Identification of residues in the human guanylate-binding protein 1 critical for nucleotide binding and cooperative GTP hydrolysis

The guanylate-binding proteins (GBPs) form a group of interferon-gamma inducible GTP-binding proteins which belong to the family of dynamin-related proteins. Like other members of this family, human guanylate-binding protein 1 (hGBP1) shows nucleotide-dependent oligomerisation that stimulates the GTPase activity of the protein. A unique feature of the GBPs is their ability to hydrolyse GTP to GDP and GMP. In order to elucidate the relationship between these findings, we designed point mutants in the phosphate-binding loop (P-loop) as well as in the switch I and switch II regions of the protein based on the crystal structure of hGBP1. These mutant proteins were analysed for their interaction with guanine nucleotides labeled with a fluorescence dye and for their ability to hydrolyse GTP in a cooperative manner. We identified mutations of amino acid residues that decrease GTPase activity by orders of magnitude a part of which are conserved in GTP-binding proteins. In addition, mutants in the P-loop were characterized that strongly impair binding of nucleotide. In consequence, together with altered GTPase activity and given cellular nucleotide concentrations this results in hGBP1 mutants prevailingly resting in the nucleotide-free (K51A and S52N) or the GTP bound form (R48A), respectively. Using size-exclusion chromatography and analytical ultracentrifugation we addressed the impact on protein oligomerisation. In summary, mutants of hGBP1 were identified and biochemically characterized providing hGBP1 locked in defined states in order to investigate their functional role in future cell biology studies.     

S-Nitrosylation Decreases the Adsorption of H-Ras in Lipid Bilayer and Changes Intrinsic Catalytic Activity

Structural, chemical, and mutational studies have shown that C-terminal cysteine residues on H-Ras could potentially be oxidized by nitrosylation. For investigating the effect of nitrosylation of Ras molecule on the adsorption of farnesylated H-Ras into lipid layer, experiments with optical waveguide lightmode spectroscopy were used. The analysis of association/dissociation kinetics to planar phospholipids under controlled hydrodynamic conditions has shown that preliminary treatment of protein by S-nitroso-cysteine decreased the adsorption of farnesylated H-Ras. The authors have found that compared with nitrosylated forms, farnesylated H-Ras has more compact configuration, because of the smaller area occupied by protein upon absorption at the membrane. The association rate coefficient for unmodified H-Ras was lower than similar parameter for farnesylated and nitrosylated forms. However, the desorbability, i.e., parameter, which reflects the rate of dissociation of protein from lipids is higher for farnesylated H-Ras. In addition, it was have found that farnesylation of cytoplasmic H-Ras, in contrast to membrane-derived forms, inhibits intrinsic GTPase activity of protein, and preliminary treatment of H-Ras by S-nitroso-cysteine restores the activity to the control level. These data suggest that nitrosylation of H-Ras rearranges the adsorptive potential and intrinsic GTPase activity of H-Ras through modification of C-terminal cysteines of molecule.     

Tetramerization of human guanylate-binding protein 1 is mediated by coiled-coil formation of the C-terminal α-helices

The human guanylate-binding protein 1 (hGBP1) is a large GTP-binding protein belonging to the dynamin family, a common feature of which is nucleotide-dependent assembly to homotypic oligomers. Assembly leads to stimulation of GTPase activity, which, in the case of dynamin, is responsible for scission of vesicles from membranes. By yeast two-hybrid and biochemical experiments we addressed intermolecular interactions between all subdomains of hGBP1 and identified the C-terminal subdomain, α12/13, as a new interaction site for self-assembly. α12/13 represents a stable subdomain of hGBP1, as shown by CD spectroscopy. In addition to contacts between GTPase domains leading to dimer formation, the interaction between two α12/13 subdomains, in the course of GTP hydrolysis, results in tetramer formation of the protein. With the help of CD spectroscopy we showed coiled-coil formation of two α12/13 subdomains and concentration-dependent measurements allow estimating a value for the dissociation constant of 7.3 μM. We suggest GTP hydrolysis-driven release of the α12/13 subdomain, making it available for coiled-coil formation. Furthermore, we can demonstrate the biological relevance of hGBP1 tetramer formation in living cells by chemical cross-link experiments.     

