Hypergravity-induced immunomodulation in a rodent model: lymphocytes and lymphoid organs

The major goal of this study was to quantify changes in lymphoid organs and cells over time due to centrifugation-induced hypergravity. C57BL/6 mice were exposed to 1, 2 and 3 G and the following assays were performed on days 1, 4, 7, 10, and 21: spleen, thymus, lung, and liver masses; total leukocyte, lymphocyte, monocyte/macrophage, and granulocyte counts; level of splenocyte apoptosis; enumeration of CD3+ T, CD3+/CD4+ T helper, CD3+/CD8+ T cytotoxic, B220+ B, and NK1.1+ natural killer cells; and quantification of cells expressing CD25, CD69, and CD71 activation markers. The data show that increased gravity resulted in decreased body, spleen, thymus, and liver, but not lung, mass. Significant reductions were noted in all three major leukocyte populations (lymphocytes, granulocytes, monocyte/macrophages) [correction of macrphages] with increased gravity; persistent depletion was noted in blood but not spleen. Among the various lymphocyte populations, the CD3+/CD8+ T cells and B220+ B cells were the most affected and NK1.1+ NK cells the least affected. Overall, the changes were most evident during the first week, with a greater influence noted for cells in the spleen. A linear relationship was found between some of the measurements and the level of gravity, especially on day 4. These findings indicate that hypergravity profoundly alters leukocyte number and distribution in a mammalian model and that some aberrations persisted throughout the three weeks of the study. In certain cases, the detected changes were similar to those observed after whole-body irradiation. In future investigations we hope to combine hypergravity with low-dose rate irradiation and immune challenge.     

Responses to hypergravity in proliferation of Paramecium tetraurelia

It has been reported that Paramecium proliferates faster when cultured under microgravity in orbit, and slower when cultured under hypergravity. This shows that the proliferation rate of Paramecium affected by gravity. The effect of gravity on Paramecium proliferation has been argued to be direct in a paper with an axenic culture under hypergravity. To clear up uncertainties with regard to the effect of gravity, Paramecium tetraurelia was cultured axenically under hypergravity (20 x g) and the time course of the proliferation was investigated quantitatively by a new non-invasive method, laser-beam optical slice, for measuring the cell density. This method includes optical slicing a part of the culture and computer-aided counting of cells in the sliced volume. The effects of hypergravity were assessed by comparing the kinetic parameters of proliferation that were obtained through a numerical analysis based on the logistic growth equation. Cells grown under 20 x g conditions had a significantly lower proliferation rate, and had a lower population density at the stationary phase. The lowered proliferation rate continued as long as cells were exposed to hypergravity (> one month). Hypergravity reduced the cell size of Paramecium. The long and short axes of the cell became shorter at 20 x g than those of control cells, which indicates a decrease in volume of the cell grown under hypergravity and is consistent with the reported increase in cell volume under microgravity. The reduced proliferation rate implies changes in biological time defined by fission age. In fact the length of autogamy immaturity decreased by measure of clock time, whereas it remained unchanged by measure of fission age.     

Endothelium-lymphocyte interactions in vitro. II. Adherence of allergized lymphocytes.

Peripheral blood lymphocytes from skin graft-sensitized pigs will adhere in vitro to fresh donor-type large vessel endothelium, but do not spread out or migrate. Similar cells will however spread out on and migrate through monolayers of cultured donor-type aortic endothelium to a significantly greater extent than nonallergized lymphocytes. Cells sensitized in mixed lymphocyte culture at first exhibit a nonspecific increase in adherence and migration correlated with increased thymidine uptake, but after more prolonged incubation adherence becomes specific for stimulator-type endothelium. It is suggested that lymphocyte infiltration of an allograft in the presence of circulating sensitized cells involves a combination of nonspecific lymphocyte adhesion to endothelium, antigenic stimulation of “primed” cells to increased motility, endothelial penetration and lymphokine production, and soluble-factor-mediated stimulation of migration by nonsensitized cells.     

