Molecular pathways of adhesion in spontaneous rosetting of T-lymphocytes to the Hodgkin's cell line L428.

Spontaneous rosetting of T-lymphocytes to Reed-Sternberg cells has been observed both in vitro and in vivo but its molecular mechanism has not been defined. We have investigated such rosetting using the Hodgkin's cell line L428. L428 expresses high levels of LFA-3 and ICAM-1, both of which are ligands for T-cell adhesion. Monoclonal antibody inhibition of spontaneous rosetting indicated that it is not dependent on the T-cell receptor complex but is largely mediated by interaction of T-cell CD2 (T11/E-rosette receptor) with its ligand LFA-3 on L428 cells. Studies using an alternate assay of adhesion (conjugate formation) confirm the roles of CD2/LFA-3 and also implicate a second mode of binding via LFA-1 on T-cells to ICAM-1 on L428. These data explain the previously reported finding of T-cell rosetting with Reed-Sternberg cells as an exaggeration of normal antigen-independent T-cell adhesion.

The lymphocyte function-associated antigen (LFA)-1 and CD2/LFA-3 pathways of antigen-independent human T cell adhesion.

Human cytotoxic T lymphocyte clones form conjugates with both antigen-positive and antigen-negative lymphoblastoid cells. Conjugates with antigen-negative targets form as rapidly, and are almost as frequent, as those with antigen-positive targets; both types are strong. Monoclonal antibodies against lymphocyte function-associated antigen (LFA)-1, CD2, and LFA-3 (or their Fab fragments) each consistently inhibit conjugate formation, but only partially; mixes of alpha LFA-1 with either CD2 monoclonal antibodies or alpha LFA-3 cause complete inhibition. Our previous studies have demonstrated two distinct pathways of antigen-independent conjugate (AIC) formation, one involving LFA-1 and the other involving CD2/LFA-3. The present studies showing supra-additive inhibition with mixes of Fab indicate that at least a major fraction of the conjugates involve T cells which utilize both pathways. Preincubation studies (and restricted expression for CD2) demonstrate that in the CD2/LFA-3 pathway, CD2 is critical on the effector and LFA-3 on the target and that in the LFA-1 pathway, LFA-1 is critical on the effector. Analysis of conjugate formation by primary allosensitized T cells confirms the critical findings made with T cell clones. Among a panel of antigen-negative "target" cell lines tested, there is wide variation in the number of AIC formed with cytotoxic T lymphocyte clones; this variation correlates partially with differences in level of expression of LFA-3. Both pathways of adhesion are utilized in AIC formation with all five targets tested, but there was variation between targets in the relative contribution by each pathway. Studies of inhibition of lysis (rather than conjugate formation) support the relevance of the two-pathway model to the lytic process as a whole. These studies demonstrate the general involvement of two pathways of adhesion in human T cell interactions: one involving T cell LFA-1 and the other involving T cell CD2 binding to target cell LFA-3.

Differential expression of integrins alpha 6 and alpha 4 determines pathways in human peripheral CD4+ T cell differentiation.

Integrins mediate leukocyte adhesion to vascular endothelium and thereby influence leukocyte recirculation. We have explored expression by peripheral blood T cells of beta 1 and beta 7 integrins, particularly alpha 4 beta 1 (VLA-4, CD49d), alpha 4 beta 7 (LPAM-1) and alpha 6 beta 1 (VLA-6, CD49f). Integrin expression differs between CD4+ cells and CD8+ cells in that CD4+ cells 1) are more heterogeneous, particularly for alpha 4; 2) express on the average less alpha 4 and beta 7; and 3) express on the average more alpha 6 and beta 1. 2D gel electrophoretic analysis was combined with flow cytometric analysis to determine which integrin chain pairs are expressed by the CD45RO- (naive) and CD45RO+ (memory) subsets of CD4+ cells. CD45RO- (naive) cells express homogeneously at intermediate levels the three integrin pairs alpha 6 beta 1, alpha 4 beta 1 and alpha 4 beta 7. Although 2D gel analysis suggests similar average integrin chain composition for CD45RO+CD4+ (memory) cells, flow cytometric analysis demonstrates multiple subsets of CD45RO+ cells differing markedly from each other and from naive cells in levels of expression of alpha 6 and alpha 4 integrins. There are a minimum of three CD45RO+ subsets: 1) alpha 4 beta 1hi alpha 6 beta 1hi alpha 4 beta 7neg, which comprises the majority of memory cells; 2) alpha 4 beta 7hi alpha 6 beta 1low presumptive gut-homing memory cells; and 3) alpha 6 beta 1hi alpha 4 beta 7neg alpha 4 beta 1neg, a previously unidentified subset expected to have unique migrational-functional properties. Of particular importance in these results are: the expression by CD4+ naive cells of alpha 6 beta 1, alpha 4 beta 1 and alpha 4 beta 7, the overall prominence and regulation of alpha 6 beta 1 on CD4+ cells, and the selective decreases as well as increases in alpha 4 beta 7 and alpha 4 beta 1 during CD4+ memory specialization. Taken together, these results suggest that differential regulation of expression of alpha 4 and alpha 6 integrin chains that accompany naive-to-memory transition in CD4+ cells are instrumental in generating functional subsets of CD4+ memory cells with specialized recirculation abilities.

