High-throughput single-molecule quantification of individual base stacking energies in nucleic acids

Punnoose, Jibin Abraham; Thomas, Kevin J; Chandrasekaran, Arun Richard; Vilcapoma, Javier; Hayden, Andrew; Kilpatrick, Kacey; Vangaveti, Sweta; Chen, Alan; Banco, Thomas; Halvorsen, Ken

doi:10.1038/s41467-023-36373-8

Cited by 9 publications

(17 citation statements)

References 69 publications

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“…Quantifying the energy contribution of base stacking has been of considerable interest via several methods, such as thermal denaturation methods, , electrophoretic analysis of equilibrium, and single-molecule approaches. − However, the methods often require complicated operations and it is difficult to quantify the energy parameter of base stacking in a native environment. Similar to a real balance, here, changes in thermodynamic parameters of the DNA balance can be employed to calculate the energy contribution of base stacking.…”

Section: Resultsmentioning

confidence: 99%

Versatile DNA Balances via Adjacent Base Stacking for Homogeneous Assay of Energy Parameters, Small Molecules, And Ribonuclease

Hao,

Cai,

Yang

et al. 2023

Anal. Chem.

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Homogeneous assays often obviate any separation and washing steps, thus minimizing the risks of contamination and false positive. DNA toehold exchange is a homogeneous, reversible process whose thermodynamic properties can be finely tuned for various assay applications. However, the developed probes often rely on direct interactions of analytes with DNA strands involved in toehold exchange, limiting the versatility of probe design. Here, the coaxial adjacent stacking between one auxiliary strand and another invading strand offers a favorable ΔG to shift one DNA balance, while the auxiliary strand is independent of the DNA balance itself. Therefore, such a DNA balance allowed fine tuning of the equilibrium via adjustment of the auxiliary strand alone. The energy contribution of base stacking can be quantified in a homogeneous solution based on the difference in the equilibrium constant. Besides, the proof of concept for DNA balance allows effective assay of a small molecule or ribonuclease in a homogeneous solution. This novel DNA balance via adjacent base stacking provides an interesting alternative to homogeneously assay various analytes.

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Section: Resultsmentioning

confidence: 99%

Versatile DNA Balances via Adjacent Base Stacking for Homogeneous Assay of Energy Parameters, Small Molecules, And Ribonuclease

Hao,

Cai,

Yang

et al. 2023

Anal. Chem.

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“…This observation could not be the case for other systems, and research about the influence of salt models and salt concentration on nucleic acids in MD simulations is ongoing . On the topic of base pair stacking, several groups have performed studies with seemingly contradicting resultssome have seen parm99 parameters result in overstacking and some observed understacking . The overstacking present, though notably mild, requires more work to be done to investigate the potential sequence dependence of base pair stacking in double-stranded nucleic acid systems.…”

Section: Discussionmentioning

confidence: 99%

“…The overstacking present, though notably mild, requires more work to be done to investigate the potential sequence dependence of base pair stacking in double-stranded nucleic acid systems. Experimentally accurate description of base pair stacking is an ever-present issue in all the force fields evaluated hereparm99-based force fields with varying results − and Tumuc1 overstabilizing base pair stacking compared to the experiment. , Possible solutions may lie in the refinement of glycosidic terms or adjustments in partial charge distributions, but further investigation is needed to address this characteristic that is critical to nucleic acid helical stability.…”

Section: Discussionmentioning

confidence: 99%

Assessing the Current State of Amber Force Field Modifications for DNA─2023 Edition

