Recognition of a tetranucleotide loop of signal recognition particle RNA by protein SRP19.

The interaction of protein SRP19 with the RNA component of human signal recognition particle (SRP) was studied by site-directed mutagenesis of the SRP RNA. The effects of nucleotide changes in the tetranucleotide loop (tetraloop) of helix 6 showed that SRP19 recognizes a tetraloop in a sequence-specific manner. Adenosine 149 at the third position of the tetraloop was essential for binding. In contrast, changes of the base at the second position had no effect. Mutations that disrupt or compensate individual SRP RNA helices were generated to investigate the importance of base pairing and to identify other binding sites. Considerable base pairing was essential in helix 6. Another SRP19-binding site was located in the distal part of helix 8. The primary sequences of the tetraloop-binding protein SR19 and of bacterial ribosomal protein S15 are shown to be similar.     

Interaction of protein SRP19 with signal recognition particle RNA lacking individual RNA-helices.

Derivatives of human SRP-RNA were constructed by site-directed mutagenesis and tested for their ability to interact with protein SRP19. An RNA missing helix 6 barely interacts with SRP19, while the helix 8-deletion mutant retains much binding capability. A mutant RNA consisting just of helix 6 also binds the protein, but not as well as the unaltered molecule. SRP19 interacts to a full extent with the fourth mutant RNA composed of helices 6, 7, 8 and a portion of helix 5. It is concluded that helix 6- and not helix 8- is the major SRP19 binding site. Helices 7, 8 and portions of helix 5 contribute to the formation of a functional site. These results agree with data suggesting a proximity of helix 6 and the conserved part of SRP-RNA.     

The signal recognition particle (SRP) RNA links conformational changes in the SRP to protein targeting

The RNA component of the signal recognition particle (SRP) is universally required for cotranslational protein targeting. Biochemical studies have shown that SRP RNA participates in the central step of protein targeting by catalyzing the interaction of the SRP with the SRP receptor (SR). SRP RNA also accelerates GTP hydrolysis in the SRP.SR complex once formed. Using a reverse-genetic and biochemical analysis, we identified mutations in the E. coli SRP protein, Ffh, that abrogate the activity of the SRP RNA and cause corresponding targeting defects in vivo. The mutations in Ffh that disrupt SRP RNA activity map to regions that undergo dramatic conformational changes during the targeting reaction, suggesting that the activity of the SRP RNA is linked to the major conformational changes in the signal sequence-binding subunit of the SRP. In this way, the SRP RNA may coordinate the interaction of the SRP and the SR with ribosome recruitment and transfer to the translocon, explaining why the SRP RNA is an indispensable component of the protein targeting machinery.     

Fluorescence-detected assembly of the signal recognition particle: binding of the two SRP protein heterodimers to SRP RNA is noncooperative.

Protein-RNA and protein-protein interactions involved in the assembly of the signal recognition particle (SRP) were examined using fluorescence spectroscopy. Fluorescein was covalently attached to the 3'-terminal ribose of SRP RNA following periodate oxidation, and the resulting SRP RNA-Fl was reconstituted into a fluorescent SRP species that was functional in promoting translocation of secretory proteins across the membrane of the endoplasmic reticulum. Each of the two protein heterodimers purified from SRP elicited a substantial change in fluorescein emission upon association with the modified RNA. The binding of SRP9/14 to singly-labeled SRP RNA-Fl increased fluorescein emission intensity by 41% at pH 7.5 and decreased its anisotropy from 0.18 to 0.16. The binding of SRP68/72 increased the fluorescein anisotropy from 0.18 to 0.23 but did not alter the emission intensity of SRP RNA-Fl. These fluorescence changes did not result from a direct interaction between the dye and protein because the fluorescein remained accessible to both iodide ions and fluorescein-specific antibodies in the complexes. The spectral changes were elicited by specific SRP RNA-protein interactions, since (i) the SRP9/14- and SRP68/72-dependent changes were unique, (ii) an excess of unlabeled SRP RNA, but not of tRNA, blocked the fluorescence changes, and (iii) no emission changes were observed when SRP RNA-Fl was titrated with other RNA-binding proteins. Each heterodimer bound tightly to the RNA, since the Kd values determined spectroscopically and at equilibrium for the SRP9/14 and the SRP68/72 complexes with SRP RNA-Fl were less than 0.1 and 7 +/- 3 nM, respectively. The binding affinity of SRP68/72 for SRP RNA-Fl was unaffected by the presence of SRP9/14, and hence the binding of the heterodimers to SRP RNA is noncooperative in the absence of SRP54 and SRP19. The SRP protein heterodimers therefore associate randomly and independently with SRP RNA to form domains in the particle that are distinct both structurally and functionally. Any cooperativity in SRP assembly would have to be mediated by SRP54 and/or SRP19.     

A basic region neighboring the lysine-rich C-terminus of protein SRP19 is required for binding to signal recognition particle RNA.

To identify some of the determinants in the 19-kilodalton protein of signal recognition particle (SRP19) for binding to signal recognition particle RNA, two mutant derivatives of the SRP19 were constructed, lacking 14 and 24 C-terminal amino acids. Polypeptides were transcribed and translated in vitro and tested for their ability to bind to signal recognition particle RNA by retention of protein-RNA complexes on DEAE-Sepharose. Both mutant polypeptides form complexes with the RNA, demonstrating that the 24 C-terminal amino acids, which include a lysine-rich sequence at positions 136-144, are dispensable. A third mutant polypeptide, in which eight additional amino acids were removed by oligonucleotide-directed digestion of the mRNA, was unable to bind. The amino acids in the sequence PKLKTRTQ correspond to positions 113-120; they are suggested to be involved in interaction with signal recognition particle RNA.     

