RhoA-mediated Phospholipase D1 signaling is not required for the formation of stress fibers and focal adhesions

The small GTPase RhoA regulates a wide spectrum of cellular functions including transformation and cytoskeletal reorganization. A large number of proteins have been identified as targets of RhoA, but their specific roles in these processes are not clear. Phospholipase D (PLD) was shown to be one such target several years ago; more recent work from our laboratory and others has demonstrated that of the two mammalian PLD isozymes, PLD1 but not PLD2 is activated by RhoA and this activation proceeds through direct binding both in vitro and in vivo. In this study, using a series of RhoA mutants, we have defined a PLD1-specific interacting site on RhoA composed of the residues Asn41, Trp58 and Asp76, using the yeast two-hybrid system, co-immunoprecipitation, and a PLD in vivo assay. The results further substantiate our previous finding that RhoA activates PLD1 through direct interaction. These mutants were then used to investigate the role of PLD1 in the cytoskeletal reorganization stimulated by RhoA signaling. Our results show that PLD1 is not required for the RhoA-mediated stress fiber and focal adhesion formation. The lack of importance of PLD1 signaling in RhoA-mediated cytoskeletal reorganization is further supported by the observation that PLD1 depletion using an shRNA approach and tetracycline-induced overexpression of the wild-type and the catalytically inactive mutant of PLD1 in stable cell lines do not alter stress fiber and focal adhesion formation.     

Novel functions of the phospholipase D2-Phox homology domain in protein kinase Czeta activation

It has been established that protein kinase Czeta (PKCzeta) participates in diverse signaling pathways and cellular functions in a wide variety of cells, exhibiting properties relevant to cellular survival and proliferation. Currently, however, the regulation mechanism of PKCzeta remains elusive. Here, for the first time, we determine that phospholipase D2 (PLD2) enhances PKCzeta activity through direct interaction in a lipase activity-independent manner. This interaction of the PLD2-Phox homology (PX) domain with the PKCzeta-kinase domain also induces the activation loop phosphorylation of PKCzeta and downstream signal stimulation, as measured by p70 S6 kinase phosphorylation. Furthermore, only the PLD2-PX domain directly stimulates PKCzeta activity in vitro, and it is necessary for the formation of the ternary complex with phosphoinositide-dependent kinase 1 and PKCzeta. The mutant that substitutes the triple lysine residues (Lys101, Lys102, and Lys103) within the PLD2-PX domain with alanine abolishes interaction with the PKCzeta-kinase domain and activation of PKCzeta. Moreover, breast cancer cell viability is significantly affected by PLD2 silencing. Taken together, these results suggest that the PLD2-mediated PKCzeta activation is induced by its PX domain performing both direct activation of PKCzeta and assistance of activation loop phosphorylation. Furthermore, we find it is an important factor in the survival of breast cancer cells.     

Smad3 Regulates Rho Signaling via NET1 in the Transforming Growth Factor-β-induced Epithelial-Mesenchymal Transition of Human Retinal Pigment Epithelial Cells

We previously demonstrated that RhoA-dependent signaling regulates transforming growth factor-β1 (TGF-β1)-induced cytoskeletal reorganization in the human retinal pigment epithelial cell line ARPE-19. Smad pathways have also been shown to mediate TGF-β1 activity. Here, we examined what regulates Rho GTPase activity and tested whether Smad signaling cross-talks with Rho pathways during TGF-β1-induced actin rearrangement. Using small interfering RNAs, we found that NET1, the guanine nucleotide exchange factor of RhoA, is critical for TGF-β1-induced cytoskeletal reorganization, N-cadherin expression, and RhoA activation. In ARPE-19 cells lacking NET1, TGF-β1-induced stress fibers and N-cadherin expression were not observed. Interestingly, in dominant-negative Smad3-expressing or constitutively active Smad7 cells, TGF-β1 failed to induce NET1 mRNA and protein expression. Consistent with these results, both dominant-negative Smad3 and constitutively active Smad7 blocked the cytoplasmic localization of NET1 and inhibited interactions between NET1 and RhoA. Finally, we found that NET1 is a direct gene target of TGF-β1 via Smad3. Taken together, our results demonstrate that Smad3 regulates RhoA activation and cytoskeletal reorganization by controlling NET1 in TGF-β1-induced ARPE-19 cells. These data define a new role for Smad3 as a modulator of RhoA activation in the regulation of TGF-β1-induced epithelial-mesenchymal transitions.     

