Changes in gravity inhibit lymphocyte locomotion through type I collagen

Summary Immunity relies on the circulation of lymphocytes through many different tissues including blood vessels, lymphatic channels, and lymphoid organs. The ability of lymphocytes to traverse the interstitium in both nonlymphoid and lymphoid tissues can be determined in vitro by assaying their capacity to locomote through Type I collagen. In an attempt to characterize potential causes of microgravity-induced immunosuppression, we investigated the effects of simulated microgravity on human lymphocyte function in vitro using a specialized rotating-wall vessel culture system developed at the Johnson Space Center. This very low shear culture system randomizes gravitational vectors and provides an in vitro approximation of microgravity. In the randomized gravity of the rotating-wall vessel culture system, peripheral blood lymphocytes did not locomote through Type I collagen, whereas static cultures supported normal movement. Although cells remained viable during the entire culture period, peripheral blood lymphocytes transferred to unit gravity (static culture) after 6 h in the rotating-wall vessel culture system were slow to recover and locomote into collagen matrix. After 72 h in the rotating-wall vessel culture system and an additional 72 h in static culture, peripheral blood lymphocytes did not recover their ability to locomote. Loss of locomotory activity in rotating-wall vessel cultures appears to be related to changes in the activation state of the lymphocytes and the expression of adhesion molecules. Culture in the rotating-wall vessel system blunted the ability of peripheral blood lymphocytes to respond to polyclonal activation with phytohemagglutinin. Locomotory response remained intact when peripheral blood lymphocytes were activated by anti-CD3 antibody and interleukin-2 prior to introduction into the rotating-wall vessel culture system. Thus, in addition to the systemic stress factors that may affect immunity, isolated lymphocytes respond to gravitational changes by ceasing locomotion through model interstitium. These in vitro investigations suggest that microgravity induces non-stress-related changes in cell function that may be critical to immunity. Preliminary analysis of locomotion in true microgravity revealed a substantial inhibition of cellular movement in Type I collagen. Thus, the rotating-wall vessel culture system provides a model for analyzing the microgravity-induced inhibition of lymphocyte locomotion and the investigation of the mechanisms related to lymphocyte movement.     

Modeled microgravity inhibits apoptosis in peripheral blood lymphocytes

Microgravity interferes with numerous lymphocyte functions (expression of cell surface molecules, locomotion, polyclonal and antigen-specific activation, and the protein kinase C activity in signal transduction). The latter suggests that gravity may also affect programmed cell death (PCD) in lymphocyte populations. To test this hypothesis, we investigated spontaneous, activation- and radiation-induced PCD in peripheral blood mononuclear cells exposed to modeled microgravity (MMG) using a rotating cell culture system. The results showed significant inhibition of radiation- and activation-induced apoptosis in MMG and provide insights into the potential mechanisms of this phenomenon.     

Molecular mechanisms of lymphocyte extravasation. III. The loss of lymphocyte extravasation potential induced by pertussis toxin is not mediated via the activation of protein kinase C

The present study evaluated whether protein kinase C (PKC) activation was involved in the lymphocytosis promoting properties of pertussis toxin (Ptx). The exposure of mouse lymphocytes to phorbol esters (as a means to selectively activate PKC) caused a depression in their subsequent capacity to localize into lymph nodes and Peyer's patches in vivo. This pattern of inhibition was quite similar to that observed with lymphocytes treated with Ptx. The mechanisms responsible for the observed decreases in localization to lymphoid organs caused by these two agents, however, appeared to be distinct. Exposure of lymphocytes to PMA was followed by a time and dosage-dependent decrease in the surface density of MEL-14 defined homing receptors. Ptx-treated lymphocytes retained normal density of this homing receptor. Consequently, PMA-treated lymphocytes lost their capacity to bind to high-endothelial venules in in vitro lymph node binding assays while Ptx-treated cells retained normal high-endothelial venule binding potential. We conclude from this study that: 1) the activation of PKC in lymphocytes by PMA can alter their recirculation properties via mechanisms that diminish their expression of surface receptors which support extravasation into lymph node and mucosal lymphoid tissues, and 2) even though Ptx has been reported to elevate the rate of inositol phosphate turnover in lymphocytes, the loss of extravasation potential of Ptx-treated lymphocytes is not mediated via the modification of surface homing receptors as observed in cells exposed to the known PKC activator, PMA.     

