Decorin inhibits endothelial migration and tube-like structure formation: role of thrombospondin-1.

Interactions between endothelial cell receptors and the extracellular matrix (ECM) play a critical, yet poorly understood role in angiogenesis. Based on the anti-adhesive role of decorin, we hypothesized that decorin binding to ECM molecules such as thrombospondin-1 (TSP-1) plays a regulatory role in endothelial tube-like structure (TLS) formation. To test this hypothesis, endothelial cells were plated on TSP-1, decorin, or mixed substrates of TSP-1 plus decorin. TLS formation was induced by applying type I collagen on the confluent endothelial monolayer. Cartilage decorin inhibited the formation of TLSs in a concentration-dependent manner. On substrates of high decorin concentrations (2.5 and 5.0 microg/cm(2)) the reduction in TLSs was due either to a reduction in the number of adhering cells or to decreased cell migration. At low decorin concentrations (0.05 and 0.25 microg/cm(2)) the reduction in TLSs was independent of the number of attached cells. Time-lapse video microscopy revealed that decorin substrates facilitated homotypic aggregation and isolated cord formation at the expense of endothelial migration and TLS formation. Consistent with the reduced migration, endothelial cells formed fewer vinculin-positive focal adhesions and actin-stress fibers on decorin substrates. Endothelial migration and TLS formation were also significantly inhibited by skin decorin and the protein core of cartilage decorin. The inhibition of TLS formation by the protein core of cartilage decorin was potentiated by TSP-1. These findings suggest that decorin alone or in combination with TSP-1 interferes with the activation of endothelial cell receptors by ECM molecules, thus blocking intracellular signals that induce cytoskeletal reorganization, migration, and TLS formation.

Modulation of A-NK cell rigidity: In vitro characterization and in vivo implications for cell delivery.

The delivery of cells to specific regions of the vasculature is a critical step in many therapeutic strategies. These include the packaging of DNA or RNA in cell "vehicles" for delivery to tissues, the reconstitution of differentiated cells to an organ using embryonic stem cells, and the enhancement of the immune response using effector lymphocytes. In most cases, these cells must be injected systemically. Unfortunately, ex vivo manipulation or activation can affect cell visco-elastic properties, making it difficult for the injected cells to traverse capillary beds. Compounding the problem is the fact that common agents used in the laboratory for increasing cell deformability generally have adverse side effects on the therapeutic potential of the cells. Using micropipet aspiration techniques, cytotoxicity assays and in vivo trafficking studies we show that: (1) the rigidity of injected effector cells directly affects resistance to passage through tissue; (2) modulation of cytoskeletal organization can be used to decrease cell rigidity, but can also compromise therapeutic efficacy; and (3) thioglycollate, an agent which does not influence effector lymphocyte cytotoxic activity, reduces cell rigidity and entrapment in the lungs.

Lateral view flow system for studies of cell adhesion and deformation under flow conditions.

Physical interactions between circulating cells and the vascular wall play a central role in inflammation, metastasis, atherosclerosis, and therapeutic cell delivery. Unfortunately, traditional in vitro flow assays cannot be used to visualize the details of cell-surface interactions in blood flow because of inappropriate geometry and the poor penetration of light in erythrocyte solutions. To overcome these obstacles, we have developed an agarose-cast cylindrical vessel system to examine the profiles of cells interacting with surfaces under flow conditions. This design allows observation and quantification of cell deformation as cells adhere to surfaces under dynamic flow conditions without modifying the microscope or optical path. Furthermore, our flow system is uniquely suited for monitoring the profiles of adherent leukocytes deforming in response to erythrocyte suspension flow. We have used this flow system to study the role of erythrocytes in leukocyte-substrate interactions. Our results show that the cell deformation index (the ratio of the cell length to cell height) is higher in erythrocyte solutions compared to erythrocyte-free saline. This novel lateral view flow system provides a powerful technique for visualizing and quantifying the morphological changes of cells in contact with substrates exposed to shear stress.