Interaction of rice and human SRP19 polypeptides with signal recognition particle RNA

The signal recognition particle (SRP) controls the transport of secretory proteins into and across lipid bilayers. SRP-like ribonucleoprotein complexes exist in all organisms, including plants. We characterized the rice SRP RNA and its primary RNA binding protein, SRP19. The secondary structure of the rice SRP RNA was similar to that found in other eukaryotes; however, as in other plant SRP RNAs, a GUUUCA hexamer sequence replaced the highly conserved GNRA-tetranucleotide loop motif at the apex of helix 8. The small domain of the rice SRP RNA was reduced considerably. Structurally, rice SRP19 lacked two small regions that can be present in other SRP19 homologues. Conservative structure prediction and site-directed mutagenesis of rice and human SRP19 polypeptides indicated that binding to the SRP RNAs occurred via a loop that is present in the N-domain of both proteins. Rice SRP19 protein was able to form a stable complex with the rice SRP RNA in vitro. Furthermore, heterologous ribonucleoprotein complexes with components of the human SRP were assembled, thus confirming a high degree of structural and functional conservation between plant and mammalian SRP components.     

Assembly of the Alu domain of the signal recognition particle (SRP): dimerization of the two protein components is required for efficient binding to SRP RNA.

The signal recognition particle (SRP), a cytoplasmic ribonucleoprotein, plays an essential role in targeting secretory proteins to the rough endoplasmic reticulum membrane. In addition to the targeting function, SRP contains an elongation arrest or pausing function. This function is carried out by the Alu domain, which consists of two proteins, SRP9 and SRP14, and the portion of SRP (7SL) RNA which is homologous to the Alu family of repetitive sequences. To study the assembly pathway of the components in the Alu domain, we have isolated a cDNA clone of SRP9, in addition to a previously obtained cDNA clone of SRP14. We show that neither SRP9 nor SRP14 alone interacts specifically with SRP RNA. Rather, the presence of both proteins is required for the formation of a stable RNA-protein complex. Furthermore, heterodimerization of SRP9 and SRP14 occurs in the absence of SRP RNA. Since a partially reconstituted SRP lacking SRP9 and SRP14 [SRP(-9/14)] is deficient in the elongation arrest function, it follows from our results that both proteins are required to assemble a functional domain. In addition, SRP9 and SRP14 synthesized in vitro from synthetic mRNAs derived from their cDNA clones restore elongation arrest activity to SRP(-9/14).     

Protein SRP68 of human signal recognition particle: identification of the RNA and SRP72 binding domains

The signal recognition particle (SRP) plays an important role in the delivery of secretory proteins to cellular membranes. Mammalian SRP is composed of six polypeptides among which SRP68 and SRP72 form a heterodimer that has been notoriously difficult to investigate. Human SRP68 was purified from overexpressing Escherichia coli cells and was found to bind to recombinant SRP72 as well as in vitro-transcribed human SRP RNA. Polypeptide fragments covering essentially the entire SRP68 molecule were generated recombinantly or by proteolytic digestion. The RNA binding domain of SRP68 included residues from positions 52 to 252. Ninety-four amino acids near the C terminus of SRP68 mediated the binding to SRP72. The SRP68-SRP72 interaction remained stable at elevated salt concentrations and engaged approximately 150 amino acids from the N-terminal region of SRP72. This portion of SRP72 was located within a predicted tandem array of four tetratricopeptide (TPR)-like motifs suggested to form a superhelical structure with a groove to accommodate the C-terminal region of SRP68.     

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.     

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.     

Isolation,characterization, and chromosomal mapping of a novel cDNA clone encoding human selenium binding protein

We have isolated the full-length human 56 kDa selenium binding protein (hSP56) cDNA clone, which is the human homolog of mouse 56 kDa selenium binding protein. The cDNA is 1,668 bp long and has an open reading frame encoding 472 amino acids. The calculated molecular weight is 52.25 kDa and the estimated isoelectric point is 6.13. Using Northern blot hybridization, we found that this 56 kDa selenium binding protein is expressed in mouse heart with an intermediate level between those found in liver/lung/kidney and intestine. We have also successfully expressed hSP56 in Escherichia coli using the expression vector-pAED4. The hSP56 gene is located at human chromosome 1q21–22. J. Cell. Biochem. 64:217–224. © 1997 Wiley-Liss, Inc.     

Isolation of a human cDNA encoding a 25 kDa FK-506 and rapamycin binding protein.

Recently, the nearly complete peptide sequence of a 25 kDa rapamycin and FK-506 binding protein that had been isolated from calf thymus, brain, and spleen was reported (1). Based upon the amino acid sequence of this bovine protein, bFKBP25, we have isolated from a JURKAT cDNA library the cDNA encoding the human homolog, hFKBP25. Translation of the open reading frame contained within this cDNA clone yields a sequence that, in its C-terminal half, is 41% identical to the major human FK-506 binding protein, hFKBP12, and 43% identical to hFKBP13. The N-terminal half of hFKBP25 is unrelated to any known protein.     

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.