Analysis of zinc binding sites in protein crystal structures

Alberts, Ian L.; Nadassy, Katalin; Wodak, Shoshana J.

doi:10.1002/pro.5560070805

Cited by 407 publications

(495 citation statements)

References 89 publications

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“…The distance (2.17 Å) and angle (107.7°) between the Zn 2 þ and coordinating atom NE2 of histidine residues (Fig. 4a) were very close to those obtained from the analysis of 111 crystal structures 18 . The zinc-bridge model of zfP2X4 V291H/T214H based on the open crystal structure also produced reasonable values for the bond angle (110.2°) and bond lengths (2.14 Å; Supplementary Fig.…”

Section: Structural Dynamics Of Lf and Df Domains During Simulationssupporting

confidence: 80%

Relative motions between left flipper and dorsal fin domains favour P2X4 receptor activation

Zhao¹,

Wang

Ma³

et al. 2014

Nat Commun

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Channel gating in response to extracellular ATP is a fundamental process for the physiological functions of P2X receptors. Here we identify coordinated allosteric changes in the left flipper (LF) and dorsal fin (DF) domains that couple ATP-binding to channel gating. Engineered disulphide crosslinking or zinc bridges between the LF and DF domains that constrain their relative motions significantly influence channel gating of P2X4 receptors, confirming the essential role of these allosteric changes. ATP-binding-induced alterations in interdomain hydrophobic interactions among I208, L217, V291 and the aliphatic chain of K193 correlate well with these coordinated relative movements. Mutations on those four residues lead to impaired or fully abolished channel activations of P2X4 receptors. Our data reveal that ATP-binding-induced altered interdomain hydrophobic interactions and the concomitant coordinated motions of LF and DF domains are allosteric events essential for the channel gating of P2X4 receptors.

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Section: Structural Dynamics Of Lf and Df Domains During Simulationssupporting

confidence: 80%

Relative motions between left flipper and dorsal fin domains favour P2X4 receptor activation

Zhao¹,

Wang

Ma³

et al. 2014

Nat Commun

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“…Both the highly efficient targeting of Y335A to the cell surface and the ability of Zn 2ϩ to rescue transporter function with a potency similar to that observed for inhibition of the WT support that the overall structure is preserved in Y335A. Because of the very strict structural requirements for binding of the small Zn 2ϩ ion (25), even a minor structural change would be expected to be accompanied by reduced Zn 2ϩ affinity. The increases in apparent affinities for substrates in Y335A and the only slight change in apparent GBR-12,909 binding affinity support furthermore that the mutant transporter is in a functionally relevant conformation.…”

Section: Discussionmentioning

confidence: 63%

Generation of an activating Zn ²⁺ switch in the dopamine transporter: Mutation of an intracellular tyrosine constitutively alters the conformational equilibrium of the transport cycle

Løland

Norregaard²,

Litman³

et al. 2002

Proc. Natl. Acad. Sci. U.S.A.

124

164

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Binding of Zn 2؉ to the endogenous Zn 2؉ binding site in the human dopamine transporter leads to potent inhibition of [ 3 H]dopamine uptake. Here we show that mutation of an intracellular tyrosine to alanine (Y335A) converts this inhibitory Zn 2؉ switch into an activating Zn 2؉ switch, allowing Zn 2؉ -dependent activation of the transporter. The tyrosine is part of a conserved YXX⌽ trafficking motif (X is any residue and ⌽ is a residue with a bulky hydrophobic group), but Y335A did not show alterations in surface targeting or protein kinase C-mediated internalization. Despite wild-type levels of surface expression, Y335A displayed a dramatic decrease in [ 3 H]dopamine uptake velocity (Vmax) to less than 1% of the wild type. In addition, Y335A showed up to 150-fold decreases in the apparent affinity for cocaine, mazindol, and related inhibitors whereas the apparent affinity for several substrates was increased. However, the presence of Zn 2؉ in micromolar concentrations increased the V max up to 24-fold and partially restored the apparent affinities. The capability of Zn 2؉ to restore transport is consistent with a reversible, constitutive shift in the distribution of conformational states in the transport cycle upon mutation of Tyr-335. We propose that this shift is caused by disruption of intramolecular interactions important for stabilizing the transporter in a conformation in which extracellular substrate can bind and initiate transport, and accordingly that Tyr-335 is critical for regulating isomerization between discrete states in the transport cycle.

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“…1, C and D). Asn-98 O␦ forms an H-bond with His-100 N␦, further stabilizing the His-100 N⑀-Zn 2ϩ bond through a well conserved 'elecHis-Zn' motif (35). The BpUreE-Zn 2ϩ interaction, although not indispensable for the formation of the dimer 1 , supposedly further contributes to its stability.…”

Section: Resultsmentioning

confidence: 99%

Structural Basis for Ni2+Transport and Assembly of the Urease Active Site by the Metallochaperone UreE from Bacillus pasteurii

Remaut¹,

Safarov²,

Ciurli³

et al. 2001

Journal of Biological Chemistry

105

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Bacillus pasteurii UreE (BpUreE) is a putative chaperone assisting the insertion of Ni 2؉ ions in the active site of urease. The x-ray structure of the protein has been determined for two crystal forms, at 1.7 and 1.85 Å resolution, using SIRAS phases derived from a Hg 2؉ -derivative. BpUreE is composed of distinct N-and Cterminal domains, connected by a short flexible linker. The structure reveals the topology of an elongated homodimer, formed by interaction of the two C-terminal domains through hydrophobic interactions. A single Zn 2؉ ion bound to four conserved His-100 residues, one from each monomer, connects two dimers resulting in a tetrameric BpUreE known to be formed in concentrated solutions. The Zn 2؉ ion can be replaced by Ni 2؉ as shown by anomalous difference maps obtained on a crystal of BpUreE soaked in a solution containing NiCl 2 . A large hydrophobic patch surrounding the metal ion site is surface-exposed in the biologically relevant dimer. The BpUreE structure represents the first for this class of proteins and suggests a possible role for UreE in the urease nickel-center assembly.The molecular details of the mechanism by which specific metal co-factors are transported in the cell and sorted into the correct metalloenzyme, among the many biological systems that employ transition metal ions for their function without being involved in alternative adventitious and possibly poisonous binding, are still rather unclear. The role of a new class of soluble metal-binding proteins, known as "metallochaperones

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Analysis of zinc binding sites in protein crystal structures

Cited by 407 publications

References 89 publications

Relative motions between left flipper and dorsal fin domains favour P2X4 receptor activation

Relative motions between left flipper and dorsal fin domains favour P2X4 receptor activation

Generation of an activating Zn ²⁺ switch in the dopamine transporter: Mutation of an intracellular tyrosine constitutively alters the conformational equilibrium of the transport cycle

Structural Basis for Ni2+Transport and Assembly of the Urease Active Site by the Metallochaperone UreE from Bacillus pasteurii

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Analysis of zinc binding sites in protein crystal structures

Cited by 407 publications

References 89 publications

Relative motions between left flipper and dorsal fin domains favour P2X4 receptor activation

Relative motions between left flipper and dorsal fin domains favour P2X4 receptor activation

Generation of an activating Zn 2+ switch in the dopamine transporter: Mutation of an intracellular tyrosine constitutively alters the conformational equilibrium of the transport cycle

Structural Basis for Ni2+Transport and Assembly of the Urease Active Site by the Metallochaperone UreE from Bacillus pasteurii

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Generation of an activating Zn ²⁺ switch in the dopamine transporter: Mutation of an intracellular tyrosine constitutively alters the conformational equilibrium of the transport cycle