Determination of lymphocyte division by flow cytometry

Techniques currently available for determining cell division are able to show one or, at best, a limited number of cell divisions. Other methods exist which can quantify overall division, but tell nothing about the division history of individual cells. Here we present a new technique in which an intracellular fluorescent label is divided equally between daughter cells upon cell division. The technique is applicable to in vitro cell division, as well as in vivo division of adoptively transferred cells, and can resolve multiple successive generations using flow cytometry. The label is fluorescein derived, allowing monoclonal antibodies conjugated to phycoerythrin or other compatible fluorochromes to be used to immunophenotype the dividing cells.

Evidence for cell surface association of CD2 and LFA-1 (CD11a/CD18) on T lymphocytes

Previous studies have reported an association of the cell surface adhesion molecule CD2 with the T cell receptor and with CD45 on mouse and human T lymphocytes. In this study the association of CD2 with cell surface molecules was investigated using cell surface biotinylation of T lymphocytes, coupled with immunoprecipitation using two CD2-specific monoclonal antibodies (mAb) (RM2-5 and 12-15) and analysis by SDS-PAGE. Although both CD2 mAb immunoprecipitated CD2 from lysates of murine lymphocytes, it was found that mAb 12-15, but not RM2-5, co-precipitated two other molecules of 95 and 180 kDa. Subsequent studies revealed that the 95- and 180-kDa molecules were associated with a subspecies of CD2 (approximately 5%) on thymocytes, the antigen-specific T cell line D10, and splenic T cells but not B cells. Two lines of evidence were obtained consistent with the 95- and 180-kDa molecules being the beta and alpha chains of LFA-1. Firstly, an analysis of 12-15 mAb immunoprecipitates on 4-12% gels under reducing and nonreducing conditions shows that the 95- and 180-kDa molecules have a molecular weight and migration pattern identical to LFA-1. Secondly, depletion of LFA-1 from lysates with LFA-1 mAb abolished the ability of CD2 mAb 12-15 to co-precipitate the 95- and 180-kDa molecules, thereby identifying these as the beta and alpha chains of mouse LFA-1, respectively. These results provide evidence for the first time for an association of LFA-1 and CD2 on mouse T lymphocytes, and suggest that the association occurs with an immunologically distinct subspecies of CD2 molecules.

CD48 is a low affinity ligand for human CD2

COS cells transiently transfected with human CD48 were found to bind human PBL, whereas mock or CD7-transfected COS cells failed to bind human lymphocytes. Binding of PBL to CD48 transfectants was almost totally inhibited by either CD48 mAb pretreatment of COS cells or CD2 mAb pretreatment of PBL, implying an interaction between CD2 and CD48. This conclusion was confirmed by the demonstration that a highly fluorescent, multimeric form of rCD2 bound to CD48 transfected COS cells in a CD48-dependent manner. Additional mAb blocking studies revealed that CD48 interacts with the T11(1) region of CD2, the same region of CD2 that binds LFA-3 (CD58). Thus, CD48 and CD58 represent alternative and possibly competing ligands for CD2, although based on blocking studies with soluble CD2, CD48 interacts with CD2 with approximately a 100-fold lower affinity that CD58.

CD48 is a low affinity ligand for human CD2

COS cells transiently transfected with human CD48 were found to bind human PBL, whereas mock or CD7-transfected COS cells failed to bind human lymphocytes. Binding of PBL to CD48 transfectants was almost totally inhibited by either CD48 mAb pretreatment of COS cells or CD2 mAb pretreatment of PBL, implying an interaction between CD2 and CD48. This conclusion was confirmed by the demonstration that a highly fluorescent, multimeric form of rCD2 bound to CD48 transfected COS cells in a CD48-dependent manner. Additional mAb blocking studies revealed that CD48 interacts with the T11(1) region of CD2, the same region of CD2 that binds LFA-3 (CD58). Thus, CD48 and CD58 represent alternative and possibly competing ligands for CD2, although based on blocking studies with soluble CD2, CD48 interacts with CD2 with approximately a 100-fold lower affinity that CD58.

Astrocytic hypertrophy: an important pathological feature of chronic experimental autoimmune encephalitis in aged rats

Experimental autoimmune encephalomyelitis (EAE) was induced in young (2-3 month old), middle-aged (12-13 month old) and geriatric (24-26 month old) Lewis (JC) rats by active immunisation with myelin basic protein (MBP) in complete Freund's adjuvant (CFA). It was found that aged Lewis (JC) rats developed a more chronic form of EAE than younger rats of the same strain, a phenomenon observed in both male and female rats despite males developing more severe disease than females at all ages. Middle-aged recipients also developed more severe disease than young recipients when EAE was induced by the adoptive transfer of lymphocytes from actively immunised young donors, suggesting that disease chronicity in middle-aged animals is a property of the central nervous system (CNS) milieu. Histological studies demonstrated that disease chronicity did not correlate with the number of inflammatory lesions in the CNS, young animals containing substantial numbers of CNS lesions following recovery and lesions being largely absent from middle-aged animals which still exhibited signs of disease. No significant differences were found in the degree of fibrin deposition or demyelination between young and middle-aged or symptomatic and asymptomatic animals. However, astrocytic hypertrophy was found to correlate with manifestation of disease in both young and middle-aged animals and in particular with disease chronicity in middle-aged animals. In parallel studies, no significant differences were found in the levels of the inflammatory mediators tumor necrosis factor (TNF)-alpha, prostaglandin E (PGE)2, reactive nitrogen intermediates (RNI) and corticosterone in young and middle-aged animals. However, markedly elevated corticosterone levels were found in both young and middle-aged animals with the development of clinical signs which returned to baseline levels with the resolution of clinical signs. Elevated levels of RNI were evident in animals immediately prior to and during the early stages of symptomatic EAE. Although these results suggest that nitric oxide may play a role in the pathogenesis of disease, whereas corticosterone may play a role in the immunoregulation of the disease, these factors cannot explain differences in disease chronicity evident in middle-aged animals.(ABSTRACT TRUNCATED AT 400 WORDS)

Investigation of the ability of several naturally occurring and synthetic polyanions to bind to and potentiate the biological activity of acidic fibroblast growth factor

The ability of several animal, plant, and bacterial derived polyanions (PAs) as well as synthetic PAs to compete with heparin for the binding of acidic fibroblast growth factor (aFGF) was correlated with their ability to potentiate the mitogenic and neurotrophic actions of this factor. Dextran sulphate, kappa-carrageenan, pentosan sulphate, polyanethole sulfonate, heparin, and fucoidin competed for the heparin binding site on aFGF at relatively low concentrations (< 50 micrograms/ml). lambda-carrageenan, iota-carrageenan, and polyvinyl sulphate exhibited lower affinity for aFGF, whereas hyaluronic acid, dermatan sulphate, chondroitin-6-sulphate, chondroitin-4-sulphate, and uncharged dextran displayed very low or no demonstrable affinity. Potentiation of the mitogenic action of aFGF for Balb/c 3T3 fibroblasts tended to be in general agreement with the aFGF binding affinity of the PAs. However, polyanethole sulfonate, the carrageenans, polyvinyl sulphate, fucoidin, and pentosan sulphate exerted a mitogenic action on the 3T3 cells that was independent of, and in addition to, the ability of these GAGs to potentiate the action of aFGF. The ability to potentiate the neurotrophic action of aFGF for E8 chick ciliary neurons was a general property of those PA with low or no activity in the mitogen assay. Thus hyaluronic acid, dermatan sulphate, chondroitin-4-sulphate, chondroitin-6-sulphate, and even unchanged dextran all potentiated aFGF induced neuronal survival. The differential effects of these PA in potentiating the biological activities of aFGF are discussed in relation to their ability to compete for the heparin-binding site of aFGF.