Cross-talk between TCR and CCR7 signaling sets a temporal threshold for enhanced T lymphocyte migration

Lymphocyte homing to, and motility within, lymph nodes is regulated by the chemokine receptor CCR7 and its two ligands CCL19 and CCL21. There, lymphocytes are exposed to a number of extracellular stimuli that influence cellular functions and determine the cell fate. In this study, we assessed the effect of TCR engagement on CCR7-mediated cell migration. We found that long-term TCR triggering of freshly isolated human T cells through CD3/CD28 attenuated CCR7-driven chemotaxis, whereas short-term activation significantly enhanced CCR7-mediated, but not CXCR4-mediated, migration efficiency. Short-term activation most prominently enhanced the migratory response of naive T cells of both CD4 and CD8 subsets. We identified distinct roles for Src family kinases in modulating CCR7-mediated T cell migration. We provide evidence that Fyn, together with Ca(2+)-independent protein kinase C isoforms, kept the migratory response of naive T cells toward CCL21 at a low level. In nonactivated T cells, CCR7 triggering induced a Fyn-dependent phosphorylation of the inhibitory Tyr505 of Lck. Inhibiting Fyn in these nonactivated T cells prevented the negative regulation of Lck and facilitated high CCR7-driven T cell chemotaxis. Moreover, we found that the enhanced migration of short-term activated T cells was accompanied by a synergistic, Src-dependent activation of the adaptor molecule linker for activation of T cells. Collectively, we characterize a cross-talk between the TCR and CCR7 and provide mechanistic evidence that the activation status of T cells controls lymphocyte motility and sets a threshold for their migratory response.     

Hypergravity affects cell traction forces of fibroblasts

Cells sense and react on changes of the mechanical properties of their environment and, likewise, respond to external mechanical stress applied to them. However, whether the gravitational field as overall body force modulates cellular behavior is unclear. Different studies demonstrated that micro- and hypergravity influences the shape and elasticity of cells, initiate cytoskeleton reorganization, and influence cell motility. All these cellular properties are interconnected and contribute to forces that cells apply on their surrounding microenvironment. Yet, studies that investigated changes of cell traction forces under hypergravity conditions are scarce. Here, we performed hypergravity experiments on 3T3 fibroblast cells using the large-diameter centrifuge at the European Space Agency - European Space Research and Technology Centre. Cells were exposed to hypergravity of up to 19.5 g for 16 h in both the upright and the inverted orientation with respect to the g-force vector. We observed a decrease in cellular traction forces when the gravitational field was increased up to 5.4 g, followed by an increase of traction forces for higher gravity fields up to 19.5 g independent of the orientation of the gravity vector. We attribute the switch in cellular response to shear thinning at low g-forces, followed by significant rearrangement and enforcement of the cytoskeleton at high g-forces.     

Modulation of lymphocyte motility by macrophages

Motility of lymphocytes plays a significant role in their functions. Because macrophages frequently associate with lymphocytes in lymphoid tissues and inflammatory sites, they are likely to be important in regulating lymphocyte motility. In this study, we identified a chemokinetic activity in macrophage culture supernatants. Interestingly, this activity could be detected by the capillary migration assay but not by the more commonly used Boyden chamber chemotaxis assay. Colchicine, on the other hand, was chemokinetic for lymphocytes in the Boyden chamber chemotaxis assay but not in the capillary migration assay. Both these observations and previous studies on the morphology of motile lymphocytes on two-dimensional (2-D) surfaces (capillary migration assay) and in 3-D matrices (Boyden chamber chemotaxis assay) suggest that lymphocytes possess more than one motility mechanism--one for 2-D surfaces and one for 3-D matrices. We propose that the macrophage-derived chemokinetic activity described herein only affected the motility mechanism on 2-D surfaces. In addition, we also observed that the chemokinetic activity was produced by "resting" macrophages and could not be augmented by further activation. Finally, the effect was greatest on mature T cells. We propose that this factor plays an important role in facilitating cell interactions within lymphoid tissues and inflammatory sites.     

