The structural basis of Arfaptin-mediated cross-talk between Rac and Arf signalling pathways.

Small G proteins are GTP-dependent molecular switches that regulate numerous cellular functions. They can be classified into homologous subfamilies that are broadly associated with specific biological processes. Cross-talk between small G-protein families has an important role in signalling, but the mechanism by which it occurs is poorly understood. The coordinated action of Arf and Rho family GTPases is required to regulate many cellular processes including lipid signalling, cell motility and Golgi function. Arfaptin is a ubiquitously expressed protein implicated in mediating cross-talk between Rac (a member of the Rho family) and Arf small GTPases. Here we show that Arfaptin binds specifically to GTP-bound Arf1 and Arf6, but binds to Rac.GTP and Rac.GDP with similar affinities. The X-ray structure of Arfaptin reveals an elongated, crescent-shaped dimer of three-helix coiled-coils. Structures of Arfaptin with Rac bound to either GDP or the slowly hydrolysable analogue GMPPNP show that the switch regions adopt similar conformations in both complexes. Our data highlight fundamental differences between the molecular mechanisms of Rho and Ras family signalling, and suggest a model of Arfaptin-mediated synergy between the Arf and Rho family signalling pathways.

Structure of the TPR domain of p67phox in complex with Rac.GTP.

p67phox is an essential part of the NADPH oxidase, a multiprotein enzyme complex that produces superoxide ions in response to microbial infection. Binding of the small GTPase Rac to p67phox is a key step in the assembly of the active enzyme complex. The structure of Rac.GTP bound to the N-terminal TPR (tetratricopeptide repeat) domain of p67phox reveals a novel mode of Rho family/effector interaction and explains the basis of GTPase specificity. Complex formation is largely mediated by an insertion between two TPR motifs, suggesting an unsuspected versatility of TPR domains in target recognition and in their more general role as scaffolds for the assembly of multiprotein complexes.

Structural analysis of 14-3-3 phosphopeptide complexes identifies a dual role for the nuclear export signal of 14-3-3 in ligand binding.

We have solved the high-resolution X-ray structure of 14-3-3 bound to two different phosphoserine peptides, representing alternative substrate-binding motifs. These structures reveal an evolutionarily conserved network of peptide-protein interactions within all 14-3-3 isotypes, explain both binding motifs, and identify a novel intrachain phosphorylation-mediated loop structure in one of the peptides. A 14-3-3 mutation disrupting Raf signaling alters the ligand-binding cleft, selecting a different phosphopeptide-binding motif and different substrates than the wild-type protein. Many 14-3-3: peptide contacts involve a C-terminal amphipathic alpha helix containing a putative nuclear export signal, implicating this segment in both ligand and Crm1 binding. Structural homology between the 14-3-3 NES structure and those within I kappa B alpha and p53 reveals a conserved topology recognized by the Crm1 nuclear export machinery.

Structure at 1.65 A of RhoA and its GTPase-activating protein in complex with a transition-state analogue.

Small G proteins of the Rho family, which includes Rho, Rac and Cdc42Hs, regulate phosphorylation pathways that control a range of biological functions including cytoskeleton formation and cell proliferation. They operate as molecular switches, cycling between the biologically active GTP-bound form and the inactive GDP-bound state. Their rate of hydrolysis of GTP to GDP by virtue of their intrinsic GTPase activity is slow, but can be accelerated by up to 10(5)-fold through interaction with rhoGAP, a GTPase-activating protein that stimulates Rho-family proteins. As such, rhoGAP plays a crucial role in regulating Rho-mediated signalling pathways. Here we report the crystal structure of RhoA and rhoGAP complexed with the transition-state analogue GDP.AlF4- at 1.65 A resolution. There is a rotation of 20 degrees between the Rho and rhoGAP proteins in this complex when compared with the ground-state complex Cdc42Hs.GMPPNP/rhoGAP, in which Cdc42Hs is bound to the non-hydrolysable GTP analogue GMPPNP. Consequently, in the transition state complex but not in the ground state, the rhoGAP domain contributes a residue, Arg85(GAP) directly into the active site of the G protein. We propose that this residue acts to stabilize the transition state of the GTPase reaction. RhoGAP also appears to function by stabilizing several regions of RhoA that are important in signalling the hydrolysis of GTP.