Identification of the Catalytic Site of Phospholipase D2 (PLD2) Newly Described Guanine Nucleotide Exchange Factor Activity

We have demonstrated that phospholipase D2 (PLD2) is a guanine nucleotide exchange factor (GEF) for Rac2 and determined the PLD2 domains and amino acid site(s) responsible for its GEF activity. Experiments using GST fusion proteins or GST-free counterparts, purified proteins revealed that the PX domain is sufficient to exert GEF activity similar to full-length PLD2. The PLD2-GEF catalytic site is formed by a hydrophobic pocket of residues Phe-107, Phe-129, Leu-166, and Leu-173, all of which are in the PX domain. A nearby Arg-172 is also important in the overall activity. PX mutants altering any of those five amino acids fail to have GEF activity but still bind to Rac2, while their lipase activity was mostly unaffected. In addition to the PX domain, a region in the pleckstrin homology domain (Ile-306–Ala-310) aids in the PX-mediated GEF activity by providing a docking site to hold Rac2 in place during catalysis. We conclude that PLD2 is a unique GEF, with the PX being the major catalytic domain for its GEF activity, whereas the pleckstrin homology domain assists in the PX-mediated activity. The physiological relevance of this novel GEF in cell biology is demonstrated here in chemotaxis and phagocytosis of leukocytes, as the specific PX and PH mutants abolished cell function. Thus, this study reveals for the first time the catalytic site that forms the basis for the mechanism behind the GEF activity of PLD2.     

α1 -Adrenergic receptor-induced cytoskeletal organization and cell motility in CCL39 fibroblasts requires phospholipase D1

The role of phospholipase D (PLD) in cytoskeletal reorganization, ERK activation, and migration is well established. Both isoforms of PLD (PLD1 and PLD2) can independently activate stress fiber formation and increase ERK phosphorylation. However, the isoform's specificity, upstream activators, and downstream targets of PLD that coordinate this process are less well understood. This study explores the role of α(1) -adrenergic receptor stimulation and its effect on PLD activity. We demonstrate that PLD1 activators, RhoA, and PKCα are critical for stress fiber formation and ERK activation, and enhance the production of phosphatidic acid (PA) upon phenylephrine addition. Ectopic expression of dominant negative PLD1 and not PLD2 blocks ERK activation, inhibits stress fiber formation, and reduces cell motility in CCL39 fibroblasts. Furthermore, we demonstrate the mechanism for PLD1 activation of ERK involves Ras. This work indicates that PLD1 plays a novel role mediating growth factor and cell motility events in α(1) -adrenergic receptor-activated cells.     

Class III PI-3-kinase activates phospholipase D in an amino acid-sensing mTORC1 pathway

The rapamycin-sensitive mammalian target of rapamycin (mTOR) complex, mTORC1, regulates cell growth in response to mitogenic signals and amino acid availability. Phospholipase D (PLD) and its product, phosphatidic acid, have been established as mediators of mitogenic activation of mTORC1. In this study, we identify a novel role for PLD1 in an amino acid-sensing pathway. We find that amino acids activate PLD1 and that PLD1 is indispensable for amino acid activation of mTORC1. Activation of PLD1 by amino acids requires the class III phosphatidylinositol 3-kinase hVps34, which stimulates PLD1 activity through a functional interaction between phosphatidylinositol 3-phosphate and the Phox homology (PX) domain of PLD1. Furthermore, amino acids stimulate PLD1 translocation to the lysosomal region where mTORC1 activation occurs in an hVps34-dependent manner, and this translocation is necessary for mTORC1 activation. The PX domain is required for PLD1 translocation, mTORC1 activation, and cell size regulation. Finally, we show that the hVps34-PLD1 pathway acts independently of, and in parallel to, the Rag pathway in regulating amino acid activation of mTORC1.     

