Separation of ϕX HAE III DNA with electrochromatography

Experimental and theoretical works were performed for the separation of large polyelectrolytes such as DNA in the column packed with gel particles under an electric field. This paper shows how intraparticle convection effects the separation of DNAs in the column because DNAs quickly oriented through the pores in the field direction. Dimensionless transient mass balance equations were derived considering diffusion and electrophoretic convection. The separation criteria is theoretically studied using two different Peclet numbers in the fluid and solid phases and these criteria were verified uing two different DNAs by electrophoretic mobilities measured experimentally, showing how the separation position of DNAs varies in the column according to values ofPe _f/Pe_g of individual DNA. Governing equations are simultaneously solved by operator theoretic and characteristic methods to yield the column response.     

Residence time distribution in the chromatographic column: Applications in the separation engineering of DNA

Experimental and theoretical works were performed for the separation of large polyelectrolyte, such as DNA, in a column packed with gel particles under the influence of an electric field. Since DNA quickly orient in the field direction through the pores, this paper presents how intraparticle convection affects the residence time distribution of DNAs in the column. The concept is further illustrated with examples from solid-liquid systems, for example, from chromatography showing how the column efficiency is improved by the use of an electric field. Dimensionless transient mass balance equations were derived, taking into consideration both diffusion and electrophoretic convection. The separation criteria are theoretically studied using two different Peclet numbers in the fluid and solid phases. These criteria were experimentally verified using two different DNAs via electrophoretic mobility measurements, which showed how the separation position of the DNAs varies in the column in relation to the Peg/Pef values of an individual DNA. The residence time distribution was solved by an operator theory and the characteristic method to yield the column response.     

Restriction enzyme analysis of tomato chloroplast and chromoplast DNA

Plastid DNA was isolated from the chloroplasts of tomato (Lycopersicon esculentum var Traveler 76) leaves and the chromoplasts of ripe tomato fruit. Comparisons of the two DNAs were made by restriction endonuclease analysis using PvuII, HpaI, and Bg1I. No differences in the electrophoretic banding patterns of the restricted plastid DNAs were detected, indicating that no major rearrangements, losses, or gains of plastid DNA accompany the transition from chloroplast to chromoplast.     

High-resolution separation and accurate size determination in pulsed-field gel electrophoresis of DNA. 2. Effect of pulse time and electric field strength and implications for models of the separation process

Bacteriophage DNAs annealed into linear oligomeric concatemers were used to examine the quantitative pulsed-field gel electrophoretic behavior of different-sized DNAs as a function of electrical field strength and pulse time. Three zones of resolution are observed for increasingly larger DNAs. In the first two zones, the electrophoretic mobility decreases linearly with increasing DNA size. The separation in zone 2 is roughly twice that in zone 1. The largest DNA molecules do not resolve at all and migrate in a compression zone. Mobility in zone 1 increases linearly with the electric field strength and decreases with the inverse of the pulse time. The behavior of DNA in zone 2 is qualitatively similar. However, the effect of field strength and pulse time on the separations in each zone is quite different. The results for zone 1 are generally consistent with the predictions of several existing physical models of pulsed-field gel electrophoresis, but no model accounts for all of the observed behavior in the three zones.     

Chromatographic Separation, and Characteristics of Nucleic Acids from HeLa Cells

The application of the phenol-duponol method to extraction of nucleic acids from HeLa cells is described. Chromatography of the phenol extract on an esterified bovine serum albumin column with a salt gradient of sodium chloride gives separation of soluble RNA, DNA, and two different high molecular RNA fractions. Ultracentrifugation of the DNA eluted from the column gives a sedimentation coefficient (s₂₀^o,w) of 38, which agrees with ultracentrifugation data on the phenol extract. The eluted RNA appears polydisperse at low ionic strength, but at high ionic strength and after alcohol precipitation two fractions with the sedimentation coefficients of 16 and 25 to 29, respectively, were obtained.     

