Structural requirements of Bacillus subtilis small cytoplasmic RNA for cell growth, sporulation, and extracellular enzyme production.

Bacillus subtilis small cytoplasmic RNA (scRNA; 271 nucleotides) is a member of the signal recognition particle (SRP) RNA family, which has evolutionarily conserved primary and secondary structures. The scRNA consists of three domains corresponding to domains I, II, and IV of human SRP 7S RNA. To identify the structural determinants required for its function, we constructed mutant scRNAs in which individual domains or conserved nucleotides were deleted, and their importance was assayed in vivo. The results demonstrated that domain IV of scRNA is necessary to maintain cell viability. On the other hand, domains I and II were not essential for vegetative growth but were preferentially required for the RNA to achieve its active structure, and assembled ribonucleoprotein between Ffh and scRNA is required for sporulation to proceed. This view is highly consistent with the fact that the presence of domains I and II is restricted to sporeforming B. subtilis scRNA among eubacterial SRP RNA-like RNAs.     

Depletion of Bacillus subtilis histone-like protein, HBsu, causes defective protein translocation and induces upregulation of small cytoplasmic RNA

Small cytoplasmic RNA (scRNA) is a metabolically stable homologue of mammalian SRP RNA that contains an Alu-like domain. The Bacillus subtilis histone-like protein HBsu can bind this domain. We demonstrate here that repressing the level of HBsu results in slow growth and the accumulation of precursor of beta-lactamase fusion proteins having the signal sequence of alkaline protease, penicillin binding protein 5* (PBP5*) or CGTase. The degree of the translocation defect varied among the various signal sequences tested. A pulse-chase experiment showed that processing the alpha-amylase signal sequence is significantly inhibited in HBsu-depleted cells. Northern blot analysis indicated that repressing the HBsu gene induces scRNA upregulation, indicating that the defective translocation of presecretory proteins is not due to a reduced scRNA level. The data presented here suggest that HBsu plays a pivotal role in SRP function rather than simply stabilizing the other SRP components such as scRNA.     

Small cytoplasmic RNA of Bacillus subtilis: functional relationship with human signal recognition particle 7S RNA and Escherichia coli 4.5S RNA.

Small cytoplasmic RNA (scRNA; 271 nucleotides) is an abundant and stable RNA of the gram-positive bacterium Bacillus subtilis. To investigate the function of scRNA in B. subtilis cells, we developed a strain that is dependent on isopropyl-beta-D-thiogalactopyranoside for scRNA synthesis by fusing the chromosomal scr locus with the spac-1 promoter by homologous recombination. Depletion of the inducer leads to a loss of scRNA synthesis, defects in protein synthesis and production of alpha-amylase and beta-lactamase, and eventual cell death. The loss of the scRNA gene in B. subtilis can be complemented by the introduction of human signal recognition particle 7S RNA, which is considered to be involved in protein transport, or Escherichia coli 4.5S RNA. These results provide further evidence for a functional relationship between B. subtilis scRNA, human signal recognition particle 7S RNA, and E. coli 4.5S RNA.     

Identification and characterization of Streptococcus pneumoniae Ffh, a homologue of SRP54 subunit of mammalian signal recognition particle

Recent studies have demonstrated that bacteria possess an essential protein translocation system similar to mammalian signal recognition particle (SRP). Here we have identified the Ffh, a homologue of the mammalian SRP54 subunit from S. pneumoniae. Ffh is a 58-kDa protein with three distinct domains: an N-terminal hydrophilic domain (N-domain), a G-domain containing GTP/GDP binding motifs, and a C-terminal methionine-rich domain (M-domain). The full-length Ffh and a truncated protein containing N and G domains (Ffh-NG) were overexpressed in E. coli and purified to homogeneity. The full-length Ffh has an intrinsic GTPase activity with k(cat) of 0.144 min(-1), and the K(m) for GTP is 10.9 microM. It is able to bind to 4.5S RNA specifically as demonstrated by gel retardation assay. The truncated Ffh-NG has approximately the same intrinsic GTPase activity to the full-length Ffh, but is unable to bind to 4.5S RNA, indicating that the NG domain is sufficient for supporting intrinsic GTP hydrolysis, and that the M domain is required for RNA binding. The interaction of S. pneumoniae Ffh with its receptor, FtsY, resulted in a 20-fold stimulation in GTP hydrolysis. The stimulation was further demonstrated to be independent of the 4.5S RNA. In addition, a similar GTPase stimulation is also observed between Ffh-NG and FtsY, suggesting that the NG domain is sufficient and the M domain is not required for GTPase stimulation between Ffh and FtsY.     