Crystal structure of a small G protein in complex with the GTPase-activating protein rhoGAP.

Small G proteins transduce signals from plasma-membrane receptors to control a wide range of cellular functions. These proteins are clustered into distinct families but all act as molecular switches, active in their GTP-bound form but inactive when GDP-bound. The Rho family of G proteins, which includes Cdc42Hs, activate effectors involved in the regulation of cytoskeleton formation, cell proliferation and the JNK signalling pathway. G proteins generally have a low intrinsic GTPase hydrolytic activity but there are family-specific groups of GTPase-activating proteins (GAPs) that enhance the rate of GTP hydrolysis by up to 10(5) times. We report here the crystal structure of Cdc42Hs, with the non-hydrolysable GTP analogue GMPPNP, in complex with the GAP domain of p50rhoGAP at 2.7A resolution. In the complex Cdc42Hs interacts, mainly through its switch I and II regions, with a shallow pocket on rhoGAP which is lined with conserved residues. Arg 85 of rhoGAP interacts with the P-loop of Cdc42Hs, but from biochemical data and by analogy with the G-protein subunit G(i alpha1), we propose that it adopts a different conformation during the catalytic cycle which enables it to stabilize the transition state of the GTP-hydrolysis reaction.

Structure and sites of phosphorylation of 14-3-3 protein: role in coordinating signal transduction pathways.

The 14-3-3 family are homo- and heterodimeric proteins whose biological role has been unclear for some time, although they are now gaining acceptance as a novel type of 'adaptor' protein that modulates interactions between components of signal transduction pathways, rather than by direct activation or inhibition. It is becoming apparent that phosphorylation of the binding partner and possibly also the 14-3-3 proteins may regulate these interactions. 14-3-3 isoforms interact with a novel phosphoserine (Sp) motif on many proteins, RSX1,2SpXP. The two isoforms that interact with Raf-1 are phosphorylated in vivo on Ser185 in a consensus sequence motif for proline-directed kinases. The crystal structure of 14-3-3 indicates that this phosphorylation could regulate interaction of 14-3-3 with its target proteins. We have now identified a number of additional phosphorylation sites on distinct mammalian and yeast isoforms.

The structural basis for 14-3-3:phosphopeptide binding specificity.

The 14-3-3 family of proteins mediates signal transduction by binding to phosphoserine-containing proteins. Using phosphoserine-oriented peptide libraries to probe all mammalian and yeast 14-3-3s, we identified two different binding motifs, RSXpSXP and RXY/FXpSXP, present in nearly all known 14-3-3 binding proteins. The crystal structure of 14-3-3zeta complexed with the phosphoserine motif in polyoma middle-T was determined to 2.6 A resolution. The bound peptide is in an extended conformation, with a tight turn created by the pS +2 Pro in a cis conformation. Sites of peptide-protein interaction in the complex rationalize the peptide library results. Finally, we show that the 14-3-3 dimer binds tightly to single molecules containing tandem repeats of phosphoserine motifs, implicating bidentate association as a signaling mechanism with molecules such as Raf, BAD, and Cbl.

Escherichia coli isocitrate dehydrogenase kinase/phosphatase. Overproduction and kinetics of interaction with its substrates by using intrinsic fluorescence and fluorescent nucleotide analogues.

