Disruption of the alpha5 helix of transducin impairs rhodopsin-catalyzed nucleotide exchange

Photoactivated rhodopsin (R) catalyzes nucleotide exchange by transducin, the heterotrimeric G protein of the rod cell. Recently, we showed that certain alanine replacement mutants of the alpha5 helix of the alpha subunit of transducin (Galpha(t)) displayed very rapid nucleotide exchange rates even in the absence of R [Marin, E. P., Krishna, A. G., and Sakmar, T. P. (2001) J. Biol. Chem. 276, 27400-27405]. We suggested that R catalyzes nucleotide exchange by perturbing residues on the alpha5 helix. Here, we characterize deletion, insertion, and proline replacement mutants of amino acid residues in alpha5. In general, the proline mutants exhibited rates of uncatalyzed nucleotide exchange that were 4-8-fold greater than wild type. The proline mutants also generally displayed decreased rates of R-catalyzed activation. The degree of reduction of the activation rate correlated with the position of the residue replaced with proline. Mutants with replacement of residues at the amino terminus of alpha5 exhibited mild (<2-fold) decreases, whereas mutants with replacement of residues at the carboxyl terminus of alpha5 were completely resistant to R-catalyzed activation. In addition, insertion of a single helical turn in the form of four alanine residues following Ile339 at the carboxyl terminus of alpha5 prevented R-catalyzed activation. Together, the results provide evidence that alpha5 serves an important function in mediating R-catalyzed nucleotide exchange. In particular, the data suggest the importance of the connection between the alpha5 helix and the adjacent carboxyl-terminal region of Galpha(t).     

The function of interdomain interactions in controlling nucleotide exchange rates in transducin

The intramolecular contacts in heterotrimeric G proteins that determine the rates of basal and receptor-stimulated nucleotide exchange are not fully understood. The alpha subunit of heterotrimeric G proteins consists of two domains: a Ras-like domain with structural homology to the monomeric G protein Ras and a helical domain comprised of six alpha-helices. The bound nucleotide lies in a deep cleft between the two domains. Exchange of the bound nucleotide may involve opening of this cleft. Thus interactions between the domains may affect the rate of nucleotide exchange in G proteins. We have tested this hypothesis in the alpha subunit of the rod cell G protein transducin (Galpha(t)). Site-directed mutations were prepared in a series of residues located at the interdomain interface. The proteins were expressed in vitro in a reticulocyte lysate system. The rates of basal and rhodopsin-catalyzed nucleotide exchange were determined using a trypsin digestion assay specifically adapted for kinetic measurements. Charge-altering substitutions of two residues at the interdomain interface, Lys(273) and Lys(276), increased basal nucleotide exchange rates modestly (5-10-fold). However, we found no evidence that interactions spanning the two domains in Galpha(t) significantly affected either basal or rhodopsin-catalyzed nucleotide exchange rates. These results suggest that opening of the interdomain cleft is not an energetic barrier to nucleotide exchange in Galpha(t). Experiments with Galpha(i1) suggest by comparison that the organization and function of the interdomain region differ among various G protein subtypes.     

Structural Evidence for a Sequential Release Mechanism for Activation of Heterotrimeric G Proteins

Heptahelical G-protein (heterotrimeric guanine nucleotide-binding protein)-coupled receptors couple to heterotrimeric G proteins to relay extracellular signals to intracellular signaling networks, but the molecular mechanism underlying guanosine 5′-diphosphate (GDP) release by the G protein α-subunit is not well understood. Amino acid substitutions in the conserved α5 helix of G_i, which extends from the C-terminal region to the nucleotide-binding pocket, cause dramatic increases in basal (receptor-independent) GDP release rates. For example, mutant Gα_i1-T329A shows an 18-fold increase in basal GDP release rate and, when expressed in culture, it causes a significant decrease in forskolin-stimulated cAMP accumulation. The crystal structure of Gα_i1-T329A·GDP shows substantial conformational rearrangement of the switch I region and additional striking alterations of side chains lining the catalytic pocket that disrupt the Mg⁺² coordination sphere and dislodge bound Mg⁺². We propose a “sequential release” mechanism whereby a transient conformational change in the α5 helix alters switch I to induce GDP release. Interestingly, this mechanistic model for heterotrimeric G protein activation is similar to that suggested for the activation of the plant small G protein Rop4 by RopGEF8.     