Phylogenetic and biochemical evidence for a secondary structure model of a small cytoplasmic RNA from Bacilli.

Small cytoplasmic RNA (scRNA; 271 nucleotides) is an abundant, stable RNA identified in the Gram-positive eubacterium Bacillus subtilis. Several findings suggest an important role of scRNA in protein biosynthesis: it shares structural and biochemical features with the Escherichia coli 4.5S RNA (114 nucleotides), a molecule known to be involved in this process, and it can complement the essential function of 4.5S RNA in vivo. The common apical hairpin motif of scRNA and 4.5S RNA also exists in eukaryotic 7SL RNA, the RNA component of the signal recognition particle. To elucidate the higher-order structure of scRNA, we have combined a phylogenetic approach with a biochemical one. The sequence of scRNA from a thermophilic relative of B. subtilis, Bacillus stearothermophilus, was determined and compared with the B. subtilis scRNA. In addition, the solution structure of B. stearothermophilus scRNA was probed with single- and double-strand-specific nucleases. Both types of analysis support a secondary structure model for scRNA that strongly resembles 4.5S RNA and respective parts of 7SL RNA. The results provide further evidence for the suggestion of a functional relationship between these RNAs.     

Domain rearrangement of SRP protein Ffh upon binding 4.5S RNA and the SRP receptor FtsY

The signal recognition particle (SRP) mediates membrane targeting of translating ribosomes displaying a signal-anchor sequence. In Escherichia coli, SRP consists of 4.5S RNA and a protein, Ffh, that recognizes the signal peptide emerging from the ribosome and the SRP receptor at the membrane, FtsY. In the present work, we studied the interactions between the NG and M domains in Ffh and their rearrangements upon complex formation with 4.5S RNA and/or FtsY. In free Ffh, the NG and M domains are facing one another in an orientation that allows cross-linking between positions 231 in the G domain and 377 in the M domain. There are binding interactions between the two domains, as the isolated domains form a strong complex. The interdomain contacts are disrupted upon binding of Ffh to 4.5S RNA, consuming a part of the total binding energy of 4.5S RNA-Ffh association that is roughly equivalent to the free energy of domain binding to each other. In the SRP particle, the NG domain binds to 4.5S RNA in a region adjacent to the binding site of the M domain. Ffh binding to FtsY also requires a reorientation of NG and M domains. These results suggest that in free Ffh, the binding sites for 4.5S RNA and FtsY are occluded by strong domain-domain interactions which must be disrupted for the formation of SRP or the Ffh-FtsY complex.     

Conformations of the signal recognition particle protein Ffh from Escherichia coli as determined by FRET

The signal recognition particle (SRP) initiates the co-translational targeting of proteins to the plasma membrane in bacteria by binding to the N-terminal signal sequence emerging from the translating ribosome. SRP in Escherichia coli is composed of one protein, Ffh, and 4.5S RNA. In the present work, we probe the structure of Ffh alone and in the complex with 4.5S RNA by measuring distances between different positions within Ffh and between Ffh and 4.5S RNA by fluorescence resonance energy transfer (FRET). According to the FRET distances, NG and M domains in free Ffh are in close contact, as in the A/A arrangement in the crystal structure of Ffh from Thermus aquaticus, in agreement with the formation of a crosslink between cysteine residues at two critical positions in the G and M domains. Upon Ffh binding to 4.5S RNA or a 61 nucleotide fragment comprising internal loops A-C, the G and M domains move apart to assume a more open conformation, as indicated by changes of FRET distances. The movement is smaller when Ffh binds to a 49 nucleotide fragment of 4.5S RNA comprising only internal loops A and B, i.e. lacking the binding site of the NG domain. The FRET results suggest that in the SRP complex 4.5S RNA is present in a bent, rather than extended, conformation. The domain rearrangement of Ffh that takes place upon formation of the SRP is probably important for subsequent steps of membrane targeting, including interactions with the translating ribosome and the SRP receptor.     