Detection of a glycosylation-dependent ligand for the T lymphocyte cell adhesion molecule CD2 using a novel multimeric recombinant CD2-binding assay

The CD2 molecule plays an important role in T cell adhesion by interacting with the ligands CD58 (LFA-3) and CD59. In order to detect additional ligands for CD2, potentially of low binding affinity, we have prepared a highly fluorescent, multimeric form of rCD2 whose binding to cells can be quantified by flow cytometry. Initial studies demonstrated that binding of multimeric rCD2 to cells was CD2-specific, concentration and time dependent, and saturable. The negative charge on cells was also found to play a critical role in the efficiency of multimeric rCD2 binding. Analysis of binding of multimeric rCD2 to 17 CD58+ cell types revealed that only 8 of the cells exhibited binding. Failure of multimeric rCD2 to interact with the other cells could not be explained by differences in CD58 expression, suggesting that, in terms of CD2 binding, there are qualitative differences in CD58 on different cell types. Binding of multimeric rCD2 to six of the seven reactive cells was virtually totally inhibited by CD58 mAb pretreatment, whereas binding to the erythroleukemic line K562 was only partially blocked, suggesting the existence of another CD2 ligand. Subsequent studies demonstrated that the putative new ligand is not CD59, and that it interacts with a different region of the CD2 molecule than CD58, probably a site located between the T11(1) and T11(2) epitopes. The binding affinity of CD2 for the new ligand is 10-fold lower than for CD58 and, based on studies with truncated rCD2, the binding site for the new ligand is located within the amino-terminal 105 amino acids of the CD2 polypeptide. Unlike CD58, the new ligand is tunicamycin sensitive suggesting that it contains a N-linked carbohydrate structure that is essential for functional activity.

Detection of a glycosylation-dependent ligand for the T lymphocyte cell adhesion molecule CD2 using a novel multimeric recombinant CD2-binding assay

The CD2 molecule plays an important role in T cell adhesion by interacting with the ligands CD58 (LFA-3) and CD59. In order to detect additional ligands for CD2, potentially of low binding affinity, we have prepared a highly fluorescent, multimeric form of rCD2 whose binding to cells can be quantified by flow cytometry. Initial studies demonstrated that binding of multimeric rCD2 to cells was CD2-specific, concentration and time dependent, and saturable. The negative charge on cells was also found to play a critical role in the efficiency of multimeric rCD2 binding. Analysis of binding of multimeric rCD2 to 17 CD58+ cell types revealed that only 8 of the cells exhibited binding. Failure of multimeric rCD2 to interact with the other cells could not be explained by differences in CD58 expression, suggesting that, in terms of CD2 binding, there are qualitative differences in CD58 on different cell types. Binding of multimeric rCD2 to six of the seven reactive cells was virtually totally inhibited by CD58 mAb pretreatment, whereas binding to the erythroleukemic line K562 was only partially blocked, suggesting the existence of another CD2 ligand. Subsequent studies demonstrated that the putative new ligand is not CD59, and that it interacts with a different region of the CD2 molecule than CD58, probably a site located between the T11(1) and T11(2) epitopes. The binding affinity of CD2 for the new ligand is 10-fold lower than for CD58 and, based on studies with truncated rCD2, the binding site for the new ligand is located within the amino-terminal 105 amino acids of the CD2 polypeptide. Unlike CD58, the new ligand is tunicamycin sensitive suggesting that it contains a N-linked carbohydrate structure that is essential for functional activity.

Polysaccharides influence the aggregation of Dictyostelium discoideum cells and bind to developmentally regulated cell surface proteins

Six of ten anionic polysaccharides studied were found to significantly reduce the adhesion of growth-phase Dictyostelium discoideum cells. However, only hyaluronic acid, chondroitin-4-sulfate and chondroitin-6-sulfate interfered with the adhesion of aggregation-competent cells. Neither EDTA-stable nor EDTA-sensitive adhesion of postaggregation cells were affected by the polyanions. The two chondroitin sulfates influenced the aggregation of cells in submerged cultures, long and broad aggregation streams being formed and the broad sheets of cells eventually building multilayered aggregates. Radioiodination of cell surface proteins followed by cellulose fiber affinity chromatography identified the same nine proteins bound by hyaluronic acid and the chondroitin sulfates, six of which were regulated during development. Protease-resistant anionic material isolated from cells bound the same surface proteins as the three glycosaminoglycans. Discoidin I bound to the uncoupled cellulose fibers, suggesting a structural role for the lectin in the extracellular slime sheath. Anionic polysaccharides and cell surface lectins that bind them may be involved in the cell recognition, cell aggregation, and the cell sorting that occurs during pattern formation.

Inhibition of adjuvant arthritis in the rat by phosphosugars and the alpha-glucosidase inhibitor castanospermine

The development of joint inflammation of adoptively transferred arthritis in rats was inhibited by treatment with the simple sugar mannose-6-phosphate or the alkaloid inhibitor of alpha-glucosidase, castanospermine. Mannose-6-phosphate was effective at a dose of 25 mg/kg per day delivered via mini-osmotic pumps implanted either subcutaneously or intraperitoneally. Castanospermine was given orally in the drinking water and rats ingested on average 60-65 mg/kg per day. Histological examination of tissue from treated rats revealed greatly reduced inflammatory infiltrates into the synovium and surrounding tissue. Castanospermine not only inhibited the development of arthritis but also inhibited the progression of the disease when treatment was commenced after the onset of symptoms. Possible mechanism(s) of action of these compounds could be their ability to inhibit the passage of leucocytes through vascular subendothelial basement membranes by inhibiting the function or expression of leucocyte cell surface-bound enzymes that are essential for such migration. Castanospermine could also inhibit inflammation through its ability to prevent the expression of adhesion molecules, which may be necessary for the capture and retention of leucocytes in the inflamed tissue.

A basement-membrane permeability assay which correlates with the metastatic potential of tumour cells

We describe an in vitro assay for measuring the ability of tumour cells to permeabilize basement membranes, using transwell chambers coated with the reconstituted basement membrane, matrigel. Unlike previous matrigel-based procedures which quantified passage of tumour cells across a matrigel barrier, the new assay measures the ability of tumour cells to degrade the basement membrane and increase the diffusion rate of fluorescent (FL) dextran through the barrier. The procedure has the major advantage that permeability can be rapidly and accurately quantified, either by fluorometry or by the use of radiolabelled dextran, thus avoiding tedious and subjective scoring methods. Optimal conditions for the assay are described. In addition, it is demonstrated that the assay can clearly discriminate between metastatic and non-metastatic tumour cell lines, metastatic tumours permeabilizing the basement membrane and non-metastatic counterparts failing to do so. A range of enzyme inhibitors suggested that the increase in basement-membrane permeability caused by the metastatic mammary adenocarcinoma 13762 MAT is probably dependent upon the synergistic action of several degradative enzymes, namely proteases, type-IV collagenase, and heparanase. Furthermore, the ability to permeabilize the basement membrane was dependent upon intact tumour cells; tumour cell extracts, lysates and supernatants were inactive.

Evidence that mannose recognition by splenic sinusoidal cells plays a role in the splenic entry of lymphocytes

Previous studies demonstrated that mannan is a potent inhibitor of splenic entry of lymphocytes and mediates its inhibitory effect at an unidentified site in the spleen rather than acting directly on lymphocytes. This report describes the in vivo site of action of mannan. In vivo localization studies with fluoresceinated preparations of mannan (Fl-mannan) and a mannose-6-phosphate-containing yeast phosphomannan monoester core from P. holstii exopolysaccharide (Fl-PPME) demonstrated that the polysaccharide specifically localize in the splenic marginal sinuses in cells with a dendritic morphology termed splenic sinusoidal cells (SSC). Uptake of the polysaccharides by SSC was mediated by a mannan-specific receptor which was saturable and of high avidity. Several lines of evidence suggested that mannan uptake by SSC inhibited splenic entry of lymphocytes. First, the ability of SSC to bind Fl-mannan and Fl-PPME closely paralleled the ability of these polysaccharides to inhibit splenic entry of lymphocytes. In fact, doses of mannan and PPME which would saturate SSC mannan receptors completely blocked splenic entry of lymphocytes. Second, SSC are situated at the initial entry point of lymphocytes into spleen and passage of lymphocytes through the SSC region of spleen was profoundly inhibited by mannan. Finally, direct evidence for adhesion between lymphocytes and SSC was obtained with spleen cell suspensions where clustering between Fl-mannan labeled SSC and lymphocytes was observed. Collectively, these data indicate that mannan (and PPME) inhibit splenic entry of lymphocytes by interacting with SSC, cell which play a critical role in the entry of lymphocytes into the spleen. Whether mannan-specific receptors on SSC directly mediate lymphocyte-SSC adhesion or play on indirect role in modifying lymphocyte migration requires further investigation.