Cells shed from tumours show reduced clonogenicity, resistance to apoptosis, and in vivo tumorigenicity.

The goal of this study was to compare growth characteristics of cells shed from a tumour with the native tumour cells. The human colon adenocarcinoma LS174T and its highly metastatic subline LS LiM 6 were grown as tissue-isolated tumours in nude mice and perfused to collect shed cells. The tumours were then excised and prepared into single-cell suspensions. Clonogenicity in 0.3-0.9% agarose, apoptotic fraction, and in vivo tumorigenicity were determined for each population. In both tumour lines, shed cells were less clonogenic, more apoptotic and less tumorigenic than cells isolated directly from their native tissue. These findings suggest that shed cells have a low metastatic potential compared to native tumour cells, most likely because they represent an apoptotic population.

Angiogenesis in the huPBL-SCID model of human transplant rejection.

BACKGROUND: Angiogenesis is characteristic of chronic inflammatory reactions. The process of angiogenesis is reported to be proinflammatory in part due to enhanced adhesion events and in part due to increased perfusion and permeability to sites of inflammation. However, little is known about the association between angiogenesis and rejection. METHODS: Severe combined immune deficient mice are permissive for the growth of human skin allografts and human peripheral blood mononuclear cells (PBMC). Human PBMC were injected into mice by intravenous or intraperitoneal injection. The infiltration of cells and the associated angiogenesis reactions in the skin allografts were analyzed temporally by videomicroscopy and spatially by immunohistochemistry. RESULTS: Human alloreactive mononuclear cells migrated to human skin but not mouse skin within hours after the intravenous infusion of PBMC. Within 3 days, areas of angiogenesis were observed in the skin grafts at the sites of infiltrates. The vessel densities in skin grafts were 24+/-6 vessels per calibrated grid at baseline on the day of the infusion and increased to 55+/-16 vessels per calibrated field by day 10. Skin grafts harvested from humanized severe combined immune deficient mice 7-14 days after the intraperitoneal infusion of human PBMC showed a similar increased density of vessels that were spatially associated with mononuclear cell infiltrates. CONCLUSIONS: A significant angiogenesis response was associated with the cell infiltrates in the human skin allografts. The onset of angiogenesis appeared after the initial development of localized infiltrates and preceded the development of microvascular destruction. These findings suggest that alloreactive T cells and/or monocytes mediate the angiogenesis response in skin allografts.

In vitro and in vivo quantification of adhesion between leukocytes and vascular endothelium.

When a leukocyte enters a blood vessel, it may continue to move with flowing blood, collide with the vessel wall, adhere transiently or stably, and finally extravasate (1). These interactions are governed by both local hydrodynamic and adhesive forces. The former are determined by the vessel diameter, fluid velocity, viscosity, and hematocrit, and the latter by the number, strength and kinetics of bond formation between adhesion molecules, and by surface area of contact (1-6). Cellular deformability affects both types of forces (7-9). Two families of cell adhesion molecules (CAMs) are involved in leukocyte rolling and stable adhesion. In general, the selectins (P, L, and E) mediate rolling, while the IgG superfamily members (ICAM-1 and VCAM-1) on endothelial cells, with their cognate receptors (ß(2) and ß(1) integrin receptors) on the leukocytes, mediate firm adhesion, with some overlap in these functions (10-12). The expression of CAMs on the endothelial cells and leukocytes can be modulated by cytokines secreted by a variety of cells (e.g., cancer cells, fibroblasts, macrophages) (13,14). Cellular deformability can be modulated by altering the cytoskeleton, membrane, or cytoplasm, with the cytoskeleton playing the dominant role (7,15,16). In this chapter, we describe methods to quantitate cellular deformability in vitro, CAM expression in vitro, leukocyte-endothelial interaction (LEI) in vitro, and LEI in vivo.

