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.     

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.     

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.     

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.     

Localization of the PAK1-, WASP-, and IQGAP1-specifying regions of Cdc42.

The Rho family small GTPase Cdc42 transmits divergent intracellular signals through multiple effector proteins to elicit cellular responses such as cytoskeletal reorganization. Potential effectors of Cdc42 implicated in mediating its cytoskeletal effect in mammalian cells include PAK1, WASP, and IQGAP1. To investigate the determinants of Cdc42-effector specificity, we utilized recombinant Cdc42 mutants and chimeras made between Cdc42 and RhoA to map the regions of Cdc42 contributing to specific effector p21-binding domain (PBD) interaction. Site-directed mutants of the switch I domain and neighboring regions of Cdc42 demonstrated differential binding patterns toward the PBDs of PAK1, WASP, and IQGAP1, suggesting that switch I provides essential determinants for the effector binding, but recognition of each effector by Cdc42 involves a distinct mechanism. Differing from Rac1, the switch I domain and the surrounding region (amino acids 29 to 55) of Cdc42 appeared to be sufficient for specific binding to PAK1, whereas determinants outside the switch I domain, residues 157-191 and 84-120 in particular, were necessary and sufficient to confer specificity to WASP and IQGAP1, respectively. In addition, IQGAP1, but not PAK1 nor WASP, required the unique "insert region," residues 122-134, of Cdc42 to achieve high affinity binding. Microinjection of the constitutively active Cdc42/RhoA chimeras into serum-starved Swiss 3T3 cells showed that although preserving PAK1- and WASP-binding activity could retain the peripheral actin microspike (PAM)-inducing activity of Cdc42, interaction with PAK1 or WASP was not required for this activity. Moreover, IQGAP1-binding alone by Cdc42 was insufficient for PAM-induction. Thus, Cdc42 utilizes multiple distinct structural determinants to specify different effector recognition and to elicit PAM-inducing effect.     

Oncogenic Dbl, Cdc42, and p21-activated kinase form a ternary signaling intermediate through the minimum interactive domains

Activation of many Rho family GTPase pathways involves the signaling module consisting of the Dbl-like guanine nucleotide exchange factors (GEFs), the Rho GTPases, and the Rho GTPase specific effectors. The current biochemical model postulates that the GEF-stimulated GDP/GTP exchange of Rho GTPases leads to the active Rho-GTP species, and subsequently the active Rho GTPases interact with and activate the effectors. Here we report an unexpected finding that the Dbl oncoprotein, Cdc42 GTPase, and PAK1 can form a complex through their minimum functional motifs, i.e., the Dbl-homolgy (DH) and Pleckstrin-homology domains of Dbl, Cdc42, and the PBD domain of PAK1. The Dbl-Cdc42-PAK1 complex is sensitive to the nucleotide-binding state of Cdc42 since either dominant negative or constitutively active Cdc42 readily disrupts the ternary binding interaction. The complex formation depends on the interactions between the DH domain of Dbl and Cdc42 and between Cdc42 and the PBD domain of PAK1 and can be reconstituted in vitro by using the purified components. Furthermore, the Dbl-Cdc42-PAK1 ternary complex is active in generating signaling output through the activated PAK1 kinase in the complex. The GEF-Rho-effector ternary intermediate is also found in other Dbl-like GEF, Rho GTPase, and effector interactions. Finally, PAK1, through the PDB domain, is able to accelerate the GEF-induced GTP loading onto Cdc42. These results suggest that signal transduction through Cdc42 and possibly other Rho family GTPases could involve tightly coupled guanine nucleotide exchange and effector activation mechanisms and that Rho GTPase effector may have a feedback regulatory role in the Rho GTPase activation.     

PAK4, a novel effector for Cdc42Hs, is implicated in the reorganization of the actin cytoskeleton and in the formation of filopodia.

