Solution structure of an oncogenic mutant of Cdc42Hs

Cdc42Hs(F28L) is a single-point mutant of Cdc42Hs, a member of the Ras superfamily of GTP-binding proteins, that facilitates cellular transformation brought about by an increased rate of cycling between GTP and GDP [Lin, R., et al. (1997) Curr. Biol. 7, 794-797]. Dynamics studies of Cdc42Hs(F28L)-GDP have shown increased flexibility for several residues at the nucleotide-binding site [Adams, P. D., et al. (2004) Biochemistry 43, 9968-9977]. The solution structure of Cdc42Hs-GDP (wild type) has previously been determined by NMR spectroscopy [Feltham, J. L., et al. (1997) Biochemistry 36, 8755-8766]. Here, we describe the solution structure of Cdc42Hs(F28L)-GDP, which provides insight into the structural basis for the change in affinity for GDP. Heteronuclear NMR experiments were performed to assign resonances in the protein, and distance, hydrogen bonding, residual dipolar coupling, and dihedral angle constraints were used to calculate a set of low-energy structures using distance geometry and simulated annealing refinement protocols. The overall structure of Cdc42Hs(F28L)-GDP is very similar to that of wild-type Cdc42Hs, consisting of a centrally located six-stranded beta-sheet structure surrounding the C-terminal alpha-helix [Feltham, J. L., et al. (1997) Biochemistry 36, 8755-8766]. In addition, the same three regions in wild-type Cdc42Hs that show structural disorder (Switch I, Switch II, and the Insert region) are disordered in F28L as well. Although the structure of Cdc42Hs(F28L)-GDP is very similar to that of the wild type, interactions with the nucleotide and hydrogen bonding within the nucleotide binding site are altered, and the region surrounding L28 is substantially more disordered.     

Backbone dynamics of inactive, active, and effector-bound Cdc42Hs from measurements of (15)N relaxation parameters at multiple field strengths.

Cdc42Hs, a member of the Ras superfamily of GTP-binding proteins, initiates a cascade that begins with the activation of several kinases, including p21-activated kinase (PAK). We have previously determined the structure of Cdc42Hs and found that the regions involved in effector (Switch I) and regulator (Switch II) actions are partially disordered [Feltham, J. L., et al. (1997) Biochemistry 36, 8755-8766]. Recently, we used a 46-amino acid fragment of PAK (PBD46) to define the binding surface on Cdc42Hs, which includes the beta2 strand and a portion of Switch I [Guo, W., et al. (1998) Biochemistry 37, 14030-14037]. Here we describe the backbone dynamics of three constructs of [(15)N]Cdc42Hs (GDP-, GMPPCP-, and GMPPCP- and PBD46-bound) using (15)N-(1)H NMR measurements of T(1), T(1)(rho), and the steady-state NOE at three magnetic field strengths. Residue-specific values of the generalized order parameters (S(s)(2) and S(f)(2)), local correlation time (tau(e)), and exchange rate (R(ex)) were obtained using the Lipari-Szabo model-free formalism. Residues in Switch I were found to exhibit high-amplitude (low-order) motions on a nanosecond time scale, whereas those in Switch II experience low-amplitude motion on the nanosecond time scale and chemical (conformational) exchange on a millisecond time scale. The Insert region of Cdc42Hs-GDP exhibits high-order, nanosecond motions; the time scale of motion in the Insert is reduced in Cdc42Hs-GMPPCP and Cdc42Hs-PBD46. Overall, significant flexibility was observed mainly in the regions of Cdc42Hs that are involved in protein-protein interactions (Switch I, Switch II, and Insert), and flexibility was reduced upon interaction with a protein ligand. These results suggest that protein flexibility is important for high-affinity binding interactions.     

