Chemotactic G protein-coupled receptors control cell migration by repressing autophagosome biogenesis

Chemotactic migration is a fundamental behavior of cells and its regulation is particularly relevant in physiological processes such as organogenesis and angiogenesis, as well as in pathological processes such as tumor metastasis. The majority of chemotactic stimuli activate cell surface receptors that belong to the G protein-coupled receptor (GPCR) superfamily. Although the autophagy machinery has been shown to play a role in cell migration, its mode of regulation by chemotactic GPCRs remains largely unexplored. We found that ligand-induced activation of 2 chemotactic GPCRs, the chemokine receptor CXCR4 and the urotensin 2 receptor UTS2R, triggers a marked reduction in the biogenesis of autophagosomes, in both HEK-293 and U87 glioblastoma cells. Chemotactic GPCRs exert their anti-autophagic effects through the activation of CAPNs, which prevent the formation of pre-autophagosomal vesicles from the plasma membrane. We further demonstrated that CXCR4- or UTS2R-induced inhibition of autophagy favors the formation of adhesion complexes to the extracellular matrix and is required for chemotactic migration. Altogether, our data reveal a new link between GPCR signaling and the autophagy machinery, and may help to envisage therapeutic strategies in pathological processes such as cancer cell invasion.     

The Galpha13-Rho signaling axis is required for SDF-1-induced migration through CXCR4

The CXC chemokine stromal cell-derived factor-1alpha (SDF-1) binds to CXCR4, a seven-transmembrane G protein-coupled receptor that plays a critical role in many physiological processes that involve cell migration and cell fate decisions, ranging from stem cell homing, angiogenesis, and neuronal development to immune cell trafficking. CXCR4 is also implicated in various pathological conditions, including metastatic spread and human immunodeficiency virus infection. Although SDF-1-induced cell migration in CXCR4-expressing cells is sensitive to pertussis toxin treatment, hence involving heterotrimeric G proteins of the G(i) family, whether other G proteins participate in the chemotactic response to SDF-1 is still unknown. In this study, we took advantage of the potent chemotactic activity of SDF-1 in Jurkat T-cells to examine the nature of the heterotrimeric G protein subunits contributing to CXCR4-mediated cell migration. We observed that whereas G(i) and Gbetagamma subunits are involved in SDF-1-induced Rac activation and cell migration, CXCR4 can also stimulate Rho potently leading to the phosphorylation of myosin light chain through the Rho effector, Rho kinase, but independently of G(i). Furthermore, we found that Galpha(13) mediates the activation of Rho by CXCR4 and that the functional activity of both Galpha(13) and Rho is required for directional cell migration in response to SDF-1. Collectively, our data indicate that signaling by CXCR4 to Rho through Galpha(13) contributes to cell migration when stimulated by SDF-1, thus identifying the Galpha(13)-Rho signaling axis as a potential pharmacological target in many human diseases that involve the aberrant function of CXCR4.     

Production of neutrophil-specific lipid chemoattractant activity by cultured endothelial cells: heterogeneity dependent on species, ligand, or endothelial cell site of origin.

Previous studies have demonstrated that the interaction of cultured bovine aortic and pulmonary arterial endothelial cells and the proinflammatory vasoactive amines histamine, serotonin, and angiotensin II, causes production of three novel lipid neutrophil-specific chemoattractants that are distinct from other phospholipid or lipid neutrophil chemoattractants. In this study, we investigated the species and site specificity of this inflammatory response by incubating human aortic and pulmonary arterial endothelial cells with histamine, serotonin, and angiotensin II and assaying the supernatants for their effect on neutrophil migration. Each of these vasoactive amines caused production of neutrophil chemoattractant activity in a concentration dependent manner in both cell types. For each amine, production was blocked by a specific antagonist: cimetidine for histamine, methiothepin for serotonin-stimulated aortas, ketanserin for serotonin-stimulated pulmonary arteries, and saralasin for angiotensin II. In each case, all chemoattractant activity partitioned into the organic phase and resolution by HPLC yielded two chemotactic lipids. As with the lipid chemoattractants produced by bovine endothelial cells, these lipids did not coelute with PAF, LTB4, 5-HETE, or 15-HETE, nor did they increase lymphocyte or monocyte migration. The pattern of chemotactic activity following resolution by HPLC was similar in both human aortic and pulmonary arterial endothelial cells, but was different from that of bovine aortic and pulmonary arterial endothelial cells in that only two chemoattractant lipids appeared; the third chemotactic lipid was never produced. These studies demonstrate that human endothelial cells may actively participate in neutrophil enriched local inflammatory responses by production of neutrophil-specific chemotactic factors. They also suggest this response may be dissimilar depending on the site and species from which the endothelial cells originate.     

