Polymorphonuclear leucocyte chemotaxis: detection of the gradient and development of cell polarity

The ability of polymorphonuclear leucocytes to respond to a chemical gradient has been examined by observing their behaviour in response to the peptide N-formylnorleucylleucylphenylalanine (f-NorleuLeuPhe). The cells appear to detect the direction of the chemical gradient by sensing differences in the number of their chemotactic receptors that are bound acroos their dimensions. When moving, a PMN has a polarized form with ruffles or pseudopods at the front and a knob-like tail at the rear. The potential for forming new pseudopods appears to exist in a gradient from anterior to posterior along the cell axis. Rapidly increasing the concentration of peptide can transiently induce the formation of ruffles over most of the cell surface except the tail. The presence of transient reversible responses to increases in the chemotactic factor suggests that with time the leucocyte adapts to the concentration of peptide to which it is exposed. A simple model which describes the cell polarity and adaptation is presented.

Chemotaxis assays for eukaryotic cells

Chemotaxis is a complex response of a cell to an external stimulus. It involves detecting and measuring the concentration of the chemoattractant, biochemical transmission of the information, and the motility and adhesive changes associated with the response. This unit describes a number of chemotaxis assays that can be used to identify chemoattractants individually and in large-scale screenings, to distinguish chemotaxis from chemokinesis, and to analyze cellular behavioral and biochemical responses. Some of these assays such as the filter, under agarose, and small population assays, can be used to monitor the behavior of large groups of cells; the bridge, pipet, and upshift assays can be used to analyze the responses of single cells.

Cdc42-induced actin filaments are protected from capping protein

Each actin filament has a pointed and a barbed end, however, filament elongation occurs primarily at the barbed end. Capping proteins, by binding to the barbed end, can terminate this elongation. The rate of capping depends on the concentration of capping protein [1], and thus, if capping terminates elongation, the length of filaments should vary inversely with the concentration of capping protein. In cell extracts, such as those derived from neutrophils, new actin filaments can be nucleated by addition of GTPgammaS-activated Cdc42 (a small GTPase of the Rho family). To determine whether elongation of these filaments is terminated by capping, we manipulated the concentration of capping protein, the major calcium-independent capping protein in neutrophils, and observed the effects on filament lengths. Depletion of 70% of the capping protein from extracts increased the mean length of filaments elongated from spectrin-actin seeds (very short actin filaments with free barbed ends) but did not increase the mean length of filaments induced by Cdc42. Furthermore, doubling the concentration of capping protein in cell extracts by adding pure capping protein did not decrease the mean length of filaments induced by Cdc42. These results suggest that the barbed ends of Cdc42-induced filaments are protected from capping by capping protein.

Actin polymerization: Where the WASP stings

How do extracellular signals induce actin polymerization, as required for many cellular responses? Key signal transducers, such as the small GTPases Cdc42 and Rac, have now been shown to link via proteins of the WASP family to the Arp2/3 complex, which nucleates actin polymerization.

Actin cytoskeleton: the Arp2/3 complex gets to the point

Actin filament polymerization results primarily from the addition of monomers to pre-existing filaments. Recent studies have revealed that the Arp2/3 protein complex, which includes two actin-related proteins, can nucleate new actin filaments, and this capacity can be enhanced by ActA, a protein used by Listeria to polymerize actin.

Mechanism of Cdc42-induced actin polymerization in neutrophil extracts

Cdc42, activated with GTPgammaS, induces actin polymerization in supernatants of lysed neutrophils. This polymerization, like that induced by agonists, requires elongation at filament barbed ends. To determine if creation of free barbed ends was sufficient to induce actin polymerization, free barbed ends in the form of spectrin-actin seeds or sheared F-actin filaments were added to cell supernatants. Neither induced polymerization. Furthermore, the presence of spectrin-actin seeds did not increase the rate of Cdc42-induced polymerization, suggesting that the presence of Cdc42 did not facilitate polymerization from spectrin-actin seeds such as might have been the case if Cdc42 inhibited capping or released G-actin from a sequestered pool. Electron microscopy revealed that Cdc42-induced filaments elongated rapidly, achieving a mean length greater than 1 micron in 15 s. The mean length of filaments formed from spectrin-actin seeds was <0.4 micron. Had spectrin-actin seeds elongated at comparable rates before they were capped, they would have induced longer filaments. There was little change in mean length of Cdc42-induced filaments between 15 s and 5 min, suggesting that the increase in F-actin over this time was due to an increase in filament number. These data suggest that Cdc42 induction of actin polymerization requires both creation of free barbed ends and facilitated elongation at these ends.

Regulation of actin polymerization in cell-free systems by GTPgammaS and Cdc42

We have established a cell-free system to investigate pathways that regulate actin polymerization. Addition of GTPgammaS to lysates of polymorphonuclear leukocytes (PMNs) or Dictyostelium discoideum amoeba induced formation of filamentous actin. The GTPgammaS appeared to act via a small G-protein, since it was active in lysates ofD. discoideum mutants missing either the alpha2- or beta-subunit of the heterotrimeric G-protein required for chemoattractant-induced actin polymerization in living cells. Furthermore, recombinant Cdc42, but not Rho or Rac, induced polymerization in the cell-free system. The Cdc42-induced increase in filamentous actin required GTPgammaS binding and was inhibited by a fragment of the enzyme PAK1 that binds Cdc42. In a high speed supernatant, GTPgammaS alone was ineffective, but GTPgammaS-loaded Cdc42 induced actin polymerization, suggesting that the response was limited by guanine nucleotide exchange. Stimulating exchange by chelating magnesium, by adding acidic phospholipids, or by adding the exchange factors Cdc24 or Dbl restored the ability of GTPgammaS to induce polymerization. The stimulation of actin polymerization did not correlate with PIP2 synthesis.