Methionine sulfoxide reductases protect Ffh from oxidative damages in Escherichia coli

In proteins, methionine residues are primary targets for oxidation. Methionine oxidation is reversed by methionine sulfoxide reductases A and B, a class of highly conserved enzymes. Ffh protein, a component of the ubiquitous signal recognition particle, contains a methionine-rich domain, interacting with a small 4.5S RNA. In vitro analyses reported here show that: (i) oxidized Ffh is unable to bind 4.5S RNA, (ii) oxidized Ffh contains methionine sulfoxide residues, (iii) oxidized Ffh is a substrate for MsrA and MsrB enzymes; and (iv) MsrA/B repairing activities allow oxidized Ffh to recover 4.5S RNA-binding abilities. In vivo analyses reveal that: (i) Ffh synthesized in the msrA msrB mutant contains methionine sulfoxide residues and is unstable, (ii) msrA msrB mutant requires high levels of Ffh synthesis for growth and (iii) msrA msrB mutation leads to defects in Ffh-dependent targeting of MalF. We conclude that MsrA and MsrB are required to repair Ffh oxidized by reactive oxygen species produced by aerobic metabolism, establishing an as-yet undescribed link between protein targeting and oxidation.     

Construction of the 'minimal' SRP that interacts with the translating ribosome but not with specific membrane receptors in Escherichia coli

Escherichia coli signal recognition particle (SRP) consists of 4.5S RNA and Ffh protein. In contrast to eukaryotes, it remains unclear whether translation arrest takes place in prokaryotic cells. To study this problem we constructed a fusion of the M domain of Ffh protein with a cleavable affinity tag. This mutant Ffh, in a complex with 4.5S RNA, can bind signal peptide at the translating ribosome but is unable to bind the membrane. This SRP-ribosome complex should accumulate in the cell if translation is arrested. To test this, the complex was purified from the cells by ultracentrifugation and affinity chromatography. The composition of the complex was analyzed and found to consist of ribosomal RNAs and proteins, the Ffh M domain and 4.5S RNA. The accumulation of this complex in the cell in significant amounts indicated that SRP-mediated translation arrest did occur in bacterial cells.     

Characterization of conserved bases in 4.5S RNA of Escherichia coli by construction of new F' factors

To more clearly understand the function of conserved bases of 4.5S RNA, the product of the essential ffs gene of Escherichia coli, and to address conflicting results reported in other studies, we have developed a new genetic system to characterize ffs mutants. Multiple ffs alleles were generated by altering positions that correspond to the region of the RNA molecule that interacts directly with Ffh in assembly of the signal recognition particle. To facilitate characterization of the ffs mutations with minimal manipulation, recombineering was used to construct new F' factors to easily move each allele into different genetic backgrounds for expression in single copy. In combination with plasmids that expressed ffs in multiple copy numbers, the F' factors provided an accurate assessment of the ability of the different 4.5S RNA mutants to function in vivo. Consistent with structural analysis of the signal recognition particle (SRP), highly conserved bases in 4.5S RNA are important for binding Ffh. Despite the high degree of conservation, however, only a single base (C62) was indispensable for RNA function under all conditions tested. To quantify the interaction between 4.5S RNA and Ffh, an assay was developed to measure the ability of mutant 4.5S RNA molecules to copurify with Ffh. Defects in Ffh binding correlated with loss of SRP-dependent protein localization. Real-time quantitative PCR was also used to measure the levels of wild-type and mutant 4.5S RNA expressed in vivo. These results clarify inconsistencies from prior studies and yielded a convenient method to study the function of multiple alleles.     

Analysis of Escherichia coli 4.5S RNA binding affinity to Ffh and EF-G

Escherichia coli 4.5S RNA is a member of the signal recognition particle RNA family that binds to Ffh and EF-G proteins in vivo. To assess the binding affinity of E. coli 4.5S RNA, wild-type Ffh and a series of amino terminal truncated EF-G mutants with a histidine tag were over-expressed in Escherichia coli and purified. Among them, EF-G mutants with a deletion of all upstream sequences up to and including the second or the third GTP binding sequence element were expressed at high levels and bound with the same activity as wild-type EF-G. Nitrocellulose filter binding assays revealed that the binding affinity values (M(1/2)) for Ffh and EF-G, defined as the concentration giving half-maximal binding, were 0.15 microM and 1.5 microM, respectively. Moreover, we also show that very little EF-G can form a stable complex with 4.5S RNA in vivo, whereas almost all Ffh binds to 4.5S RNA.     