Modulation of PDGF mediated osteoblast chemotaxis by leukemia inhibitory factor LIF

Cell migration is a key event in tissue repair and remodeling. PDGF, a growth factor for multiple target cells, has been shown to be a potent chemoattractant for a variety of mesenchymal cells. However, it is likely that PDGF-mediated cell migration will be influenced by other cytokines that can be produced during physiological and pathological conditions. Leukemia inhibitory factor (LIF), a cytokine that is produced by a variety of cells including osteoblasts, may promote bone formation, but the mechanism is not known. Since osteoblasts are responsible for laying down new matrix during skeletal remodeling, in this report we have examined whether PDGF or LIF influences the migration of osteoblasts. Among several cytokines and growth factors tested, only PDGF was able to elicit a major chemotactic (directed migration) and a minor chemokinetic (random-migration) response in osteoblasts. LIF alone was not active in either chemotaxis or chemokinesis but when included with PDGF it caused a reduction in chemokinesis. Further, pretreatment of osteoblasts with LIF caused an increase in PDGF-driven chemotaxis. Finally, osteoblasts exposed briefly to LIF synthesized a higher level of non-collagenous proteins upon further treatment with PDGF. These observations are consistent with a role for LIF in promoting bone formation, both by influencing directional migration of osteoblasts and in laying down new matrix. © 1996 Wiley-Liss, Inc.     

Assays for in vitro monitoring of human airway smooth muscle (ASM) and human pulmonary arterial vascular smooth muscle (VSM) cell migration

Migration of human pulmonary vascular smooth muscle (VSM) cells contributes to vascular remodeling in pulmonary arterial hypertension and atherosclerosis. Evidence also indicates that, in part, migration of airway smooth muscle (ASM) cells may contribute to airway remodeling associated with asthma. Here we describe migration of VSM and ASM cells in vitro using Transwell or Boyden chamber assays. Because dissecting signaling mechanisms regulating cell migration requires molecular approaches, our protocol also describes how to assess migration of transfected VSM and ASM cells. Transwell or Boyden chamber assays can be completed in approximately 8 h and include plating of serum-deprived VSM or ASM cell suspension on membrane precoated with collagen, migration of cells toward chemotactic gradient and visual (Transwell) or digital (Boyden chamber) analysis of membrane. Although the Transwell assay is easy, the Boyden chamber assay requires hands-on experience; however, both assays are reliable cell-based approaches providing valuable information on how chemotactic and inflammatory factors modulate VSM and ASM migration.     

Modeling cell gradient sensing and migration in competing chemoattractant fields

Directed cell migration mediates physiological and pathological processes. In particular, immune cell trafficking in tissues is crucial for inducing immune responses and is coordinated by multiple environmental cues such as chemoattractant gradients. Although the chemotaxis mechanism has been extensively studied, how cells integrate multiple chemotactic signals for effective trafficking and positioning in tissues is not clearly defined. Results from previous neutrophil chemotaxis experiments and modeling studies suggested that ligand-induced homologous receptor desensitization may provide an important mechanism for cell migration in competing chemoattractant gradients. However, the previous mathematical model is oversimplified to cell gradient sensing in one-dimensional (1-D) environment. To better understand the receptor desensitization mechanism for chemotactic navigation, we further developed the model to test the role of homologous receptor desensitization in regulating both cell gradient sensing and migration in different configurations of chemoattractant fields in two-dimension (2-D). Our results show that cells expressing normal desensitizable receptors preferentially orient and migrate toward the distant gradient in the presence of a second local competing gradient, which are consistent with the experimentally observed preferential migration of cells toward the distant attractant source and confirm the requirement of receptor desensitization for such migratory behaviors. Furthermore, our results are in qualitative agreement with the experimentally observed cell migration patterns in different configurations of competing chemoattractant fields.     

