Haemoglobin: The structural changes related to ligand binding and its allosteric mechanism

AbstractThe aberrant expression of microRNAs (miRs) has been linked to several human diseases. A promising approach for targeting these anomalies is the use of small-molecule inhibitors of miR biogenesis. These inhibitors have the potential to (i) dissect miR mechanisms of action, (ii) discover new drug targets, and (iii) function as new therapeutic agents. Here, we designed Förster resonance energy transfer (FRET)-labeled oligoribonucleotides of the precursor of the oncogenic miR-21 (pre-miR-21) and used them together with a set of aminoglycosides to develop an interbase-FRET assay to detect ligand binding to pre-miRs. Our interbase-FRET assay accurately reports structural changes of the RNA oligonucleotide induced by ligand binding. We demonstrate its application in a rapid, qualitative drug candidate screen by assessing the relative binding affinity between 12 aminoglycoside antibiotics and pre-miR-21. Surface plasmon resonance (SPR) and isothermal titration calorimetry (ITC) were used to validate our new FRET method, and the accuracy of our FRET assay was shown to be similar to the established techniques. With its advantages over SPR and ITC owing to its high sensitivity, small sample size, straightforward technique and the possibility for high-throughput expansion, we envision that our solution-based method can be applied in pre-miRNA–target binding studies.

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A Small Chemical Mimicking Actin Binding to Myosin and Putative Structural Changes of Myosin Molecule upon Ligand Binding

Biophysical Journal ◽

10.1016/j.bpj.2013.11.3381 ◽

2014 ◽

Vol 106 (2) ◽

pp. 611a

Author(s):

Takayuki Miyanishi ◽

Io Omotuyi ◽

Taku Yamaguchi

Keyword(s):

Ligand Binding ◽

Structural Changes ◽

Actin Binding ◽

Myosin Molecule ◽

Small Chemical

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Growth-regulatory Human Galectin-1: Crystallographic Characterisation of the Structural Changes Induced by Single-site Mutations and their Impact on the Thermodynamics of Ligand Binding

Journal of Molecular Biology ◽

10.1016/j.jmb.2004.08.078 ◽

2004 ◽

Vol 343 (4) ◽

pp. 957-970 ◽

Cited By ~ 204

Author(s):

María F. López-Lucendo ◽

Dolores Solís ◽

Sabine André ◽

Jun Hirabayashi ◽

Ken-ichi Kasai ◽

...

Keyword(s):

Ligand Binding ◽

Structural Changes ◽

Single Site

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Cytoglobin ligand binding regulated by changing haem-co-ordination in response to intramolecular disulfide bond formation and lipid interaction

Biochemical Journal ◽

10.1042/bj20140827 ◽

2014 ◽

Vol 465 (1) ◽

pp. 127-137 ◽

Cited By ~ 23

Author(s):

Penny Beckerson ◽

Michael T. Wilson ◽

Dimitri A. Svistunenko ◽

Brandon J. Reeder

Keyword(s):

Ligand Binding ◽

Redox State ◽

Structural Changes ◽

Bond Formation ◽

Lipid Binding ◽

Binding Kinetics ◽

Disulfide Bond Formation ◽

Physiological Properties ◽

Intramolecular Disulfide Bond ◽

Lipid Interaction

The redox state of the two-surface exposed cysteine residues in cytoglobin (Cygb) regulates the biochemical and potential physiological properties of the protein. Significant changes to ligand-binding kinetics, peroxidase activity and lipid-binding-induced structural changes are observed.

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Structural Changes Due to Antagonist Binding in Ligand Binding Pocket of Androgen Receptor Elucidated Through Molecular Dynamics Simulations

Frontiers in Pharmacology ◽

10.3389/fphar.2018.00492 ◽

2018 ◽

Vol 9 ◽

Cited By ~ 10

Author(s):

Sugunadevi Sakkiah ◽

Rebecca Kusko ◽

Bohu Pan ◽

Wenjing Guo ◽

Weigong Ge ◽

...

Keyword(s):

Molecular Dynamics ◽

Androgen Receptor ◽

Ligand Binding ◽

Molecular Dynamics Simulations ◽

Structural Changes ◽

Binding Pocket ◽

Ligand Binding Pocket ◽

Antagonist Binding ◽

Dynamics Simulations

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Cross-subunit Interactions that Stabilize Open States Mediate Gating in NMDA Receptors

10.1101/2020.06.08.140525 ◽

2020 ◽

Author(s):

Gary J Iacobucci ◽

Han Wen ◽

Matthew B Helou ◽

Wenjun Zheng ◽

Gabriela K Popescu

Keyword(s):

