Two-dimensional motion of DNA bands during pulsed-field gel electrophoresis. II. Effect of field angle

In pulsed-field gel electrophoresis, megabase DNAs are well separated if the angle θ between the two electric fields is 120° but not if θ = 90°. To elucidate the molecular basis for this observation, we measured the instantaneous position (x, y) and velocity (v_x, v_y) of a band of G-DNA (670 kb) while the field switched direction, for 90° ≤ θ ≤ 102°. For θ = 120° and long pulse period T. The band retraced the last segment of the preceding pulse before moving in- the new field direction. The retracing wax done at a velocity much greater than the average forward velocity. For θ = 90°, rather than retrace itself, the path during one pulse appeared to originate from a point beyond that reached in the previous pulse, end the velocity showed only a brief backward spike. A Monte Carlo simulation that included tube-length fluctuations and hernias was carried out for a model DNA chain moving through a three-dimensional network of interconnected pores, with parameters corresponding to the DNA size, agarose concentration, and field strength of the experiments, Both the xy path and the instantaneous velocities of the simulation were in excellent agreement with experiment for 90° ≤ θ ≤ 120°. When the field changed direction in the simulation, hernias often advanced from both ends in the new field direction. In the 120° case, those near the erstwhile trailing segments of the chain soon established superiority because chain tension and a component of the new field aided their growth. For θ = 90° and long T, however, segments from the head end were more likely to continue to lead because there was often an excess of relaxed segments there, and no component of the field aided either end. © 1995 John Wiley & Sons, Inc.     

Determination of microbial genome sizes by two-dimensional denaturing gradient gel electrophoresis.

In two-dimensional denaturing gradient gel electrophoresis, DNA is digested with a restriction endonuclease and the resulting DNA fragments are separated as a function of size by conventional agarose gel electrophoresis. Following this first dimension electrophoresis, the fragment distribution is placed at the top of a denaturing gradient slab gel and electrophoresis is carried out parallel to the gradient direction. This second dimension separation is a complex function of the base sequence of each fragment. Analysis of the DNA fragment distribution as a function of fragment size allows the DNA size to be calculated. This method has been applied to calculate three microbial genome sizes: Mycoplasma capricolum, 724 kb; Acholeplasma laidlawii, 1646 kb; and Hemophilus influenzae, 1833 kb.     

Preparation of large quantities of separated strands from simian virus 40 DNA restriction fragments by low-temperature low-salt agarose gel electrophoresis.

We have used agarose gel electrophoresis to separate complementary DNA strands obtained from simian virus 40 DNA restriction fragments produced by HindII and III or by EcoRI and HpaII digestion. By modifying existing methods we have virtually eliminated the problematic renaturation of DNA during electrophoresis. This has allowed us to recover large quantities of separated DNA strands (approximately 20 μg of DNA per 12-mm-diameter preparative tube gel). By using a combination of low temperature and low buffer concentration during electrophoresis, we have also significantly improved the resolution of DNA strands.     

Preliminary genomic characterization of microsporidian Nosema bombycis

In order to characterize the genome of Nosema bombycis, the techniques of karyotyping, pulsed field gel electrophoresis, and polymerase chain reaction were applied. Nosema genomic DNA moved as 23 kb fragment on a standard agarose gel. The karyotype showed four chromosomes, the molecular karyotyping by pulsed field gel electrophoresis also showed four chromosomes. Arbitrarily primed polymerase chain reaction (PCR) with various primers showed amplification products of sizes ranging from 1.6 to 0.15 kb. Polymerase chain reaction with specific primer showed an amplification product of approximately 315 nucleotides. The DNA hybridizations are discussed. This is the first report of its kind on microsporidian Nosema bombycis. The current data can play a major role in elucidating the molecular biology of this parasite. This revised version was published online in July 2006 with corrections to the Cover Date.     

A family of moderately repetitive sequences in mouse DNA.

When mouse DNA is digested to completion with restriction endonuclease Eco R1, a distinct band of 1.3 kb segments comprising about 0.5-3% of the genome is observed upon agarose gel electrophoresis. This DNA is not tandemly repeated in the genome and is not derived from mouse satellite DNA. Restriction endonuclease analysis suggested that the 1.3 kb segments are heterogeneous. Specific sequences were selected from the 1.3 kb segments and amplified by cloning in plasmid pBR322. Southern transfer experiments indicated that three separately cloned mouse DNA inserts hybridized predominantly to the Eco R1 1.3 kb band and to the conspicuous subsegments generated by secondary restriction endonuclease cleavage of the sucrose gradient purified 1.3 kb segments. Segments were also excised by Hha I (Hha I segments) from the chimeric plasmids containing mouse DNA inserts and subjected to restriction endonuclease and cross-hybridization analysis. It was found that the three Hha I segments were different, although two of them exhibited partial sequence homology. Cot analysis indicated that each of the Hha I segments are repeated about 10(4) times in the mouse genome. These findings indicate that a family of related but non-identical, moderately repetitive DNA sequences, rather than a single homogeneous repeat, is present in the 1.3 kb Eco R1 band.     