Dynamic and Thermodynamic Response of the Ras Protein Cdc42Hs upon Association with the Effector Domain of PAK3

Human cell division cycle protein 42 (Cdc42Hs) is a small, Rho-type guanosine triphosphatase involved in multiple cellular processes through its interactions with downstream effectors. The binding domain of one such effector, the actin cytoskeleton-regulating p21-activated kinase 3, is known as PBD46. Nitrogen-15 backbone and carbon-13 methyl NMR relaxation was measured to investigate the dynamical changes in activated GMPPCP·Cdc42Hs upon PBD46 binding. Changes in internal motion of the Cdc42Hs, as revealed by methyl axis order parameters, were observed not only near the Cdc42Hs–PBD46 interface but also in remote sites on the Cdc42Hs molecule. The binding-induced changes in side-chain dynamics propagate along the long axis of Cdc42Hs away from the site of PBD46 binding with sharp distance dependence. Overall, the binding of the PBD46 effector domain on the dynamics of methyl-bearing side chains of Cdc42Hs results in a modest rigidification, which is estimated to correspond to an unfavorable change in conformational entropy of approximately − 10 kcal mol^− 1 at 298 K. A cluster of methyl probes closest to the nucleotide-binding pocket of Cdc42Hs becomes more rigid upon binding of PBD46 and is proposed to slow the catalytic hydrolysis of the γ phosphate moiety. An additional cluster of methyl probes surrounding the guanine ring becomes more flexible on binding of PBD46, presumably facilitating nucleotide exchange mediated by a guanosine exchange factor. In addition, the Rho insert helix, which is located at a site remote from the PBD46 binding interface, shows a significant dynamic response to PBD46 binding.     

Concerted motion of a protein-peptide complex: backbone dynamics studies of an (15)N-labeled peptide derived from P(21)-activated kinase bound to Cdc42Hs.GMPPCP.

Cdc42Hs is a member of the Ras superfamily of GTPases which, when active, initiates a cascade beginning with the activation of several kinases, including P(21)-activated kinase (PAK). We previously determined the structure of a complex between a 46 amino acid fragment peptide derived from the PAK binding domain (PBD46) and Cdc42Hs.GMPPCP (Gizachew, D., Guo, W., Chohan, K. K., Sutcliffe, M. J., and Oswald, R. E. (2000) Biochemistry 39, 3963-3971). Previous studies (Loh, A. P., Guo, W., Nicholson, L. K., and Oswald, R. E. (1999) Biochemistry 38, 12547-12557) suggest that the regions of Cdc42Hs that bind effectors and regulators have distinct dynamic properties from the remainder of the protein. Here, we describe the backbone dynamics of PBD46 bound to Cdc42Hs.GMPPCP. T(1), T(2), T(1)(rho), and steady-state nuclear Overhauser effects were measured at 500 and 600 MHz. An extension of the Lipari-Szabo model-free analysis was used to determine the order parameters (S(2)) and local correlation times (tau(e)) of the N-H bond vectors within PBD46. Both Cdc42Hs and PBD46 exhibit increased mobility in the free versus the bound state, suggesting that protein flexibility may be required for high-affinity PBD46 binding and, presumably, the activation of PAK. Different backbone dynamics were observed in different regions of the peptide. The beta-strand region of bound PBD46, which makes contacts with beta2 of Cdc42Hs, exhibits low mobility on the pico- to nanosecond timescale. However, the part of PBD46 that interacts with Switch I of Cdc42Hs exhibits greater mobility. Thus, PBD46 and Cdc42Hs form a tight complex that exhibits concerted dynamics.     

Structure of the complex of Cdc42Hs with a peptide derived from P-21 activated kinase

Cdc42Hs is a member of the Ras superfamily of GTPases and initiates a cascade that begins with the activation of several kinases, including p21-activated kinase (PAK). We have previously used a 46 amino acid fragment of PAK (PBD46) to define the binding surface on Cdc42Hs [Guo et al. (1998) Biochemistry 37, 14030-14037]. Here we describe the three-dimensional solution structure of the Cdc42Hs. GMPPCP-PBD46 complex. Heteronuclear NMR methods were used to assign resonances in the complex, and approximately 2400 distance and dihedral restraints were used to calculate a set of 20 structures using a combination of distance geometry, simulated annealing, and chemical shift and Ramachandran refinement. The overall structure of Cdc42Hs in the complex differs from the uncomplexed structure in two major aspects: (1) the first alpha helix is reoriented to accommodate the binding of the peptide and (2) the regions corresponding to switch I and switch II are less disordered. As suggested by our previous work (Guo et al., 1998) and similar to the complex between Cdc42Hs and fACK [Mott et al. (1999) Nature 399, 384-388], PBD46 forms an intermolecular beta-sheet with beta2 of Cdc42Hs and contacts both switch I and switch II. The extensive binding surface between PBD46 and Cdc42Hs can account for both the high affinity of the complex and the inhibition by PBD46 of GTP hydrolysis.     