Signal transduction and actin filament organization

Small GTP-binding proteins of the Rho family appear to integrate extracellular signals from diverse receptor types and initiate rearrangements of F-actin. Active members of the Rho family, Rho and Rac, are now joined by Cdc42 which induces filopodia. Downstream of the Rho family proteins, actin polymerization may be induced by an increase in the availability of actin filament barbed ends. Actin organization may be affected by exposure of actin-binding sites on proteins such as vinculin and ezrin.

Actin filament barbed-end capping activity in neutrophil lysates: the role of capping protein-beta 2

A barbed-end capping activity was found in high speed supernates of neutrophils lysed in submicromolar calcium. In dilute supernate (> or = 100-fold dilution of cytoplasm), this activity accounted for most of the inhibition of barbed-end elongation of pyrenyl-G-actin from spectrin-F-actin seeds. Pointed-end elongation from gelsolin-capped F-actin seeds was not inhibited at comparable concentrations of supernate, thus excluding actin monomer sequestration as a cause of the observed inhibition. Most of the capping activity was due to capping protein-beta 2 (a homologue of cap Z). Thus, while immunoadsorption of > or = 95% of the gelsolin in the supernate did not decrease capping activity, immunoadsorption of capping protein-beta 2 reduced capping activity proportionally to the amount of capping protein-beta 2 adsorbed. Depletion of > 90% of capping protein-beta 2 from the supernate removed 90% of its capping activity. The functional properties of the capping activity were defined. The dissociation constant for binding to barbed ends (determined by steady state and kinetic analyses) was approximately 1-2 nM; the on-rate of capping was between 7 x 10(5) and 5 x 10(6) M-1 s-1; and the off-rate was approximately 2 x 10(-3) s-1. The concentration of capper free in the intact cell (determined by adsorption of supernate with spectrin-actin seeds) was estimated to be approximately 1-2 microM. Thus, there appeared to be enough high affinity capper to cap all the barbed ends in vivo. Nevertheless, immediately after lysis with detergent, neutrophils contained sites that nucleate barbed-end elongation of pyrenyl-G-actin. These barbed ends subsequently become capped with a time course and concentration dependence similar to that of spectrin-F-actin seeds in high speed supernates. These observations suggest that, despite the excess of high affinity capper, some ends either are not capped in vivo or are transiently uncapped upon lysis and dilution.

Actin polymerization induced by GTP gamma S in permeabilized neutrophils is induced and maintained by free barbed ends

To address the mechanisms through which agonists stimulate actin polymerization, we examined the roles of monomer sequestering proteins and free barbed ends on actin polymerization induced by guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) in neutrophils permeabilized with streptolysin O. Addition of profilin (without GTP gamma S) caused a net decrease in F-actin. Thus, merely making profilin available in the cell was not sufficient to induce actin polymerization. On the other hand, addition of profilin hardly affected the polymerization induced by GTP gamma S, while thymosin beta 4 or DNase I decreased this polymerization. These data suggested that GTP gamma S induced polymerization by increasing the availability of barbed ends. In the presence of cytochalasin B, profilin did inhibit polymerization induced by GTP gamma S, demonstrating that GTP gamma S did not inhibit profilin's monomer sequestering ability. The F-actin induced by GTP gamma S was not limited by a time-dependent loss of G-actin or G-proteins from permeabilized cells since, following stimulation with suboptimal concentrations of GTP gamma S, addition of more GTP gamma S induced further polymerization. Barbed ends remained free after F-actin reached plateau since (a) cytochalasin B caused depolymerization of induced F-actin and (b) profilin did not depolymerize induced F-actin unless the cells were first treated with cytochalasin to cap barbed ends. The data indicate that GTP gamma S maintains an increased level of F-actin by keeping at least a few barbed ends available for polymerization.

Induction of actin polymerization in permeabilized neutrophils. Role of ATP

We have used streptolysin-O (SO)-permeabilized neutrophils to investigate the signal transduction pathway through which chemoattractants induce actin polymerization. Chemoattractants stimulate phosphorylation of various proteins and lipids but whether these phosphorylations are required for actin polymerization is not known. Addition of guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) to SO-permeabilized neutrophils induced a doubling of the F-actin. This induction of F-actin, assayed by TRITC-labeled phalloidin binding, did not require the addition of ATP. Neither addition of apyrase to deplete residual ATP nor addition of ADP or UDP to compete with residual endogenous ATP inhibited significantly the GTP gamma S-induced polymerization. Addition of ATP on its own caused no increase in F-actin and did not affect the time course or concentration dependence of GTP gamma S-induced F-actin. Addition of ATP did increase the maximal amount of F-actin induced by GTP gamma S by about 20%. N-Formylnorleucylleucylphenalanine (formyl-peptide) in the presence of GTP, but not in its absence, also stimulated an increase in F-actin in SO-permeabilized cells. The F-actin induced by formyl-peptide plus GTP was inhibited by pertussis toxin. The induction did not require addition of ATP and addition of ADP to compete with residual ATP only slightly decreased the level of actin. However, addition of UDP significantly reduced the response to formyl-peptide plus GTP. Addition of ATP enhanced the increase in F-actin induced by optimal concentrations of GTP with formyl-peptide. ATP also lowered the apparent Km for GTP, but not for N-formyl peptide. The non-hydrolyzable ATP analog, adenosine 5'-(beta, gamma-imino)triphosphate, did not enhance the actin polymerization. Rather its presence inhibited the response induced by formyl-peptide plus GTP. The data suggest that actin polymerization can be induced by GTP gamma S in an manner that is largely ATP-independent. A role for ATP cannot be ruled out in the induction of actin polymerization by formyl-peptide plus GTP.

