PDBsum entry 2q6h

Transport protein

PDB id

2q6h

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Contents

			Protein chain

					512 a.a. *

			Ligands

					BOG ×5


					LEU


					CXX ×2

			Metals

					_NA ×2

			Waters ×134

* Residue conservation analysis

PDB id:

2q6h

Links

Name:

Transport protein

Title:

Crystal structure analysis of leut complexed with l-leucine, sodium, and clomipramine

Structure:

Transporter. Chain: a. Engineered: yes

Source:

Aquifex aeolicus. Organism_taxid: 224324. Strain: vf5. Gene: snf. Expressed in: escherichia coli. Expression_system_taxid: 562.

Resolution:

1.85Å

R-factor:

0.198

R-free:

0.218

Authors:

S.K.Singh,A.Yamashita,E.Gouaux

Key ref:

S.K.Singh et al. (2007). Antidepressant binding site in a bacterial homologue of neurotransmitter transporters. Nature, 448, 952-956. PubMed id: 17687333 DOI: 10.1038/nature06038

Date:

05-Jun-07

Release date:

21-Aug-07

PROCHECK

	Headers

	References

Protein chain

O67854 (O67854_AQUAE) - Na(+):neurotransmitter symporter (Snf family) from Aquifex aeolicus (strain VF5)

Seq: Struc:					513 a.a. 512 a.a.

Key:

PfamA domain

Secondary structure



		Enzyme reactions

Enzyme class:

E.C.?

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

DOI no: 10.1038/nature06038	Nature 448:952-956 (2007)
PubMed id: 17687333

Antidepressant binding site in a bacterial homologue of neurotransmitter transporters.
S.K.Singh, A.Yamashita, E.Gouaux.

ABSTRACT

Sodium-coupled transporters are ubiquitous pumps that harness pre-existing sodium gradients to catalyse the thermodynamically unfavourable uptake of essential nutrients, neurotransmitters and inorganic ions across the lipid bilayer. Dysfunction of these integral membrane proteins has been implicated in glucose/galactose malabsorption, congenital hypothyroidism, Bartter's syndrome, epilepsy, depression, autism and obsessive-compulsive disorder. Sodium-coupled transporters are blocked by a number of therapeutically important compounds, including diuretics, anticonvulsants and antidepressants, many of which have also become indispensable tools in biochemical experiments designed to probe antagonist binding sites and to elucidate transport mechanisms. Steady-state kinetic data have revealed that both competitive and noncompetitive modes of inhibition exist. Antagonist dissociation experiments on the serotonin transporter (SERT) have also unveiled the existence of a low-affinity allosteric site that slows the dissociation of inhibitors from a separate high-affinity site. Despite these strides, atomic-level insights into inhibitor action have remained elusive. Here we screen a panel of molecules for their ability to inhibit LeuT, a prokaryotic homologue of mammalian neurotransmitter sodium symporters, and show that the tricyclic antidepressant (TCA) clomipramine noncompetitively inhibits substrate uptake. Cocrystal structures show that clomipramine, along with two other TCAs, binds in an extracellular-facing vestibule about 11 A above the substrate and two sodium ions, apparently stabilizing the extracellular gate in a closed conformation. Off-rate assays establish that clomipramine reduces the rate at which leucine dissociates from LeuT and reinforce our contention that this TCA inhibits LeuT by slowing substrate release. Our results represent a molecular view into noncompetitive inhibition of a sodium-coupled transporter and define principles for the rational design of new inhibitors.

Selected figure(s)