Nadrin GAP activity is isoform- and target-specific regulated by tyrosine phosphorylation

Cytoskeletal reorganization is crucial for platelet adhesion and thrombus formation to avoid excessive bleeding. Major regulators of cytoskeletal dynamics are small GTPases of the Rho family. Rho GTPases become activated by G-protein coupled receptor activation, downstream of immunoreceptor tyrosine-based activation motif (ITAM)-coupled receptors and by outside-in signaling of integrins. They act as molecular switches and cycle between active and inactive states. GTPase activating proteins (GAPs) stimulate the hydrolysis of GTP to GDP to terminate Rho signaling. Nadrin is a RhoGAP that was recently identified in platelets. Five Nadrin isoforms are known consisting of a unique GAP and an N-terminal BAR domain responsible for the selective regulation of RhoA, Cdc42 and Rac1. Besides BAR domain mediated regulation of Nadrin GAP activity nothing is known about the regulation of Nadrin and the impact on cytoskeletal reorganization. Here we show that Nadrin becomes tyrosine phosphorylated upon platelet activation. We found Src family proteins (Src, Lyn, Fyn) to be responsible to control Nadrin GAP activity by phosphorylation. Interestingly, phosphorylation of Nadrin leads to tightly regulated Rho activation that was found to be Nadrin isoform- and (Rho) target-specific. Src-phosphorylation of Nadrin5 mediated inactivation of Cdc42 while RhoA and Rac1 became activated upon Src-mediated phosphorylation of Nadrin2. Our results suggest a critical role for spatial and temporal regulation of Nadrin and thus for the control of Rho GTPases in platelets.     

Mechanism of membrane binding of the phospholipase D1 PX domain

Mammalian phospholipases D (PLD), which catalyze the hydrolysis of phosphatidylcholine to phosphatidic acid (PA), have been implicated in various cell signaling and vesicle trafficking processes. Mammalian PLD1 contains two different membrane-targeting domains, pleckstrin homology and Phox homology (PX) domains, but the precise roles of these domains in the membrane binding and activation of PLD1 are still unclear. To elucidate the role of the PX domain in PLD1 activation, we constructed a structural model of the PX domain by homology modeling and measured the membrane binding of this domain and selected mutants by surface plasmon resonance analysis. The PLD1 PX domain was found to have high phosphoinositide specificity, i.e. phosphatidylinositol 3,4,5-trisphosphate (PtdIns-(3,4,5)P(3)) > phosphatidylinositol 3-phosphate > phosphatidylinositol 5-phosphate > other phosphoinositides. The PtdIns(3,4,5)P(3) binding was facilitated by the cationic residues (Lys(119), Lys(121), and Arg(179)) in the putative binding pocket. Consistent with the model structure that suggests the presence of a second lipid-binding pocket, vesicle binding studies indicated that the PLD1 PX domain could also bind with moderate affinity to PA, phosphatidylserine, and other anionic lipids, which were mediated by a cluster of cationic residues in the secondary binding site. Simultaneous occupancy of both binding pockets synergistically increases membrane affinity of the PX domain. Electrostatic potential calculations suggest that a highly positive potential near the secondary binding site may facilitate the initial adsorption of the domain to the anionic membrane, which is followed by the binding of PtdIns(3,4,5)P(3) to its binding pocket. Collectively, our results suggest that the interaction of the PLD1 PX domain with PtdIns(3,4,5)P(3) and/or PA (or phosphatidylserine) may be an important factor in the spatiotemporal regulation and activation of PLD1.     

Regulation of phospholipase D1 subcellular cycling through coordination of multiple membrane association motifs

The signaling enzyme phospholipase D1 (PLD1) facilitates membrane vesicle trafficking. Here, we explore how PLD1 subcellular localization is regulated via Phox homology (PX) and pleckstrin homology (PH) domains and a PI4,5P2-binding site critical for its activation. PLD1 localized to perinuclear endosomes and Golgi in COS-7 cells, but on cellular stimulation, translocated to the plasma membrane in an activity-facilitated manner and then returned to the endosomes. The PI4,5P2-interacting site sufficed to mediate outward translocation and association with the plasma membrane. However, in the absence of PX and PH domains, PLD1 was unable to return efficiently to the endosomes. The PX and PH domains appear to facilitate internalization at different steps. The PH domain drives PLD1 entry into lipid rafts, which we show to be a step critical for internalization. In contrast, the PX domain appears to mediate binding to PI5P, a lipid newly recognized to accumulate in endocytosing vesicles. Finally, we show that the PH domain-dependent translocation step, but not the PX domain, is required for PLD1 to function in regulated exocytosis in PC12 cells. We propose that PLD1 localization and function involves regulated and continual cycling through a succession of subcellular sites, mediated by successive combinations of membrane association interactions.     