Ability of different chemically modified heparins to potentiate the biological activity of heparin-binding growth factor 1: lack of correlation with growth factor binding

A range of chemically modified heparins was examined for their ability to bind heparin-binding growth factor 1 (HBGF-1; acidic fibroblast growth factor) and potentiate the in vitro mitogenic and neurotrophic activity of HBGF-1. It was found that carboxyl-reduced heparin bound HBGF-1 as effectively as the native heparin molecule. Totally desulfated heparin and N-desulfated heparin lack HBGF-1-binding capacity, and substitution of the exposed amino group with acetyl or acetoacetyl groups only partially restored binding capacity, indicating that N-sulfates only play a limited role in growth factor binding. However, the failure of totally desulfated, N-resulfated heparin to interact with HBGF-1 demonstrated that N-sulfates alone are insufficient and ester sulfates are absolutely essential for HBGF-1 binding. In contrast, the ability of the modified heparins to potentiate the mitogenic activity of HBGF-1 correlated only to a limited extent with their affinity for HBGF-1. Thus, the carboxyl-reduced molecule which displayed similar affinity for HBGF-1 as native heparin was consistently less potent in augmenting mitogenesis. Similarly, the N-acetylated and the N-acetoacetylated species, which had much lower affinity for HBGF-1 than the carboxyl-reduced molecule, conferred similar biological activity to HBGF-1 whereas N-desulfated heparin, which was unable to bind growth factor, potentiated the mitogenic activity of HBGF-1 for both 3T3 and HUVE cells. In contrast, the neurotrophic activity of HBGF-1 was potentiated by modified heparin species which failed to bind HBGF-1 and were without activity in the mitogenic assays.(ABSTRACT TRUNCATED AT 250 WORDS)

Selective localisation of neuro-specific T lymphocytes in the central nervous system

Using experimental autoimmune encephalomyelitis (EAE) in the rat as a model of central nervous system (CNS) inflammation, activated and quiescent T lymphocytes with different antigen specificities were labelled with the fluorescent dye Hoechst 33342 and tested by fluorescence microscopy for their ability to accumulate in different regions of the spinal cord and in other organs at varying times post inoculation. With this highly sensitive assay it was found that activated myelin basic protein (MBP)-specific T cell lines accumulated in the spinal cord (a 1000-fold increase in the lumbar/sacral region by day 4) and caused clinical signs of EAE. In contrast, interleukin-2 (IL-2)-maintained (quiescent) MBP-specific T cell lines failed to accumulate in the CNS and cause disease. Activated ovalbumin (OA)-specific and purified protein derivative of tuberculin (PPD)-specific T cell lines were also found at significantly higher levels in the spinal cord than non-activated cells although they failed to accumulate to a substantial degree when injected alone. When injected with activated MBP-specific T cells the activated OA- and PPD-specific cell lines accumulated in the spinal cord following initial accumulation of the MBP-specific cells, demonstrating that during the inflammatory process there is considerable non-specific recruitment of cells into the inflammatory site. CNS accumulation of activated MBP-specific T cell lines occurred 1-2 days later in irradiated animals than in non-irradiated recipients. This was consistent with irradiated animals also exhibiting a later onset of disease and suggests that irradiation may directly affect the endothelium in a way that makes it less adhesive. In conclusion, this study demonstrates that activated lymphocytes of any specificity enter the spinal cord, and that the neuro-antigen specific cells accumulate there and lead to the recruitment of other cells. Non-activated cells, even those with neural antigen specificity fail to enter the cord. Understanding the nature of what an 'activated' lymphocyte is may allow us to design strategies to inhibit such immune-mediated inflammation.

Calcein: a novel marker for lymphocytes which enter lymph nodes

Previous studies have identified unique cell surface antigens which are associated with the specific binding of lymphocytes to high endothelial venules (HEV). Evidence is presented in this paper which demonstrates that uptake of the fluorescent dye calcein by lymphocytes represents an additional marker for the lymph node homing subpopulation of lymphocytes. Calcein exhibits a characteristic ability to label lymphocytes differentially into two distinct populations, based on fluorescence intensity, that does not occur with three other structurally related, fluorescein-based dyes. In vivo lymphocyte migration studies revealed that cells displaying the "dull" fluorescence phenotype, although entering all lymphoid organs examined, preferentially homed to the lymph nodes, particularly the popliteal lymph node (PLN). By contrast, lymphocytes displaying the "bright" phenotype were essentially excluded from entering lymphoid organs, where entry is HEV dependent, but were observed entering spleen, where entry is HEV independent. Furthermore, a high proportion (76.5%) of lymphocytes displaying the dull fluorescence phenotype expressed the PLN homing receptor MEL-14. Based on these observations it is suggested that calcein uptake may be a marker for general membrane properties, such as fluidity and plasticity, essential for the passage of lymphocytes through HEV.

Dextran sulfate induces changes in the free intracellular calcium ion concentration of a subpopulation of immature thymocytes

Previous studies have shown that certain sulfated polysaccharides, such as dextran sulfate (DxS), can induce a rapid and sustained increase in the free intracellular calcium ion concentration ([Ca2+]i) of thymocytes, whereas they cannot induce a change in the [Ca2+]i of peripheral lymphocytes. This study examined this phenomenon in more detail and clearly demonstrated that only immature thymocytes can respond to DxS. Cortisone-resistant thymocytes failed to exhibit an increase in [Ca2+]i when exposed to DxS. Furthermore, analysis of [Ca2+]i changes at the single cell level using a flow cytometer demonstrated that only a subpopulation of immature thymocytes responded to DxS. Additional flow cytometry studies revealed that DxS and Con-A induce a [Ca2+]i response in different subpopulations of thymocytes, approximately 30% of thymocytes responding to Con-A and 15-20% to DxS. Thus, responsiveness to Con-A and DxS, in terms of increases in [Ca2+]i, may represent a novel marker for two different thymocyte subpopulations. Such metabolic markers could be used to complement the conventional serological methods currently employed to define stages in thymocyte differentiation.

Conservation of a polyanion binding site in mammalian and avian CD4

A polyanion binding site was identified recently on human CD4 which is distinct from the human immunodeficiency virus (HIV)-gp120 binding region but which incorporates the first two immunoglobulin (Ig)-like domains of the molecule. To determine if this site is conserved in other species, several polyanions that blocked monoclonal antibody (mAb) binding to human CD4 were examined for their ability to inhibit the binding of mAb to mouse, rat, pig, sheep and chicken CD4. It was found that aurintricarboxylic acid (ATA) was a particularly effective inhibitor, blocking mAb binding to human, mouse, pig, sheep and rat CD4 by greater than 90% and to chicken CD4 by 80-90%. The polyanions dextran sulphate (DxS), polyvinyl sulphate (PVS) and polyanethole sulphonate (PAS) were also effective inhibitors of anti-CD4 mAb binding in most species, although there were clear species differences in the effects obtained. The polyanions did not inhibit mAb binding to a variety of other cell-surface antigens in the different species, with the exception of sheep CD8, suggesting that the inhibitory effects observed were essentially CD4 specific. Collectively these data indicate that a polyanion binding site is conserved in mammalian and avian CD4. Comparison of the amino acid sequences of human, mouse and rat CD4 revealed that basic residues in human CD4 which could participate in a polyanion binding site are conserved in mouse and rat CD4. It is proposed that this conserved polyanion binding site of CD4 interacts with a sulphated glycosaminoglycan chain which is associated with class II major histocompatibility complex (MHC) molecules containing recently processed antigen.

