Induced structural changes of 7SL RNA during the assembly of human signal recognition particle

The eukaryotic signal recognition particle (SRP) is a cytoplasmic ribonucleoprotein particle that targets secretory and membrane proteins to the endoplasmic reticulum. The binding of SRP54 to the S domain of 7SL RNA is highly dependent on SRP19. Here we present the crystal structure of a human SRP ternary complex consisting of SRP19, the M domain of SRP54 and the S domain of 7SL RNA. Upon binding of the M domain of SRP54 to the 7SL RNA-SRP19 complex, the asymmetric loop of helix 8 in 7SL RNA collapses. The bases of the four nucleotides in the long strand of the asymmetric loop continuously stack and interact with the M domain, whereas the two adenines in the short strand flip out and form two A-minor motifs with helix 6. This stabilizing interaction is only possible when helix 6 has been positioned parallel to helix 8 by the prior binding of SRP19 to the tetraloops of helices 6 and 8. Hence, the crystal structure of the ternary complex suggests why SRP19 is necessary for the stable binding of SRP54 to the S domain RNA.     

Identification of a minimal Alu RNA folding domain that specifically binds SRP9/14.

We have identified functionally and analyzed a minimal Alu RNA folding domain that is recognized by SRPphi14-9. Recombinant SRPphi14-9 is a fusion protein containing on a single polypeptide chain the sequences of both the SRP14 and SRP9 proteins that are part of the Alu domain of the signal recognition particle (SRP). SRPphi14-9 has been shown to bind to the 7SL RNA of SRP and it confers elongation arrest activity to reconstituted SRP in vitro. Alu RNA variants with homogeneous 3' ends were produced in vitro using ribozyme technology and tested for specific SRPphi14-9 binding in a quantitative equilibrium competition assay. This enabled identification of an Alu RNA of 86 nt (SA86) that competes efficiently with 7SL RNA for SRPphi14-9 binding, whereas smaller RNAs did not. The secondary structure of SA86 includes two stem-loops that are connected by a highly conserved bulge and, in addition, a part of the central adaptor stem that contains the sequence at the very 3' end of 7SL RNA. Circularly permuted variants of SA86 competed only if the 5' and 3' ends were joined with an extended linker of four nucleotides. SA86 can thus be defined as an autonomous RNA folding unit that does not require its 5' and 3' ends for folding or for specific recognition by SRPphi14-9. These results suggest that Alu RNA identity is determined by a characteristic tertiary structure, which might consist of two flexibly linked domains.     

Characterization of human autoantibodies that selectively precipitate the 7SL RNA component of the signal recognition particle

The signal recognition particle (SRP), which consists of the 7SL RNA molecule associated with six polypeptides ranging between 9,000 and 72,000 m.w., mediates the translocation of newly synthesized proteins across the endoplasmic reticulum. We have characterized autoantibodies that are directed against this particle from two patients with rheumatic diseases. These sera immunoprecipitated the 7SL RNA from whole extracts of HeLa cells radiolabeled with 32P, but no RNA from deproteinized cell extracts. From 35S-methionine-labeled cell extracts, they immunoprecipitated a single polypeptide of 54,000 m.w. that is consistent with a known SRP component. Sucrose density gradient studies confirmed that this protein co-migrated with the 7SL RNA, indicating the likelihood that it is physically associated with this RNA. Thus, the 54,000 m.w. SRP protein, which is essential for the SRP functions of elongation arrest and translocation, appears to be a preferential target for human autoimmune responses. Human autoantibodies that recognize the SRP should be useful adjuncts to animal antisera for studies of the structure and function of this particle.     

The organization of the 7SL RNA in the signal recognition particle.