The sphingolipid degradation product trans-2-hexadecenal induces cytoskeletal reorganization and apoptosis in a JNK-dependent manner

The bioactive signaling molecule d-erythro-sphingosine-1-phosphate (S1P) is irreversibly degraded by the enzyme S1P lyase (SPL). The reaction of SPL with C18-S1P generates ethanolamine phosphate and a long-chain fatty aldehyde, trans-2-hexadecenal. Modulation of SPL expression in cells and organisms produces significant phenotypes, most of which have been attributed to corresponding changes in S1P-dependent signaling. However, the physiological functions of SPL products are not well understood. In the present study, we explored the biological activities of trans-2-hexadecenal in human and murine cells. We demonstrate that trans-2-hexadecenal causes cytoskeletal reorganization leading to cell rounding, detachment and eventual cell death by apoptosis in multiple cell types, including HEK293T, NIH3T3 and HeLa cells. Trans-2-hexadecenal stimulated a signaling pathway involving MLK3 and the respective phosphorylation of MKK4/7 and JNK, whereas ERK, AKT and p38 were unaffected. Trans-2-hexadecenal-induced apoptosis was accompanied by activation of downstream targets of JNK including c-Jun phosphorylation, cytochrome c release, Bax activation, Bid cleavage and increased translocation of Bim into mitochondria. The antioxidant N-acetylcysteine prevented JNK activation by trans-2-hexadecenal. Further, inhibition of JNK abrogated the cytoskeletal changes and apoptosis caused by trans-2-hexadecenal, whereas Rac1 and RhoA were not involved. In conclusion, our studies provide a new paradigm of sphingolipid signaling by demonstrating for the first time that S1P metabolism generates a bioactive product that induces cellular effects through oxidant stress-dependent MAP kinase cell signaling.     

Increased cell growth due to a new lipase-GEF (Phospholipase D2) fastly acting on Ras

We report the novel finding that Phospholipase D2 (PLD2), through its PX and PH domains, binds specifically to Ras and catalyzes the GDP/GTP exchange (i.e., is a GEF), with potency comparable to Ras-GRF-1, a known Ras-GEF. Cells overexpressing PLD2-GEF inactive mutants (F129Y and R172C/L173A) fail to stimulate cell proliferation compared to the wild type-expressing cells. The GEF effect on Ras follows a faster kinetics than other GTPase substrates (such as Rac2 or Rac1) and is a better substrate, too. The GEF action is due to PLD2 (protein) itself, independent of the lipase product PA. PA can still have a fine-tuning regulatory effect on Ras-GTP depending upon its cellular concentration. Rapidly growing human breast cancer cells MDA-MB 231 (but not the slow growing MCF7 counterpart) have high levels of endogenous PLD2-GEF which correlates with high Ras activation. The PLD2-“GEF” activity is even higher than the classical “lipase” activity and is abrogated with GEF single point mutants, particularly F129Y, and concomitantly with a slow rate of cell growth. This can be crucial to cancer biology in that not only Ras mutations explain abnormal growth, but the existence of a new GEF for Ras: a GEF molecule that happens to be a phospholipase.     

Cell invasion of highly metastatic MTLn3 cancer cells is dependent on phospholipase D2 (PLD2) and Janus kinase 3 (JAK3)

MTLn3 cells are highly invasive breast adenoacarcinoma cells. The relative level of the epidermal-growth-factor-stimulated invasion of this cell line is greater than two other breast cancer cell lines (MDA-MB-231 and MCF-7) and one non-small cell lung cancer cell line (H1299). We have determined that the mechanism of cancer cell invasion involves the presence of an enzymatically active phospholipase D (PLD), with the PLD2 isoform being more relevant than PLD1. PLD2 silencing abrogated invasion, whereas ectopic expression of PLD2 augmented cell invasion in all four cell lines, with an efficacy (MTLn3 ± MDA-MB-231 > H1299 ± MCF-7) that correlated well with their abilities to invade Matrigel in vitro. We also report that PLD2 is under the control of Janus kinase 3 (JAK3), with the kinase phosphorylating PLD2 at the Y415 residue, thus enabling its activation. Y415 is located downstream of a PH domain and upstream of the catalytic HKD-1 domain of PLD2. JAK3 knockdown abrogated lipase activity and epidermal-growth-factor-stimulated cell invasion directly. For the purposes of activating PLD2 for cell invasion, JAK3 operates via an alternative pathway that is independent of STAT, at least in MTLn3 cells. We also consistently found that JAK3 and PLD2 pathways are utilized at the maximum efficiency (phosphorylation and activity) in highly invasive MTLn3 cells versus a relatively low utilization in the less invasive MCF-7 cell line. In summary, a high level of cell invasiveness of cancer cells can be explained for the first time by combined high JAK3/PLD2 phosphorylation and activity involving PLD2's Y415 residue, which might constitute a novel target to inhibit cancer cell invasion.     