Modification of lymphocyte migration by mannans and phosphomannans. Different carbohydrate structures control entry of lymphocytes into spleen and lymph nodes

Previous in vitro studies suggest that recognition of phosphomannosyl structures by lymphocytes plays a central role in the binding of lymphocytes to high endothelial venules. However, the physiologic relevance of phosphomannosyl recognition in in vivo lymphocyte migration has not been established. This paper describes experiments that examined this question. It was demonstrated that the phosphomannan monoester core (PPME) from Pichia holstii, a potent inhibitor of peripheral node high endothelial venule interactions in vitro, was a very effective inhibitor of in vivo lymphocyte migration, as little as 39 micrograms/mouse significantly inhibiting popliteal lymph node entry. Furthermore, PPME exhibited a similar hierarchy of inhibition in vivo as previously reported in vitro, most effectively inhibiting entry of lymphocytes into popliteal lymph node, somewhat less effectively inhibiting mesenteric lymph node entry and being a relatively poor inhibitor of Peyer's patch entry. Additionally, PPME inhibited splenic entry of lymphocytes, and inhibition of lymphoid organ entry was accompanied by a substantial leukocytosis. Two additional mannose-containing compounds were found to modify lymphocyte migration, namely a well defined mannose containing pentasaccharide (PENT) with terminal mannose-6-phosphate (M6P) and an unphosphorylated yeast mannan. Both PENT and mannan induced leukocytosis and were particularly effective at inhibiting splenic entry of lymphocytes. In fact, detailed dose-response curves indicated that mannan was a much more potent inhibitor of splenic entry than PPME or PENT, whereas in lymph nodes PPME was the most effective inhibitor. Pretreatment of lymphocytes before injection with either PPME or mannan demonstrated that PPME could act at the lymphocyte level, whereas mannan probably acted at some other site. Collectively, these data suggest that different carbohydrate structures are involved in the entry of lymphocytes into different lymphoid organs, with mannose recognition playing an important role in splenic entry and recognition of M6P-like structures controlling lymph node entry. In contrast, it was found that mannose-and M6P-containing structures, unlike sulfated polysaccharides such as fucoidan, did not affect the subsequent positioning of lymphocytes within lymphoid organs.

Modification of lymphocyte migration by mannans and phosphomannans. Different carbohydrate structures control entry of lymphocytes into spleen and lymph nodes

Previous in vitro studies suggest that recognition of phosphomannosyl structures by lymphocytes plays a central role in the binding of lymphocytes to high endothelial venules. However, the physiologic relevance of phosphomannosyl recognition in in vivo lymphocyte migration has not been established. This paper describes experiments that examined this question. It was demonstrated that the phosphomannan monoester core (PPME) from Pichia holstii, a potent inhibitor of peripheral node high endothelial venule interactions in vitro, was a very effective inhibitor of in vivo lymphocyte migration, as little as 39 micrograms/mouse significantly inhibiting popliteal lymph node entry. Furthermore, PPME exhibited a similar hierarchy of inhibition in vivo as previously reported in vitro, most effectively inhibiting entry of lymphocytes into popliteal lymph node, somewhat less effectively inhibiting mesenteric lymph node entry and being a relatively poor inhibitor of Peyer's patch entry. Additionally, PPME inhibited splenic entry of lymphocytes, and inhibition of lymphoid organ entry was accompanied by a substantial leukocytosis. Two additional mannose-containing compounds were found to modify lymphocyte migration, namely a well defined mannose containing pentasaccharide (PENT) with terminal mannose-6-phosphate (M6P) and an unphosphorylated yeast mannan. Both PENT and mannan induced leukocytosis and were particularly effective at inhibiting splenic entry of lymphocytes. In fact, detailed dose-response curves indicated that mannan was a much more potent inhibitor of splenic entry than PPME or PENT, whereas in lymph nodes PPME was the most effective inhibitor. Pretreatment of lymphocytes before injection with either PPME or mannan demonstrated that PPME could act at the lymphocyte level, whereas mannan probably acted at some other site. Collectively, these data suggest that different carbohydrate structures are involved in the entry of lymphocytes into different lymphoid organs, with mannose recognition playing an important role in splenic entry and recognition of M6P-like structures controlling lymph node entry. In contrast, it was found that mannose-and M6P-containing structures, unlike sulfated polysaccharides such as fucoidan, did not affect the subsequent positioning of lymphocytes within lymphoid organs.

Characterization of lymphocyte receptors for glycosaminoglycans

This paper describes attempts to isolate and characterize glycosaminoglycan (GAG)-binding molecules on the surface of lymphocytes and lymphoma cell lines and relate their expression to splenic and lymph node homing capacity. Initial binding studies with radiolabelled GAG and rosetting studies with GAG-coupled erythrocytes revealed that there are receptors on lymphocytes for the major classes of GAG (i.e. hyaluronic acid, chrondroitin sulfates, heparin), but lymphocytes bind heparin much more avidly than other GAG species. Analysis of the binding of solubilized radiolabelled cell-surface molecules to immobilized GAG revealed cell-type specific expression of GAG-binding molecules. Thus, each of four lymphoma cell lines tested gave a characteristic pattern of GAG-binding molecules, some molecules being unique to a particular cell line and others being shared by some of the lines. Similarly, splenocytes expressed at least 10 distinct GAG-binding molecules with molecular weights (MW) ranging from 10,000 to 100,000, whereas thymocytes expressed additional GAG-binding proteins of 190,000 and 250,000 MW. Furthermore, splenocytes differed from thymocytes by possessing a unique family of cell-surface molecules which reacted with each GAG. Immunoprecipitation studies demonstrated that the GAG-binding molecules on splenocytes did not correspond to any of the cell-surface antigens tested, notably the cell adhesion molecules MEL-14, CD11/CD18 and CD44, although CD8 bound weakly to heparin. Four lymphoma cell lines with well-characterized migration properties were examined for GAG-binding molecules which may control lymphocyte migration. It was found that no one GAG-binding protein could be correlated with the entry of cells into a particular lymphoid organ. Nevertheless, the role of GAG-binding molecules in the subsequent positioning of lymphocytes within lymphoid organs requires further investigation.

New fluorescent dyes for lymphocyte migration studies. Analysis by flow cytometry and fluorescence microscopy

16 fluorochromes were examined for their ability to label viable lymphocytes in vitro and yield fluorescence detectable by fluorescence microscopy and flow cytometry. Of these fluorochromes, four intracellular dyes were found to be suitable for in vivo migration studies. They were H33342, the well known DNA-binding dye which excites and emits in the UV range, and three fluorescein based cytoplasmic dyes, namely BCECF-AM, Calcein-AM and CFSE which excite and emit in the visible range. Lymphocytes labelled with H33342, BCECF-AM and Calcein-AM were suitable for short term in vivo migration experiments with detection by flow cytometry 2-3 days post injection. In contrast lymphocytes labelled with CFSE, a fluorochrome which can covalently couple with intracellular macromolecules, were detected by flow cytometry up to 8 weeks post injection and thus this fluorochrome is ideal for long term migration experiments. Due to marked differences in fluorescence profiles, BCECF-AM and Calcein-AM could be used for short term double labelling experiments using the flow cytometer in which entry of injected lymphocytes into lymphoid organs was quantified. Similarly, in vivo localization of lymphocyte subpopulations could be examined by fluorescence microscopy utilizing differences in fluorescence excitation and emission spectra of lymphocytes labelled with H33342 and one of the fluorescein based dyes.

