PDBsum entry 1dk1

Ribosome

PDB id

1dk1

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Contents

			Protein chain

					86 a.a. *

			DNA/RNA

			Metals

					_NA ×2


					__K


					_MG ×9

			Waters ×25

* Residue conservation analysis

PDB id:

1dk1

Links

Name:

Ribosome

Title:

Detailed view of a key element of the ribosome assembly: crystal structure of the s15-rrna complex

Structure:

Rrna fragment. Chain: b. Engineered: yes. 30s ribosomal protein s15. Chain: a. Fragment: residues 2-87. Engineered: yes. Mutation: yes

Source:

Thermus thermophilus. Organism_taxid: 274. Expressed in: escherichia coli. Expression_system_taxid: 562. Expression_system_taxid: 562

Biol. unit:

Tetramer (from PQS)

Resolution:

2.80Å

R-factor:

0.213

R-free:

0.291

Authors:

A.Nikulin,A.Serganov,E.Ennifar,S.Tischenko,N.Nevskaya

Key ref:

A.Nikulin et al. (2000). Crystal structure of the S15-rRNA complex. Nat Struct Biol, 7, 273-277. PubMed id: 10742169 DOI: 10.1038/74028

Date:

06-Dec-99

Release date:

02-Apr-00

PROCHECK

	Headers

	References

Protein chain

P80378 (RS15_THETH) - Small ribosomal subunit protein uS15 from Thermus thermophilus

Seq: Struc:					89 a.a. 86 a.a.*

Key:

Secondary structure

CATH domain

* PDB and UniProt seqs differ at 2 residue positions (black crosses)

DNA/RNA chain

G-G-G-C-G-G-C-C-U-U-C-G-G-G-C-U-A-G-A-C-G-G-U-G-G-G-A-G-A-G-G-C-U-U-C-G-G-C-U- 57 bases

DOI no: 10.1038/74028	Nat Struct Biol 7:273-277 (2000)
PubMed id: 10742169

Crystal structure of the S15-rRNA complex.
A.Nikulin, A.Serganov, E.Ennifar, S.Tishchenko, N.Nevskaya, W.Shepard, C.Portier, M.Garber, B.Ehresmann, C.Ehresmann, S.Nikonov, P.Dumas.

ABSTRACT

In bacterial ribosomes, the small (30S) ribosomal subunit is composed of 16S rRNA and 21 distinct proteins. Ribosomal protein S15 is of particular interest because it binds primarily to 16S rRNA and is required for assembly of the small subunit and for intersubunit association, thus representing a key element in the assembly of a whole ribosome. Here we report the 2.8 ¿ resolution crystal structure of the highly conserved S15-rRNA complex. Protein S15 interacts in the minor groove with a G-U/G-C motif and a three-way junction. The latter is constrained by a conserved base triple and stacking interactions, and locked into place by magnesium ions and protein side chains, mainly through interactions with the unique three-dimensional geometry of the backbone. The present structure gives insights into the dual role of S15 in ribosome assembly and translational regulation.

Selected figure(s)



	Figure 1. Figure 1. Components of the S15−rRNA complex. a, Sequence of the Thermus thermophilus S15 protein^17. Colored residues are >80% conserved among 23 bacterial sequences (green) and additionally conserved among 55 homologous sequences from plastids, Archaea and Eukarya (red). Amino acids that interact with the rRNA fragment are underlined, and the four -helices deduced from the crystallographic structure are indicated. b, Schematic of tertiary structure of the 57 nt RNA corresponding to nucleotides 584−590/649−667/739−757 of E. coli rRNA as determined by comparative sequence analysis, and contacts with protein. Nucleotides within the UUCG loops capping helices 21 and 22 are in italics. Bases in red are >95% conserved in 6,000 prokaryotic sequences. Ribose rings in black are in a C2'-endo conformation, stacking is shown by hatched lines, and water molecules are indicated by W. Two alternative conformations of G664 are shown. Nucleotide C748 is not well defined. Conserved amino acid residues are colored as in (a), and their contacts with RNA backbone (phosphate group or 2'-OH) or functional groups of bases are indicated. Contacts are with amino acid side chains, with the single exception of Gly 22, which interacts through the backbone carbonyl.		Figure 4. Figure 4. Schematic representation of the recognition by S15 on rRNA, possible implications in 30S assembly and comparison with mRNA binding. S15 is schematized in green with its two RNA binding sites numbered 1 and 2. The first one recognizes a particular backbone geometry (the three-way junction in rRNA and the pseudoknot fold in mRNA). The second one recognizes an analogous G-U/G-C motif in both RNAs. In 16S rRNA, binding induces a conformational adjustment (widening of the deep groove), denoted by a red star, that is most likely required for subsequent 30S assembly steps (for example, S18 binding).