Genetic diversity and vegetative compatibility among Trichoderma harzianum isolates

Trichoderma harzianum is the collective name of a set of asexual fungal strains which exhibit heterogeneity in genome structure, DNA sequence and behavior. Contour-clamped homogeneous field (CHEF) electrophoresis of the chromosomes of ten isolates of T. harzianum revealed six clearly distinct electrophoretic karyotypes. Of the ten isolates analyzed, four (GH12, G109, Y and YF) could be classified in a single group with identical karyotypes, while the strains T35 and 315 formed a second group. The genome size characteristic of the different isolates fell into a broad range varying from 29.6 to 56.1?Mb. Gene assignments to the resolved chromosomes showed that all genes analyzed were localized on equivalent chromosomes in the isolates belonging to the same group. Analysis of randomly amplified polymorphic DNAs from the ten isolates confirmed the classification into groups and allowed us to distinguish between isolates T35 and 315, as well as between isolates GH12, G109, Y and YF. Direct confrontation assays using isolates of the same group showed compatible interactions, whereas the same experiment carried out with isolates of different groups showed an incompatible interaction characterized by an area of cell damage. Microscopic observation of the compatible interactions showed hyphal fusions between the isolates, similar to those described for vegetative compatible groups in other fungi. The molecular karyotypes correlated well with the compatibility of the isolates. In addition, we have evaluated both electrophoretic karyotype and randomly amplified polymorphic DNAs analysis as criteria for grouping isolates within the genus according to their capacity for biocontrol of plant pathogens.     

Resolution of α, β and γ DNA of Saccharomyces cerevisiae with the antitumor drug cis-Pt(NH3)2Cl2. Evidence for preferential drug binding by GpG sequences of DNA

This paper reports further studies on the separation of DNAs with the antitumor drug cis-Pt(NH₃)₂Cl₂. cis-Pt(NH₃)₂Cl₂ permits resolution of the three DNA components from whole Saccharomyces cerevisiae in CsCl gradients, avoids pelleting of mitochondrial (β) DNA and does not require a critical molar ratio of platinum drug to DNA-P. However, the difficulty in removing all of the DNA-bound platinum may limit its preparative use. The linear relationship between the increase in buoyant density of platinized double-stranded DNA and its G + C content is employed to calculate a G + C content of 41.2% and 45.8% for α and γ DNA, respectively, using a value of 20% G + C for β DNA. In parallel experiments, we find that poly(dG)·poly(dC), which contains sequential guanine bases, exhibits an unexpectedly large buoyant density increase with cis-Pt(NH₃)₂ Cl₂, while the buoyant density increase of poly[d(G-C)]is markedly retarded, indicating an effect of nucleotide base sequence on DNA separation. The trans platinum compound, which has no antitumor properties, separates DNAs on the basis of G + C content in a similar fashion, but does not preferentially increase the buoyant density of poly(dG)·poly(dC).     

The degree of unwinding of the DNA helix by ethidium. I. Titration of twisted PM2 DNA molecules in alkaline cesium chloride density gradients

A series of covalently closed bacteriophage PM2 DNA samples with varying degrees of superhelicity were prepared in vitro. The amount of bound ethidium per DNA nueleotide needed for the removal of all superhelical turns, v_c⁰, was determined for each sample by a number of methods. In order to evaluate the unwinding angle for the binding of one ethidium molecule to a DNA double helix, the pH dependence of the buoyant densities in CsCI of these samples was examined. A new calibration relating the change in buoyant density of a DNA to the fraction of bases titrated has been obtained, by measuring the buoyant densities of a number of catenanes (interlocked rings) containing both single-stranded and double-stranded λ DNA rings, at a pH such that the single-stranded DNA is fully titrated while the double-stranded DNA is not titrated. This calibration was used to obtain the pH dependence of the fraction of DNA bases titrated for the phage PM2 DNAs with differing extents of supercoiling. A simple theoretical analysis shows that in a restricted pH range close to pH_m, the melting pH of the DNA in the absence of the topological constraint associated with covalently closed double-stranded DNAs, the difference in the fraction of bases titrated at a certain pH between two covalently closed DNAs with different degrees of superhelicity is directly proportional to the difference in the v_c⁰ values of the DNAs. The unwinding angle per bound ethidium molecule can be obtained from the proportionality constant. In this way, it is not necessary to know precisely the actual pH value for either DNA, pH_e, at which the DNA is titrated to the extent that it contains no superhelical turns. The conclusion of the theoretical analysis and the experimental results is that the binding of an ethidium molecule to a double-stranded DNA unwinds the DNA helix by an angle φ_e = 26 °. The uncertainty in this value is estimated to be less than 10%. The new value for φ_e is approximately a factor of two larger than the value 12 °, which has been in use in the past decade. In the earlier alkaline titration results for polyoma DNA (Vinograd et al., 1968), which had been interpreted as supporting the 12 ° value, the calculation of φ_e was critically dependent on knowing pH_e. It is believed that pH_e was underestimated in the earlier work, resulting in a low φ_e value. Since the previous value φ_e = 12 ° has been widely used in the determination of the number of superhelical turns for many DNAs, and in measurements on the angular alterations of the DNA helix by the binding of a variety of small and large molecules and by solvent and temperature changes, the new value φ_e = 26 ° requires proportional adjustments of many previous results.     

