Structure of the conserved GTPase domain of the signal recognition particle

Expression, purification, and crystallography of the conserved methionine-rich domain of human signal recognition particle 54 kDa protein

Protein SRP54 is an essential component of eukaryotic signal recognition particle (SRP). The methionine-rich M-domain (SRP54M or 54M) interacts with the SRP RNA and is also involved in the binding to signal peptides of secretory proteins during their targeting to cellular membranes. To gain insight into the molecular details of SRP-mediated protein targeting, we studied the human 54M polypeptide. The recombinant human protein was expressed successfully in Escherichia coli and was purified to homogeneity. Our studies determined the sites that were susceptible to limited proteolysis, with the goal to design smaller functional mutant derivatives that lacked nonessential amino acid residues from both termini. Of the four polypeptides produced by V8 protease or chymotrypsin, 54MM-2 was the shortest (120 residues; Mr = 13,584.8), but still contained the conserved amino acids suggested to associate with the signal peptide or the SRP RNA. 54MM-2 was cloned, expressed, purified to homogeneity, and was shown to bind human SRP RNA in the presence of protein SRP19, indicating that it was functional. Highly reproducible conditions for the crystallization of 54MM-2 were established. Examination of the crystals by X-ray diffraction showed an orthorhombic unit cell of dimensions a = 29.127 A, b = 63.693 A, and c = 129.601 A, in space group P2(1)2(1)2(1), with reflections extending to at least 2.0 A.

Protein targeting to the bacterial cytoplasmic membrane

Proteins that perform their activity within the cytoplasmic membrane or outside this cell boundary must be targeted to the translocation site prior to their insertion and/or translocation. In bacteria, several targeting routes are known; the SecB- and the signal recognition particle-dependent pathways are the best characterized. Recently, evidence for the existence of a third major route, the twin-Arg pathway, was gathered. Proteins that use either one of these three different pathways possess special features that enable their specific interaction with the components of the targeting routes. Such targeting information is often contained in an N-terminal extension, the signal sequence, but can also be found within the mature domain of the targeted protein. Once the nascent chain starts to emerge from the ribosome, competition for the protein between different targeting factors begins. After recognition and binding, the targeting factor delivers the protein to the translocation sites at the cytoplasmic membrane. Only by means of a specific interaction between the targeting component and its receptor is the cargo released for further processing and translocation. This mechanism ensures the high-fidelity targeting of premembrane and membrane proteins to the translocation site.

A signal recognition particle receptor gene from the early-diverging eukaryote, Giardia lamblia

The molecular mechanisms for targeting and translocation of secreted proteins are highly conserved from bacteria to mammalian cells, although the machinery is more complex in higher eukaryotes. To investigate protein transport in the early-diverging eukaryote, Giardia lamblia, we cloned the gene encoding the alpha subunit (SRalpha) of the signal recognition particle (SRP) receptor. SRalpha is a small GTPase that functions in SRP-ribosome targeting to the ER. Sequence and phylogenetic analyses showed that SRalpha from G. lamblia is most homologous to SRalpha proteins from higher eukaryotes, although it lacks some conserved motifs. Specifically, giardial SRalpha has an N-terminal extension that enables SRalpha of higher eukaryotes to interact with a beta subunit that anchors it in the ER membrane. While the C-terminal regions are similar, giardial SRalpha lacks a prominent 13 amino acid regulatory loop that is characteristic of higher eukaryotic versions. Thus, giardial SRalpha resembles that of higher eukaryotes, but likely diverged before the advent of the regulatory loop. The 1.8 kb SRalpha transcript has extremely short untranslated regions (UTRs): a 1-2 nt 5'- and a 9 nt 3' UTR with the polyadenylation signal overlapping with the stop codon. RT-PCR, Northern and Western analyses showed that SRalpha is present at relatively constant levels during vegetative growth and encystation, even though there are extensive changes in endomembrane structures and secretory activity during encystation. Imnuno-EM showed that SRalpha localizes to ER-like structures, strengthening the observation of a typical ER in G. lamlia. Unexpectedly, SRalpha was also found in the lysosome-like peripheral vacuoles, suggesting unusual protein traffic in this early eukaryote. Our results indicate that the eukaryotic type of cotranslational transport appeared early in the evolution of the eukaryotic cell.

