Stacking and T-shape Competition in Aromatic−Aromatic Amino Acid Interactions

Chelli, Riccardo; Gervasio, Francesco Luigi; Procacci, Piero; Schettino, Vincenzo

doi:10.1021/ja0121639

Cited by 248 publications

(243 citation statements)

References 38 publications

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“…Each docking run was ranked by energy (see key at bottom) and defined by the number of HERG Tyr652 or Phe656 aromatic ring atoms within 4.5 Å of a propafenone aromatic ring atom. A distance cutoff of 4.5 Å was taken to be the maximum separation of aromatic ring atoms that give rise to energetically favorable -stacking interactions (McGaughey et al, 1998;Chelli et al, 2002). The maximum number of ring atoms per Tyr652 or Phe656 was taken to be 11 (all ring carbons and ring-bound atoms ortho-, meta-, or para-to the carbon atom linking the ring to the ␤ carbon of the side chain).…”

Section: Discussionmentioning

confidence: 99%

The Low-Potency, Voltage-Dependent HERG Blocker Propafenone—Molecular Determinants and Drug Trapping

Witchel

Dempsey²,

Sessions³

et al. 2004

Mol Pharmacol

103

104

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The molecular determinants of high-affinity human ether-a-gogo-related gene (HERG) potassium channel blockade by methanesulfonanilides include two aromatic residues (Phe656 and Tyr652) on the inner helices (S6) and residues on the pore helices that face into the inner cavity, but determinants for lower-affinity HERG blockers may be different. In this study, alanine-substituted HERG channel mutants of inner cavity residues were expressed in Xenopus laevis oocytes and were used to characterize the HERG channel binding site of the antiarrhythmic propafenone. Propafenone's blockade of HERG was strongly dependent on residue Phe656 but was insensitive or weakly sensitive to mutation of Tyr652, Thr623, Ser624, Val625, Gly648, or Val659 and did not require functional inactivation. Homology models of HERG based on KcsA and MthK crystal structures, representing the closed and open forms of the channel, respectively, suggest propafenone is trapped in the inner cavity and is unable to interact exclusively with Phe656 in the closed state (whereas exclusive interactions between propafenone and Phe656 are found in the open-channel model). These findings are supported by very slow recovery of wild-type HERG channels from block at Ϫ120 mV, but extremely rapid recovery of D540K channels that reopen at this potential. The experiments and modeling suggest that the open-state propafenone binding-site may be formed by the Phe656 residues alone. The binding site for propafenone (which may involve -stacking interactions with two or more Phe656 side-chains) is either perturbed or becomes less accessible because of closed-channel gating. This provides further evidence for the existence of gating-induced changes in the spatial location of Phe656 side chains.Pharmacological blockade of the cardiac 'rapid' delayed rectifier potassium (K ϩ ) current (I Kr ) is commonly associated with a drug's propensity to cause acquired long QT syndrome (Roden et al., 1996). The ␣-subunit of the I Kr channel is encoded by HERG (Sanguinetti et al., 1995). Molecular determinants of this channel's blockade by the archetypal highpotency HERG blockers, the methanesulfonanilides, reside in the inner cavity of the channel pore and are composed of amino acid residues in the H5 loop (adjacent to the selectivity filter) and the S6 transmembrane domain (Lees-Miller et al., 2000;Mitcheson et al., 2000a). For all drugs tested, the molecular determinants include the amino acid residues Phe656 and Tyr652 [except for vesnarinone, which does not require Tyr652 (Kamiya et al., 2001), and fluvoxamine, which can block HERG when Phe656 or Tyr652 are mutated ], and in many cases the molecular determinants additionally include a combination of Thr623, Ser624, Val625, Gly648, and Val659. Most drugs with a high-affinity for HERG have been shown to have an open-state-dependent blockade mechanism (Spector et al., 1996). Open-state blockade of HERG may involve drug trapping [e.g., MK-499 (Mitcheson et al., 2000b)], a 'foot in the door' type mechanism [e.g., chloroquine (Sanch...

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Section: Discussionmentioning

confidence: 99%

The Low-Potency, Voltage-Dependent HERG Blocker Propafenone—Molecular Determinants and Drug Trapping

Witchel

Dempsey²,

Sessions³

et al. 2004

Mol Pharmacol

103

104

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“…-stacking), which supports transporter oligomerization and subsequent plasma membrane targeting. The phenol ring of tyrosine and the phenyl-side chain of phenylalanine have a propensity to interact with the planar hydrophobic moieties in a stacked or T-shaped conformation (26). These interactions between phenyls were shown to drive self-association of a transmembrane segment of IsK ion channel (27).…”

Section: Discussionmentioning

confidence: 99%

Oligomerization of the γ-Aminobutyric Acid Transporter-1 Is Driven by an Interplay of Polar and Hydrophobic Interactions in Transmembrane Helix II

