Sonia Paris

Toxin-induced activation of the G protein p21 Rho by deamidation of glutamine

Pathogenic Escherichia coli are responsible for a variety of diseases, including diarrhoea, haemolytic uraemic syndrome, kidney infection, septicaemia, pneumonia and meningitis. Toxins called cytotoxic necrotizing factors (CNFs) are among the virulence factors produced by uropathogenic (CNF1) or enteropathogenic (CNF2) E. coli strains that cause diseases in humans and animals, respectively. CNFs induce an increase in the content of actin stress fibres and focal contacts in cultured cells,. Effects of CNFs on the actin cytoskeleton correlated with a decrease in the electrophoretic mobility of the GTP-binding protein Rho, and indirect evidence indicates that CNF1 might constitutively activate Rho. Here we show that CNF1 catalyses the deamidation of a glutamine residue at position 63 of Rho, turning it into glutamic acid, which inhibits both intrinsic GTP hydrolysis and that stimulated by its GTPase-activating protein (GAP). Thus, this deamidation of glutamine 63 by CNF1 leads to the constitutive activation of Rho, and induces the reorganization of actin stress fibres. To our knowledge, CNF1 is the first example of a bacterial toxin acting by deamidation of a specific target protein.

A glutamic finger in the guanine nucleotide exchange factor ARNO displaces Mg2+ and the beta-phosphate to destabilize GDP on ARF1.

The Sec7 domain of the guanine nucleotide exchange factor ARNO (ARNO‐Sec7) is responsible for the exchange activity on the small GTP‐binding protein ARF1. ARNO‐Sec7 forms a stable complex with the nucleotide‐free form of [Δ17]ARF1, a soluble truncated form of ARF1. The crystal structure of ARNO‐Sec7 has been solved recently, and a site‐directed mutagenesis approach identified a hydrophobic groove and an adjacent hydrophilic loop as the ARF1‐binding site. We show that Glu156 in the hydrophilic loop of ARNO‐Sec7 is involved in the destabilization of Mg2+ and GDP from ARF1. The conservative mutation E156D and the charge reversal mutation E156K reduce the exchange activity of ARNO‐Sec7 by several orders of magnitude. Moreover, [E156K]ARNO‐Sec7 forms a complex with the Mg2+‐free form of [Δ17]ARF1‐GDP without inducing the release of GDP. Other mutations in ARNO‐Sec7 and in [Δ17]ARF1 suggest that prominent hydrophobic residues of the switch I region of ARF1 insert into the groove of the Sec7 domain, and that Lys73 of the switch II region of ARF1 forms an ion pair with Asp183 of ARNO‐Sec7.

Role of Protein-Phospholipid Interactions in the Activation of ARF1 by the Guanine Nucleotide Exchange Factor Arno

Arno is a 47-kDa human protein recently identified as a guanine nucleotide exchange factor for ADP ribosylation factor 1 (ARF1) with a central Sec7 domain responsible for the exchange activity and a carboxyl-terminal pleckstrin homology (PH) domain (Chardin, P., Paris, S., Antonny, B., Robineau, S., Béraud-Dufour, S., Jackson, C. L., and Chabre, M. (1996)Nature 384, 481–484). Binding of the PH domain to phosphatidylinositol 4,5-bisphosphate (PIP2) greatly enhances Arno-mediated activation of myristoylated ARF1. We show here that in the absence of phospholipids, Arno promotes nucleotide exchange on [Δ17]ARF1, a soluble mutant of ARF1 lacking the first 17 amino acids. This reaction is unaffected by PIP2, which suggests that the PIP2-PH domain interaction does not directly regulate the catalytic activity of Arno but rather serves to recruit Arno to membranes. Arno catalyzes the release of GDP more efficiently than that of GTP from [Δ17]ARF1, and a stable complex between Arno Sec7 domain and nucleotide-free [Δ17]ARF1 can be isolated. In contrast to [Δ17]ARF1, full-length unmyristoylated ARF1 is not readily activated by Arno in solution. Its activation requires the presence of phospholipids and a reduction of ionic strength and Mg2+ concentration. PIP2 is strongly stimulatory, indicating that binding of Arno to phospholipids is involved, but in addition, electrostatic interactions between phospholipids and the amino-terminal portion of unmyristoylated ARF1GDP seem to be important. We conclude that efficient activation of full-length ARF1 by Arno requires a membrane surface and two distinct protein-phospholipid interactions: one between the PH domain of Arno and PIP2, and the other between amino-terminal cationic residues of ARF1 and anionic phospholipids. The latter interaction is normally induced by insertion of the amino-terminal myristate into the bilayer but can also be artificially facilitated by decreasing Mg2+ and salt concentrations.