A switch I mutant of Cdc42 exhibits less conformational freedom

Cdc42 is a Ras-related small G-protein and functions as a molecular switch in signal transduction pathways linked with cell growth and differentiation. It is controlled by cycling between GTP-bound (active) and GDP-bound (inactive) forms. Nucleotide binding and hydrolysis are modulated by interactions with effectors and/or regulatory proteins. These interactions are centralized in two relatively flexible "Switch" regions as characterized by internal dynamics on multiple time scales [Loh, A. P., et al. (2001) Biochemistry 40, 4590-4600], and this flexibility may be essential for protein interactions. In the Switch I region, Thr(35) seems to be critical for function, as it is completely invariant in Ras-related proteins. To investigate the importance of conformational flexibility in Switch I of Cdc42, we mutated threonine to alanine, determined the solution structure, and characterized the backbone dynamics of the single-point mutant protein, Cdc42(T35A). Backbone dynamics data suggest that the mutation changes the time scale of the internal motions of several residues, with several resonances not being discernible in wild-type Cdc42 [Adams, P. D., and Oswald, R. E. (2007) Biomol. NMR Assignments 1, 225-227]. The mutation does not appear to affect the thermal stability of Cdc42, and chymotrypsin digestion data further suggest that changes in the conformational flexibility of Switch I slow proteolytic cleavage relative to that of the wild type. In vitro binding assays show less binding of Cdc42(T35A), relative to that of wild type, to a GTPase binding protein that inhibits GTP hydrolysis in Cdc42. These results suggest that the mutation of T(35) leads to the loss of conformational freedom in Switch I that could affect effector-regulatory protein interactions.     

Antiapoptotic Cdc42 mutants are potent activators of cellular transformation

Cdc42 is a small GTP-binding protein which has been implicated in a number of cellular activities, including cell morphology, motility, cell-cycle progression, and malignant transformation. While GTPase-defective forms of Cdc42 inhibit cell growth, a mutation [Cdc42(F28L)] that allows the constitutive exchange of GDP for GTP and is GTPase-competent induces cellular transformation. These results suggest that Cdc42 must cycle between its GTP- and GDP-bound states to stimulate cell growth. In attempting to design Cdc42 molecules with more potent transforming activity, we set out to generate other types of Cdc42 mutants capable of constitutive GDP-GTP exchange. Here, we describe one such mutant, generated by changing a conserved aspartic acid residue at position 118 to an asparagine. The Cdc42(D118N) protein exchanges GDP for GTP more rapidly than wild-type Cdc42, but significantly more slowly than the Cdc42(F28L) mutant. Despite its slower rate of activation, the Cdc42(D118N) mutant is more potent at inducing cellular transformation than the Cdc42(F28L) protein, and causes a significant loss in actin stress fibers, reminiscent of what is observed with fibroblasts transformed by oncogenic Ras mutants. Effector-loop mutations made within the D118N background inhibit Cdc42-induced transformation and Cdc42-mediated antiapoptotic (survival) activity to similar extents. In addition, mutating aspartic acid 121 (to asparagine), which forms part of a caspase cleavage site (DLRD, residues 118-121 of Cdc42), in combination with the F28L mutation generates a Cdc42 molecule [Cdc42(F28L/D121N)] with transforming activity significantly stronger than that of Cdc42(F28L). Thus, mutations that combine some capacity for cycling between the GTP- and GDP-bound states with increased survival against apoptotic signals yield Cdc42 molecules with the maximum capability for inducing cellular transformation.     

A 1H NMR determination of the solution conformation of a synthetic peptide analogue of calcium-binding site III of rabbit skeletal troponin C

NMR techniques have been used to determine the structure in solution of acetyl (Asp 105) skeletal troponin C (103-115) amide, one of a series of synthetic peptide analogues of calcium-binding site III of rabbit skeletal troponin C [Marsden et al. (1988) Biochemistry 27, 4198-4206]. The NMR measurements include 1H-1H nuclear Overhauser enhancements and gadolinium-induced 1H relaxation measurements. The former yield short-range internuclear distances (less than 4 A); the latter, once properly corrected for chemical exchange, yield longer range metal to proton distances (5-10 A). These measurements were then used as pseudo potential energy restraints in energy minimization and molecular dynamics calculations to determine the solution structure. Further information was provided by NMR coupling constants, amide proton exchange rates, and the temperature dependences of amide proton chemical shifts. The solution structure of the peptide analogue is very similar to that of the calcium-binding loop in the protein, the root-mean-square deviation between the backbone atoms being approximately 1.1 A.     