Conformation of 4.5S RNA in the signal recognition particle and on the 30S ribosomal subunit

The signal recognition particle (SRP) from Escherichia coli consists of 4.5S RNA and protein Ffh. It is essential for targeting ribosomes that are translating integral membrane proteins to the translocation pore in the plasma membrane. Independently of Ffh, 4.5S RNA also interacts with elongation factor G (EF-G) and the 30S ribosomal subunit. Here we use a cross-linking approach to probe the conformation of 4.5S RNA in SRP and in the complex with the 30S ribosomal subunit and to map the binding site. The UV-activatable cross-linker p-azidophenacyl bromide (AzP) was attached to positions 1, 21, and 54 of wild-type or modified 4.5S RNA. In SRP, cross-links to Ffh were formed from AzP in all three positions in 4.5S RNA, indicating a strongly bent conformation in which the 5' end (position 1) and the tetraloop region (including position 54) of the molecule are close to one another and to Ffh. In ribosomal complexes of 4.5S RNA, AzP in both positions 1 and 54 formed cross-links to the 30S ribosomal subunit, independently of the presence of Ffh. The major cross-linking target on the ribosome was protein S7; minor cross-links were formed to S2, S18, and S21. There were no cross-links from 4.5S RNA to the 50S subunit, where the primary binding site of SRP is located close to the peptide exit. The functional role of 4.5S RNA binding to the 30S subunit is unclear, as the RNA had no effect on translation or tRNA translocation on the ribosome.     

Functional analysis of the signal recognition particle in Escherichia coli by characterization of a temperature-sensitive ffh mutant

The Ffh protein of Escherichia coli is a 48-kDa polypeptide that is homologous to the SRP54 subunit of the eukaryotic signal recognition particle (SRP). Efforts to understand the function of Ffh in bacteria have depended largely on the use of E. coli strains that allow depletion of the wild-type gene product. As an alternative approach to studying Ffh, a temperature-sensitive ffh mutant was isolated. The ffh-10(Ts) mutation results in two amino acid changes in conserved regions of the Ffh protein, and characterization of the mutant revealed that the cells rapidly lose viability at the nonpermissive temperature of 42 degrees C as well as show reduced growth at the permissive temperature of 30 degrees C. While the ffh mutant is defective in insertion of inner membrane proteins, the export of proteins with cleavable signal sequences is not impaired. The mutant also shows elevated expression of heat shock proteins and accumulates insoluble proteins, especially at 42 degrees C. It was further observed that the temperature sensitivity of the ffh mutant was suppressed by overproduction of 4.5S RNA, the RNA component of the bacterial SRP, by stabilizing the thermolabile protein. Collectively, these results are consistent with a model in which Ffh is required only for localization of proteins integral to the cytoplasmic membrane and suggest new genetic approaches to the study of how the structure of the SRP contributes to its function.     

Crystal structure of the ffh and EF-G binding sites in the conserved domain IV of Escherichia coli 4.5S RNA

BACKGROUND: Bacterial signal recognition particle (SRP), consisting of 4.5S RNA and Ffh protein, plays an essential role in targeting signal-peptide-containing proteins to the secretory apparatus in the cell membrane. The 4.5S RNA increases the affinity of Ffh for signal peptides and is essential for the interaction between SRP and its receptor, protein FtsY. The 4.5S RNA also interacts with elongation factor G (EF-G) in the ribosome and this interaction is required for efficient translation. RESULTS: We have determined by multiple anomalous dispersion (MAD) with Lu(3+) the 2.7 A crystal structure of a 4.5S RNA fragment containing binding sites for both Ffh and EF-G. This fragment consists of three helices connected by a symmetric and an asymmetric internal loop. In contrast to NMR-derived structures reported previously, the symmetric loop is entirely constituted by non-canonical base pairs. These pairs continuously stack and project unusual sets of hydrogen-bond donors and acceptors into the shallow minor groove. The structure can therefore be regarded as two double helical rods hinged by the asymmetric loop that protrudes from one strand. CONCLUSIONS: Based on our crystal structure and results of chemical protection experiments reported previously, we predicted that Ffh binds to the minor groove of the symmetric loop. An identical decanucleotide sequence is found in the EF-G binding sites of both 4.5S RNA and 23S rRNA. The decanucleotide structure in the 4.5S RNA and the ribosomal protein L11-RNA complex crystals suggests how 4.5S RNA and 23S rRNA might interact with EF-G and function in translating ribosomes.     

