Cell adhesion and communication最新文献

Lysophosphatidate (LPA) is an intercellular phospholipid messenger with a wide range of biologic effects. The first discovered source of LPA in the human body were activated platelets, but several other sites of LPA generation are now known. The number of cellular interactions is also growing steadily and responses to the compound range wide, from induction of mitogenesis to neurite retraction. LPA acts via a specific G protein-coupled receptor, of which one or more subtypes may exist. Intracellularly, this receptor activates several heterotrimeric G proteins. LPA induces cell proliferation via the small GTP-binding proteins ras, and triggers actin-based cytoskeletal events through rho. This review describes the most relevant recent developments in our understanding of LPA signaling.

CD44 is the principle transmembrane receptor for the extracellular matrix glycosaminoglycan, hyaluronan. This receptor: ligand interaction is required for many normal cellular processes including lymphocyte homing into inflammatory sites, assembly of a pericellular matrix during chondrogenesis, wound healing and tissue morphogenesis during development. In order to mediate these diverse events, CD44 expressing cells must be able to regulate, and respond to, interactions with hyaluronan. The mechanisms responsible have been subject to scrutiny over the past few years as it has become clear that their disruption can underlie the progression of both metastatic tumours and chronic inflammatory diseases. Here we describe recent data identifying discrete regions within the transmembrane and cytoplasmic domains of CD44 which regulate this important adhesion receptor.

It has been clearly shown that continuous recirculation of lymphocytes is crucial for the development of primary immune responses and that naive CD4 cells are distinguished from memory CD4 cells by differences in expression of several adhesion molecules. These findings suggest that changes in migratory behavior accompany the naive to memory cell transition. This area is first reviewed and then to evaluate this hypothesis, we compare the tissue distributions of highly purified naive and memory CD4 cells after transfer to syngeneic recipients. Naive cells which express high levels of L-selectin, and low levels of alpha 4 and beta 2 integrins, and CD44 localized in secondary lymphoid organs and were detectable in these tissues and in the blood for several weeks after transfer. Memory cells, which have a reciprocal phenotype, showed a markedly different distribution, particularly with respect to tissues where entry is controlled through high endothelial venules.

To study the diversity of protocadherins, a rat brain cDNA library was screened using a cDNA for the cytoplasmic domain of human protocadherin Pcdh2 as a probe. The resultant clones contained three different types. One type corresponds to rat Pcdh2; the other two types are distinct from Pcdh2 but contain the same sequence in their cytoplasmic domains and part of the 3' flanking sequence. To clarify the structure of the proteins defined by the new clones, a putative entire coding sequence corresponding to one of the clones was determined. The overall structure is essentially the same as Pcdh2, indicating that the proteins defined by this clone, and probably by other clones, belong to the protocadherin family. Two PCR experiments and an RNase protection assay showed the existence of the corresponding mRNAs in rat brain preparations. Human and mouse cDNA clones with the same sequence properties were also isolated. Taken together, these results indicate that the clones are not cloning artifacts and that corresponding mRNAs are actually expressed in brains of various species. The results of in situ hybridization showed that the mRNAs corresponding to these clones were expressed in different regions in brain. Since protocadherins encoded by these mRNAs are likely to have different specificity in their interaction and share a common activity at their cytoplasmic domains, these protocadherins may provide a molecular basis, in part, to support the complex cell cell interaction in brain.

Ligands for L-selectin are expressed not only on vascular endothelial cells but also in the extravascular tissues. In this article, we summarize the current understanding of the "vascular" ligands for L-selectin. We also describe identification of "non-vascular" ligands for L-selectin and discuss their possible biological significance.

Blood-borne lymphocytes migrate continuously to peripheral lymph nodes (PLN) and other organized lymphoid tissues where they are most likely to encounter their cognate antigen. Lymphocyte homing to PLN is a highly regulated process that occurs exclusively in specialized high endothelial venules (HEV) in the nodal paracortex. Recently, it has become possible to explore this vital aspect of peripheral immune surveillance by intravital microscopy of the subiliac lymph node microcirculation in anesthetized mice. This paper reviews technical and experimental aspects of the new model and summarizes recent advances in our understanding of the molecular mechanisms of lymphocyte homing to PLN which were derived from its use. Both lymphocytes and granulocytes initiate rolling interactions via L-selectin binding to the peripheral node addressin (PNAd) in PLN HEV. Subsequently, a G protein-coupled chemoattractant stimulus activates LFA-1 on rolling lymphocytes, but not on granulocytes. Thus, granulocytes continue to roll through the PLN, whereas LFA-1 activation allows lymphocytes to arrest and emigrate into the extravascular compartment. We have also identified a second homing pathway that allows L-selectin low/(activated/memory) lymphocytes to home to PLN. P-selectin on circulating activated platelets can mediate simultaneous platelet adhesion to PNAd in HEV and to P-selectin glycoprotein ligand (PSGL)-1 on lymphocytes. Through this mechanism, platelets can form a cellular bridge which can effectively substitute for the loss of L-selectin on memory cell subsets.