Regulation of lymphocyte motility by macrophages: characterization of a lymphocyte migration inhibitory factor derived from a macrophage-like cell line

An inhibitory factor on lymphocyte migration was detected using a capillary random migration assay in the culture supernatant of peritoneal exudate macrophages cultured at concentrations greater than 8 x 10(6) cells/ml. After examining different macrophage-like cell lines, J774A.1 cells were found to produce this inhibitory factor, which was termed lymphocyte migration inhibitory factor (LMIF). The inhibitory effect of LMIF on the migration of spleen lymphocytes, thymocytes, and bone marrow cells was determined. The migration of thymocytes was more sensitive to LMIF than was the migration of spleen lymphocytes and bone marrow cells. Interestingly, when the effect of LMIF was tested on the migration of spleen T cells and B cells, T cells were more sensitive than B cells. When the thymocytes were separated by peanut agglutinin into mature and immature thymocytes, the migration of mature thymocytes was more sensitive than that of immature thymocytes, the migration of mature thymocytes was more sensitive than that of immature thymocytes to the effect of LMIF, suggesting that the greatest effect of LMIF was on the migration of mature T cells. Partial purification of LMIF by ion-exchange and gel-filtration chromatography revealed that it is approximately 14,000 in molecular weight and could exist in either monomeric or dimeric forms. The possible role of this factor in an immune response is discussed.     

Production of a human T lymphocyte chemotactic factor by T cell subpopulations

Concanavalin A-stimulated human peripheral blood mononuclear cells release a lymphocyte chemotactic factor. This lymphocyte chemotactic factor is produced optimally after 24 to 48 hr of culture and is not found before 3 hr of culture, which suggests that the factor is synthesized de novo and is not preformed and secreted after Con A stimulation. This is further supported by experiments showing that the protein synthesis inhibitors cycloheximide and puromycin totally prevent the production of the chemotactic factor. Experiments using cultured and uncultured T lymphocytes as responding cells show that cultured T cells respond more efficiently than uncultured T cells to this factor. Furthermore, the lymphocyte chemotactic factor preferentially stimulates T lymphocyte locomotion as compared to peripheral blood non-T lymphocyte migration. Fractionation of mononuclear cells into glass nonadherent lymphocytes, monocyte-enriched preparations, T lymphocytes, and non-T lymphocytes shows that lymphocyte chemotactic factor is produced by Con A-stimulated, glass nonadherent lymphocytes and T cells but not by monocytes or non-T lymphocytes. Further fractionation of T lymphocytes into Leu-2 and Leu-3 T cell subpopulations shows that the production of T lymphocyte chemotactic factor can be attributed to the Leu-2 suppressor/cytotoxic T cell subset. The generation of a T lymphocyte chemotactic factor by Leu-2 T cells may represent a means of recruiting other T cells to the site of its release.     

Alterations of the actin cytoskeleton and increased nitric oxide synthesis are common features in human primary endothelial cell response to changes in gravity

Because endothelial cells are fundamental to the maintenance of the functional integrity of the vascular wall, endothelial modifications in altered gravity conditions might offer some insights into the mechanisms leading to circulatory impairment in astronauts. We cultured human endothelial cells in a dedicated centrifuge (MidiCAR) to generate hypergravity and in two different devices, namely the Rotating Wall Vessel and the Random Positioning Machine, to generate hypogravity. Hypogravity stimulated endothelial growth, did not affect migration, and enhanced nitric oxide production. It also remodeled the actin cytoskeleton and reduced the total amounts of actin. Hypergravity did not affect endothelial growth, markedly stimulated migration, and enhanced nitric oxide synthesis. In addition, hypergravity altered the distribution of actin fibers without, however, affecting the total amounts of actin. A short exposure to hypergravity (8 min) abolished the hypogravity induced growth advantage. Our results indicate that cytoskeletal alterations and increased nitric oxide production represent common denominators in endothelial responses to both hypogravity and hypergravity.     