Activation of ADP-ribosylation Factor 1 GTPase-Activating Protein by Phosphatidylcholine-derived Diacylglycerols

Disassembly of the coatomer from Golgi vesicles requires that the small GTP-binding protein ADP-ribosylation factor 1 (ARF1) hydrolyzes its bound GTP by the action of a GTPase-activating protein. In vitro, the binding of the ARF1 GTPase-activating protein to lipid vesicles and its activity on membrane-bound ARF1GTP are increased by diacylglycerols with monounsaturated acyl chains, such as those arising in vivo as secondary products from the hydrolysis of phosphatidylcholine by ARF-activated phospholipase D. Thus, the phospholipase D pathway may provide a feedback mechanism that promotes GTP hydrolysis on ARF1 and the consequent uncoating of vesicles.

Myristoylation-facilitated Binding of the G Protein ARF1 to Membrane Phospholipids Is Required for Its Activation by a Soluble Nucleotide Exchange Factor

We have investigated the role of N-myristoylation in the activation of bovine ADP-ribosylation factor 1 (ARF1). We previously showed that myristoylation allows some spontaneous GDP-to-GTP exchange to occur on ARF1 at physiological Mg levels in the presence of phospholipid vesicles (Franco, M., Chardin, P., Chabre, M., and Paris, S.(1995) J. Biol. Chem. 270, 1337-1341). Here, we report that this basal nucleotide exchange can be accelerated (by up to 5-fold) by addition of a soluble fraction obtained from bovine retinas. This acceleration is totally abolished by brefeldin A (IC = 2 μM) and by trypsin treatment of the retinal extract, as expected for an ARF-specific guanine nucleotide exchange factor. To accelerate GDP release from ARF1, this soluble exchange factor absolutely requires myristoylation of ARF1 and the presence of phospholipid vesicles. The retinal extract also stimulates guanosine 5′-3-O-(thio)triphosphate (GTPS) release from ARF1 in the presence of phospholipids, but in this case myristoylation of ARF is not required. These observations, together with our previous findings that both myristoylated and nonmyristoylated forms of ARF but only the myristoylated form of ARF bind to membrane phospholipids, suggest that (i) the retinal exchange factor acts only on membrane-bound ARF, (ii) the myristate is not involved in the protein-protein interaction between ARF1 and the exchange factor, and (iii) N-myristoylation facilitates both spontaneous and catalyzed GDP-to-GTP exchange on ARF1 simply by facilitating the binding of ARF to membrane phospholipids.

Dual Interaction of ADP Ribosylation Factor 1 with Sec7 Domain and with Lipid Membranes during Catalysis of Guanine Nucleotide Exchange

Sec7 domains catalyze the replacement of GDP by GTP on the G protein ADP-ribosylation factor 1 (myrARF1) by interacting with its switch I and II regions and by destabilizing, through a glutamic finger, the β-phosphate of the bound GDP. The myristoylated N-terminal helix that allows myrARF1 to interact with membrane lipids in a GTP-dependent manner is located some distance from the Sec7 domain-binding region. However, these two regions are connected. Measuring the binding to liposomes of functional or abortive complexes between myrARF1 and the Sec7 domain of ARNO demonstrates that myrARF1, in complex with the Sec7 domain, adopts a high affinity state for membrane lipids, similar to that of the free GTP-bound form. This tight membrane attachment does not depend on the release of GDP induced by the Sec7 domain but is partially inhibited by the uncompetitive inhibitor brefeldin A. These results suggest that the conformational switch of the N-terminal helix of myrARF1 to the membrane-bound form is an early event in the nucleotide exchange pathway and is a prerequisite for a structural rearrangement at the myrARF1-GDP/Sec7 domain interface that allows the glutamic finger to expel GDP from myrARF1.

The small G‐protein ARF1GDP binds to the Gtβγ subunit of transducin, but not to GtαGDP‐Gtβγ

AlF4 − activates heterotrimeric G‐proteins Gα subunits but not small GDP/GTP‐binding proteins like ARF1. On retinal membranes containing holotransducin (Gt α GDP‐Gt βγ and incubated with ARFGDP, AlF4 − induced Gt α GDP‐AlF4 release and ARFGDP binding, probably to the remaining membrane‐attached Gt βγ. On phospholipid vesicles reconstitued with Gt βγ, ARFGDP bound in proportion to Gt βγ, and was released upon subsequent GtαGDP addition. Thus ARFGDP competes with GtαGDP for binding to Gtβγ, probably through a conserved motif in the ‘α2 helix’ of Gtα and ARF. This motif is found in the C‐terminal helix of PH domains that bind to Gβγ.