Receptor activation of G proteins

G proteins are a highly conserved family of membrane-associated proteins composed of alpha, beta, and gamma subunits. The alpha subunit, which is unique for each G protein, binds GDP or GTP. Receptors such as those for beta- and alpha-adrenergic catecholamines, muscarinic agonists, and the retinal photoreceptor rhodopsin, catalyze the exchange of GDP for GTP binding to the alpha subunit of a specific G protein. G alpha.GTP regulates appropriate effector enzymes such as adenylyl cyclase or the cyclic GMP phosphodiesterase. The beta gamma-subunit complex of G proteins is required for efficient receptor-catalyzed alpha subunit guanine nucleotide exchange and also functions as an attenuator of alpha subunit activation of effector enzymes. Recent elucidation of both receptor and G protein primary sequence has allowed structural predictions and new experimental approaches to study the mechanism of receptor-catalyzed G protein regulation of specific effector systems and the control of cell function including metabolism, secretion, and growth.     

A Conserved Phenylalanine as a Relay between the α5 Helix and the GDP Binding Region of Heterotrimeric Gi Protein α Subunit

G protein activation by G protein-coupled receptors is one of the critical steps for many cellular signal transduction pathways. Previously, we and other groups reported that the α5 helix in the G protein α subunit plays a major role during this activation process. However, the precise signaling pathway between the α5 helix and the guanosine diphosphate (GDP) binding pocket remains elusive. Here, using structural, biochemical, and computational techniques, we probed different residues around the α5 helix for their role in signaling. Our data showed that perturbing the Phe-336 residue disturbs hydrophobic interactions with the β2-β3 strands and α1 helix, leading to high basal nucleotide exchange. However, mutations in β strands β5 and β6 do not perturb G protein activation. We have highlighted critical residues that leverage Phe-336 as a relay. Conformational changes are transmitted starting from Phe-336 via β2-β3/α1 to Switch I and the phosphate binding loop, decreasing the stability of the GDP binding pocket and triggering nucleotide release. When the α1 and α5 helices were cross-linked, inhibiting the receptor-mediated displacement of the C-terminal α5 helix, mutation of Phe-336 still leads to high basal exchange rates. This suggests that unlike receptor-mediated activation, helix 5 rotation and translocation are not necessary for GDP release from the α subunit. Rather, destabilization of the backdoor region of the Gα subunit is sufficient for triggering the activation process.     

Molecular dynamics simulations of transducin: interdomain and front to back communication in activation and nucleotide exchange

The dynamic events that underlie the nucleotide exchange process for the Galpha subunit of transducin (Galpha(t)) were studied with nanosecond time-scale molecular dynamics simulations. The modeled systems include the active and inactive forms of the wild-type Galpha(t) and three of its mutants (GDP-bound form only): F332A, A322S, and Q326A that are known to exhibit various degrees of enhancement of their basal and receptor-catalyzed rates of nucleotide exchange (150-fold, 70-fold and WT-like, respectively). The results of these computational experiments reveal a number of nucleotide-dependent structural and dynamic changes (involving the alpha(B)-alpha(C) loop, the inter-domain orientation of the helical and GTPase domains and the alpha(5) helix) that were not observed in the various crystal structures of Galpha(t). Notably, the results show the existence of a front to back communication device (involving the beta(2)-beta(3) hairpin, the alpha(1) helix and the alpha(5) helix), strategically located near all elements susceptible to be involved in receptor-mediated activation/nucleotide exchange. The wild-type simulations suggest that the dynamic interplay between the elements of this device would be critical for the activation of the Galpha(t) subunit. This inference is confirmed by the results of the computational experiments on the mutants that show that even in their GDP-bound forms, the A322S and F332A mutants acquire an "active-like" structure and dynamics phenotype. The same is not true for the Q326A mutant whose structural and dynamic properties remain similar to those of the GDP-bound WT. Taken together the results suggest a nucleotide exchange mechanism, analogous to that found in the Arf family GTPases, in which a partially activated state, achievable from a receptor-mediated action of the front to back communication device either by displacement of the C-terminal alpha(5) helix, of the N-terminal alpha(N) helix, or of the Gbetagamma subunit, could precede the dissociation of GDP from the native Galpha subunit.     