CD45RB expression defines two interconvertible subsets of human CD4+ T cells with memory function.

Reciprocal expression of CD45RA and CD45RO in human CD4+ T cells defines populations understood to be naive cells (CD45RA+CD45RO-) and memory cells (CD45RA-CD45RO+). We investigate two subsets of CD45RA-CD45RO+ CD4+ human T cells which differ by fourfold in their expression of the CD45RB isoform; one is CD45RBbright and the other is CD45RBintermediate. In contrast, CD45RA+ naive cells are all CD45RBbright. Both subsets of CD45RA- cells proliferate in response to recall antigens so we designate them MEM 1 (CD45RO+RBbright) and MEM 2 (CD45RO+RBintermediate). CD45RA and CD45RB expression are regulated independently during in vitro activation of naive cells. When MEM 1 cells are activated they tend to down-regulate CD45RB expression, whereas activated MEM 2 cells tend to up-regulate CD45RB expression. Thus, in contrast to the stability of the CD45RA-CD45RO+ phenotype, the MEM 1 and MEM 2 phenotypes are labile and may interconvert. MEM 1 and MEM 2 cells produced comparable amounts of interleukin(IL)-2, IL-4, and IL-5 though MEM 1 cells produced slightly more interferon(IFN)-gamma (mean 1.7-fold more). MEM 1 cells consistently proliferated more (mean 2.3-fold more) than MEM 2 cells early during in vitro activation. Thus, differential expression of CD45RB within CD45RA- cells defines two subsets that have similar properties except for somewhat greater IFN-gamma production and proliferative responses by MEM 1 cells. Variability in CD45RB expression may represent a mechanism for fine-tuning the responsiveness of memory cells in vivo.

Remote T cell co-stimulation via LFA-1/ICAM-1 and CD2/LFA-3: demonstration with immobilized ligand/mAb and implication in monocyte-mediated co-stimulation.

Proliferative response of resting T cells generally requires not only cross-linking of the T cell receptor (TcR) but also co-stimulatory signals from accessory molecules. We here have used a "three-cell" model consisting of: (a) resting human CD4+ T cells as responders; (b) CD3 monoclonal antibody (mAb) OKT3 on latex beads as surrogate stimulators; (c) autologous monocytes as source of co-stimulation. As described by Kawakami et al. (J. Immunol. 1989, 142: 1818), T cell proliferation in this system is observed with paraformaldehyde-fixed monocytes if they have been activated and interleukin (IL) 1 beta/IL 6 is supplied. Since this three-cell system provides TcR cross-linking at a site spatially "remote" from co-stimulation, they help distinguish adhesion from signal transduction but the molecules that mediate co-stimulation in this system have not been identified. Our studies now demonstrate that co-stimulation by the monocytes is dependent on each of two receptor/ligand pathways CD2/LFA-3 and LFA-1/ICAM-1 since it is inhibited by each relevant mAb but not a variety of control mAb. The hypotheses that CD2 and LFA-1 could each mediate co-stimulation was tested in simplified model systems in which the monocyte was replaced with immobilized CD2 mAb or purified ICAM-1 presented on a separate surface from the CD3 mAb. The results in these simplified models demonstrate that on resting T cells either CD2 or LFA-1 molecules alone can mediate "remote" co-stimulation unlike most other T cell surface molecules. Co-stimulation requires IL 1 beta/IL6 both in the weaker LFA-1 ligand-mediated co-stimulation and at lower CD2 mAb concentrations in the stronger CD2 mAb-mediated co-stimulation. Thus: (a) the accessory cell function of stimulated fixed monocytes in T cell proliferation requires both the LFA-1/ICAM-1 and CD2/LFA-3 pathways; and (b) the T cell molecules CD2 and LFA-1 can give co-stimulatory signals that can act in a "remote" fashion.

Differential expression of VLA-alpha 4 and VLA-beta 1 discriminates multiple subsets of CD4+CD45R0+ "memory" T cells.

Given the importance of adhesion in T cell development, we have undertaken systematic flow cytometric analysis of CD4 T cells to determine relationships between the developmentally regulated marker CD45R0 and adhesion receptors (five VLA integrin chains). The most important findings are that: 1) expression of alpha 3, alpha 5, and alpha 6 are closely coregulated with beta 1 on CD4 cells, while regulation of VLA-alpha 4 is quite discordant. 2) CD45R0- cells, generally understood to be naive cells, have low homogeneous expression of VLA-alpha 3, VLA-alpha 4, VLA-alpha 5, VLA-alpha 6, and beta 1 integrin chains; studies of cord blood CD4 cells confirm the low homogeneous expression of alpha 4 and beta 1 on naive cells. 3) In marked contrast, CD45R0+ cells, generally understood to be memory cells, show not only an overall increase in expression of these integrins (relative to CD45R0- cells) but also heterogeneity. Dramatic heterogeneity is revealed when the markers VLA-alpha 4 and beta 1 are analyzed together. Many CD45R0+ cells show increased levels of both VLA-alpha 4 and VLA-beta 1; however, some have increased levels principally of either VLA-beta 1 or VLA-alpha 4. We hypothesize that T cells becoming memory cells in different microenvironments specialize their integrin phenotype, thereby acquiring distinctive functional and homing capacities; in this process, VLA-4 (CD49d) appears to play a unique role.