The GTPases Rac and Cdc42Hs control diverse cellular functions. In addition to being mediators of intracellular signaling cascades, they have important roles in cell morphogenesis and mitogenesis. We have identified a novel PAK-related kinase, PAK4, as a new effector molecule for Cdc42Hs. PAK4 interacts only with the activated form of Cdc42Hs through its GTPase-binding domain (GBD). Co-expression of PAK4 and the constitutively active Cdc42HsV12 causes the redistribution of PAK4 to the brefeldin A-sensitive compartment of the Golgi membrane and the subsequent induction of filopodia and actin polymerization. Importantly, the reorganization of the actin cytoskeleton is dependent on PAK4 kinase activity and on its interaction with Cdc42Hs. Thus, unlike other members of the PAK family, PAK4 provides a novel link between Cdc42Hs and the actin cytoskeleton. The cellular locations of PAK4 and Cdc42Hs suggest a role for the Golgi in cell morphogenesis.     

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.     

Role of myosin-II phosphorylation in V12Cdc42-mediated disruption of Drosophila cellularization

Microinjection of constitutively active Cdc42 (V12Cdc42) disrupts the actomyosin cytoskeleton during cellularization (Crawford et al., Dev. Biol., 204, 151-164 (1998)). The p21-activated kinase (PAK) family of Ser/Thr kinases are effectors of GTP-bound forms of the small GTPases, Cdc42 and Rac. Drosophila PAK, which colocalizes with actin and myosin-II during cellularization, concentrates at sites of V12Cdc42-induced actomyosin disruption. In vitro biochemical analyses demonstrate that PAK phosphorylates the regulatory light chain (RLC) of Drosophila nonmuscle myosin-II on Ser21, a site known to activate myosin-II function. Although activated PAK does not disrupt the actomyosin cytoskeleton, it induces increased levels of Ser21 phosphorylated RLC. These findings suggest that increased levels of RLC phosphorylation do not contribute to disruption of the actomyosin hexagonal array.     

Backbone dynamics of an oncogenic mutant of Cdc42Hs shows increased flexibility at the nucleotide-binding site

Cdc42Hs, a member of the Ras superfamily of GTP-binding signal transduction proteins, binds guanine nucleotides, and acts as a molecular-timing switch in multiple signal transduction pathways. The structure of the wild-type protein has been solved (Feltham et al. (1997) Biochemistry 36, 8755-8766), and the backbone dynamics have been characterized by NMR spectroscopy (Loh et al. (1999) Biochemistry 38, 12547-12557). The F28L mutation of Cdc42Hs is characterized by an increased rate of cycling between the GTP and GDP-bound forms leading to cell transformation (Lin et al. (1997) Curr. Biol. 7, 794-797). Here, we describe the backbone dynamics of Cdc42Hs(F28L)-GDP using 1H-15N NMR measurements of T1, T1rho, and steady-state NOE at two magnetic field strengths. Residue-specific values of the generalized order parameters (Ss2 and Sf2), local correlation time (tau(e)), and exchange rate (R(ex)) were obtained using the Lipari-Szabo formalism. Chemical-shift perturbation analysis suggested that very little structural change was evident outside of the nucleotide-binding site. However, residues comprising the nucleotide-binding site, as well as the nucleotide itself, exhibit increased dynamics over a wide range of time scales in Cdc42Hs(F28L) relative to the wild type. In addition to changes in dynamics measured by relaxation methods, hydrogen-deuterium exchange indicated a substantial disruption of the hydrogen-bonding network within the nucleotide-binding site. Thus, local dynamic changes introduced by a single-point mutation can affect important aspects of signaling processes without disrupting the conformation of the whole protein.     