A synthetic peptide homologous to retroviral transmembrane envelope proteins depresses protein kinase C mediated lymphocyte proliferation and directly inactivated protein kinase C: a potential mechanism for immunosuppression

CKS-17, an immunosuppressive peptide homologous to certain retroviral transmembrane envelope protein, has been shown to inhibit lymphocyte proliferation in response to mitogens or alloantigens when covalently attached to bovine serum albumin (CKS-17-BSA). To define its site of action, we determined if CKS-17 conjugated to human serum albumin (CKS-17-HSA) could block the direct activation of lymphocytes by phorbol-12-myristate-13-acetate (PMA) or by a synthetic diacylglycerol, dioctanoylglycerol (DiC8). CKS-17-HSA inhibited lymphocyte proliferation in response to PMA and ionomycin in a dose-dependent manner with up to 88% inhibition occurring with 15 microM CKS-17-HSA. The conjugated peptide also inhibited the proliferation of lymphocytes in response to DiC8 and ionomycin by up to 57% at 15 microM CKS-17-HSA. Based on these findings we investigated the effect of CKS-17-HSA on the activity of protein kinase C (PKC), an enzyme directly activated by PMA and DiC8. PKC was isolated chromatographically from the cytosol of human neutrophils or the human lymphoblastoid cell line Jurkat. CKS-17-HSA caused a dose-dependent enzyme inhibition with a concentration giving half-maximal inhibition (IC50) of ca.3 microM and greater than 95% inhibition at 15 microM CKS-17-HSA. Inhibition of PKC by the conjugated peptide was not reversed by increasing concentrations of Ca2+, Mg2+, phosphatidylserine, diolein, or adenosine triphosphate (ATP), indicating that the conjugated peptide did not function as a chelator or competitive inhibitor. In contrast to its effects on PKC, CKS-17-HSA did not inhibit the activity of adenosine 3':5'-cyclic monophosphate (cyclic AMP)-dependent protein kinase (PK-A) nor the calcium and phospholipid-independent form of PKC (PK-M). Moreover the peptide inhibited in vivo PKC activity in cytosol of intact cells and in membrane of PMA-stimulated cells. These results suggest that the inhibition of lymphocyte proliferation by CKS-17-HSA may be due to the direct inactivation of PKC.     

Protein kinase C activation induces phosphatidylserine exposure on red blood cells

We have shown previously that red blood cells (RBCs) can be induced to influx Ca(2+) when treated with lipid mediators, such as lysophosphatidic acid and prostaglandin E(2), that are released during clot formation. Since calcium loading of RBCs can lead to both protein kinase C (PKC) activation and phosphatidylserine (PS) exposure, we decided to investigate the possible linkage between PKC activation and membrane PS scrambling using phorbol 12-myristate-13-acetate (PMA), a commonly used activator of PKC. Treatment of RBCs with PMA in a calcium-containing buffer caused immediate PS exposure in an RBC subpopulation. The size of the subpopulation did not change upon further incubation, indicating that not all RBCs are equally susceptible to this treatment. Using a fluorescent indicator, we found a subpopulation of RBCs with elevated intracellular calcium levels. In the absence of extracellular calcium, no PS exposure was found. However, we did find cells with high levels of calcium that did not expose PS, and a variable percentage of PS-exposing cells that did not show elevated calcium concentrations. Inhibition of PKC with either calphostin C, a blocker of the PMA binding site, or chelerythrine chloride, an inhibitor of the active site, diminished the level of formation of PS-exposing cells. However, the inhibitors had different effects on calcium internalization, indicating that a high calcium concentration alone was not responsible for inducing PS exposure in the absence of PKC activity. Moreover, PKC inhibition could prevent PS exposure induced by calcium and ionophore treatment of RBCs. We conclude that PKC is implicated in the mechanism of membrane phospholipid scrambling.     