Human Guanylate Binding Proteins Potentiate the Anti-Chlamydia Effects of Interferon-γ

Chlamydiae are obligate intracellular pathogens that are sensitive to pro-inflammatory cytokine interferon-γ. IFN-γ-inducible murine p47 GTPases have been demonstrated to function in resistance to chlamydia infection in vivo and in vitro. Because the human genome does not encode IFN-γ-inducible homologues of these proteins, the significance of the p47 GTPase findings to chlamydia pathogenesis in humans is unclear. Here we report a pair of IFN-γ-inducible proteins, the human guanylate binding proteins (hGBPs) 1 and 2 that potentiate the anti-chlamydial properties of IFN-γ. hGBP1 and 2 localize to the inclusion membrane, and their anti-chlamydial functions required the GTPase domain. Alone, hGBP1 or 2 have mild, but statistically significant and reproducible negative effects on the growth of Chlamydia trachomatis, whilst having potent anti-chlamydial activity in conjunction with treatment with a sub-inhibitory concentration of IFN-γ. Thus, hGBPs appear to potentiate the anti-chlamydial effects of IFN-γ. Indeed, depletion of hGBP1 and 2 in cells treated with IFN-γ led to an increase in inclusion size, indicative of better growth. Interestingly, chlamydia species/strains harboring the full-length version of the putative cytotoxin gene, which has been suggested to confer resistance to IFN-γ was not affected by hGBP overexpression. These findings identify the guanylate binding proteins as potentiators of IFN-γ inhibition of C. trachomatis growth, and may be the targets of the chlamydial cytotoxin.     

The guanine cap of human guanylate-binding protein 1 is responsible for dimerization and self-activation of GTP hydrolysis

Human guanylate-binding protein 1 (hGBP1) belongs to the superfamily of large, dynamin-related GTPases. The expression of hGBP1 is induced by stimulation with interferons (mainly interferon-γ), and it plays a role in different cellular responses to inflammatory cytokines, e.g. pathogen defence, control of proliferation, and angiogenesis. Although other members of the dynamin superfamily show a diversity of cellular functions, they share a common GTPase mechanism that relies on nucleotide-controlled oligomerization and self-activation of the GTPase. Previous structural studies on hGBP1 have suggested a mechanism of GTPase and GDPase activity that, as a critical step, involves dimerization of the large GTP-binding domains. In this study, we show that the guanine cap of hGBP1 is the key structural element responsible for dimerization, and is thereby essential for self-activation of the GTPase activity. Studies of concentration-dependent GTP hydrolysis showed that mutations of residues in the guanine cap, in particular Arg240 and Arg244, resulted in higher dissociation constants of the dimer, whereas the maximum hydrolytic activity was largely unaffected. Additionally, we identified an intramolecular polar contact (Lys62-Asp255) whose mutation leads to a loss of self-activation capability and controlled oligomer formation. We suggest that this contact structurally couples the guanine cap to the switch regions of the GTPase, translating the structural changes that occur upon nucleotide binding to a change in oligomerization and self-activation.     

Transient kinetic investigation of GTP hydrolysis catalyzed by interferon-gamma-induced hGBP1 (human guanylate binding protein 1)

Within the family of large GTP-binding proteins, human guanylate binding protein 1 (hGBP1) belongs to a subgroup of interferon-inducible proteins. GTP hydrolysis activity of these proteins is much higher compared with members of other GTPase families and underlies mechanisms that are not understood. The large GTP-binding proteins form self-assemblies that lead to stimulation of the catalytic activity. The unique result of GTP hydrolysis catalyzed by hGBP1 is GDP and GMP. We investigated this reaction mechanism by transient kinetic methods using radioactively labeled GTP as well as fluorescent probes. Substrate binding and formation of the hGBP1 homodimer are fast as no lag phase is observed in the time courses of GTP hydrolysis. Instead, multiple turnover experiments show a rapid burst of P(i) formation prior to the steady state phase, indicating a rate-limiting step after GTP cleavage. Both molecules are catalytically active and cleave off a phosphate ion in the first step. Then bifurcation into catalytic inactivation, probably by irreversible dissociation of the dimer, and into GDP hydrolysis is observed. The second cleavage step is even faster than the first step, implying a rapid rearrangement of the nucleotide within the catalytic center of hGBP1. We could also show that the release of the products, including the phosphate ions, is fast and not limiting the steady state activity. We suggest that slow dissociation of the GMP-bound homodimer gives rise to the burst behavior and controls the steady state. The assembled forms of the GDP- and GMP-bound states of hGBP1 are accessible only through GTP binding and hydrolysis and achieve a lifetime of a few seconds.     