Ligand Binding ◽

Nmda Receptors ◽

Structural Changes ◽

Chemical Interaction ◽

Transmembrane Helix ◽

Binding Domain ◽

Ligand Binding Domain ◽

Activation Reaction ◽

Mechanical Coupling ◽

Current Decay

ABSTRACTNMDA receptors are excitatory channels with critical functions in the physiology of central synapses. Their activation reaction proceeds as a series of kinetically distinguishable, reversible steps, whose structural bases are of current interest. Very likely, the earliest steps in the activation reaction include glutamate binding to and compression of the ligand-binding domain. Later, three short linkers transduce this movement to open the gate by mechanical coupling with transmembrane helices. Here, we used double-mutant cycle analyses to demonstrate that a direct chemical interaction between GluN1-I642 (on M3) and GluN2A-L550 (on L1-M1) stabilizes receptors after they have opened, and therefore represents one of the structural changes that occur late in the activation reaction. This native interaction extends the current decay, and its absence predicts deficits in charge transfer by GluN1-I642L, a pathogenic human variant.SIGNIFICANCE STATEMENTNMDA receptors are glutamatergic channels whose activations control the strength of excitatory synapses in the central nervous system. Agonist binding initiates a complex activation reaction that consists of a stepwise sequence of reversible isomerizations. In addition to previously identified steps in this series, which include agonist-induced closure of the ligand-binding lobes, and the subsequent mechanical pulling by the ligand-binding domain on the gate-forming transmembrane helix, we identify a new cross-subunit interaction, which stabilizes open receptors and slows the rate of the current decay. Naturally occurring NMDA receptor variants lacking this interaction are pathogenic.

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Capturing Peptide–GPCR Interactions and Their Dynamics

Molecules ◽

10.3390/molecules25204724 ◽

2020 ◽

Vol 25 (20) ◽

pp. 4724

Author(s):

Anette Kaiser ◽

Irene Coin

Keyword(s):

Ligand Binding ◽

Conformational Changes ◽

Structural Changes ◽

Structural Heterogeneity ◽

Receptor Interaction ◽

Spectroscopic Techniques ◽

Peptide Receptors ◽

Physiological Processes ◽

High Dynamics ◽

G Protein Coupled

Many biological functions of peptides are mediated through G protein-coupled receptors (GPCRs). Upon ligand binding, GPCRs undergo conformational changes that facilitate the binding and activation of multiple effectors. GPCRs regulate nearly all physiological processes and are a favorite pharmacological target. In particular, drugs are sought after that elicit the recruitment of selected effectors only (biased ligands). Understanding how ligands bind to GPCRs and which conformational changes they induce is a fundamental step toward the development of more efficient and specific drugs. Moreover, it is emerging that the dynamic of the ligand–receptor interaction contributes to the specificity of both ligand recognition and effector recruitment, an aspect that is missing in structural snapshots from crystallography. We describe here biochemical and biophysical techniques to address ligand–receptor interactions in their structural and dynamic aspects, which include mutagenesis, crosslinking, spectroscopic techniques, and mass-spectrometry profiling. With a main focus on peptide receptors, we present methods to unveil the ligand–receptor contact interface and methods that address conformational changes both in the ligand and the GPCR. The presented studies highlight a wide structural heterogeneity among peptide receptors, reveal distinct structural changes occurring during ligand binding and a surprisingly high dynamics of the ligand–GPCR complexes.

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2P074 UV Resonance Raman Studies on the Trigger of Structural Changes of Myoglobin upon Ligand Binding

Seibutsu Butsuri ◽

10.2142/biophys.44.s128_2 ◽

2004 ◽

Vol 44 (supplement) ◽

pp. S128

Author(s):

Y. Gao ◽

Biswajit Pal ◽

T. Hayashi ◽

K. Harada ◽

T. Nakagawa ◽

...

Keyword(s):

Ligand Binding ◽

Structural Changes ◽

Resonance Raman ◽

Uv Resonance Raman

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Partial oxygen-dissociation of crystalline giant hemoglobin

Acta Crystallographica Section A Foundations and Advances ◽

10.1107/s2053273314095254 ◽

2014 ◽

Vol 70 (a1) ◽

pp. C474-C474 ◽

Cited By ~ 1

Author(s):

Nobutaka Numoto ◽

Taro Nakagawa ◽

Akiko Kita ◽

Nobutoshi Ito ◽

Yoshihiro Fukumori ◽

...

Keyword(s):

Structural Changes ◽

Quaternary Structure ◽

Oxygen Binding ◽

Nitrogen Gas ◽

Soaking Time ◽

Allosteric Mechanism ◽

Oxygen Dissociation ◽

Intermediate States ◽

Complete Dissociation ◽

Partial Oxygen

Allosteric oxygen-binding of hemoglobin (Hb) has been widely discussed based on the quaternary structural changes elucidated by the crystal structures of the oxygenated and deoxygenated states. However, it remains to be determined the structure of intermediate states between the oxy and deoxy forms without any artificial modification of the Hb molecule. A tubeworm, Lamellibrachia satsuma has extracellular giant hemoglobins with a molecular mass of about 400 and 3,600 kDa. Recently, we have determined the crystal structure of the 400 kDa Hb (V2Hb) in the oxy state, and then we successfully obtained the deoxygenated crystals of V2Hb from oxy crystals by the soaking methods [1]. These findings encourage us to initiate structural studies for the intermediate states between the oxy and deoxy forms of V2Hb, which should provide a more accurate understanding of the allosteric mechanism of Hbs. The deoxy crystals of V2Hb were obtained from oxy crystals through the soaking in a solution containing 50 mM sodium hydrosulfite, and incubated for a few minutes. We tested various soaking times from 3 s to 180 s and then immediately flash-frozen under a nitrogen gas stream. The obtained structures reveal that in the case of the soaking time was longer than 10 s, the electron densities of the oxygen molecules at some heme pockets (oxygen binding sites) were very week or disappeared. These `intermediate' structures show almost the same quaternary structure as that of the oxy structure. This fact suggests that quaternary rearrangement of V2Hb might arise just before a complete dissociation of all the oxygen molecules from all the subunits.

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