PDBsum entry 1d2e

RNA binding protein

PDB id

1d2e

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Contents

			Protein chains

					397 a.a. *

			Ligands

					GDP ×4

			Metals

					_MG ×4

			Waters ×1201

* Residue conservation analysis

PDB id:

1d2e

Links
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Name:

RNA binding protein

Title:

Crystal structure of mitochondrial ef-tu in complex with gdp

Structure:

Elongation factor tu (ef-tu). Chain: a, b, c, d

Source:

Bos taurus. Cattle. Organism_taxid: 9913. Organ: liver. Organelle: mitochondria

Resolution:

1.94Å

R-factor:

0.237

R-free:

0.257

Authors:

G.R.Andersen,S.Thirup,L.L.Spremulli,J.Nyborg

Key ref:

G.R.Andersen et al. (2000). High resolution crystal structure of bovine mitochondrial EF-Tu in complex with GDP. J Mol Biol, 297, 421-436. PubMed id: 10715211 DOI: 10.1006/jmbi.2000.3564

Date:

23-Sep-99

Release date:

28-Sep-99

PROCHECK

	Headers

	References

Protein chains

P49410 (EFTU_BOVIN) - Elongation factor Tu, mitochondrial from Bos taurus

Seq: Struc:					452 a.a. 397 a.a.

Key:

PfamA domain

Secondary structure

CATH domain



		Enzyme reactions

Enzyme class:

E.C.?

[IntEnz] [ExPASy] [KEGG] [BRENDA]

DOI no: 10.1006/jmbi.2000.3564	J Mol Biol 297:421-436 (2000)
PubMed id: 10715211

High resolution crystal structure of bovine mitochondrial EF-Tu in complex with GDP.
G.R.Andersen, S.Thirup, L.L.Spremulli, J.Nyborg.

ABSTRACT

The crystal structure of bovine mitochondrial elongation factor Tu (EF-Tu) in complex with GDP has been determined at a resolution of 1. 94 A. The structure is similar to that of EF-Tu:GDP from Escherichia coli and Thermus aquaticus, but the orientation of the GDP-binding domain 1 is changed relative to domains 2 and 3. Sixteen conserved water molecules common to EF-Tu and other G-proteins in the GDP-binding site are described. These water molecules create a network linking separated parts of the binding pocket. Mitochondrial EF-Tu binds nucleotides less tightly than prokaryotic EF-Tu possibly due to an increased mobility in regions close to the GDP-binding site. The C-terminal extension of mitochondrial EF-Tu has structural similarities with DNA recognising zinc fingers suggesting that the extension may be involved in recognition of RNA.

Selected figure(s)