Digestion of the signal recognition particle (SRP) of dog pancreas with micrococcal nuclease results in the stepwise cleavage of the 300 nucleotide 7SL RNA moiety producing five major fragments approximately 220 (1), 150 (2), 72 (3), 62 (4) and 45 (5) nucleotides long. The RNA molecule is initially cut once yielding fragments 1 and 3. Further degradation releases fragments 2, 4 and 5. The introduction of the first nick into the 7SL RNA does not alter the structure nor the function of the SRP. Further degradation of the RNA results in disruption and loss of activity of the particle. The sequence of the RNA fragments shows that the nuclease causes discrete cuts in the RNA with minimal nibbling indicating that only few sites are accessible to the action of the enzyme. The five major products of nuclease digestion together span almost the entire length of the 7SL RNA. Nicking occurs mainly around the boundary region between the central S sequence and the flanking Alu sequences constituting the 7SL RNA (1). The S fragment is bound to the four largest polypeptides while the 5' and 3' Alu fragments are associated with the two smallest protein constituents of the SRP.     

Changes in 7SL RNA conformation during the signal recognition particle cycle.

The structure of 7SL RNA has been probed by chemical modification followed by primer extension, using four substrates: (i) naked 7SL RNA; (ii) free signal recognition particle (SRP); (iii) polysome bound SRP; and (iv) membrane bound SRP. Decreasing sensitivity to chemical modification between these different substrates suggests regions on 7SL RNA that: bind proteins associated with SRP might interact with ribosomes; and are protected by binding to membranes. Other areas increase in chemical sensitivity, exemplified by a tertiary interaction present in naked 7SL RNA but not in free SRP. Such changes suggest that 7SL RNA changes its conformation during the SRP cycle. These conformational changes could be a necessary component to move through the SRP cycle from one stage to the next.     

The trypanosomatid signal recognition particle consists of two RNA molecules,a 7SL RNA homologue and a novel tRNA-like molecule

Trypanosomatids are ancient eukaryotic parasites affecting humans and livestock. Here we report that the trypanosomatid signal recognition particle (SRP), unlike all other known SRPs in nature, contains, in addition to the 7SL RNA homologue, a short RNA molecule, termed sRNA-85. Using conventional chromatography, we discovered a small RNA molecule of 85 nucleotides co-migrating with the Leptomonas collosoma 7SL RNA. This RNA molecule was isolated, sequenced, and used to clone the corresponding gene. sRNA-85 was identified as a tRNA-like molecule that deviates from the canonical tRNA structure. The co-existence of these RNAs in a single complex was confirmed by affinity selection using an antisense oligonucleotide to sRNA-85. The two RNA molecules exist in a particle of approximately 14 S that binds transiently to ribosomes. Mutations were introduced in sRNA-85 that disrupted its putative potential to interact with 7SL RNA by base pairing; such mutants were unable to bind to 7SL RNA and to ribosomes and were aberrantly distributed within the cell. We postulate that sRNA-85 may functionally replace the truncated Alu domain of 7SL RNA. The discovery of sRNA-85 raises the intriguing possibility that sRNA-85 functional homologues may exist in other lower eukaryotes and eubacteria that lack the Alu domain.     

The methionine-rich domain of the 54 kd protein subunit of the signal recognition particle contains an RNA binding site and can be crosslinked to a signal sequence.

The 54 kd protein subunit of the signal recognition particle (SRP54) has been shown to bind signal sequences by UV crosslinking. Primary structure analysis and phylogenetic comparisons have suggested that SRP54 is composed of two domains: an amino-terminal domain that contains a putative GTP-binding site (G-domain) and a carboxy-terminal domain that contains a high abundance of methionine residues (M-domain). Partial proteolysis of SRP revealed that the two proposed domains of SRP54 indeed represent structurally discrete entities. Upon proteolysis the intact G-domain was released from SRP, whereas the M-domain remained attached to the core of the particle. Reconstitution experiments demonstrated that the isolated M-domain associates with 7SL RNA in the presence of SRP19. In addition, we observed a specific binding of the M-domain directly to 4.5S RNA of Escherichia coli, which contains a structural motif also present in 7SL RNA. This shows that the M-domain contains an RNA binding site, and suggests that SRP54 may be linked to the rest of SRP through this domain by a direct interaction with 7SL RNA. Using UV crosslinking, we found that in an in vitro translation system the preprolactin signal sequence contacts SRP through the M-domain of SRP54. These results imply that the M-domain contains the signal sequence binding site of SRP54, although we cannot exclude that the G-domain may also be in proximity to bound signal sequences.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