Low molecular weight DNA in the heteromeric macronuclei of two cyrtophorid ciliates

Summary— The size range of the native DNA molecules in the heteromeric macronuclei of two cyrtophorid ciliates (Trithigmostoma cucullulus, Chilodonella uncinata) was mainly investigated by using agarose gel electrophoresis. Numerous bands superimposed on a continuous spectrum of molecular sizes between about 0.35 kb and 30 kb were resolved by conventional electrophoresis. Species-specific banding patterns indicate a variation between species in the copy number of individual DNA fragments. A slight intra-specific variability of banding patterns can exist. Electrophoretic distributions for two strains of T cucullulus were indeed found to differ by at least one more intense band (‘overamplified’ sequences?). Fractionation by contour-clamped homogeneous electric field (CHEF) gel electrophoresis revealed that the size continum of macronuclear DNA molecules does not extend beyond 60–70 kb. The average size was estimated to be around 4 kb. Unresolved DNA fraction (> 1000 kb) accounted for less than 10% of the mass of cellular DNA entering CHEF gels. Macronuclear ribosomal DNA of each cyrtophorid species was identified by Southern hybridization with a Tetrahymena rDNA probe. The hybridization signal was observed on a single band of low molecular weight DNA. The corresponding size was close to 14.5 kb in Trithigmostoma and 15.5 kb in Chilodonella, which is about twice the size of monomeric rDNA in hypotrichous ciliates. We showed that S1 nuclease resistant duplexes wit half the length of the native rDNA can be formed by rapid renaturation of heat-denatured molecules and hybridized with native rDNA. This strongly suggests that the nucleotide sequence of this rDNA is a large palindrome. Unlike the hypotrichs, macronuclear rDNA in cyrtophorids should be organized into palindromic dimers as in Tetrahymena species.     

家蚕浓核病毒中国株基因组DNA的分离纯化与鉴定

家蚕浓核病毒中国株的正链DNA和负链DNA分别包裹在不同的病毒粒子中,而且两条链的大小不同,经高盐浓度的DNA抽提缓冲液提取后,在琼脂糖凝胶电泳谱中呈现出大小不同的两条带,一条6．4kb,另一条5．8kb。作者分别用高盐和低盐抽提缓冲液提取了家蚕浓核病毒中国株的基因组DNA,意外发现用低盐抽提缓冲液抽提出来的基因组DNA在琼脂糖凝胶电泳谱中仅呈现一条带。推测可能是由于大小不同且不完全互补的正负链,在低盐缓冲液中形成有效的互补,因而呈现一条6．2kb的条带。     

A small (58-nm) attached sphere perturbs the sieving of 40-80-kilobase DNA in 0.2-2.5% agarose gels: analysis of bacteriophage T7 capsid-DNA complexes by use of pulsed field electrophoresis.

Although the icosahedral bacteriophage T7 capsid has a diameter (58 nm) that is 234-fold smaller than the length of the linear, double-stranded T7 DNA, binding of a T7 capsid to T7 DNA is found here to have dramatic effects on the migration of the DNA during both pulsed field agarose gel electrophoresis (PFGE; the field inversion mode is used) and constant field agarose gel electrophoresis (CFGE). For these studies, capsid-DNA complexes were obtained by expelling DNA from mature bacteriophage T7; this procedure yields DNA with capsids bound at a variable position on the DNA. When subjected to CFGE at 2-6 V/cm in 0.20-2.5% agarose gels, capsid-DNA complexes arrest at the electrophoretic origin. Progressively lowering the electrical potential gradient to 0.5 V/cm results in migration; most complexes form a single band. The elevated electrical potential gradient (3 V/cm) induced arrest of capsid-DNA complexes is reversed when PFGE is used instead of CFGE. For some conditions of PFGE, the mobility of capsid-DNA complexes is a function of the position of the capsid on the DNA. During either CFGE (0.5 V/cm) or PFGE, capsid-DNA complexes increasingly separate from capsid-free DNA as the percentage of agarose increases. During these studies, capsid-DNA complexes are identified by electron microscopy of enzymatically-digested pieces of agarose gel; this is apparently the first successful electron microscopy of DNA from an agarose gel.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electrophysiological correlates of rapid escape reflexes in intact earthworms,Eisenia foetida. I. Functional development of giant nerve fibers during embryonic and postembryonic periods