Cloning and characterization of a mammalian prenyl protein-specific protease

Proteins containing C-terminal "CAAX" sequence motifs undergo three sequential post-translational processing steps: modification of the cysteine with either a 15-carbon farnesyl or 20-carbon geranylgeranyl isoprenyl lipid, proteolysis of the C-terminal -AAX tripeptide, and methylation of the carboxyl group of the now C-terminal prenylcysteine. A putative prenyl protein protease in yeast, designated Rce1p, was recently identified. In this study, a portion of a putative human homologue of RCE1 (hRCE1) was identified in a human expressed sequence tag data base, and the corresponding cDNA was cloned. Expression of hRCE1 was detected in all tissues examined. Both yeast and human RCE1 proteins were produced in Sf9 insect cells by infection with a recombinant baculovirus; membrane preparations derived from the infected Sf9 cells exhibited a high level of prenyl protease activity. Recombinant hRCE1 so produced recognized both farnesylated and geranylgeranylated proteins as substrates, including farnesyl-Ki-Ras, farnesyl-N-Ras, farnesyl-Ha-Ras, and the farnesylated heterotrimeric G protein Ggamma1 subunit, as well as geranylgeranyl-Ki-Ras and geranylgeranyl-Rap1b. The protease activity of hRCE1 activity was specific for prenylated proteins, because unprenylated peptides did not compete for enzyme activity. hRCE1 activity was also exquisitely sensitive to a prenyl peptide analogue that had been previously described as a potent inhibitor of the prenyl protease activity in mammalian tissues. These data indicate that both the yeast and the human RCE1 gene products are bona fide prenyl protein proteases and suggest that they play a major role in the processing of CAAX-type prenylated proteins.     

A novel GTP-binding protein hGBP3 interacts with NIK/HGK

A novel human guanylate-binding protein (GBP) hGBP3 was identified and characterized. Similar as the two human guanylate-binding proteins hGBP1 and hGBP2, hGBP3 has the first two motifs of the three classical guanylate-binding motifs, GXXXXGKS (T) and DXXG, but lacks the N (T) KXD motif. Escherichia coli-expressed hGBP3 protein specifically binds to guanosine triphosphate (GTP). Using a yeast two-hybrid system, it was revealed that the N-terminal region of hGBP3 binds to the C-terminal regulatory domain of NIK/HGK, a member of the group I GCK (germinal center kinase) family. This interaction was confirmed by in vitro glutathione-S-transferase (GST) pull-down and co-immunoprecipitation assays.     

Identification of a novel human Rho protein with unusual properties: GTPase deficiency and in vivo farnesylation.

We have identified a human Rho protein, RhoE, which has unusual structural and biochemical properties that suggest a novel mechanism of regulation. Within a region that is highly conserved among small GTPases, RhoE contains amino acid differences specifically at three positions that confer oncogenicity to Ras (12, 59, and 61). As predicted by these substitutions, which impair GTP hydrolysis in Ras, RhoE binds GTP but lacks intrinsic GTPase activity and is resistant to Rho-specific GTPase-activating proteins. Replacing all three positions in RhoE with conventional amino acids completely restores GTPase activity. In vivo, RhoE is found exclusively in the GTP-bound form, suggesting that unlike previously characterized small GTPases, RhoE may be normally maintained in an activated state. Thus, amino acid changes in Ras that are selected during tumorigenesis have evolved naturally in this Rho protein and have similar consequences for catalytic function. All previously described Rho family proteins are modified by geranylgeranylation, a lipid attachment required for proper membrane localization. In contrast, the carboxy-terminal sequence of RhoE predicts that, like Ras proteins, RhoE is normally farnesylated. Indeed, we have found that RhoE in farnesylated in vivo and that this modification is required for association with the plasma membrane and with an unidentified cellular structure that may play a role in adhesion. Thus, two unusual structural features of this novel Rho protein suggest a striking evolutionary divergence from the Rho family of GTPases.     

Nucleotide dependent cysteine reactivity of hGBP1 uncovers a domain movement during GTP hydrolysis

As a member of the dynamin superfamily human guanylate-binding protein 1 (hGBP1) binds and hydrolyses GTP thereby undergoing structural changes which lead to self-assembly of the protein. Here, we employ the reactivity of hGBP1 with a cysteine reactive compound in order to monitor structural changes imposed by GTP binding and hydrolysis. Positions of cysteine residues buried between the C-terminal domain of hGBP1 and the rest of the protein are identified which report a large change of accessibility by the compound after addition of GTP. Our results indicate that nucleotide hydrolysis induces a domain movement in hGBP1, which we suggest enables further assembly of the protein.     