Korkhov¹,

Farhan

Freissmuth

et al. 2004

Journal of Biological Chemistry

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The available evidence indicates that members of the neurotransmitter:sodium symporter family form constitutive oligomers. Their second transmembrane helix (TM2) contains a leucine heptad repeat proposed to be involved in oligomerization. In artificial transmembrane segments, interhelical interactions are stabilized by polar residues. We searched for these hydrogen bond donors in TM2 by mutating the five polar residues in TM2 of the ␥-aminobutyric acid transporter-1 (GAT1). We tested the ability of the resulting mutants to oligomerize by fluorescence microscopy, Foerster resonance energy transfer, and ␤-lactamase fragment complementation. Of all generated mutants, only Y86A-(but not Y86F-), E101A-, E101Q-, and E101D-GAT1 were judged by these criteria to be deficient in oligomerization and were retained intracellularly. , are conserved in related transporters from archaeae to humans; they are therefore likely to support oligomeric assembly in transporter orthologs and possibly other proteins with multiple transmembrane segments. ␥-Aminobutyric acid (GABA)1 -mediated inhibitory synaptic transmission is terminated by clearance of GABA from the synaptic cleft by high affinity uptake proteins. The four known GABA transporters (GAT1, BGT1 (betaine/GABA transporter), GAT2, and GAT3) belong to the neurotransmitter:sodium symporter (NSS) (1) family, which also includes carriers for dopamine, serotonin, glycine, etc. (2). All members of the family share sequence similarity, membrane topology, and common functional features (e.g. ion channel-like properties, sodium, and chloride) as transported cosubstrates and bidirectional transport of substrates. The interest in transporters of this family is motivated in part by their clinical relevance; they are targets for drugs of abuse (e.g. cocaine, ecstasy, and metamphetamine) and for therapeutic agents including antidepressants (amitryptiline, desipramine, citalopram, and paroxetine) and anticonvulsants (tiagabine), etc. (reviewed in Ref. 3).With the notable exception of the glycine transporter-1 (4), all members of the neurotransmitter transporter family that have so far been examined form oligomers (reviewed in Ref. 5). This is also true for GAT1, for which oligomers have been visualized in membranes of living cells by fluorescence resonance energy transfer (FRET) microscopy (6). The TM2 of GAT1 contains a leucine heptad repeat that seems to supports oligomer formation (7). The leucine heptad repeat in TM2 is a highly conserved feature throughout the NSS family. Consistent with this finding, TM2-mediated dimer formation was also suggested for dopamine transporter (8).By analogy with leucine zippers in soluble proteins, the stretch of leucine residues in the TM2 of GAT1 lines one side of a hypothetical ␣-helix. If this leucine heptad repeat is to serve as an interface between two transporter molecules, there must be additional forces that stabilize this arrangement. In aqueous solution, the hydrophobic leucine (or isoleucine) side chains are tightly packed to minimize the solve...

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“…16 Molecular dynamics simulation calculations on model compounds indicate that one of the optimal geometries for aromatic residue pairs is a T-shaped arrangement where the edge of one ring points to the face of the other. 18 In this configuration, hydrogen atoms with partial positive charges on the edge of one ring can interact favorably with the pi electrons or the partially negatively charged carbons of the other ring. In the scFv6H4 crystal structures, the aromatic rings of METH and MDMA molecules are oriented nearly perpendicular to the benzene ring of TrpL91 and similarly the PheL96 side chain is almost orthogonal to the aromatic rings of METH and MDMA, indicating that the pairing interactions play an important role in binding.…”

Section: Aromatic Pairing Interactions In the Binding Pocketmentioning

confidence: 99%

Crystal structures of a therapeutic single chain antibody in complex with two drugs of abuse—Methamphetamine and 3,4‐methylenedioxymethamphetamine

Celikel¹,

Peterson²,

Owens³

et al. 2009

Protein Science

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Methamphetamine (METH) is a major drug threat in the United States and worldwide. Monoclonal antibody (mAb) therapy for treating METH abuse is showing exciting promise and the understanding of how mAb structure relates to function will be essential for future development of these important therapies. We have determined crystal structures of a high affinity anti-(1)-METH therapeutic single chain antibody fragment (scFv6H4, K D 5 10 nM) derived from one of our candidate mAb in complex with METH and the (1) stereoisomer of another abused drug, 3,4-methylenedioxymethamphetamine (MDMA), known by the street name ''ecstasy.'' The crystal structures revealed that scFv6H4 binds to METH and MDMA in a deep pocket that almost completely encases the drugs mostly through aromatic interactions. In addition, the cationic nitrogen of METH and MDMA forms a salt bridge with the carboxylate group of a glutamic acid residue and a hydrogen bond with a histidine side chain. Interestingly, there are two water molecules in the binding pocket and one of them is positioned for a CAHÁ Á ÁO interaction with the aromatic ring of METH. These first crystal structures of a high affinity therapeutic antibody fragment against METH and MDMA (resolution 5 1.9 Å , and 2.4 Å , respectively) provide a structural basis for designing the next generation of higher affinity antibodies and also for carrying out rational humanization.

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Stacking and T-shape Competition in Aromatic−Aromatic Amino Acid Interactions

Cited by 248 publications

References 38 publications

The Low-Potency, Voltage-Dependent HERG Blocker Propafenone—Molecular Determinants and Drug Trapping

The Low-Potency, Voltage-Dependent HERG Blocker Propafenone—Molecular Determinants and Drug Trapping

Oligomerization of the γ-Aminobutyric Acid Transporter-1 Is Driven by an Interplay of Polar and Hydrophobic Interactions in Transmembrane Helix II

Crystal structures of a therapeutic single chain antibody in complex with two drugs of abuse—Methamphetamine and 3,4‐methylenedioxymethamphetamine

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