T lymphocytes and neutrophil granulocytes differ in regulatory signaling and migratory dynamics with regard to spontaneous locomotion and chemotaxis

Chemotactic migration of T lymphocytes and neutrophil granulocytes within a three-dimensional collagen matrix is distinct from spontaneous, matrix-induced migration concerning dynamic parameters and regulatory intracellular signaling. Both spontaneous T lymphocyte locomotion and stromal-cell-derived factor-1 (SDF-1)-induced chemotaxis-involved protein tyrosine kinase (PTK) activity, whereas only SDF-1-induced migration was protein kinase C (PKC) dependent. Spontaneous locomotion of neutrophil granulocytes was independent of PKC and PTK activity, but formyl-methionyl-leucyl-phenylalanine-induced migration involved PKC activity. In addition, the microtubule cytoskeleton was not changed after induction of chemotaxis in both cell types. T lymphocytes had a well-developed microtubule cytoskeleton with the microtubule organizing center located in the uropod, whereas neutrophil granulocytes revealed a clustered tubulin distribution at the leading edge of the migrating cell. Therefore, differences of the microtubule cytoskeleton might contribute to differences in locomotion between T lymphocytes and neutrophil granulocytes but not to differences between spontaneous locomotion and chemotaxis.     

Analysis of gene expression of lymphocytes in microgravity.

It has been reported that lymphocyte function decreases under microgravity. Though molecular mechanism of the immunosuppression in microgravity still remains enigmatic, it is suggested that gene expression of lymphocytes may be altered in microgravity. In this study we developed automatic flash-freezing equipment which can be utilized for exposing lymphocytes to microgravity by drop shaft experiments in Japan Microgravity Center (JAMIC). Gene expression profiles were analyzed by using DNA array in ground control lymphocytes and microgravity-exposed lymphocytes.     

Rapid modulation of homing receptors (gp90MEL-14) induced by activators of protein kinase C. Receptor shedding due to accelerated proteolytic cleavage at the cell surface

Lymphocyte entry into lymph nodes and Peyer's patches is initiated by the adhesion of the lymphocytes to specialized postcapillary high endothelial venules (HEV). The binding of lymphocytes to lymph node HEV is mediated by the cell surface receptor gp90MEL-14 (gp90). Previous work has shown that gp90 is down-regulated over a period of days after mitogenic or mixed lymphocyte reaction stimulation of T lymphocytes. In our study, it is shown that stimulation of lymphocytes with activators of protein kinase C (PKC), such as PMA or 1-oleoyl 2-acetyl-glycerol, results in the nearly complete loss of surface expression of gp90 within 1 h. Pretreatment of the cells with H-7 or staurosporine, PKC inhibitors, but not HA1004, a general protein kinase inhibitor, prevents the loss of gp90MEL-14. Within 15 min of stimulation of PKC, a novel form of gp90 can be immunoprecipitated from the supernatant of stimulated cells. Upon deglycosylation, this soluble gp90 polypeptide is shown to be 12 kDa smaller than the cell surface protein. Peptide mapping showed identical patterns for surface and soluble receptor, confirming that the soluble Ag is related to the cell membrane protein. Together, these experiments suggest that activation of PKC results in the proteolytic cleavage of gp90MEL-14, resulting in receptor shedding and the inability of the lymphocytes to adhere to HEV endothelium. Furthermore, because supernatant from unstimulated, normal lymphocytes also contains a small amount of the low Mr form of gp90, cell surface proteolysis may be part of the normal turnover of this receptor glycoprotein. These experiments suggest that PKC may play a role in the regulation of lymphocyte traffic to lymphoid tissues.     

Activation of human T lymphocytes by bryostatin

The immunologic effects of bryostatin (Bryo), a PKC activator with antineoplastic activity, were assessed and compared to PMA. Bryo induced IL-2R expression on CD4+ and CD8+ human T lymphocytes with a dose response comparable to PMA. However, Bryo induced only a marginal proliferative response as compared with the vigorous response induced by PMA. Bryo mediated functional receptor expression because the proliferative response was enhanced by addition of rIL-2. Furthermore, the proliferative response was inhibited by the relatively specific Ca+, phospholipid-dependent protein kinase (PKC) inhibitor, H-7, indicating a role of PKC in Bryo-induced activation. Addition of the calcium ionophore, ionomycin, to Bryo-stimulated lymphocytes resulted in the production and secretion of IL-2 with a concomitant proliferative response. This effect of the calcium ionophore could be inhibited by cyclosporine with identical results obtained in PMA-stimulated cultures. A most intriguing finding was that Bryo could effectively antagonize PMA-induced T cell proliferation. Although this mechanism of inhibition is unclear, a discussion with respect to differential effects on potential intracellular PKC isoforms is provided. These studies indicated that Bryo has potent immunopotentiating properties that share some similar effects of the phorbol ester, PMA, but offers the additional property of modulating other phorbol ester effects on proliferation.     