	Figure 2. Figure 2: TCAs bind in the putative permeation pathway of LeuT. F[o]–F[c] simulated annealing omit maps, both contoured at 3.0 , of clomipramine (a) and imipramine (b), in which the TCA was omitted from the simulated annealing run and subsequent phase calculation. The chlorine atom of clomipramine is green. c, LeuT tilted 15° from the membrane plane to illustrate the binding sites of clomipramine and leucine, both depicted in space-filling representation. Helices whose residues interact with clomipramine are coloured. d, Electrostatic properties of the LeuT extracellular-facing vestibule, with clomipramine (yellow) cradled in the negatively charged crevice. Electrostatic potential isocontours were set at +7 kT e^–1 (blue) and –7 kT e^–1 (red). EL4 is tinted green. To make clomipramine more visible, LeuT has been tilted an additional 5° towards the reader from the view in c ( 20° from the membrane plane).		Figure 3. Figure 3: Clomipramine-binding site. a, Stereo view, with clomipramine and leucine carbon atoms depicted in yellow, sodium ions in purple and two water molecules in red. Residues whose interactions with clomipramine are hydrophobic, polar (Q34) or ionic (D401) are coloured grey, orange and pink, respectively. Atoms depicted as spheres interact through either a hydrogen bond or a salt bridge. b, F[o]–F[c] simulated annealing omit map, contoured at 3.0 , of D404 and R30, depicting the direct salt bridge between the guanidium of R30 and the carboxylate of D404, with displacement of two water molecules (compare to overlay in d). Distances (Å) are shown along dashed lines. c, F[o]–F[c] simulated annealing omit map, contoured at 3.0 , of the tip of EL4 (residues A317–N321), illustrating the movement 'up' of A319 in the LeuT–clomipramine crystal structure (compare to overlay in d). d, Same view as in a with residues from the original LeuT structure (PDB ID 2A65) overlaid (in green with two water molecules between D404 and R30 in cyan) onto those from the LeuT–clomipramine crystal structure (in pink with the two displaced waters in red and labelled as H[2]O (CMI)). e, CPK rendering of clomipramine, R30 and F253 illustrating how the positively charged guanidium group is sandwiched between the aromatic rings of clomipramine and F253.

Figures were selected by an automated process.

Literature references that cite this PDB file's key reference

PubMed id

Reference

22301872

H.H.Lim, and C.Miller (2012).
It takes two to transport, or is it one?

Nat Struct Mol Biol, 19, 129-130.

22230955

H.Krishnamurthy, and E.Gouaux (2012).
X-ray structures of LeuT in substrate-free outward-open and apo inward-open states.

Nature, 481, 469-474.

PDB codes:

3tt1 3tt3 3tu0

22245965

H.Wang, J.Elferich, and E.Gouaux (2012).
Structures of LeuT in bicelles define conformation and substrate binding in a membrane-like context.

Nat Struct Mol Biol, 19, 212-219.

PDB codes:

3usg 3usi 3usj 3usk 3usl 3usm 3uso 3usp

22245968

M.Quick, L.Shi, B.Zehnpfennig, H.Weinstein, and J.A.Javitch (2012).
Experimental conditions can obscure the second high-affinity site in LeuT.

Nat Struct Mol Biol, 19, 207-211.

20816875

H.Bisgaard, M.A.Larsen, S.Mazier, T.Beuming, A.H.Newman, H.Weinstein, L.Shi, C.J.Loland, and U.Gether (2011).
The binding sites for benztropines and dopamine in the dopamine transporter overlap.

Neuropharmacology, 60, 182-190.

21161089

J.DeChancie, I.H.Shrivastava, and I.Bahar (2011).
The mechanism of substrate release by the aspartate transporter GltPh: insights from simulations.

Mol Biosyst, 7, 832-842.

21516104

Y.Zhao, D.S.Terry, L.Shi, M.Quick, H.Weinstein, S.C.Blanchard, and J.A.Javitch (2011).
Substrate-modulated gating dynamics in a Na+-coupled neurotransmitter transporter homologue.

Nature, 474, 109-113.

20739005

A.Nyola, N.K.Karpowich, J.Zhen, J.Marden, M.E.Reith, and D.N.Wang (2010).
Substrate and drug binding sites in LeuT.

Curr Opin Struct Biol, 20, 415-422.

20052679

A.Schlessinger, P.Matsson, J.E.Shima, U.Pieper, S.W.Yee, L.Kelly, L.Apeltsin, R.M.Stroud, T.E.Ferrin, K.M.Giacomini, and A.Sali (2010).
Comparison of human solute carriers.

Protein Sci, 19, 412-428.

21179170

C.L.Piscitelli, H.Krishnamurthy, and E.Gouaux (2010).
Neurotransmitter/sodium symporter orthologue LeuT has a single high-affinity substrate site.

Nature, 468, 1129-1132.

21131297

C.M.Anderson, P.D.Kidd, and S.Eskandari (2010).
GATMD: γ-aminobutyric acid transporter mutagenesis database.

Database (Oxford), 2010, baq028.

20562855

D.P.Claxton, M.Quick, L.Shi, F.D.de Carvalho, H.Weinstein, J.A.Javitch, and H.S.McHaourab (2010).
Ion/substrate-dependent conformational dynamics of a bacterial homolog of neurotransmitter:sodium symporters.

Nat Struct Mol Biol, 17, 822-829.