An increase in side chain entropy facilitates effector binding: NMR characterization of the side chain methyl group dynamics in Cdc42Hs

Cdc42Hs is a signal transduction protein that is involved in cytoskeletal growth and organization. We describe here the methyl side chain dynamics of three forms of (2)H,(13)C,(15)N-Cdc42Hs [GDP-bound (inactive), GMPPCP-bound (active), and GMPPCP/PBD46-bound (effector-bound)] from (13)C-(1)H NMR measurements of deuterium T(1) and T(1 rho) relaxation times. A wide variation in flexibility was observed throughout the protein, with methyl axis order parameters (S(2)(axis)) ranging from 0.2 to 0.4 (highly disordered) in regions near the PBD46 binding site to 0.8--1.0 (highly ordered) in some helices. The side chain dynamics of the GDP and GMPPCP forms are similar, with methyl groups on the PBD46 binding surface experiencing significantly greater mobility (lower S(2)(axis)) than those not on the binding surface. Binding of PBD46 results in a significant increase in the disorder and a corresponding increase in entropy for the majority of methyl groups. Many of the methyl groups that experience an increase in mobility are found in residues that are not part of the PBD46 binding interface. This entropy gain represents a favorable contribution to the overall entropy of effector binding and partially offsets unfavorable entropy losses such as those that occur in the backbone.     

Cdc42Hs facilitates cytoskeletal reorganization and neurite outgrowth by localizing the 58-kD insulin receptor substrate to filamentous actin

Cdc42Hs is involved in cytoskeletal reorganization and is required for neurite outgrowth in N1E-115 cells. To investigate the molecular mechanism by which Cdc42Hs regulates these processes, a search for novel Cdc42Hs protein partners was undertaken by yeast two-hybrid assay. Here, we identify the 58-kD substrate of the insulin receptor tyrosine kinase (IRS-58) as a Cdc42Hs target. IRS-58 is a brain-enriched protein comprising at least four protein-protein interaction sites: a Cdc42Hs binding site, an Src homology (SH)3-binding site, an SH3 domain, and a tryptophan, tyrptophan (WW)-binding domain. Expression of IRS-58 in Swiss 3T3 cells leads to reorganization of the filamentous (F)-actin cytoskeleton, involving loss of stress fibers and formation of filopodia and clusters. In N1E-115 cells IRS-58 induces neurite outgrowth with high complexity. Expression of a deletion mutant of IRS-58, which lacks the SH3- and WW-binding domains, induced neurite extension without complexity in N1E-115 cells. In Swiss 3T3 cells and N1E-115 cells, IRS-58 colocalizes with F-actin in clusters and filopodia. An IRS-58(1267N) mutant unable to bind Cdc42Hs failed to localize with F-actin to induce neurite outgrowth or significant cytoskeletal reorganization. These results suggest that Cdc42Hs facilitates cytoskeletal reorganization and neurite outgrowth by localizing protein complexes via adaptor proteins such as IRS-58 to F-actin.     

Half-of-the-sites binding of reactive intermediates and their analogues to 4-oxalocrotonate tautomerase and induced structural asymmetry of the enzyme