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.     

Characterisation of DNA from condensed and dispersed human chromatin

Condensed and dispersed chromatin fractions were isolated from human placental nuclei. The DNA of each fraction was purified and characterised by isopycnic centrifugation, thermal fractionation on hydroxylapatite (HAP) and sequence complexity studies. The DNAs had identical buoyant densities in neutral CsCl (1.698 g/cm³) and similar melting profiles on HAP. Analytical ultracentrifugation in Ag⁺-Cs₂SO₄, however, showed that satellite DNAs were present in the condensed fraction DNA (DNA_C) but were not visible in the dispersed fraction DNA (DNA_D). In addition, DNA_C was found to be enriched in highly reiterated sequences (20% reassociated by C₀t 10^?3) which can be correlated with the presence of satellite DNAs, whereas DNA_D contained only 3% of these fast reassociating sequences. In contrast DNA_D contained 30% intermediate sequences (reassociating between C₀t 10^?3 and C₀t 100) which represent only 10% of DNA_C. The reassociated highly repeated sequences of DNA_C showed the presence of two components in both CsCl density gradients and HAP thermal elution studies. This suggests that either there are sequence relationships resulting in partial mismatching between the different highly repeated DNA sequences in this fraction, or that highly repeated sequences are associated with less repetitious DNA. The results are discussed in terms of possible differences in genetic activity between the chromatin fractions.     

Characterization of Satellite DNA from Three Marine Dinoflagellates (Dinophyceae): Glenodinium sp. and Two Members of the Toxic Genus, Protogonyaulax

Using CsCl-Hoechst dye or CsCl-ethidium bromide gradients, satellite and nuclear DNAs were separated and characterized in three marine dinoflagellates: Glenodinium sp., and two toxic dinoflagellates, Protogonyaulax tamarensis and Protogonyaulax catenella. In all three dinoflagellates, the lowest density fraction, satellite DNA₁, hybridized to chloroplast genes derived from terrestrial plants and/or other algae. Dinoflagellate chloroplast DNAs exhibited molecular sizes of 114 to 125 kilobase pairs, which is consistent with plastid sizes determined for other chromophytic algae (120-150 kilobase pairs). Mitochondrial DNA was not resolved from nuclear DNA in this system. Two additional satellite DNAs, satellite DNA₂ and satellite DNA₃, recovered from P. tamarensis and P. catenella were similar to one another, both within and between species, when characterized by restriction enzyme analysis. These satellites were 85 to 95 kilobase pairs in size, and exhibited restriction fragments that hybridized to yeast nuclear ribosomal RNA genes. Restriction enzyme analyses and DNA hybridization studies of cpDNA document that the two Protogonyaulax isolates are not evolutionarily identical.     