	Figure 1. Figure 1. (a) Cartoon of EF-Tum with helices (red) and strands (cyan). The protein is organized in three struc- tural domains as known from EF-Tut and EF-Tue. Domain 1 (right) contains the binding site for GDP and Mg 2+ and comprises the N-terminal half of the protein. Helices B, C and D are located to the left of the central b-sheet and helices A, E and F to the right. The C-term- inal half is folded into two structural domains 2 (top left) and 3 (bottom left). In contrast to EF-Tut and EF- Tue, EF-Tum contains a small helix at the C-terminal of domain 3 (bottom left). The definition of the secondary structure is given in Figure 2 and the topology is described in Figure 2 of Song et al. (1999). (b) Density around the GDP binding site in the final sigmaA- weighted 3Fo - 2Fc map contoured at two standard deviations. The guanine ring is inserted between K182 and L221. D184 (right) forms two hydrogen bonds to N1 and N2 of the base. Water molecules (red spheres). Figure 3(c) shows this region in more detail.		Figure 4. Figure 4. (a) The GDP binding site of EF-Tum (molecule A). The Mg 2+ and its six ligands (thin red lines). Besides the four water molecules coordinating the Mg 2+ , 12 additional water molecules are shown. The waters are roughly organized in two clusters, one around the Mg 2+ and the phosphate groups, and the other around the ribose ring of the GDP. (b) The Mg 2+ binding site with selected distances shorter than 3.1 Å . The six Mg-ligand distances (red), others (blue). Interatomic distances between w1-w4 are not shown, but have an average value of 2.96 Å . The water molecule w8 is displaced slightly away from the typical position due to the presence of Y92-OH. Except for w8, all other water molecules have at least two possible hydrogen bond donors/acceptors. The water molecules bridge the different parts of the binding site, e.g. w7 bridges the NH+3 group of K70 with Omc of P128. (c) Binding site for the ribose and guanine ring of GDP. The guanine ring is inserted between the aliphatic part of K182 and L221. The NH+3 group of K70 forms hydrogen bonds to w9 and w10, and Omc of D67, instead of hydrogen bonding to the endocyclic O of the ribose. As for the Mg 2+ -binding site, the well ordered water molecules connect separated parts of the binding site. The water molecules w9, w10, w11 and w13 connect D155, K182, the ribose ring of GDP and T72. (d) The environment of the NKXD sequence with helix D (right) and the loop connecting helices E -F (top). Compared to EF-Tue (yellow), EF-Tum (gray) contains two extra residues, while EF-Tut contains eight extra residues. The loop connecting helices D-E in EF-Tue and EF-Tut contains an arginine residue, forming a saltbridge to helix D, R172e-E150e, which is absent in EF-Tum.

Figures were selected by an automated process.

Literature references that cite this PDB file's key reference

PubMed id

Reference

19151083

C.Takemoto, L.L.Spremulli, L.A.Benkowski, T.Ueda, T.Yokogawa, and K.Watanabe (2009).
Unconventional decoding of the AUA codon as methionine by mitochondrial tRNAMet with the anticodon f5CAU as revealed with a mitochondrial in vitro translation system.

Nucleic Acids Res, 37, 1616-1627.

19546194

S.Balasubramanian, T.R.Kannan, P.J.Hart, and J.B.Baseman (2009).
Amino acid changes in elongation factor Tu of Mycoplasma pneumoniae and Mycoplasma genitalium influence fibronectin binding.

Infect Immun, 77, 3533-3541.

19622744

T.S.Guu, Z.Liu, Q.Ye, D.A.Mata, K.Li, C.Yin, J.Zhang, and Y.J.Tao (2009).
Structure of the hepatitis E virus-like particle suggests mechanisms for virus assembly and receptor binding.

Proc Natl Acad Sci U S A, 106, 12992-12997.

PDB code:

3hag

18275820

M.Topf, K.Lasker, B.Webb, H.Wolfson, W.Chiu, and A.Sali (2008).
Protein structure fitting and refinement guided by cryo-EM density.

Structure, 16, 295-307.

17327676

R.Fukunaga, and S.Yokoyama (2007).
Structure of the AlaX-M trans-editing enzyme from Pyrococcus horikoshii.

Acta Crystallogr D Biol Crystallogr, 63, 390-400.

PDB code:

2e1b

17012285

M.Arita, T.Suematsu, A.Osanai, T.Inaba, H.Kamiya, K.Kita, M.Sisido, Y.Watanabe, and T.Ohtsuki (2006).
An evolutionary 'intermediate state' of mitochondrial translation systems found in Trichinella species of parasitic nematodes: co-evolution of tRNA and EF-Tu.

Nucleic Acids Res, 34, 5291-5299.

16533850

S.Melchionna, R.Sinibaldi, and G.Briganti (2006).
Explanation of the stability of thermophilic proteins based on unique micromorphology.

Biophys J, 90, 4204-4212.

15557323

M.G.Jeppesen, T.Navratil, L.L.Spremulli, and J.Nyborg (2005).
Crystal structure of the bovine mitochondrial elongation factor Tu.Ts complex.

J Biol Chem, 280, 5071-5081.

