Structures of SRP54 and SRP19, the two proteins that organize the ribonucleic core of the signal recognition particle from Pyrococcus furiosus

In all organisms the Signal Recognition Particle (SRP), binds to signal sequences of proteins destined for secretion or membrane insertion as they emerge from translating ribosomes. In Archaea and Eucarya, the conserved ribonucleoproteic core is composed of two proteins, the accessory protein SRP19, the essential GTPase SRP54, and an evolutionarily conserved and essential SRP RNA. Through the GTP-dependent interaction between the SRP and its cognate receptor SR, ribosomes harboring nascent polypeptidic chains destined for secretion are dynamically transferred to the protein translocation apparatus at the membrane. We present here high-resolution X-ray structures of SRP54 and SRP19, the two RNA binding components forming the core of the signal recognition particle from the hyper-thermophilic archaeon Pyrococcus furiosus (Pfu). The 2.5 A resolution structure of free Pfu-SRP54 is the first showing the complete domain organization of a GDP bound full-length SRP54 subunit. In its ras-like GTPase domain, GDP is found tightly associated with the protein. The flexible linker that separates the GTPase core from the hydrophobic signal sequence binding M domain, adopts a purely alpha-helical structure and acts as an articulated arm allowing the M domain to explore multiple regions as it scans for signal peptides as they emerge from the ribosomal tunnel. This linker is structurally coupled to the GTPase catalytic site and likely to propagate conformational changes occurring in the M domain through the SRP RNA upon signal sequence binding. Two different 1.8 A resolution crystal structures of free Pfu-SRP19 reveal a compact, rigid and well-folded protein even in absence of its obligate SRP RNA partner. Comparison with other SRP19*SRP RNA structures suggests the rearrangement of a disordered loop upon binding with the RNA through a reciprocal induced-fit mechanism and supports the idea that SRP19 acts as a molecular scaffold and a chaperone, assisting the SRP RNA in adopting the conformation required for its optimal interaction with the essential subunit SRP54, and proper assembly of a functional SRP.     

Two strategically placed base pairs in helix 8 of mammalian signal recognition particle RNA are crucial for the SPR19-dependent binding of protein SRP54

Signal recognition particle (SRP) guides secretory proteins to biological membranes in all organisms. Assembly of the large domain of mammalian SRP requires binding of SRP19 prior to the binding of protein SRP54 to SRP RNA. The crystal structure of the ternary complex reveals the parallel arrangement of RNA helices 6 and 8, a bridging of the helices via a hydrogen bonded A149-A201 pair and protein SRP19, and two A minor motifs between the asymmetric loop of helix 8 (A213 and A214) and helix 6. We investigated which residues in helix 8 are responsible for the SRP19-dependent binding of SRP54 by taking advantage of the finding that binding of human SRP54 to Methanococcus jannaschii SRP RNA is independent of SRP19. Chimeric human/M. jannaschii SRP RNA molecules were synthesized containing predominantly human SRP RNA but possessing M. jannaschii SRP RNA-derived substitutions. Activities of the chimeric RNAs were measured with respect to protein SRP19 and the methionine-rich RNA-binding domain of protein SRP54 (SRP54M). Changing A213 and A214 to a uridine has no effect on the SRP19-dependent binding of SRP54M. Instead, the two base pairs C189-G210 and C190-G209, positioned between the conserved binding site of SRP54 and the asymmetric loop, are critical for conveying SRP19 dependency. Furthermore, the nucleotide composition of five base pairs surrounding the asymmetric loop affects binding of SRP54M significantly. These results demonstrate that subtle, and not easily perceived, structural differences are of crucial importance in the assembly of mammalian SRP.     

Binding site of the M-domain of human protein SRP54 determined by systematic site-directed mutagenesis of signal recognition particle RNA.