Zonal rate centrifugation of proteoglycans in sucrose gradients

A simple reverse-phase chromatographic system for separating deoxyribonucleoside monophosphates is described. Using isocratic elution at room temperature, clear separation of seven of the deoxyribonucleoside monophosphates that occur in either procaryotic or eucaryotic DNAs can be achieved in less than 2 h. Thus, this method allows a sensitive and rapid analysis of submicrogram quantities of ³²P-labeled deoxyribonucleoside monophosphates derived from DNA labeled in vivo with ³²P_i or from DNA labeled enzymatically in vitro at the 5′ or 3′ ends. The suitability of the method for studying methylation of mammalian DNAs is illustrated by presenting examples of its application to (a) quantitation of major and minor nucleotides in newly synthesized DNA, (b) determination of the specificity of in vitro methylation of DNA, and (c) quantitation of the extent to which specific restriction endonuclease sites are methylated in vivo.     

Contrasting the Chromosomal Organization of Repetitive DNAs in Two Gryllidae Crickets with Highly Divergent Karyotypes

A large percentage of eukaryotic genomes consist of repetitive DNA that plays an important role in the organization, size and evolution. In the case of crickets, chromosomal variability has been found using classical cytogenetics, but almost no information concerning the organization of their repetitive DNAs is available. To better understand the chromosomal organization and diversification of repetitive DNAs in crickets, we studied the chromosomes of two Gryllidae species with highly divergent karyotypes, i.e., 2n(♂) = 29,X0 (Gryllus assimilis) and 2n = 9, neo-X₁X₂Y (Eneoptera surinamensis). The analyses were performed using classical cytogenetic techniques, repetitive DNA mapping and genome-size estimation. Conserved characteristics were observed, such as the occurrence of a small number of clusters of rDNAs and U snDNAs, in contrast to the multiple clusters/dispersal of the H3 histone genes. The positions of U2 snDNA and 18S rDNA are also conserved, being intermingled within the largest autosome. The distribution and base-pair composition of the heterochromatin and repetitive DNA pools of these organisms differed, suggesting reorganization. Although the microsatellite arrays had a similar distribution pattern, being dispersed along entire chromosomes, as has been observed in some grasshopper species, a band-like pattern was also observed in the E. surinamensis chromosomes, putatively due to their amplification and clustering. In addition to these differences, the genome of E. surinamensis is approximately 2.5 times larger than that of G. assimilis, which we hypothesize is due to the amplification of repetitive DNAs. Finally, we discuss the possible involvement of repetitive DNAs in the differentiation of the neo-sex chromosomes of E. surinamensis, as has been reported in other eukaryotic groups. This study provided an opportunity to explore the evolutionary dynamics of repetitive DNAs in two non-model species and will contribute to the understanding of chromosomal evolution in a group about which little chromosomal and genomic information is known.     

Fractionation of microbial DNA strands on poly I-coated kieselguhr

The column chromatographic method employing poly I-coated kieselguhr (IHCK) for partitioning of microbial DNA strands into complementary fractions has been modified for use with AT-type DNAs. Both the original and the modified procedures are given in this paper. DNA sample size may vary from nanograms to milligrams. Partially degraded, denatured DNA specimens (including coliphage T2 DNA) have invariably been separated into two distinct fractions. Comparisons have been made as to the relative length of the separated strands, their base composition and their relative affinity for poly C, in several DNAs with GC contents ranging from 23% (Clostridium perfringens) to 73% (Micrococcus lysodeikticus).     

Molecular recognition of plant DNA: Does it differ from conventional animal DNA?

The recognition mechanism of DNA with small drugs/ligands is an important field of research from pharmacological point of view. Such studies are ample with DNAs extracted from animal cells, but are rare for those extracted from plant cells. However, such a study is strongly demanding for the formulation of pesticides and other agrochemicals. In this contribution, for the first time, we report the interaction of two well-known DNA binder ethidium bromide (EB) and Hoechst 33258 (H33258) with two genomic DNAs extracted from the leaves of Ricinus communis L. (castor bean) and Mangifera indica (mango) using steady-state and picosecond-resolved fluorescence spectroscopy. The purity of the extracted DNAs is confirmed from gel electrophoresis and optical absorption studies. As evidenced from the circular dichroism (CD) measurements the DNAs retain physiologically relevant B forms. The well-known DNA intercalator EB has been found to show an additional electrostatic mode of binding with the DNAs, which is not present in the conventional animal DNAs. The binding affinity of EB is found to be even weaker for the DNA extracted from M. indica compared to that in R. communis L. On the other hand, the binding affinity of H33258 with the plant DNAs is found to be comparable to that of animal DNAs. The difference in interaction could be rationalized from the possible differences in the base sequences.     

