Expression of the type II voltage-dependent sodium channel gene is restricted to neurons by a silencer element active in nonneuronal cells. We have cloned cDNA coding for a transcription factor (REST) that binds to this silencer element. Expression of a recombinant REST protein confers the ability to silence type II reporter genes in neuronal cell types lacking the native REST protein, whereas expression of a dominant negative form of REST in nonneuronal cells relieves silencing mediated by the native protein. REST transcripts in developing mouse embryos are detected ubiquitously outside of the nervous system. We propose that expression of the type II sodium channel gene in neurons reflects a default pathway that is blocked in nonneuronal cells by the presence of REST.
PLD2 is a newly identified mammalian PLD isoform with novel regulatory properties. Our findings suggest that regulated secretion and morphological reorganization, the two most frequently proposed biological roles for PLD, are likely to be effected separately by PLD1 and PLD2.
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.
Insulin stimulates glucose uptake in fat and muscle by mobilizing Glut4 glucose transporters from intracellular membrane storage sites to the plasma membrane. This process requires the trafficking of Glut4-containing vesicles toward the cell periphery, docking at exocytic sites, and plasma membrane fusion. We show here that phospholipase D (PLD) production of the lipid phosphatidic acid (PA) is a key event in the fusion process. PLD1 is found on Glut4-containing vesicles, is activated by insulin signaling, and traffics with Glut4 to exocytic sites. Increasing PLD1 activity facilitates glucose uptake, whereas decreasing PLD1 activity is inhibitory. Diminished PA production does not substantially hinder trafficking of the vesicles or their docking at the plasma membrane, but it does impede fusion-mediated extracellular exposure of the transporter. The fusion block caused by RNA interference-mediated PLD1 deficiency is rescued by exogenous provision of a lipid that promotes fusion pore formation and expansion, suggesting that the step regulated by PA is late in the process of vesicle fusion. INTRODUCTIONInsulin-stimulated uptake of glucose by fat and muscle and the maintenance of glucose homeostasis are primarily mediated by the Glut4 glucose transporter (Bryant et al., 2002). Glut4 cycles between the plasma membrane and cytoplasmic storage sites, with most of the transporter residing intracellularly in the absence of insulin signaling because the basal rate of endocytosis exceeds the basal rate of exocytosis. Insulin signaling greatly stimulates the rate of exocytosis, leading to recruitment of up to 50% of the transporter to the cell surface where it facilitates glucose uptake. Each of the major elements of this regulated exocytosis process-vesicle mobilization, trafficking to the plasma membrane, docking, and fusion-have been shown to be rate limiting under different circumstances, and the mechanisms that regulate them remain under investigation.Phospholipase D (PLD), a membrane-associated enzyme regulated by agonist stimulation (reviewed in Frohman and Morris, 1999), has been proposed to function at many different steps in vesicle trafficking, including activation of signaling networks (Andresen et al., 2002), budding of vesicles from the trans-Golgi (Chen et al., 1997), and vesicle fusion (reviewed in McDermott et al., 2004). PLD generates the lipid phosphatidic acid (PA), which has been shown to activate phosphatidylinositol 4-phosphate 5-kinase (Honda et al., 1999) and thus increase the levels of phosphatidylinositol 4,5-bisphosphate, a lipid critically required for exocytosis (Di Paolo et al., 2004). PA also has been reported to serve as a membrane anchor for a growing number of protein targets (Manifava et al., 2001), including yeast and mammalian components of the soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) complex (Wagner and Tamm, 2001;Nakanishi et al., 2004), and it has been proposed to act as a fusogenic lipid in biophysical modeling studies by lowering the activation...
The mammalian phosphatidylcholine-specific phospholipase D (PLD) enzymes PLD1 and PLD2 have been proposed to play roles in signal transduction and membrane vesicular trafficking in distinct subcellular compartments. PLD1 is activated in a synergistic manner in vitro by protein kinase C-␣, ADP-ribosylation factor 1 (ARF1), and Rho family members. In contrast, PLD2 is constitutively active in vitro. We describe here molecular analysis of PLD2. We show that the NH 2 -terminal 308 amino acids are required for PLD2's characteristic high basal activity. Unexpectedly, PLD2 lacking this region becomes highly responsive to ARF proteins and displays a modest preference for activation by ARF5. Chimeric analysis of PLD1 and PLD2 suggests that the ARF-responsive region is in the PLD carboxyl terminus. We also inserted into PLD2 a region of sequence unique to PLD1 known as the "loop" region, which had been proposed initially to mediate effector stimulation but that subsequently was shown instead to be required in part for the very low basal activity characteristic of PLD1. The insertion decreased PLD2 activity, consistent with the latter finding. Finally, we show that the critical role undertaken by the conserved carboxyl terminus is unlikely to involve promoting PLD association with membrane surfaces.
Activation of phosphatidylcholine-specific phospholipase D (PLD) has been implicated as a critical step in numerous cellular pathways, including signal transduction, membrane trafficking, and the regulation of mitosis. We report here the identification of the first human PLD cDNA, which defines a new and highly conserved gene family. Characterization of recombinant human PLD1 reveals that it is membrane-associated, selective for phosphatidylcholine, stimulated by phosphatidylinositol 4,5-bisphosphate, activated by the monomeric G-protein ADP-ribosylation factor-1, and inhibited by oleate. PLD1 likely encodes the gene product responsible for the most widely studied endogenous PLD activity.
G protein-coupled and tyrosine kinase receptor activation of phospholipase D1 (PLD1) play key roles in agonist-stimulated cellular responses such as regulated exocytosis, actin stress fiber formation, and alterations in cell morphology and motility. Protein Kinase C, ADP-ribosylation factor (ARF), and Rho family members activate PLD1 in vitro; however, the actions of the stimulators on PLD1 in vivo have been proposed to take place through indirect pathways. We have used the yeast split-hybrid system to generate PLD1 alleles that fail to bind to or to be activated by RhoA but that retain wild-type responses to ARF and PKC. These alleles then were employed in combination with alleles unresponsive to PKC or to both stimulators to examine the activation of PLD1 by G protein-coupled receptors. Our results demonstrate that direct stimulation of PLD1 in vivo by RhoA (and by PKC) is critical for significant PLD1 activation but that PLD1 subcellular localization and regulated phosphorylation occur independently of these stimulatory pathways.
Activation of phosphatidylcholine-specific phospholipase D(PLD) occurs as part of the complex signal-transduction cascade initiated by agonist stimulation of tyrosine kinase and G-protein-coupled receptors. A variety of mammalian PLD activities have been described, and cDNAs for two PLDs recently reported (human PLD1 and murine PLD2). We describe here the cloning and chromosomal localization of murine PLD1. Northern-blot hybridization and RNase protection analyses were used to examine the expression of murine PLD1 and PLD2 ina variety of cell lines and tissues. PLD1 and PLD2 were expressed in all RNA samples examined, although the absolute expression of each isoform varied, as well as the ratio of PLD1 to PLD2. Moreover, in situ hybridization of adult brain and murine embryo sections revealed high levels of expression of individual PLDs in some cell types and no detectable expression in others. Thus the two PLDs probably carry out distinct roles in restricted subsets of cells rather than ubiquitous roles in all cells.
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