Probing the mechanism of rhodopsin-catalyzed transducin activation

An agonist-bound G protein-coupled receptor (GPCR) induces a GDP/GTP exchange on the G protein alpha-subunit (G alpha) followed by the release of G alpha GTP and G beta gamma which, subsequently, activate their targets. The C-terminal regions of G alpha subunits constitute a major receptor recognition domain. In this study, we tested the hypothesis that the GPCR-induced conformational change is communicated from the G alpha C-terminus, via the alpha 5 helix, to the nucleotide-binding beta 6/alpha 5 loop causing GDP release. Mutants of the visual G protein, transducin, with a modified junction of the C-terminus were generated and analyzed for interaction with photoexcited rhodopsin (R*). A flexible linker composed of five glycine residues or a rigid three-turn alpha-helical segment was inserted between the 11 C-terminal residues and the alpha 5 helix of G alpha(t)-like chimeric G alpha, G alpha(ti). The mutant G alpha subunits with the Gly-loop (G alpha(ti)L) and the extended alpha 5 helix (G alpha(ti)H) retained intact interactions with G beta gamma(t), and displayed modestly reduced binding to R*. G alpha(ti)H was capable of efficient activation by R*. In contrast, R* failed to activate G alpha(ti)L, suggesting that the Gly-loop absorbs a conformational change at the C-terminus and blocks G protein activation. Our results provide evidence for the role of G alpha C-terminus/alpha 5 helix/beta 6/alpha 5 loop route as a dominant channel for transmission of the GPCR-induced conformational change leading to G protein activation.     

Proline residues in transmembrane alpha helices affect the folding of bacteriorhodopsin

Proline residues occur frequently in transmembrane alpha helices, which contrasts with their behaviour as helix-breakers in water-soluble proteins. The three membrane-embedded proline residues of bacteriorhodopsin have been replaced individually by alanine and glycine to give P50A, or P50G on helix B, P91A, or P91G on helix C, and P186A or P186G on helix F, and the effect on the protein folding kinetics has been investigated. The rate-limiting apoprotein folding step, which results in formation of a seven transmembrane, alpha helical state, was slower than wild-type protein for the Pro50 and Pro91 mutants, regardless of whether they were mutated to Ala or Gly. These proline residues give rise to several inter-helix contacts, which are therefore important in folding to the seven transmembrane helix state. No evidence for cis-trans isomerisations of the peptidyl prolyl bonds was found during this rate-limiting apoprotein folding step. Mutations of all three membrane-embedded proline residues affected the subsequent retinal binding and final folding to bacteriorhodopsin, suggesting that these proline residues contribute to formation of the retinal binding pocket within the helix bundle, again via helix/helix interactions. These results point to proline residues in transmembrane alpha helices being important in the folding of integral membrane proteins. The helix/helix interactions and hydrogen bonds that arise from the presence of proline residues in transmembrane alpha helices can affect the formation of transmembrane alpha helix bundles as well as cofactor binding pockets.     

Mechanism of the receptor-catalyzed activation of heterotrimeric G proteins

Heptahelical receptors activate intracellular signaling pathways by catalyzing GTP for GDP exchange on the heterotrimeric G protein alpha subunit (G alpha). Despite the crucial role of this process in cell signaling, little is known about the mechanism of G protein activation. Here we explore the structural basis for receptor-mediated GDP release using electron paramagnetic resonance spectroscopy. Binding to the activated receptor (R*) causes an apparent rigid-body movement of the alpha5 helix of G alpha that would perturb GDP binding at the beta6-alpha5 loop. This movement was not observed when a flexible loop was inserted between the alpha5 helix and the R*-binding C terminus, which uncouples R* binding from nucleotide exchange, suggesting that this movement is necessary for GDP release. These data provide the first direct observation of R*-mediated conformational changes in G proteins and define the structural basis for GDP release from G alpha.     