Distribution of F-actin elongation sites in lysed polymorphonuclear leukocytes parallels the distribution of endogenous F-actin

We compared, on lysed polymorphonuclear leukocytes (PMNs), the spatial distributions of sites that nucleate actin polymerization with the spatial distribution of endogenous F-actin. Sites nucleating polymerization of exogenous actin were detected by incubating lysed cells with rhodamine-labeled G-actin under polymerizing conditions. Endogenous F-actin was stabilized and stained by lysis of cells into fluorescein-labeled (FITC) phalloidin. We found the distributions of rhodamine and fluorescein intensities in a given cell, resting or stimulated with chemoattractant, to be similar. Thus, after lysis the number of sites able to nucleate actin polymerization is proportional to the local F-actin concentration. Quantitative fluorescence microscopic analysis also demonstrated that (1) if cells were stimulated with chemoattractant shortly before lysis, the total fluorescence per cell of both fluorophores went up; (2) if peptide was diluted shortly before lysis, the endogenous F-actin in the lamellae was dramatically reduced, but nucleation sites persisted, giving a high rhodamine to fluorescein ratio; and (3) there was a small increase in the ratio of rhodamine (exogenously grown actin) to fluorescein (endogenous F-actin) in a region near the lamellar/endoplasm border, centripetal to regions of the highest concentration of endogenous F-actin. The rhodamine signal appeared to be due to in situ actin polymerization probably nucleated by existing free barbed ends, since (1) the rhodamine signal increased linearly with time with no detectable lag if the actin concentration was above that of the critical concentration of the barbed end; (2) the rhodamine signal was dramatically reduced if lysates were incubated with gelsolin-actin complex (which stably caps barbed ends), then washed before the rhodamine G-actin was added; and (3) the number of nucleation sites at the time of lysis is similar to the number of the barbed ends of actin filaments determined by the kinetics of depolymerization [Cano et al., 1991]. The fact that the distribution of exogenous actin polymerization paralleled the endogenous F-actin suggests that the number of free barbed ends per F-actin is roughly constant. If all filament ends were free, or if a constant fraction of the filaments ends were free, these data would suggest that the mean filament length is roughly constant throughout the cell.

Recent quantitative studies of actin filament turnover during cell locomotion

Cell locomotion depends on polymerization and depolymerization of filamentous actin. Net polymerization at the cell front occurs fast enough to fill the extending lamellipod, and since total F-actin is essentially constant over time, depolymerization must equal polymerization. Indeed, the fastest moving cell types have the highest rates of depolymerization. Accounting for the high rate of depolymerization raises several problems. One is that net depolymerization requires the concentration of G-actin to be low (below the critical concentration), but rapid polymerization (occurring < 1 micron away) requires the concentration of G-actin to be high (well above the critical concentration). This may be accomplished by spatial compartmentalization of factors that favor polymerization or depolymerization, and/or by proteins that bind G-actin and prevent spontaneous polymerization while allowing barbed-end elongation. A second problem is that depolymerization proceeds faster than would seem possible from studies of F-actin in vitro (as calculated from number and lengths of filaments present and in vitro rate constants). Rapid depolymerization may be accomplished by filament cutters or by cytoplasmic components (as yet undiscovered) that increase the rate of depolymerization.

Thymosin beta 4 sequesters the majority of G-actin in resting human polymorphonuclear leukocytes

Thymosin beta 4 (T beta 4), a 5-kD peptide which binds G-actin and inhibits its polymerization (Safer, D., M. Elzinga, and V. T. Nachmias. 1991. J. Biol. Chem. 266:4029-4032), appears to be the major G-actin sequestering protein in human PMNs. In support of a previous study by Hannappel, E., and M. Van Kampen (1987. J. Chromatography. 397:279-285), we find that T beta 4 is an abundant peptide in these cells. By reverse phase HPLC of perchloric acid supernatants, human PMNs contain approximately 169 fg/cell +/- 90 fg/cell (SD), corresponding to a cytoplasmic concentration of approximately 149 +/- 80.5 microM. On non-denaturing polyacrylamide gels, a large fraction of G-actin in supernatants prepared from resting PMNs has a mobility similar to the G-actin/T beta 4 complex. Chemoattractant stimulation of PMNs results in a decrease in this G-actin/T beta 4 complex. To determine whether chemoattractant induced actin polymerization results from an inactivation of T beta 4, the G-actin sequestering activity of supernatants prepared from resting and chemoattractant stimulated cells was measured by comparing the rates of pyrenyl-actin polymerization from filament pointed ends. Pyrenyl actin polymerization was inhibited to a greater extent in supernatants from stimulated cells and these results are qualitatively consistent with T beta 4 being released as G-actin polymerizes, with no chemoattractant-induced change in its affinity for G-actin. The kinetics of bovine spleen T beta 4 binding to muscle pyrenyl G-actin are sufficiently rapid to accommodate the rapid changes in actin polymerization and depolymerization observed in vivo in response to chemoattractant addition and removal.

Inhibition of actin filament depolymerization by the Dictyostelium 30,000-D actin-bundling protein

We have studied the effect of the Dictyostelium discoideum 30,000-D actin-bundling protein on the assembly and disassembly of pyrenyl-labeled actin in vitro. The results indicate that the protein is a potent inhibitor of the rate of actin depolymerization. The inhibition is rapid, dose dependent, and is observed at both ends of the filament. There is little effect of 30-kD protein on the initial rate of elongation from F-actin seeds or on the spontaneous nucleation of actin polymerization. We could detect little or no effect on the critical concentration. The novel feature of these results is that the filament ends are free for assembly but are significantly impaired in disassembly with little change in the critical concentration at steady state. The effects appear to be largely independent of the cross-linking of actin filaments by the 30-kD protein. Actin cross-linking proteins may not only cross-link actin filaments, but may also differentially protect filaments in cells from disassembly and promote the formation of localized filament arrays with enhanced stability.