The aceK gene of Escherichia coli, which encodes the isocitrate dehydrogenase kinase/phosphatase (IDH K/P), was cloned in the pQE30 expression vector to overproduce a protein tagged with six histidine residues at its N-terminus. By using a one-step chromatographic procedure, the IDH K/P was purified to near homogeneity. The IDH K/P, which contains nine Trp residues, exhibited a characteristic intrinsic tryptophan fluorescence with a low maximal emission at 326 nm. The low value of the Stern-Volmer quenching constant in the presence of acrylamide (Ksv = 2.1 M-1) indicated that the tryptophan residues were deeply buried in the protein. Furthermore, the intrinsic tryptophan fluorescence was very sensitive to the binding of nucleotide. The quenching of protein fluorescence induced by the binding of nucleotide together with an increased intrinsic fluorescence of fluorescent nucleotide analogues, methylanthraniloyl-derivatives ADP, ATP, GDP and GTP and adenosine-5'-triphosphoro-1-(5-sulfonic-acid) naphthylamidate, were used to investigate the interaction with IDH K/P. The IDH K/P dimer was shown to contain two identical nucleotide binding sites, one on each subunit, with a Kd in the range of 1.7-2.5 microM for unmodified ADP or ATP and of 2.5-3.7 microM for fluorescently labelled nucleotides. In contrast, the affinity for GDP or GTP was 10-fold lower than for adenine nucleotides. The nucleotide binding site was located within residues 315-340 by using limited proteolysis of IDH K/P by endoproteinase Lys-C. Only one main site of cleavage was obtained: the peptide bond K346-E347 which was strongly protected in the presence of ATP.

Conformational stability of dimeric HIV-1 and HIV-2 reverse transcriptases.

The dissociation of dimeric reverse transcriptase (RT) of the human immunodeficiency virus (HIV) types 1 and 2 has been investigated using acetonitrile as a dissociating agent. The equilibrium transitions were monitored by combining different approaches (fluorescence spectroscopy, polymerase activity assay, and size-exclusion HPLC). The dissociation of RT induced a complete loss of polymerase activity and a 25% increase of the intrinsic fluorescence. It is fully reversible, and the midpoints of the equilibrium transition curves are dependent on the concentration of the enzyme used, suggesting a two-state transition model for the dissociation of RT in which dimers are in equilibrium with folded monomers. For both RTs, the heterodimeric form is more stable against dissociating agents and different pH than the corresponding homodimeric form. Moreover, heterodimeric HIV-2 RT exhibits a higher stability than HIV-1 RT, with a free energy of dissociation of 12.1 kcal/mol at pH 6.5 and 25 degrees C, instead of 10 kcal/mol for HIV-1 RT. The binding of a primer/template induces a marked conformational change in both RTs, shown by the lower accessibility of the tryptophans to quenchers and the increase in tryptophan heterogeneity, and stabilized the dimeric form of both RTs (10-100-fold). The central role of hydrophobic interactions in dimer formation has been revealed by the 30% increase of exposure of the tryptophan cluster to quenchers upon dissociation of RT and the binding of 4 equiv of 1-anilino-8-naphthalenesulfonate to the dissociated enzymes.

Interface peptides as structure-based human immunodeficiency virus reverse transcriptase inhibitors.

Reverse transcriptases from both human immunodeficiency viruses type 1 and 2 are obligatory dimers. A tryptophan-rich repeat motif that is highly conserved between these proteins, as well as in the reverse transcriptase from simian immunodeficiency virus, has been postulated to be involved in hydrophobic subunit interactions. A synthetic 19-mer peptide covering part of this tryptophan repeat motif was recently shown to inhibit human immunodeficiency viruses type 1 reverse transcriptase subunit dimerization (Divita, G., Restle, T., Goody, R. S., Chermann, J.-C., and Baillon, J. G. (1994) J. Biol. Chem. 269, 13080-13083). In the present study, we show that the same peptide can also inhibit human immunodeficiency virus type 2 reverse transcriptase subunit dimerization, suggesting that the same inhibitors might be used as agents against both viruses as well as against variants of human immunodeficiency virus type 1 that differ from the variant against which they were developed. Under appropriate experimental conditions, e.g. at acidic pH, this peptide is also able to induce the dissociation of the enzyme from human immunodeficiency virus type 1.

Human immunodeficiency virus reverse transcriptase substrate-induced conformational changes and the mechanism of inhibition by nonnucleoside inhibitors.

