Interstitial leukocyte migration and immune function

The trafficking of leukocytes into and within lymphoid and peripheral tissues is central to immune cell development, immunosurveillance and effector function. Interstitial leukocyte trafficking is the result of amoeboid polarization and migration, guided by soluble or tissue-bound chemoattractant signals for positioning and local arrest. In contrast to other migration modes, amoeboid movement is particularly suited for scanning cellular networks and tissues. Here, we review mechanisms of leukocyte migration and sensing involved in diapedesis, tissue-based interstitial migration and egress, immune cell positioning in inflammation, and emerging therapeutic interference strategies.     

Amoeboid leukocyte crawling through extracellular matrix: lessons from the Dictyostelium paradigm of cell movement

Cell movement within three-dimensional tissues is a cycling multistep process that requires the integration of complex biochemical and biophysical cell functions. Different cells solve this challenge differently, which leads to differences in migration strategies. Migration principles established for leukocytes share many characteristics with those described for ameba of the lower eukaryote Dictyostelium discoideum. The hallmarks of amoeboid movement include a simple polarized shape, dynamic pseudopod protrusion and retraction, flexible oscillatory shape changes, and rapid low-affinity crawling. Amoeboid crawling includes haptokinetic adhesion-dependent as well as biophysical migration mechanisms on or within many structurally and functionally different substrates. We describe central aspects of amoeboid movement in leukocytes and the implications for leukocyte crawling and positioning strategies within interstitial tissues.     

Viscoelastic Gel-Strip Model for the Simulation of Migrating Cells

Migrating tumor cells can exhibit both mesenchymal- and amoeboid-type behaviors. Recent studies have shown that both cellular and extracellular structural and mechanical variables control the transition of tumor cells from one mode to the other and provide them with morphological plasticity. The mesenchymal-mode migration is characterized by strong adhesion and proteolytic machinery to navigate through complex extracellular matrices. The amoeboid-mode migration is characterized by little or no adhesion and strong actomyosin contraction to squeeze through the matrices. While adhesion dependent migration has been computationally and experimentally studied in both 2D and 3D environments, quantitative models of amoeboid motion in native environments are lacking. In order to address this major gap in our understanding and to probe the mesenchymal to amoeboid transitions quantitatively and comprehensively, we have developed an axisymmetric viscoelastic gel-strip model of a single cell to investigate a cell migrating in native-like environments. In this model, cell migration and morphology are governed by internal stresses as well as external forces. The internal stresses are controlled by F-actin density distribution, protrusion strength, and contraction strength. The external forces are controlled by adhesion strength and steric resistance from the extracellular matrix. Our model predicts that the transition of the cell migration mode from mesenchymal- to amoeboid-type, and vice versa, is closely related to the loss of adhesion as well as increased contraction strength of the cells. Our results indicate that amoeboid migration is more suited for low-resistance environment while mesenchymal migration is preferred in high-resistance environment, which would explain the versatile behaviors of tumor cells in complex environments.     

Immune cell migration as a means to control immune privilege: lessons from the CNS and tumors

Summary:  Certain organs, such as the brain, eye, and gonads, are particularly sensitive to damage by inflammation. Therefore, these tissues have developed unique immunological properties that curtail inflammatory responses, a phenomenon termed immune privilege. In addition, by co-opting some of the regulatory cues operant in immune privilege in normal organs, tumors can evade immunosurveillance. While many different mechanisms contribute to immune privilege, there is evidence that leukocyte migration is an important checkpoint in its control. This hypothesis is based on the fact that leukocyte entry into these organs is restricted by physical barriers and that the collapse of these obstacles marks a critical step in the development of inflammatory/autoimmune disease at these sites. Numerous studies in a variety of experimental systems have characterized the molecular and cellular mechanisms involved in leukocyte homing to immune-privileged organs. Recently, two-photon microscopy has revealed critical insights into the events occurring in the extravascular space of immune-privileged organs, including locomotion patterns and interactive behavior of leukocytes in the interstitial space. Here, we review our current understanding of immune cell migration to and within immune-privileged organs and highlight how this knowledge may be exploited for immunotherapeutic purposes.     