Mice lacking E-selectin show normal numbers of rolling leukocytes but reduced leukocyte stable arrest on cytokine-activated microvascular endothelium.

OBJECTIVE: Previous work indicated that E-selectin mediates transient interactions between leukocytes and cytokine-activated endothelium in vitro. Here we examine the role of E-selectin in blood leukocyte interactions with microvascular endothelium in vivo. METHODS: E-selectin-deficient (E-/-) mice were produced by gene targeting. The effect of this null mutation on leukocyte-endothelial interactions was determined by intravital microscopy before and 4 to 5 hours after local administration of the proinflammatory cytokine tumor necrosis factor alpha (TNF alpha) in dermal microvessels with low blood flow (dorsal skin-fold chambers, intact ear skin), and after endotoxin activation in exteriorized mesenteric microvessels with higher blood flow. RESULTS: E-/- mice were viable, fertile with normal circulating leukocyte and platelet profiles. Approximately 60% of circulating leukocytes rolled in dermal microvessels of both normal (E+/+) and E-/- mice without inflammatory stimulation. After local administration of TNF alpha, rolling increased modestly and equivalently in both genotypes. The main effect of TNF alpha was a dramatic increase in leukocyte stable adhesion and, unlike rolling, this manifestation of endothelial activation was significantly reduced in E-/- animals. This reflected fewer dermal microvessels supporting higher adhesion densities in E-/- mice, and a similar trend was observed in mesenteric microvessels. CONCLUSIONS: E-selectin plays a previously unappreciated role in facilitating and/or mediating stable adhesion of leukocytes to inflamed microvascular endothelium.

Intracellular magnetic labeling of lymphocytes for in vivo trafficking studies.

Lymphocyte adhesion and trafficking is difficult to observe in vivo over time. We used magnetic resonance imaging (MRI) to identify magnetically labeled lymphocytes in phantom experiments and in tissue. A method of lymphocyte labeling was developed that is based on fluid-phase endocytosis of nanometer-sized biocompatible superparamagnetic particles. The maximum cell uptake in culture was 0.11 ng Fe/cell corresponding to 5 x 10(6) particles/lymphocyte. Cells stably retained the label and were fully viable for at least 3 days. Labeled lymphocytes showed adhesion to human endothelial cells similar to unlabeled cells, indicating no effect of labeling on cell surface expression of adhesion proteins. No particle-mediated cytotoxicity could be observed. The detection threshold of MRI for detecting labeled lymphocytes in the current study was 2.5 x 10(6) cells/30 microL sampling volume. Following intravenous injection of labeled lymphocytes into rats, cells accumulated in spleen, lymph nodes and liver with a similar bio-distribution as unlabeled cells. Lymphocyte accumulation in the spleen resulted in MRI signal intensity changes readily detectable by MRI. These findings suggest that intracellular lymphocyte labeling with superparamagnetic particles is feasible, does not alter the viability or tissue distribution of labeled cells and allows the detection of labeled lymphocytes by MRI.

Solid stress inhibits the growth of multicellular tumor spheroids.

In normal tissues, the processes of growth, remodeling, and morphogenesis are tightly regulated by the stress field; conversely, stress may be generated by these processes. We demonstrate that solid stress inhibits tumor growth in vitro, regardless of host species, tissue of origin, or differentiation state. The inhibiting stress for multicellular tumor spheroid growth in agarose matrices was 45 to 120 mm Hg. This stress, which greatly exceeds blood pressure in tumor vessels, is sufficient to induce the collapse of vascular or lymphatic vessels in tumors in vivo and can explain impaired blood flow, poor lymphatic drainage, and suboptimal drug delivery previously reported in solid tumors. The stress-induced growth inhibition of plateau-phase spheroids was accompanied, at the cellular level, by decreased apoptosis with no significant changes in proliferation. A concomitant increase in the cellular packing density was observed, which may prevent cells from undergoing apoptosis via a cell-volume or cell-shape transduction mechanism. These results suggest that solid stress controls tumor growth at both the macroscopic and cellular levels, and thus influences tumor progression and delivery of therapeutic agents.