Mechanisms responsible for F-actin stabilization after lysis of polymorphonuclear leukocytes

While actin polymerization and depolymerization are both essential for cell movement, few studies have focused on actin depolymerization. In vivo, depolymerization can occur exceedingly rapidly and in a spatially defined manner: the F-actin in the lamellipodia depolymerizes in 30 s after chemoattractant removal (Cassimeris, L., H. McNeill, and S. H. Zigmond. 1990. J. Cell Biol. 110:1067-1075). To begin to understand the regulation of F-actin depolymerization, we have examined F-actin depolymerization in lysates of polymorphonuclear leukocytes (PMNs). Surprisingly, much of the cell F-actin, measured with a TRITC-phalloidin-binding assay, was stable after lysis in a physiological salt buffer (0.15 M KCl): approximately 50% of the F-actin did not depolymerize even after 18 h. This stable F-actin included lamellar F-actin which could still be visualized one hour after lysis by staining with TRITC-phalloidin and by EM. We investigated the basis for this stability. In lysates with cell concentrations greater than 10(7) cells/ml, sufficient globular actin (G-actin) was present to result in a net increase in F-actin. However, the F-actin stability was not solely because of the presence of free G-actin since addition of DNase I to the lysate did not increase the F-actin loss. Nor did it appear to be because of barbed end capping factors since cell lysates provided sites for barbed end polymerization of exogenous added actin. The stable F-actin existed in a macromolecular complex that pelleted at low gravitational forces. Increasing the salt concentration of the lysis buffer decreased the amount of F-actin that pelleted at low gravitational forces and increased the amount of F-actin that depolymerized. Various actin-binding and cross-linking proteins such as tropomyosin, alpha-actinin, and actin-binding protein pelleted with the stable F-actin. In addition, we found that alpha-actinin, a filament cross-linking protein, inhibited the rate of pyrenyl F-actin depolymerization. These results suggested that actin cross-linking proteins may contribute to the stability of cellular actin after lysis. The activity of crosslinkers may be regulated in vivo to allow rapid turnover of lamellipodia F-actin.

Characterization of tetramethylrhodaminyl-phalloidin binding to cellular F-actin

Fluorescent derivatives of phalloidin are widely used to measure filamentous actin (F-actin) levels and to stabilize F-actin. We have characterized the kinetics and affinity of binding of tetramethylrhodaminyl (TRITC)-phalloidin to rabbit skeletal muscle F-actin and to F-actin in lysates of rabbit polymorphonuclear leukocytes (PMNs). We have defined conditions where TRITC-phalloidin can be used to inhibit F-actin depolymerization and to quantify F-actin without prior fixation. By equilibrium measurements, the affinity of TRITC-phalloidin binding to rabbit skeletal muscle F-actin (pyrene labeled) or to PMN lysate F-actin was 1-4 x 10(-7) M. In both cases, the stoichiometry of binding was approximately 1:1. Kinetic measurements of TRITC-phalloidin binding to PMN lysate F-actin resulted in an association rate constant of 420 +/- 120 M-1 sec-1 and a dissociation rate constant of 8.3 +/- 0.9 x 10(-5) sec-1. The affinity calculated from the kinetic measurements (2 +/- 1 x 10(-7) M) agreed well with that obtained by equilibrium measurements. The rate with which 0.6 microM TRITC-phalloidin inhibited 0.1 microM pyrenyl F-actin depolymerization (90% inhibition in 10 sec) was much faster than the rate of binding to pyrenyl F-actin (less than 1% bound in 10 sec), suggesting that phalloidin binds to filament ends more rapidly than to the rest of the filament. We show that TRITC-phalloidin can be used to measure F-actin levels in cell lysates when G-actin is also present (i.e., in cell lysates at high concentrations) if DNase I is included to prevent phalloidin-induced polymerization.

Kinetic analysis of F-actin depolymerization in polymorphonuclear leukocyte lysates indicates that chemoattractant stimulation increases actin filament number without altering the filament length distribution

The rate of filamentous actin (F-actin) depolymerization is proportional to the number of filaments depolarizing and changes in the rate are proportional to changes in filament number. To determine the number and length of actin filaments in polymorphonuclear leukocytes and the change in filament number and length that occurs during the increase in F-actin upon chemoattractant stimulation, the time course of cellular F-actin depolymerization in lysates of control and peptide-stimulated cells was examined. F-actin was quantified by the TRITC-labeled phalloidin staining of pelletable actin. Lysis in 1.2 M KCl and 10 microM DNase I minimized the effects of F-actin binding proteins and G-actin, respectively, on the kinetics of depolymerization. To determine filament number and length from a depolymerization time course, depolymerization kinetics must be limited by the actin monomer dissociation rate. Comparison of time courses of depolymerization in the presence (pointed ends free) or absence (barbed and pointed ends free) of cytochalasin suggested depolymerization occurred from both ends of the filament and that monomer dissociation was rate limiting. Control cells had 1.7 +/- 0.4 x 10(5) filaments with an average length of 0.29 +/- 0.09 microns. Chemo-attractant stimulation for 90 s at room temperature with 0.02 microM N-formylnorleucylleucylphenylalanine caused a twofold increase in F-actin and about a two-fold increase in the total number of actin filaments to 4.0 +/- 0.5 x 10(5) filaments with an average length of 0.27 +/- 0.07 microns. In both cases, most (approximately 80%) of the filaments were quite short (less than or equal to 0.18 micron). The length distributions of actin filaments in stimulated and control cells were similar.