Extracellular proteolysis in macrophage migration: losing grip for a breakthrough

Macrophage tissue infiltration is a hallmark of several pathological situations including cancer, neurodegenerative disorders and chronic inflammation. Hence, deciphering the mechanisms of macrophage migration across a variety of tissues holds great potential for novel anti-inflammatory therapies. Leukocytes have long been thought to migrate through tissues by using the amoeboid (protease-independent) migration mode; however, recent evidence indicates that macrophages can use either the amoeboid or the mesenchymal (protease-dependent) migration mode depending on the environmental constraints. Proteolytic activity is required for several key processes including cell migration. Paradoxically, the role of proteases in macrophage migration has been poorly studied. Here, by focusing on the best characterized extracellular protease families - MMPs, cathepsins and urokinase-type plasminogen activator - we give an overview of their probable involvement in macrophage migration. These proteases appear to play a role in all of the situations encountered by migrating macrophages, i.e. diapedesis, 2D and 3D migration. Migration of macrophages across tissues seems to proceed through an integrative analysis of numerous environmental clues allowing the cells to adapt their migration mode (amoeboid/mesenchymal) and secrete dedicated proteases to ensure efficient tissue infiltration, as discussed in this review. The role of proteases in macrophage migration is an emerging field of research, which deserves further work to allow a more precise understanding.     

SPARC is a VCAM-1 counter-ligand that mediates leukocyte transmigration

VCAM-1 is a cell surface molecule, which has been shown to mediate leukocyte adhesion to the endothelium and subsequent transmigration. Although VCAM-1 regulates adhesion through its interaction with VLA-4, VLA-4 does not play a role in VCAM-1-dependent diapedesis, an observation suggesting the presence of a second ligand for VCAM-1. We now report a novel interaction between VCAM-1 and secreted protein acidic and rich in cysteine (SPARC), which induces actin cytoskeletal rearrangement and intercellular gaps, physiological processes known to be important for leukocyte transmigration. The binding of leukocyte-derived SPARC to VCAM-1 was demonstrated to be necessary for leukocyte transmigration through endothelial monolayers (diapedesis) in vitro, and furthermore, SPARC null mice have abnormalities in leukocyte recruitment to the inflamed peritoneum in vivo. These findings provide new insight into the mechanisms of transendothelial leukocyte migration and suggest a potential, targetable interaction for therapeutic intervention.     

Integrin signal transduction in myeloid leukocytes

Integrin-mediated adhesion serves as a powerful costimulus for neutrophil activation. Clustering of integrins at the leukocyte membrane by interaction with surface-bound ligands (extracellular matrix proteins or endothelial cell counter-receptors) leads to a number of signaling events that culminate in actin cytoskeletal rearrangement and neutrophil functional responses such as migration, degranulation, and respiratory burst. Although the signaling reactions elicited by integrin ligation are complex and the relative contribution of each pathway to neutrophil function is unclear, a large body of evidence suggests that activation of tyrosine kinases is a very proximal event in these signaling cascades. This review summarizes the role of adhesion in activating neutrophil functional properties and the contribution of leukocyte tyrosine kinases to regulation of integrin signaling in myeloid cells. Significant advances in our understanding of leukocyte integrin signaling have been afforded by studies using knockout mice lacking members of the Src-family of tyrosine kinases normally expressed in myeloid cells. These studies have demonstrated that these kinases (Hck, Fgr, and Lyn) are not required for myeloid cell development or for many of the functional properties of myeloid cells but are critical in controlling integrin-mediated signaling events. Absence of these kinases results in impaired adhesion-dependent neutrophil activation both in vivo and in vitro. These studies suggest that leukocyte-specific tyrosine kinases may be good therapeutic targets for controlling myeloid cell-dependent inflammatory disease.     

Leukocyte traffic to sites of inflammation.

The adhesion of circulating leukocytes to the vascular endothelium is essential for effective host inflammatory and immune responses. Adhesion proteins expressed by both the leukocyte and endothelial cell have been well characterized, and studies of these molecules have shown that both cell types are actively involved in regulating these binding events. Most leukocyte (leukocyte integrins) and endothelial cell (vascular selectins, ICAM-1, and VCAM) adhesion proteins increase in expression and function in response to mediators released by inflamed tissues. In contrast, the expression and function of one type of leukocyte molecule, L-selectin (previously called LECAM-1, LAM-1, gp90MEL-14), is "down-regulated" by inflammatory signals. The purpose of this review is to summarize in vitro and in vivo regulatory and functional studies of some of the molecular mechanisms which regulate leukocyte-endothelial cell adhesion, with particular emphasis on L-selectin, and to present a hypothetical model of how these molecules may be orchestrated in vivo resulting in the control of host inflammatory responses.     

