Stephen Shaw

Lymphocyte interactions with extracellular matrix.

To mediate an immune response, lymphocytes must be able to interact with and respond to the surrounding extracellular environment. In addition to cell surface molecules that facilitate adhesion of lymphocytes to other cells, recent studies have demonstrated that lymphocytes interact with glycoproteins and glycosaminoglycans that are major components of the extracellular matrix (ECM). Although many receptors mediating the effects of ECM components on lymphocyte function remain poorly defined, a number of lymphocyte ECM receptors have recently been identified; these include members of the integrin family of adhesion molecules as well as structurally unrelated molecules such as CD44 and CD26. Furthermore, as lymphocytes must be able to move between various microenvironments in vivo, they have proved to be an excellent cell type in which to identify and analyze various modes of regulation of cell‐ECM interactions. As with other cell types, the ECM has been shown to have multiple effects on lymphocytes; functional analysis reveals effects of the ECM on lymphocyte migration, recognition/activation, and differentiation. These studies emphasize: 1) the importance of lymphocytes as a model system for identifying and analyzing ECM receptor expression and function, and 2) the multiple roles that the ECM plays in the function of the immune system in vivo.—Shimizu, Y.; Shaw, S. Lymphocyte interactions with extracellular matrix. FASEB J. 5: 2292–2299; 1991.

The CD2-LFA-3 and LFA-1-ICAM pathways: relevance to T-cell recognition

No process is more central to T-lymphocyte function than cell-cell adhesion, yet it is only recently that interest in lymphocyte adhesion has burgeoned. Neglect of adhesion is particularly surprising since immunologists are surrounded by a veritable sea of adhesive interactions of lymphocytic cells: transformed lymphocytes grow in aggregates, stimulated lymphocytes aggregate and T cells conjugate with their targets. In retrospect, it is obvious that all lymphocyte adhesion (both antigen-specific and seemingly non-specific adhesive interactions) has to be based on specific receptor-ligand interactions. In this review Malegapuru Makgoba, Martin Sanders and Stephen Shaw focus primarily on the two molecular pathways of lymphocyte adhesion that have been shown to play a critical role in facilitation of antigen-specific recognition, namely CD2 and its ligand, lymphocyte function associated antigen-3 (LFA-3), and LFA-1 and its ligand, intercellular adhesion molecule-1 (ICAM-1). A variety of excellent recent reviews have dealt with this and related aspects of T-cell adhesion. Of particular interest is the review that follows in this issue: it deals with the CD44 molecule which has also been implicated in both adhesion and activation of T cells.

Roles of multiple accessory molecules in T-cell activation

Accessory molecules expressed on T cells can mediate adhesion between T cells and other cells, or the extracellular matrix. The same T-cell accessory molecules participate in a dialogue with their ligands (counter-receptors) on the antigen-presenting cells, and elicit signals that determine the specifics of activation and subsequent differentiation of the T cells and antigen-presenting cells.

Rab35 and its GAP EPI64C in T cells regulate receptor recycling and immunological synapse formation.

Upon antigen recognition, T-cell receptor (TCR/CD3) and other signaling molecules become enriched in a specialized contact site between the T cell and antigen-presenting cell, i.e. the immunological synapse (IS). Enrichment occurs via mechanisms that include polarized secretion from recycling endosomes, but the Rabs and RabGAPs that regulate this are unknown. EPI64C (TBC1D10C) is an uncharacterized candidate RabGAP we identified by mass spectrometry as abundant in human peripheral blood T cells that is preferentially expressed in hematopoietic cells. EPI64C is a Rab35-GAP based both on in vitro Rab35-specific GAP activity and findings in transfection assays. EPI64C and Rab35 dominant negative (DN) constructs each impaired transferrin export from a recycling pathway in Jurkat T-cells and induced large vacuoles marked by transferrin receptor, TCR, and SNAREs implicated in TCR-polarized secretion. Rab35 localized to the plasma membrane and to intracellular vesicles where it substantially colocalized with TfR and with TCR. Rab35 was strongly recruited to the IS. Conjugate formation was impaired by transfection with Rab35-DN or EPI64C and by EPI64C knock down. TCR enrichment at the IS was impaired by Rab35-DN. Thus, EPI64C and Rab35 regulate a recycling pathway in T cells and contribute to IS formation, most likely by participating in TCR transport to the IS.

