Unhooking dynamics of U-shaped DNA molecule undergoing gel electrophoresis.

It has been found that DNA molecules are often hooked around obstacles in a U-shaped configuration in gel electrophoresis. To understand the dynamics of the unhooking of U-shaped DNA molecules undergoing gel electrophoresis, we have examined the length changes of the longer and shorter arms of the U-shape as a function of time. Two types of unhooking have been found. In one type, the length changes of both arms are expontential in time but with different time constants. In another type, the length changes of the shorter arm is exponential and that of the longer one is linear with time. The interpretation is that the extent of stretch of the spring-like DNA chain decreases as the length difference between the two arms increases during the unhooking processes, and that the frictions at the pivot point can be relatively large depending upon the local structure of the gel. The friction coefficient at the pivot point is estimated to be nu 0 = (2.98 +/- 1.42)x10(-5) g/sec.     

Orientation of DNA Molecules in Agarose Gels By Pulsed Electric Fields

Abstract

The electric birefringence of DNA restriction fragments of three different sizes, 622,1426, and 2936 base pairs, imbedded in agarose gels of different concentrations, was measured. The birefringence relaxation times observed in the gels are equal to the values observed in free solution, if the median pore diameter of the gel is larger than the effective hydrodynamic length of the DNA molecule in solution. However, if the median pore diameter is smaller than the apparent hydrodynamic length, the birefringence relaxation times increase markedly, becoming equal to the values expected for the birefringence relaxation of fully stretched DNA molecules. This apparent elongation indicates that end-on migration, or reptation is a likely mechanism for the electrophoresis of large DNA molecules in agarose gels. The relaxation times of the stretched DNA molecules scale with molecular weight (or contour length) as N^2.8, in reasonable agreement with reptation theories.     

Resolving Power: A Quantitative Measure of Electrophoretic Resolution

Resolving power is a quantitative measure of the ability of an electrophoretic system to separate DNA (and other) molecules of similar size. It is a dimensionless quantity, and hence facilitates comparison of the performance of electrophoretic systems that operate very differently. Resolving power can be determined as a function of molecular length from experimental data consisting of a series of completely resolved bands on a gel or blot; closely spaced bands are not required. We discuss factors such as the mass of DNA in a particular band and the spatial resolution of the system used to image the distribution of DNA on a gel or blot that, while not an intrinsic part of the electrophoretic system, may influence the observed resolving power. We derive an empirical global dispersion function that applies both to images of gels obtained after a fixed time of electrophoresis of all the samples and to images obtained as each species reaches a detector located at a fixed distance from the starting well. We use this dispersion function to show that the improvement in resolving power produced by extending the time or distance of electrophoresis in a static, uniform electric field asymptotically approaches a limiting value that is a function of the length of the DNA. When plotted as a function of molecular length, this limiting value defines an envelope that characterizes the intrinsic limits of performance of a particular electrophoretic system (e.g., electric field strength, gel type and concentration, buffer, temperature). Comparing the resolving power of static field agarose gel electrophoresis as routinely practiced for separating DNA molecules from 10³ to 10⁵ bp long with other electrophoretic schemes suggests that significant improvements should be achievable.     

Water molecule binding and lifetimes on the DNA duplex d(CGCGAATTCGCG)2

Summary Measurements of the water proton spin-lattice relaxation rate for aqueous solutions of the palindromic dodecamer, d(CGCGAATTCGCG)₂, are reported as a function of the magnetic field strength. The magnitude of the relaxation rates at low magnetic field strengths and the shape of the relaxation dispersion curve permit assessment of the number of water molecules which may be considered bound to the DNA for a time equal to or longer than the rotational correlation time of the duplex. The data are examined using limiting models that arbitrarily use the measured rotational correlation time of the polynucleotide complex as a reference point for the water molecule lifetime. If it is assumed that water molecules are bound at DNA sites for times as long as or longer than the rotational correlation time of the duplex, then the magnitude of the relaxation rates at low field require that there may be only two or three such water sites. However, if the lifetime constraints is relaxed, and we assume that the number of water molecules bound to the DNA is more nearly the number identified in the X-ray structures, then the average water molecule lifetime is on the order of 1 ns. Measurements of ¹H NOESY spectra demonstrate that some water molecules must have lifetimes sufficiently long that negative Overhauser effects are observed. Taken together, these results suggest a distribution of water molecule lifetimes in which most of the DNA-bound water molecule lifetimes are shorter than the rotational correlation time of the duplex, but where some have lifetimes of at least 1 ns under these concentrated conditions.Abbreviations DNA deoxyribonucleic acid - NOE nuclear Overhauser enhancement - NOESY nuclear Overhauser enhancement spectroscopy     