Imaging the function of regulatory T cells in vivo

Despite extensive research on regulatory T cells (Tregs) since their rebirth more than twenty years ago, the cellular and molecular mechanisms by which they act to suppress immune responses remain largely elusive. In vitro suppression assays are instrumental in the functional identification of these cells. However, suppressive mechanisms defined in in vitro assays might not be relevant to situations in vivo. Advances in live tissue and intravital imaging technologies combined with the ability to grow large numbers of Tregs for in vivo experimentation have created an opportunity to analyze Treg function in vivo in their native environment in real-time. Two-photon laser-scanning microscopic studies of Treg control of lymph node priming suggest that Tregs exert their function by limiting T helper (Th) cell access to dendritic cells (DCs). In the absence of Tregs, Th cells initially form transient interactions with DCs that lead to arrest of the Th cells and to the formation of stable conjugates between Th cells and DCs. In the presence of increasing number of Tregs, Th cell arrest and their prolonged contacts with DCs are progressively inhibited. The reduced DC contacts in the presence of Tregs are associated with suppressed proliferation and differentiation of Th cells. Expansion of such analysis to peripheral tissues together with the development of functional reporter mice will help to further elucidate the mode of operation of Tregs in vivo.     

Cell-autonomous and environmental contributions to the interstitial migration of T cells

A key to understanding the functioning of the immune system is to define the mechanisms that facilitate directed lymphocyte migration to and within tissues. The recent development of improved imaging technologies, most prominently multi-photon microscopy, has enabled the dynamic visualization of immune cells in real-time directly within intact tissues. Intravital imaging approaches have revealed high spontaneous migratory activity of T cells in secondary lymphoid organs and inflamed tissues. Experimental evidence points towards both environmental and cell-intrinsic cues involved in the regulation of lymphocyte motility in the interstitial space. Based on these data, several conceptually distinct models have been proposed in order to explain the coordination of lymphocyte migration both at the single cell and population level. These range from “stochastic” models, where chance is the major driving force, to “deterministic” models, where the architecture of the microenvironment dictates the migratory trajectory of cells. In this review, we focus on recent advances in understanding naïve and effector T cell migration in vivo. In addition, we discuss some of the contradictory experimental findings in the context of theoretical models of migrating leukocytes.     

Adhesion molecule cascades direct lymphocyte recirculation and leukocyte migration during inflammation

Leukocyte inter actions with vascular endothelium are high lyorchestrated processes that include the capture of free-flow ing leukocytes from the blood with subsequent leukocyte rolling, arrest, firm adhesion, and ensuing diapedesis. These interactions occur under high shear stresses within venules and depend on multiple families of adhesion molecules. Many of the adhesion molecules involved are now identified. In addition, precise mechanisms underlying their regulation and our understanding of how different families of adhesion molecules work together is becoming clearer. Specifically, leukocyte/endothelial cell interactions such as capture, rolling, and firm adhesion can no longer beviewed asoccurring in discrete steps mediated by individual families of adhesion molecules, but rather as a series of overlapping synergistic interactions among adhesion molecules resulting in an adhesion cascade. Although long thought to be mediated by distinct adhesion pathways, overlapping adhesion cascades mediate normal lymphocyte recirculation to peripheral lymphoid tissues and inflammation-induced leukocyte migration. These cascades thereby direct leukocyte migration, which is essential for the generation of effective inflammatory responses and the development of rapid immune responses.     

The actin cytoskeleton in cancer cell motility

Cancer cell metastasis is a multi-stage process involving invasion into surrounding tissue, intravasation, transit in the blood or lymph, extravasation, and growth at a new site. Many of these steps require cell motility, which is driven by cycles of actin polymerization, cell adhesion and acto-myosin contraction. These processes have been studied in cancer cells in vitro for many years, often with seemingly contradictory results. The challenge now is to understand how the multitude of in vitro observations relates to the movement of cancer cells in living tumour tissue. In this review we will concentrate on actin protrusion and acto-myosin contraction. We will begin by presenting some general principles summarizing the widely-accepted mechanisms for the co-ordinated regulation of actin polymerization and contraction. We will then discuss more recent studies that investigate how experimental manipulation of actin dynamics affects cancer cell invasion in complex environments and in vivo.     