Domain structure, GTP-hydrolyzing activity and 7S RNA binding of Acidianus ambivalens ffh-homologous protein suggest an SRP-like complex in archaea

In this study we provide, for the first time, experimental evidence that a protein homologous to bacterial Ffh is part of an SRP-like ribonucleoprotein complex in hyperthermophilic archaea. The gene encoding the Ffh homologue in the hyperthermophilic archaeote Acidianus ambivalens has been cloned and sequenced. Recombinant Ffh protein was expressed in E. coli and subjected to biochemical and functional studies. A. ambivalens Ffh encodes a 50.4-kDa protein that is structured by three distinct regions: the N-terminal hydrophilic N-region (N), the GTP/GDP-binding domain (G) and a C-terminal located C-domain (C). The A. ambivalens Ffh sequence shares 44-46% sequence similarity with Ffh of methanogenic archaea, 34-36% similarity with eukaryal SRP54 and 30-34% similarity with bacterial Ffh. A polyclonal antiserum raised against the first two domains of A. ambivalens Ffh reacts specifically with a single protein (apparent molecular mass: 46 kDa, termed p46) present in cytosolic and in plasmamembrane cell fractions of A. ambivalens. Recombinant Ffh has a melting point of tm = 89 degreesC. Its intrinsic GTPase activity obviously depends on neutral pH and low ionic strength with a preference for chloride and acetate salts. Highest rates of GTP hydrolysis have been achieved at 81 degreesC in presence of 0.1-1 mm Mg2+. GTP hydrolysis is significantly inhibited by high glycerol concentrations, and the GTP hydrolysis rate also markedly decreases by addition of detergents. The Km for GTP is 13.7 microm at 70 degreesC and GTP hydrolysis is strongly inhibited by GDP (Ki = 8 microm). A. ambivalens Ffh, which includes an RNA-binding motif in the C-terminal domain, is shown to bind specifically to 7S RNA of the related crenarchaeote Sulfolobus solfataricus. Comparative sequence analysis reveals the presence of typical signal sequences in plasma membrane as well as extracellular proteins of hyperthermophilic crenarchaea which strongly supposes recognition events by an Ffh containing SRP-like particle in these organisms.

Protein targeting: getting into the groove

The 54 kDa subunit of the signal recognition particle has to identify a diverse family of substrates and deliver them in a controlled manner to the translocation machinery of the endoplasmic reticulum. Important new insights into the function of this sorting protein have emerged from recent biochemical and structural studies.

A functional GTPase domain, but not its transmembrane domain, is required for function of the SRP receptor beta-subunit

The signal recognition particle and its receptor (SR) target nascent secretory proteins to the ER. SR is a heterodimeric ER membrane protein whose subunits, SRalpha and SRbeta, are both members of the GTPase superfamily. Here we characterize a 27-kD protein in Saccharomyces cerevisiae (encoded by SRP102) as a homologue of mammalian SRbeta. This notion is supported (a) by Srp102p's sequence similarity to SRbeta; (b) by its disposition as an ER membrane protein; (c) by its interaction with Srp101p, the yeast SRalpha homologue; and (d) by its role in SRP-dependent protein targeting in vivo. The GTP-binding site in Srp102p is surprisingly insensitive to single amino acid substitutions that inactivate other GTPases. Multiple mutations in the GTP-binding site, however, inactivate Srp102p. Loss of activity parallels a loss of affinity between Srp102p and Srp101p, indicating that the interaction between SR subunits is important for function. Deleting the transmembrane domain of Srp102p, the only known membrane anchor in SR, renders SR soluble in the cytosol, which unexpectedly does not significantly impair SR function. This result suggests that SR functions as a regulatory switch that needs to associate with the ER membrane only transiently through interactions with other components.