During angiogenesis, vascular endothelial growth factor and basic fibroblast growth factor regulate natural killer cell adhesion to tumor endothelium.

Localization of activated natural killer (A-NK) cells in the microvasculature of growing tumors is the result of recognition of the intracellular and vascular cell-adhesion molecules ICAM-1 and VCAM-1 on the tumor endothelium, mediated by lymphocyte function-associated protein LFA-1 and vascular lymphocyte function-associated protein VLA-4. In vitro and in vivo studies of A-NK cell adhesion to endothelial cells showed that vascular endothelial growth factor (VEGF) promotes adhesion, whereas basic fibroblast growth factor (bFGF) inhibits adhesion through the regulation of these molecules on tumor vasculature. Thus, some angiogenic factors may facilitate lymphocyte recognition of angiogenic vessels, whereas others may provide such vessels with a mechanism that protects them from cytotoxic lymphocytes.

Physiologically based kinetic model of effector cell biodistribution in mammals: implications for adoptive immunotherapy.

The goal of the present investigation was to develop a physiologically based kinetic model to describe the biodistribution of immunologically active effector cells in normal and neoplastic tissues of mammals based on the current understanding of lymphocyte trafficking pathways and signals. The model was used to extrapolate biodistribution among different animal species and to identify differences among different effector populations and between intra-arterial and systemic injections. Most importantly, the model was used to discern critical parameters for improving the delivery of effector cells. In the model, the mammalian body was divided into 12 organ compartments, interconnected in anatomic fashion. Each compartment was characterized by blood flow rate, organ volume and lymphatic flow rate, and other physiological and immunological parameters. The resulting set of 45 differential equations was solved numerically. The model was used to simulate the following biodistribution data: (a) nonactivated T lymphocytes in rats; (b) interleukin 2-activated tumor-infiltrating lymphocytes in humans; (c) nonactivated natural killer (NK) cells in rats; and (d) interleukin 2-activated adherent NK cells in mice. Comparisons between simulations and data demonstrated the feasibility of the model and the scaling scheme. The similarities as well as differences in biodistribution of different lymphocyte populations were revealed as results of their trafficking properties. The importance of lymphocyte infiltration from surrounding normal tissues into tumor tissue was found to depend on lymphocyte migration rate, tumor size, and host organ. The study confirmed that treatment with effector cells has not been as impressive as originally promised, due, in part, to the biodistribution problems. The model simulations demonstrated that low effector concentrations in the systemic circulation greatly limited their delivery to tumor. This was due to high retention in normal tissues, especially in the lung. Reducing normal tissue retention through decreasing attachment rate or adhesion site density in the lung by 50% could increase the tumor uptake by approximately 40% for tumor-infiltrating lymphocytes and by approximately 60% for adherent NK cells. Our analysis suggested the following strategies to improve effector cell delivery to tumor: (a) bypassing the initial lung entrapment with administration to the arterial supply of tumor; (b) reducing normal tissue retention using effector cells with high deformability or blocking lymphocyte adhesion to normal vessels; and (c) enhancing tumor-specific capture and arrest by modifying the tumor microenvironment.

Role of erythrocytes in leukocyte-endothelial interactions: mathematical model and experimental validation.