CD45 is not involved in the processing of spatial information required for chemotaxis

To examine the possible role of CD45 (a cell surface tyrosine phosphatase) in processing spatial information leading to the orientation of neutrophils in a gradient of chemoattractant, we used antibodies to cap CD45. If the phosphatase activity of CD45 was processing spatial information coming from occupied receptors and leading to the directional cell response, sequestering CD45 in one region of the cell surface should lead to a decreased ability of the cells to orient in a gradient of chemoattractant. CD45 was capped by sequential addition of KC56, a mAb against CD45, and a rabbit anti-mouse antiserum. Cells with capped CD45 were able to orient toward N-formylnorleucylleucylphenylalanine and C5a at levels similar to those achieved by cells processed simultaneously but without capping CD45. This indicates that the spatial arrangement of CD45 is not critical for the ability of cells to orient in a gradient of chemoattractant.

CD45 is not involved in the processing of spatial information required for chemotaxis

To examine the possible role of CD45 (a cell surface tyrosine phosphatase) in processing spatial information leading to the orientation of neutrophils in a gradient of chemoattractant, we used antibodies to cap CD45. If the phosphatase activity of CD45 was processing spatial information coming from occupied receptors and leading to the directional cell response, sequestering CD45 in one region of the cell surface should lead to a decreased ability of the cells to orient in a gradient of chemoattractant. CD45 was capped by sequential addition of KC56, a mAb against CD45, and a rabbit anti-mouse antiserum. Cells with capped CD45 were able to orient toward N-formylnorleucylleucylphenylalanine and C5a at levels similar to those achieved by cells processed simultaneously but without capping CD45. This indicates that the spatial arrangement of CD45 is not critical for the ability of cells to orient in a gradient of chemoattractant.

Binding of IgG containing immune complexes to human neutrophil Fc gamma RII and Fc gamma RIII induces actin polymerization by a pertussis toxin-insensitive transduction pathway

The ability of a phagocytic stimulus, rabbit IgG anti-BSA/BSA immune complexes, to increase the F-actin content of human polymorphonuclear leukocytes was quantitated by flow cytometry following staining with nitrobenzoxadiazole-phallacidin. A significant rise in F-actin assembly was induced by addition of 5 micrograms/ml immune complex. Concentrations of immune complex of more than 200 micrograms/ml caused a maximal (approximately twofold) increase in F-actin content. After a delay of 5 s, the F-actin levels rose and reached maximum levels by 60 s after adding immune complexes. The twofold elevation in F-actin persisted for up to 60 min. Both anti-Fc gamma RII and anti-Fc gamma RIII mAb blocked immune complex stimulated actin polymerization. Exposure to pertussis toxin failed to affect the rate or extent of immune complex-induced actin polymerization. Cells incubated with immune complexes and then lysed with Triton had an increased number of sites able to nucleate actin polymerization. These findings suggest that immune complex binding to both polymorphonuclear leukocytes Fc gamma RII and Fc gamma RIII is required for actin filament assembly and that the induction of assembly occurs via transduction pathways that differ from those used by chemoattractants. As with adhesion this phagocytic stimulus induces actin assembly by a pertussis toxin insensitive pathway and produces a rise in actin filament content that persists for prolonged periods of time.

Binding of IgG containing immune complexes to human neutrophil Fc gamma RII and Fc gamma RIII induces actin polymerization by a pertussis toxin-insensitive transduction pathway

The ability of a phagocytic stimulus, rabbit IgG anti-BSA/BSA immune complexes, to increase the F-actin content of human polymorphonuclear leukocytes was quantitated by flow cytometry following staining with nitrobenzoxadiazole-phallacidin. A significant rise in F-actin assembly was induced by addition of 5 micrograms/ml immune complex. Concentrations of immune complex of more than 200 micrograms/ml caused a maximal (approximately twofold) increase in F-actin content. After a delay of 5 s, the F-actin levels rose and reached maximum levels by 60 s after adding immune complexes. The twofold elevation in F-actin persisted for up to 60 min. Both anti-Fc gamma RII and anti-Fc gamma RIII mAb blocked immune complex stimulated actin polymerization. Exposure to pertussis toxin failed to affect the rate or extent of immune complex-induced actin polymerization. Cells incubated with immune complexes and then lysed with Triton had an increased number of sites able to nucleate actin polymerization. These findings suggest that immune complex binding to both polymorphonuclear leukocytes Fc gamma RII and Fc gamma RIII is required for actin filament assembly and that the induction of assembly occurs via transduction pathways that differ from those used by chemoattractants. As with adhesion this phagocytic stimulus induces actin assembly by a pertussis toxin insensitive pathway and produces a rise in actin filament content that persists for prolonged periods of time.

Chemoattractant stimulation of polymorphonuclear leucocyte locomotion

Chemoattractants stimulate both cell locomotion and the orientation of this locomotion (chemotaxis) in polymorphonuclear leukocytes. Cell locomotion is a complex process which includes the coordinated protrusion of cell processes, formation of attachments to the substrate and contraction of the rear of the cell. To understand how chemoattractants regulate this process, it is helpful to dissect the process into components that can be examined separately. Comparison of these components in cells before and after stimulation with chemoattractant provides information about their regulation. In this review we focus on three components: how chemoattractants induce the development of cell polarity; how chemoattractants modulate cytoskeletal components (especially actin) to cause pseudopod protrusion; and how chemoattractant modulation of cell adhesions might contribute to cell locomotion. Spatial and temporal coordination of these and other components of locomotion result in efficient and directed cell movement. Our treatment of these questions is speculative and not comprehensive. We propose simple hypothetical models which can provide the reader with a conceptual framework that integrates the information available.