Adiabatic Heating of Electrons in the Magnetospheric Current Sheet

Electron dynamics and acceleration in an electromagnetic field configuration modeling the current sheet configuration of the Earth’s magnetotail region is investigated. A focus is made on the role of the dawn?dusk magnetic field component B_y in the convection electron heating by an electric field E_y. For numerical integration of a large number of test particle trajectories over long time intervals, the equations of motion written in the guiding center approximation are used. It is shown that the presence of a B_y ≠ 0 magnetic field significantly changes the electron heating and allows electrons with small pitch angles to gain energy much more efficiently than the equatorial electrons. As a result, the convection heating in the current sheet with B_y ≠ 0 leads to the formation of an accelerated anisotropic population of particles with energies higher than a few hundred electronvolts. The obtained results and spacecraft observations in the Earth’s magnetotail are compared, and possible limitations in the proposed model approaches are discussed.     

Isolation and Characterization of Linear DNA Elements from the Mitochondria of Gaeumannomyces graminis

Different Gaeumannomyces graminis strains of diverse geographic origin contain one or two small DNAs ranging in size from 7.2 to 10 kilobases. These DNAs exhibit different degrees of homology with each other. We have characterized these low-molecular-weight DNAs from one strain, Ha-01. These small DNAs, E1 and E2, are mitochondrial in origin and were isolated as linear molecules which exhibited an intrinsic difference in density from the high-molecular-weight DNA.     

Substrate-specific inhibition of RecQ helicase

The RecQ helicases constitute a small but highly conserved helicase family. Proteins in this family are of particular interest because they are critical to maintenance of genomic stability in prokaryotes and eukaryotes. Eukaryotic RecQ helicase family members have been shown to unwind not only DNA duplexes but also DNAs with alternative structures, including structures stabilized by G quartets (G4 DNAs). We report that Escherichia coli RecQ can also unwind G4 DNAs, and that unwinding requires ATP and divalent cation. RecQ helicase is comparably active on duplex and G4 DNA substrates, as measured by direct comparison of protein activity and by competition assays. The porphyrin derivative, N-methyl mesoporphyrin IX (NMM), is a highly specific inhibitor of RecQ unwinding activity on G4 DNA but not duplex DNA: the inhibition constant (K_i) for NMM inhibition of G4 DNA unwinding is 1.7 µM, approximately two orders of magnitude below the K_i for inhibition of duplex DNA unwinding (>100 µM). NMM may therefore prove to be a valuable compound for substrate-specific inhibition of other RecQ family helicases in vitro and in vivo.     

Properties of SDS-polyacrylamide gels highly cross-linked with N,N'-diallyltartardiamide and the rapid isolation of macromolecules from the gel matrix.

Polyacrylamide gels cross-linked with N,N′-diallyltartardiamide (DATD) are, in contrast to gels cross-linked with N,N′-methylenebisacrylamide (Bis), readily solubilized by periodic acid (Anker, H. S., 1970, FEBS Lett.7, 293), thus permitting efficient analyses of electrophoretically separated, labeled biological material. The capacities of polyacrylamide gels, cross-linked with Bis and DATD, to serve as media for electrophoretic separation of proteins, were compared. As DATD-cross-linked gels were inferior to equimolar Bis-crosslinked gels with 5% cross-linking (C_Bis = 5%) by the criteria of more pronounced swelling, markedly softer gels and, less concentrated and bended protein zones on electrophoresis and subsequent staining, gels cross-linked with different percentage CDATD were examined. The water regain of DATD-cross-linked gels, the retardation coefficients, and free mobilities of different proteins in equimolar Bis- and DATD-cross-linked gels were determined. When the DATD concentration in gels was increased to C_DATD = 27%, gels assumed physical characteristics comparable to those cross-linked with Bis at C_Bis = 5%. We report further the rapid, facile isolation of protein bands out of the gel matrix cross-linked with DATD. However, the isolation procedure results in an irreversible loss of biological activity.