Interdomain interactions regulate GDP release from heterotrimeric G proteins.

The role of interdomain contact sites in basal GDP release from heterotrimeric G proteins is unknown. G(alpha)(o) and G(alpha)(i1) display a 5-fold difference in the rate of GDP dissociation with half-times of 2.3 +/- 0.2 and 10.4 +/- 1.3 min, respectively. To identify molecular determinants of the GDP release rate, we evaluated the rate of binding of the fluorescent guanine nucleotide 2'(3')-O-(N-methyl-3'-anthraniloyl)guanosine 5'-O-(3-thiotriphosphate) (mGTPgammaS) to chimers of G(alpha)(o) and G(alpha)(i1). Although no one region of the G protein determined the GDP dissociation rate, when the C-terminal 123 amino acids in G(alpha)(i1) were replaced with those of G(alpha)(o), the GDP release rate increased 3.3-fold compared to that of wild-type G(alpha)(i1). Within the C-terminal portion, modification of four amino acids in a coil between beta4 and the alpha3 helix resulted in GDP release kinetics identical to those of wild-type G(alpha)(o). Based on the G(alpha)(i1)-GDP crystal structure of this region, Leu(232) appeared to form a hydrophobic contact with Arg(144) of the helical domain. The role of this interaction was confirmed by G(alpha)(i1) L232Q and G(alpha)(i1) R144A which displayed 2-5-fold faster GDP release rates compared to wild-type G(alpha)(i1) (t(1/2) 4.7 and 1.5 min, respectively), suggesting that interdomain bridging contacts partially determine the basal rate of GDP release from heterotrimeric G proteins.     

Rhodopsin recognition by mutant G(s)alpha containing C-terminal residues of transducin

The C-terminal regions of the heterotrimeric G protein alpha-subunits play key roles in selective activation of G proteins by their cognate receptors. In this study, mutant G(s)alpha proteins with substitutions by C-terminal residues of transducin (G(t)alpha) were analyzed for their interaction with light-activated rhodopsin (R*) to delineate the critical determinants of the G(t)alpha/R* coupling. In contrast to G(s)alpha, a chimeric G(s)alpha/G(t)alpha protein containing only 11 C-terminal residues from transducin was capable of binding to and being potently activated by R*. Our results suggest that Cys(347) and Gly(348) are absolutely essential, whereas Asp(346) is more modestly involved in the G(t) activation by R*. In addition, the analysis of the intrinsic nucleotide exchange in mutant G(s)alpha indicated an interaction between the C terminus and the switch II region in G(t)alpha.GDP. Mutant G(s)alpha containing the G(t)alpha C terminus and substitutions of Asn(239) and Asp(240) (switch II) by the corresponding G(t)alpha residues, Glu(212) and Gly(213), displayed significant reductions in spontaneous guanosine 5'-O-(3-thiotriphosphate)-binding rates to the levels approaching those in G(t)alpha. Communication between the C terminus and switch II of G(t)alpha does not appear essential for the activational coupling between G(t) and R*, but may represent one of the mechanisms by which Galpha subunits control intrinsic nucleotide exchange.     

C5a receptor activation. Genetic identification of critical residues in four transmembrane helices.

Hormones and sensory stimuli activate serpentine receptors, transmembrane switches that relay signals to heterotrimeric guanine nucleotide-binding proteins (G proteins). To understand the switch mechanism, we subjected 93 amino acids in transmembrane helices III, V, VI, and VII of the human chemoattractant C5a receptor to random saturation mutagenesis. A yeast selection identified 121 functioning mutant receptors, containing a total of 523 amino acid substitutions. Conserved hydrophobic residues are located on helix surfaces that face other helices in a modeled seven-helix bundle (Baldwin, J. M., Schertler, G. F., and Unger, V. M. (1997) J. Mol. Biol. 272, 144-164), whereas surfaces predicted to contact the surrounding lipid tolerate many substitutions. Our analysis identified 25 amino acid positions resistant to nonconservative substitutions. These appear to comprise two distinct components of the receptor switch, a surface at or near the extracellular membrane interface and a core cluster in the cytoplasmic half of the bundle. Twenty-one of the 121 mutant receptors exhibit constitutive activity. Amino acids substitutions in these activated receptors predominate in helices III and VI; other activating mutations truncate the receptor near the extracellular end of helix VI. These results identify key elements of a general mechanism for the serpentine receptor switch.     