A polyanion binding site on the CD4 molecule. Proximity to the HIV-gp120 binding region

Recent studies have demonstrated that sulfated polyanions (SP) are potent inhibitors of HIV infection in vitro, appearing to inhibit virus attachment. To understand the mode of action of these compounds a large panel of SP were examined for their ability to inhibit HIV infection, block anti-CD4 mAb binding and, when immobilized, bind soluble CD4 and virion gp120. Based on anti-CD4 mAb binding-inhibition studies a SP binding site was identified on the CD4 molecule. Dextran sulfate (DXS)-500 kDa, polyvinylsulfate (PVS), and polyanethole sulfonate were particularly potent SP inhibitors, blocking the binding of 11 of the 12 anti-CD4 mAb tested. These 11 mAb are known to interact with the two amino-terminal Ig-like domains of CD4. In fact, DXS-500 kDa exhibited an hierarchy of inhibition of anti-CD4 mAb which suggests that SP bind to a conformational site incorporating the first two Ig-like domains of CD4. This SP binding site is clearly distinct but closely associated with the gp120 binding region of CD4. In terms of anti-HIV activity there was no evidence that SP act at the virion level as rgp120 did not bind to immobilized SP and preincubation of virions with SP did not affect infectivity. In contrast, many of the SP tested showed some affinity for CD4 based on anti-CD4 mAb blocking studies and binding of soluble CD4 to immobilized SP. The most active in this regard were DXS-500 kDa and PVS, whose anti-HIV activity could be entirely due to disruption of the CD4-gp120 interaction. However, with SP such as heparin, fucoidan, the carrageenans, and polyanethole sulfonate, although CD4 blocking may contribute to anti-HIV activity, some other anti-viral mechanism is also operating. Finally, pentosan sulfate, a SP with anti-HIV activity comparable to DXS-500 kDa and PVS, showed little or no reactivity with CD4 and must inhibit HIV infection by a totally CD4-independent mechanism.

A polyanion binding site on the CD4 molecule. Proximity to the HIV-gp120 binding region

Recent studies have demonstrated that sulfated polyanions (SP) are potent inhibitors of HIV infection in vitro, appearing to inhibit virus attachment. To understand the mode of action of these compounds a large panel of SP were examined for their ability to inhibit HIV infection, block anti-CD4 mAb binding and, when immobilized, bind soluble CD4 and virion gp120. Based on anti-CD4 mAb binding-inhibition studies a SP binding site was identified on the CD4 molecule. Dextran sulfate (DXS)-500 kDa, polyvinylsulfate (PVS), and polyanethole sulfonate were particularly potent SP inhibitors, blocking the binding of 11 of the 12 anti-CD4 mAb tested. These 11 mAb are known to interact with the two amino-terminal Ig-like domains of CD4. In fact, DXS-500 kDa exhibited an hierarchy of inhibition of anti-CD4 mAb which suggests that SP bind to a conformational site incorporating the first two Ig-like domains of CD4. This SP binding site is clearly distinct but closely associated with the gp120 binding region of CD4. In terms of anti-HIV activity there was no evidence that SP act at the virion level as rgp120 did not bind to immobilized SP and preincubation of virions with SP did not affect infectivity. In contrast, many of the SP tested showed some affinity for CD4 based on anti-CD4 mAb blocking studies and binding of soluble CD4 to immobilized SP. The most active in this regard were DXS-500 kDa and PVS, whose anti-HIV activity could be entirely due to disruption of the CD4-gp120 interaction. However, with SP such as heparin, fucoidan, the carrageenans, and polyanethole sulfonate, although CD4 blocking may contribute to anti-HIV activity, some other anti-viral mechanism is also operating. Finally, pentosan sulfate, a SP with anti-HIV activity comparable to DXS-500 kDa and PVS, showed little or no reactivity with CD4 and must inhibit HIV infection by a totally CD4-independent mechanism.

Mapping the dextran sulfate binding site on CD2

This study has analysed the binding of a series of anti-CD2 monoclonal antibodies (MoAbs) to T cells in the presence of the sulfated polysaccharide dextran sulfate (2.3 sulfates/monosaccharide, 500 kDa) (DXS) to define the DXS binding site on CD2. The results show that DXS interacts primarily at the T11(2) epitope. Thus five anti-CD2 MoAbs which bound to the T11(2) epitope were inhibited in their binding by DXS. In contrast, seven anti-CD2 MoAbs that totally inhibited sheep red blood cells (SRBC) rosetting (identifying the T11(1) epitope) were unaffected in their binding to T cells in the presence of DXS. Three MoAbs which partially inhibited SRBC rosetting and thereby defining only part of the T11(1) epitope, were also inhibited in their binding by DXS. Consistent with the conclusion that the DXS binding site on CD2 is associated with the T11(2) epitope was the observation that interaction of DXS with CD2 resulted in augmented binding of the four MoAbs defining the T11(3) epitope, possibly reflecting an increased expression of the T11(3) (activation, CD2R) epitope of CD2. Collectively, the data presented support the notion that a natural ligand for the T11(2) epitope of CD2 will be identified as a sulphated carbohydrate structure.

Phosphosugars are potent inhibitors of central nervous system inflammation

Adoptively transferred allergic encephalomyelitis can be inhibited by various phosphosugars, particularly mannose-6-phosphate. The sugar specificity suggests that inhibition may be due to depletion of lymphocyte cell-surface lysosomal enzymes, which are essential for the passage of lymphocytes across the vascular endothelium and the entry of lymphocytes into the central nervous system parenchyma.

Receptors on lymphocytes for endogenous splenic glycosaminoglycans

Previous studies have shown that lymphocytes carry cell surface receptors for sulphated polysaccharides (SPS), and SPS recognition may play a role in lymphocyte migration and positioning in vivo. This paper describes attempts to isolate and characterize the endogenous glycosaminoglycans (GAGs) of murine spleen and determine whether splenic lymphocytes carry cell surface receptors for these GAGs. A procedure was devised for isolating GAGs from murine spleen in good yield and high purity and the GAG preparation was then radiolabelled for subsequent binding studies. It was found that the splenic GAGs bound to murine splenocytes in a saturable, rapid and reversible manner with only a small subpopulation of the splenic GAG preparation being involved in binding. This reactive species was chondroitinase ABC-resistant and nitrous acid-sensitive, indicative of a heparan sulphate/heparin-like molecule. Furthermore, using immunofluorescent flow cytometry studies it was demonstrated that the majority of spleen cells have receptors for these GAGs. Subsequent ion-exchange fractionation and SDS-PAGE analysis of chondroitinase ABC-resistant GAGs confirmed that the splenic GAG recognized by splenocytes was a heparan sulphate/heparin molecule of approximately 20,000 MW with a binding affinity to splenocytes of approximately 5 X 10(-8) M. Additional binding inhibition studies indicated two possible binding sites for splenic GAGs on the splenocyte surface, one being fully inhibited by a range of SPS such as heparin (both coagulant and anticoagulant forms), pentosan sulphate, fucoidan, dextran sulphate, lambda- and iota-carrageenan, and the second being partially inhibited by kappa-carrageenan. The possible relevance of these heparan sulphate/heparin receptors on splenocytes to lymphocyte positioning in vivo is discussed.

Inhibition of experimental allergic encephalomyelitis by the alpha-glucosidase inhibitor castanospermine

The alkaloid castanospermine is a potent inhibitor of oligosaccharide processing in vitro. Our recent findings indicating the importance of carbohydrate moieties in some critical step of the neuro-immunologic inflammatory process of allergic encephalomyelitis prompted us to investigate the effect of castanospermine on this disease process. The alkaloid inhibited passively induced allergic encephalomyelitis in a dose-dependent manner when administered continuously for 7 days beginning at the time of lymphocyte transfer. Although clinical disease was totally inhibited, treated animals did have inflammatory lesions in the central nervous system. These lesions were qualitatively different from those seen in untreated animals in that the inflammatory cells were tightly packed around the vessels and showed little migration into surrounding tissues. Castanospermine also effectively inhibited clinical disease in recipient animals which had had a previous episode of allergic encephalomyelitis. Castanospermine did not alter the disease when treatment was started after the onset of clinical symptoms.

Is a natural ligand of the T lymphocyte CD2 molecule a sulfated carbohydrate?