Figures were selected by an automated process.

Literature references that cite this PDB file's key reference

PubMed id

Reference

20085723

G.Chen, Z.J.Tan, and S.J.Chen (2010).
Salt-dependent folding energy landscape of RNA three-way junction.

Biophys J, 98, 111-120.

19864433

J.Zhang, J.Dundas, M.Lin, R.Chen, W.Wang, and J.Liang (2009).
Prediction of geometrically feasible three-dimensional structures of pseudoknotted RNA through free energy estimation.

RNA, 15, 2248-2263.

18388132

B.J.Kaspar, A.L.Bifano, and M.G.Caprara (2008).
A shared RNA-binding site in the Pet54 protein is required for translational activation and group I intron splicing in yeast mitochondria.

Nucleic Acids Res, 36, 2958-2968.

18560149

F.Pavelcik, and B.Schneider (2008).
Building of RNA and DNA double helices into electron density.

Acta Crystallogr D Biol Crystallogr, 64, 620-626.

18375510

S.Haider, G.N.Parkinson, and S.Neidle (2008).
Molecular dynamics and principal components analysis of human telomeric quadruplex multimers.

Biophys J, 95, 296-311.

17881366

A.A.Malygin, N.M.Parakhnevitch, A.V.Ivanov, I.C.Eperon, and G.G.Karpova (2007).
Human ribosomal protein S13 regulates expression of its own gene at the splicing step by a feedback mechanism.

Nucleic Acids Res, 35, 6414-6423.

17259282

T.Créty, and T.E.Malliavin (2007).
The conformational landscape of the ribosomal protein S15 and its influence on the protein interaction with 16S RNA.

Biophys J, 92, 2647-2665.

PDB code:

2fkx

16373494

A.Lescoute, and E.Westhof (2006).
Topology of three-way junctions in folded RNAs.

RNA, 12, 83-93.

16463312

A.Oleksy, A.Oleksi, A.G.Blanco, R.Boer, I.Usón, J.Aymamí, A.Rodger, M.J.Hannon, and M.Coll (2006).
Molecular recognition of a three-way DNA junction by a metallosupramolecular helicate.

Angew Chem Int Ed Engl, 45, 1227-1231.

PDB code:

2et0

16707260

R.T.Batey (2006).
Structures of regulatory elements in mRNAs.

Curr Opin Struct Biol, 16, 299-306.

16510980

R.Utsunomiya, K.Suto, D.Balasundaresan, A.Fukamizu, P.K.Kumar, and H.Mizuno (2006).
Structure of an RNA duplex r(GGCGBrUGCGCU)2 with terminal and internal tandem G.U base pairs.

Acta Crystallogr D Biol Crystallogr, 62, 331-338.

PDB code:

2ao5

17139090

S.Tishchenko, E.Nikonova, A.Nikulin, N.Nevskaya, S.Volchkov, W.Piendl, M.Garber, and S.Nikonov (2006).
Structure of the ribosomal protein L1-mRNA complex at 2.1 A resolution: common features of crystal packing of L1-RNA complexes.

Acta Crystallogr D Biol Crystallogr, 62, 1545-1554.

PDB code:

2hw8

16245373

B.D.Gooch, M.Krishnamurthy, M.Shadid, and P.A.Beal (2005).
Binding of helix-threading peptides to E. coli 16S ribosomal RNA and inhibition of the S15-16S complex.

Chembiochem, 6, 2247-2254.

16138302

H.M.Al-Hashimi (2005).
Dynamics-based amplification of RNA function and its characterization by using NMR spectroscopy.

Chembiochem, 6, 1506-1519.

14730351

K.L.Holmes, and G.M.Culver (2004).
Mapping structural differences between 30S ribosomal subunit assembly intermediates.

Nat Struct Mol Biol, 11, 179-186.