Cloning and characterization of a Bacillus subtilis gene encoding a homolog of the 54-kilodalton subunit of mammalian signal recognition particle and Escherichia coli Ffh.

By using a DNA fragment of Escherichia coli ffh as a probe, the Bacillus subtilis ffh gene was cloned. The complete nucleotide sequence of the cloned DNA revealed that it contained three open reading frames (ORFs). Their order in the region, given by the gene product, was suggested to be ORF1-Ffh-S16, according to their similarity to the gene products of E. coli, although ORF1 exhibited no significant identity with any other known proteins. The orf1 and ffh genes are organized into an operon. Genetic mapping of the ffh locus showed that the B. subtilis ffh gene is located near the pyr locus on the chromosome. The gene product of B. subtilis ffh shared 53.9 and 32.6% amino acid identity with E. coli Ffh and the canine 54-kDa subunit of signal recognition particle, respectively. Although there was low amino acid identity with the 54-kDa subunit of mammalian signal recognition particle, three GTP-binding motifs in the NH2-terminal half and amphipathic helical cores in the COOH-terminus were conserved. The depletion of ffh in B. subtilis led to growth arrest and drastic morphological changes. Furthermore, the translocation of beta-lactamase and alpha-amylase under the depleted condition was also defective.     

The signal recognition particle binds to protein L23 at the peptide exit of the Escherichia coli ribosome

The signal recognition particle (SRP) from Escherichia coli, composed of Ffh protein and 4.5S RNA, mediates membrane targeting of translating ribosomes displaying a signal or signal-anchor sequence. SRP binds at the peptide exit of the large ribosomal subunit. Structural details of the interaction are not known. Here, the position of Ffh or SRP on the ribosome was probed by using site-specific UV-induced crosslinking by p-azidophenacyl bromide (AzP) attached to a number of cysteine residues engineered into surface positions of Ffh. Efficient crosslinking to vacant ribosomes took place from two positions (AzP17 and AzP25) in the N domain of Ffh, both with Ffh and SRP. Both AzP17 and AzP25 were predominantly crosslinked to ribosomal protein L23 that is located at the peptide exit of the 50S subunit. The SRP receptor, FtsY, did not change the crosslink pattern, whereas the presence of a nascent signal peptide on the ribosome resulted in a second crosslink between Ffh(AzP17) and protein L23, indicating that binding to the nascent signal peptide induced a slightly different arrangement of SRP on the ribosome. These results indicate a model of the topographical arrangement of SRP at the peptide exit of the 50S ribosomal subunit.     

The Alu domain homolog of the yeast signal recognition particle consists of an Srp14p homodimer and a yeast-specific RNA structure

The mammalian Alu domain of the signal recognition particle (SRP) consists of a heterodimeric protein SRP9/14 and the Alu portion of 7SL RNA and comprises the elongation arrest function of the particle. To define the domain in Saccharomyces cerevisiae SRP that is homologous to the mammalian Alu domain [Alu domain homolog in yeast (Adhy)], we examined the assembly of a yeast protein homologous to mammalian SRP14 (Srp14p) and scR1 RNA. Srp14p binds as a homodimeric complex to the 5' sequences of scR1 RNA. Its minimal binding site consists of 99 nt. (Adhy RNA), comprising a short hairpin structure followed by an extended stem. As in mammalian SRP9/14, the motif UGUAAU present in most SRP RNAs is part of the Srp14p binding sites as shown by footprint and mutagenesis studies. In addition, certain basic amino acid residues conserved between mammalian SRP14 and Srp14p are essential for RNA binding in both proteins. These findings confirm the common ancestry of the yeast and the mammalian components and indicate that Srp14p together with Adhy RNA represents the Alu domain homolog in yeast SRP that may comprise its elongation arrest function. Despite the similarities, Srp14p selectively recognizes only scR1 RNA, revealing substantial changes in RNA-protein recognition as well as in the overall structure of the complex. The alignment of the three yeast SRP RNAs known to date suggests a common structure for the putative elongation arrest domain of all three organisms.