Structure of PAK1 in an autoinhibited conformation reveals a multistage activation switch

The p21-activated kinases (PAKs), stimulated by binding with GTP-liganded forms of Cdc42 or Rac, modulate cytoskeletal actin assembly and activate MAP-kinase pathways. The 2.3 A resolution crystal structure of a complex between the N-terminal autoregulatory fragment and the C-terminal kinase domain of PAK1 shows that GTPase binding will trigger a series of conformational changes, beginning with disruption of a PAK1 dimer and ending with rearrangement of the kinase active site into a catalytically competent state. An inhibitory switch (IS) domain, which overlaps the GTPase binding region of PAK1, positions a polypeptide segment across the kinase cleft. GTPase binding will refold part of the IS domain and unfold the rest. A related switch has been seen in the Wiskott-Aldrich syndrome protein (WASP).     

Cdc42Hs and Rac1 GTPases induce the collapse of the vimentin intermediate filament network

In this study we show that expression of active Cdc42Hs and Rac1 GTPases, two Rho family members, leads to the reorganization of the vimentin intermediate filament (IF) network, showing a perinuclear collapse. Cdc42Hs displays a stronger effect than Rac1 as 90% versus 75% of GTPase-expressing cells show vimentin collapse. Similar vimentin IF modifications were observed when endogenous Cdc42Hs was activated by bradykinin treatment, endogenous Rac1 by platelet-derived growth factor/epidermal growth factor, or both endogenous proteins upon expression of active RhoG. This reorganization of the vimentin IF network is not associated with any significant increase in soluble vimentin. Using effector loop mutants of Cdc42Hs and Rac1, we show that the vimentin collapse is mostly independent of CRIB (Cdc42Hs or Rac-interacting binding)-mediated pathways such as JNK or PAK activation but is associated with actin reorganization. This does not result from F-actin depolymerization, because cytochalasin D treatment or Scar-WA expression have merely no effect on vimentin organization. Finally, we show that genistein treatment of Cdc42 and Rac1-expressing cells strongly reduces vimentin collapse, whereas staurosporin, wortmannin, LY-294002, R(p)-cAMP, or RII, the regulatory subunit of protein kinase A, remain ineffective. Moreover, we detected an increase in cellular tyrosine phosphorylation content after Cdc42Hs and Rac1 expression without modification of the vimentin phosphorylation status. These data indicate that Cdc42Hs and Rac1 GTPases control vimentin IF organization involving tyrosine phosphorylation events.     

A bivalent dissectional analysis of the high-affinity interactions between Cdc42 and the Cdc42/Rac interactive binding domains of signaling kinases in Candida albicans

The small GTPase Cdc42, a member of the highly conserved Rho family of intracellular GTPases, communicates with downstream signaling proteins via high-affinity interactions with the consensus Cdc42/Rac interactive binding (CRIB) polypeptide sequence. Previous biochemical and structural studies show that the CRIB motif itself is insufficient for high-affinity binding to Cdc42 but requires the sequence segment C-terminal to the CRIB motif for enhanced affinity. In this study, we have investigated the high-affinity (K(d) in units of nanomolar) associations of two highly homologous extended CRIB domains (eCRIBs) from the PAK kinases, Cla4 and Cst20, with Cdc42 from Candida albicans. (1)H-(15)N NMR heteronuclear NOE data of the eCRIB polypeptides in complex with Candida Cdc42 (CaCdc42) indicate that both eCRIB peptides have approximately two binding loci for CaCdc42. When each of the two eCRIB peptides is dissected into two fragments, the N-terminal fragments containing the minimal CRIB motif (mCRIB), mCla4 and mCst20, have relatively high binding affinities with dissociation constants (K(d)) of 4.2 and 0.43 microM, respectively. On the other hand, the C-terminal fragments (cCRIB), cCla4 and cCst20, exhibit significantly lower affinities for their binding to CaCdc42. The cCla4 peptide binds to CaCdc42 with a sub-millimolar K(d) of 275 microM, and the cCst20 peptide shows an even lower binding affinity (K(d) = 1160 microM). Cross-titration experiments with the cognate fragments show that the binding affinity of cCst20 is enhanced approximately 5.5-fold (K(d) = 207 microM) in the presence of saturating amounts of mCst20, and vice versa. No such effect is observed for the binding of cCla4 and mCla4. These results suggest that the Cdc42-CRIB system can be represented by a "dual recognition" model for protein-protein interactions [Kleanthous, C., et al. (1998) Mol. Microbiol. 28, 227-233], following much the same mechanisms of multivalent molecular interactions [Song, J., and Ni, F. (1998) Biochem. Cell Biol. 76, 177-188; Mammen, M., et al. (1998) Angew Chem., Int. Ed. 37, 2754-2794]. The bivalent modeling of linked peptide fragments shows that the binding of eCla4 follows a simple additivity/avidity model, while binding of eCst20 appears to have a more complex mechanism involving cooperative effects. The differential binding mechanisms between closely related eCRIB polypeptides and CaCdc42 provide a new molecular basis for understanding kinase activation and for the design of antifungal agents targeting the large protein interaction interfaces engaged by the fungal GTPase.     