Conformational variability in structures of the nitrogenase iron proteins from Azotobacter vinelandii and Clostridium pasteurianum

The nitrogenase iron (Fe) protein performs multiple functions during biological nitrogen fixation, including mediating the mechanistically essential coupling between ATP hydrolysis and electron transfer to the nitrogenase molybdenum iron (MoFe) protein during substrate reduction, and participating in the biosynthesis and insertion of the FeMo-cofactor into the MoFe-protein. To establish a structural framework for addressing the diverse functions of Fe-protein, crystal structures of the Fe-proteins from Azotobacter vinelandii and Clostridium pasteurianum have been determined at resolutions of 2.2 A and 1.93 A, respectively. These two Fe-proteins are among the more diverse in terms of amino acid sequence and biochemical properties. As described initially for the A. vinelandii Fe-protein in a different crystal form at 2.9 A resolution, each subunit of the dimeric Fe-protein adopts a polypeptide fold related to other mononucleotide-binding proteins such as G-proteins, with the two subunits bridged by a 4Fe:4S cluster. The overall similarities in the subunit fold and dimer arrangement observed in the structures of the A. vinelandii and C. pasteurianum Fe-proteins indicate that they are representative of the conformation of free Fe-protein that is not in complex with nucleotide or the MoFe-protein. Residues in the cluster and nucleotide-binding sites are linked by a network of conserved hydrogen bonds, salt-bridges and water molecules that may conformationally couple these regions. Significant variability is observed in localized regions, especially near the 4Fe:4S cluster and the MoFe-protein binding surface, that change conformation upon formation of the ADP.AlF4- stabilized complex with the MoFe-protein. A core of 140 conserved residues is identified in an alignment of 59 Fe-protein sequences that may be useful for the identification of homologous proteins with functions comparable to that of Fe-protein in non-nitrogen fixing systems.

Crystal structure of the signal sequence binding subunit of the signal recognition particle

The crystal structure of the signal sequence binding subunit of the signal recognition particle (SRP) from Thermus aquaticus reveals a deep groove bounded by a flexible loop and lined with side chains of conserved hydrophobic residues. The groove defines a flexible, hydrophobic environment that is likely to contribute to the structural plasticity necessary for SRP to bind signal sequences of different lengths and amino acid sequence. The structure also reveals a helix-turn-helix motif containing an arginine-rich alpha helix that is required for binding to SRP RNA and is implicated in forming the core of an extended RNA binding surface.

The X-ray structure of a cobalamin biosynthetic enzyme, cobalt-precorrin-4 methyltransferase

Biosynthesis of the corrin ring of vitamin B12 requires the action of six S-adenosyl-L-methionine (AdoMet) dependent transmethylases, closely related in sequence. The first X-ray structure of one of these, cobalt-precorrin-4 transmethylase, CbiF, from Bacillus megaterium has been determined to a resolution of 2.4 A. CbiF contains two alphabeta domains forming a trough in which S-adenosyl-L-homocysteine (AdoHcy) binds. The location of AdoHcy and a number of conserved residues, helps define the precorrin binding site. A second crystal form determined at 3.1 A resolution highlights the flexibility of two loops around this site. CbiF employs a unique mode of AdoHcy binding and represents a new class of transmethylase.

Binding of GTP and GDP induces a significant conformational change in the GTPase domain of Ffh, a bacterial homologue of the SRP 54 kDa subunit

The bacterial Ffh protein is homologous to the SRP54 subunit of the signal recognition particle. Ffh plays a key role in the targeting of proteins to the membrane and it is composed of a N-terminal domain (N), a middle GTPase (G) domain and a C-terminal M domain which has binding sites for SRP RNA and signal peptide. The GTP binding and hydrolysis of Ffh is critical to its function. We have used protease digestion to probe the conformation of the Mycoplasma mycoides Ffh N+G domain. In the absence of nucleotide the protein was comparatively sensitive to protease cleavage and we identified sites particularly prone to cleavage in a region near the C-terminus of the GTPase domain. However, in the presence of GTPgammaS or GDP this region is stabilized and the protein adopts a more ordered structure. The pattern of cleavage with GTPgammaS was indistinguishable from that when GDP was bound, indicating that the conformation of the nucleotide-free form is distinct from that when either GTPgammaS or GDP is bound to the protein. The possible functional role of this significant conformational change is discussed.