The interaction of protein SRP54M from the human signal recognition particle with SRP RNA was studied by systematic site-directed mutagenesis of the RNA molecule. Protein binding sites were identified by the analysis of mutations that removed individual SRP RNA helices or disrupted helical sections in the large SRP domain. The strongest effects on the binding activity of a purified polypeptide that corresponds to the methionine-rich domain of SRP54 (SRP54M) were caused by changes in helix 8 of the SRP RNA. Binding of protein SRP19 was diminished significantly by mutations in helix 6 and was stringently required for SRP54M to associate. Unexpectedly, mutant RNA molecules that resembled bacterial SRP RNAs were incapable of interaction with SRP54M, showing that protein SRP19 has an essential and direct role in the formation of the ternary complex with SRP54 and SRP RNA. Our findings provide an example for how, in eukaryotes, an RNA function has become protein dependent.     

Assembly of the human signal recognition particle (SRP): overlap of regions required for binding of protein SRP54 and assembly control.

Assembly of the human signal recognition particle (SRP) entails the incorporation of protein SRP54, mediated by a protein SRP1 9-induced conformational change in SRP RNA. To localize the region that controls this crucial step in the assembly of human SRP RNA, four chimeras, Ch-1 to Ch-4, composed of portions of human and Methanococcus jannashii SRP RNAs, were generated by PCR site-directed mutagenesis from a larger precursor. Protein-binding activities of the hybrid RNAs were determined using purified human SRP19 and a polypeptide (SRP54M) that corresponded to the methionine-rich domain of human SRP54. Mutant Ch-1 containing the large domain of M. jannashii SRP RNA, as well as mutant Ch-2 RNA in which helices 6 and 8 were replaced, bound SRP54M independently of SRP19. Mutant Ch-3 RNA, which contained M. jannashii helix 6, required SRP19 for binding of SRP54M, but mutant Ch-4 RNA, which possessed M. jannashii helix 8, bound SRP54M without SRP19. We concluded that the formation of a stable ternary complex did not rely on extensive conformational changes that might take place throughout the large domain of SRP, but was controlled by a smaller region encompassing certain RNA residues at positions 177 to 221. Five chimeric RNAs altered within helix 8 were used to investigate the potential role of a significant AA-to-U change and to determine the boundaries of the assembly control region. Reduced protein-binding activities of these chimeras demonstrated a considerable overlap of regions required for SRP54 binding and assembly control.     

Crystal structure of the conserved subdomain of human protein SRP54M at 2.1 A resolution: evidence for the mechanism of signal peptide binding.

Protein SRP54 is an integral part of the mammalian signal recognition particle (SRP), a cytosolic ribonucleoprotein complex which associates with ribosomes and serves to recognize, bind, and transport proteins destined for the membrane or secretion. The methionine-rich M-domain of protein SRP54 (SRP54M) binds the SRP RNA and the signal peptide as the nascent protein emerges from the ribosome. A focal point of this critical cellular function is the detailed understanding of how different hydrophobic signal peptides are recognized efficiently and transported specifically, despite considerable variation in sequence. We have solved the crystal structure of a conserved functional subdomain of the human SRP54 protein (hSRP54m) at 2.1 A resolution showing a predominantly alpha helical protein with a large fraction of the structure available for binding. RNA binding is predicted to occur in the vicinity of helices 4 to 6. The N-terminal helix extends significantly from the core of the structure into a large but constricted hydrophobic groove of an adjacent molecule, thus revealing molecular details of possible interactions between alpha helical signal peptides and human SRP54.     

Crystal structure of SRP19 in complex with the S domain of SRP RNA and its implication for the assembly of the signal recognition particle

The signal recognition particle (SRP) is a ribonucleoprotein particle involved in GTP-dependent translocation of secretory proteins across membranes. In Archaea and Eukarya, SRP19 binds to 7SL RNA and promotes the incorporation of SRP54, which contains the binding sites for GTP, the signal peptide, and the membrane-bound SRP receptor. We have determined the crystal structure of Methanococcus jannaschii SRP19 bound to the S domain of human 7SL RNA at 2.9 A resolution. SRP19 clamps the tetraloops of two branched helices (helices 6 and 8) and allows them to interact side by side. Helix 6 acts as a splint for helix 8 and partially preorganizes the binding site for SRP54 in helix 8, thereby facilitating the binding of SRP54 in assembly.     