A Study of the B-A Transition in DNA by Gel Electrophoresis

Abstract

A procedure is developed for studying the B-A transition in DNA using gel electrophoresis. The starting point has been the idea that the junction between the A and B sections, which appear within the transition interval would increase the mobility of the DNA molecules. Indeed, the mobility of DNA in a gel is shown to increase in the middle of the B-A transition due to the formation of the largest possible number of boundaries between the B and A forms. The middle of the B-A transition in supercoiled DNA appears to be shifted against the middle of the transition in open circular (as well as linear) DNA by about 1.3% towards lower ethanol concentrations under the influence of the superhelical stress.     

A new continuous, monodimensional electrophoretic system for the separation and quantitation of individual glycosaminoglycans

A rapid and sensitive method for agarose gel electrophoresis is described. By simply miniaturizing a conventional gel electrophoresis apparatus, we have decreased the time necessary for the separation of nucleic acid molecules by a factor of 10. The ability to detect DNA molecules by ethidium bromide fluorescence has simultaneously been increased fivefold. Transfer of DNA from these “minigels” onto nitrocellulose filters followed by hybridization using the procedure of C. M. Southern (1975, J. Mol. Biol.98, 503–517) was found to be efficient and rapid. This technique is sufficiently sensitive to detect radioactive quantities of [³²P]phosphate-labeled DNA or RNA microinjected into 500 chick embryo fibroblasts.     

Agarose Gel Electrophoresis for the Separation of DNA Fragments

Agarose gel electrophoresis is the most effective way of separating DNA fragments of varying sizes ranging from 100 bp to 25 kb¹. Agarose is isolated from the seaweed genera Gelidium and Gracilaria, and consists of repeated agarobiose (L- and D-galactose) subunits². During gelation, agarose polymers associate non-covalently and form a network of bundles whose pore sizes determine a gel''s molecular sieving properties. The use of agarose gel electrophoresis revolutionized the separation of DNA. Prior to the adoption of agarose gels, DNA was primarily separated using sucrose density gradient centrifugation, which only provided an approximation of size. To separate DNA using agarose gel electrophoresis, the DNA is loaded into pre-cast wells in the gel and a current applied. The phosphate backbone of the DNA (and RNA) molecule is negatively charged, therefore when placed in an electric field, DNA fragments will migrate to the positively charged anode. Because DNA has a uniform mass/charge ratio, DNA molecules are separated by size within an agarose gel in a pattern such that the distance traveled is inversely proportional to the log of its molecular weight³. The leading model for DNA movement through an agarose gel is "biased reptation", whereby the leading edge moves forward and pulls the rest of the molecule along⁴. The rate of migration of a DNA molecule through a gel is determined by the following: 1) size of DNA molecule; 2) agarose concentration; 3) DNA conformation⁵; 4) voltage applied, 5) presence of ethidium bromide, 6) type of agarose and 7) electrophoresis buffer. After separation, the DNA molecules can be visualized under uv light after staining with an appropriate dye. By following this protocol, students should be able to: 1. Understand the mechanism by which DNA fragments are separated within a gel matrix 2. Understand how conformation of the DNA molecule will determine its mobility through a gel matrix 3. Identify an agarose solution of appropriate concentration for their needs 4. Prepare an agarose gel for electrophoresis of DNA samples 5. Set up the gel electrophoresis apparatus and power supply 6. Select an appropriate voltage for the separation of DNA fragments 7. Understand the mechanism by which ethidium bromide allows for the visualization of DNA bands 8. Determine the sizes of separated DNA fragments       

The Stability of DNA and RNA G-Quartets

Abstract

We have investigated the thermodynamic stability of DNA and RNA G-quartet by circular dichroism spectroscopy, gel electrophoresis, and melting analysis. The free energy (δG°37) for G-quartet formation of d(TTGGGG)⁴ and r(UUGGGG)⁴ at 100 mM NaCl and 37°C were 1.4 kcal mol-¹ and ?3.0 kcal mol-¹, respectively. On the other hand, at 100 mh4 KCI, δG°₃₇ of the DNA and RNA were ?10.0 kcal mol-1 and ?8.2 kcal mol-¹. This result indicates that the dependence of DNA G-quartet stability on these ions is larger than that of RNA.