Stimulation of AIDS lymphocytes with calcium ionophore (A23187) and phorbol ester (PMA): studies of cytoplasmic free Ca, IL-2 receptor expression, IL-2 production, and proliferation

We have studied whether the decreased lymphocyte proliferative responses of AIDS lymphocytes to stimulation by mitogens and antigens may be overcome when challenged with a combination of calcium ionophore A23187 and phorbol ester PMA. Comparison of the proliferative response of lymphocytes from nine patients with AIDS with the response of lymphocytes from nine control subjects showed that the response of AIDS lymphocytes was severely decreased when stimulated with PHA and no further response could be achieved by stimulation with A23187/PMA. On the other hand, no significant difference between the PHA-induced rise of cytoplasmic free calcium concentration ([Ca2+]1) in normal and AIDS lymphocytes was observed. The percentage of cells expressing IL-2 receptors (CD25) was also normal both after addition of PHA and after addition of A23187/PMA and the expression was normal on both CD4 and CD8 cells. The production of IL-2 in normal lymphocytes stimulated with A23187/PMA was 33 times higher than that after stimulation with PHA. In AIDS lymphocytes the production of IL-2 induced by all activators was severely decreased compared to control subjects, although the production of IL-2 after stimulation with A23187/PMA was higher than that in control lymphocytes after stimulation with PHA. The present study shows that a direct activation of protein kinase C combined with mobilization of cytoplasmic calcium does not overcome the lymphocyte proliferative deficiency of AIDS lymphocytes.     

Cell interactions in microgravity: cytotoxic effects of natural killer cells in vitro

To study cell-to-cell interactions in microgravity we examined the functional activity of natural killer cells on board of the ISS. NK cells are the effector cells with direct cytotoxic activity to oncogenic, virus-infected cells and cells with modified differentiation. Ground-based experiments have shown that the examination of target cell lysis after incubation with NK cells is a simple and informative model for studying the influence of microgravity. NK cytotoxicity was measured as the value of non-degradeted labeled myeloblasts (K-562) after 24 hrs exposure with human lymphocytes in suspension. A special device was developed for space flight experiments. Human cultured lymphocytes and labeled K-562 cells were loaded into special syringes and delivered to the Russian segment of the ISS. Cosmonauts prepared co-cultured suspensions during the first day of microgravity, exposed them at 37 degrees C for 24 hrs and then separated H3-labeled cells on special filters. The results of ISS-8 mission showed that human NK cells in vitro remain lysis activity toward target cells in microgravity. The basal level of NK cytotoxicity was low and we did not found significant differences between "control" and "flight" values. Interferon production during the interaction between immune and target cells (ratio 10:1) in microgravity did not differ compared with ground-based control experiments. Ground exposure of the same lymphocyte samples with K-562 cells to 24 hrs clinorotation also did not lead to significant differences. These experiments paved the way for understanding the cell interaction mechanisms in space flight and the obtained results suggest that microgravity does not disrupt the interaction of NK cells with tumor cells.     

Activation of human T lymphocytes under conditions similar to those that occur during exposure to microgravity: a proteomics study

A number of experiments, conducted under microgravity conditions, i.e. in space shuttle biolaboratories or in ground based systems simulating the conditions occurring in microgravity, show that in hypogravity, in vitro human lymphocyte activation is severely impaired. However, very early stimulation steps of T lymphocytes are not compromised, since CD69 receptor, the earliest membrane activation marker, is expressed by T cells at a level comparable to that observed on 1 g activated lymphocytes. Since CD69 engagement, together with submitogenic doses of phorbol esters, transduces an activation signal to T lymphocytes, we undertook a comparative study on the stimulation mediated through this receptor on human CD3+ cells cultured under conditions similar to those which occur during exposure to microgravity, i.e. in clinorotation, or at 1 g. During the early hours of activation, increased levels of intracellular calcium and increased mitochondrial membrane potential were detectable in clinorotating as well as in 1 g cells. However, after 48 hours clinorotation, interleukin 2 production by T lymphocytes was significantly reduced and cell proliferation was greatly decreased. By means of a differential proteomics approach on T cells activated in clinorotation or at 1 g for 48 hours, we were able to detect statistically significant quantitative protein alterations. Seven proteins with modified expression values were identified; they are involved in nucleic acids processing, proteasome regulation and cytoskeleton structure.     