Grids of recording electrodes etched onto printed circuit boards were used for noninvasive recording of medial (MGF) and lateral (LGF) giant nerve fiber spikes in developing earthworms, Eisenia foetida. Stereotyped patterns of throughconducted giant fiber spikes, evoked by light tactile stimulation, were first detectable in the normal crawling embryonic stage and continuned to be detectable throughout postembryonic development. Giant fiber spiking activity in normal crawling embryos was accompanied by stereotyped muscle activity and rapid escape withdrawal, suggesting that giant fiber reflex pathways are functionally intact before the worm hatches. For both the MGF and LFG, several age-de-pendent changes were noted, including the following: increases in spike conduction velocity, increases in giant fiber diameter, and decreases in spike duration. The MGF conduction velocity in normal crawling embryos was 1.1–1.6 m s^?1 (6–7 μm diameter) and increased to 7.0–8.5 m s^?1 (20–25 μm diameter) by 60 days after hatching. The LGF conduction velocity in normal crawling embryos was 0.7–1.1 m s^?1 (2.5–4.0 μm diameter) and increased to 4.0–5.5 m s^?1 (8–14 μm diameter) by 60 days after hatching. During postembryonic development MGF and LGF conduction velocities were linearly related to fiber diameter.     

Moving pictures of DNA released upon lysis from bacteria,chloroplasts, and mitochondria

Summary Cells and organelles suspended in gelled agarose agarose were lysed with detergent and protease, stained with ethidium bromide and their DNA was observed by fluorescence microscopy. The migration of individual DNA molecules during electrophoresis on a microscope slide was recorded on video tape so that moving pictures could be analyzed. The DNA from lysed bacteria (Escherichia coli andAgrobacterium tumefaciens) appeared as a rosette of at least twenty loops of varying size, whereas that from bacterial spheroplasts (E. coli andPseudomonas aeruginosa) appeared as circular forms or rods with many fine filaments of RNA extending toward the anode. The DNA from chloroplasts of watermelon (Citrullus vulgaris) and pea (Pisum sativum) did not appear as a rosette of loops. Many or most of the chloroplast DNA molecules per lysed chloroplast were immobile in the electric field, as if in circular form hooked on agarose fibers. The amount of DNA-fluorescence per watermelon mitochondrial particle was much less than that found for either chloroplasts or bacteria. The appearance of the mitochondrial DNA during electrophoresis was that of linear molecules, no obviously circular forms were evident and no rosette structures were observed.Abbreviations cpDNA chloroplast DNA - DAPI 4,6-diamidino-2-phenylindole - kb kilobase pairs - mtDNA mitochondrial DNA - PFGE pulsed-field gel electrophoresis     

Electrophoresis of DNA in agarose gels. II. Effects of loading mass and electroendosmosis on electrophoretic mobilities

We have investigated several experimental factors which affect the accurate determination of electrophoretic mobilities of circular and linear DNAs in agarose gels. We demonstrate that: (1) The mobility of individual DNA species is affected by the total mass in the sample loaded. The increased mobility and band distortion observed become apparent when the DNA mass exceeds approximately 0.2 μg per 0.15 cm² of surface area in the loading well. (2) The migration velocity of a given DNA species depends on the coefficient of electroendosmosis (?m_r) of the agarose preparations used. In the range 0.081 ≤ ?m_r ≤ 0.441, the DNA migration velocity is proportional to (?m_r)^?0.5.     

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.     

Characterization of two circular plasmids from the marine diatom Cylindrotheca fusiformis: plasmids hybridize to chloroplast and nuclear DNA.

Summary This paper reports the discovery and initial characterization of two small plasmids, pCfl and pCf2, in the marine diatomCylindrotheca fusiformis. Extracted diatom DNA separates into two bands in CsCI-Hoechst 33258 dye gradients. Upon agarose gel electrophoresis of a sample of the upper band of the gradient we observed, in addition to high molecular weight (genomic) chloroplast and mitochondrial DNA, pairs of lower molecular weight bands. These bands contained two species of circular plasmid DNA molecules, as shown by electron microscopy. The nucleotide composition of the plasmids, and chloroplast and mitochondrial DNAs is similar, as indicated by their co-banding in the gradients. They were cloned, and their restriction maps determined, showing that pCfl is 4.27 and pCf2 4.08 kb in size. By hybridization analysis, we showed that pCfl and pCf2 share regions of similarity, but not identity. Neither plasmid hybridizes with mitochondrial DNA. Both plasmids hybridize with chloroplast DNA, and pCf2 also hybridizes with nuclear DNA.     