Mutational analysis of the catalytic domain of O-linked N-acetylglucosaminyl transferase

O-Linked N-acetylglucosaminyltransferase (OGT) catalyzes the transfer of O-linked GlcNAc to serine/threonine residues of a variety of target proteins, many of which have been implicated in such diseases as diabetes and neurodegeneration. The addition of O-GlcNAc to proteins occurs in response to fluctuations in cellular concentrations of UDP-GlcNAc, which result from nutrients entering the hexosamine biosynthetic pathway. However, the molecular mechanisms involved in sugar nucleotide recognition and transfer to protein are poorly understood. We employed site-directed mutagenesis to target potentially important amino acid residues within the two conserved catalytic domains of OGT (CD I and CD II), followed by an in vitro glycosylation assay to evaluate N-acetylglucosaminyltransferase activity after bacterial expression. Although many of the amino acid substitutions caused inactivation of the enzyme, we identified three amino acid residues (two in CD I and one in CD II) that produced viable enzymes when mutated. Structure-based homology modeling revealed that these permissive mutants may be either in or near the sugar nucleotide-binding site. Our findings suggest a model in which the two conserved regions of the catalytic domain, CD I and CD II, contribute to the formation of a UDP-GlcNAc-binding pocket that catalyzes the transfer of O-GlcNAc to substrate proteins. Identification of viable OGT mutants may facilitate examination of its role in nutrient sensing and signal transduction cascades.     

Structural elements of the gamma-aminobutyric acid type A receptor conferring subtype selectivity for benzodiazepine site ligands

gamma-aminobutyric acid type A (GABAA) receptors comprise a subfamily of ligand-gated ion channels whose activity can be modulated by ligands acting at the benzodiazepine binding site on the receptor. The benzodiazepine binding site was characterized using a site-directed mutagenesis strategy in which amino acids of the alpha5 subunit were substituted by their corresponding alpha1 residues. Given the high affinity and selectivity of alpha1-containing compared with alpha5-containing GABAA receptors for zolpidem, mutated alpha5 subunits were co-expressed with beta2 and gamma2 subunits, and the affinity of recombinant receptors for zolpidem was measured. One alpha5 mutant (bearing P162T, E200G, and T204S) exhibited properties similar to that of the alpha1 subunit, notably high affinity zolpidem binding and potentiation by zolpidem of GABA-induced chloride current. Two of these mutations, alpha5P162T and alpha5E200G, might alter binding pocket conformation, whereas alpha5T204S probably permits formation of a hydrogen bond with a proton acceptor in zolpidem. These three amino acid substitutions also influenced receptor affinity for CL218872. Our data thus suggest that corresponding amino acids of the alpha1 subunit, particularly alpha1-Ser204, are the crucial residues influencing ligand selectivity at the binding pocket of alpha1-containing receptors, and a model of this binding pocket is presented.     

Perturbing the linker regions of the alpha-subunit of transducin: a new class of constitutively active GTP-binding proteins