Development of a new method of analysing chemotactic deactivation of human neutrophil granulocytes

Measurement of chemotactic migration of human neutrophil granulocytes (PMN) induced by chemotaxins serves as a simple and reliable method for assessing the expression of chemotaxin receptors. Incubation of PMN with a certain chemotaxin leads to a diminished chemotactic migration towards this chemotaxin. This is called chemotactic deactivation. We developed a new deactivation chamber to determine chemotaxis and chemotactic deactivation of human PMN. This novel chamber is a modification of the commercially available acrylic 48-well microchemotaxis chamber consisting of an upper block with wells drilled all the way through the block and a blind-well lower block. Both blocks are separated by a polycarbonate membrane. PMN from the wells in the upper block migrate through the pores of the membrane into the wells of the lower block containing the chemoattractants. Migrated PMN on the lower side of the PC membrane were quantified after staining by measuring specific light absorbance. The chemotactic activity is quantified as a ratio of stimulated migration and random migration (chemotactic index=CI). For our novel chamber, only the upper blocks of this commercial chamber were connected like a sandwich, including a polyvinylpyrrolidone-free polycarbonate membrane with a pore size of 3 microm. The wells in the upper compartment were filled with 5 x 10(4) PMN and deactivating chemotaxin. The lower block was then filled with the chemotactic stimulus and the chamber was then incubated in humidified air with 5% CO2 atmosphere at 37 degrees C. The influence of cell concentration, incubation time, chemotactic factor concentration, pore size and alkaline treatment of polycarbonate membranes on migrational activity of PMN have been investigated. The technique was rigorously standardized in order to optimize the assay conditions. The method is relatively simple, sensitive and fast. The determination of chemotaxis and deactivation are performed in the same chamber, thus avoiding cell loss due to nonspecific adherence in other incubation tubes. The chamber can be used to characterize the chemotactic activity of chemoattractants of unknown structure via known and unknown receptors. This new chamber can be very helpful in detecting unknown chemotactic stimuli, which are not detectable by, for example, antibodies.     

Suppression of human lymphocyte chemotaxis and transendothelial migration by anti-LFA-1 antibody

The role of lymphocyte function-associated antigen 1 (LFA-1) in human T cell chemotaxis was investigated by using mAb specific to the beta-chain (TS1/18) (CD18) and alpha-chain (TS1/22) (CD11a) of LFA-1. T cell chemotaxis in response to IL-2 and to lymphocyte chemotactic factor (LCF) was markedly suppressed by the addition of TS1/18. TS1/22 was a less effective inhibitor than TS1/18 with only LCF stimulated responses showing significant inhibition when compared in seven different T cell preparations. Neither TS1/18 nor TS1/22 antibody inhibited random T cell migration. Control mAb to CD4 T cells failed to inhibit T cell random migration or chemotaxis. Additional studies to evaluate the adherence and migration of T cells through IL-1-stimulated human umbilical vein endothelial cell (HUVEC) monolayers showed that both TS1/22 and TS1/18 suppressed T cell migration through HUVEC, but failed to inhibit adherence of T cells to these cells. These studies indicate that LFA-1 plays a role in the migration of T cells through HUVEC and in the in vitro chemotactic response of T lymphocytes to IL-2 and LCF.     

Lysophosphatidylglycerol stimulates chemotactic migration in human natural killer cells

We observed that lysophosphatidylglycerol (LPG) stimulates chemotactic migration in human natural killer (NK) cells. The LPG-induced chemotactic migration of NK cells was completely inhibited by pertussis toxin (PTX). LPG also stimulated the extracellular signal-regulated kinase (ERK) and Akt activities in NK cells. LPG-stimulated ERK activity was inhibited by PTX, indicating the involvement of PTX-sensitive G-proteins. The preincubation of NK cells with an ERK inhibitor (PD98059) or phosphoinositide-3-kinase (PI3K) inhibitors (wortmannin and LY294002) completely inhibited LPG-induced chemotactic migration, suggesting the essential role of ERK and PI3K in the process. Moreover, LPG-induced chemotactic migration in NK cell was inhibited by Ki16425, an LPA_1/3 receptor-selective antagonist, suggesting the involvement of the Ki16425-sensitive G-protein coupled receptor (GPCR) in the process. Taken together, the results indicate that LPG stimulates chemotactic migration in NK cells through GPCR, suggesting a new function of LPG as a modulator of NK cell functioning.     

