Crystal structure of the phosphorolytic exoribonuclease RNase PH from Bacillus subtilis and implications for its quaternary structure and tRNA binding (original) (raw)
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Crystal Structure of RNase T, an Exoribonuclease Involved in tRNA Maturation and End Turnover
2007
The 3′ processing of most bacterial precursor tRNAs involves exonucleolytic trimming to yield a mature CCA end. This step is carried out by RNase T, a member of the large DEDD family of exonucleases. We report the crystal structures of RNase T from Escherichia coli and Pseudomonas aeruginosa, which show that this enzyme adopts an opposing dimeric arrangement, with the catalytic DEDD residues from one monomer closely juxtaposed with a large basic patch on the other monomer. This arrangement suggests that RNase T has to be dimeric for substrate specificity, and agrees very well with prior site-directed mutagenesis studies. The dimeric architecture of RNase T is very similar to the arrangement seen in oligoribonuclease, another bacterial DEDD family exoribonuclease. The catalytic residues in these two enzymes are organized very similarly to the catalytic domain of the third DEDD family exoribonuclease in E. coli, RNase D, which is monomeric.
Biochemistry, 2002
Ribonuclease P (RNase P) is a ribonucleoprotein enzyme that catalyzes the 5′ maturation of tRNA precursors. The bacterial RNase P holoenzyme is composed of a large, catalytic RNA and a small protein. Our previous work showed that Bacillus subtilis RNase P forms a specific "dimer" that contains two RNase P RNA and two RNase P protein subunits in the absence of substrate. We investigated the equilibrium and the structure of the dimeric and the monomeric holoenzyme in the absence and presence of substrates by synchrotron small-angle X-ray scattering, 3′ autolytic processing, and hydroxyl radical protection. In the absence of substrate, the dimer-monomer equilibrium is sensitive to monovalent ions and the total holoenzyme concentration. At 0.1 M NH 4 Cl, formation of the dimer is strongly favored, whereas at 0.8 M NH 4 Cl, the holoenzyme is a monomer. Primary hydroxyl radical protection in the dimer is located in the specificity domain, or domain I, of the RNase P RNA. The ES complex with a substrate containing a single tRNA is always monomeric. In contrast, the dominant ES complex with a substrate containing two tRNAs is dimeric at 0.1 M NH 4 Cl and monomeric at 0.8 M NH 4 Cl. Our results show that the B. subtilis holoenzyme can be a dimer and a monomer, and the fraction of the dimer is very sensitive to the environment. Under a variety of conditions, both the holoenzyme dimer and monomer can be present in significant amounts. Because the majority of tRNA genes are organized in large operons and because of the lack of RNase E in B. subtilis, a dimeric holoenzyme may be necessary to facilitate the processing of large precursor tRNA transcripts. Alternatively, the presence of two forms of the RNase P holoenzyme may be required for other yet unknown functions. . ‡ University of Chicago. § These authors contributed equally to this work. | Present address: Ambion, Inc., 2130 Woodward St., Austin, TX 78744.
Journal of Molecular Biology, 2009
Polynucleotide phosphorylase (PNPase) is a processive exoribonuclease that contributes to messenger RNA turnover and quality control of ribosomal RNA precursors in many bacterial species. In Escherichia coli, a proportion of the PNPase is recruited into a multi-enzyme assembly, known as the RNA degradosome, through an interaction with the scaffolding domain of the endoribonuclease RNase E. Here, we report crystal structures of E. coli PNPase complexed with the recognition site from RNase E and with manganese in the presence or in the absence of modified RNA. The homotrimeric PNPase engages RNase E on the periphery of its ring-like architecture through a pseudo-continuous anti-parallel β-sheet. A similar interaction pattern occurs in the structurally homologous human exosome between the Rrp45 and Rrp46 subunits. At the centre of the PNPase ring is a tapered channel with an adjustable aperture where RNA bases stack on phenylalanine side chains and trigger structural changes that propagate to the active sites. Manganese can substitute for magnesium as an essential cofactor for PNPase catalysis, and our crystal structure of the enzyme in complex with manganese suggests how the metal is positioned to stabilise the transition state. We discuss the implications of these structural observations for the catalytic mechanism of PNPase, its processive mode of action, and its assembly into the RNA degradosome.
Solution structure of RNase P RNA
RNA, 2011
The ribonucleoprotein enzyme ribonuclease P (RNase P) processes tRNAs by cleavage of precursor-tRNAs. RNase P is a ribozyme: The RNA component catalyzes tRNA maturation in vitro without proteins. Remarkable features of RNase P include multiple turnovers in vivo and ability to process diverse substrates. Structures of the bacterial RNase P, including full-length RNAs and a ternary complex with substrate, have been determined by X-ray crystallography. However, crystal structures of free RNA are significantly different from the ternary complex, and the solution structure of the RNA is unknown. Here, we report solution structures of three phylogenetically distinct bacterial RNase P RNAs from Escherichia coli, Agrobacterium tumefaciens, and Bacillus stearothermophilus, determined using small angle X-ray scattering (SAXS) and selective 29-hydroxyl acylation analyzed by primer extension (SHAPE) analysis. A combination of homology modeling, normal mode analysis, and molecular dynamics was used to refine the structural models against the empirical data of these RNAs in solution under the high ionic strength required for catalytic activity.