The GDP-GTP exchange activity of the retinal G protein, transducin, is markedly accelerated by the photoreceptor rhodopsin in the first step of visual transduction. The x-ray structures for the alpha subunits of transducin (alpha(T)) and other G proteins suggest that the nucleotide-binding (Ras-like) domain and a large helical domain form a "clam shell" that buries the GDP molecule. Thus, receptor-promoted G protein activation may involve "opening the clam shell" to facilitate GDP dissociation. In this study, we have examined whether perturbing the linker regions connecting the Ras-like and helical domains of Galpha subunits gives rise to a more readily exchangeable state. The sole glycine residues in linkers 1 and 2 were individually changed to proline residues within an alpha(T)/alpha(i1) chimera (designated alpha(T)(*)). Both alpha(T)(*) linker mutants showed significant increases in their basal rates of GDP-GTP exchange when compared either to retinal alpha(T) or recombinant alpha(T)(*). The alpha(T)(*) linker mutants were responsive to aluminum fluoride, which binds to alpha-GDP complexes and induces changes in Switch 2. Although both linker mutants were further activated by light-activated rhodopsin together with the betagamma complex, their activation was not influenced by betagamma alone, arguing against the idea that the betagamma complex helps to pry apart the helical and Ras-like domains of Galpha subunits. Once activated, the alpha(T)(*) linker mutants were able to stimulate the cyclic GMP phosphodiesterase. Overall, these findings highlight a new class of activated Galpha mutants that constitutively exchange GDP for GTP and should prove valuable in studying different G protein-signaling systems.     

The receptor-bound "empty pocket" state of the heterotrimeric G-protein alpha-subunit is conformationally dynamic

Heterotrimeric G-protein activation by a G-protein-coupled receptor (GPCR) requires the propagation of structural signals from the receptor-interacting surfaces to the guanine nucleotide-binding pocket. To probe conformational changes in the G-protein alpha-subunit (G(alpha)) associated with activated GPCR (R*) interactions and guanine nucleotide exchange, high-resolution solution NMR methods are being applied in studying signaling of the G-protein, transducin, by light-activated rhodopsin. Using these methods, we recently demonstrated that an isotope-labeled G(alpha) reconstituted heterotrimer forms functional complexes under NMR experimental conditions with light-activated, detergent-solubilized rhodopsin and a soluble mimic of R*, both of which trigger guanine nucleotide exchange [Ridge, K. D., et al. (2006) J. Biol. Chem. 281, 7635-7648]. Here, it is shown that both light-activated rhodopsin and the soluble mimic of R form trapped intermediate complexes with a GDP-released "empty pocket" state of the heterotrimer in the absence of GTP (or GTPgammaS). In contrast to guanine nucleotide-bound forms of G(alpha), the NMR spectra of the GDP-released, R-bound empty pocket state of G(alpha) display severe line broadening suggestive of a dynamic intermediate state. Interestingly, the conformation of a GDP-depleted, Mg(2+)-bound state of G(alpha) generated in a manner independent of R* does not exhibit a similar degree of line broadening but rather appears structurally similar to the GDP/Mg(2+)-bound form of the protein. Taken together, these results suggest that R*-mediated changes in the receptor-interacting regions of G(alpha), and not the absence of bound guanine nucleotide, are the predominant factors which dictate G(alpha) conformation and dynamics in this R*-bound state of the heterotrimer.     

Critical role of helix 12 of the vitamin D(3) receptor for the partial agonism of carboxylic ester antagonists.

The carboxy-terminal alpha-helix of a nuclear receptor ligand-binding domain (LBD), helix 12, contains a critical, ligand-modulated interface for the interaction with coactivator proteins. In this study, using the example of the vitamin D receptor (VDR) and the partial antagonist ZK159222, the role of helix 12 (residues 417-427) for both antagonistic and agonistic receptor actions was investigated. Amino acid residue G423 was demonstrated to be critical for partial agonism of ZK159222, but not for the activity of the natural VDR agonist, 1alpha,25-dihydroxyvitamin D(3) (1alpha,25(OH)(2)D(3)). The amount of partial agonism of ZK159222 increased when helix 12 was truncated by the last four amino acid residues (Delta424-27) and augmented even more, when in addition helix 12 of VDR's dimerization partner, retinoid X receptor (RXR), was truncated. In contrast, the low agonism of a structural derivative of ZK159222, ZK168281, was not affected comparably, whereas other close structural relatives of ZK159222 even demonstrated the same agonistic activity as that of 1alpha,25(OH)(2)D(3). The amount of agonism of ZK159222 and ZK168281 at different variations of helix 12 correlated well with VDR's ability to complex with coactivator proteins and inversely correlated with the strength of the compound's antagonistic action on 1alpha,25(OH)(2)D(3) signalling. Molecular dynamics simulations of the LBD complexed with the two antagonists could explain their different action by demonstrating a more drastic displacement of helix 12 through ZK168281 than through ZK159222. Moreover, the modelling could indicate a kink of helix 12 at amino acid residue G423, which provides the last four amino acid residues of helix 12 with a modulatory role for the partial agonism of some VDR antagonists, such as ZK159222. In conclusion, partial agonism of a VDR antagonist is lower the more it disturbs helix 12 in taking the optimal position for coactivator interaction.     