Crystal structure of the SH3 domain of betaPIX in complex with a high affinity peptide from PAK2

The p21-activated kinases (PAKs) are important effector proteins of the small GTPases Cdc42 and Rac and control cytoskeletal rearrangements and cell proliferation. The direct interaction of PAKs with guanine nucleotide exchange factors from the PIX/Cool family, which is responsible for the localization of PAK kinases to focal complexes in the cell, is mediated by a 24-residue peptide segment in PAKs and an N-terminal src homology 3 (SH3) domain in PIX/Cool. The SH3-binding segment of PAK contains the atypical consensus-binding motif PxxxPR, which is required for unusually high affinity binding. In order to understand the structural basis for the high affinity and specificity of the PIX-PAK interaction, we solved crystal structures for the N-terminal SH3 domain of betaPIX and for the complex of the atypical binding segment of PAK2 with the N-terminal SH3 domain of betaPIX at 0.92 A and 1.3A resolution, respectively. The asymmetric unit of the crystal contains two SH3 domains and two peptide ligands. The bound peptide adopts a conformation that allows for intimate contacts with three grooves on the surface of the SH3 domain that lie between the n-Src and RT-loops. Most notably, the arginine residue of the PxxxPR motif forms a salt-bridge and is tightly coordinated by a number of residues in the SH3 domain. This arginine-specific interaction appears to be the key determinant for the high affinity binding of PAK peptides. Furthermore, C-terminal residues of the peptide engage in additional interactions with the surface of the RT-loop, which significantly increases binding specificity. Compared to a recent NMR structure of a similar complex, our crystal structure reveals an alternate binding mode. Finally, we compare our crystal structure with the recently published betaPIX/Cbl-b complex structure, and suggest the existence of a molecular switch.     

Group I and II mammalian PAKs have different modes of activation by Cdc42

p21‐activated kinases (PAKs) are Cdc42 effectors found in metazoans, fungi and protozoa. They are subdivided into PAK1‐like (group I) or PAK4‐like (group II) kinases. Human PAK4 is widely expressed and its regulatory mechanism is unknown. We show that PAK4 is strongly inhibited by a newly identified auto‐inhibitory domain (AID) formed by amino acids 20 to 68, which is evolutionarily related to that of other PAKs. In contrast to group I kinases, PAK4 is constitutively phosphorylated on Ser 474 in the activation loop, but held in an inactive state until Cdc42 binding. Thus, group II PAKs are regulated through conformational changes in the AID rather than A‐loop phosphorylation.     