Hypergravity impairs angiogenic response of in vitro cultured human primary endothelial cells

A variety of evidence suggest that cardiovascular system functions are impaired in altered gravity conditions. In this study we investigated the influence of hypergravity environment (3g) on endothelial cell proliferation, endothelial vasoactive compound production and on in vitro angiogenesis. We found that cultured primary human endothelial cells were very sensitive to mild hypergravity conditions. Even if we did not record changes in cell viability and apoptosis, we found significant differences in cell proliferation, prostacyclin (PGI2) synthesis, nitric oxide (NO) synthesis, and in angiogenic responses. Using western blotting technique we detected an increased expression of cycloxygenase-2 (COX-2) in primary endothelial cells exposed for 48 hours to hypergravity, in comparison to those exposed to normal gravity.     

Homeostatic lymphoid chemokines synergize with adhesion ligands to trigger T and B lymphocyte chemokinesis

Homeostatic chemokines such as CCL19, CCL21, and CXCL13 are known to elicit chemotaxis from naive T and B cells and play a critical role in lymphocyte homing to appropriate zones within secondary lymphoid organs (SLO). Here we tested whether CCL21 and CXCL13 modulate murine lymphocyte motility in the absence of concentration gradients, using videomicroscopy to directly observe the migration of single cells. CCL21 treatment of T cells induced rapid polarization and sustained random migration with average speeds of 5.16 +/- 2.08 microm/min; B cell migration (average velocity 4.10 +/- 1.58 microm/min) was similarly induced by CXCL13. Migration required the presence of both chemokine and adhesion ligands and was sustained for >24 h. Furthermore, in in vitro assays modeling the relative infrequency of Ag-specific T cell-dendritic cell (DC) encounters during primary immune responses, we found that CCL21 addition to T-DC cocultures accelerated the kinetics of CD69 up-regulation and enhanced by 2-fold the proliferation of Ag-specific T cells in a manner dependent on G-protein-coupled receptor signaling in T cells. These results suggest that homeostatic chemokines could substantially impact the dynamics and priming of lymphocytes within SLO even in the absence of significant concentration gradients.     

Migration of lymphocytes through endothelial cell monolayers: augmentation by interferon-gamma

During normal lymphocyte recirculation and in chronic inflammation, lymphocytes emigrate from blood into the perivascular tissue. The mechanism of lymphocyte migration through the endothelial cell (EC) layer of blood vessels is poorly understood. To identify factors that control lymphocyte emigration, a method has been developed to measure human peripheral blood lymphocyte migration through monolayers of human umbilical vein EC and into nitrocellulose (NC) filters located below the EC monolayer. Counts were made of lymphocytes that had migrated into the NC filter using a particle counter. T lymphocytes attached to and migrated through EC monolayers in a T-cell-number- and time-dependent fashion. Migration required viable EC since lymphocytes failed to migrate through formaldehyde-fixed EC monolayers or monolayers of dermal fibroblasts. Interferon-gamma (IFN-gamma) markedly augmented the migration in a dose- and time-dependent manner when preincubated with the EC. When T lymphocytes were pretreated with IFN-gamma, no increase in migration was observed. Finally, IFN-gamma augmented the migration of T cells prebound to the EC, indicating that the IFN-gamma-enhanced migration was not due to increased binding of T cells to the EC, but rather to an action on the EC to facilitate subsequent migration.     