Recent studies have implicated sulfated polysaccharide (SP) recognition in a range of cell adhesion systems. Inasmuch as the CD2 (E rosette receptor, T11, LFA-2) molecule of human T lymphocytes is a cell surface glycoprotein involved in the adhesion of T cells to various target cells the possibility that CD2 binds SP was investigated. It was found that E rosetting of human T lymphocytes, a phenomenon involving CD2, was readily inhibited by the SP dextran sulfate (DxS) and, to a lesser extent, by the sulfated polymer polyvinyl sulfate whereas 11 other SP had no effect on E rosetting, this effect occurring at the T cell level. mAb binding studies revealed that DxS and polyvinyl sulfate, but none of the other SP tested, inhibited the binding to T cells of the anti-CD2 mAb OKT11 and anti-T112 but augmented expression of the T113 epitope of the CD2 molecule. In contrast, DxS had little or no effect on the binding of anti-CD3, -CD4, -CD8, -Pgp-1 and WT31 (TCR alpha/beta) mAb. Direct evidence that CD2 binds DxS was demonstrated by the ability of DxS-coupled fibers to totally deplete the CD2 Ag from lysates of radiolabeled human T lymphocytes and by the quantitative recovery of the CD2 Ag in fiber eluates. Control fibers coupled with other SP bound little or no CD2. Collectively, the data indicate that the CD2 molecule specifically binds DxS and suggest that a potential target cell ligand for CD2 is a sulfated carbohydrate structure.

Is a natural ligand of the T lymphocyte CD2 molecule a sulfated carbohydrate?

Recent studies have implicated sulfated polysaccharide (SP) recognition in a range of cell adhesion systems. Inasmuch as the CD2 (E rosette receptor, T11, LFA-2) molecule of human T lymphocytes is a cell surface glycoprotein involved in the adhesion of T cells to various target cells the possibility that CD2 binds SP was investigated. It was found that E rosetting of human T lymphocytes, a phenomenon involving CD2, was readily inhibited by the SP dextran sulfate (DxS) and, to a lesser extent, by the sulfated polymer polyvinyl sulfate whereas 11 other SP had no effect on E rosetting, this effect occurring at the T cell level. mAb binding studies revealed that DxS and polyvinyl sulfate, but none of the other SP tested, inhibited the binding to T cells of the anti-CD2 mAb OKT11 and anti-T112 but augmented expression of the T113 epitope of the CD2 molecule. In contrast, DxS had little or no effect on the binding of anti-CD3, -CD4, -CD8, -Pgp-1 and WT31 (TCR alpha/beta) mAb. Direct evidence that CD2 binds DxS was demonstrated by the ability of DxS-coupled fibers to totally deplete the CD2 Ag from lysates of radiolabeled human T lymphocytes and by the quantitative recovery of the CD2 Ag in fiber eluates. Control fibers coupled with other SP bound little or no CD2. Collectively, the data indicate that the CD2 molecule specifically binds DxS and suggest that a potential target cell ligand for CD2 is a sulfated carbohydrate structure.

Automated fluorometric assay for T cell cytotoxicity

A fluorometric assay avoiding the use of radioactivity has been developed for detecting cytotoxic T lymphocytes (Tc cells). The method involves labelling targets with Hoechst dye no. 33342 (H33342) which becomes brightly fluorescent on binding to DNA. Lysis of target cells by Tc cells is quantified by measuring the release of fluorescent H33342 into the supernatant of culture wells. The fluorescence is measured using an automated Microfluor reader which allows results to be obtained rapidly. The assay has been used to detect alloreactive Tc cells and H-2 restricted Tc cells against influenza virus in a short-term 6 h assay using P815 and L929 as targets with comparable results to those obtained with 51Cr labelling. In contrast, lymphocyte blasts were found to be less sensitive in 6 h fluorometric assays when compared with the 51Cr assay. In long-term overnight assays (possible because of the low spontaneous release of H33342 from targets) lymphocyte blasts gave high specific lysis and some anti-self reactivity. The cause of the anti-self reactivity may reflect fundamental differences between the H33342 and 51Cr release assays.

Inhibition of allergic encephalomyelitis in rats by treatment with sulfated polysaccharides

A number of sulfated polysaccharides were tested for their ability to inhibit passively induced experimental allergic encephalomyelitis (EAE) in rats. Heparin and fucoidan both completely inhibited passive EAE even when treatment was begun 3 days after transfer of cells. Pentosan sulfate was partially inhibitory whereas chondroitin-4-sulfate had no effect. Inhibition was not merely due to killing of the cells since active sensitization 14 days after cell transfer resulted in an early onset of disease indicating the persistence of transferred cells as memory cells. Although all the inhibitory polysaccharides are anticoagulants, it would appear that this function alone is not the reason for inhibition since a heparin preparation devoid of anticoagulant activity also partially inhibited EAE. Actively induced EAE was also significantly delayed by treatment with heparin. The results are discussed in terms of the polysaccharides inhibiting the enzymatic dependent movement of lymphocytes across central nervous system vascular endothelium.

Inhibition of allergic encephalomyelitis in rats by treatment with sulfated polysaccharides

A number of sulfated polysaccharides were tested for their ability to inhibit passively induced experimental allergic encephalomyelitis (EAE) in rats. Heparin and fucoidan both completely inhibited passive EAE even when treatment was begun 3 days after transfer of cells. Pentosan sulfate was partially inhibitory whereas chondroitin-4-sulfate had no effect. Inhibition was not merely due to killing of the cells since active sensitization 14 days after cell transfer resulted in an early onset of disease indicating the persistence of transferred cells as memory cells. Although all the inhibitory polysaccharides are anticoagulants, it would appear that this function alone is not the reason for inhibition since a heparin preparation devoid of anticoagulant activity also partially inhibited EAE. Actively induced EAE was also significantly delayed by treatment with heparin. The results are discussed in terms of the polysaccharides inhibiting the enzymatic dependent movement of lymphocytes across central nervous system vascular endothelium.

Monosaccharide inhibition of cytotoxic T-cell function: demonstration of clone-specific effects

A range of monosaccharides has been tested for their capacity to influence the induction and effector function of alloreactive cytotoxic T (Tc) cells. Strain-specific differences in the capacity of monosaccharides to inhibit Tc cell induction have been demonstrated. Monosaccharides can also inhibit effector function of target cell lysis, but this could only be demonstrated by assessing the effect of sugars added to limiting dilution cultures of alloantigen-stimulated T cells. B10.A(4R) anti-BALB/c Tc cells have been reproducibly inhibited by D-glucosamine and D-galactosamine, as well as D-galacturonic acid, at both the induction and effector phases of the Tc cell response. Analysis of monosaccharide inhibition of cytotoxicity in limiting dilution cultures has confirmed that D-glucosamine is the most effective inhibitor of B10.A(4R) anti-BALB/c Tc cells, while D-galactosamine and D-galacturonic acid inhibit cytotoxicity in only some limiting dilution wells. Analysis of several B10.A(4R) anti-BALB/c Tc cell clones has revealed at least two different 'clone-specific' patterns of inhibition by D-glucose, D-glucuronic acid and D-galacturonic acid. Since Tc cell recognition of antigen is generally specific for class I major histocompatibility complex (MHC) antigens, this data implicates a role for MHC-associated carbohydrate structures expressed by target cells in T-lymphocyte interactions with antigen.

The T11(3) epitope of the CD2 molecule, sheep erythrocytes, and the alternative T-cell activation pathway

In this study, results are presented showing that the T11(3) epitope of the CD2 molecule is expressed on unfractionated peripheral blood mononuclear cells, resting T cells and activated T cells. T11(3) is not therefore, an activation-specific CD2 epitope. Sheep erythrocytes (SRC) which present a cell-surface ligand for CD2 could not effectively replace anti-T11(2) in initiating proliferation of resting T cells, stimulated by anti-T11(3). SRC with either of these anti-CD2 monoclonal antibodies did activate resting T cells, but proliferation required the presence of added IL-2.