4-Oxalocrotonate tautomerase (4-OT), a homohexameric enzyme, converts the unconjugated enone, 2-oxo-4-hexenedioate (1), to the conjugated enone, 2-oxo-3-hexenedioate (3), via a dienolic intermediate, 2-hydroxymuconate (2). Pro-1 serves as the general base, and both Arg-11 and Arg-39 function in substrate binding and catalysis in an otherwise hydrophobic active site. Although 4-OT exhibits hyperbolic kinetics and no structural asymmetry either by X-ray or by NMR, inactivation by two affinity labels showed half-site stoichiometry [Stivers, J. T., et al. (1996) Biochemistry 35, 803-813; Johnson, W. H., Jr., et al. (1997) Biochemistry 36, 15724-15732], and titration of the R39Q mutant with cis,cis-muconate showed negative cooperativity [Harris, T. K., et al. (1999) Biochemistry 38, 12343-12357]. To test for anticooperativity during catalysis, 4-OT was titrated with equilibrium mixtures (> or = 81% product) of the reactive dicarboxylate or monocarboxylate intermediates, 2 or 2-hydroxy-2,4-pentadienoate (4), respectively, in three types of NMR experiments: two-dimensional 1H-15N HSQC titrations of backbone NH and of Arg N epsilonH resonances and one-dimensional 15N NMR titrations of Arg N epsilon resonances. All titrations showed substoichiometric binding of the equilibrium mixtures to 3 +/- 1 sites per hexamer with apparent dissociation constants comparable to the Km values of the intermediates. Compound 4 also bound 1 order of magnitude less tightly at another site, suggesting negative cooperativity. Consistent with negative cooperativity, asymmetry of the resulting complexes at saturating levels of 2 and 4 is indicated by splitting of the backbone NH resonances of 11 residues and 10 residues of 4-OT, respectively. The dicarboxylate competitive inhibitor, (2E)-fluoromuconate (5), with a KI of 45 +/- 7 microM, also exhibited substoichiometric binding to 3 +/- 1 sites per hexamer, with a KD of 25 +/- 18 microM, and splitting of the backbone NH resonance of L8. The monocarboxylate inhibitors (2E)- (6) and (2Z)-2-fluoro-2,4-pentadienoate (7) showed much weaker binding (KD = 3.1 +/- 1.3 mM), as well as splitting of two and five backbone NH resonances, respectively, indicating asymmetry of the complexes. The N epsilon resonances of both Arg-11 and Arg-39 were shifted downfield, and that of Pro-1N was broadened by all ligands, consistent with the major catalytic roles of these residues. Structural pathways for the site-site interactions which result in negative cooperativity are proposed on the basis of the X-ray structures of free and affinity-labeled 4-OT. Selective resonance broadenings induced by the binding of inactive analogues and active intermediates indicate residues which may be mobilized during reversible ligand binding and during catalysis, respectively.     

Temperature dependence of dynamics and thermodynamics of the regulatory domain of human cardiac troponin C

Binding of Ca(2+) to the regulatory domain of troponin C (TnC) in cardiac muscle initiates a series of protein conformational changes and modified protein-protein interactions that initiate contraction. Cardiac TnC contains two Ca(2+) binding sites, with one site being naturally defunct. Previously, binding of Ca(2+) to the functional site in the regulatory domain of TnC was shown to lead to a decrease in conformational entropy (TDeltaS) of 2 and 0.5 kcal mol(-1) for the functional and nonfunctional sites, respectively, using (15)N nuclear magnetic resonance (NMR) relaxation studies [Spyracopoulos, L., et al. (1998) Biochemistry 37, 18032-18044]. In this study, backbone dynamics of the Ca(2+)-free regulatory domain are investigated by backbone amide (15)N relaxation measurements at eight temperatures from 5 to 45 degrees C. Analysis of the relaxation measurements yields an order parameter (S(2)) indicating the degree of spatial restriction for a backbone amide H-N vector. The temperature dependence of S(2) allows estimation of the contribution to protein heat capacity from pico- to nanosecond time scale conformational fluctuations on a per residue basis. The average heat capacity contribution (C(p,j)) from backbone conformational fluctuations for regions of secondary structure for the regulatory domain of cardiac apo-TnC is 6 cal mol(-1) K(-1). The average heat capacity for Ca(2+) binding site 1 is larger than that for site 2 by 1.3 +/- 0.8 cal mol(-1) K(-1), and likely represents a mechanism where differences in affinity between Ca(2+) binding sites for EF hand proteins can be modulated.     

Stimulation of phospholipase C-beta2 by the Rho GTPases Cdc42Hs and Rac1.

