Your search keyword '"Oncogene Protein p21(ras) chemistry"' showing total 6 results

1. Structure of the G60A mutant of Ras: implications for the dominant negative effect.

Author

Ford B, Skowronek K, Boykevisch S, Bar-Sagi D, and Nassar N

Subjects

Alanine genetics, Animals, COS Cells, Chlorocebus aethiops, Crystallography, Glycine genetics, Guanosine Diphosphate metabolism, Guanosine Triphosphate metabolism, Mice, NIH 3T3 Cells, Oncogene Protein p21(ras) metabolism, Oocytes, Protein Binding, Protein Structure, Secondary, Protein Structure, Tertiary, Xenopus, Amino Acid Substitution, Oncogene Protein p21(ras) chemistry, Oncogene Protein p21(ras) genetics

Abstract

Substituting alanine for glycine at position 60 in v-H-Ras generated a dominant negative mutant that completely abolished the ability of v-H-Ras to transform NIH 3T3 cells and to induce germinal vesicle breakdown in Xenopus oocytes. The crystal structure of the GppNp-bound form of RasG60A unexpectedly shows that the switch regions adopt an open conformation reminiscent of the structure of the nucleotide-free form of Ras in complex with Sos. Critical residues that normally stabilize the guanine nucleotide and the Mg(2+) ion have moved considerably. Sos binds to RasG60A but is unable to catalyze nucleotide exchange. Our data suggest that the dominant negative effect observed for RasG60A.GTP could result from the sequestering of Sos in a non-productive Ras-GTP-guanine nucleotide exchange factor ternary complex.

Published

2005

2. H-Ras and phosphoinositide 3-kinase cooperate to induce alpha(1,3)-fucosyltransferase VII expression in Jurkat T cells.

Author

Zisoulis DG and Kansas GS

Subjects

Humans, Isomerism, Jurkat Cells, Mitogen-Activated Protein Kinase 1 metabolism, Mitogen-Activated Protein Kinase 3, Mitogen-Activated Protein Kinases metabolism, Mutation, Oncogene Protein p21(ras) chemistry, Proto-Oncogene Proteins c-raf metabolism, Fucosyltransferases genetics, Gene Expression Regulation, Enzymologic physiology, Oncogene Protein p21(ras) metabolism, Phosphatidylinositol 3-Kinases metabolism, Signal Transduction physiology

Abstract

The alpha(1,3)-fucosyltransferase FucT-VII is essential for the biosynthesis of selectin ligands, but the signaling pathways mediating FucT-VII induction in T cells and other lymphocytes are poorly understood. We have shown previously that sustained activation of Ras in Jurkat T cells induces FucT-VII transcription, which requires the Raf-MEK-ERK pathway. In this study we report that FucT-VII induction is specific to the H-Ras isoform. Jurkat T cells retrovirally transduced with constitutively active H-Ras but not N- or K-Ras up-regulated expression of FucT-VII. Pharmacological inhibition studies also revealed that phosphoinositide 3-kinase (PI3K) activity is required for H-Ras-mediated FucT-VII induction. However, the ability of H-Ras to selectively induce FucT-VII is not a function of the inability of the N- or K-Ras isoforms to activate Raf or PI3K pathways. The use of effector-loop domain mutants of H-Ras, which are impaired for their ability to interact selectively with individual effectors alone or in combination with active Raf, indicated that induction of FucT-VII requires the concomitant activation of at least three signaling pathways. These studies show that H-Ras mediates FucT-VII induction in Jurkat T cells via the activation of the Raf, PI3K, and a distinct, H-Ras-specific effector signaling pathway.

Published

2004

3. Structure-based mutagenesis reveals distinct functions for Ras switch 1 and switch 2 in Sos-catalyzed guanine nucleotide exchange.

Author

Hall BE, Yang SS, Boriack-Sjodin PA, Kuriyan J, and Bar-Sagi D

Subjects

Amino Acid Substitution, Humans, Magnesium metabolism, Models, Molecular, Mutagenesis, Site-Directed, Oncogene Protein p21(ras) chemistry, Oncogene Protein p21(ras) metabolism, Phosphates metabolism, Protein Conformation, Guanosine Diphosphate metabolism, Oncogene Protein p21(ras) physiology

Abstract

Ras GTPases function as binary switches in signaling pathways controlling cell growth and differentiation. The guanine nucleotide exchange factor Sos mediates the activation of Ras in response to extracellular signals. We have previously solved the crystal structure of nucleotide-free Ras in complex with the catalytic domain of Sos (Boriack-Sjodin, P. A., Margarit, S. M., Bar-Sagi, D., and Kuriyan, J. (1998) Nature 394, 337-343). The structure demonstrates that Sos induces conformational changes in two loop regions of Ras known as switch 1 and switch 2. In this study, we have employed site-directed mutagenesis to investigate the functional significance of the conformational changes for the catalytic function of Sos. Switch 2 of Ras is held in a very tight embrace by Sos, with almost every external side chain coordinated by Sos. Mutagenesis of contact residues at the switch 2-Sos interface shows that only a small set of side chains affect binding, with the most important contact being mediated by tyrosine 64, which is buried in a hydrophobic pocket of Sos in the Ras.Sos complex. Substitutions of Ras and Sos side chains that are inserted into the Mg(2+)- and nucleotide phosphate-binding site of switch 2 (Ras Ala(59) and Sos Leu(938) and Glu(942)) have no effect on the catalytic function of Sos. These results indicate that the interaction of Sos with switch 2 is necessary for tight binding, but is not the critical driving force for GDP displacement. The structural distortion of switch 1 induced by Sos is mediated by a small number of specific contacts between highly conserved residues on both Ras and Sos. Mutations of a subset of these residues (Ras Tyr(32) and Tyr(40)) result in an increase in the intrinsic rate of nucleotide dissociation from Ras and impair the binding of Ras to Sos. Based on this analysis, we propose that the interactions of Sos with the switch 1 and switch 2 regions of Ras have distinct functional consequences: the interaction with switch 2 mediates the anchoring of Ras to Sos, whereas the interaction with switch 1 leads to disruption of the nucleotide-binding site and GDP dissociation.