The binding of circulating cells to the vascular wall is a central process in inflammation, metastasis, and therapeutic cell delivery. Previous in vitro studies have identified the adhesion molecules on various circulating cells and the endothelium that govern the process under static conditions. Other studies have attempted to simulate in vivo conditions by subjecting adherent cells to shear stress as they interact with the endothelial cells in vitro. These experiments are generally performed with the cells suspended in Newtonian solutions. However, in vivo conditions are more complex because of the non-Newtonian flow of blood, which is a suspension consisting of 20-40% erythrocytes by volume. The forces imparted by the erythrocytes in the flow can contribute to the process of cell adhesion. A number of experimental and theoretical studies have suggested that the rheology of blood can influence the binding of circulating leukocytes by increasing the normal and axial forces on leukocytes or the frequency of their collision with the vessel wall, but there have been no systematic investigations of these phenomena to date. The present study quantifies the contribution of red blood cells (RBCs) in cell capture and adhesion to endothelial monolayers using a combination of mathematical modeling and in vitro studies. Mathematical modeling of the flow experiments suggested a physical mechanism involving RBC-induced leukocyte dispersion and/or increased normal adhesive contact. Flow chamber studies performed with and without RBCs in the suspending medium showed increases in wall collision and binding frequencies, and a decrease in rolling velocity in the presence of erythrocytes. Increased fluid viscosity alone did not influence the binding frequency, and the differences could not be attributed to large near-wall excesses of the lymphocytes. The results indicate that RBCs aid in the transport and initial engagement of lymphocytes to the vascular wall, modifying the existing paradigm for immune cell surveillance of the vascular endothelium by adding the erythrocyte as an essential contributor to this process.

Leukocyte-endothelial adhesion and angiogenesis in tumors.

Leukocyte-endothelial adhesion and angiogenesis, until recently considered as separate processes, have been shown to be linked by two recent findings: soluble cellular adhesion molecules (CAMs) involved in leukocyte-endothelial interactions are angiogenic and well known angiogenic molecules secreted by cancer or immune. cells can modulate the endothelial CAMs. This molecular link may partially explain why the overall leukocyte-endothelial interaction is often low and heterogeneous in angiogenic tumor vessels and why activated lymphocytes adhere nonuniformly to tumor vessels when injected into the tumor's blood supply.

Adhesion of activated natural killer cells to tumor necrosis factor-alpha-treated endothelium under physiological flow conditions.

Adhesion of activated natural killer (A-NK) cells to activated and nonactivated endothelial cells in vitro was studied under dynamic flow conditions. Endothelial cells grown on glass slides were either treated with tumor necrosis factor-alpha (TNF alpha) or medium, then placed into a flow chamber over which suspensions of A-NK cells were passed using a range of defined shear stress levels. Significant numbers of binding cells could be consistently observed at shear stress levels less than 3 dyn/cm2 on TNF alpha-activated endothelium or at 0.59 dyn/cm2 on nonactivated endothelium. Stable adhesion occurred rapidly following the initial interaction of the following cells with the endothelium in the absence of detectable rolling. Pretreatment of the A-NK cells with monoclonal antibodies directed against CD18 (LFA-1) or CD49d (VLA-4) resulted in a significant reduction in the number of binding cells. Simultaneous treatment with both monoclonal antibodies eliminated all A-NK adhesion occurring over 0.5 dyn/cm2. Pretreatment of the endothelial cells with antibodies against E- or P-selectin resulted in a small but significant reduction in binding only at 0.5 dyn/cm2. The binding efficiency of the A-NK cells was similar to that previously observed for T lymphocytes under the same conditions. Once bound, approximately half of the adherent cells could resist detachment when exposed to wall shear stresses over 12 dyn/cm2. These findings indicate that A-NK cell adhesion to activated endothelium can occur under shear stress conditions which are representative of postcapillary venules and that this binding is mediated principally by both CD18 and CD49d. A-NK cell adhesion also occurs to nonactivated endothelium but only at wall shear stress levels less than 1 dyn/cm2.

Selectin- and integrin-mediated T-lymphocyte rolling and arrest on TNF-alpha-activated endothelium: augmentation by erythrocytes.