Structure of the most conserved internal loop in SRP RNA.

The signal recognition particle (SRP) directs translating ribosomes to the protein translocation apparatus of endoplasmic reticulum (ER) membrane or the bacterial plasma membrane. The SRP is universally conserved, and in prokaryotes consists of two essential subunits, SRP RNA and SRP54, the latter of which binds to signal sequences on the nascent protein chains. Here we describe the solution NMR structure of a 28-mer RNA composing the most conserved part of SRP RNA to which SRP54 binds. Central to this function is a six-nucleotide internal loop that assumes a novel Mg2+-dependent structure with unusual cross-strand interactions; besides a cross-strand A/A stack, two guanines form hydrogen bonds with opposite-strand phosphates. The structure completely explains the phylogenetic conservation of the loop bases, underlining its importance for SRP54 binding and SRP function.     

Molecular evolution of SRP cycle components: functional implications.

Signal recognition particle (SRP) is a cytoplasmic ribonucleoprotein that targets a subset of nascent presecretory proteins to the endoplasmic reticulum membrane. We have considered the SRP cycle from the perspective of molecular evolution, using recently determined sequences of genes or cDNAs encoding homologs of SRP (7SL) RNA, the Srp54 protein (Srp54p), and the alpha subunit of the SRP receptor (SR alpha) from a broad spectrum of organisms, together with the remaining five polypeptides of mammalian SRP. Our analysis provides insight into the significance of structural variation in SRP RNA and identifies novel conserved motifs in protein components of this pathway. The lack of congruence between an established phylogenetic tree and size variation in 7SL homologs implies the occurrence of several independent events that eliminated more than half the sequence content of this RNA during bacterial evolution. The apparently non-essential structures are domain I, a tRNA-like element that is constant in archaea, varies in size among eucaryotes, and is generally missing in bacteria, and domain III, a tightly base-paired hairpin that is present in all eucaryotic and archeal SRP RNAs but is invariably absent in bacteria. Based on both structural and functional considerations, we propose that the conserved core of SRP consists minimally of the 54 kDa signal sequence-binding protein complexed with the loosely base-paired domain IV helix of SRP RNA, and is also likely to contain a homolog of the Srp68 protein. Comparative sequence analysis of the methionine-rich M domains from a diverse array of Srp54p homologs reveals an extended region of amino acid identity that resembles a recently identified RNA recognition motif. Multiple sequence alignment of the G domains of Srp54p and SR alpha homologs indicates that these two polypeptides exhibit significant similarity even outside the four GTPase consensus motifs, including a block of nine contiguous amino acids in a location analogous to the binding site of the guanine nucleotide dissociation stimulator (GDS) for E. coli EF-Tu. The conservation of this sequence, in combination with the results of earlier genetic and biochemical studies of the SRP cycle, leads us to hypothesize that a component of the Srp68/72p heterodimer serves as the GDS for both Srp54p and SR alpha. Using an iterative alignment procedure, we demonstrate similarity between Srp68p and sequence motifs conserved among GDS proteins for small Ras-related GTPases. The conservation of SRP cycle components in organisms from all three major branches of the phylogenetic tree suggests that this pathway for protein export is of ancient evolutionary origin.     

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.     

