Jean-Pierre Estève

Ectopic |[beta]|-chain of ATP synthase is an apolipoprotein A-I receptor in hepatic HDL endocytosis

The effect of high-density lipoprotein (HDL) in protecting against atherosclerosis is usually attributed to its role in ‘reverse cholesterol transport’. In this process, HDL particles mediate the efflux and the transport of cholesterol from peripheral cells to the liver for further metabolism and bile excretion. Thus, cell-surface receptors for HDL on hepatocytes are chief partners in the regulation of cholesterol homeostasis. A high-affinity HDL receptor for apolipoprotein A-I (apoA-I) was previously identified on the surface of hepatocytes. Here we show that this receptor is identical to the β-chain of ATP synthase, a principal protein complex of the mitochondrial inner membrane. Different experimental approaches confirm this ectopic localization of components of the ATP synthase complex and the presence of ATP hydrolase activity at the hepatocyte cell surface. Receptor stimulation by apoA-I triggers the endocytosis of holo-HDL particles (protein plus lipid) by a mechanism that depends strictly on the generation of ADP. We confirm this effect on endocytosis in perfused rat liver ex vivo by using a specific inhibitor of ATP synthase. Thus, membrane-bound ATP synthase has a previously unsuspected role in modulating the concentrations of extracellular ADP and is regulated by a principal plasma apolipoprotein.

The Tyrosine Phosphatase SHP-1 Associates with the sst2 Somatostatin Receptor and Is an Essential Component of sst2-mediated Inhibitory Growth Signaling

Activation of the somatostatin receptor sst2, a member of the Gi protein-coupled receptor family, results in the stimulation of a protein-tyrosine phosphatase activity involved in the sst2-mediated growth inhibitory signal. Here, we report that SHP-1, a cytoplasmic protein-tyrosine phosphatase containing two Src homology 2 domains constitutively associated with sst2 as evidence by coprecipitation of SHP-1 protein with sst2, in Chinese hamster ovary cells coexpressing sst2 and SHP-1. Activation of sst2 by somatostatin resulted in a rapid dissociation of SHP-1 from sst2 accompanied by an increase of SHP-1 activity. SHP-1 was phosphorylated on tyrosine in control cells and somatostatin induced a rapid and transient dephosphorylation on tyrosine residues of the enzyme. Stimulation of SHP-1 activity by somatostatin was abolished by pertussis toxin pretreatment of cells. Giα3 was specifically immunoprecipitated by anti-sst2 and anti-SHP-1 antibodies, and somatostatin induced a rapid dissociation of Giα3 from sst2, suggesting that Giα3 may be involved in the sst2·SHP-1 complexes. Finally, somatostatin inhibited the proliferation of cells coexpressing sst2 and SHP-1, and this effect was suppressed in cells coexpressing sst2 and the catalytic inactive SHP-1 (C453S mutant). Our data identify SHP-1 as the tyrosine phosphatase associated with sst2 and demonstrate that this enzyme may be an initial key transducer of the antimitogenic signaling mediated by sst2.

Porphyrin Derivatives for Telomere Binding and Telomerase Inhibition

The capacity of G‐quadruplex ligands to stabilize four‐stranded DNA makes them able to inhibit telomerase, which is involved in tumour cell proliferation. A series of cationic metalloporphyrin derivatives was prepared by making variations on a meso‐tetrakis(4‐N‐methyl‐pyridiniumyl)porphyrin skeleton (TMPyP). The DNA binding properties of nickel(II) and manganese(III) porphyrins were studied by surface plasmon resonance, and the capacity of the nickel porphyrins to inhibit telomerase was tested in a TRAP assay. The nature of the metal influences the kinetics (the process is faster for Ni than for Mn) and the mode of interaction (stacking or external binding). The chemical alterations did not lead to increased telomerase inhibition. The best selectivity for G‐quadruplex DNA was observed for Mn‐TMPyP, which has a tenfold preference for quadruplex over duplex.

sst2 Somatostatin receptor inhibits cell proliferation through Ras-, Rap1-, and B-Raf-dependent ERK2 activation

