Trypsin-modified Elongation Factor Tu (EF-Tu)Trypsin-modified Elongation Factor Tu (EF-Tu)

spinqualitylabelsall models PDB ID 2hdn Show:Asymmetric Unit Biological Assembly Drag the structure with the mouse to rotate   Export Animated Image
2hdn, resolution 2.80Å ()
Ligands:	, ,
Related:	2hcj
Structural annotation: Resources: InterPro : Ipr000795, Ipr004161, Ipr009000, Ipr004160, Ipr005225, Ipr004541, Ipr009001 Pfam : PF00009, PF03144, PF03143 UniProt : P0A6N1, Q83JC4
Functional annotation: Cellular component: membrane cytoplasm intracellular Biological process: translational elongation translation response to antibiotic Molecular function: nucleotide binding GTP binding protein binding translation elongation factor activity GTPase activity
Evolutionary conservation: Toggle Conservation Colors: Rows = identical sequences: Further Information: Caveats, Explanation, Complete Results at ConSurfDB
Resources:	FirstGlance, OCA, PDBsum, RCSB
Coordinates:	save as pdb, mmCIF, xml

General InformationGeneral Information

Trypsin-modified Elongation Factor thermo unstable (Tm-EF-Tu) is a prokaryotic transcription factor and GTP_ase, which regulates the movement of aminoacyl tRNA into a free site of a ribosome ^[1]. This protein has been studied in Escherichia coli (E. coli) and shows modification at three regions of the native peptide sequence; Arg-44, Arg-58, and Lys-56 ^[2]. Tm-EF-Tu tends to form a complex with the antibiotic tetracycline The resulting complex, Tm-EF-Tu-MgGDP, is composed of three domains and can be found in two crystalline structures ^[1].

StructureStructure

EF-Tu is a 12 chain structure in E. coli that tends to form a complex with the antibiotic tetracycline. Two different crystalline forms of the structure have been identified ^[1]. In the first crystal form, P₂₁, six copies of EF-Tu, GDP, tetracycline, and Mg²⁺ are arranged as dimers in an asymmetric manner ^[1]. An alternative form, P₄₃₂₁₂, is a monomeric, asymmetric unit with tetracycline complexes within the structure ^[1].

The P₂₁ structure forms a final complex consisting of six EF-Tu proteins, GDP, tetracycline, Mg²⁺, and 244 water molecules^[1]. The final complex of the P₄₃₂₁₂ crystal is composed of one protein copy, GDP, tetracycline, Mg²⁺, SO₂, glyoxylic acid, 3 Na⁺ and 160 H2O molecules ^[1]. In either case, the binding site for tetracycline is located in domain one, allowing it to interact with the major functional groups. Residues Tet O11 and Tet O12 of tetracycline co-ordinate Mg^2+[1]. There is also an interaction with the phosphate of the GDP and the residues Thr25 and Asp80 ^[1]. When bound, tetracycline replaces two well ordered water molecules from the EF-Tu structure.

There are three domains making up the EF-Tu molecule. Domain 1 is the guanine-nucleotide domain made from residues 8-40 and 59-204 ^[1]. Domain 2 is composed on residues 205-298 and domain 3 of residues 299-393 ^[1]. The fragments 8-44 and 59-393 are associated through non-covalent interactions and retain their native conformation, with the exception of residues 40-44 and 260-263 ^[1].

In domain 1 of EF-Tu, the protein-protein interactions involved four anti-parallel β-sheet hydrogen bonds between residues 64-66’ and 66-64’ (where the primes indicate non-crystallographically related residues)^[1]. Hydrogen bonds are also formed between the side chain of Asn63 and Glu68 as well as the main chain residues Ile62 with His66 and Glu60 ^[1].

In the second domain, residues 216,259,261,262, and 287 form two electrostatic interactions and six hydrogen bonds form with 216’, 261’, 262’, and 283’ to create a mobile loop from Arg262-Leu264 ^[1]. There are also stabilizing van der Waals interactions between the dimers. The tetracycline rings are nearly parallel to the dimer unit creating a hydrophobic environment. Each dimer of the Tm-EF-Tu-MgGDP complex is related to another pair by a pseudo-twofold axis with minimal intermolecular interactions ^[1]. Conformations of the protein complexed to tetracycline to not appear to differ from those which are non-complexed, suggesting little effect on the proteins structure ^[1].

Residues 40-44 and 260-263 are disordered when EF-Tu-MgGDP undergoes trypsin modification ^[1]. In addition, residues 1-7 and 45-58 are removed, the latter of which makes up the Switch I loop ^[1]. The Switch I loop conformation that is regulated by the binding of MgGDP and MgGTP. The presence of tetracycline may affect the conversion rate between the EF-Tu-MgGTP and EF-Tu-MgGDP conformations, affecting the interaction with the ribosome ^[1]. In this way, tetracycline may act to inhibit protein synthesis by preventing the binding of aminoacyl-tRNA to the A site of the ribosome.

FunctionFunction

EF-Tu binds an aminoacylated tRNA molecule and allows entry into the ribosome ^[1]. The tRNA anticodon associates with the mRNA codon in the A site of the ribosome. If the pairing is incorrect, the tRNA will likely leave the ribosome. However, if a correct pairing has occurred, EF-Tu hydrolyzes guanosine triphosphate (GTP) to the diphosphate form (GDP)^[1]. This hydrolysis results in a change in conformation of the tRNA, which allows it to dissociate from EF-Tu. The dissociation allows the tRNA molecule to then completely interact with the A site of the ribosome the tRNA can be transferred to the growing peptide chain via covalent bond formation ^[1]. In this way, EF-Tu is a vital component in the propcess of lengthening a peptide during protein synthesis.

EF-Tu has also been shown to play a role in the inhibition of tetracycline during protein synthesis in many different organisms ^[1]. EF-Tu may be a target protein of tetracycline, although this idea has commonly been dismissed because the ribosome may be inhibited in the presence of the antibiotic ^[1]. Now however, it has been demonstated that Tm-EF-Tu-MgGDP is bound in a complex during crystallization, binding the the GTPase active site. This information could be useful for developing mechanisms of counteracting resistance to this particular antibiotic ^[1].

ReferencesReferences