Dynamics of Ionic Interactions at Protein–Nucleic Acid Interfaces

Yu, Binhan; Pettitt, B. Montgomery; Iwahara, Junji

doi:10.1021/acs.accounts.0c00212

Cited by 41 publications

(31 citation statements)

References 90 publications

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“…This protein is a DNA-binding protein that recognizes the TAATGG sequence. Charge neutralization upon protein-DNA association is known to cause a release of cations from DNA ( 25 – 27 ). In our recent NMR study using 15 NH 4 + ions, we showed that the 15-bp DNA duplex containing the Antp recognition sequence releases 10.8 cations when it forms a complex with the Antp homeodomain ( 28 ).…”

Section: Resultsmentioning

confidence: 99%

Quantifying and visualizing weak interactions between anions and proteins

Pletka

Iwahara

2020

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

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The molecular properties of proteins are influenced by various ions present in the same solution. While site-specific strong interactions between multivalent metal ions and proteins are well characterized, the behavior of other ions that are only weakly interacting with proteins remains elusive. In the current study, using NMR spectroscopy, we have investigated anion–protein interactions for three proteins that are similar in size but differ in overall charge. Using a unique NMR-based approach, we quantified anions accumulated around the proteins. The determined numbers of anions that are electrostatically attracted to the charged proteins were notably smaller than the overall charge valences and were consistent with predictions from the Poisson–Boltzmann theory. This NMR-based approach also allowed us to measure ionic diffusion and characterize the anions interacting with the positively charged proteins. Our data show that these anions rapidly diffuse while bound to the proteins. Using the same experimental approach, we observed the release of the anions from the protein surface upon the formation of the Antp homeodomain–DNA complex. Using paramagnetic relaxation enhancement (PRE), we visualized the spatial distribution of anions around the free proteins and the Antp homeodomain–DNA complex. The obtained PRE data revealed the localization of anions in the vicinity of the highly positively charged regions of the free Antp homeodomain and provided further evidence of the release of anions from the protein surface upon the protein–DNA association. This study sheds light on the dynamic behavior of anions that electrostatically interact with proteins.

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Section: Resultsmentioning

confidence: 99%

Quantifying and visualizing weak interactions between anions and proteins

Pletka

Iwahara

2020

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

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“…The final transfection ability of the mutants appeared to be a sum of the mutations to the protein, demonstrating a “less is more” principle in the design process since seemingly synergistic mutations could actually compete against each other and not yield the desired result. Future designs should aim to further improve protein secondary structure to create even more favorable protein-siRNA interactions [30], while maintaining a favorable positive charge density [31].…”

Section: Discussionmentioning

confidence: 99%

“…In nature, the majority of nucleic acid binding proteins are alphahelical and positively charged [28, 29]. This can allow for sequence specific interactions through the orientation of side chains able to form hydrogen bonds with specific nucleic acid base pairs [30], or sequence independent interactions through electrostatic interactions between positively charged amino acids and the negatively charged nucleic acid phosphate backbone [31]. The degree of alpha-helicity is also important, as more organized alpha-helices have been shown to form more energetically favorable interactions with nucleic acid binding partners [32].…”

Section: Introductionmentioning

confidence: 99%

Increased alpha-helicity of a supercharged coiled-coil protein increases siRNA delivery efficiency of protein-lipid hybrid vehicle

Thomas

Monkovic

Frezzo

et al. 2021

Preprint

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Gene therapy has the potential to treat various diseases and has recently gained new interest due to the deployment nucleic acid based vaccines for COVID-19. Despite these developments, there still remains a need for further development of gene delivery vehicles to increase their safety and efficacy.. We have recently developed a lipoproteoplex (LPP) consisting of a super-charged coiled-coil protein (CSP) and a cationic liposomal carrier, that has the ability to condense nucleic acids and deliver them in vivo. The LPP is distinct from other liposomal gene delivery systems in that it utilizes a modular protein component to drive transfection activity as opposed to relying on the passive effects of the cationic lipids. A CSP library has been rationally designed to improve the efficacy of the LPP compared to the parent protein via improved alpha-helical structure and increased nucleic acid binding through the use of extended histidine tags and increased positive charge. The secondary structure and nucleic acid binding ability of each library member was assessed, then compared to functional transfection data in NIH-3T3 mouse fibroblasts. Structural and functional data suggests that increasing alpha-helicity of the protein component of the LPP compared to the parent sequence doubles nucleic acid binding affinity and increases transfection activity almost 3-fold with a favorable safety profile.

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“…The protein molecule must transiently break all of these ions pairs when it moves from one site to another on DNA. The requirement of breaking all ion pairs could represent an energy barrier for sliding [ 70 ]. In fact, for many proteins, the 1D diffusion coefficient for the sliding on DNA is ~10 2 –10 3 fold smaller than the 3D diffusion coefficient calculated with the Stokes-Einstein equation that gives the diffusion coefficient as a function of the hydrodynamic radius, viscosity, and temperature.…”

Section: Discrete-state Stochastic Kinetic Models For Protein Translomentioning

confidence: 99%

“…Because electrostatic interactions are crucial for protein-DNA association [ 70 ], the kinetics and thermodynamics of protein-DNA interactions strongly depend on the salt concentration used in experiments [ 29 , 34 , 64 , 67 , 83 – 88 ]. The counterion condensation theory predicts a linear relationship between log K d and log[salt] for the dissociation constants of protein-DNA complexes [ 85 , 86 ] and a similar linear relationship between log k and log[salt] for some kinetic rate constants relevant to protein-DNA constants [ 89 ].…”

Section: Experimental Applicationsmentioning

confidence: 99%

Discrete-state stochastic kinetic models for target DNA search by proteins: Theory and experimental applications

Iwahara

Kolomeisky

2021

Biophysical Chemistry

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To perform their functions, transcription factors and DNA-repair/modifying enzymes randomly search DNA in order to locate their specific targets on DNA. Discrete-state stochastic kinetic models have been developed to explain how the efficiency of the search process is influenced by the molecular properties of proteins and DNA as well as by other factors such as molecular crowding. These theoretical models not only offer explanations on the relation of microscopic processes to macroscopic behavior of proteins, but also facilitate the analysis and interpretation of experimental data. In this review article, we provide an overview on discrete-state stochastic kinetic models and explain how these models can be applied to experimental investigations using stopped-flow, single-molecule, nuclear magnetic resonance (NMR), and other biophysical and biochemical methods.

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Dynamics of Ionic Interactions at Protein–Nucleic Acid Interfaces

Cited by 41 publications

References 90 publications

Quantifying and visualizing weak interactions between anions and proteins

Quantifying and visualizing weak interactions between anions and proteins

Increased alpha-helicity of a supercharged coiled-coil protein increases siRNA delivery efficiency of protein-lipid hybrid vehicle

Discrete-state stochastic kinetic models for target DNA search by proteins: Theory and experimental applications

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