The principles determining the migration of different cell types may results from their differences in origin, size and shape, function of adhesion receptors, and environmental factors, including the extracellular matrix. Polarized leukocytes (T lymphocytes and dendritic cells) migrating in three-dimensional collagen lattices are small developing a highly dynamic leading edge and a trailing uropod, whereas invasive melanoma cells are larger, highly polarized and less dynamic. In contrast to leukocyte, tumor cells may additionally develop migrating cell clusters maintaining intense cell-cell interaction and cluster polarity. Leukocytes show a speed-oriented, oscillating and directionally unpredictable path profile strongly guided by matrix fibers, while melanoma cells and migrating cell clusters exhibit slow yet highly directional migration. Whereas leukocytes form short-lived interactions with collagen fibers in complete absence of tissue remodeling, melanoma cells and neoplastic cell clusters reorganize the matrix via profound pulling at attachment sites, limited fiber disruption upon detachment, and the shedding of cell surface determinants. Using blocking anti-integrin antibodies, tumor cell migration and migration-associated matrix reorganization were shown to be dependent on beta 1 integrin-mediated adhesion, whereas migrating T cells cannot be inhibited by a panel of anti-beta 1-, beta 2-, beta 3-, and alpha-integrin antibodies, either alone or in combination. Consequently, migrating melanoma cells use focal adhesions of integrins coclustered with cytoskeletal components at contacts with collagen fibers. T cells, however, lack typical focal adhesions, redistribute beta 1 integrins to the uropod and the focal adhesion kinase to the leading edge. In conclusion, an adhesion-dependent and reorganizing migration type employed by melanoma cells may be distinct from largely integrin-independent and non-reorganizing migration strategies used by leukocytes.

L-selectin plays a major role in leukocyte traffic through lymph node high endothelial venules (HEV). We have investigated the role of GlyCAM-1, a major L-selectin ligand produced by HEV, in mediating leukocyte rolling under in vitro flow conditions. Purified GlyCAM-1 was found to support tethering and rolling in physiological shear flow of both human and murine L-selectin expressing leukocytes at an efficiency comparable to the HEV-derived L-selectin ligands termed peripheral node addressin (PNAd). Major dynamic differences between L-selectin rolling of peripheral blood T lymphocytes and neutrophils expressing similar L-selectin level were observed on GlyCAM-1. Lymphocytes established slower and more shear resistant rolling than neutrophils and could roll on GlyCAM-1 at shear stresses lower than the threshold values required for L-selectin-mediated neutrophil rolling. Notably, high stability of L-selectin rolling of lymphocytes requires intact cellular energy, although initial lymphocyte tethering to L-selectin ligands is energy-independent. By contrast, L-selectin mediated rolling of neutrophils is insensitive to energy depletion. The distinct dynamic behavior and energy-dependence of L-selectin rolling in different leukocytes suggest that L-selectin adhesiveness in shear flow is regulated in a cell-type specific manner. The greater stability of L-selectin rolling of lymphocytes on surface-adsorbed GlyCAM-1 may contribute to their selective recruitment at peripheral lymph nodes.

Migration of circulating neutrophils occurs in several steps: capture and rolling adhesion are followed by activation of beta 2-integrins and immobilisation, and then neutrophils move over and through the endothelium. However, it is not clear how the underlying mechanisms and completion of each step depend on the concentration of stimulatory cytokines such as tumour necrosis factor-alpha (TNF). We therefore perfused neutrophils over human umbilical vein endothelial cells (HUVEC) which had been cultured with varying concentration of TNF (1-1000 U/ml) for 4 h, and recorded adhesion and migration by videomicroscopy. The number of adherent neutrophils increased with increasing TNF up to 5 U/ml, but changed little at higher concentrations. Interestingly, rolling adhesion at first predominated, but an increasing proportion of adherent cells became immobilised and migrated through the HUVEC monolayer over the complete TNF range. Immobilisation was inhibited by treating neutrophils with antibody against CD18, so that the major change in adhesive behaviour at higher levels of TNF occurred because the surface of the HUVEC presented agent(s) able to activate neutrophil beta 2-integrins. It was also evident that the selectins initiating capture of flowing neutrophils varied with concentration of TNF. At 100 U/ml TNF, both E-selectin and P-selectin supported capture and rolling adhesion, and antibody blockade of both receptors was required to inhibit adhesion. At lower dose (10 U/ml TNF), stable adhesion was blocked by antibody against E-selectin, although short-lived attachments could still be seen which were inhibited by antibody against P-selectin. Expression of sclectins increased with increasing concentration of TNF, judging from surface ELISA and reduction in the velocity of rolling adherent cells. Thus the efficiency of capture, the selectins mediating capture and the proportion of captured cells immobilised and migrating all depend on the concentration of TNF to which endothelial cells are exposed. These results suggest a model in which highly localised and efficient migration of neutrophils is achieved if a concentration gradient of TNF exists around an inflammatory locus.

Upon an increasing cell density human neutrophils develop more cell-to-cell contacts in conjunction with an increase in the pHi. These changes are accompanied by decreased superoxide formation after adherence, and a decrease in the total amount of 5-lipoxygenase products after various stimuli. Among the various arachidonate metabolites, leukotriene formation remained almost constant but the yield in 5-HETE decreased. This drop in could account for the decrease in total 5-lipoxygenase products observed when the cell density increased. We conclude that cellular signalling can be affected by an increase of cell-cell interactions. Whether the increase in cellular pH is a cause or consequence of such contact inhibition has yet be answered.