Systematic site-directed mutagenesis of human protein SRP54: interactions with signal recognition particle RNA and modes of signal peptide recognition

The amino acid residues of human protein SRP54 which are required for binding to SRP RNA were identified by generating 40 nonoverlapping tri-alanine alterations within its methionine-rich M-domain (SRP54M). The mutant polypeptides were expressed in Escherichia coli, and their ability to bind to human and Methanococcus jannaschii SRP RNA were determined in vitro. Residues at positions 379-387, 394-396, 400-405, and 409-411 of human SRP54 were within the predicted RNA binding site, and their alteration abolished the binding activities of the mutant polypeptides as expected. Changes at positions 418-423 had intermediate effects. Polypeptides containing mutations of 328-TLR-330 were inactive although these residues were far away from the presumed RNA binding site in the crystal structure of the free protein. Using the structures of the E. coli Ffh/4.5S core and of the human SRP54m dimer as templates, a molecular model of the complex between human SRP RNA helix 8 and a single SRP54M molecule was constructed in which Leucine 329 was positioned in closer proximity to the RNA binding domain. This representation was supported by studies of the SRP54m monomer/dimer ratio using gel filtration. The results were consistent with a change in the shape of the signal peptide binding groove upon binding of SRP54 to SRP RNA. We propose that the SRP RNA and a small region centered at a bulky nonpolar amino acid residue at position 329 of protein SRP54 play a critical role in the SRP-dependent binding and release of signal peptides.     

Saccharomyces SRP RNA secondary structures: a conserved S-domain and extended Alu-domain

The contribution made by the RNA component of signal recognition particle (SRP) to its function in protein targeting is poorly understood. We have generated a complete secondary structure for Saccharomyces cerevisiae SRP RNA, scR1. The structure conforms to that of other eukaryotic SRP RNAs. It is rod-shaped with, at opposite ends, binding sites for proteins required for the SRP functions of signal sequence recognition (S-domain) and translational elongation arrest (Alu-domain). Micrococcal nuclease digestion of purified S. cerevisiae SRP separated the S-domain of the RNA from the Alu-domain as a discrete fragment. The Alu-domain resolved into several stable fragments indicating a compact structure. Comparison of scR1 with SRP RNAs of five yeast species related to S. cerevisiae revealed the S-domain to be the most conserved region of the RNA. Extending data from nuclease digestion with phylogenetic comparison, we built the secondary structure model for scR1. The Alu-domain contains large extensions, including a sequence with hallmarks of an expansion segment. Evolutionarily conserved bases are placed in the Alu- and S-domains as in other SRP RNAs, the exception being an unusual GU(4)A loop closing the helix onto which the signal sequence binding Srp54p assembles (domain IV). Surprisingly, several mutations within the predicted Srp54p binding site failed to disrupt SRP function in vivo. However, the strength of the Srp54p-scR1 and, to a lesser extent, Sec65p-scR1 interaction was decreased in these mutant particles. The availability of a secondary structure for scR1 will facilitate interpretation of data from genetic analysis of the RNA.     

Solution structure of a SRP19 binding domain in human SRP RNA

Assembly of the human signal recognition particle (SRP) requires SRP19 protein to bind to helices 6 and 8 of SRP RNA. In the present study, structure of a 29-mer RNA composing the SRP19 binding site in helix 6 was determined by NMR spectroscopy. The two A:C mismatches were continuously stacked to each other and formed wobble type A:C base pairs. The GGAG tetraloop in helix 6 was found to adopt a similar conformation to that of GNRA tetraloop, suggesting that these tetraloops are included in an extensive new motif GNRR. Compared with the crystal structure of helix 6 in complex with SRP19 determined previously, the GGAG tetraloop in the complex was found to adopt a similar conformation to the free form, although the loop structure becomes more open upon SRP19 binding. Thus, SRP19 is thought to recognize the overall fold of the GGAG loop.     