7SL RNA, but not the 54-kd signal recognition particle protein, is an abundant component of both infectious HIV-1 and minimal virus-like particles

The virion incorporation of 7SL, the RNA component of the host signal recognition particle (SRP), has been shown for several simple retroviruses. Data here demonstrate that 7SL is also packaged by HIV-1, in sevenfold molar excess of genomic RNA. Viral determinants of HIV-1 genome and primer tRNA packaging were not required for 7SL incorporation, as virus-like particles with only minimal assembly components efficiently packaged 7SL. The majority of 7SL within cells resides in ribonucleoprotein complexes bound by SRP proteins, and most SRP protein exists in signal recognition particles. However, Western blot comparison of virion and cell samples revealed that there is at least 25-fold less SRP p54 protein per 7SL RNA in HIV-1 particles than in cells. Comparing 7SL:actin mRNA ratios in virions and cells revealed that 7SL RNA appears selectively enriched in virions.     

Protein-induced conformational changes of RNA during the assembly of human signal recognition particle

The human signal recognition particle (SRP) is a large RNA-protein complex that targets secretory and membrane proteins to the endoplasmic reticulum membrane. The S domain of SRP is composed of roughly half of the 7SL RNA and four proteins (SRP19, SRP54, and the SRP68/72 heterodimer). In order to understand how the binding of proteins induces conformational changes of RNA and affects subsequent binding of other protein subunits, we have performed chemical and enzymatic probing of all S domain assembly intermediates. Ethylation interference experiments show that phosphate groups in helices 5, 6 and 7 that are essential for the binding of SRP68/72 are all on the same face of the RNA. Hydroxyl radical footprinting and dimethylsulphate (DMS) modifications show that SRP68/72 brings the lower part of helices 6 and 8 closer. SRP68/72 binding also protects the SRP54 binding site (helix 8 asymmetric loop) from chemical modification and RNase cleavage, whereas, in the presence of both SRP19 and SRP68/72, the long strand of helix 8 asymmetric loop becomes readily accessible to chemical and enzymatic probes. These results indicate that the RNA platform observed in the crystal structure of the SRP19-SRP54M-RNA complex already exists in the presence of SRP68/72 and SRP19. Therefore, SRP68/72, together with SRP19, rearranges the 7SL RNA in an SRP54 binding competent state.     

Disassembly and domain structure of the proteins in the signal-recognition particle

The signal-recognition particle (SRP) is a ribonucleoprotein (RNP) complex consisting of six different polypeptide chains and a 7SL RNA. It participates in initiating the translocation of proteins across the membrane of the endoplasmic reticulum. SRP was disassembled in 2 M KCl into three components, one RNP composed of 7SL RNA and the 54-kDa and 19-kDa proteins, and two heterodimers consisting of the 72/68-kDa and the 14/9-kDa proteins respectively. The 54-kDa protein could be released from the RNP subparticle by chromatography on DEAE-Sepharose in Mg2+-depleted buffer, while the 19-kDa protein remained bound to the 7SL RNA. The domain structure of SRP proteins was probed by using mild elastase treatment and protein-specific antibodies. It was found that the 72, 68, 54 and 19-kDa SRP proteins were proteolytically processed in distinct steps. Most remarkably a protein fragment of 55-kDa, generated from the 72-kDa SRP protein, and a 35-kDa fragment from the 54-kDa SRP protein were both released from the RNP particle. Fragments generated from the 68-kDa protein and detectable with the anti-(68-kDa protein) antibody remained associated with the RNP particle. Cleavage of the SRP proteins by elastase at 2.5 micrograms/ml resulted in partial loss of activity, while 10 micrograms/ml caused complete inactivation of the particle. Neither the elongation arrest of IgG light chain nor its translocation across SRP-depleted microsomal membranes was promoted. The implications of these results on the possible interaction between the SRP subunits are discussed.     