Cholera toxin discriminates between murine T lymphocyte proliferation stimulated by activators of protein kinase C and proliferation stimulated by IL-2. Possible role for intracellular cAMP

The regulation of the activation of T lymphocyte proliferation is not well understood. It is known that the tumor promoter, PMA, which activates protein kinase C (PKC), can induce the proliferation of several murine CTL clones; in combination with calcium ionophores, which raise the level of intracellular Ca2+, PMA can also stimulate the proliferation of several HTL clones. Activation of the TCR is believed to result in the liberation of diacylglycerol, which is an activator of PKC, and inositol 1,4,5-trisphosphate, which stimulates an increase in intracellular levels of calcium. We now report that pretreatment with cholera toxin (CT) inhibits the proliferation of murine T cell clones stimulated through the TCR/CD3 complex. In addition, CT-pretreatment blocks the proliferation of CTL clones activated with PMA or of HTL clones activated with PMA + calcium ionophore. In contrast, CT-pre-treatment inhibits much less effectively (100- to 1000-fold) the proliferation of these T cell clones stimulated with IL-2. Furthermore, activators of PKC, but not IL-2, potentiate the CT-induced cAMP elevation in T cell clones. The ability of CT to inhibit much more effectively the proliferation triggered by putative activators of PKC than that induced by IL-2 may be mediated by cAMP-dependent mechanisms.     

Alterations of B lymphocyte Fc gamma R II expression and ligand binding capacity induced by various activators.

Murine B lymphocytes cultured with F(ab')2 anti-mouse mu or delta lost (85%) the capacity to bind antigen-IgG antibody complexes as assessed by flow microfluorometry. Anti-mu-induced loss of binding of complexes was concentration, time, and temperature dependent, reversible, and not due to decreased expression of the receptor because binding of monoclonal anti-Fc gamma R II to B lymphocytes cultured with anti-mu was unaffected. Activation of PKC and elevation of [Ca2+]i obtained by culturing B lymphocytes with the combination of PMA and Ca2+ ionophore induced a similar loss of binding of Cx. Since stimulation of B lymphocytes with anti-mu also activates PKC and elevates [Ca2+]i, these changes may be involved in the anti-mu-induced alterations in the binding of complexes to Fc gamma R II. In contrast to the effects of other activators, LPS caused increased expression (threefold) of B lymphocyte Fc gamma R II as measured by the binding of both complexes and monoclonal anti-Fc gamma R II. Thus, different B lymphocyte activators have distinct effects on Fc gamma R II expression or ligand binding capacity and can thereby affect Fc gamma R II-generated regulatory signals.     

Variable lymphocyte responses in rats after space flight.

Most studies of human blood lymphocyte function following space flight have indicated that microgravity suppresses T cell proliferation. However, several other postflight experiments with animals have shown no decrease in proliferation of lymphocytes from peripheral lymphatic tissues, suggesting that different tissues may be variably affected by microgravity. Therefore, we examined the proliferation of lymphocytes from both spleen and lymph nodes of rats following a 4-day flight aboard the Space Shuttle. The experiments were designed to investigate tissue variability as well as potential mechanisms involved in suppressing proliferation. We found that proliferation of lymph node lymphocytes (LNL) from flight (FLT) animals stimulated with the antigen receptor-dependent T cell mitogen concanavalin A was depressed and could not be restored by supplementing cultures with interleukin 1 or interleukin 2 (IL-2). Response to another receptor-dependent mitogen, phytohemagglutinin, was not decreased. However, proliferation of FLT LNL following stimulation with the receptor-independent, mitogenic combination of phorbol ester and ionomycin was depressed. LNL IL-2 activity, cell surface marker expression, and B cell responses to mitogen were normal. Thus, deficits in antigen receptor/ligand interactions, cell surface marker expression, or IL-2 did not account for the suppressed lymphocyte proliferation observed postflight. In contrast to LNL, FLT splenocyte proliferation was not depressed. Assayable IL-2, IL-2 receptor expression, and cell surface marker expression likewise were unaffected by space flight. The differences between lymph node and splenic responses demonstrate the tissue-specific nature of microgravity effects on individual lymphatic tissues.     