     

Information concerning the mechanism of electrophoretic DNA separation provided by quantitative video-epifluorescence microscopy

Changes in conformation, length, and mobility of individual DNA molecules during agarose gel electrophbresis were measured using video micrographs obtained by epifluorescence microscopy. Globular, V-shaped, and linear conformations of DNA are found. The mobility, upon transformation from the globular to the V-shaped conformation, decreases, suggesting a collision with a gel fiber. The duration of interaction between DNA and gel fiber is proportional to the length of DNA. Hypothetically, this proportionality underlies the size separation of DNA by agarose gel electrophoresis. DNA release from the gel fiber appears to involve the movement of the arms of the V-shaped molecule around the gel fiber. Concomitant with this movement is a length reduction the degree of which is constant for DNA of various lengths in a particular buffer milieu. The luminant densitometric profiles of DNA molecules in the V conformation show maxima at the ends and apex of the V. The unequal distribution of nucleotides along the DNA chain appears to provide the driving force for the molecular movement around the gel fiber.     

Analysis of the electrophoretic properties of double-stranded DNA and RNA in agarose gels at a finite voltage gradient

The electrophoretic mobilities of double-stranded (ds) DNAs and ds RNAs of various lenths, L, were measured in gels of 0.4–1.8% (w/v) agarose at a voltage gradient of 1.0 V/cm. Differences in the electrophoresis of ds DNA and ds RNA are presented and discussed. A general expression is derived that describes the electrophoretic mobility, M, of either type of ds nucleic acid as a function of the gel concentration and the nucleic acid length: M = M′₁(L/L₀)^?x ? M₂, where M′₁ and L₀ are constants, and x and M₂ depend on the agarose gel concentration. The results obtained by fitting our data with this equation are consistent with the mobilities of nucleic acids in a wide range of gel concentrations, including free electrophoresis in solution and electrophoresis in gles of high agarose concentration in which nuleic acids are expected to reptate through the gel matrix. Finally, various methods of plotting agarose gel electrophoresis data are discussed.     

Spectroscopic investigations on DNA binding profile of two new naphthyridine carboxamides and their application as turn-on fluorescent DNA staining probes

Abstract

Two new 10-methoxydibenzo[b,h][1,6]naphthyridine-2-carboxamide derivatives (R1 and R2) have been synthesized and characterized using different spectral techniques. The binding of these probes with DNA was investigated using spectral (Electronic, fluorescence, ¹H NMR and circular dichroism) and molecular docking studies. These probes exhibited a strong fluorescence around 440?nm upon excitation around 380?nm. Electronic and competitive fluorescence titration studies, in HEPES [(4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid)] buffer/dimethyl sulfoxide (pH 7.4) medium, suggest that these probes bind strongly to DNA, which is substantiated by ¹H NMR study. The binding constants are calculated to be 5.3?×?10⁷ and 6.8?×?10⁶ M^?1 for R1 and R2, respectively. From the results of spectral studies, it is proposed that the mechanism of binding of these probes with DNA is through minor groove binding mode, which is further confirmed by circular dichroism and molecular docking studies. Initial cell viability screening using MTT (3-[4,5-methylthiazol-2-yl]-2,5-diphenyl-tetrazolium bromide) assay shows that normal Vero cells are viable towards these probes at nano molar concentration, which is the concentration range employed in the present study for DNA staining (IC₅₀ in the order of 0.023?mM). The enhancement in fluorescence intensity of these probes upon binding with DNA enables the staining of DNA in agarose gel in gel electrophoresis experiment. The sensitivity of these probes is comparable with that of ethidium bromide and DNA amounts as low as 4 nano gram are detectable.