Love

Galindo‐Murillo

Zgarbová

et al. 2023

J. Chem. Theory Comput.

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Advances in molecular dynamics (MD) software alongside enhanced computational power and hardware have allowed for MD simulations to significantly expand our knowledge of biomolecular structure, dynamics, and interactions. Furthermore, it has allowed for the extension of conformational sampling times from nanoseconds to the microsecond level and beyond. This has not only made convergence of conformational ensembles through comprehensive sampling possible but consequently exposed deficiencies and allowed the community to overcome limitations in the available force fields. The reproducibility and accuracy of the force fields are imperative in order to produce biologically relevant data. The Amber nucleic acid force fields have been used widely since the mid-1980s, and improvement of these force fields has been a community effort with several artifacts revealed, corrected, and reevaluated by various research groups. Here, we focus on the Amber force fields for use with double-stranded DNA and present the assessment of two recently developed force field parameter sets (OL21 and Tumuc1). Extensive MD simulations were performed with six test systems and two different water models. We observe the improvement of OL21 and Tumuc1 compared to previous generations of the Amber DNA force. We did not detect any significant improvement in the performance of Tumuc1 compared to OL21 despite the reparameterization of bonded force field terms in the former; however, we did note discrepancies in Tumuc1 when modeling Z-DNA sequences.

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“…Decades of benchmarking and evaluations have provided a thorough record of the current limitations of the available Amber nucleic acid force fields. ,− These works have uncovered a hyper-tendency for hydrogen bonding, overstacking, and the overstabilization of infinite helices, to name a few. ,, Many of these issues have been attributed to a misbalance in the van der Waals (vdW) parameters, which have not been improved since their development in tandem with the original parm94 force field . At their conception, Amber vdW parameters were defined by atom typefor example, all sp3-hybridized carbon atoms share the same vdW parameters, as do all sp2-hybridized carbon atoms. , These initial carbon and hydrogen atom type vdW parameters were originally fit to reproduce the densities and enthalpies of vaporization for alkanes and benzenes. , Concurrently, oxygen, nitrogen, and phosphorus atom vdW parameters were developed to reproduce neat liquid properties, as well as to fit lattice energies and crystal structures .…”

Section: Introductionmentioning

confidence: 99%

van der Waals Parameter Scanning with Amber Nucleic Acid Force Fields: Revisiting Means to Better Capture the RNA/DNA Structure through MD

Love,

Winkler,

Cheatham

2023

J. Chem. Theory Comput.

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Molecular dynamics simulations can be used in combination with experimental techniques to uncover the intricacies of biomolecular structure, dynamics, and the resulting interactions. However, many noncanonical nucleic acid structures have proven to be challenging to replicate in accurate agreement with experimental data, often attributed to known force field deficiencies. A common force field criticism is the handling of van der Waals (vdW) parameters, which have not been updated since the regular use of Ewald's methods became routine. This work dives into the effects of minute vdW radii shifts on RNA tetranucleotide, B-DNA, and Z-DNA model systems described by commonly used Amber force fields. Using multidimensional replica exchange molecular dynamics (M-REMD), the GACC RNA tetranucleotide demonstrated changes in the structural distribution between the NMR minor and anomalous structure populations based on the O2′ vdW radii scanning. However, no significant change in the NMR Major conformation population was observed. There were minimal changes in the B-DNA structure but there were more substantial improvements in Z-DNA structural descriptions, specifically with the Tumuc1 force field. This occurred with both LJbb vdW radii adjustments and incorporation of the CUFIX nonbonded parameter modifications. Though the limited vdW modifications tested did not provide a universal fix to the challenge of simulating the various known nucleic acid structures, they do provide direction and a greater understanding for future force field development efforts.

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High-throughput single-molecule quantification of individual base stacking energies in nucleic acids

Cited by 9 publications

References 69 publications

Versatile DNA Balances via Adjacent Base Stacking for Homogeneous Assay of Energy Parameters, Small Molecules, And Ribonuclease

Versatile DNA Balances via Adjacent Base Stacking for Homogeneous Assay of Energy Parameters, Small Molecules, And Ribonuclease

Assessing the Current State of Amber Force Field Modifications for DNA─2023 Edition

van der Waals Parameter Scanning with Amber Nucleic Acid Force Fields: Revisiting Means to Better Capture the RNA/DNA Structure through MD

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