PAK2 activated by Cdc42 and caspase 3 mediates different cellular responses to oxidative stress-induced apoptosis

p21-activated protein kinase (PAK2) is a unique member of the PAK family kinases that plays important roles in stress signaling. It can be activated by binding to the small GTPase, Cdc42 and Rac1, or by caspase 3 cleavage. Cdc42-activated PAK2 mediates cytostasis, whereas caspase 3-cleaved PAK2 contributes to apoptosis. However, the relationship between these two states of PAK2 activation remains elusive. In this study, through protein biochemical analyses and various cell-based assays, we demonstrated that full-length PAK2 activated by Cdc42 was resistant to the cleavage by caspase 3 in vitro and within cells. When mammalian cells were treated by oxidative stress using hydrogen peroxide, PAK2 was highly activated through caspase 3 cleavage that led to apoptosis. However, when PAK2 was pre-activated by Cdc42 or by mild stress such as serum deprivation, it was no longer able to be cleaved by caspase 3 upon hydrogen peroxide treatment, and the subsequent apoptosis was also largely inhibited. Furthermore, cells expressing active mutants of full-length PAK2 became more resistant to hydrogen peroxide-induced apoptosis than inactive mutants. Taken together, this study identified two states of PAK2 activation, wherein Cdc42- and autophosphorylation-dependent activation inhibited the constitutive activation of PAK2 by caspase cleavage. The regulation between these two states of PAK2 activation provides a new molecular mechanism to support PAK2 as a molecular switch for controlling cytostasis and apoptosis in response to different types and levels of stress with broad physiological and pathological relevance.     

Structure of Cdc42 bound to the GTPase binding domain of PAK

The Rho family GTPases, Cdc42, Rac and Rho, regulate signal transduction pathways via interactions with downstream effector proteins. We report here the solution structure of Cdc42 bound to the GTPase binding domain of alphaPAK, an effector of both Cdc42 and Rac. The structure is compared with those of Cdc42 bound to similar fragments of ACK and WASP, two effector proteins that bind only to Cdc42. The N-termini of all three effector fragments bind in an extended conformation to strand beta2 of Cdc42, and contact helices alpha1 and alpha5. The remaining residues bind to switches I and II of Cdc42, but in a significantly different manner. The structure, together with mutagenesis data, suggests reasons for the specificity of these interactions and provides insight into the mechanism of PAK activation.     

A method to measure the interaction of Rac/Cdc42 with their binding partners using fluorescence resonance energy transfer between mutants of green fluorescent protein

Enhanced blue fluorescent protein (EBFP) and enhanced green fluorescent protein (EGFP) mutants of GFP in close proximity to one another can act as a fluorescence resonance energy transfer (FRET) pair. Unstructured amino acid linkers of varying length were inserted between EBFP and EGFP, revealing that linkers even as long as 50 amino acids can be accommodated and still allow FRET to occur. This led to the development of a novel biosensor for Rac/Cdc42 binding to their effector proteins based on the insertion of amino acids 75-118 of p21-activated kinase (PAK) between the GFP mutants. We demonstrate that this protein construct allows significant FRET between EBFP and EGFP and retains the ability to bind to Rac in its GTP-bound form with a binding affinity similar to the uncomplexed PAK fragment, and furthermore, on binding to Rac or Cdc42 a marked change in FRET takes place. This forms the basis for a simple, sensitive, and rapid method to measure binding of Rac/Cdc42 to their effector proteins. Since the signal is dependent upon the interaction with active GTP-bound forms it acts as a biosensor for the activation of Rac/Cdc42. It has the potential for use in live cells and for identifying localization of Rac/Cdc42 within subcellular compartments.     

GIT1 activates p21-activated kinase through a mechanism independent of p21 binding

p21-activated kinases (PAKs) associate with a guanine nucleotide exchange factor, Pak-interacting exchange factor (PIX), which in turn binds the paxillin-associated adaptor GIT1 that targets the complex to focal adhesions. Here, a detailed structure-function analysis of GIT1 reveals how this multidomain adaptor also participates in activation of PAK. Kinase activation does not occur via Cdc42 or Rac1 GTPase binding to PAK. The ability of GIT1 to stimulate alphaPAK autophosphorylation requires the participation of the GIT N-terminal Arf-GAP domain but not Arf-GAP activity and involves phosphorylation of PAK at residues common to Cdc42-mediated activation. Thus, the activation of PAK at adhesion complexes involves a complex interplay between the kinase, Rho GTPases and protein partners that provide localization cues.