A systematic study of field inversion gel electrophoresis.

The mobilities of oligomers of phage lambda DNA and of yeast chromosomes in agarose gels during field inversion gel electrophoresis (FIGE) were measured at different pulse times and electric fields. Also the ratios between forward and backward pulse times and/or field gradients were varied. The problem of 'band inversion' during FIGE, leading to an ambiguity in the mobility of large DNA fragments, was solved by using two dimensional gel electrophoresis with different parameters in the first and second dimension. The results are compared with those obtained with other pulsed electrophoresis systems and with a theoretical model.     

Electric birefringence imaging of electrokinetic agarose orientation.

Time-resolved and steady-state electric birefringence imaging with a slow-scan video camera is used to study orientation during DNA agarose gel electrophoresis. The hydrodynamically induced gel distortion is shown to be the major source of birefringence under electrophoresis running conditions and to generate a birefringence image that approximates the image of the DNA concentration gradient in the electric field direction. A fluid kinematic model is presented to describe the spatial distribution of steady-state birefringence and is verified with fluorescence measurements of DNA distribution. The stress-optic coefficient of 1% agarose gel is measured by mechanical compression and used to evaluate the magnitude of the induced strain on the gel during electrophoresis.     

CHARACTERIZATION OF THE NUCLEAR DNA OF HORDEUM VULGARE ROOT HAIRS: AMPLIFICATION DISAPPEARS UNDER SALT STRESS

In Hordeum vulgare L., the nucleus of differentiating root hairs contains amplified, extrachromosomal DNA sequences. Cytophotometry shows that the nuclei of trichoblasts and root hairs grown under normal conditions contain up to 50% more DNA than those grown in 200 mM salt. Although the root hairs develop and differentiate under salt stress, amplification of their nuclear DNA is suppressed. From this, we conclude that amplification is not necessary for differentiation at the cellular level. Characterization of the amplified nuclear DNA of the root hair is based on the physical/chemical nature of the DNA. The amplified sequences separate as a satellite band when total nucleic acids are centrifuged on CsCl gradients. Enzyme restriction of the satellite and main bands with Msp I and Hpa II followed by agarose gel electrophoresis shows that the satellite band is not more highly methylated than the main band. Restriction of the root hair DNA with EcoRI reveals repetitive DNA sequences not seen in similarly restricted whole root, leaf or salt-stressed root hair preparations. While these unique, repetitive sequences in the 2–6 kb region of the gel do not hybridize with ribosomal, chloroplast, or mitochondrial DNAs, RNA hybridization shows that some of them are transcribed. We believe that the amplified sequences are extrachromosomal based on their selective degradation during root hair senescence, their separation as a satellite band and their restriction patterns.     

Transient electric birefringence of agarose gels. I. Unidirectional electric fields

The orientation of agarose gels in pulsed electric fields has been studied by the technique of transient electric birefringence. The unidirectional electric fields ranged from 2 to 20 V/cm in amplitude and 1 to 100 s in duration, values within the range typically used for pulsed field gel electrophoresis (PFGE). Agarose gels varying in concentration from 0.3 to 2.0% agarose were studied. The sign of the birefringence varied randomly from one gel to another, as described previously [J. Stellwagen & N. C. Stellwagen (1989), Nucleic Acids Research, Vol. 17, 1537–1548]. The sign and amplitude of the birefringence also varied randomly at different locations within each gel, indicating that agarose gels contain multiple subdomains that orient independently in the electric field. Three or four relaxation times of alternating sign were observed during the decay of the birefringence. The various relaxation times, which range from 1 to ～ 120 s, can be attributed to hierarchies of aggregates that orient in different directions in the applied electric field. The orienting domains range up to ～ 22 μm in size, depending on the pulsing conditions. The absolute amplitude of the birefringence of the agarose gels increased approximately as the square of the electric field strength. The measured Ker constants are ～ 5 orders of magnitude larger than those observed when short, high-voltage pulses are applied to agarose gels. The increase in the Kerr constants in the low-voltage regime parallels the increase in the relaxation times in low-voltage electric fields. Birefringence saturation saturation curves in both the low- and high-voltage regimes can be fitted by theoretical curves for permanent dipole orientation. The apparent permanent dipole moment increase approximately as the 1.6 power of fiber length, consistent with the presence of overlapping agarose helices in the large fiber bundles orienting in low-voltage electric fields, the optical factor is approximately independent of fiber length. Therefore, the marked increase in the Kerr constants observed in the low-voltage regime is due to the large increase in the electrical orientation factor, which is due in turn to the increased length of the fiber bundles and domains orienting in low-voltage electric fields. Since the size of the fiber bundles and domains approximates the size of the DNA molecules being separated by PFGE, the orientation of the agarose matrix in the applied electric field may facilitate the migration of large DNA molecules during PFGE. © 1994 John Wiley & Sons, Inc.     