Evidence that the lipid phosphatase SHIP-1 regulates T lymphocyte morphology and motility

SHIP-1 negatively regulates the PI3K pathway in hematopoietic cells and has an emerging role in T lymphocyte biology. PI3K and SHIP can regulate cell migration in leukocytes, particularly in neutrophils, although their role in T cell migration has been less clear. Therefore, we sought to explore the role of SHIP-1 in human CD4(+) T lymphocyte cell migration responses to chemoattractants using a lentiviral-mediated expression system and a short hairpin RNA approach. Silencing of SHIP-1 leads to increased basal phosphorylation of protein kinase B/Akt and its substrate GSK3β, as well as an increase in basal levels of polymerized actin, suggesting that SHIP-1 might regulate changes in the cytoskeleton. Accordingly, silencing of SHIP-1 led to loss of microvilli and ezrin/radixin/moesin phosphorylation, which could not be rescued by the PI3K inhibitor Ly294002. There were striking morphological changes, including a loss of microvilli projections, which mirrored changes in wild type cells after stimulation with the chemokine CXCL11. There was no defect in directional T cell migration toward CXCL11 in the SHIP-1-silenced cells but, importantly, there was a defect in the overall basal motility of SHIP-1 knockdown cells. Taken together, these results implicate SHIP-1 as a key regulator of basal PI3K signaling in human CD4(+) T lymphocytes with important phosphatase-independent actions, which together are key for maintaining normal morphology and basal motility.     

Lymphocyte recruitment in delayed-type hypersensitivity. The role of IFN-gamma

Lymphocytes are recruited out of the blood into delayed-type hypersensitivity (DTH) reactions, but the factors controlling their migration are poorly understood. Our previous studies have shown that IFN-alpha/beta, its inducers, and T cell lymphokines can induce lymphocyte migration into the skin after intradermal injection. The present studies were designed to determine the effect of rIFN-gamma, IL-1, and anti-IFN-gamma on lymphocyte recruitment into DTH. Small peritoneal exudate lymphocytes, which preferentially migrate to inflammatory sites, were labelled with 111In and injected i.v. into rats. The intradermal injection of IFN-gamma stimulated the migration of these lymphocytes into the skin. IL-1 induced very little migration by itself, but enhanced the effect of IFN-gamma. Kinetic analysis demonstrated that the migration of lymphocytes to IFN-gamma was rapid, with a peak at 6 h, whereas migration into a DTH reaction was minimal for the first 8 h and reached a peak 24 h after intradermal injection. Polyclonal rabbit anti-IFN-gamma anti-serum, and a Mab to IFN-gamma, DB-2, could almost completely block lymphocyte migration induced by IFN-gamma. Furthermore, DB-2 inhibited lymphocyte recruitment into DTH reactions by 50 to 90%. This Mab did not affect migration in response to IFN-alpha/beta, although it partially inhibited the response to polyI:C. The effect of IFN-gamma on lymphocyte recruitment was not specific for small peritoneal exudate lymphocytes, because both spleen T cells and lymph node cells migrated in response to IFN-gamma and DB-2 inhibited the recruitment of splenic T cells to DTH. Thus, IFN-gamma is a potent stimulator of lymphocyte migration into the skin and a major mediator of lymphocyte recruitment into DTH.     

Human T Lymphocyte Isolation,Culture and Analysis of Migration In Vitro

The migration of T lymphocytes involves the adhesive interaction of cell surface integrins with ligands expressed on other cells or with extracellular matrix proteins. The precise spatiotemporal activation of integrins from a low affinity state to a high affinity state at the cell leading edge is important for T lymphocyte migration ¹. Likewise, retraction of the cell trailing edge, or uropod, is a necessary step in maintaining persistent integrin-dependent T lymphocyte motility ². Many therapeutic approaches to autoimmune or inflammatory diseases target integrins as a means to inhibit the excessive recruitment and migration of leukocytes ³. To study the molecular events that regulate human T lymphocyte migration, we have utilized an in vitro system to analyze cell migration on a two-dimensional substrate that mimics the environment that a T lymphocyte encounters during recruitment from the vasculature. T lymphocytes are first isolated from human donors and are then stimulated and cultured for seven to ten days. During the assay, T lymphocytes are allowed to adhere and migrate on a substrate coated with intercellular adhesion molecule-1 (ICAM-1), a ligand for integrin LFA-1, and stromal cell-derived factor-1 (SDF-1). Our data show that T lymphocytes exhibit a migratory velocity of ~15 μm/min. T lymphocyte migration can be inhibited by integrin blockade ¹ or by inhibitors of the cellular actomyosin machinery that regulates cell migration ².Download video file.^{(98M, mp4)}     

Lymphocyte development of adherence and motility in extracellular matrix during IL-2 stimulation.