Periarteriolar localization of mast cells promotes oriented interstitial migration of leukocytes in the hamster cheek pouch.

As studied by intravital microscopy, mast cell-dependent inflammatory reactions evoked by antigen or compound 48/80 in the hamster cheek pouch involved leakage of plasma and emigration of leukocytes exclusively from the venules. The leukocyte diapedesis and subsequent tissue migration induced by antigen or compound 48/80 were oriented from the venules towards adjacent arterioles. In contrast, leukocyte emigration induced by a mast cell-independent stimulus, leukotriene B4, did not show preferential orientation towards arterioles. Moreover, mast cells were abundant in the hamster cheek pouch, and they were localized predominantly along arterioles, rather than along venules. Because mast cells are considered to be the source of the chemotactic mediators causing the leukocyte emigration, the periarteriolar mast cell localization may be of functional significance by creating chemotactic gradients between arterioles and venules, thereby promoting oriented and effective interstitial migration of leukocytes. Whether or not a similar mechanism is operative in other species and tissues remains to be established, however, arteriolar predominance of mast cells was observed also in rat calvarial periosteum and in mouse skin.     

Contraction of collagen-glycosaminoglycan matrices by peripheral nerve cells in vitro

The objective of this study was to investigate the contractile behavior of peripheral nerve support cells in collagen-glycosaminoglycan (GAG) matrices in vitro. Contractile fibroblasts (myofibroblasts) are known to participate in wound contraction during healing of selected connective tissues (viz., dermis), but little is known about the activity of non-muscle contractile cells during healing of peripheral nerves. Explants from adult rat sciatic nerves were placed onto collagen-GAG matrix disks and maintained in culture for up to 30 days. Groups of collagen-GAG matrices were tested that differed in average pore diameter and in degree of cross-linking. Cell migration from nerve explants into the matrices was examined, and immunohistochemical staining was used to identify cells expressing a contractile actin isoform (alpha-smooth muscle actin; alpha-SMA) and Schwann cells (S-100). Geometric contraction of matrix disks was quantified every five days as the percent reduction in disk diameter. The amount of contraction of matrix disks was significantly affected by the degree of cross-linking. Cell migration into the matrices and the distribution of cells staining for alpha-SMA or S-100 was not affected by matrix parameters. These studies demonstrate that cells from peripheral nerve explants were capable of adopting a contractile phenotype and causing geometric contraction of matrices in vitro and suggest that contractile processes may be important during nerve wound healing in vivo.     

Mechanisms of lymphocyte migration in autoimmune disease

The recruitment of leukocytes to inflamed tissues plays an essential role in combating infection and promoting wound healing. However, in autoimmune diseases such as multiple sclerosis and diabetes, leukocytes enter tissues and contribute to inappropriate inflammatory responses, which cause tissue injury and dysfunction. In diseases of this type, lymphocytes play critical roles in initiating and maintaining these aberrant inflammatory responses. The aim of this review is to examine the mechanisms whereby T-lymphocytes enter tissues in autoimmune diseases and to compare these mechanisms between various organs and diseases. An overview of the mechanisms of leukocyte recruitment and the techniques used to study leukocyte trafficking is provided, focusing on the use of intravital microscopy as a tool to assess the functional microvasculature in vivo. We also discuss the series of tissue homing events which allow na?ve lymphocytes to first enter lymph nodes and undergo activation, then subsequently to home to the peripheral organ where their cognate antigen is present. Finally, we examine mechanisms of leukocyte recruitment in diseases such as multiple sclerosis, autoimmune diabetes, systemic lupus erythematosus, rheumatoid arthritis, inflammatory bowel disease and asthma.     