Fluctuations in the velocity of individual DNA Molecules during agarose gel electrophoresis

The velocity of the center of mass of individual T4 DNA molecules during agarose gel electrophoresis, computed from digitized video-microscopic images, fluctuated between 0 and 4.5 μm/s after a field E = 5 V/cm was applied; the amplitude of the velocity peaks was twice the averaged steady-state velocity. The velocity fluctuations correlated with changes in molecular configuration. The mean velocity (10 molecules) showed a sharp rise in less than 0.2 s, followed by a shallow minimum and a broad peak, before reaching a plateau. The much smaller amplitude of these oscillatory features demonstrated that the velocity fluctuations of individual molecules were largely, but not entirely, uncorrelated with the onset of the field. The components of the shape tensor S of individual chains, which are a measure of the extension of the chains, were also determined for each image sequence. Only the principal component in the direction of E, S_xx, increased.     

Reversible translocation of antibiotic resistance determinants in Salmonella ordonez.

Summary Salmonella ordonez (BM 2000) codes for kanamycin (Km, aphA), ampicillin (Ap), streptomycin (SmSp: aadA and Sm: aphC), chloramphenicol (Cm), tetracycline (Tc) and sulfornamide (Su) resistances and for production of colicin Ib (Cib). Genetical analysis by incompatibility testing, conjugation, transformation and physical studies using electron microscopy, agarose gel electrophoresis, led us to associate the Km and Cib characters to a 98.7 kilobase (kb) IncII plasmid (pIP565), and the Sm (aphC) and Su determinants to a 8.3 kb plasmid (pIP605). The ApCmSmSp(aadA)SuTc determinants were not associated in BM2000 S. ordonez with a plasmid structure. Following conjugation of S. ordonez to E. coli, the ApCmSmSpSuTc determinants were found stably associated with a single plasmid structure (pIP173, 127.5 kb) belonging to IncII group. Agarose gel electrophoresis of plasmid DNA restriction endonuclease digests and electron microscopy heteroduplex analysis showed that the acquisition of the ApCmSmSpSuTc determinants resulted from the insertion into pIP565 of a 28.8 kb DNA sequence. This sequence coding for ApCmSmSpSuTc resistances in S. ordonez could be translocated either to pIP565 plasmid or to several IncII plasmids but never to plasmids belonging to IncW, IncP or IncFII, suggesting the existence of specific sequences on the IncII receptor plasmids. Mereover, R-determinants were translocated back en bloc from pIP173 to the chromosome of a susceptible S. ordonez. The results were consistent with the presence in BM2000 S. ordonez chromosomal DNA of an integrated translocatable sequence encoding ApCmSmSpSuTc resistances. Such a structural association could account for the stability of these resistances in the Salmonella ordonez serotype.     

Orientation of DNA in agarose gels.

An orientation of the lambda DNA during the electrophoresis in agarose gels was measured by a microscopic linear dichroism technique. The method involved staining the DNA with the dye ethidium bromide and measuring under the microscope the polarization properties of the fluorescence field around the electrophoretic band containing the nucleic acid. It was first established that the fluorescence properties of the ethidium bromide-DNA complex were the same in agarose gel and in a solution. Then the linear dichroism method was used to measure the dichroism of the absorption dipole of EB dye bound to lambda DNA. In a typical experiment the orientation of two-tenth of a picogram (2 x 10(-13)g) of DNA was measured. When the electric field was turned on, the dichroism developed rapidly and assumed a steady state value which increased with the strength of the field and with the size of DNA. A linear dichroism equation related the measured dichroism of fluorescence to the mean orientation of the absorption dipole of ethidium bromide and to an extent to which the orientation of this dipole deviated from the mean. The observed development of dichroism in the presence of an electric field was interpreted as an alignment of DNA along the direction of the field. The increase in the steady state value of dichroism with the rise in the strength of the field and with the increase of the size of DNA was interpreted as a better alignment of DNA along the direction of the field and as a smaller deviation from its mean orientation.