19892699

J.Andersen, L.Olsen, K.B.Hansen, O.Taboureau, F.S.Jørgensen, A.M.Jørgensen, B.Bang-Andersen, J.Egebjerg, K.Strømgaard, and A.S.Kristensen (2010).
Mutational mapping and modeling of the binding site for (S)-citalopram in the human serotonin transporter.

J Biol Chem, 285, 2051-2063.

20686672

J.Sun, S.Aluvila, R.Kotaria, J.A.Mayor, D.E.Walters, and R.S.Kaplan (2010).
Mitochondrial and Plasma Membrane Citrate Transporters: Discovery of Selective Inhibitors and Application to Structure/Function Analysis.

Mol Cell Pharmacol, 2, 101-110.

20067583

K.C.Schmitt, S.Mamidyala, S.Biswas, A.K.Dutta, and M.E.Reith (2010).
Bivalent phenethylamines as novel dopamine transporter inhibitors: evidence for multiple substrate-binding sites in a single transporter.

J Neurochem, 112, 1605-1618.

19826804

K.McLuskey, A.W.Roszak, Y.Zhu, and N.W.Isaacs (2010).
Crystal structures of all-alpha type membrane proteins.

Eur Biophys J, 39, 723-755.

20667175

K.R.Vinothkumar, and R.Henderson (2010).
Structures of membrane proteins.

Q Rev Biophys, 43, 65.

20352074

M.Indarte, Y.Liu, J.D.Madura, and C.K.Surratt (2010).
Receptor-Based Discovery of a Plasmalemmal Monoamine Transporter Inhibitor via High Throughput Docking and Pharmacophore Modeling.

ACS Chem Neurosci, 1, 223-233.

19899168

P.C.Gedeon, M.Indarte, C.K.Surratt, and J.D.Madura (2010).
Molecular dynamics of leucine and dopamine transporter proteins in a model cell membrane lipid bilayer.

Proteins, 78, 797-811.

20204338

R.J.Naftalin (2010).
Reassessment of models of facilitated transport and cotransport.

J Membr Biol, 234, 75.

20865057

S.A.Shaikh, and E.Tajkhorshid (2010).
Modeling and dynamics of the inward-facing state of a Na+/Cl- dependent neurotransmitter transporter homologue.

PLoS Comput Biol, 6, 0.

19948720

S.Sinning, M.Musgaard, M.Jensen, K.Severinsen, L.Celik, H.Koldsø, T.Meyer, M.Bols, H.H.Jensen, B.Schiøtt, and O.Wiborg (2010).
Binding and orientation of tricyclic antidepressants within the central substrate site of the human serotonin transporter.

J Biol Chem, 285, 8363-8374.

20090677

X.Gao, L.Zhou, X.Jiao, F.Lu, C.Yan, X.Zeng, J.Wang, and Y.Shi (2010).
Mechanism of substrate recognition and transport by an amino acid antiporter.

Nature, 463, 828-832.

PDB code:

3l1l

20463731

Y.Zhao, D.Terry, L.Shi, H.Weinstein, S.C.Blanchard, and J.A.Javitch (2010).
Single-molecule dynamics of gating in a neurotransmitter transporter homologue.

Nature, 465, 188-193.

19363027

A.K.Meinild, D.D.Loo, S.Skovstrup, U.Gether, and N.Macaulay (2009).
Elucidating Conformational Changes in the {gamma}-Aminobutyric Acid Transporter-1.

J Biol Chem, 284, 16226-16235.

19898476

A.Picollo, M.Malvezzi, J.C.Houtman, and A.Accardi (2009).
Basis of substrate binding and conservation of selectivity in the CLC family of channels and transporters.

Nat Struct Mol Biol, 16, 1294-1301.

19875446

A.R.Edington, A.A.McKinzie, A.J.Reynolds, M.Kassiou, R.M.Ryan, and R.J.Vandenberg (2009).
Extracellular loops 2 and 4 of GLYT2 are required for N-arachidonylglycine inhibition of glycine transport.

J Biol Chem, 284, 36424-36430.

19238460

A.W.Ravna, I.Sylte, and S.G.Dahl (2009).
Structure and localisation of drug binding sites on neurotransmitter transporters.

J Mol Model, 15, 1155-1164.

19134477

D.Hilger, Y.Polyhach, H.Jung, and G.Jeschke (2009).
Backbone Structure of Transmembrane Domain IX of the Na(+)/Proline Transporter PutP of Escherichia coli.

Biophys J, 96, 217-225.

18977735

E.Gouaux (2009).
Review. The molecular logic of sodium-coupled neurotransmitter transporters.