Neutrophils contain a soluble guanine-nucleotidebinding protein, made up of two components with molecular masses of 23 and 26 kDa, that mediates stimulation of phospholipase C-beta2 (PLCbeta2). We have identified the two components of the stimulatory heterodimer by amino acid sequencing as a Rho GTPase and the Rho guanine nucleotide dissociation inhibitor LyGDI. Using recombinant Rho GTPases and LyGDI, we demonstrate that PLCbeta2 is stimulated by guanosine 5'-O-(3-thiotriphosphate) (GTP[S])-activated Cdc42HsxLyGDI, but not by RhoAxLyGDI. Stimulation of PLCbeta2, which was also observed for GTP[S]-activated recombinant Rac1, was independent of LyGDI, but required C-terminal processing of Cdc42Hs/Rac1. Cdc42Hs/Rac1 also stimulated PLCbeta2 in a system made up of purified recombinant proteins, suggesting that this function is mediated by direct protein-protein interaction. The Cdc42Hs mutants F37A and Y40C failed to stimulate PLCbeta2, indicating that the Cdc42Hs effector site is involved in this interaction. The results identify PLCbeta2 as a novel effector of the Rho GTPases Cdc42Hs and Rac1, and as the first mammalian effector directly regulated by both heterotrimeric and low-molecular-mass GTP-binding proteins.     

Involvement of phenylalanine 272 of DNA polymerase beta in discriminating between correct and incorrect deoxynucleoside triphosphates

DNA polymerase beta is a small monomeric polymerase that participates in base excision repair and meiosis [Sobol, R., et al. (1996) Nature 379, 183-186; Plug, A., et al. (1997) Proc. Natl. Acad. Sci. U.S.A. 94, 1327-1331]. A DNA polymerase beta mutator mutant, F272L, was identified by an in vivo genetic screen [Washington, S., et al. (1997) Proc. Natl. Acad. Sci. U.S.A. 94, 1321-1326]. Residue 272 is located within the deoxynucleoside triphosphate (dNTP) binding pocket of DNA polymerase beta according to the known DNA polymerase beta crystal structures [Pelletier, H., et al. (1994) Science 264, 1891-1893; Sawaya, M., et al. (1997) Biochemistry 36, 11205-11215]. The F272L mutant produces errors at a frequency 10-fold higher than that of wild type in vivo and in the in vitro HSV-tk gap-filling assay. F272L shows an increase in the frequency of both base substitution mutations and frameshift mutations. Single-enzyme turnover studies of misincorporation by wild type and F272L DNA polymerase beta demonstrate that there is a 4-fold decrease in fidelity of the mutant as compared to that of the wild type enzyme for a G:A mismatch. The decreased fidelity is due primarily to decreased discrimination between the correct and incorrect dNTP during ground-state binding. These results suggest that the phenylalanine 272 residue is critical for maintaining fidelity during the binding of the dNTP.     

Conformation of a Cdc42/Rac interactive binding peptide in complex with Cdc42 and analysis of the binding interface.

Most of the putative effectors for the Rho-family small GTPases Cdc42 and Rac share a common sequence motif referred to as the Cdc42/Rac interactive binding (CRIB) motif. This sequence, with a consensus of I-S-x-P-(x)2-4-F-x-H-x-x-H-V-G [Burbelo, P. D., et al. (1995) J. Biol. Chem. 270, 29071-29074], has been shown to be essential for the functional interactions between these effector proteins and Cdc42. We have characterized the interactions of a 22-residue CRIB peptide derived from human PAK2 [PAK2(71-92)] with Cdc42 using proton and heteronuclear NMR spectroscopy. This CRIB peptide binds to GTP-gammaS-loaded Cdc42 in a saturable manner, with an apparent Kd of 0.6 microM, as determined by fluorescence titration using sNBD-labeled Cdc42. Interaction of the 22-residue peptide PAK2(71-92) with GTP-gammaS-loaded Cdc42 causes resonance perturbations in the 1H-15N HSQC spectrum of Cdc42 that are similar to those observed for a longer (46-amino acid) CRIB-containing protein fragment [Guo, W., et al. (1998) Biochemistry 37, 14030-14037]. Proton NMR studies of PAK2(71-92) demonstrate structuring of PAK2(71-92) in the presence of GTP-gammaS-loaded Cdc42, through the observation of many nonsequential transferred NOEs. Structure calculations based on the observed transferred NOEs show that the central portion of the Cdc42-bound CRIB peptide assumes a loop conformation in which the side chains of consensus residues Phe80, His82, Ile84, His85, and Val86 are brought into proximity. The CRIB motif may therefore represent a minimal interfacial region in the complexes between Cdc42 and its effector proteins.     