A combination of transient kinetic and equilibrium titration methods has been used to show that both primer/template and nucleotide binding to human immunodeficiency virus type 1 (HIV-1) reverse transcriptase are two-step processes. In both cases, after initial formation of relatively weakly bound states, isomerization reactions lead to tightly bound states. In the case of deoxynucleotide binding to the reverse transcriptase-primer/template complex, the second step in the interaction is rate-limiting in the overall reaction during processive polymerization. Discrimination against incorrect nucleotides occurs both in the initial weak binding and in the second step but is purely kinetic in the second step (as opposed to thermodynamic in the first step). Nonnucleoside inhibitors have a relatively small effect on nucleotide-binding steps (overall affinity is reduced by a factor of ca. 10), while the affinity of the primer/template duplex is increased by at least a factor of 10. The major effect of nonnucleoside inhibitors is on the chemical step (nucleotide transfer).

Dimerization kinetics of HIV-1 and HIV-2 reverse transcriptase: a two step process.

The dimerization processes of the human immunodeficiency virus (HIV) types 1 and 2 reverse transcriptase (RTs) from their subunits have been investigated using a number of complementary approaches (fluorescence spectroscopy, size exclusion-HPLC and polymerase activity assay). The formation of the native heterodimeric form of HIV-1 and HIV-2 RT occurs in a two step process. The first step is a concentration-dependent association of the two subunits (p66 and p51) to give a heterodimeric intermediate, which slowly isomerizes to the "mature" heterodimeric form of the enzyme. For both RTs, the first step behaves as a second order reaction with similar association rate constants (in the range of 2 x 10(4) to 4 x 10(4) M-1 s-1). This initial dimerization results in a 25% quenching of the intrinsic fluorescence and a 30% decrease in the accessibility of the tryptophan hydrophobic cluster to solvent as revealed by iodide quenching experiments and by monitoring the binding of 1-anilino-8-naphthalenesulphonate. The formation of the intermediate-RT form appears to involve hydrophobic regions of the subunits containing tryptophan residues. This intermediate form is devoid of polymerase activity, but is able to bind primer/template with high affinity. The final stage of the mature RT-heterodimer formation occurs in a slow first order reaction, which is 12-fold faster for HIV-2 (1.2 h-1) than HIV-1 RT (0.1 h-1). At micromolar concentrations, this slow isomerization constitutes the rate limiting step of the RT maturation and the structural change involved appears to be partly associated with the catalytic site, as shown using fluorescent labelled primer/template. On the basis of both the presently available X-ray structure of the HIV-1 RT and the predicted structure of HIV-2 RT, the thumb subdomain of the p51 subunit seems to be involved in this maturation step, which is probably the interaction of this domain with the RNAse H domain of the large subunit. The placement of the fingers subdomain of p51 in the palm subdomain of the p66 subunit may also be associated with formation of mature heterodimeric RTs.

Kinetics of interaction of HIV reverse transcriptase with primer/template.

Intrinsic protein fluorescence of reverse transcriptases from HIV-1 and HIV-2 provides a sensitive signal for monitoring the interaction of the enzymes with primer/template duplex molecules. Kd values for 18/36-mer DNA/DNA duplexes were found to be in the range of a few nanomolar (about 3 times higher for the enzyme from HIV-2 than for that from HIV-1). The quenching of protein fluorescence induced on binding primer/template, together with an increase in extrinsic fluorescence on interaction with primer/template containing a fluorescent nucleotide at the 3'-end of the primer, was used to investigate the kinetics of interaction with reverse transcriptase from HIV-1. The results can be explained in terms of a two-step binding model, with a rapid diffusion-limited initial association (k(ass) = ca. 5 x 10(8) M-1 s-1) followed by a slow isomerization step (k = ca. 0.5 s-1). These (forward) rate constants are increased in the presence of a non-nucleoside inhibitor (S-TIBO) of HIV-1 reverse transcriptase, while the reverse rate constant for the second step is decreased, leading to an increase in affinity between the enzyme and primer/template by a factor of at least 10 when S-TIBO is bound. The results are discussed in terms of present knowledge of the structure of reverse transcriptase.

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Representative Leland, a pharmacist raised in Houston's ghetto, uses health subcommittee post to draw attention to the needs of his constituents.