Chemoattractant-stimulated polymorphonuclear leukocytes contain two populations of actin filaments that differ in their spatial distributions and relative stabilities

Chemoattractants stimulate actin polymerization in lamellipodia of polymorphonuclear leukocytes. We find that removal of chemoattractant results in rapid (within 10 s at 37 degrees C) and selective depolymerization of the F-actin located in lamellipodia. Addition of 10 microM cytochalasin B, in the presence of chemoattractant, also resulted in rapid and selective depolymerization of lamellar F-actin. The elevated F-actin level induced by chemoattractant rapidly returns to the level present in unstimulated cells after (a) a 10-fold decrease in chemoattractant concentration; (b) the addition of 10 microM cytochalasin B; or (c) cooling to 4 degrees C. The F-actin levels of unstimulated cells are only slightly affected by these treatments. Based on the similar effects of cytochalasin addition and chemoattractant dilution, it is likely that both treatments result in actin depolymerization from the pointed ends of filaments. Based on our results we propose that chemoattractant-stimulated polymorphonuclear leukocytes contain two distinct populations of actin filaments. The actin filaments within the lamellipodia are highly labile and in the continued presence of chemoattractant these filaments are rapidly turning over, continually polymerizing at their plus (barbed) ends, and depolymerizing at their minus ends. In contrast, the cortical F-actin filaments of both stimulated and unstimulated cells are differentially stable.

Polymorphonuclear leukocyte adherence induces actin polymerization by a transduction pathway which differs from that used by chemoattractants

Nitrobenzoxadiazole-phallacidin in combination with quantitative fluorescent microscopy have been used to measure F-actin concentrations in human polymorphonuclear leukocytes (PMN) as they adhere to a plastic surface. Like stimulation with chemoattractants, adherence is associated with a twofold rise in F-actin content. However unlike the rapid rise in F-actin induced by chemoattractants which peaks within 30 s, actin assembly induced by adherence is slower, maximum F-actin values not being observed until 10 min. Furthermore the rise in F-actin induced by adherence is persistent, remaining constant over 60 min while F-actin returns to near basal levels after 20 min exposure to chemoattractant. The combination of adherence (5 min) followed by chemoattractant (FMLP 5 x 10(-8) M for 40 s) resulted in an additive rise in F-actin content to greater than threefold over unstimulated values. Unlike chemoattractant induced actin assembly, adherence-associated PMN actin polymerization was not inhibited by pertussis toxin, but was markedly reduced by lowering extracellular Ca2+. Fluorescent micrographs of adherent PMN stained with nitrobenzoxadiazole-phallacidin revealed F-actin in the lamellipodia and in small foci on the adherent surface. These findings suggest that the transduction mechanisms by which adherence induces PMN actin polymerization differ from those used by chemoattractant receptors.

Measurement of leukocyte motility and chemotaxis parameters with the Millipore filter assay

Although in vitro assays have been widely used to study leukocyte chemotactic migration, finding the best way to quantitate these assays has proven to be an elusive goal. Investigators have usually resorted to reporting quantities such as the leading front distance, total migrating cells or number of cells past a given distance from their starting point. While these measures may often provide a valid comparison of cell migration under specific assay conditions, they also reflect physical characteristics of the assay that are irrelevant to the basic phenomenon of interest; thus, typical quantities measured in the assay are not useful for comparison between different systems or for correlation with in vivo performance. Recently, however, Tranquillo et al. (1988) demonstrated the utility of an analysis of the under-agarose assay in which the density profile of migrating cells is characterized in terms of two parameters: the random motility coefficient, mu, and the chemotaxis coefficient, chi. These parameters do reflect intrinsic cell movement independently of extraneous physical conditions. The analysis relies primarily on matching theoretical cell density profiles, calculated from a mathematical model in which mu and chi appear, to cell density profiles measured experimentally in the assay. In this paper, we extend the work of Tranquillo et al. to show that the same model can be applied successfully to the Millipore filter assay. In addition, we present measured values of mu and chi for rabbit polymorphonuclear leukocytes (PMNs) in response to, and as a function of the concentration of, the peptide attractant formyl-norleucyl-leucyl-phenylalanine (FNLLP). We also examine the relationship between results obtained for the filter assay and the under-agarose assay and consider the mechanistic basis of the parameters mu and chi.

Chemoattractant-stimulated GTPase activity is decreased on membranes from polymorphonuclear leukocytes incubated in chemoattractant

Polymorphonuclear leukocytes, PMNs, incubated in a chemoattractant undergo a time-dependent decrease in responsiveness to the chemoattractant; i.e. they desensitize or adapt. We have examined the role of ligand-induced changes at early steps in signal transduction for adaptation of PMNs to chemoattractants. The chemoattractant stimulation of a pertussis toxin-sensitive GTPase activity on PMN membranes was used as an assay of signal transduction. We find a decreased basal GTPase activity and a decrease in the ability of N-formylnorleucylleucylphenylalanine (FN-LLP) to stimulate this activity on membranes prepared from PMNs incubated with the chemotactic peptide FNLLP. The basal GTPase activity is decreased by up to 70% and the peptide-stimulated GTPase activity by up to 95% on membranes from PMNs incubated for 20 min at 37 degrees C in 10(-7) M FNLLP. The decrease in peptide-stimulated GTPase activity cannot be accounted for by the decreased number of FNLLP receptors on the membranes. Rather, receptors that remain available for binding stimulate the GTPase activity with a decreased efficiency. The ligand-induced change in GTPase activity is not stimulus specific. GTPase activity stimulated by both C5a and LTB4 was decreased on membranes from PMNs incubated in FNLLP. The decrease in chemoattractant-stimulated GTPase activity is partially reversed if cells are subsequently incubated at 37 degrees C in the absence of peptide prior to membrane preparation. We detected no quantitative or qualitative change in either pertussis toxin substrates or immunoreactive G proteins when membranes from control and FNLLP-treated cells were compared.