15007109

N.Carrasco, Y.Buzin, E.Tyson, E.Halpert, and Z.Huang (2004).
Selenium derivatization and crystallization of DNA and RNA oligonucleotides for X-ray crystallography using multiple anomalous dispersion.

Nucleic Acids Res, 32, 1638-1646.

15101974

N.Mathy, O.Pellegrini, A.Serganov, D.J.Patel, C.Ehresmann, and C.Portier (2004).
Specific recognition of rpsO mRNA and 16S rRNA by Escherichia coli ribosomal protein S15 relies on both mimicry and site differentiation.

Mol Microbiol, 52, 661-675.

15121895

P.S.Klosterman, D.K.Hendrix, M.Tamura, S.R.Holbrook, and S.E.Brenner (2004).
Three-dimensional motifs from the SCOR, structural classification of RNA database: extruded strands, base triples, tetraloops and U-turns.

Nucleic Acids Res, 32, 2342-2352.

15627386

S.V.Revtovich, A.D.Nikulin, and S.V.Nikonov (2004).
Role of N-terminal helix in interaction of ribosomal protein S15 with 16S rRNA.

Biochemistry (Mosc), 69, 1319-1323.

PDB code:

1kuq

12682022

A.Serganov, A.Polonskaia, B.Ehresmann, C.Ehresmann, and D.J.Patel (2003).
Ribosomal protein S15 represses its own translation via adaptation of an rRNA-like fold within its mRNA.

EMBO J, 22, 1898-1908.

12548626

G.M.Culver (2003).
Assembly of the 30S ribosomal subunit.

Biopolymers, 68, 234-249.

12840018

S.Raibaud, P.Vachette, M.Guillier, F.Allemand, C.Chiaruttini, and F.Dardel (2003).
How bacterial ribosomal protein L20 assembles with 23 S ribosomal RNA and its own messenger RNA.

J Biol Chem, 278, 36522-36530.

11953757

A.Torres-Larios, A.C.Dock-Bregeon, P.Romby, B.Rees, R.Sankaranarayanan, J.Caillet, M.Springer, C.Ehresmann, B.Ehresmann, and D.Moras (2002).
Structural basis of translational control by Escherichia coli threonyl tRNA synthetase.

Nat Struct Biol, 9, 343-347.

PDB code:

1kog

11929999

H.D.Kim, G.U.Nienhaus, T.Ha, J.W.Orr, J.R.Williamson, and S.Chu (2002).
Mg2+-dependent conformational change of RNA studied by fluorescence correlation and FRET on immobilized single molecules.

Proc Natl Acad Sci U S A, 99, 4284-4289.

11953318

Y.Yang, N.Declerck, X.Manival, S.Aymerich, and M.Kochoyan (2002).
Solution structure of the LicT-RNA antitermination complex: CAT clamping RAT.

EMBO J, 21, 1987-1997.

PDB code:

1l1c

11160889

F.Robert, and L.Brakier-Gingras (2001).
Ribosomal protein S7 from Escherichia coli uses the same determinants to bind 16S ribosomal RNA and its messenger RNA.

Nucleic Acids Res, 29, 677-682.

11891627

J.Sühnel (2001).
Beyond nucleic acid base pairs: from triads to heptads.

Biopolymers, 61, 32-51.

12762060

M.I.Recht, and J.R.Williamson (2001).
Thermodynamics and kinetics of central domain assembly.

Cold Spring Harb Symp Quant Biol, 66, 591-598.

10851193

A.D.Frankel (2000).
Fitting peptides into the RNA world.

Curr Opin Struct Biol, 10, 332-340.

11123902

E.J.Jeong, G.S.Hwang, K.H.Kim, M.J.Kim, S.Kim, and K.S.Kim (2000).
Structural analysis of multifunctional peptide motifs in human bifunctional tRNA synthetase: identification of RNA-binding residues and functional implications for tandem repeats.

Biochemistry, 39, 15775-15782.

PDB code:

1fyj

The most recent references are shown first. Citation data come partly from CiteXplore and partly from an automated harvesting procedure. Note that this is likely to be only a partial list as not all journals are covered by either method. However, we are continually building up the citation data so more and more references will be included with time. Where a reference describes a PDB structure, the PDB code is shown on the right.