Protein SRP54 of human signal recognition particle: cloning, expression, and comparative analysis of functional sites

Signal recognition particle (SRP) plays a critical role in the targeting of secretory proteins to cellular membranes. An essential component of SRP is the protein SRP54, which interacts not only with the nascent signal peptide, but also with the SRP RNA. To understand better how protein targeting occurs in the human system, the human SRP54 gene was cloned, sequenced, and the protein was expressed in bacteria and insect cells. Recombinant SRP54 was purified from both sources. The protein bound to SRP RNA in the presence of protein SRP19, and associated with the signal peptide of in vitro translated pre-prolactin. Comparative sequence analysis of human SRP54 with homologs from all three phylogenetic domains was combined with high-stringency protein secondary structure prediction. A conserved RNA-binding loop was predicted in the largely helical M-domain of SRP54. Contrary to general belief, the unusually high number of methionine residues clustered outside the predicted helices, thus indicating a mechanism of signal peptide recognition that may involve methionine-rich loops.

G proteins, effectors and GAPs: structure and mechanism

G proteins from a diverse family of regulatory GTPases which, in the GTP-bound state, bind to and activate downstream effectors. Structures of Ras homologs bound to effector domains have revealed mechanisms by which G proteins couple GTP binding to effector activation and achieve specificity. Complexes between structurally unrelated GTPase-activating proteins with complementary G proteins suggest common mechanisms by which GTP hydrolysis is stimulated via direct interactions with conformationally labile switch regions of the G protein.

Domain interactions in E. coli SRP: stabilization of M domain by RNA is required for effective signal sequence modulation of NG domain

The E. coli protein, Fth, binds to 4.5S RNA through its M domain to form the signal recognition particle (SRP). The other domain of Fth (NG) is a GTPase, which binds and is coordinately regulated by its receptor, FtsY. We find that the helical M domain is inherently flexible. Binding of 4.5S RNA to Fth stabilizes the M domain yet has little apparent effect on the binding of signal peptides. However, in the absence of the RNA, signal peptide binding results in a global destabilization of Fth, which is prevented by binding of 4.5S RNA. Signal peptide binding to isolated NG domain also causes a pronounced destabilization, implicating the NG domain in direct recognition of signal peptide.

The signal recognition particle receptor of Escherichia coli (FtsY) has a nucleotide exchange factor built into the GTPase domain

Targeting of many secretory and membrane proteins to the inner membrane in Escherichia coli is achieved by the signal recognition particle (SRP) and its receptor (FtsY). In E. coli SRP consists of only one polypeptide (Ffh), and a 4.5S RNA. Ffh and FtsY each contain a conserved GTPase domain (G domain) with an alpha-helical domain on its N terminus (N domain). The nucleotide binding kinetics of the NG domain of the SRP receptor FtsY have been investigated, using different fluorescence techniques. Methods to describe the reaction kinetically are presented. The kinetics of interaction of FtsY with guanine nucleotides are quantitatively different from those of other GTPases. The intrinsic guanine nucleotide dissociation rates of FtsY are about 10(5) times higher than in Ras, but similar to those seen in GTPases in the presence of an exchange factor. Therefore, the data presented here show that the NG domain of FtsY resembles a GTPase-nucleotide exchange factor complex not only in its structure but also kinetically. The I-box, an insertion present in all SRP-type GTPases, is likely to act as an intrinsic exchange factor. From this we conclude that the details of the GTPase cycle of FtsY and presumably other SRP-type GTPases are fundamentally different from those of other GTPases.