PDB code:

1xb2

15695360

S.Chiron, A.Suleau, and N.Bonnefoy (2005).
Mitochondrial translation: elongation factor tu is essential in fission yeast and depends on an exchange factor conserved in humans but not in budding yeast.

Genetics, 169, 1891-1901.

16113240

T.Suematsu, A.Sato, M.Sakurai, K.Watanabe, and T.Ohtsuki (2005).
A unique tRNA recognition mechanism of Caenorhabditis elegans mitochondrial EF-Tu2.

Nucleic Acids Res, 33, 4683-4691.

14688270

A.Roll-Mecak, P.Alone, C.Cao, T.E.Dever, and S.K.Burley (2004).
X-ray structure of translation initiation factor eIF2gamma: implications for tRNA and eIF2alpha binding.

J Biol Chem, 279, 10634-10642.

PDB code:

1s0u

14978301

C.Blouin, D.Butt, and A.J.Roger (2004).
Rapid evolution in conformational space: a study of loop regions in a ubiquitous GTP binding domain.

Protein Sci, 13, 608-616.

15005711

N.Hino, T.Suzuki, T.Yasukawa, K.Seio, K.Watanabe, and T.Ueda (2004).
The pathogenic A4269G mutation in human mitochondrial tRNA(Ile) alters the T-stem structure and decreases the binding affinity for elongation factor Tu.

Genes Cells, 9, 243-252.

15169320

S.Melchionna, G.Briganti, P.Londei, and P.Cammarano (2004).
Water induced effects on the thermal response of a protein.

Phys Rev Lett, 92, 158101.

14622005

T.Navratil, and L.L.Spremulli (2003).
Effects of mutagenesis of Gln97 in the switch II region of Escherichia coli elongation factor Tu on its interaction with guanine nucleotides, elongation factor Ts, and aminoacyl-tRNA.

Biochemistry, 42, 13587-13595.

12220486

M.Kjeldgaard (2002).
Another worm in translation.

Structure, 10, 1154-1155.

12145639

T.Ohtsuki, A.Sato, Y.Watanabe, and K.Watanabe (2002).
A unique serine-specific elongation factor Tu found in nematode mitochondria.

Nat Struct Biol, 9, 669-673.

12762045

G.R.Andersen, and J.Nyborg (2001).
Structural studies of eukaryotic elongation factors.

Cold Spring Harb Symp Quant Biol, 66, 425-437.

11574461

L.Vitagliano, M.Masullo, F.Sica, A.Zagari, and V.Bocchini (2001).
The crystal structure of Sulfolobus solfataricus elongation factor 1alpha in complex with GDP reveals novel features in nucleotide binding and exchange.

EMBO J, 20, 5305-5311.

PDB code:

1jny

11737263

T.Hanada, T.Suzuki, T.Yokogawa, C.Takemoto-Hori, M.Sprinzl, and K.Watanabe (2001).
Translation ability of mitochondrial tRNAsSer with unusual secondary structures in an in vitro translation system of bovine mitochondria.

Genes Cells, 6, 1019-1030.

11106763

G.R.Andersen, L.Pedersen, L.Valente, I.Chatterjee, T.G.Kinzy, M.Kjeldgaard, and J.Nyborg (2000).
Structural basis for nucleotide exchange and competition with tRNA in the yeast elongation factor complex eEF1A:eEF1Balpha.

Mol Cell, 6, 1261-1266.

PDB code:

1f60

11112539

M.Masullo, P.Arcari, B.de Paola, A.Parmeggiani, and V.Bocchini (2000).
Psychrophilic elongation factor Tu from the antarctic Moraxella sp. Tac II 25: biochemical characterization and cloning of the encoding gene.

Biochemistry, 39, 15531-15539.

11045624

Y.C.Cai, J.M.Bullard, N.L.Thompson, and L.L.Spremulli (2000).
Interaction of mammalian mitochondrial elongation factor EF-Tu with guanine nucleotides.

Protein Sci, 9, 1791-1800.

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.