Evidence that Thy-1 and Ly-5 (T-200) antigens interact with sulphated carbohydrates

Recent studies have demonstrated that lymphocytes express an array of cell surface receptors for sulphated polysaccharides (SP). Experiments were undertaken to determine the binding characteristics of these receptors and establish whether any known lymphocyte cell surface antigens interact with sulphated carbohydrates. It was found that murine thymocytes lack receptors for chondroitin-4-sulphate but express saturable, high affinity binding sites for heparin, fucoidan and dextran sulphate, with an apparent affinity constant range of 0.03-2.6 x 10(-9) mol/l. Binding inhibition experiments revealed one class of binding sites on murine thymocytes that is shared by heparin, fucoidan and dextran sulphate and another class of sites that is dextran sulphate-specific. The cell surface receptors for the SP were affinity-purified by applying detergent lysates of 125I-labelled thymocyte membranes to SP-coupled solid supports. It was found that the Thy-1 and Ly-5 (T-200 or leucocyte common antigen) molecules of murine thymocytes bind to sulphated carbohydrates, although the two molecules differed substantially in their reactivity with the four different SP tested. Furthermore, only subpopulations of the Thy-1 and Ly-5 molecules interacted with sulphated sugars. Four additional sulphated carbohydrate-binding molecules were also detected. It is suggested that the SP-binding molecules are involved in the interaction of lymphocytes with glycosaminoglycans on other cells and in the interstitial space.

Analysis of the genetic control of lymphocyte positioning

A possible role for the major histocompatibility complex (MHC) in the localization of lymphocytes in different lymphoid organs was investigated using inbred mouse strains. Lymphocytes labelled with the intracellular fluorochrome Hoechst 33342 (H33342) were transfused intravenously (IV) into unimmunized mice and the distribution of these labelled lymphocytes examined. In some combinations (e.g. C57BL/6----CBA) 2 h after injection allogeneic lymphocytes accumulated in the region between the marginal zones and outer aspects of the white pulp of the spleen. In contrast, in syngeneic controls (e.g. CBA----CBA) the lymphocytes migrated normally into the while pulp. Similar results were obtained in Peyer's patches. Mapping studies in the spleen indicated that the failure to migrate normally is predominantly controlled by the MHC complex, although some non-MHC genes may play a role. In the case of the MHC the most definitive combination was BALB/c-H-2dm2 (H-2L deletion mutant) lymphocytes transfused into BALB/c recipients, the mutant lymphocytes failing to migrate normally and, therefore, implicating the H-2L region in the phenomenon. No differences in the viability of labelled lymphocytes at 6 and 24 h after injection into either syngeneic or allogeneic recipients suggests that the inability of cells to passage through lymphoid organs may represent inappropriate receptors rather than elimination of the allogeneic lymphocytes by natural killer cells (NK) as previously proposed.

Evidence that sulphated polysaccharides inhibit tumour metastasis by blocking tumour-cell-derived heparanases

Recent studies in this laboratory demonstrated that several sulphated polysaccharides can inhibit metastasis of the rat mammary adenocarcinoma 13762 MAT, probably by preventing the passage of tumour cells through the walls of blood vessels. In order to directly test this possibility, 13762 MAT cells were cultured with (35S)O4(=)-labelled subendothelial extracellular matrices (ECM) and ECM degradation was monitored in either the presence or absence of different sulphated polysaccharides. Degradation products were detected by sodium dodecyl sulphate polyacrylamide gel electrophoresis and subsequent autoradiography. The 5 sulphated polysaccharides that had previously been shown to possess anti-metastatic activity were potent inhibitors of the degradation of subendothelial ECM by 13762 MAT cells. In contrast, of the 4 polysaccharides tested that failed to inhibit metastasis, 3 had no effect on ECM breakdown and one (carrageenan-kappa) was substantially less effective at inhibiting ECM degradation than the anti-metastatic preparations. It was also shown that 13762 MAT cells produce a heparan sulphate-specific glycosidase (heparanase) that degrades the heparan sulphate side-chains of the ECM, the action of this enzyme rather than that of other ECM-solubilizing enzymes being inhibited by the antimetastatic sulphated polysaccharides. Additional experiments indicated that the anti-coagulant activity of the polysaccharides probably plays a minor role in their anti-metastatic effects since heparin, almost completely depleted (98-99.5%) of heparin molecules with anti-coagulant activity by passage over an anti-thrombin III column, retained its ability to inhibit 13762 MAT heparanases and was almost as effective as unfractionated heparin at inhibiting tumour-cell metastasis. Collectively, these data suggest that sulphated polysaccharides inhibit the metastasis of 13762 MAT cells by inhibiting tumour-cell-derived heparanases involved in the penetration of the vascular endothelium and its underlying basement membrane by tumour cells.

The effect of sulfated polysaccharides on the free intracellular calcium ion concentration of lymphocytes

Recent studies have demonstrated that murine lymphocytes express specific cell-surface receptors for a range of sulfated polysaccharides. In order to determine whether polysaccharide binding induces transmembrane signaling, the effects of sulfated polysaccharides on the free intracellular calcium ion concentration [( Ca2+]i) of mouse thymocytes and spleen cells were determined. Cells were loaded with Indo-I, a fluorescent indicator of calcium ion concentration. The validity and limitations in the use of this indicator in the determination of [Ca2+]i are documented. Dextran sulfate (Mn = 500,000), iota-carrageenan, lambda-carrageenan and kappa-carrageenan all cause relatively large changes in the [Ca2+]i of thymocytes (change in [Ca2+]i greater than 50 nM). Of these, dextran sulfate (Mn = 500,000) always had the greatest effect on [Ca2+]i. Smaller responses were obtained with heparin and dextran sulfate (Mn = 5000), while no response was obtained with chondroitin 4-sulfate, chondroitin 6-sulfate, pentosan sulfate or fucoidin. This response pattern (with the exception of fucoidin and pentosan sulfate) corresponds with the expression of thymocyte receptors for these polysaccharides. The increase in [Ca2+]i caused by the sulfated polysaccharides requires extracellular Ca2+ ions however, it is unlikely that voltage-dependent ion channels are involved in these responses. In contrast to thymocytes, although spleen cells express receptors for sulfated polysaccharides, they were unresponsive to all of the sulfated polysaccharides tested, suggesting a basic difference between thymocytes and peripheral T and B lymphocytes in their response to the binding of sulfated polysaccharides.

A role for sulfated polysaccharide recognition in sponge cell aggregation

Molecules binding sulfated polysaccharides were detected as lectins in cholate lysates of cells from twelve sponge species. Each species exhibited a unique binding profile. The pattern of binding indicated that the specificity was most probably determined by the orientation of the sulfate groups on the polysaccharide chains. Cells from each of the three species examined in more detail were found to express sulfated polysaccharide-binding molecules at their surface and at least one of the polysaccharides recognized was found to inhibit the reaggregation of cells from each species. Moreover, in all but one instance, lectins for the inhibitory polysaccharide were both detected in cell lysates and shown to be expressed at the cell surface. Sulfated polysaccharides, therefore, appeared to be involved in cell interaction events in the Porifera. This conclusion was confirmed by the isolation via ion exchange chromatography of an endogenous polysaccharide from an O. tenuis cell extract. This molecule contained uronic acid and hexose units in a ratio of 2:1, 11.9% sulfur and less than 0.5% protein. It inhibited the aggregation of O. tenuis cells and the agglutination of dextran-sulfate- and polyvinyl-sulfate-coupled erythrocytes by O. tenuis cell lysates. O. tenuis cell aggregation was also inhibited by polyvinyl sulfate and dextran sulfate and molecules binding these compounds were expressed on the surface of O. tenuis cells. Thus, is was probable that the cell surface receptor for polyvinyl sulfate and dextran sulfate and isolated sponge sulfated polysaccharide are one and the same. Finally, using a dextran sulfate affinity procedure, a 35 kD dextran-sulfate-binding protein was isolated from the surface of O. tenuis cells. The possibility that the polysaccharide isolated from O. tenuis cell extracts in the absence of calcium is the monomeric form of a cell aggregation-enhancing factor is discussed.