Eukaryotic protein secretion

The components responsible for protein translocation across the endoplasmic reticulum membrane have been identified and their functions have been clarified in vitro. The structural features of the signal peptide specify the factors and pathways of membrane translocation. Various chaperones and folding enzymes are involved in the folding and quality control of secretory proteins in the lumen.

Co-translational protein targeting catalyzed by the Escherichia coli signal recognition particle and its receptor

The Ffh-4.5S ribonucleoprotein particle (RNP) and FtsY from Escherichia coli are homologous to essential components of the mammalian signal recognition particle (SRP) and SRP receptor, respectively. The ability of these E. coli components to function in a bona fide co-translational targeting pathway remains unclear. Here we demonstrate that the Ffh-4.5S RNP and FtsY can efficiently replace their mammalian counterparts in targeting nascent secretory proteins to microsomal membranes in vitro. Targeting in the heterologous system requires a hydrophobic signal sequence, utilizes GTP and, moreover, occurs co-translationally. Unlike mammalian SRP, however, the Ffh-4.5S RNP is unable to arrest translational elongation, which results in a narrow time window for the ribosome nascent chain to interact productively with the membrane-bound translocation machinery. The highly negatively charged N-terminal domain of FtsY, which is a conserved feature among prokaryotic SRP receptor homologs, is important for translocation and acts to localize the protein to the membrane. Our data illustrate the extreme functional conservation between prokaryotic and eukaryotic SRP and SRP receptors and suggest that the basic mechanism of co-translational protein targeting is conserved between bacteria and mammals.

Empty site forms of the SRP54 and SR alpha GTPases mediate targeting of ribosome-nascent chain complexes to the endoplasmic reticulum

The SRP54 and SR alpha subunits of the signal recognition particle (SRP) and the SRP receptor (SR) undergo a tightly coupled GTPase cycle that mediates the signal sequence-dependent attachment of ribosomes to the Sec61 complex. Here, we show that SRP54 and SR alpha are in the empty site conformation prior to contact between the SRP-ribosome complex and the membrane-bound SR. Cooperative binding of GTP to SRP54 and SR alpha stabilizes the SRP-SR complex and initiates signal sequence transfer from SRP54 to Sec61 alpha. The GTP-bound conformations of SR alpha and SRP54 perform distinct roles, with SR alpha performing a predominant role in complex stabilization. Hydrolysis by both SRP54 and SR alpha is a prerequisite for dissociation of the SRP-SR complex.

The N-domain of the signal recognition particle 54-kDa subunit promotes efficient signal sequence binding

The signal recognition particle 54-kDa subunit (SRP54) binds to the signal sequences of nascent presecretory and transmembrane proteins. Previous studies have shown that signal sequences bind to the C-terminal methionine-rich domain of the protein (M-domain), but have raised the possibility that either the N-terminal domain (N-domain) or the central guanosine triphosphatase module (GTPase-domain) also contribute to signal-sequence-binding activity. We have generated a series of N-domain and GTPase-domain mutants to investigate this issue further. Mutations in a conserved N-domain motif (ALLEADV) produced significant defects in signal sequence binding that correlate with the severity of the mutation. The magnitude of the defect was independent of the preprotein substrate, which suggested that the mutations do not alter the specificity of signal sequence recognition. The N-domain mutants also showed defects in promoting the translocation of presecretory proteins across the membrane of microsomal vesicles, but these defects appeared to be a direct consequence of the reduction in signal-sequence-binding activity and not separate effects of the mutations. By contrast, mutations in the guanosine triphosphatase consensus sequence had no effect on signal sequence binding, but instead severely impaired protein translocation activity. These results indicate that a principal function of the SRP54 N-domain is to promote efficient signal sequence binding. These data also suggest that the SRP54 GTPase regulates the cycle of signal sequence binding and release, perhaps by modulating the relative orientation of the N- and M-domains.