Activation of protein kinases A and C increase lymphocyte penetration through endothelial monolayers

A brief incubation of lymphocytes with either PMA, stimulating protein kinase C, or with dibutyryl-cAMP, leading to protein kinase A activation, led to increased lymphocyte penetration through intact endothelial monolayers in vitro. The PMA-induced penetration could be dose-dependently down-regulated with a protein kinase C inhibitor, H7. Similarly HA 1004, being mainly a protein kinase A inhibitor, decreased the dibutyryl-cAMP induced penetration. Treatment of lymphocytes with PMA and cAMP did not alter the expression of CD44 homing receptors on lymphocytes. Stimulation of lymphocytes with dibutyryl-cGMP or calcium ionophore had no effect on lymphocyte penetration. These results suggest that activation of both protein kinases A and C is important in the lymphocyte binding to endothelium.     

B-cell subsets responsive to fluorescein-conjugated antigens. I. Sensitivity to anti-IgD, tolerance, and cross-priming

Human peripheral blood monocyte-depleted lymphocytes, T lymphocytes, and non-T lyphocytes were studied for their locomotor activity in response to several common chemotactic stimuli. The factors used to stimulate lymphocyte locomotion were casein, C5a, and f-Met-Leu-Phe. Chemotaxis (directional locomotion) as well as chemokinesis (nondirectional locomotion) in response to each factor were delineated. Monocyte-depleted lymphocyte locomotion was stimulated significantly by all of the above factors. Separation of lymphocytes into T cells and non-T cells indicated that T-lymphocyte locomotion was stimulated by casein and C5a but not by f-Met-Leu-Phe. Non-T lymphocytes were found to respond to C5a and f-Met-Leu-Phe but responded minimally to casein. Additional experiments indicated that casein and f-Met-Leu-Phe were chemokinetic for both monocyte-depleted lymphocytes and non-T lymphocytes, while C5a was chemotactic for both monocyte-depleted lymphocyte preparations and purified T cells.     

Mechanism and regulation of neutrophil priming by platelet-activating factor

Although a weak direct stimulus of superoxide anion (O₂^?) production, platelet-activating factor (PAF) markedly enhances responses to chemotactic peptides (such as n-formyl-met-leu-phe, FMLP) and phorbol esters (such as phorbol myristate acetate, PMA) in human neutrophils. The mechanism of priming was explored first through inhibition of steps in the signal transduction pathway at and following PAF receptor occupation. Priming was not altered by pertussis toxin or intracellular calcium chelation, but the PAF receptor antagonist WEB 2086 and the protein kinase C (PKC) inhibitors sphinganine and staurosporine significantly inhibited the primed response. In order to study the regulation of PAF priming, the effect of PAF alone was desensitized by exposure to escalating doses of PAF prior to exposure to the secondary stimuli. The priming effect of PAF was not desensitized under these conditions. The role of PKC in desensitization was also studied. Prior exposure to PAF also desensitized the increase in membrane PKC activity evoked by a single concentration of PAF. However, when the PAF response was desensitized, PKC priming of the response to FMLP or PMA still occurred, suggesting that PKC activity may play a role in the maintenance of the primed state despite PAF desensitization. These data suggest that: (1) PAF priming is receptor- and PKC-mediated but is independent of pertussis toxin-inhibitable G-proteins or intracellular calcium, (2) during migration in vivo, neutrophils may be desensitized to the direct effects of PAF but maintain the capacity for enhanced responses to other stimuli, (3) desensitization of PAF-induced particulate PKC activity also occurs, but PAF primes PKC activity despite PAF desensitization, and (4) distinct mechanisms govern the direct and priming effects of PAF on oxidative metabolism. © 1993 Wiley-Liss, Inc.