Characterisation of the Nucleotide Exchange Factor ITSN1L: Evidence for a Kinetic Discrimination of GEF-Stimulated Nucleotide Release from Cdc42

Cdc42, a member of the Ras superfamily of small guanine nucleotide binding proteins, plays an important role in regulating the actin cytoskeleton, intracellular trafficking, and cell polarity. Its activation is controlled by guanine nucleotide exchange factors (GEFs), which stimulate the dissociation of bound guanosine-5′-diphosphate (GDP) to allow guanosine-5′-triphosphate (GTP) binding. Here, we investigate the exchange factor activity of the Dbl-homology domain containing constructs of the adaptor protein Intersectin1L (ITSN1L), which is a specific GEF for Cdc42. A detailed kinetic characterisation comparing ITSN1L-mediated nucleotide exchange on Cdc42 in its GTP- versus GDP-bound state reveals a kinetic discrimination for GEF-stimulated dissociation of GTP: The maximum acceleration of the intrinsic mGDP [2′/3′-O-(N-methyl-anthraniloyl)-GDP] release from Cdc42 by ITSN1L is accelerated at least 68,000-fold, whereas the exchange of mGTP [2′/3′-O-(N-methyl-anthraniloyl)-GTP] is stimulated only up to 6000-fold at the same GEF concentration. The selectivity in nucleotide exchange kinetics for GDP over GTP is even more pronounced when a Cdc42 mutant, F28L, is used, which is characterised by fast intrinsic dissociation of nucleotides. We furthermore show that both GTP and Mg²⁺ ions are required for the interaction with effectors. We suggest a novel model for selective nucleotide exchange residing on a conformational change of Cdc42 upon binding of GTP, which enables effector binding to the Cdc42 · GTP complex but, at the same time, excludes efficient modulation by the GEF. The higher exchange activity of ITSN1L towards the GDP-bound conformation of Cdc42 could represent an evolutionary adaptation of this GEF that ensures nucleotide exchange towards the formation of the signalling-active GTP-bound form of Cdc42 and avoids dissociation of the active complex.     

RhoGDI is required for Cdc42-mediated cellular transformation

BACKGROUND: Cdc42, a Rho-related small GTP binding protein, plays pivotal roles in actin cytoskeletal organization, Golgi vesicular trafficking, receptor endocytosis, and cell cycle progression. However, the target/effectors mediating these cellular activities and, in particular, those responsible for Cdc42-mediated cell growth regulation and transformation are still being determined. In this study, we set out to examine how the regulatory protein RhoGDI influences the cellular responses elicited by activated Cdc42. RESULTS: X-ray crystallographic analysis of the Cdc42-RhoGDI complex suggested that arginine 66 of Cdc42 is essential for its interaction with RhoGDI. Here we show that mutation of either arginine 66 or arginine 68 within the Switch II domain of Cdc42 completely abolished the binding of Cdc42 to RhoGDI without affecting the binding of other known regulators or target/effectors of this GTP binding protein. Introduction of the RhoGDI binding-defective mutation R66A within a constitutively active Cdc42(F28L) background was accompanied by changes in cell shape and an accumulation of Cdc42 in the Golgi when these cells were compared to those expressing Cdc42(F28L). However, the most striking change was that unlike Cdc42(F28L), which was able to induce the transformation of NIH 3T3 fibroblasts as assayed by their growth in low serum or their ability to form colonies in soft-agar, the Cdc42(F28L,R66A) mutant was transformation-defective. Likewise, the introduction of RhoGDI siRNA into Cdc42(F28L)-transfected cells inhibited their transformation. CONCLUSIONS: Taken together, the results reported here indicate that despite being a negative regulator of Cdc42 activation and GTP hydrolysis, RhoGDI plays an essential role in Cdc42-mediated cellular transformation.     