A stochastic model for leukocyte random motility and chemotaxis based on receptor binding fluctuations

Two central features of polymorphonuclear leukocyte chemosensory movement behavior demand fundamental theoretical understanding. In uniform concentrations of chemoattractant, these cells exhibit a persistent random walk, with a characteristic "persistence time" between significant changes in direction. In chemoattractant concentration gradients, they demonstrate a biased random walk, with an "orientation bias" characterizing the fraction of cells moving up the gradient. A coherent picture of cell movement responses to chemoattractant requires that both the persistence time and the orientation bias be explained within a unifying framework. In this paper, we offer the possibility that "noise" in the cellular signal perception/response mechanism can simultaneously account for these two key phenomena. In particular, we develop a stochastic mathematical model for cell locomotion based on kinetic fluctuations in chemoattractant/receptor binding. This model can simulate cell paths similar to those observed experimentally, under conditions of uniform chemoattractant concentrations as well as chemoattractant concentration gradients. Furthermore, this model can quantitatively predict both cell persistence time and dependence of orientation bias on gradient size. Thus, the concept of signal "noise" can quantitatively unify the major characteristics of leukocyte random motility and chemotaxis. The same level of noise large enough to account for the observed frequency of turning in uniform environments is simultaneously small enough to allow for the observed degree of directional bias in gradients.

Polymorphonuclear leukocyte locomotion is insensitive to lowered cytoplasmic calcium levels

Chemotactic factors stimulate the rate of locomotion of polymorphonuclear leukocytes (PMNs). To investigate the importance of cytoplasmic calcium we have examined the ability of the chemotactic peptide N-formylnorleucyl eucylphenalanine (FNLLP) to stimulate the locomotion of PMNs whose cytoplasmic calcium levels were reduced by incubation in EGTA or in EGTA plus the calcium ionophores, ionomycin or A23187. Locomotion was assayed by migration through micropore filters and by time-lapse videomicroscopy. Cells in EGTA exhibited similar or slightly reduced rates of locomotion compared to cells in Hanks' balanced salt solution (HBSS). The peptide dose dependence for the stimulation of locomotion was similar in medium containing calcium or EGTA. The presence of 1 microM ionophore plus EGTA had no effect on the stimulation of locomotion by peptide. The presence of ionophores (1 microM) plus external calcium inhibited locomotion.

Measurement of the chemotaxis coefficient for human neutrophils in the under-agarose migration assay

Clinical and scientific investigations of leukocyte chemotaxis will be greatly aided by an ability to measure quantitative parameters characterizing the intrinsic random motility, chemokinetic, and chemotactic properties of cell populations responding to a given attractant. Quantities typically used at present, such as leading front distances, migrating cell numbers, etc., are unsatisfactory in this regard because their values are affected by many aspects of the assay system unrelated to cell behavioral properties. In this paper we demonstrate the measurement of cell migration parameters that do, in fact, characterize the intrinsic cell chemosensory movement responses using cell density profiles obtained in the linear under-agarose assay. These parameters are the random motility coefficient, mu, and the chemotaxis coefficient, chi, which appear in a theoretical expression for cell population migration. We propose a priori the dependence of chi on attractant concentration, based on an independent experimental correlation of individual cell orientation bias in an attractant gradient with a spatial difference in receptor occupancy. Our under-agarose population migration results are consistent with this proposition, allowing chemotaxis to be reliably characterized by a chemotactic sensitivity constant, chi 0, to which chi is directly proportional. Further, chi 0 has fundamental significance; it represents the reciprocal of the difference in number of bound receptors across cell dimensions required for directional orientation bias. In particular, for the system of human peripheral blood polymorphonuclear neutrophil leukocytes responding to FNLLP, we find that the chemotaxis coefficient is a function of attractant concentration, a following the expression: chi = chi 0NT0 f(a) S(a) Kd/(Kd + a)2 where Kd is the FNLLP-receptor equilibrium dissociation constant and NT0 is the total number of cell surface receptors for FNLLP. f(a) is the fraction of surface receptors remaining after down-regulation, and S(a) is the cell movement speed, both known functions of FNLLP concentration. We find that chi 0NT0 = 0.2 cm; according to a theoretical argument outlined in the Appendix this means that these cells exhibit 75% orientation toward higher attractant concentration when the absolute spatial difference in bound receptors is 0.0025NT0 over 10 micron. (For example, if NT0 = 50,000 this would correspond to a spatial difference of 125 bound receptors over 10 micron.) This result can be compared with estimates obtained from visual studies of individual neutrophils.

An actin-nucleating activity in polymorphonuclear leukocytes is modulated by chemotactic peptides

We examined the actin-nucleating activity in polymorphonuclear leukocyte lysates prepared at various times after chemotactic peptide addition. The actin nucleation increases two- to threefold within 15 s after peptide addition, decays to basal levels within 90 s, and is largely independent of cytoplasmic calcium fluxes. The peptide-induced nucleation sites behave as free barbed ends and therefore may increase the level of polymerized actin in vivo. The new nucleation sites may also determine the cellular sites of actin polymerization. This localization of actin polymerization could be important for the directional extension of lamellipodia during chemotaxis.

Chemotactic peptide binding by rabbit polymorphonuclear leukocytes. Presence of two compartments having similar affinities but different kinetics

N-Formylnorleucylleucylphenylalanine (f-Nle-LeuPhe) bound to rabbit peritoneal polymorphonuclear leukocytes at 4 degrees C exists in at least two compartments that can be differentiated by their off rates. The off rate of one compartment is similar to that of the receptor characterized previously, about 0.4 min-1 (Aswanikumar, S., Corcoran, B., Schiffmann, E., Day, A. R., Freer, R. J., Showell, H. J., Becker, E. L., and Pert, C. B. (1977) Biochem. Biophys. Res. Commun. 74, 810-817; Sullivan, S. J., and Zigmond, S. H. (1980) J. Cell Biol. 85, 703-711); the off rate of the second compartment is about 0.005 min-1. Lysis of the cells at 4 degrees C with 1% Triton does not affect the peptide release from either compartment. Accumulation of peptide at 4 degrees C into the fast off-rate compartment is rapid, reaching a plateau in about 5 min, while peptide in the slow off-rate compartment continues to increase for up to 4 h. The rate of accumulation in the slow off-rate compartment is approximately proportional to the amount of peptide bound to the fast off-rate compartment. Cells lysed at 4 degrees C before binding are still able to accumulate peptide into both compartments. Three possible models to explain the data are presented.