Phospholipase C-mediated hydrolysis of PIP2 releases ERM proteins from lymphocyte membrane.

Mechanisms controlling the disassembly of ezrin/radixin/moesin (ERM) proteins, which link the cytoskeleton to the plasma membrane, are incompletely understood. In lymphocytes, chemokine (e.g., SDF-1) stimulation inactivates ERM proteins, causing their release from the plasma membrane and dephosphorylation. SDF-1–mediated inactivation of ERM proteins is blocked by phospholipase C (PLC) inhibitors. Conversely, reduction of phosphatidylinositol 4,5-bisphosphate (PIP2) levels by activation of PLC, expression of active PLC mutants, or acute targeting of phosphoinositide 5-phosphatase to the plasma membrane promotes release and dephosphorylation of moesin and ezrin. Although expression of phosphomimetic moesin (T558D) or ezrin (T567D) mutants enhances membrane association, activation of PLC still relocalizes them to the cytosol. Similarly, in vitro binding of ERM proteins to the cytoplasmic tail of CD44 is also dependent on PIP2. These results demonstrate a new role of PLCs in rapid cytoskeletal remodeling and an additional key role of PIP2 in ERM protein biology, namely hydrolysis-mediated ERM inactivation.

Hepatic expression of macrophage inflammatory protein-1α and macrophage inflammatory protein-1β after liver transplantation

Two local events that are crucial for T cell emigration into tissue are (1) activation of T cell integrins to permit binding to endothelial counter-receptors and (2) directed migration through the endothelium and into tissue in response to chemotactic factors. Because the chemokines macrophage inflammatory protein-1 alpha (MIP-1 alpha) and MIP-1 beta can activate adhesion and induce migration of T cells in vitro, we investigated their expression in human liver allografts to determine whether they might be involved in regulating the recruitment of T cells to allografts in vivo. Both chemokines were expressed strongly by infiltrating leukocytes during rejection and could be detected immunohistochemically on biliary epithelium, an important target for T cell mediated graft damage. Both chemokines, but particularly MIP-1 beta, were detected on the vascular and sinusoidal endothelium of rejecting liver allografts, where they were coexpressed with the T cell beta 1-integrin receptor vascular cell adhesion molecule-1. In situ hybridization with complementary ribonucleic acid probes showed no MIP-1 alpha or MIP-1 beta mRNA in normal liver but dramatic expression of both chemokines in infiltrating leukocytes and graft endothelium during rejection. Expression was reduced after successful corticosteroid treatment of rejection but persisted in patients progressing to chronic rejection. Increased MIP-1 alpha and MIP-1 beta mRNA expression was already found in biopsies taken at the end of the transplant operation, suggesting that early induction of chemokines, possibly in response to graft reperfusion, might promote the subsequent development of graft rejection. These data demonstrate for the first time that MIP-1 alpha and MIP-1 beta are (1) expressed in human liver allografts, (2) produced by endothelial cells in vivo, and (3) induced early after transplantation. They suggest that MIP-1 alpha and MIP-1 beta produced by graft infiltrating leukocytes and graft endothelium might play a crucial role in regulating T cell recruitment to liver allografts in vivo.

Population studies of the HLA-linked SB antigens

Using allogeneic T-cell recognition we have previously defined five new histocompatibility antigens designated “SB” antigens. To standardize typing for these antigens, cryopreserved, primed lymphocytes are now used as standard reagents and a technique of cluster analysis has been modified to score typing results objectively. Two primed lymphocyte reagents are used to define each SB antigen; although derived from independent responder-stimulator combinations, the concordance between the reagents is good (r is greater than 0.86). The SB-antigen distribution in a population of 215 normal donors is consistent with Hardy-Weinberg equilibrium of alleles of a single locus. Estimated gene frequencies ranged between 3 percent (SB5) and 36 percent (SB4) with 31 percent blanks. Analysis of association between the SB antigens and A, B, DR antigens in 200 normal donors revealed that associations were generally weak with a few exceptions, in particular, the A1, B8, DR3, SB1 “haplotype” and also the B7, DR2, SB5 “haplotype”.