Farnesylation of Ras is important for the interaction with phosphoinositide 3-kinase gamma.

The correct functioning of Ras proteins requires post-translational modification of the GTP hydrolases (GTPases). These modifications provide hydrophobic moieties that lead to the attachment of Ras to the inner side of the plasma membrane. In this study we investigated the role of Ras processing in the interaction with various putative Ras-effector proteins. We describe a specific, GTP-independent interaction between post-translationally modified Ha- and Ki-Ras4B and the G-protein responsive phosphoinositide 3-kinase p110gamma. Our data demonstrate that post-translational processing increases markedly the binding of Ras to p110gamma in vitro and in Sf9 cells, whereas the interaction with p110alpha is unaffected under the same conditions. Using in vitro farnesylated Ras, we show that farnesylation of Ras is sufficient to produce this effect. The complex of p110gamma and farnesylated RasGTP exhibits a reduced dissociation rate leading to the efficient shielding of the GTPase from GTPase activating protein (GAP) action. Moreover, Ras processing affects the dissociation rate of the RasGTP complex with the Ras binding domain (RBD) of Raf-1, indicating that processing induces alterations in the conformation of RasGTP. The results suggest a direct interaction between a moiety present only on fully processed or farnesylated Ras and the putative target protein p110gamma.     

Mechanism of GTPase-Activity-Induced Self-Assembly of Human Guanylate Binding Protein 1

Human guanylate binding protein 1 (hGBP1) belongs to the dynamin superfamily of large GTPases (LGs). In the course of GTP hydrolysis, the protein undergoes structural changes leading to self-assembly of the protein, which is a characteristic property of all family members. For self-assembly, the protein employs two distinct interaction sites, one of which is located within the LG domain of the protein located at the N-terminus, and the second is located in the C-terminal α-helical domain. Here, we identify intramolecular contacts between the LG domain and the helical part of hGBP1, which relay nucleotide-dependent structural changes from the N-terminus to the C-terminus and thereby mediate tetramer formation of the protein through a second contact site at the C-terminus. Furthermore, we demonstrate the impact of this intramolecular communication on the enzymatic activity of hGBP1 and on its cellular localization.     

Sequence dependence of protein isoprenylation

Several proteins have been shown to be post-translationally modified on a specific C-terminal cysteine residue by either of two isoprenoid biosynthetic pathway metabolites, farnesyl diphosphate or geranylgeranyl diphosphate. Three enzymes responsible for protein isoprenylation were resolved chromatographically from the cytosolic fraction of bovine brain: a farnesyl-protein transferase (FTase), which modified the cell-transforming Ras protein, and two geranyl-geranyl-protein transferases, one (GGTase-I) which modified a chimeric Ras having the C-terminal amino acid sequence of the gamma-6 subunit of heterotrimeric GTP-binding proteins, and the other (GGTase-II) which modified the Saccharomyces cerevisiae secretory GTPase protein YPT1. In a S. cerevisiae strain lacking FTase activity (ram1), both GGTases were detected at wild-type levels. In a ram2 S. cerevisiae strain devoid of FTase activity, GGTase-I activity was reduced by 67%, suggesting that GGTase-I and FTase activities derive from different enzymes but may share a common genetic feature. For the FTase and the GGTase-I activities, the C-terminal amino acid sequence of the protein substrate, the CAAX box, appeared to contain all the critical determinants for interaction with the transferase. In fact, tetrapeptides with amino acid sequences identical to the C-terminal sequences of the protein substrates for FTase or GGTase-I competed for protein isoprenylation by acting as alternative substrates. Changes in the CAAX amino acid sequence of protein substrates markedly altered their ability to serve as substrates for both FTase and GGTase-I. In addition, it appeared that FTase and GGTase-I had complementary affinities for CAAX protein substrates; that is, CAAX proteins that were good substrates for FTase were, in general, poor substrates for GGTase-I, and vice versa. In particular, a leucine residue at the C terminus influenced whether a CAAX protein was either farnesylated or geranylgeranylated preferentially. The YPT1 C terminus peptide, TGGGCC, did not compete or serve as a substrate for GGTase-II, indicating that the interaction between GGTase-II and YPT1 appeared to depend on more than the 6 C-terminal residues of the protein substrate sequence. These results identify three different isoprenyl-protein transferases that are each selective for their isoprenoid and protein substrates.     