Polarised Clathrin‐Mediated Endocytosis of EGFR During Chemotactic Invasion

Directed cell migration is critical for numerous physiological processes including development and wound healing. However chemotaxis is also exploited during cancer progression. Recent reports have suggested links between vesicle trafficking pathways and directed cell migration. Very little is known about the potential roles of endocytosis pathways during metastasis. Therefore we performed a series of studies employing a previously characterised model for chemotactic invasion of cancer cells to assess specific hypotheses potentially linking endocytosis to directed cell migration. Our results demonstrate that clathrin‐mediated endocytosis is indispensable for epidermal growth factor (EGF) directed chemotactic invasion of MDA‐MB‐231 cells. Conversely, caveolar endocytosis is not required in this mode of migration. We further found that chemoattractant receptor (EGFR) trafficking occurs by clathrin‐mediated endocytosis and is polarised towards the front of migrating cells. However, we found no role for clathrin‐mediated endocytosis in focal adhesion disassembly in this migration model. Thus, this study has characterised the role of endocytosis during chemotactic invasion and has identified functions mechanistically linking clathrin‐mediated endocytosis to directed cell motility.      

细胞表面糖链末端唾液酸和岩藻糖和某些细胞生物学行为的关系

用神经氨酸酶和α-L-岩藻糖苷酶分别切除人肝癌细胞株7721细胞表面糖链中的末端唾液酸（SA）和岩藻糖（Fuc)残基来研究表面聚糖结构和某些细胞生物学行为之间的关系。选择细胞对纤连蛋白（Fn）,层黏蛋白（Ln)和人脐静脉内皮细胞（HUVEC）的黏附能力,细胞趋化性迁移以及趋化性侵袭作为细胞行为的指标。结果表明：表面人脐静脉内皮细胞（HUVEC）的黏附能力,细胞趋化性迁移以及趋化性侵袭作为细胞行为的指标。结果表明：表面糖链末端SA对细胞黏附至Fn并不必需,对细胞黏附至Ln和细胞的趋化性侵袭却至为重要,而对细胞黏附至HUVEC以及趋化性迁移则为关键性残基。与SA相比,Fuc可能参与细胞Fn,Ln和HUVEC的黏附,但对趋化性迁移以及趋化性侵袭并不重要。细胞对HUVEC的黏附以及趋化性迁移和侵袭可被唾液酸化Lewis X(SLe^x)单抗抑制,但不被未唾液酸化的Lewis X(Le^x)单抗抑制,这一结果支持SA在上述三种细胞过程中Fuc残基重要。     

An urokinase receptor antagonist that inhibits cell migration by blocking the formyl peptide receptor

Urokinase receptor (uPAR) plays a key role in physiological and pathological processes sustained by an altered cell migration. We have developed peptides carrying amino acid substitutions along the Ser(88)-Arg-Ser-Arg-Tyr(92) (SRSRY) uPAR chemotactic sequence. The peptide pyro glutamic acid (pGlu)-Arg-Glu-Arg-Tyr-NH2 (pERERY-NH(2)) shares the same binding site with SRSRY and competes with N-formyl-Met-Leu-Phe (fMLF) for binding to the G-protein-coupled N-formyl-peptide receptor (FPR). pERERY-NH(2) is a dose-dependent inhibitor of both SRSRY- and fMLF-directed cell migration, and prevents agonist-induced FPR internalization and fMLF-dependent ERK1/2 phosphorylation. pERERY-NH(2) is a new and potent uPAR inhibitor which may suggest the generation of new pharmacological treatments for pathological conditions involving increased cell migration.     

Purification and structural analysis of a murine chemotactic cytokine (CP-10) with sequence homology to S100 proteins.

In delayed-type hypersensitivity reactions, cytokine-mediated cell migration leads to localized accumulation of neutrophils and mononuclear cells over 4-48 h. In contrast to transient (2-6 h) responses elicited by other chemotactic factors, earlier studies indicated that a chemotactic activity previously described in our laboratory elicited skin test responses over 24 h, identical to those induced by injection of antigen into a sensitized test subject. We have isolated this factor, a 10.3-kDa chemotactic protein designated CP-10, from supernatants of activated murine spleen cells. Purification to homogeneity was achieved using affinity chromatography on iminodiacetic acid-immobilized copper and cation-exchange, mixed mode (cation exchange/metal affinity), reversed-phase, and size-exclusion high performance liquid chromatography. CP-10 had maximal chemotactic activity for neutrophils at 10(-13) M. The 76-amino acid sequence, obtained by automated N-terminal microsequence analysis of native CP-10, and fragments derived from trypsin digestion and cyanogen bromide cleavage indicated no sequence identity with any known cytokine or chemotactic factor but revealed up to 55% sequence homology with S100, Ca2(+)-binding proteins. CP-10 appears to be the first protein of this family with a well defined function affecting cell migration, and its biological potency suggests an important role for this cytokine in cellular immune reactions.     