Philos Trans R Soc Lond B Biol Sci, 364, 149-154.

19458710

H.Krishnamurthy, C.L.Piscitelli, and E.Gouaux (2009).
Unlocking the molecular secrets of sodium-coupled transporters.

Nature, 459, 347-355.

19557250

J.Andersen, A.S.Kristensen, B.Bang-Andersen, and K.Strømgaard (2009).
Recent advances in the understanding of the interaction of antidepressant drugs with serotonin and norepinephrine transporters.

Chem Commun (Camb), (), 3677-3692.

19213730

J.Andersen, O.Taboureau, K.B.Hansen, L.Olsen, J.Egebjerg, K.Strømgaard, and A.S.Kristensen (2009).
Location of the antidepressant binding site in the serotonin transporter: IMPORTANCE OF SER-438 IN RECOGNITION OF CITALOPRAM AND TRICYCLIC ANTIDEPRESSANTS.

J Biol Chem, 284, 10276-10284.

19996368

L.R.Forrest, and G.Rudnick (2009).
The rocking bundle: a mechanism for ion-coupled solute flux by symmetrical transporters.

Physiology (Bethesda), 24, 377-386.

19478460

M.A.Kurian, J.Zhen, S.Y.Cheng, Y.Li, S.R.Mordekar, P.Jardine, N.V.Morgan, E.Meyer, L.Tee, S.Pasha, E.Wassmer, S.J.Heales, P.Gissen, M.E.Reith, and E.R.Maher (2009).
Homozygous loss-of-function mutations in the gene encoding the dopamine transporter are associated with infantile parkinsonism-dystonia.

J Clin Invest, 119, 1595-1603.

19307590

M.Quick, A.M.Winther, L.Shi, P.Nissen, H.Weinstein, and J.A.Javitch (2009).
Binding of an octylglucoside detergent molecule in the second substrate (S2) site of LeuT establishes an inhibitor-bound conformation.

Proc Natl Acad Sci U S A, 106, 5563-5568.

PDB codes:

3gjc 3gjd

19641126

S.Tavoulari, L.R.Forrest, and G.Rudnick (2009).
Fluoxetine (Prozac) binding to serotonin transporter is modulated by chloride and conformational changes.

J Neurosci, 29, 9635-9643.

19831380

X.Huang, H.H.Gu, and C.G.Zhan (2009).
Mechanism for cocaine blocking the transport of dopamine: insights from molecular modeling and dynamics simulations.

J Phys Chem B, 113, 15057-15066.

19519772

Y.J.Liang, J.Zhen, N.Chen, and M.E.Reith (2009).
Interaction of catechol and non-catechol substrates with externally or internally facing dopamine transporters.

J Neurochem, 109, 981-994.

19837674

Z.Tao, Y.W.Zhang, A.Agyiri, and G.Rudnick (2009).
Ligand effects on cross-linking support a conformational mechanism for serotonin transport.

J Biol Chem, 284, 33807-33814.

19430461

Z.Zhou, J.Zhen, N.K.Karpowich, C.J.Law, M.E.Reith, and D.N.Wang (2009).
Antidepressant specificity of serotonin transporter suggested by three LeuT-SSRI structures.

Nat Struct Mol Biol, 16, 652-657.

PDB codes:

3gwu 3gwv 3gww

18844672

A.M.Jørgensen, and S.Topiol (2008).
Driving forces for ligand migration in the leucine transporter.

Chem Biol Drug Des, 72, 265-272.

18381286

A.Rosenberg, and B.I.Kanner (2008).
The substrates of the gamma-aminobutyric acid transporter GAT-1 induce structural rearrangements around the interface of transmembrane domains 1 and 6.

J Biol Chem, 283, 14376-14383.

18668099

B.I.Kanner (2008).
Structural biology: It's not all in the family.

Nature, 454, 593-594.

18357440

B.Wenge, and H.Bönisch (2008).
N-Ethylmaleimide differentially inhibits substrate uptake by and ligand binding to the noradrenaline transporter.

Naunyn Schmiedebergs Arch Pharmacol, 377, 255-265.

18354055

C.C.Walline, D.E.Nichols, F.I.Carroll, and E.L.Barker (2008).
Comparative molecular field analysis using selectivity fields reveals residues in the third transmembrane helix of the serotonin transporter associated with substrate and antagonist recognition.

J Pharmacol Exp Ther, 325, 791-800.