The exquisite regulation of PLD2 by a wealth of interacting proteins: S6K, Grb2, Sos, WASp and Rac2 (and a surprise discovery: PLD2 is a GEF)

Phospholipase D (PLD) catalyzes the conversion of the membrane phospholipid phosphatidylcholine to choline and phosphatidic acid (PA). PLD's mission in the cell is two-fold: phospholipid turnover with maintenance of the structural integrity of cellular/intracellular membranes and cell signaling through PA and its metabolites. Precisely, through its product of the reaction, PA, PLD has been implicated in a variety of physiological cellular functions, such as intracellular protein trafficking, cytoskeletal dynamics, chemotaxis of leukocytes and cell proliferation. The catalytic (HKD) and regulatory (PH and PX) domains were studied in detail in the PLD1 isoform, but PLD2 was traditionally studied in lesser detail and much less was known about its regulation. Our laboratory has been focusing on the study of PLD2 regulation in mammalian cells. Over the past few years, we have reported, in regards to the catalytic action of PLD, that PA is a chemoattractant agent that binds to and signals inside the cell through the ribosomal S6 kinases (S6K). Regarding the regulatory domains of PLD2, we have reported the discovery of the PLD2 interaction with Grb2 via Y169 in the PX domain, and further association to Sos, which results in an increase of de novo DNA synthesis and an interaction (also with Grb2) via the adjacent residue Y179, leading to the regulation of cell ruffling, chemotaxis and phagocytosis of leukocytes. We also present the complex regulation by tyrosine phosphorylation by epidermal growth factor receptor (EGF-R), Janus Kinase 3 (JAK3) and Src and the role of phosphatases. Recently, there is evidence supporting a new level of regulation of PLD2 at the PH domain, by the discovery of CRIB domains and a Rac2-PLD2 interaction that leads to a dual (positive and negative) effect on its enzymatic activity. Lastly, we review the surprising finding of PLD2 acting as a GEF. A phospholipase such as PLD that exists already in the cell membrane that acts directly on Rac allows a quick response of the cell without intermediary signaling molecules. This provides only the latest level of PLD2 regulation in a field that promises newer and exciting advances in the next few years.     

Angiostatin effects on endothelial cells mediated by ceramide and RhoA

Angiostatin is a cleavage product of plasminogen that has anti-angiogenic properties. We investigated whether the effects of angiostatin on endothelial cells are mediated by ceramide, a lipid implicated in endothelial cell signaling. Our results demonstrate that angiostatin produces a transient increase in ceramide that correlates with actin stress fiber reorganization, detachment and death. DNA array expression analysis performed on ceramide-treated human endothelial cells demonstrated induction of certain genes involved in cytoskeleton organization. Specifically, we report that treatment with angiostatin or ceramide results in the activation of RhoA, an important effector of cytoskeletal structure. We also show that treatment of endothelial cells with the antioxidant N-acetylcysteine abrogates morphological changes and cytotoxic effects of treatment with angiostatin or ceramide. These findings support a model in which angiostatin induces a transient rise in ceramide, RhoA activation and free radical production.     