Diversity of 7 SL RNA from the signal recognition particle of maize endosperm.

An 11 S ribonucleoprotein particle was isolated from maize endosperm and shown to be functionally and structurally equivalent to the mammalian signal recognition particle. However, unlike animal cells which apparently contain a single 7 SL RNA species, maize endosperm contains a heterogeneous population of 7 SL RNA. To investigate this diversity, we have cloned and sequenced a number of the maize endosperm 7 SL RNAs isolated from functionally active SRP preparations. Some maize 7 SL RNAs are strikingly similar, differing by single base changes or short deletions; surprisingly, others share less than 70 percent sequence homology. Despite differences in primary sequence, nearly identical secondary structures can be suggested for all maize 7 SL RNAs, consistent with a proposed functional role in protein translocation for each of these RNAs. The amount of new available sequence data enabled us to define two conserved regions of presumed functional importance: A conserved sequence -G-N-A-R- in the center of a variable region which forms a well defined stem-loop and possibly is involved in an interaction with the 19 kDa protein of the SRP. Secondly, three short nucleotide stretches located in the central domain of 7 SL RNA may form part of a dynamic RNA-switch structure.     

Elongation arrest is not a prerequisite for secretory protein translocation across the microsomal membrane

Signal recognition particle (SRP) is a ribonucleoprotein consisting of six distinct polypeptides and one molecule of small cytoplasmic 7SL RNA. It was previously shown to promote the co-translational translocation of secretory proteins across the endoplasmic reticulum by (a) arresting the elongation of the presecretory nascent chain at a specific point, and (b) interacting with the SRP receptor, an integral membrane protein of the endoplasmic reticulum which is active in releasing the elongation arrest. Recently a procedure was designed by which the particle could be disassembled into its protein and RNA components. We have further separated the SRP proteins into four homogeneous fractions. When recombined with each other and with 7SL RNA, they formed fully active SRP. Particles missing specific proteins were assembled in the hope that some of these would retain some functional activity. SRP(-9/14), the particle lacking the 9-kD and 14-kD polypeptides, was fully active in promoting translocation, but was completely inactive in elongation arrest. This implied that elongation arrest is not a prerequisite for protein translocation. SRP receptor was required for SRP(-9/14)-mediated translocation to occur, and thus must play some role in the translocation process in addition to releasing the elongation arrest.     

The 7S RNA from tomato leaf tissue resembles a signal recognition particle RNA and exhibits a remarkable sequence complementarity to viroids.

From tomato leaf tissue we sequenced and characterized a 7S RNA which consists of 299 nucleotides with either two or three additional uridine nucleotides at its 3'-terminus. About 56% of the nucleotides of this higher plant 7S RNA are in nearly identical positions as those of the human 7SL RNA which is an integral component of the signal recognition particle (SRP) that mediates protein translocation. Computer modelling and digestion studies with nucleases led to a secondary structure model for tomato 7S RNA, the overall shape of which is very similar to that of the human 7SL (SRP) RNA. This structural similarity strongly suggests that tomato 7S RNA is actually an SRP RNA and an integral part of the plant SRP, and that the protein translocation system of higher plants is very similar to the one operating in mammalian cells. Tomato SRP RNA contains a stretch of 36-53 nucleotides which exhibit a high degree of sequence complementarity to five viroid 'species' that cause disease in tomato. In the case of potato spindle tuber viroid and citrus exocortis viroid this complementarity spans the lower strand of the region, the nucleotides of which are known to modulate virulence. This extensive sequence complementarity could lead to a thermodynamically favoured base-pairing in vivo which renders the tomato SRP RNA a possible host target with which viroids could interact and thus incite disease.     