Evidence that the cytoskeleton plays a key role in cell adhesion

A range of pharmacological agents with defined effects on cell metabolism was used to determine the metabolic requirements of three cell adhesion systems: aggregation of cells from the sponge, Ophlitaspongia tenuis; fibronectin-induced adhesion of fibroblasts to substrata and an in vitro murine thymocyte-macrophage interaction. Cell adhesion in all three systems was found to have similar metabolic requirements, implying that the mechanism of cell adhesion has been conserved through evolution. In fact, based on analysis of F-actin organization in fibroblasts, all of the pharmacological agents that inhibited cell adhesion were found to disrupt the cytoskeleton, suggesting that the cytoskeleton plays a central role in the adhesion process, presumably via redistribution of cell surface molecules. This concept was supported by the finding that the same drugs that inhibited cell adhesion inhibited anti-Ig-induced redistribution of surface Ig on B lymphocytes. The drug inhibition studies also revealed that two drugs, bromophenacyl bromide (BPB) and nordihydroguaiaretic acid (NDGA), that were previously believed to be selective inhibitors of arachidonic acid synthesis and metabolism, are also potent disruptors of the cytoskeleton.

Analysis of the inhibition of tumour metastasis by sulphated polysaccharides

Lung metastases resulting from the intravenous (i.v.) injection of cells from the rat mammary adenocarcinoma 13762 MAT were significantly reduced by a variety of sulphated polysaccharides, the most effective being heparin, fucoidan and Carrageenan lambda. Although all the inhibitory polysaccharides were anticoagulants, it is unlikely that anticoagulation is the total explanation of their antimetastatic effect because: (i) heparin preparations from 2 different suppliers, although exhibiting comparable anticoagulant activities, differed 10-fold in their antimetastatic capability; (ii) certain sulphated polysaccharides consistently gave a 30% difference in the number of metastatic lesions, yet exhibited identical anticoagulant activity; and (iii) the entrapment of 13762 MAT cells in the lung was not impaired by heparin or fucoidan. It was more probable that the sulphated polysaccharides were interfering with the passaging of tumour cells across the capillary wall as heparin significantly inhibited metastasis when injected up to 3 hr after lodgement, and heparin and fucoidan caused a gradual loss of tumour cells from the lung which only became apparent greater than 1 hr following cell lodgement. The data did not eliminate the possibility that tumour cell adhesion to the endothelium occurred via sulphated polysaccharide recognition. A negative correlation existed between the sulphated polysaccharides that bound to the surface of the tumour cells and those that inhibited metastasis.

Fractionation of detergent lysates of cells by ammonium sulphate-induced phase separation

A procedure is described for fractionating detergent lysates of cells based on the ability of (NH4)2SO4 to induce phase separation of detergents such as Triton X-100, sodium deoxycholate, and sodium cholate, into detergent-rich and detergent-depleted phases. An analysis of six murine lymphocyte cell surface molecules revealed that the partitioning in Triton X-100 of each molecule was highly dependent upon the (NH4)2SO4 concentration, each antigen partitioning into the detergent-rich phase at a defined salt concentration. In contrast, none of the six molecules appeared in the detergent-rich phase of a Triton X-114 phase separation, even though two of the molecules, namely Ly-2/3 and L3T4, are well-characterized integral membrane proteins. It was also observed that (NH4)2SO4 resulted in the partitioning of many nonmembrane proteins into the detergent-rich phase, indicating that the procedure can be used to fractionate all cellular proteins. By judicious choice of (NH4)2SO4 concentrations, precipitation of cellular proteins at two different (NH4)2SO4 concentrations, and combining the method with subcellular fractionation prior to detergent solubilization, substantial enrichment and concentration of particular cellular proteins could be achieved.

Cell surface receptors for sulphated polysaccharides: a potential marker for macrophage subsets

The expression of a diverse array of receptors for sulphated polysaccharides on lymphocytes has been demonstrated by Parish & Snowden (1985). This paper presents evidence to suggest that other cell types, namely macrophages, polymorphonuclear leucocytes, mast cells and fibroblasts, can bind similar polysaccharides. Using a rosetting assay and eleven structurally unique polysaccharides, each cell type was observed to bind a characteristic array of these polysaccharides. Analysis of the polysaccharide reactivity of macrophages revealed that BCG-activated and thioglycollate-elicited macrophages express an expanded repertoire of reactivity compared to resident peritoneal macrophages. For example, only thioglycollate-elicited macrophages, but not resident and BCG-activated peritoneal macrophages, reacted with the glycosaminoglycans, chondroitin-4-sulphate, chondroitin-6-sulphate and dermatan sulphate, while both BCG- and thioglycolate-activated, but not resident peritoneal macrophages, bound pentosan polysulphate-coupled sheep erythrocytes. The expression of the receptors for chondroitin-4 and -6-sulphate was observed to be cyclic and peaked at 2 and 5-6 days after thioglycollate treatment. Preliminary analyses of the functional significance of the observed binding of polysaccharides to macrophages revealed that heparin, fucoidan and kappa-carrageenen were specifically endocytosed. However, endocytosis of all other test polysaccharides was not observed. Finally, polysaccharide-coupled sheep erythrocytes were not phagocytosed, even though they interacted strongly with the macrophage surface. The possible relevance of these observations to an inflammatory response and as a means of identifying cellular subsets is discussed.

Modification of lymphocyte migration by sulfated polysaccharides

The role of sulfated polysaccharides in lymphocyte migration has been analyzed in vivo using lymphocytes labeled with an intracellular DNA-binding fluorochrome Hoechst 33342. The influence of a panel of sulfated polysaccharides on entry (by injecting the sulfated polysaccharide prior to the labeled cells) and displacement from lymphoid organs (by injecting the sulfated polysaccharide after the labeled cells have localized) indicated that different sulfated polysaccharides have selective effects on entry and displacement, and furthermore positioning of subpopulations within organs. Additional experiments suggested that receptors for sulfated polysaccharides on high endothelial venules may interact with complementary structures on lymphocytes. The data supporting this conclusion were: (a) the normal localization behavior of lymphocytes preincubated with sulfated polysaccharides; (b) an inverse relationship between the expression of lymphocyte surface receptors for sulfated polysaccharides and the ability of the lymphocytes to enter lymphoid organs and (c) the selective binding of sulfated polysaccharide-coupled fluoresceinated beads to high endothelial venules. In this case only the beads coupled with the sulfated polysaccharides that inhibited entry bound to the high endothelial venules. These findings are discussed in terms of a fundamental cellular recognition system utilizing sulfated polysaccharides.

Binding sites for glycosaminoglycans on developing sympathetic neurones

Recent studies have suggested that cell to cell communication in the immune system is mediated by cell surface receptors for glycosaminoglycans (GAGs) [Parish et al, 1984]. The intention of this study was to see whether similar recognition molecules for GAGs are present on sympathetic neurones. A mechanical dissociation technique was used to isolate neurones from superior cervical ganglia (SCG) of rats aged between gestational day 19 and postnatal day 21. Receptors for GAGs on sympathetic neurones were detected by the ability of neurones to form rosettes with sheep red blood cells coupled with one of 12 different GAGs. It was found that SCG cells bind to all the GAGs tested. In addition, a range of developmental binding patterns for the various GAGs was found.

Topographical studies of lymphocyte localization using an intracellular fluorochrome

A procedure for analysing the topographical localization in tissue sections or whole-organ mounts of lymphocytes labelled with an intracellular DNA-binding fluorochrome, Hoechst dye No. 33342, is described. The localization of intravenously injected lymphocytes in spleen, popliteal lymph nodes, and Peyer's patches was followed up to 7 days. In the case of spleen, both B and T lymphocytes initially localised in the marginal zone. Subsequently, B cells appeared to exit via the red pulp, while T cells aggregated around vessels in the white pulp. In Peyer's patches, B and T lymphocytes localized to different lymphoid areas. The advantages and potential applications of this technique are discussed.