Cdc42 and Ras cooperate to mediate cellular transformation by intersectin-L

Cdc42, a Ras-related GTP-binding protein, has been implicated in the regulation of the actin cytoskeleton, membrane trafficking, cell-cycle progression, and malignant transformation. We have shown previously that a Cdc42 mutant (Cdc42(F28L)), capable of spontaneously exchanging GDP for GTP (referred to as "fast-cycling"), transformed NIH 3T3 cells because of its ability to interfere with epidermal growth factor receptor (EGFR)-Cbl interactions and EGFR down-regulation. To further examine the link between the hyperactivation of Cdc42 and its ability to alter EGFR signaling and thereby cause cellular transformation, we examined the effects of expressing different forms of the Cdc42-specific guanine nucleotide exchange factor, intersectin-L, in fibroblasts. Full-length intersectin-L exhibited little ability to stimulate nucleotide exchange on Cdc42, whereas a truncated version that contained five Src homology 3 (SH3) domains, the Dbl and pleckstrin homology domains (DH and PH domains, respectively), and a C2 domain (designated as SH3A-C2) showed modest guanine nucleotide exchange factor activity, whereas a form containing just the DH, PH, and C2 domains (DH-C2) strongly activated Cdc42. However, DH-C2 showed little ability to stimulate growth in low serum or colony formation in soft agar, whereas SH3A-C2 gave rise to a much stronger stimulation of cell growth in low serum and was highly effective in stimulating colony formation. Moreover, although SH3A-C2 strongly transformed fibroblasts, it differed from the actions of the Cdc42(F28L) mutant, as SH3A-C2 showed little ability to alter EGFR levels or the lifetime of EGF-coupled signaling through ERK. Rather, we found that SH3A-C2 exhibited strong transforming activity through its ability to mediate cooperation between Ras and Cdc42.     

Opposing roles for actin in Cdc42p polarization

In animal and fungal cells, the monomeric GTPase Cdc42p is a key regulator of cell polarity that itself exhibits a polarized distribution in asymmetric cells. Previous work showed that in budding yeast, Cdc42p polarization is unaffected by depolymerization of the actin cytoskeleton (Ayscough et al., J. Cell Biol. 137, 399-416, 1997). Surprisingly, we now report that unlike complete actin depolymerization, partial actin depolymerization leads to the dispersal of Cdc42p from the polarization site in unbudded cells. We provide evidence that dispersal is due to endocytosis associated with cortical actin patches and that actin cables are required to counteract the dispersal and maintain Cdc42p polarity. Thus, although Cdc42p is initially polarized in an actin-independent manner, maintaining that polarity may involve a reinforcing feedback between Cdc42p and polarized actin cables to counteract the dispersing effects of actin-dependent endocytosis. In addition, we report that once a bud has formed, polarized Cdc42p becomes more resistant to dispersal, revealing an unexpected difference between unbudded and budded cells in the organization of the polarization site.     

Cdc42 negatively regulates intrinsic migration of highly aggressive breast cancer cells

The small GTPase Cdc42 has been implicated as an important regulator of cell migration. However, whether Cdc42 plays similar role in all cancer cells irrespective of metastatic potential remains poorly defined. Here, we show by using three different breast cancer cell lines with different metastatic potential, the role of Cdc42 in cell migration/invasion and its relationship with a number of downstream signaling pathways controlling cell migration. Small interfering RNA (siRNA)-mediated knockdown of Cdc42 in two highly metastatic breast cancer cell lines (MDA-MB-231 and C3L5) resulted in enhancement, whereas the same in moderately metastatic (Hs578T) cell line resulted in inhibition of intrinsic cellular migration/invasion. Furthermore, Cdc42 silencing in MDA-MB-231 and C3L5 but not Hs578T cells was shown to be accompanied by increased RhoA activity and phosphorylation of protein kinase C (PKC)-δ, extracellular signal regulated kinase1/2 (Erk1/2), and protein kinase A (PKA). Pharmacological inhibition of PKCδ, MEK-Erk1/2, or PKA was shown to inhibit migration of both control and Cdc42-silenced MDA-MB-231 cells. Furthermore, introduction of constitutively active Cdc42 was shown to decrease migration/invasion of MDA-MB-231 and C3L5 but increase migration/invasion of Hs578T cells. This decreased migration/invasion of MDA-MB-231 and C3L5 cells was also shown to be accompanied by the decrease in the phosphorylations of PKCδ, Erk1/2, and PKA. These results suggested that endogenous Cdc42 could exert a negative regulatory influence on intrinsic migration/invasion and some potentially relevant changes in phosphorylation of PKCδ, Erk1/2, and PKA of some aggressive breast cancer cells.