected. We interpret these results to indicate that Edelta is required for Jdelta1 but not Ddelta3 accessibility within the minilocus, and we conclude that enhancers regulate V(D)J recombination by providing local accessibility to the recombinase. cis-acting elements other than Edelta must maintain Ddelta3 in an accessible state in the absence of Edelta. The analysis of DSB formation in a single-copy minilocus integrant indicates that efficient DSB formation at the accessible RSS 3' of Ddelta3 requires an accessible partner RSS, arguing that RSS synapsis is required for DSB formation in chromosomal substrates in vivo.

An enhancer-blocking element between alpha and delta gene segments within the human T cell receptor alpha/delta locus.

T cell receptor (TCR) alpha and delta gene segments are organized within a single genetic locus but are differentially regulated during T cell development. An enhancer-blocking element (BEAD-1, for blocking element alpha/delta 1) was localized to a 2.0-kb region 3' of TCR delta gene segments and 5' of TCR alpha joining gene segments within this locus. BEAD-1 blocked the ability of the TCR delta enhancer (Edelta) to activate a promoter when located between the two in a chromatin-integrated construct. We propose that BEAD-1 functions as a boundary that separates the TCR alpha/delta locus into distinct regulatory domains controlled by Edelta and the TCR alpha enhancer, and that it prevents Edelta from opening the chromatin of the TCR alpha joining gene segments for VDJ recombination at an early stage of T cell development.

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.

Identification of a glycosaminoglycan-binding site in chemokine macrophage inflammatory protein-1alpha.

Chemokines bind to receptors of the seven-transmembrane type on target cells and also bind to glycosaminoglycans (GAGs), including heparin. In this study, we have sought to identify structural motifs mediating binding of the beta-chemokine macrophage inflammatory protein-1alpha (MIP-1alpha) to GAGs. Alignment of beta-chemokine amino acid sequences revealed the presence of several highly conserved basic amino acids, and molecular modeling predicted that the side chains of three of the basic amino acids fold closely together in MIP-1alpha. Site-directed mutagenesis was used to change the conserved basic residues in MIP-1alpha to alanines, and both wild-type and mutant proteins were produced in a transient COS cell expression system. Wild-type MIP-1alpha bound to heparin-Sepharose, while three of the mutants, R18A, R46A, and R48A, failed to bind. Mutant K45A eluted from heparin-Sepharose at lower NaCl concentrations than wild type, while the binding of K61A, with a mutation in the C-terminal alpha-helix, was indistinguishable from that of the wild-type protein. To determine whether GAG-binding capacity is required for receptor binding and cell activation, we performed competition radioligand binding and calcium mobilization experiments using one of the non-heparin-binding mutants, R46A. R46A bound as efficiently as wild-type MIP-1alpha to CCR1 and was equally active in eliciting increases in intracellular free calcium concentrations. Our data define a GAG binding site in MIP-1alpha consisting of three noncontiguous basic amino acids and show that the capacity to bind to GAGs is not a prerequisite for receptor binding or signaling in vitro.

Regulation of I-309 gene expression in human monocytes by endogenous interleukin-1.

Activated human monocytes are a source of numerous beta-chemokines. The present study was conducted to determine whether these cells produce the human beta-chemokine I-309 and to compare the induction requirements of I-309 to those of other beta-chemokines. We demonstrate that appropriately stimulated adherence-purified human peripheral blood monocytes express I-309 transcripts and secreted I-309 protein. Two stimuli, immobilized IgG and lipopolysaccharide (LPS), synergize strongly to induce I-309 gene expression. We further demonstrate that the production of endogenous interleukin (IL)-1alpha plays a crucial role in I-309 induction. Thus, neutralization of endogenous IL-1alpha using an anti-IL-1alpha antiserum inhibits the induction of I-309 transcripts in response to stimulation with immobilized IgG and LPS, and exogenous IL-1alpha or IL-1beta induces I-309 transcripts in monocytes stimulated with immobilized IgG. Immobilized IgG and LPS have the opposite effect on monocyte chemoattractant protein-1 (MCP-1) gene expression, in that the induction observed with either stimulus alone is diminished using the two stimuli in combination. Furthermore, endogenous and exogenous IL-1 can be either stimulatory or inhibitory for MCP-1 gene expression depending on other signals delivered to the monocytes. Immobilized IgG and LPS synergize to induce macrophage inflammatory protein-1alpha transcripts, but endogenous IL-1 does not play a significant role. Thus, each of these beta-chemokine genes is under distinct regulatory control in human monocytes.

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.