Absence of the endothelial oxidase AOC3 leads to abnormal leukocyte traffic in vivo

Leukocyte migration from the blood to tissues is a prerequisite for normal immune responses. We produced mice deficient in an endothelial cell-surface oxidase (amine oxidase, copper containing-3 [AOC3], also known as vascular adhesion protein-1 [VAP-1]) and found that this enzyme is needed for leukocyte extravasation in vivo. Real-time imaging shows that AOC3 mediates slow rolling, firm adhesion, and transmigration of leukocytes in vessels at inflammatory sites and lymphoid tissues. Absence of AOC3 results in reduced lymphocyte homing into lymphoid organs and in attenuated inflammatory response in peritonitis. These data alter the paradigm of leukocyte extravasation cascade by providing the first physiological proof for the concept that endothelial cell surface enzymes regulate the development of inflammatory reactions in vivo and suggest that this enzyme should be useful as an anti-inflammatory target.     

Concepts of GPCR‐controlled navigation in the immune system

G‐protein–coupled receptor (GPCR) signaling is essential for the spatiotemporal control of leukocyte dynamics during immune responses. For efficient navigation through mammalian tissues, most leukocyte types express more than one GPCR on their surface and sense a wide range of chemokines and chemoattractants, leading to basic forms of leukocyte movement (chemokinesis, haptokinesis, chemotaxis, haptotaxis, and chemorepulsion). How leukocytes integrate multiple GPCR signals and make directional decisions in lymphoid and inflamed tissues is still subject of intense research. Many of our concepts on GPCR‐controlled leukocyte navigation in the presence of multiple GPCR signals derive from in vitro chemotaxis studies and lower vertebrates. In this review, we refer to these concepts and critically contemplate their relevance for the directional movement of several leukocyte subsets (neutrophils, T cells, and dendritic cells) in the complexity of mouse tissues. We discuss how leukocyte navigation can be regulated at the level of only a single GPCR (surface expression, competitive antagonism, oligomerization, homologous desensitization, and receptor internalization) or multiple GPCRs (synergy, hierarchical and non‐hierarchical competition, sequential signaling, heterologous desensitization, and agonist scavenging). In particular, we will highlight recent advances in understanding GPCR‐controlled leukocyte navigation by intravital microscopy of immune cells in mice.     

Two-photon microscopy analysis of leukocyte trafficking and motility

During the last several years, live tissue imaging, in particular using two-photon laser microscopy, has advanced our understanding of leukocyte trafficking mechanisms. Studies using this technique are revealing distinct molecular requirements for leukocyte migration in different tissue environments. Also emerging from the studies are the ingenious infrastructures for leukocyte trafficking, which are produced by stromal cells. This review summarizes the recent imaging studies that provided novel mechanistic insights into in vivo leukocyte migration essential for immunosurveillance.     

A real time in vitro assay for studying leukocyte transendothelial migration under physiological flow conditions

The mechanisms underlying leukocyte migration across endothelial barriers are largely elusive. Most of the current knowledge on transendothelial migration (TEM) of leukocytes has been derived from in vitro modified Boyden chamber transfilter migration assays. In these assays, leukocyte migration towards chemokine gradients constructed across the endothelial barrier is measured under shear-free conditions. These assays do not incorporate the contribution of shear flow to leukocyte adherence and migration across the endothelial barrier. Furthermore, transfilter assays do not reconstitute the physiological distribution of endothelial chemokines shown to be displayed in vivo at high levels on vessel walls. To overcome these two drawbacks, we have recently developed a novel in vitro assay to follow real time leukocyte migration across endothelial barriers under physiological flow conditions. Using this assay, we have found that apically displayed endothelial chemokines could trigger robust lymphocyte TEM through signaling to lymphocyte-expressed G-protein coupled receptors. This migration required continuous exposure of lymphocytes, adherent to the endothelial barrier, to fluid shear, but did not require a chemotactic gradient across the barrier. In the present review, we describe this new flow-based migration assay and discuss future applications for investigating TEM processes of different types of leukocytes across distinct endothelial barriers.     

Rodent models of lymphocyte migration.

The ability of leukocytes to migrate out of blood into tissues enables them to perform their surveillance functions. Understanding the molecular mechanisms by which this migration is accomplished has the potential of unveiling new methods of regulating immune responses. The existing knowledge of rodent physiology and the recent development of knockout mice makes rodents attractive models for studying the mechanisms of leukocyte migration in vivo. This review considers the existing rodent models in light of the knowledge gained from them in lymphocyte migration, and in addition, shows the advantages and limitations of using rodent models in studying lymphocyte migration.