Published

2001

4. A molecular redox switch on p21(ras). Structural basis for the nitric oxide-p21(ras) interaction.

Author

Lander HM, Hajjar DP, Hempstead BL, Mirza UA, Chait BT, Campbell S, and Quilliam LA

Subjects

Amino Acid Sequence, DNA, Complementary, Humans, Jurkat Cells, Molecular Sequence Data, Nitric Oxide metabolism, Oncogene Protein p21(ras) genetics, Oncogene Protein p21(ras) metabolism, Oxidation-Reduction, Signal Transduction, Transfection, Nitric Oxide chemistry, Oncogene Protein p21(ras) chemistry

Abstract

We have identified the site of molecular interaction between nitric oxide (NO) and p21(ras) responsible for initiation of signal transduction. We found that p21(ras) was singly S-nitrosylated and localized this modification to a fragment of p21(ras) containing Cys118. A mutant form of p21(ras), in which Cys118 was changed to a serine residue and termed p21(ras)C118S, was not S-nitrosylated. NO-related species stimulated guanine nucleotide exchange on wild-type p21(ras), resulting in an active form, but not on p21(ras)C118S. Furthermore, in contrast to parental Jurkat T cells, NO-related species did not stimulate mitogen-activated protein kinase activity in cells transfected with p21(ras)C118S. These data indicate that Cys118 is a critical site of redox regulation of p21(ras), and S-nitrosylation of this residue triggers guanine nucleotide exchange and downstream signaling.

Published

1997

5. Depalmitoylation of CAAX motif proteins. Protein structural determinants of palmitate turnover rate.

Author

Lu JY and Hofmann SL

Subjects

Amino Acid Sequence, Animals, Base Sequence, Cell Line, Cell Membrane metabolism, Chlorocebus aethiops, DNA Primers, Kidney, Kinetics, Molecular Sequence Data, Mutagenesis, Site-Directed, Oncogene Protein p21(ras) chemistry, Palmitic Acid, Polymerase Chain Reaction, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins metabolism, Transfection, ras Proteins chemistry, Oncogene Protein p21(ras) metabolism, Palmitic Acids metabolism, ras Proteins metabolism

Abstract

In the present study, we examined the effect of amino acid substitutions on the rate of turnover of palmitate bound to a model "CAAX" motif protein H-Ras. These experiments were designed to shed light on the specificity of the process that removes palmitate from prenylated proteins. H-Ras, protein A-Ras fusion constructs, and constructs with amino acid substitutions in the H-Ras hypervariable region were transfected into COS cells, and the turnover rate of palmitate bound to each expressed protein was measured. We found no evidence for strict sequence specificity for palmitate removal, but found a strong inverse correlation between palmitate turnover rate and the degree of membrane association for any given construct, with slower turnover rates associated with stronger membrane binding. These data support a model in which the palmitate turnover rate is determined by access to a depalmitoylating enzyme and argue against a more complex model in which specific recognition of palmitoylated proteins is required.

Published

1995

6. Carboxyl-terminal isoprenylation of ras-related GTP-binding proteins encoded by rac1, rac2, and ralA.

Author

Kinsella BT, Erdman RA, and Maltese WA

Subjects

Amino Acid Sequence, Base Sequence, Chromatography, Gel, Electrophoresis, Polyacrylamide Gel, Isoproterenol, Molecular Sequence Data, Mutagenesis, Site-Directed, Oncogene Protein p21(ras) genetics, Plasmids, Polyisoprenyl Phosphates metabolism, Protein Processing, Post-Translational, GTP-Binding Proteins chemistry, Oncogene Protein p21(ras) chemistry

Abstract

Membrane localization of p21ras is dependent upon its posttranslational modification by a 15-carbon farnesyl group. The isoprenoid is linked to a cysteine located within a conserved carboxyl-terminal sequence termed the "CAAX" box (where C is cysteine, A is an aliphatic amino acid, and X is any amino acid). We now show that three GTP-binding proteins encoded by the recently identified rac1, rac2, and ralA genes also undergo isoprenoid modification. cDNAs coding for each protein were transcribed in vitro, and the RNAs were translated in reticulocyte lysates. Incorporation of isoprenoid precursors, [3H]mevalonate or [3H]farnesyl pyrophosphate, indicated that the translation products were modified by isoprenyl groups. A protein recognized by an antibody to rac1 also comigrated with a protein metabolically labeled by a product of [3H] mevalonate in cultured cells. Gel permeation chromatography of radiolabeled hydrocarbons released from the rac1, rac2, and ralA proteins by reaction with Raney nickel catalyst indicated that unlike p21Hras, which was modified by a 15-carbon moiety, the rac and ralA translation products were modified by 20-carbon isoprenyl groups. Site-directed mutagenesis established that the isoprenylated cysteines in the rac1, rac2, and ralA proteins were located in the fourth position from the carboxyl terminus. The three-amino acid extension distal to the cysteine was required for this modification. The isoprenylation of rac1 (CSLL), ralA (CCIL), and the site-directed mutants rac1 (CRLL) and ralA (CSIL), demonstrates that the amino acid adjacent to the cysteine need not be aliphatic. Therefore, proteins with carboxyl-terminal CXXX sequences that depart from the CAAX motif should be considered as potential targets for isoprenoid modification.

Published

1991