Analysis of the roles of microvessel endothelial cell random motility and chemotaxis in angiogenesis.

The growth of new capillary blood vessels, or angiogenesis, is a prominent component of numerous physiological and pathological conditions. An understanding of the co-ordination of underlying cellular behaviors would be helpful for therapeutic manipulation of the process. A probabilistic mathematical model of angiogenesis is developed based upon specific microvessel endothelial cell (MEC) functions involved in vessel growth. The model focuses on the roles of MEC random motility and chemotaxis, to test the hypothesis that these MEC behaviors are of critical importance in determining capillary growth rate and network structure. Model predictions are computer simulations of microvessel networks, from which questions of interest are examined both qualitatively and quantitatively. Results indicate that a moderate MEC chemotactic response toward an angiogenic stimulus, similar to that measured in vitro in response to acidic fibroblast growth factor, is necessary to provide directed vascular network growth. Persistent random motility alone, with initial budding biased toward the stimulus, does not adequately provide directed network growth. A significant degree of randomness in cell migration direction, however, is required for vessel anastomosis and capillary loop formation, as simulations with an overly strong chemotactic response produce network structures largely absent of these features. The predicted vessel extension rate and network structure in the simulations are quantitatively consistent with experimental observations of angiogenesis in vivo. This suggests that the rate of vessel outgrowth is primarily determined by MEC migration rate, and consequently that quantitative in vitro migration assays might be useful tools for the prescreening of possible angiogenesis activators and inhibitors. Finally, reduction of MEC speed results in substantial inhibition of simulated angiogenesis. Together, these results predict that both random motility and chemotaxis are MEC functions critically involved in determining the rate and morphology of new microvessel network growth.     

Haptotactic activity of fibronectin on lymphocyte migration in vitro

In addition to mediating cell adhesion, fibronectin (FN) also affects the migration of different cell types. However, the role of FN in lymphocyte migration is unclear. In this study, we examined the effects of FN on the in vitro migration of lymphocytes. Using the checkerboard analysis in a blind-well microchemotaxis assay, soluble FN was determined to have neither a chemotactic nor chemokinetic effect on spleen or thymus lymphocytes. However, when the nitrocellulose filter was coated unidirectionally with FN, the migration of both spleen and thymus lymphocytes into the filter was enhanced, indicating that FN is haptotactic for lymphocytes. When the filter was coated bidirectionally, no enhancement in migration was observed, indicating that FN is not haptokinetic for lymphocytes. When the FN cell-binding domain and the heparin-binding domain were tested, the cell-binding domain was haptotactic for both spleen and thymus lymphocytes, whereas the heparin-binding domain was only haptotactic for spleen lymphocytes. Because the heparin-binding domain can mediate strong adhesion of thymus lymphocytes, the lack of haptotactic activity is likely to be the result of excessive binding that prevents cell motility.     

Advantages and limitations of methods for measuring cellular chemotaxis and chemokinesis

Summary Cell migration is an important component of many physiological reactions, for example inflammation, wound healing and formation of atherosclerotic lesions. This review summarizes the methods currently available for examining cell movement in vitro. The applications of each method, and its particular advantages and disadvantages are discussed. Techniques are described for preparing purified leukocyte populations for use in migration studies and for differentiating between chemotactic and chemokinetic cell migration.     