The adhesive and hemodynamic forces that lead to lymphocyte rolling and arrest on activated endothelium and the biophysical role of various adhesion molecules and blood elements in this process are poorly understood. By quantifying their behaviour both in vivo and in vitro, we show here that erythrocytes facilitate selectin- and integrin-mediated rolling and binding of T-lymphocytes on tumor necrosis factor alpha-activated endothelium. The relative contribution of selectins and integrins to this process can be distinguished by using a simple mathematical expression of lymphocyte capture within the range of physiological shear stress. The need for selectin participation in lymphocyte capture increases with shear stress (> 1 dyn/cm2), and both beta 1 and beta 2 integrins act in synergy to produce adhesive drag on captured cells. These findings are potentially useful in developing strategies for intervening with T-cells in a variety of normal and pathological responses as well as for the delivery of genetically modified T-cells to their targets in vivo.

Rolling in P-selectin-deficient mice is reduced but not eliminated in the dorsal skin.

P-selectin-mediated rolling is believed to be important in the recruitment of leukocytes to tissue after ischemia-reperfusion injury. The dorsal skin chamber was used to examine differences in the rolling and stable adhesion of circulating leukocytes in subcutaneous (SC) vessels of P-selectin-deficient and age-matched wild-type mice, both under basal conditions and after ischemia-reperfusion. Rolling in the postcapillary venules in SC tissue of P-selectin-deficient mice was significantly lower than that in wild-type mice under the basal conditions and post-ischemia-reperfusion (P < .05), but was not eliminated by the deletion of the P-selectin gene. No significant difference between P-selectin-deficient and wild-type mice in shear rate or leukocyte-endothelial adhesion was observed up to 24 hours after ischemia-reperfusion. These results show that P-selectin-mediated rolling is not a prerequisite for ischemia-reperfusion-induced leukocyte-endothelial adhesion in the skin.

Tumor necrosis factor alpha-induced leukocyte adhesion in normal and tumor vessels: effect of tumor type, transplantation site, and host strain.

Tumor necrosis factor alpha (TNF-alpha) can lead to tumor regression when injected locally or when used in an isolated limb perfusion, and it can enhance the tumoricidal effect of various therapies. TNF-alpha can also up-regulate adhesion molecules, and thus, facilitate the binding of leukocytes to normal vessels. The present study was designed to investigate the extent to which the host leukocytes roll and adhere to vessels of different tumors (MCaIV, a murine mammary adenocarcinoma; HGL21, a human malignant astrocytoma) at a given site or to the same tumor at different sites (dorsal skin and cranium), in different mouse strains [C3H and severe combined immunodeficient (SCID)], both with and without TNF-alpha-activation. There was no significant difference in hemodynamic parameters such as RBC velocity, diameter, or shear rate between PBS-treated control groups and corresponding TNF-alpha-treated groups. Under PBS control conditions, the leukocyte rolling count in MCaIV tumor vessels in the dorsal chamber in C3H and SCID mice and in the cranial window in C3H mice was significantly lower than that in normal vessels (P < 0.05), but stable cell adhesion was similar between normal and tumor vessels. TNF-alpha led to an increase (P < 0.05) in leukocyte-endothelial interaction in vessels in the following cases: normal tissue regardless of sites and strains, MCaIV tumor in the cranial window in C3H mice, and HGL21 tumor in the cranial window in SCID mice. However, the increase in rolling and adhesion in the MCaIV tumor in response to TNF-alpha was significantly lower than in the corresponding normal vessels (P < 0.05) in the dorsal chamber in C3H and SCID mice and in the cranial window in C3H mice. The HGL21 tumor in the cranial window in SCID mice showed leukocyte rolling and adhesion comparable to that in normal pial vessels. These findings suggest that (a) in general, basal leukocyte rolling is lower in tumor vessels than in normal vessels; (b) leukocyte rolling and adhesion in tumors can be enhanced by TNF-alpha-mediated activation; and (c) the TNF-alpha response is dependent on tumor type, transplantation site, and host strain. These results have significant implications in the gene therapy of cancer using TNF-alpha-gene-transfected cancer cells or lymphocytes.