The Grb2/PLD2 interaction is essential for lipase activity, intracellular localization and signaling in response to EGF

The adaptor protein Grb2 associates with phospholipase D2 (PLD2), but it is not known if this interaction is necessary for the functionality of the lipase in vivo. We demonstrate that stable short hairpin RNA (shRNA)-based silencing of Grb2, a critical signal transducer of the epidermal growth factor receptor (EGFR) and linker to the Ras/Erk pathway, resulted in the reduction of PLD2 activity in COS7 cells. Transfection of a Grb2 construct refractory to shGrb2 silencing (XGrb2(SiL)) into the Grb2-knockdown cells (COS7(shGrb2)), resulted in the nearly full rescue of PLD2 activity. However, Grb2-R86K, an SH2-deficient mutant of Grb2 that is incapable of binding to PLD2, failed to induce an enhancement of the impaired PLD2 activity in COS7(shGrb2) cells. Grb2 and PLD2 are directly associated and Grb2 is brought down with anti-myc antibodies irrespective of the presence or absence of EGFR activation. Immunofluorescence microscopy showed that co-transfected PLD2 and Grb2 re-localize to Golgi-like structures after EGF stimulation. Since this was not observed in cotransfection experiments with Grb2 and PLD2-Y169/179F, a lipase mutant that does not bind to Grb2, we inferred that Grb2 serves to hijack PLD2 to the perinuclear Golgi region through its SH2 domain. Supporting this is the finding that the primary cell line HUVEC expresses PLD2 diffusely in the cytoplasm and in the perinuclear Golgi region, where PLD2 and Grb2 colocalize. Such colocalization in primary cells increased after stimulation with EGF. These results demonstrate for the first time that the presence of Grb2 and its interaction with localized intracellular structures is essential for PLD2 activity and signaling in vivo.     

Protease-activated receptor mediated RhoA signaling and cytoskeletal reorganization in LNCaP cells

Thrombin and trypsin induce cell signaling through a subclass of G-protein-coupled receptors called the protease-activated receptors (PARs). In many cells, PAR signaling results in the activation of RhoA and other members of the Rho family of small GTPases which are involved in cytoskeletal reorganization. The expression of PARs and their role in the activation of Rho GTPases in prostate cancer cells are not clearly known. FACS analysis demonstrated that the androgen-dependent LNCaP cells express PAR1, PAR2, and PAR4 but not PAR3. Stimulation with thrombin and trypsin resulted in the rapid activation of RhoA in a dose-dependent manner with an EC(50) of 1.0 and 5 nM, respectively. Activation of RhoA was enhanced by, but not dependent on, the presence of 1 nM dihydrotestosterone. Inhibition of the proteolytic properties of thrombin by hirudin and trypsin by diisopropyl fluorophosphate abolished the observed RhoA activation. Stimulation with 150 microM PAR-activating peptides TFFLRN (PAR1), SLIGKV (PAR2), and AYPGKF (PAR4) demonstrated that PAR1 and PAR2 mediated protease-activated RhoA signaling. Fluorescent microscopy studies showed that LNCaP cells treated with either thrombin (10 nM) or trypsin (10 nM) developed an increased number of filopodia, stress fibers, and focal adhesions relative to untreated cells. These observations represent the first report of PAR signaling in prostate cancer cells as well as the ability of PAR2 to mediate RhoA activation. Since the activation of RhoA is important for cytoskeletal reorganization, we postulate that PAR-mediated RhoA activation may be a major signaling pathway in the biology of prostate cancer.     

Protein kinase C induces actin reorganization via a Src- and Rho-dependent pathway

We have investigated the mechanism of PKC-induced actin reorganization in A7r5 vascular smooth muscle cells. PKC activation by 12-O-tetradecanoylphorbol-13-acetate induces the disassembly of actin stress fibers concomitant with the appearance of membrane ruffles. PKC also induces rapid tyrosine phosphorylation in these cells. As we could show, utilizing the Src-specific inhibitor PP2 and a kinase-deficient c-Src mutant, actin reorganization is dependent on PKC-induced Src activation. Subsequently, the activity of the small G-protein RhoA is decreased, whereas Rac and Cdc42 activities remain unchanged. Disassembly of actin stress fibers could also be observed using the Rho kinase-specific inhibitor Y-27632, indicating that the decrease in RhoA activity on its own is responsible for actin reorganization. In addition, we show that tyrosine phosphorylation of p190RhoGAP is increased upon 12-O-tetradecanoylphorbol-13-acetate stimulation, directly linking Src activation to a decrease in RhoA activity. Our data provide substantial evidence for a model elucidating the molecular mechanisms of PKC-induced actin rearrangements.