The G protein-coupled sst2 somatostatin receptor is a critical negative regulator of cell proliferation. sstII prevents growth factor-induced cell proliferation through activation of the tyrosine phosphatase SHP-1 leading to induction of the cyclin-dependent kinase inhibitor p27Kip1. Here, we investigate the signaling molecules linking sst2 to p27Kip1. In Chinese hamster ovary-DG-44 cells stably expressing sst2 (CHO/sst2), the somatostatin analogue RC-160 transiently stimulates ERK2 activity and potentiates insulin-stimulated ERK2 activity. RC-160 also stimulates ERK2 activity in pancreatic acini isolated from normal mice, which endogenously express sst2, but has no effect in pancreatic acini derived from sst2 knock-out mice. RC-160-induced p27Kip1 up-regulation and inhibition of insulin-dependent cell proliferation are both prevented by pretreatment of CHO/sst2 cells with the MEK1/2 inhibitor PD98059. In addition, using dominant negative mutants, we show that sst2-mediated ERK2 stimulation is dependent on the pertussis toxin-sensitive Gi/o protein, the tyrosine kinase Src, both small G proteins Ras and Rap1, and the MEK kinase B-Raf but is independent of Raf-1. Phosphatidylinositol 3-kinase (PI3K) and both tyrosine phosphatases, SHP-1 and SHP-2, are required upstream of Ras and Rap1. Taken together, our results identify a novel mechanism whereby a Gi/o protein-coupled receptor inhibits cell proliferation by stimulating ERK signaling via a SHP-1-SHP-2-PI3K/Ras-Rap1/B-Raf/MEK pathway.

Direct binding of p85 to sst2 somatostatin receptor reveals a novel mechanism for inhibiting PI3K pathway

Phosphatidylinositol 3‐kinase (PI3K) regulates many cellular functions including growth and survival, and its excessive activation is a hallmark of cancer. Somatostatin, acting through its G protein‐coupled receptor (GPCR) sst2, has potent proapoptotic and anti‐invasive activities on normal and cancer cells. Here, we report a novel mechanism for inhibiting PI3K activity. Somatostatin, acting through sst2, inhibits PI3K activity by disrupting a pre‐existing complex comprising the sst2 receptor and the p85 PI3K regulatory subunit. Surface plasmon resonance and molecular modeling identified the phosphorylated‐Y71 residue of a p85‐binding pYXXM motif in the first sst2 intracellular loop, and p85 COOH‐terminal SH2 as direct interacting domains. Somatostatin‐mediated dissociation of this complex as well as p85 tyrosine dephosphorylation correlates with sst2 tyrosine dephosphorylation on the Y71 residue. Mutating sst2‐Y71 disabled sst2 to interact with p85 and somatostatin to inhibit PI3K, consequently abrogating sst2s ability to suppress cell survival and tumor growth. These results provide the first demonstration of a physical interaction between a GPCR and p85, revealing a novel mechanism for negative regulation by ligand‐activated GPCR of PI3K‐dependent survival pathways, which may be an important molecular target for antineoplastic therapy.

A Novel Protein-Protein Interaction between a G Protein-coupled Receptor and the Phosphatase SHP-2 Is Involved in Bradykinin-induced Inhibition of Cell Proliferation

Mitogenic G protein-coupled receptor (GPCR) signaling has been extensively studied. In contrast, little is known about anti-mitogenic GPCR signaling. We show here that anti-mitogenic signaling of a GPCR, the bradykinin B2 receptor, involves a novel direct protein-protein interaction. The antiproliferative effect of bradykinin was accompanied by a transient increase in protein-tyrosine phosphatase activity. Using surface plasmon resonance analysis, we observed that an immunoreceptor tyrosine-based inhibitory motif (ITIM) located in the C-terminal part of the B2 receptor interacted specifically with the protein-tyrosine phosphatase SHP-2. The interaction was confirmed in primary culture renal mesangial cells by co-immunoprecipitation of a B2 receptor·SHP-2 complex. The extent of the interaction was transiently increased by stimulation with bradykinin, which was accompanied by an increase in specific SHP-2 phosphatase activity. Mutational analysis of the key ITIM residue confirmed that the B2 receptor ITIM sequence is required for interaction with SHP-2, SHP-2 activation, and the anti-mitogenic effect of bradykinin. Finally, in mesangial cells transfected with a dominant-negative form of SHP-2, bradykinin lost the ability to inhibit cell proliferation. These observations demonstrate that bradykinin inhibits cell proliferation by a novel mechanism involving a direct protein-protein interaction between a GPCR (the B2 receptor) and SHP-2.

Induction of a negative autocrine loop by expression of sst2 somatostatin receptor in NIH 3T3 cells.

The somatostatin receptor subtype sst2 mediates both activation of a tyrosine phosphatase activity and inhibition of cell proliferation induced by somatostatin analogues. In the absence of exogenous ligand, expression of sst2 in NIH 3T3 cells resulted in inhibition of cell growth. Polymerase chain reaction coupled to reverse transcription demonstrated that expression of sst2 in NIH 3T3 cells stimulated the expression of preprosomatostatin mRNA accompanied by a production of immunoreactive somatostatin-like peptide which corresponded predominantly to somatostatin 14. Moreover anti-somatostatin antibodies suppressed sst2-promoted inhibition of cell proliferation. Inhibition of cell proliferation associated with increased secretion of somatostatin-like immunoreactivity was also observed after expression of sst2 in human pancreatic tumor cells BxPC3 devoid of endogenous receptors. In addition, expression of sst2 in NIH 3T3 cells was associated with constitutive activation of tyrosine phosphatase PTP1C that resulted from enhanced expression of the protein. Blocking of PTP1C tyrosine phosphatase activity with orthovanadate or that of PTP1C protein with antisense PTP1C oligonucleotides decreased the sst2-induced inhibition of cell proliferation. These results, taken together, show that expression of sst2 in NIH 3T3 cells generated a negative autocrine loop by stimulating sst2 ligand production and amplifying PTP1C sst2-transducer. Sst2/ligand may function as a determinant factor involved in the negative growth control of cells.

