Non-Conserved Amino Acid Residues Modulate the Thermodynamics of Zn(II) Binding to Classical ββα Zinc Finger Domains

Classical zinc fingers domains (ZFs) bind Zn(II) ion by a pair of cysteine and histidine residues to adopt a characteristic and stable ββα fold containing a small hydrophobic core. As a component of transcription factors, they recognize specific DNA sequences to transcript particular genes. The loss...

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Bibliographic Details
Published in:International journal of molecular sciences 2022-11, Vol.23 (23), p.14602
Main Authors: Kluska, Katarzyna, Chorążewska, Aleksandra, Peris-Díaz, Manuel David, Adamczyk, Justyna, Krężel, Artur
Format: Article
Language:English
Subjects:
Affinity
Amino Acid Sequence
Amino Acids
Binding Sites
Cellular structure
DNA
energetics
Flexibility
Histidine
Hydrogen bonds
Hydrophobicity
isothermal titration calorimetry
metal binding affinity
metal-coupled folding
Molecular dynamics
Nucleotide sequence
Peptides
Protein structure
Proteins
Residues
Saturation
Secondary structure
Simulation
Stability
Structure-function relationships
Thermodynamics
Transcription factors
Zinc
Zinc - metabolism
Zinc Fingers
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Summary:Classical zinc fingers domains (ZFs) bind Zn(II) ion by a pair of cysteine and histidine residues to adopt a characteristic and stable ββα fold containing a small hydrophobic core. As a component of transcription factors, they recognize specific DNA sequences to transcript particular genes. The loss of Zn(II) disrupts the unique structure and function of the whole protein. It has been shown that the saturation of ZFs under cellular conditions is strictly related to their affinity for Zn(II). High affinity warrants their constant saturation, while medium affinity results in their transient structurization depending on cellular zinc availability. Therefore, there must be factors hidden in the sequence and structure of ZFs that impact Zn(II)-to-protein affinities to control their function. Using molecular dynamics simulations and experimental spectroscopic and calorimetric approaches, we showed that particular non-conserved residues derived from ZF sequences impact hydrogen bond formation. Our in silico and in vitro studies show that non-conserved residues can alter metal-coupled folding mechanisms and overall ZF stability. Furthermore, we show that Zn(II) binding to ZFs can also be entropically driven. This preference does not correlate either with Zn(II) binding site or with the extent of the secondary structure but is strictly related to a reservoir of interactions within the second coordination shell, which may loosen or tighten up the structure. Our findings shed new light on how the functionality of ZFs is modulated by non-coordinating residues diversity under cellular conditions. Moreover, they can be helpful for systematic backbone alteration of native ZF ββα scaffold to create artificial foldamers and proteins with improved stability.
ISSN:1422-0067
1661-6596
1422-0067
DOI:10.3390/ijms232314602