Assays of leukocyte chemotaxis

A number of disorders of leukocyte motility and chemotaxis have been reported clinically. In this paper we present a rational approach for testing cell populations for a defect in leukocyte migration and for defining the cellular basis of any abnormality observed. The principles and difficulties of individual and population-type assays are discussed.

Inhibition of receptor-mediated but not fluid-phase endocytosis in polymorphonuclear leukocytes

We have found that hypertonic medium inhibited the receptor-mediated uptake of the chemotactic peptide N-formylnorleucylleucylphenylalanine without affecting fluid-phase endocytosis by polymorphonuclear leukocytes (PMNs). Morphological and biochemical evidence demonstrated that cells in hypertonic medium did not accumulate peptide in a receptor-mediated manner. However, the cells continued to form endosomes containing fluid-phase markers. Furthermore, the content of these endosomes was processed normally, i.e., both digested and intact material were released into the medium. The inhibition of receptor-mediated uptake was a function of the tonicity. Partial inhibition occurred in 0.45 and 0.6 osmolar medium and maximal inhibition occurred in 0.75 osmolar medium. The inhibition was independent of the solute used to increase the tonicity: sodium chloride, sucrose, and lactose all inhibited uptake to similar extents. Hypertonic medium had little effect on saturable peptide binding. However, it did prevent the clustering of surface molecules as indicated by the inhibition of capping of fluorescent concanavalin A. In addition, hypertonic medium prevented the peptide-stimulated increase in cytosolic calcium levels as measured by quin 2 fluorescence. The tonicity dependence of the inhibition of quin 2 fluorescence paralleled the inhibition of receptor-mediated uptake.

Phosphorylase a activity as an indicator of neutrophil activation by chemotactic peptide

The activity of glycogen phosphorylase, an enzyme that is activated by both cAMP and calcium, was used as an indicator of the state of the cytoplasm after chemotactic stimulation of polymorphonuclear leukocytes (neutrophils). The activity of the enzyme showed a clear dependence on cytoplasmic calcium. Addition of the calcium ionophore A23187 caused a 4-5-fold increase in activity of phosphorylase a. In the absence of external Ca2+, A23187 caused only brief transient activation of phosphorylase; probably reflecting release of sequestered intracellular Ca2+. Addition of the chemotactic peptide N-formylnorleucylleucylphenylalanine (FNLLP) caused a transient 2-3-fold activation of the enzyme. The dose-dependence of activation by FNLLP showed a peak at 10(-8) M, near the Kd of the receptor for FNLLP. The phosphorylase activity peaks by 90 s and then declines, returning to basal levels by 20 min after stimulation with 10(-8) M peptide and by 60 min with 10(-7) M peptide. This finding suggests that the cells do not need to maintain elevated cytoplasmic calcium levels to exhibit stimulated locomotion. Thus, if calcium continues to modulate the motility, there either must be highly localized changes that are not detected in measures of the total cytoplasm, or the sensitivity to calcium must be variable such that basal levels are sufficient to maintain locomotion. Cells loaded with the fluorescence calcium probe quin2 (0.6 mM) in the presence or absence of external Ca2+ had elevated phosphorylase levels before addition of FNLLP. Thus, the presence of quin2 may alter the cytoplasmic Ca2+ level, and it clearly alters some aspects of the neutrophil physiology. Phosphorylase a appears to be a sensitive, nonperturbing indicator of the cytoplasmic calcium levels.

Effects of sodium on chemotactic peptide binding to polymorphonuclear leukocytes

The affinity of binding of the chemotactic peptide N-formylnorleucylleucylphenylalanine to rabbit peritoneal polymorphonuclear leukocytes is increased when sodium ions are removed from the medium. In Hanks' balanced salt solution, the dissociation constant of the binding is about 2 X 10(-8) M, while in Na+-free medium, the dissociation constant is between 3 and 6 X 10(-9) M. Removal of Na+ appears to cause little or no change in receptor number. The change in affinity is rapid and reversible, occurs at 4 degrees C as well as 37 degrees C, and occurs when the Na+ is replaced by K+, choline, or sucrose. The increased binding of low concentrations of peptide is seen on broken as well as whole cells and therefore does not depend on an ion gradient across the membrane. The high affinity receptors are functional in mediating peptide uptake and lysosomal enzyme release. The receptors undergo down-regulation in Na+-free medium, and the dose dependence of the receptor loss is shifted to lower concentrations consistent with the higher affinity of the binding.

Effects of sodium on chemotactic peptide binding to polymorphonuclear leukocytes

The affinity of binding of the chemotactic peptide N-formylnorleucylleucylphenylalanine to rabbit peritoneal polymorphonuclear leukocytes is increased when sodium ions are removed from the medium. In Hanks' balanced salt solution, the dissociation constant of the binding is about 2 X 10(-8) M, while in Na+-free medium, the dissociation constant is between 3 and 6 X 10(-9) M. Removal of Na+ appears to cause little or no change in receptor number. The change in affinity is rapid and reversible, occurs at 4 degrees C as well as 37 degrees C, and occurs when the Na+ is replaced by K+, choline, or sucrose. The increased binding of low concentrations of peptide is seen on broken as well as whole cells and therefore does not depend on an ion gradient across the membrane. The high affinity receptors are functional in mediating peptide uptake and lysosomal enzyme release. The receptors undergo down-regulation in Na+-free medium, and the dose dependence of the receptor loss is shifted to lower concentrations consistent with the higher affinity of the binding.