Communicated by Ramaswamy H. Sarma     

Multiple oligo(A) tracts associated with inactive sea urchin maternal mRNA sequences

Maternal RNA of sea urchin eggs and embryos was analyzed for short poly(A) sequences by digesting hybrids formed between [³H]poly(U) and poly(A) with RNase at 4°C. When the undigested [³H]poly(U) is precipitated with CTAB, all (A)_n tracts longer than 6 nucleotides are detected. This assay revealed a poly(A) content severalfold higher than is obtained with a similar assay using RNase at higher temperatures. On polyacrylamide gel electrophoresis, most of the previously undetected (A)_n tracts ran as a peak of oligo(A) of less than 20 nucleotides which accumulated at the dye front. The oligo(A) sequences were resolved into a single peak of (A)₁₀ when sized on Sephadex G100. These (A)₁₀ sequences were associated with large mRNA-sized molecules of about 3000 nucloetides average length which comprised 0.5 to 2% of the total maternal RNA. However, the (A)₁₀ sequences were not in mRNA molecules containing 3′-terminal poly(A) of 50–120 nucleotides nor did they remain in RNA that entered polysomes upon fertilization. However, hybridization studies showed that all sequences represented in the maternal poly(A)-containing RNA appeared to be present in the RNA molecules containing only (A)₁₀ sequences. The results suggest that the (A)₁₀-containing RNA might be incompletely processed mRNA precursor-like molecules.     

Gel purification of radiolabeled nucleic acids via phosphorimaging: Dip-N-Dot

RNA and DNA oligonucleotides radiolabeled with ³²P or ³³P often require gel electrophoresis to remove undesired side and/or degradation products. Common ways to visualize these molecules after electrophoresis are by ultraviolet (UV) shadowing, which necessarily reduces the specific activity of the oligonucleotide, and by autoradiography using film, which is cumbersome and increases the cost of generating the radiolabeled molecule. A more cost-effective method is to physically inject the gel with a “Dip-N-Dot” solution of dye and radionuclide after electrophoresis but prior to phosphorimaging. The gel can be overlaid on its computer-generated image, allowing the labeled molecules to be visualized quickly.     

Synthesis,DNA Binding,and Oxidative Cleavage Studies of Fe(II) and Co(III) Complexes Containing Bioactive Ligands

The two complexes containing bioactive ligands of the type and [Fe(L)] (PF₆)₂ (1) (where L = [1-{[2-{[2-hydroxynaphthalen-1-yl)methylidine]amino}phenyl)imino] methyl}naphthalene-2-ol]) and [Co(L₁L₂)] (PF₆)₃ (2) (where L₁L₂ = mixed ligand of 2-seleno-4-methylquinoline and 1,10-phenanthroline in the ratio 1:2, respectively) were synthesized and structurally characterized. The DNA binding property of the complexes with calf thymus DNA has been investigated using absorption spectra, viscosity measurements, and thermal denaturation experiments. Intrinsic binding constant K_b has been estimated at room temperature. The absorption spectral studies indicate that the complexes intercalate between the base pairs of the CT-DNA tightly with intrinsic DNA binding constant of 2.8 × 10⁵ M^?1 for (1) and 4.8 × 10⁵ M^?1 for (2) in 5 mM Tris-HCl/50 mM NaCl buffer at pH 7.2, respectively. The oxidative cleavage activity of (1) and (2) were studied by using gel electrophoresis and the results show that complexes have potent nuclease activity.     

The isolation of IS1 and IS2 DNA

Summary DNA of the IS-elements IS1 and IS2 was prepared by digestion of appropriate heteroduplex molecules with endonuclease S1, followed by sucrose gradient centrifugation or gel electrophoresis. The material obtained is homogeneous with regard to size. The length of IS1 DNA is 820±65 nucleotides, the length of IS2 DNA is 1.350±70 nucleotides. IS1 DNA is not cleaved by the restriction endonucleases Eco R1, Hind II or Hind III. IS2 DNA is cleaved once by each of the two latter enzymes. The buoyant density determined by equilibrium centrifugation of Hg-complexes in Cs₂SO₄ corresponds to a GC content of approximately 50%. Labelling with polynucleotide kinase indicates that both IS DNA's have a guanosyl residue at both of their 5-termini.     

High-speed electrophoretic separation of DNA fragments using a short capillary

Capillary electrophoresis using a replaceable gel buffer was applied to the separation of DNA fragments. A short effective length capillary (1–2 cm) at low electric field allowed the separation of a 20–1000 bp ladder in 1 min. Although similar separation speed was achieved with a longer capillary at high field, the resolution of larger fragments was degraded. The short effective length capillaries were able to separate the wildtype and mutant PCR products of the TGF-β₁ gene in under 45 s.     