The Bacillus subtilis RNase P holoenzyme contains two RNase P RNA and two RNase P protein subunits
RNA, 2001
Ribonuclease P (RNase P) catalyzes the 59 maturation of precursor tRNA transcripts and, in bacteria, is composed of a catalytic RNA and a protein. We investigated the oligomerization state and the shape of the RNA alone and the holoenzyme of Bacillus subtilis RNase P in the absence of substrate by synchrotron small-angle X-ray scattering and affinity retention. The B. subtilis RNase P RNA alone is a monomer; however, the scattering profile changes upon the addition of monovalent ions, possibly suggesting different interdomain angles. To our surprise, the X-ray scattering data combined with the affinity retention results indicate that the holoenzyme contains two RNase P RNA and two RNase P protein molecules. We propose a structural model of the holoenzyme with a symmetrical arrangement of the two RNA subunits, consistent with the X-ray scattering results. This (P RNA) 2 (P protein) 2 complex likely binds substrate differently than the conventional (P RNA) 1 (P protein) 1 complex; therefore, the function of the B. subtilis RNase P holoenzyme may be more diverse than previously thought. These revisions to our knowledge of the RNase P holoenzyme suggest a more versatile role for proteins in ribonucleoprotein complexes. Abbreviations: Holoenzyme: the complex between P RNA and P protein at 1:1 molar ratio+ I 0 : scattering intensity at zero angle+ M1 RNA: The E. coli RNase P RNA+ P protein: The B. subtilis RNase P pro-tein+ P 32P : P RNA labeled with a-32 P-CTP+ P biotin : P RNA with a biotin covalently attached to its 39 end+ P RNA: The B. subtilis RNase P RNA+ SAXS: small-angle X-ray scattering+ RNA (2001), 7:233-241+ Cambridge University Press+ Printed in the USA+
Biochemistry, 2005
RNase P catalyzes the 5′ maturation of transfer RNA (tRNA). RNase P from Bacillus subtilis comprises a large RNA component (130 kDa, P RNA) and a small protein subunit (14 kDa, P protein). Although P RNA alone can efficiently catalyze the maturation reaction in vitro, P protein is strictly required under physiological conditions. We have used time-resolved fluorescence resonance energy transfer on a series of donor-labeled substrates and two acceptor-labeled P proteins to determine the conformation of the pre-tRNA 5′ leader relative to the protein in the holoenzyme-pre-tRNA complex. The resulting distance distribution measurements indicate that the leader binds to the holoenzyme in an extended conformation between nucleotides 3 and 7. The conformational mobility of nucleotides 5-8 in the leader is reduced, providing further evidence that these nucleotides interact with the holoenzyme. The increased fluorescence intensity and lifetime of the 5′-fluorescein label of these leaders indicate a more hydrophobic environment, consistent with the notion that such interactions occur with the central cleft of the P protein. Taken together, our data support a model where the P protein binds to the 5′ leader between the fourth and seventh nucleotides upstream of the cleavage site, extending the leader and decreasing its structural dynamics. Thus, P protein acts as a wedge to separate the 5′ from the 3′ terminus of the pre-tRNA and to position the cleavage site in the catalytic core. These results reveal a structural basis for the P protein dependent discrimination between precursor and mature tRNAs. tRNA; P protein, protein subunit of RNase P; P RNA, RNA subunit of RNase P; RNase P, ribonuclease P; TMR, tetramethylrhodamine; 5-TMRIA, tetramethylrhodamine-5-iodoacetamide; tr-FRET, time-resolved fluorescence resonance energy transfer; tRNA, transfer RNA.
Crystal structure of Bacillus subtilis S-adenosylmethionine:tRNA ribosyltransferase-isomerase
Biochemical and Biophysical Research Communications, 2006
The enzyme S-adenosylmethionine:tRNA ribosyltransferase-isomerase (QueA) is involved in the biosynthesis of the hypermodified tRNA nucleoside queuosine. It is unprecedented in nature as it uses the cofactor S-adenosylmethionine as the donor of a ribosyl group. We have determined the crystal structure of Bacillus subtilis QueA at a resolution of 2.9 Å . The structure reveals two domains representing a 6-stranded b-barrel and an aba-sandwich, respectively. All amino acid residues invariant in the QueA enzymes of known sequence cluster at the interface of the two domains indicating the localization of the substrate binding region and active center. Comparison of the B. subtilis QueA structure with the structure of QueA from Thermotoga maritima suggests a high domain flexibility of this enzyme.
The Crystal Structure of the Escherichia coli RNase E Apoprotein and a Mechanism for RNA Degradation
Structure, 2008
RNase E is an essential bacterial endoribonuclease involved in the turnover of messenger RNA and the maturation of structured RNA precursors in Escherichia coli. Here, we present the crystal structure of the E. coli RNase E catalytic domain in the apo-state at 3.3 Å . This structure indicates that, upon catalytic activation, RNase E undergoes a marked conformational change characterized by the coupled movement of two RNA-binding domains to organize the active site. The structural data suggest a mechanism of RNA recognition and cleavage that explains the enzyme's preference for substrates possessing a 5 0 -monophosphate and accounts for the protective effect of a triphosphate cap for most transcripts. Internal flexibility within the quaternary structure is also observed, a finding that has implications for recognition of structured RNA substrates and for the mechanism of internal entry for a subset of substrates that are cleaved without 5 0 -end requirements.