To extravasate into normal and neoplastic tissue, lymphocytes must migrate through the subendothelial basement membrane and underlying interstitium, structures rich in extracellular matrix (ECM). We have performed a time-course study of the development of motility in ECM by murine lymphocytes during in vitro exposure to high titers of IL-2 (1000 Cetus units/ml). This protocol generates immunotherapeutic lymphocyte populations expressing lymphokine-activated killer activity. Spontaneous motility was measured in three-dimensional gels of type I (interstitial) collagen or Matrigel, a model basement membrane. A newly developed assay permitted not only the measurement of distance traveled by the leading cell front, but also the separation of lymphocytes on the basis of three types of behavior. The motile fraction consisted of lymphocytes that penetrated beneath the ECM gel surface during an 18-h migration period. There were also two nonmotile fractions: the nonadherent fraction, which failed to bind to the gel surface; and the adherent fraction, which bound but did not penetrate during the assay period. During a 3- to 5-day exposure to high titer IL-2, both adherence and motility increased significantly. In type I collagen, cells of the NK lineage developed greater surface adherence and less motility than cells of the T lineage. The surface-adherent fraction expressed higher lymphokine-activated killer and NK activity than did the nonadherent or motile fractions. Under prolonged IL-2 stimulation (7 to 12 days), there was a decline in the percentage of cells exhibiting motility in both types of ECM, and an increase in the percentage of surface-adherent cells. The findings indicate that the behavior of an IL-2-stimulated lymphocyte population in ECM is profoundly influenced by the duration of IL-2 exposure. Furthermore, lack of lymphocyte motility may reflect two different behaviors, nonadherence and adherence without motility. The nonadherent and surface-adherent populations may differ in phenotypic distribution and function. The motility system described in this report will be useful in separating and studying the mechanisms that produce lymphocyte adherence and motility, and in understanding the in vivo implications of these behaviors.     

Nonrandom migration of CD4+, CD8+, and gamma delta+T19+ lymphocyte subsets following in vivo stimulation with antigen

We report here the results of experiments in which the migration of three T cell subsets (CD4+, CD8+, and gamma delta+T19+ cells) through antigen-stimulated lymph nodes and subcutaneous granulomas has been compared with that through normal skin and resting lymph nodes. The percentage of gamma delta+T19+ lymphocytes was halved and the percentage of CD8+ lymphocytes was doubled in lymph draining stimulated compared with control tissues, and all lymphocyte subsets except gamma delta+T19+ lymphocytes had higher hourly outputs in lymph draining antigen-stimulated compared with control tissues. Antigen also resulted in a higher percentage of CD8+ lymphoblasts and a lower percentage of gamma delta+T19+ lymphoblasts in efferent lymph draining antigen-stimulated lymph nodes. The data indicate that lymphocyte subsets leave the blood with differing efficiencies in different vascular beds and raise the possibility that antigen can influence the rate at which tissues extract individual T cell subsets from the blood.     

Hypergravity signal transduction and gene expression in cultured mammalian cells

A number of studies have been conducted during space flight and with clinostats and centrifuges, suggesting that gravity effects the proliferation and differentiation of mammalian cells in vitro. However, little is known about the mechanisms by which mammalian cells respond to changes in gravitational stress. This paper summarizes studies designed to clarify the effects of hypergravity on the cultured human HeLa cells and to investigate the mechanism of hypergravity signal transduction in these cells.