From earlier work it is known that folic acid attracts the amoebae of various species of cellular slime molds (11). Here we have tested a wide variety of pteridines, pyrimidines, and pyrazines to determine what part of the folic acid molecule is chemotactically active. It was shown that the activity lies in the pteridine ring itself. Furthermore, the cell-free supernatants of slime mold amoebae contain an enzyme that renders pterin and folic acid chemotactically inactive, which apparently increases the chemotactic sensitivity of the amoebae to those compounds. Despite the fact that slime mold amoebae secrete small amounts of folic acid-related compounds, there is no evidence that folates are acrasins; rather it is postulated that attraction to folates may be a food-seeking device for the amoebae which prey on folate-secreting bacteria in the soil.
Leukocytes use urokinase receptors (uPAR; CD87) in adhesion, migration, and proteolysis of matrix proteins. Typically, uPAR clusters at cell-substratum interfaces, at focal adhesions, and at the leading edges of migrating cells. This study was undertaken to determine whether uPAR clustering mediates activation signaling in human polymorphonuclear neutrophils. Cells were labeled with fluo-3/AM to quantitate intracellular Ca2+ ([Ca2+]i) by spectrofluorometry, and uPAR was aggregated by Ab cross-linking. Aggregating uPAR induced a highly reproducible increase in [Ca2+]i (baseline to peak) of 295 ± 37 nM (p = 0.0002). Acutely treating cells with high m.w. urokinase (HMW-uPA; 4000 IU/ml) produced a response of similar magnitude but far shorter duration. Selectively aggregating uPA-occupied uPAR produced smaller increases in [Ca2+]i, but saturating uPAR with HMW-uPA increased the response to approximate that of uPAR cross-linking. Cross-linking uPAR induced rapid and significant increases in membrane expression of CD11b and increased degranulation (release of β-glucuronidase and lactoferrin) to a significantly greater degree than cross-linking control Abs. The magnitude of degranulation correlated closely with the difference between baseline and peak [Ca2+]i, but was not dependent on the state of uPA occupancy. By contrast, selectively cross-linking uPA-occupied uPAR was capable of directly inducing superoxide release as well as enhancing FMLP-stimulated superoxide release. These results could not be duplicated by preferentially cross-linking unoccupied uPAR. We conclude that uPAR aggregation initiates activation signaling in polymorphonuclear neutrophils through at least two distinct uPA-dependent and uPA-independent pathways, increasing their proinflammatory potency (degranulation and oxidant release) and altering expression of CD11b/CD18 to favor a firmly adherent phenotype.
Leukocyte urokinase plasminogen activator receptors (uPARs) cluster at adhesion interfaces and at migratory fronts where they participate in adhesion, chemotaxis, and proteolysis. uPAR aggregation triggers activation signaling even though this glycolipid-anchored protein must associate with membrane-spanning proteins to access the cell interior. This study demonstrates a novel partnership between uPAR and L-selectin in human polymorphonuclear neutrophils. Fluorescence resonance energy transfer demonstrated a direct physical association between uPAR and L-selectin. To examine the role of L-selectin in uPAR-mediated signaling, uPAR was cross-linked and intracellular Ca2+ concentrations were measured by spectrofluorometry. A mAb reactive against the carbohydrate binding domain (CBD) of L-selectin substantially inhibited uPAR-mediated Ca2+ mobilization, whereas mAbs against the β2 integrin complement receptor 3 (CR3), another uPAR-binding adhesion protein, had no effect. Similarly, fucoidan, a sulfated polysaccharide that binds to L-selectin CBD, inhibited the Ca2+ signal. We conclude that uPAR associates with the CBD region of L-selectin to form a functional signaling complex.
Urokinase plasminogen activator (uPA) receptors (uPAR) can be engaged for activation signaling either by aggregation or by binding exogenous uPA. These signaling mechanisms require uPAR to associate with two distinct adhesion proteins, L-selectin and complement receptor 3 (CR3), respectively. uPAR contains a glycosylphosphatidylinositol anchor, suggesting that it is concentrated within glycosphingolipid-enriched microdomains, or "lipid rafts". This study was undertaken to determine the extent to which uPAR-mediated signaling is compartmentalized to lipid rafts. Human neutrophil uPAR was cross-linked or stimulated with uPA after pretreatment with the lipid raft-disrupting agents, methyl-beta-cyclodextrin or filipin III. Both agents suppressed increases in intracellular Ca(2+) concentrations ([Ca(2+)](i)) triggered by cross-linking, but did not affect [Ca(2+) ](i) in response to uPA. Neutrophil membranes were separated into lipid raft and non-raft fractions, revealing the presence of uPAR and L-selectin, but the virtual absence of CR3 alpha chain in lipid rafts, either constitutively or in response to uPAR aggregation. Fluorescence resonance energy transfer experiments confirmed close proximity of a lipid raft marker to both uPAR and L-selectin, but not CR3. We conclude that uPAR can engage distinct signaling pathways involving different partner proteins that are functionally and physically segregated from one another in both lipid raft and non-raft domains of the plasma membrane.
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