Neuronal nitric oxide synthase: a substrate for SHP-1 involved in sst2 somatostatin receptor growth inhibitory signaling

Somatostatin receptor sst2 is an inhibitory G protein‐coupled receptor, which inhibits normal and tumor cell growth by a mechanism involving the tyrosine phosphatase SHP‐1. We reported previously that SHP‐1 associates transiently with and is activated by sst2 and is a critical component for sst2 growth inhibitory signaling. Here, we demonstrate that in Chinese hamster ovary cells expressing sst2, SHP‐1 is associated at the basal level with the neuronal nitric oxide synthase (nNOS). Following sst2 activation by the somatostatin analog RC‐160, SHP‐1 rapidly recruits nNOS tyrosine dephosphorylates and activates it. The resulting NO activates guanylate cyclase and inhibits cell proliferation. Coexpression of a catalytically inactive SHP‐1 mutant with sst2 blocks RC‐160‐induced nNOS dephosphorylation and activation, as well as guanylate cyclase activation. In mouse pancreatic acini, RC‐160 treatment reduces nNOS tyrosine phosphorylation accompanied by an increase of its activity. By opposition, in acini from viable motheaten (mev/mev) mice, which express a markedly inactive SHP‐1, RC‐160 has no effect on nNOS activity. Finally, expression of a dominant‐negative form of nNOS prevents both RC‐160‐induced p27 up‐regulation and cell proliferation inhibition. We therefore identified nNOS as a novel SHP‐1 substrate critical for sst2‐induced cell‐growth arrest.

Molecular mechanisms of antiproliferative effect of somatostatin: Involvement of a tyrosine phosphatase

A protein of 66 kd immunoreactive to anti-tyrosine phosphatase (PTP1C) antibodies coeluted with, and so may be associated with, somatostatin receptors (ssts) from rat pancreatic membranes. Also, anti-PTP1C antibodies immunoprecipitated functional ssts from pancreatic membranes, suggesting a PTP1C protein can associate with ssts at the membrane level. Somatostatin analog RC 160 had good affinity for sst2,3 and sst5 (IC50 = 0.2, 0.1, and 21 nmol/L) and low affinity for sst1 and sst4 (IC50 = 200 and 620 nmol/L), and induced rapid dose-dependent stimulation of PTP activity (maximal at 1 nmol/L and half maximal at 5 pmol/L) in NIH3T3 and CHO cells expressing sst2, with similar results for sst1, but no stimulation with sst3,4 or sst5. Treatment of cells expressing sst2 with RC 160 for 24 hours inhibited serum- or growth factor-induced cell proliferation dose-dependently (maximal at 1 nmol/L, half maximal at 6 to 53 pmol/L RC 160). In cells expressing sst1, weak inhibition of fibroblast growth factor 2-induced NIH3T3 cell proliferation was provoked by somatostatin analogs (> 10 nmol/L). The good correlation between inhibition of somatostatin binding, stimulation of PTP activity, and inhibition of cell proliferation implicates a PTP in growth inhibition mediated by sst2 and sst1.

Juvenile hormone binding protein traffic - Interaction with ATP synthase and lipid transfer proteins.

Juvenile hormone (JH) controls insect development, metamorphosis and reproduction. In insect hemolymph a significant proportion of JH is bound to juvenile hormone binding protein (JHBP), which serves as a carrier supplying the hormone to the target tissues. To shed some light on JHBP passage within insect tissues, the interaction of this carrier with other proteins from Galleria mellonella (Lepidoptera) was investigated. Our studies revealed the presence of JHBP within the tracheal epithelium and fat body cells in both the membrane and cytoplasmic sections. We found that the interaction between JHBP and membrane proteins occurs with saturation kinetics and is specific and reversible. ATP synthase was indicated as a JHBP membrane binding protein based upon SPR-BIA and MS analysis. It was found that in G. mellonella fat body, this enzyme is present in mitochondrial fraction, plasma membranes and cytosol as well. In the model system containing bovine F(1) ATP synthase and JHBP, the interaction between these two components occurs with K(d)=0.86 nM. In hemolymph we detected JHBP binding to apolipophorin, arylphorin and hexamerin. These results provide the first demonstration of the physical interaction of JHBP with membrane and hemolymph proteins which can be involved in JHBP molecule traffic.