Mechanism of sequence‐based separation of single‐stranded DNA in capillary zone electrophoresis

Zhao, Jia; Cramer, Steven M.; McGown, Linda B.

doi:10.1002/elps.201900418

Cited by 2 publications

(2 citation statements)

References 32 publications

(47 reference statements)

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“…The mobilities observed for ss‐ and dsDNA oligomers containing 20 bases or base pairs varied with the AT/GC ratio and the arrangement of the nucleotides in the sequence [90]. The free‐solution mobilities observed for ssDNAs containing 15 thymine residues decreased when 1 or 2 thymines were replaced by adenine or guanine; the observed mobilities also depended on the position of the substitution in the sequence [91,92]. Since the mobility differences were not correlated with the radius of gyration, stacking interactions between neighboring nucleotides were suggested as a possible source of the mobility differences [92].…”

Section: Resultsmentioning

confidence: 99%

Using capillary electrophoresis to characterize the hydrodynamic and electrostatic properties of DNA in solutions containing various monovalent cations

Stellwagen

2021

Electrophoresis

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Using capillary electrophoresis to characterize the hydrodynamic and electrostatic properties of DNA in solutions containing various monovalent cationsThis review describes the results obtained by using free-solution capillary electrophoresis to probe the electrostatic and hydrodynamic properties of DNA in solutions containing various monovalent cations. In brief, we found that the mobilities of double-stranded DNAs (dsDNAs) increase with increasing molecular weight before leveling off and becoming constant at molecular weights ≥400 bp. The mobilities of single-stranded DNAs (ssDNAs) go through a maximum at ∼10-20 nucleotides before decreasing and becoming constant for oligomers larger than ∼30-50 bases. The mobilities of both ss-and dsDNAs increase linearly with the logarithm of increasing charge per unit length and decrease linearly with the logarithm of increasing ionic strength. Surprisingly, ss-and dsDNA mobilities level off and become nearly constant at ionic strengths ≥0.6 M. The thermal stabilities of dsDNAs decrease linearly with increasing solution viscosity. The diffusion coefficients of dsDNA are modulated by the diffusion coefficients of their counterions because of electrostatic DNA-cation coupling interactions. Finally, the anomalously slow mobilities observed for A-tract-containing DNAs can be attributed both to differences in shape and to the preferential localization of small cations in the A-tract minor groove. Since many of these results are mirrored in other polyion-counterion systems, free-solution electrophoresis can be viewed as a reporter of the electrostatics and hydrodynamics of highly charged polyions. New results describing the mobilities of dsDNA analogues of a microRNA-messenger RNA complex are also presented.

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Section: Resultsmentioning

confidence: 99%

Using capillary electrophoresis to characterize the hydrodynamic and electrostatic properties of DNA in solutions containing various monovalent cations

Stellwagen

2021

Electrophoresis

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“…Free zone electrophoresis was originally based on methods for purifying cells and bacteria. Zone electrophoresis (ZE), by default, is an appropriate method for separating [27] small molecules, proteins, [281,282] biomolecules, [283] peptides, [217,284] DNA, [285,286] viruses, [218,287] and membranes. In capillary zone electrophoresis (CZE), the electrophoretic separation of glycoproteins and glycopeptides can be performed by consideration of the m and z differences among the input ingredients, where m is the mass and z is the charge of the compartments.…”

Section: Micro Free-flow Electrophoresis (μ-Ffe)mentioning

confidence: 99%

Molecular Separation by Using Active and Passive Microfluidic chip Designs: A Comprehensive Review

Ebrahimi,

Icoz,

Didarian

et al. 2023

Adv Materials Inter

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Separation and identification of molecules and biomolecules such as nucleic acids, proteins, and polysaccharides from complex fluids are known to be important due to unmet needs in various applications. Generally, many different separation techniques, including chromatography, electrophoresis, and magnetophoresis, have been developed to identify the target molecules precisely. However, these techniques are expensive and time consuming. “Lab‐on‐a‐chip” systems with low cost per device, quick analysis capabilities, and minimal sample consumption seem to be ideal candidates for separating particles, cells, blood samples, and molecules. From this perspective, different microfluidic‐based techniques have been extensively developed in the past two decades to separate samples with different origins. In this review, “lab‐on‐a‐chip” methods by passive, active, and hybrid approaches for the separation of biomolecules developed in the past decade are comprehensively discussed. Due to the wide variety in the field, it will be impossible to cover every facet of the subject. Therefore, this review paper covers passive and active methods generally used for biomolecule separation. Then, an investigation of the combined sophisticated methods is highlighted. The spotlight also will be shined on the elegance of separation successes in recent years, and the remainder of the article explores how these permit the development of novel techniques.

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Mechanism of sequence‐based separation of single‐stranded DNA in capillary zone electrophoresis

Cited by 2 publications

References 32 publications

Using capillary electrophoresis to characterize the hydrodynamic and electrostatic properties of DNA in solutions containing various monovalent cations

Using capillary electrophoresis to characterize the hydrodynamic and electrostatic properties of DNA in solutions containing various monovalent cations

Molecular Separation by Using Active and Passive Microfluidic chip Designs: A Comprehensive Review

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