Two antigen-independent adhesion pathways used by human cytotoxic T-cell clones.

Cell-cell adhesion is essential for many immunological functions, including interaction of cytotoxic T lymphocytes (CTLs) with their targets. We have explored CTL-target interactions using well-characterized cloned human CTLs. Conjugate formation between these CTLs and many antigen-negative targets is almost as efficient as with specific target cells, but does not lead to target-cell lysis. Thus, on specific target cells, adhesion by antigen-independent pathways may occur concurrently with or precede antigen recognition. The molecules LFA-1, CD2 (T11, LFA-2) and LFA-3 have been shown to be involved in human CTL conjugation with and lysis of specific target cells. Here we describe monoclonal antibody inhibition studies using individual monoclonal antibodies and mixes which demonstrate (1) that LFA-1, CD2 and LFA-3 are involved in antigen-independent conjugate formation; and (2) suggest that CD2 and LFA-3 are involved in one pathway and LFA-1 in another. We confirmed the existence of distinct pathways by the demonstration that LFA-1-dependent adhesion requires divalent cations and is temperature-sensitive whereas CD2- and LFA-3-dependent adhesion does not require divalent cations and is temperature-insensitive. Together with previous data, our studies suggest that CD2 on the effector interacts with LFA-3 as its ligand on targets.

Functional evidence that intercellular adhesion molecule-1 (ICAM-1) is a ligand for LFA-1-dependent adhesion in T cell-mediated cytotoxicity.

Although intercellular adhesion molecule-1 (ICAM-1) has been implicated as a ligand in some LFA-1-dependent adhesion, its importance to T cell function has not been established. The present studies investigate the importance of ICAM-1 for human cytotoxic T lymphocytes (CTL), both in their formation of antigen-independent conjugates (AIC) and in their lysis of targets. Analysis of monoclonal antibody (mAb) inhibition of AIC formation indicate that ICAM-1 mAb 1 blocks (a) AIC formation with some but not all targets; (b) the LFA-1 pathway but not the CD2/LFA-3 pathway of adhesion; (c) by binding to the target cell, not the T cell. In studies of cell-mediated lysis (CML) ICAM-1 mAb inhibited lysis of some targets, such as U-937, that use ICAM-1 predominantly in AIC formation; CML on some other targets is not inhibited by ICAM-1 mAb. These data indicate that ICAM-1 is a ligand for AIC formation, antigen-specific CTL recognition and cytolysis of particular target cells. The data also indicate that ICAM-1 is not used in LFA-1-dependent CTL interactions with all kinds of target cells, suggesting the existence of alternative ligands for LFA-1.

ICAM-1 a ligand for LFA-1-dependent adhesion of B, T and myeloid cells.

Cell-cell adhesion is essential for many immunological functions. The LFA-1 molecule, a member of a superfamily of adhesion molecules, participates in adhesion which is critical to the function of each of the three major subsets of leukocytes: lymphocytes, monocytes and granulocytes. Putative LFA-1 ligands have been identified functionally in different laboratories using three different monoclonal antibodies that inhibit LFA-1-mediated leukocyte adhesion in particular model systems; however, there may be more than one LFA-1 ligand. We have directly compared the three relevant monoclonal antibodies, and show that each binds to the same molecule, intercellular-adhesion molecule-1 (ICAM-1). Most important, B, T and myeloid cells adhere specifically to purified ICAM-1-coated surfaces; such adhesion has distinctive requirements for Mg2+ and Ca2+. This constitutes biochemical evidence that ICAM-1 functions as a ligand for LFA-1-dependent adhesion by a variety of leukocytes.

Selective expression of integrin alpha 4 beta 7 on a subset of human CD4+ memory T cells with Hallmarks of gut-trophism.

Human memory CD4+ T lymphocytes are heterogenous in expression of integrins; one subset has the unexpected phenotype beta 1 low alpha 4 high. We demonstrate that this subset is unique among CD4+ cells in expression of high levels of alpha 4 beta 7, detected by a distinctive mAb Act-1. alpha 4 beta 7 is involved in binding to both fibronectin and vascular cell adhesion molecule-1; Act-1 blocks cell binding to the former and augments binding to the latter. Act-1 expression marks a subset of memory cells that, unlike the predominant circulating memory cell, has up-regulated beta 7 rather than beta 1. Their phenotype is distinct from that described for skin-homing T cells and is fully consistent with that described for gut-homing T cells. Differential adhesion capacity of this subset is verified by selective binding to FN and vascular cell adhesion molecule-1 in a beta 1-independent fashion. Thus, alpha 4 beta 7 detected on this subset of circulating normal T cells fits the expectations for a gut-homing receptor.