Role of SRP19 in assembly of the Archaeoglobus fulgidus signal recognition particle

Previous studies have shown that SRP19 promotes association of the highly conserved signal peptide-binding protein, SRP54, with the signal recognition particle (SRP) RNA in both archaeal and eukaryotic model systems. In vitro characterization of this process is now reported using recombinantly expressed components of SRP from the hyperthermophilic, sulfate-reducing archaeon Archaeoglobus fulgidis. A combination of native gel mobility shift, filter binding, and Ni-NTA agarose bead binding assays were used to determine the binding constants for binary and ternary complexes of SRP proteins and SRP RNA. Archaeal SRP54, unlike eukaryotic homologues, has significant intrinsic affinity for 7S RNA (K(D) approximately 15 nM), making it possible to directly compare particles formed in the presence and absence of SRP19 and thereby assess the precise role of SRP19 in the assembly process. Chemical modification studies using hydroxyl radicals and DEPC identify nonoverlapping primary binding sites for SRP19 and SRP54 corresponding to the tips of helix 6 and helix 8 (SRP19) and the distal loop and asymmetric bulge of helix 8 (SRP54). SRP19 additionally induces conformational changes concentrated in the proximal asymmetric bulge of helix 8. Selected nucleotides in this bulge become modified as a result of SRP19 binding but are subsequently protected from modification by formation of the complete complex with SRP54. Together these results suggest a model for assembly in which bridging the ends of helix 6 and helix 8 by SRP19 induces a long-range structural change to present the proximal bulge in a conformation compatible with high-affinity SRP54 binding.     

Identification of RNA sequences and structural elements required for assembly of fission yeast SRP54 protein with signal recognition particle RNA.

Signal recognition particle (SRP) is a ribonucleoprotein composed of six polypeptides and a single RNA molecule. SRP RNA can be divided into four structural domains, the last of which is the most highly conserved and, in Schizosaccharomyces pombe, is the primary location to which deleterious mutations map. The ability of mammalian SRP54 protein (SRP54p) to bind Escherichia coli 4.5S RNA, a homolog of SRP RNA which contains only domain IV, suggested that SRP54p might interact directly with this region. To determine whether domain IV is critical for SRP54p binding in fission yeast cells, we used a native immunoprecipitation-RNA sequencing assay to test 13 mutant SRP RNAs for the ability to associate with the protein in vivo. The G156A mutation, which alters the 5' residue of the noncanonical first base pair of the domain IV terminal helix and confers a mild conditional growth defect, reduces assembly of the RNA with SRP54p. Mutating either of the two evolutionarily invariant residues in the bulged region 5' to G156 is more deleterious to growth and virtually abolishes SRP54p binding. We conclude that the conservation of nucleotides 154 to 156 is likely to be a consequence of their role as a sequence-specific recognition element for the SRP54 protein. We also tested a series of mutants with nucleotide substitutions in the conserved tetranucleotide loop and adjoining stem of domain IV. Although tetraloop mutations are deleterious to growth, they have little effect on SRP54p binding. Mutations which disrupt the base pair flanking the tetraloop result in conditional growth defects and significantly reduce association with SRP54p. Disruption of the other two base pairs in the short stem adjacent to the tetranucleotide loop has similar but less dramatic effects on SRP54p binding. These data provide the first evidence that both sequence-specific contacts and the structural integrity of domain IV of SRP RNA are important for assembly with SRP54p.     

Evolutionary substitution of two amino acids in chloroplast SRP54 of higher plants cause its inability to bind SRP RNA

The chloroplast signal recognition particle (cpSRP) consists of a conserved 54kDa subunit (cpSRP54) and a unique 43kDa subunit (cpSRP43) but lacks SRP-RNA, an essential and universally conserved component of cytosolic SRPs. High sequence similarity exists between cpSRP54 and bacterial SRP54 except for a plant-specific C-terminal extension containing the cpSRP43-binding motif. We found that cpSRP54 of higher plants lacks the ability to bind SRP-RNA because of two amino acid substitutions within a region corresponding to the RNA binding domain of cytosolic SRP54, whereas the C-terminal extension does not affect RNA binding. Phylogenetic analysis revealed that these mutations occur in the cpSRP54 homologues of higher plants but not in most algae.     