Covalent protein modification with ISG15 via a conserved cysteine in the hinge region

The ubiquitin-like protein ISG15 (interferon-stimulated gene of 15 kDa) is strongly induced by type I interferons and displays antiviral activity. As other ubiquitin-like proteins (Ubls), ISG15 is post-translationally conjugated to substrate proteins by an isopeptide bond between the C-terminal glycine of ISG15 and the side chains of lysine residues in the substrates (ISGylation). ISG15 consists of two ubiquitin-like domains that are separated by a hinge region. In many orthologs, this region contains a single highly reactive cysteine residue. Several hundred potential substrates for ISGylation have been identified but only a few of them have been rigorously verified. In order to investigate the modification of several ISG15 substrates, we have purified ISG15 conjugates from cell extracts by metal-chelate affinity purification and immunoprecipitations. We found that the levels of proteins modified by human ISG15 can be decreased by the addition of reducing agents. With the help of thiol blocking reagents, a mutational analysis and miRNA mediated knock-down of ISG15 expression, we revealed that this modification occurs in living cells via a disulphide bridge between the substrates and Cys78 in the hinge region of ISG15. While the ISG15 activating enzyme UBE1L is conjugated by ISG15 in the classical way, we show that the ubiquitin conjugating enzyme Ubc13 can either be classically conjugated by ISG15 or can form a disulphide bridge with ISG15 at the active site cysteine 87. The latter modification would interfere with its function as ubiquitin conjugating enzyme. However, we found no evidence for an ISG15 modification of the dynamin-like GTPases MxA and hGBP1. These findings indicate that the analysis of potential substrates for ISG15 conjugation must be performed with great care to distinguish between the two types of modification since many assays such as immunoprecipitation or metal-chelate affinity purification are performed with little or no reducing agent present.     

Photoreceptor cGMP phosphodiesterase delta subunit (PDEdelta) functions as a prenyl-binding protein

Bovine PDEdelta was originally copurified with rod cGMP phosphodiesterase (PDE) and shown to interact with prenylated, carboxymethylated C-terminal Cys residues. Other studies showed that PDEdelta can interact with several small GTPases including Rab13, Ras, Rap, and Rho6, all of which are prenylated, as well as the N-terminal portion of retinitis pigmentosa GTPase regulator and Arl2/Arl3, which are not prenylated. We show by immunocytochemistry with a PDEdelta-specific antibody that PDEdelta is present in rods and cones. We find by yeast two-hybrid screening with a PDEdelta bait that it can interact with farnesylated rhodopsin kinase (GRK1) and that prenylation is essential for this interaction. In vitro binding assays indicate that both recombinant farnesylated GRK1 and geranylgeranylated GRK7 co-precipitate with a glutathione S-transferase-PDEdelta fusion protein. Using fluorescence resonance energy transfer techniques exploiting the intrinsic tryptophan fluorescence of PDEdelta and dansylated prenyl cysteines as fluorescent ligands, we show that PDEdelta specifically binds geranylgeranyl and farnesyl moieties with a Kd of 19.06 and 0.70 microm, respectively. Our experiments establish that PDEdelta functions as a prenyl-binding protein interacting with multiple prenylated proteins.     

R-loop-dependent hypernegative supercoiling in Escherichia coli topA mutants preferentially occurs at low temperatures and correlates with growth inhibition

hGBP1 is a GTPase with antiviral activity encoded by an interferon- activated human gene. Specific binding of hGBP1 to guanine nucleotides has been established although only two classical GTP-binding motifs were found in its primary sequence. The unique position of hGBP1 amongst known GTPases is further demonstrated by the hydrolysis of GTP to GDP and GMP. Although subsequent cleavage of orthophosphates rather than pyrophosphate was demonstrated, GDP coming from bulk solution cannot serve as a substrate. The relation of guanine nucleotide binding and hydrolysis to the antiviral function of hGBP1 is unknown. Here we show similar binding affinities for all three guanine nucleotides and the ability of both products, GDP and GMP, to compete with GTP binding. Fluorimetry and isothermal titration calorimetry were applied to prove that only one nucleotide binding site is present in hGBP1. Furthermore, we identified the third canonical GTP-binding motif and verified its role in nucleotide recognition by mutational analysis. The high guanine nucleotide dissociation rates measured by stopped-flow kinetics are responsible for the weak affinities to hGBP1 when compared to other GTPases like Ras or Galpha. By means of fluorescence and NMR spectroscopy it is demonstrated that aluminium fluoride forms a complex with hGBP1 only in the GDP state, presumably mimicking the transition state of GTP hydrolysis. Tentatively, the involvement of a GAP domain in hGBP1 in GTP hydrolysis is suggested. These results will serve as a basis for the determination of the differential biological functions of the three nucleotide states and for the elucidation of the unique mechanism of nucleotide hydrolysis catalysed by hGBP1.     