Identification of dynamical correlations within the myosin motor domain by the normal mode analysis of an elastic network model

In order to systematically analyze functionally relevant dynamical correlations within macromolecular complexes, we have developed computational methods based on the normal mode analysis of an elastic network model. First, we define two types of dynamical correlations (fluctuation-based and density-based), which are computed by summing up contributions from all low-frequency normal modes up to a given cutoff. Then we use them to select dynamically important "hinge residues" whose elastic distortion affects the fluctuations of a large number of residues. Second, in order to clarify long-range dynamical correlations, we decompose the dynamical correlations to individual normal modes to identify the most relevant modes. We have applied these methods to the analysis of the motor domain of Dictyostelium myosin and have obtained the following three interesting results that shed light on its mechanism of force generation: first, we find the hinge residues are distributed over several key inter-subdomain joints (including the nucleotide-binding pocket, the relay helix, the SH1 helix, the strut between the upper 50 kDa and the lower 50 kDa subdomains), which is consistent with their hypothesized roles in modulating functionally relevant inter-subdomain conformational changes; second, a single mode 7 (for structure 1VOM) is found to dominate the fluctuation-based correlations between the converter/strut and the nucleotide-binding pocket, revealing a surprising simplicity for their intriguing roles in the force generation mechanism; finally, we find a negative density-based correlation between the strut and the nucleotide-binding pocket, which is consistent with the hypothesized signaling pathway that links the actin-binding site's opening/closing with the nucleotide-binding pocket's closing/opening.     

Sequence landmark patterns identify and characterize protein families

The three-dimensional structures of homologous proteins are usually conserved during evolution, as are critical residues in a few short sequence motifs that often constitute the active site in enzymes. The precise spatial organization of such sites depends on the lengths and positions of the secondary structural elements connecting the motifs. We show how members of protein superfamilies, such as kinesins, myosins, and G(alpha) subunits of trimeric G proteins, are identified and classed by simply counting the number of amino acid residues between important sequence motifs in their nucleotide triphosphate-hydrolyzing domains. Subfamily-specific landmark patterns (motif to motif scores) are principally due to inserts and gaps in surface loops. Unusual protein sequences and possible sequence prediction errors are detected.     

Trp fluorescence reveals an activation‐dependent cation‐π interaction in the Switch II region of Gαi proteins

Crystal structures of Gα_i (and closely related family member Gα_t) reveal much of what we currently know about G protein structure, including changes which occur in Switch regions. Gα_t exhibits a low rate of basal (uncatalyzed) nucleotide exchange and an ordered Switch II region in the GDP‐bound state, unlike Gα_i, which exhibits higher basal exchange and a disordered Switch II region in Gα_iGDP structures. Using purified Gα_i and Gα_t, we examined the intrinsic tryptophan fluorescence of these proteins, which reports conformational changes associated with activation and deactivation of Gα proteins. In addition to the expected enhancement in tryptophan fluorescence intensity, activation of GαGDP proteins was accompanied by a modest but notable red shift in tryptophan emission maxima. We identified a cation‐π interaction between tryptophan and arginine residues in the Switch II of Gα_i family proteins that mediates the observed red shift in emission maxima. Furthermore, amino‐terminal myristoylation of Gα_i resulted in a less polar environment for tryptophan residues in the GTPase domain, consistent with an interaction between the myristoylated amino terminus and the GTPase domain of Gα proteins. These results reveal unique insights into conformational changes which occur upon activation and deactivation of G proteins in solution.