18708457

D.A.Caplan, J.O.Subbotina, and S.Y.Noskov (2008).
Molecular mechanism of ion-ion and ion-substrate coupling in the Na+-dependent leucine transporter LeuT.

Biophys J, 95, 4613-4621.

18209729

D.L.Murphy, and K.P.Lesch (2008).
Targeting the murine serotonin transporter: insights into human neurobiology.

Nat Rev Neurosci, 9, 85-96.

18446902

H.Zettl, M.Schubert-Zsilavecz, and C.D.Siebert (2008).
[The medicinal chemistry of tricyclic antidepressives. Targets and stereochemistry]

Pharm Unserer Zeit, 37, 206-213.

18426798

J.Kniazeff, L.Shi, C.J.Loland, J.A.Javitch, H.Weinstein, and U.Gether (2008).
An intracellular interaction network regulates conformational transitions in the dopamine transporter.

J Biol Chem, 283, 17691-17701.

18462966

J.Lee, J.Chen, C.L.Brooks, and W.Im (2008).
Application of solid-state NMR restraint potentials in membrane protein modeling.

J Magn Reson, 193, 68-76.

18786172

K.C.Schmitt, J.Zhen, P.Kharkar, M.Mishra, N.Chen, A.K.Dutta, and M.E.Reith (2008).
Interaction of cocaine-, benztropine-, and GBR12909-like compounds with wild-type and mutant human dopamine transporters: molecular features that differentially determine antagonist-binding properties.

J Neurochem, 107, 928-940.

18266934

K.Severinsen, S.Sinning, H.K.Müller, and O.Wiborg (2008).
Characterisation of the zebrafish serotonin transporter functionally links TM10 to the ligand binding site.

J Neurochem, 105, 1794-1805.

18024499

L.Celik, B.Schiøtt, and E.Tajkhorshid (2008).
Substrate binding and formation of an occluded state in the leucine transporter.

Biophys J, 94, 1600-1612.

18647834

L.R.Forrest, Y.W.Zhang, M.T.Jacobs, J.Gesmonde, L.Xie, B.H.Honig, and G.Rudnick (2008).
Mechanism for alternating access in neurotransmitter transporters.

Proc Natl Acad Sci U S A, 105, 10338-10343.

18570870

L.Shi, M.Quick, Y.Zhao, H.Weinstein, and J.A.Javitch (2008).
The mechanism of a neurotransmitter:sodium symporter--inward release of Na+ and substrate is triggered by substrate in a second binding site.

Mol Cell, 30, 667-677.

18687947

N.K.Karpowich, and D.N.Wang (2008).
Structural biology. Symmetric transporters for asymmetric transport.

Science, 321, 781-782.

18227061

P.Courville, E.Urbankova, C.Rensing, R.Chaloupka, M.Quick, and M.F.Cellier (2008).
Solute carrier 11 cation symport requires distinct residues in transmembrane helices 1 and 6.

J Biol Chem, 283, 9651-9658.

19074341

S.K.Singh, C.L.Piscitelli, A.Yamashita, and E.Gouaux (2008).
A competitive inhibitor traps LeuT in an open-to-out conformation.

Science, 322, 1655-1661.

PDB codes:

3f3a 3f3c 3f3d 3f3e 3f48 3f4i 3f4j

18927357

S.Weyand, T.Shimamura, S.Yajima, S.Suzuki, O.Mirza, K.Krusong, E.P.Carpenter, N.G.Rutherford, J.M.Hadden, J.O'Reilly, P.Ma, M.Saidijam, S.G.Patching, R.J.Hope, H.T.Norbertczak, P.C.Roach, S.Iwata, P.J.Henderson, and A.D.Cameron (2008).
Structure and molecular mechanism of a nucleobase-cation-symport-1 family transporter.

Science, 322, 709-713.

PDB codes:

2jln 2jlo

18536011

S.Y.Noskov (2008).
Molecular mechanism of substrate specificity in the bacterial neutral amino acid transporter LeuT.

Proteins, 73, 851-863.

18568020

T.Beuming, J.Kniazeff, M.L.Bergmann, L.Shi, L.Gracia, K.Raniszewska, A.H.Newman, J.A.Javitch, H.Weinstein, U.Gether, and C.J.Loland (2008).
The binding sites for cocaine and dopamine in the dopamine transporter overlap.

Nat Neurosci, 11, 780-789.

18257176

S.Kitayama, and T.Dohi (2007).
[New development in study of neurotransmitter transporters]

Nippon Yakurigaku Zasshi, 130, 443.

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 codes are shown on the right.