Genetic and biochemical analysis of the fission yeast ribonucleoprotein particle containing a homolog of Srp54p.

Mammalian signal recognition particle (SRP), a complex of six polypeptides and one 7SL RNA molecule, is required for targeting nascent presecretory proteins to the endoplasmic reticulum (ER). Earlier work identified a Schizosaccharomyces pombe homolog of human SRP RNA and showed that it is a component of a particle similar in size and biochemical properties to mammalian SRP. The recent cloning of the gene encoding a fission yeast protein homologous to Srp54p has made possible further characterization of the subunit structure, subcellular distribution, and assembly of fission yeast SRP. S. pombe SRP RNA and Srp54p co-sediment on a sucrose velocity gradient and coimmunoprecipitate, indicating that they reside in the same complex. In vitro assays demonstrate that fission yeast Srp54p binds under stringent conditions to E. coli SRP RNA, which consists essentially of domain IV, but not to the full-length cognate RNA nor to an RNA in which domain III has been deleted in an effort to mirror the structure of bacterial homologs. Moreover, the association of S. pombe Srp54p with SRP RNA in vivo is disrupted by conditional mutations not only in domain IV, which contains its binding site, but in domains I and III, suggesting that the particle may assemble cooperatively. The growth defects conferred by mutations throughout SRP RNA can be suppressed by overexpression of Srp54p, and the degree to which growth is restored correlates inversely with the severity of the reduction in protein binding. Conditional mutations in SRP RNA also reduce its sedimentation with the ribosome/membrane pellet during cell fractionation. Finally, immunoprecipitation under native conditions of an SRP-enriched fraction from [35S]-labeled fission yeast cells suggests that five additional polypeptides are complexed with Srp54p; each of these proteins is similar in size to a constituent of mammalian SRP, implying that the subunit structure of this ribonucleoprotein is conserved over vast evolutionary distances.     

Association of 7 SL RNA and an SRP-like particle with polysomes and endoplasmic reticulum in the developing sea urchin embryo

We have identified the sea urchin cognate of the mammalian signal recognition particle (SRP). This particle contains the diagnostic 7 SL small RNA, sediments at a similar velocity to that reported for the mammalian particle, and is found associated with the ER and polysomes. We have examined its subcellular localization during embryogenesis in order to determine whether it could serve in a translational regulatory capacity for a subset of the stored maternal mRNAs. In these studies the 7 SL RNA was used as a marker for the particle, since we determined that the 7 SL RNA exists exclusively within the SRP-like particle at all developmental stages. The relative distribution of the SRP among cytoplasmic structures changes dramatically during development. This represents an actual change in subcellular localization because the 7 SL RNA level remains nearly constant per embryo until the pluteus stage, when it increases slightly. In eggs, the SRP exists almost entirely free in the cytoplasm as an 11 S particle. Very soon after fertilization and throughout development there is an increase in the association of the particle with rapidly sedimenting structures, until by the pluteus stage greater than 90% of the SRP exists in a bound state. The nature of the associations is complex, and the bound structures include, at least in part, ribosomes, polysomes, and microsomes. The SRP is associated with microsomal membranes in gastrula (36 hr) but not in blastula (12 hr) or earlier embryos. Using the criteria of sensitivity to Triton X-100, we determined that 16% of the SRP in a 10,000g cytoplasmic fraction was bound to membranes in a microsomal (endoplasmic reticulum)-containing fraction in the gastrula. In contrast, less than 1% was membrane associated in the blastula. The SRP was also found in a ribosome-polysome fraction in 12-, 36-, and 48-hr embryos, but not in eggs. Finally, a small but significant portion of the SRP was found associated with monosomes in cleavage stage embryos. The possible role the SRP could play in the elongation arrest of stored maternal messages for secreted proteins is discussed.