Virus-immune cytotoxic T cells recognize structural differences between serologically indistinguishable HLA-A2 molecules

The self-specificity of human influenza virus-immune cytotoxic T cells has been analyzed in order to identify the relationship between the self-determinants which they recognize and the serologically defined HLA-A and -B antigenic determinants. Virus-immune T cells were generated in vitro by culture of normal adult peripheral blood lymphocytes with A/HK influenza virus. Virus-immune effectors from HLA-A2 positive donors were tested on panels of virus-infected target cells from donors who were either HLA-mismatched or matched only for the HLA-A2 specificity. Virus-immune T cells from 11/11 A2-positive donors lysed all A2-matched virus-infected target cells (and no HLA-mismatched targets), except that each of these effector cell populations consistently failed to lyse the virus-infected target cells from one A2-positive donor (designated M7). Although the A2 antigen of donor M7 could also be distinguished from the A2 antigen of other donors by alloimmune cytotoxic T cells, no differences in the A2 antigen of donor M7 could be defined by extensive serological analyses. Results of isoelectric focusing of A2 molecules from three individuals plus M7 demonstrated that the M7 A2 heavy-polypeptide chain is structurally distinct. These results indicate that: 1) there is a strong but incomplete association between a self antigen recognized by virus-immune T cells and the serologically defined HLA-A2 specificity; and 2) there may be at least two structurally and functionally distinct epitopes on the same A2 molecule: one is the serologically defined HLA-A2 antigenic determinant; the other is the self determinant recognized by T cells on HLA-A2 molecules.

Rac1 Mediates Collapse of Microvilli on Chemokine-Activated T Lymphocytes

Lymphocytes circulate in the blood and upon chemokine activation rapidly bind, where needed, to microvasculature to mediate immune surveillance. Resorption of microvilli is an early morphological alteration induced by chemokines that facilitates lymphocyte emigration. However, the antecedent molecular mechanisms remain largely undefined. We demonstrate that Rac1 plays a fundamental role in chemokine-induced microvillar breakdown in human T lymphocytes. The supporting evidence includes: first, chemokine induces Rac1 activation within 5 s via a signaling pathway that involves Gαi. Second, constitutively active Rac1 mediates microvilli disintegration. Third, blocking Rac1 function by cell permeant C-terminal “Trojan” peptides corresponding to Rac1 (but not Rac2, Rho, or Cdc42) blocks microvillar loss induced by the chemokine stromal cell-derived factor 1α (SDF-1α). Furthermore, we demonstrate that the molecular mechanism of Rac1 action involves dephosphorylation-induced inactivation of the ezrin/radixin/moesin (ERM) family of actin regulators; such inactivation is known to detach the membrane from the underlying actin cytoskeleton, thereby facilitating disassembly of actin-based peripheral processes. Specifically, ERM dephosphorylation is induced by constitutively active Rac1 and stromal cell-derived factor 1α-induced ERM dephosphorylation is blocked by either the dominant negative Rac1 construct or by Rac1 C-terminal peptides. Importantly, the basic residues at the C terminus of Rac1 are critical to Rac1’s participation in ERM dephosphorylation and in microvillar retraction. Together, these data elucidate new roles for Rac1 in early signal transduction and cytoskeletal rearrangement of T lymphocytes responding to chemokine.

Constitutively active ezrin increases membrane tension, slows migration, and impedes endothelial transmigration of lymphocytes in vivo in mice

ERM (ezrin, radixin moesin) proteins in lymphocytes link cortical actin to plasma membrane, which is regulated in part by ERM protein phosphorylation. To assess whether phosphorylation of ERM proteins regulates lymphocyte migration and membrane tension, we generated transgenic mice whose T-lymphocytes express low levels of ezrin phosphomimetic protein (T567E). In these mice, T-cell number in lymph nodes was reduced by 27%. Lymphocyte migration rate in vitro and in vivo in lymph nodes decreased by 18% to 47%. Lymphocyte membrane tension increased by 71%. Investigations of other possible underlying mechanisms revealed impaired chemokine-induced shape change/lamellipod extension and increased integrin-mediated adhesion. Notably, lymphocyte homing to lymph nodes was decreased by 30%. Unlike most described homing defects, there was not impaired rolling or sticking to lymph node vascular endothelium but rather decreased migration across that endothelium. Moreover, decreased numbers of transgenic T cells in efferent lymph suggested defective egress. These studies confirm the critical role of ERM dephosphorylation in regulating lymphocyte migration and transmigration. Of particular note, they identify phospho-ERM as the first described regulator of lymphocyte membrane tension, whose increase probably contributes to the multiple defects observed in the ezrin T567E transgenic mice.