Domain 2 of the urokinase receptor contains an integrin-interacting epitope with intrinsic signaling activity: generation of a new integrin inhibitor

We investigated the interaction between the urokinase receptor (uPAR) and the integrin alphavbeta3. Vitronectin (VN) induces cell migration by binding to alphavbeta3, but expression of the uPAR boosts its efficacy. Thus, uPAR may regulate VN-induced cell migration by interacting laterally with alphavbeta3. In contrast, cells expressing a uPAR mutant lacking domain 2 do not migrate in response to VN. This effect is overcome by D2A, a synthetic peptide derived from the sequence of domain 2. In addition, D2A has chemotactic activity that requires alphavbeta3 and activates alphavbeta3-dependent signaling pathways such as the Janus kinase/Stat pathway. Moreover, D2A disrupts uPAR-alphavbeta3 and uPAR-alpha5beta1 co-immunoprecipitation, indicating that it can bind both of these integrins. We also identify the chemotactically active epitope harbored by peptide D2A. Mutating two glutamic acids into two alanines generates peptide D2A-Ala, which lacks chemotactic activity but inhibits VN-, FN-, and collagen-dependent cell migration. In fact, the GEEG peptide has potent chemotactic activity, and the GAAG sequence has inhibitory capacities. In summary, we have identified an integrin-interacting sequence located in domain 2 of uPAR, which is also a new chemotactic epitope that can activate alphavbeta3-dependent signaling pathways and stimulate cell migration. This sequence thus plays a pivotal role in the regulation of uPAR-integrin interactions. Moreover, we describe a novel, very potent inhibitor of integrin-dependent cell migration.     

BDNF stimulates migration of cerebellar granule cells

During development of the nervous system, neural progenitors arise in proliferative zones, then exit the cell cycle and migrate away from these zones. Here we show that migration of cerebellar granule cells out of their proliferative zone, the external granule cell layer (EGL), is impaired in Bdnf(-/-) mice. The reason for impaired migration is that BDNF directly and acutely stimulates granule cell migration. Purified Bdnf(-/-) granule cells show defects in initiation of migration along glial fibers and in Boyden chamber assays. This phenotype can be rescued by exogenous BDNF. Using time-lapse video microscopy we find that BDNF is acutely motogenic as it stimulates migration of individual granule cells immediately after addition. The stimulation of migration reflects both a chemokinetic and chemotactic effect of BDNF. Collectively, these data demonstrate that BDNF is directly motogenic for granule cells and provides a directional cue promoting migration from the EGL to the internal granule cell layer (IGL).     

The canine mast cell activation via CRP

We report here canine mastocytoma-derived cell (CMMC) activation via two pentraxin, limulus- and human-CRP. Mast cell chemotaxis was measured by Boyden's blindwell chamber. To confirm that the cell migration was chemotactic, "checkerboard" analysis was performed. We used Fura-2 to investigate CRP-mediated cytosolic calcium elevation. To examine whether CRP-induced stimulation is mediated through G-proteins, CMMC were incubated with pertussis toxin (PTx) before use in chemotaxis assay and Ca(2+) mobilization. CMMC migration in response to CRP was both chemokinetic and chemotactic. Limulus-CRP induced a transient Ca(2+)-mobilization dose-dependently. Preincubation of the cells with PTx inhibited CRP chemotaxis and Ca(2+)-mobilization, suggesting that G-proteins of the Gi-class are involved in the chemotaxis. We suggest that CRP may participate in the migration of mast cells to inflamed tissues during an acute-phase response. CRP-mediated recruitment of mast cells might play an important role in hypersensitivity and inflammatory processes.     

The chemotactic response to PDGF-BB: evidence of a role for Ras

The PDGF receptor-beta mediates both mitogenic and chemotactic responses to PDGF-BB. Although the role of Ras in tyrosine kinase- mediated mitogenesis has been characterized extensively, its role in PDGF-stimulated chemotaxis has not been defined. Using cells expressing a dominant-negative ras, we find that Ras inhibition suppresses migration toward PDGF-BB. Overexpression of either Ras-GTPase activating protein (Ras-GAP) or a Ras guanine releasing factor (GRF) also inhibited PDGF-stimulated chemotaxis. In addition, cells producing excess constitutively active Ras failed to migrate toward PDGF-BB, consistent with the observation that either excess ligand or excess signaling intermediate can suppress the chemotactic response. These results suggest that Ras can function in normal cells to support chemotaxis toward PDGF-BB and that either too little or too much Ras activity can abrogate the chemotactic response. In contrast to Ras overexpression, cells producing excess constitutively active Raf, a downstream effector of Ras, did migrate toward PDGF-BB. Cells expressing dominant-negative Ras were able to migrate toward soluble fibronectin demonstrating that these cells retained the ability to migrate. These results suggest that Ras is an intermediate in PDGF- stimulated chemotaxis but may not be required for fibronectin- stimulated cell motility.