Solution Structures of the Huntington's Disease DNA Triplets, (CAG)n

Summary

Highly polymorphic DNA triplet repeats, (CAG)_n, are located inside the first exon of the Huntington's disease gene. Inordinate expansion of this repeat is correlated with the onset and progression of the disease. NMR spectroscopy, gel electrophoresis, digestion by single-strand specific PI enzyme, and in vitro replication assay have been used to investigate the structural basis of (CAG)_n expansion. Nondenaturing gel electrophoresis and ID ¹H NMR studies of (CAG)₅ and (CAG)₆ reveal the presence of hairpins and mismatched duplexes as the major and minor populations respectively. However, at high DNA concentrations (i.e., 1.0–2.0 mM that is typically required for 2D NMR experiments) both (CAG)₅ and (CAG)₆ exist predominantly in mismatched duplex forms. Mismatched duplex structures of (CAG)₅and (CAG)₆ are useful, because they adequately model the stem of the biologically relevant hairpins formed by (CAG).,. We, therefore, performed detailed NMR spectroscopic studies on the duplexes of (CAG)₅ and (CAG)₆. We also studied a model duplex, (CGCAGCG)₂ that contains the underlined building block of the duplex. This duplex shows the following structural characteristics: (i) all the nucleotides are in (C2′-endo, anti) conformations, (ii) mismatched A?A base pairs are flanked by two Watson-Crick G?C base pairs and (iii) A?A base pairs are stably stacked (and intra-helical) and are formed by a single N6-H—N1 hydrogen bond. The nature of A?A pairing is confirmed by temperature-dependent HMQC and HMQC-NOESY experiments on the [(CA*G)₅]₂ duplex where the adenines are ¹⁵N-labeled at N6. Temperature-and pH-dependent imino proton spectra, nondenaturing electrophoresis, and PI digestion data demonstrate that under a wide range of solution conditions longer (CAG)_n repeats (n>10) exist exclusively in hairpin conformation with two single-stranded loops. Finally, an in vitro replication assay with (CAG)₈₂₁ inserts in the Ml3 single-stranded DNA templates shows a replication bypass for the (CAG)₂₁ insert but not for the (CAG)₈ insert in the template. This demonstrates that for a sufficiently long insert (n=21 in this case), a hairpin is formed by the (CAG)., even in presence of its complementary strand. This observation implies that the formation of hairpin by the (CAG)_n may cause slippage during replication and thus may explain the observed length polymorphism.     

Denaturing Urea Polyacrylamide Gel Electrophoresis (Urea PAGE)

Urea PAGE or denaturing urea polyacrylamide gel electrophoresis employs 6-8 M urea, which denatures secondary DNA or RNA structures and is used for their separation in a polyacrylamide gel matrix based on the molecular weight. Fragments between 2 to 500 bases, with length differences as small as a single nucleotide, can be separated using this method¹. The migration of the sample is dependent on the chosen acrylamide concentration. A higher percentage of polyacrylamide resolves lower molecular weight fragments. The combination of urea and temperatures of 45-55 °C during the gel run allows for the separation of unstructured DNA or RNA molecules.In general this method is required to analyze or purify single stranded DNA or RNA fragments, such as synthesized or labeled oligonucleotides or products from enzymatic cleavage reactions.In this video article we show how to prepare and run the denaturing urea polyacrylamide gels. Technical tips are included, in addition to the original protocol ^1,2.     

DNA of a new parvo-like virus isolated from the silkworm,Bombyx mori

Parvo-like virus, which was designated as “Ina-flacherie virus (Ina-FV),” was isolated from the silkworm, Bombyx mori, and the properties of its DNA were characterized. Purified Ina-FV had a diameter of 22 ± 0.5 nm and a sedimentation coefficient of 102 S. On density gradient separation in CsCl, particles were found at densities of 1.40 and 1.45 g/ml. The DNA content of Ina-FV was 28 ± 2%. The DNA in low-salt buffer possessed properties typical of a single-stranded (ss) molecule. Double-stranded (ds) DNA was extracted under conditions of appropriate high salt and elevated temperature. Electron microscopical examination revealed that the ds DNA was composed of linear molecules with an average length of 1.7 μm and other less well-defined structures. The linear ds molecule had a molecular weight of about 3.4 × 10⁶ determined by electron microscopy (EM) and agarose gel electrophoresis. When the ds DNA was alkali-denatured and examined in an EM, linear ss molecules with approximate length of 1.7 μm were observed, indicating that the linear ds molecule was formed from the annealing of the linear ss molecules of unit length. These data suggest that Ina-FV is closely related to members of the densovirus subgroup.