TLR序列在SRP54蛋白与SRPRNA和信号肽结合中的作用

SRP54蛋白是信号识别颗粒(signal recognition particle)的一个关键组分.对人SRP54蛋白328～330位的TLR3个氨基酸进行人工诱变,在大肠杆菌BL21(DE3)pLysS中表达了A3突变体,并对A3突变体进行纯化和Superdex75凝胶过滤分析.观察到A3突变体丧失了与SRPRNA结合的能力,其自身也不能形成二聚体.结果证明,TLR这3个氨基酸残基与二聚体结构的形成有关,TLR是SRP54蛋白结合SRPRNA和新生蛋白质信号肽所必需的关键性氨基酸序列.     

Anti-cooperative assembly of the SRP19 and SRP68/72 components of the signal recognition particle

The mammalian SRP (signal recognition particle) represents an important model for the assembly and role of inter-domain interactions in complex RNPs (ribonucleoproteins). In the present study we analysed the interdependent interactions between the SRP19, SRP68 and SRP72 proteins and the SRP RNA. SRP72 binds the SRP RNA largely via non-specific electrostatic interactions and enhances the affinity of SRP68 for the RNA. SRP19 and SRP68 both bind directly and specifically to the same two RNA helices, but on opposite faces and at opposite ends. SRP19 binds at the apices of helices 6 and 8, whereas the SRP68/72 heterodimer binds at the three-way junction involving RNA helices 5, 6 and 8. Even though both SRP19 and SRP68/72 stabilize a similar parallel orientation for RNA helices 6 and 8, these two proteins bind to the RNA with moderate anti-cooperativity. Long-range anti-cooperative binding by SRP19 and SRP68/72 appears to arise from stabilization of distinct conformations in the stiff intervening RNA scaffold. Assembly of large RNPs is generally thought to involve either co-operative or energetically neutral interactions among components. By contrast, our findings emphasize that antagonistic interactions can play significant roles in assembly of multi-subunit RNPs.     

The crystal structure of the signal recognition particle Alu RNA binding heterodimer, SRP9/14.

The mammalian signal recognition particle (SRP) is an 11S cytoplasmic ribonucleoprotein that plays an essential role in protein sorting. SRP recognizes the signal sequence of the nascent polypeptide chain emerging from the ribosome, and targets the ribosome-nascent chain-SRP complex to the rough endoplasmic reticulum. The SRP consists of six polypeptides (SRP9, SRP14, SRP19, SRP54, SRP68 and SRP72) and a single 300 nucleotide RNA molecule. SRP9 and SRP14 proteins form a heterodimer that binds to the Alu domain of SRP RNA which is responsible for translation arrest. We report the first crystal structure of a mammalian SRP protein, that of the mouse SRP9/14 heterodimer, determined at 2.5 A resolution. SRP9 and SRP14 are found to be structurally homologous, containing the same alpha-beta-beta-beta-alpha fold. This we designate the Alu binding module (Alu bm), an additional member of the family of small alpha/beta RNA binding domains. The heterodimer has pseudo 2-fold symmetry and is saddle like, comprising a strongly curved six-stranded amphipathic beta-sheet with the four helices packed on the convex side and the exposed concave surface being lined with positively charged residues.     

A Mycoplasma protein homologous to mammalian SRP54 recognizes a highly conserved domain of SRP RNA.

A protein homologous to SRP54, a subunit of the mammalian signal recognition particle (SRP), was identified in Mycoplasma mycoides. The mycoplasma protein was expressed in E.coli and purified to near homogeneity. It was shown to bind specifically in vitro to a small mycoplasma RNA with structural features related to the RNA component of SRP. These findings provide evidence of a ribonucleoprotein complex in mycoplasma reminiscent of SRP. A part of the RNA was protected from ribonuclease digestion in the presence of the SRP54 homologue. The protected region contains structural elements that have been highly conserved in SRP RNAs during evolution.