Role of arginine kinase in Paramecium tetraurelia (Ciliophora,Peniculida): Subcellular localization of AK3 and phosphoarginine shuttle system in cilia

The ciliate Paramecium tetraurelia has four arginine kinase genes (AK1, AK2, AK3, and AK4). Of these genes, only AK3 has a signal sequence for farnesylation, a post-translational modification that enables anchoring of the modified enzyme to the ciliary membrane. To confirm this modification, AK3 was synthesized using a cell-free protein synthesis system and the peptide masses were analyzed using peptide mass fingerprinting (PMF). The PMF analysis indicated that the C-terminal peptide of AK3 is farnesylated. Thus, AK3 can be farnesylated under physiologically appropriate conditions. To determine the subcellular localization of P. tetraurelia AK3, Western blot analysis was performed using an AK3 polyclonal antibody for the proteins extracted from intact cells and ciliary fractions. When extraction was performed using Triton X-100, AK3 was detected the ciliary fraction. This result suggested that the ciliary fraction contains AK3. In addition, we investigated the role of P. tetraurelia AKs in ciliary movement using the feeding RNA interference method. The swimming velocity of AK1- and AK3-silenced cells was significantly reduced to half the value of that control cells. In summary, P. tetraurelia AK3 is likely to be located in the ciliary membrane and influences swimming velocity, presumably through the phosphoarginine shuttle system present in cilia.     

Farnesylation of the SNARE protein Ykt6 increases its stability and helical folding

The evolutionarily conserved soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins are involved in the fusion of vesicles with their target membranes. While most SNAREs are permanently anchored to membranes by their transmembrane domains, the vesicle-associated SNARE Ykt6 has been found both in soluble and in membrane-bound pools. The R-SNARE Ykt6 is thought to mediate interactions between various Q-SNAREs by a reversible membrane-targeting cycle. Membrane attachment of Ykt6 is achieved by its C-terminal prenylation and palmitoylation motif succeeding the SNARE motif. In this study, we have analyzed full-length farnesylated Ykt6 from yeast and humans by biochemical and structural means. In vitro farnesylation of the C-terminal CAAX box of recombinant full-length Ykt6 resulted in stabilization of the native protein and a more compactly folded structure, as shown by size exclusion chromatography and limited proteolysis. Circular dichroism spectroscopy indicated a specific increase in the helical content of the farnesylated Ykt6 compared to the nonlipidated form or the single-longin domain, which correlated with a marked increase in stability as observed by heat denaturation experiments. Although highly soluble, farnesylated Ykt6 is capable of lipid membrane binding independent of the membrane charge, as shown by surface plasmon resonance. The crystal structure of the N-terminal longin domain of yeast Ykt6 (1-140) was determined at 2.5 Å resolution. As similarly found in a previous NMR structure, the Ykt6 longin domain contains a hydrophobic patch at its surface that may accommodate the lipid moiety. In the crystal structure, this hydrophobic surface is buried in a crystallographic homomeric dimer interface. Together, these observations support a previously suggested closed conformation of cytosolic Ykt6, where the C-terminal farnesyl moiety folds onto a hydrophobic groove in the N-terminal longin domain.     

Rbg1–Tma46 dimer structure reveals new functional domains and their role in polysome recruitment

Developmentally Regulated GTP-binding (DRG) proteins are highly conserved GTPases that associate with DRG Family Regulatory Proteins (DFRP). The resulting complexes have recently been shown to participate in eukaryotic translation. The structure of the Rbg1 GTPase, a yeast DRG protein, in complex with the C-terminal region of its DFRP partner, Tma46, was solved by X-ray diffraction. These data reveal that DRG proteins are multimodular factors with three additional domains, helix–turn–helix (HTH), S5D2L and TGS, packing against the GTPase platform. Surprisingly, the S5D2L domain is inserted in the middle of the GTPase sequence. In contrast, the region of Tma46 interacting with Rbg1 adopts an extended conformation typical of intrinsically unstructured proteins and contacts the GTPase and TGS domains. Functional analyses demonstrate that the various domains of Rbg1, as well as Tma46, modulate the GTPase activity of Rbg1 and contribute to the function of these proteins in vivo. Dissecting the role of the different domains revealed that the Rbg1 TGS domain is essential for the recruitment of this factor in polysomes, supporting further the implication of these conserved factors in translation.