Structural characteristics (reassociation and melting kinetics) of kinetoplast DNA from Crithidia oncopelti

A highly purified associate of kinetoplast DNA is isolated from C. oncopelti, and its physico-chemical properties are studied. Both native associate and its ultrasonic fragments are found to have a complex character of melting. 5-6 melting zones (3 of them being the main) are found on the melting curve. Analysis of reassociation kinetics of sonicated associate of kinetoplast DNA has revealed the presence of at least two components: fast reassociating component (65-70% of complex DNA), which reassociation kinetics is equivalent to the unique sequence with molecular weight of 2.3. - 10(6) daltons, and slow reassotiating component (15% of complex DNA), having reassociation kinetics equivalent to unique sequence of 26 - 10(6) daltons. The data obtained suggest that complex associate of kinetoplast DNA is heterogenous for its nucleotide sequence and base composition.     

Structure of mitochondrial DNA from Paramecium tetraurelia

Mitochondrial DNA (mtDNA) from endosymbiote-free stocks of Paramecium tetraurelia was isolated by 2 procedures. The buoyant density of the mtDNA in neutral CsCl was 1.702 gm/cm3, a value consistent with the melting temperature of the mtDNA. Only linear molecules were observed by electron microscopy. These molecules were homogeneous in size with a monomer molecular weight of 25.6 x 10(6) daltons. The size of the mtDNA determined after digestion with the restriction endonucleases EcoRI or Hind III agreed with the value obtained by electron microscopy. These studies also revealed that the digestion pattern of mtDNA from stock 172 differed from that of other 3 stocks (51, 127, 203) examined. Some mtDNA molecules exhibited snapback reassociation following denaturation.     

Structure of Mitochondrial Dna From Paramecium Tetraurelia*

Mitochondrial DNA (mtDNA) from endosymbiote-free stocks of Paramecium tetraurelia was isolated by 2 procedures. the buoyant density of the mtDNA in neutral CsCI was 1.702 gm/cm³. a value consistent with the melting temperature of the mtDNA. Only linear molecules were observed by electron microscopy. These molecules were homogeneous in size with a monomer molecular weight of 25.6 × 10⁶ daltons. the size of the mtDNA determined after digestion with the restriction endonucleases EcoRI or Hind III agreed with the value obtained by electron microscopy. These studies also revealed that the digestion pattern of mtDNA from stock 172 differed from that of the other 3 stocks (51, 127. 203) examined. Some mtDNA molecules exhibited snapback reassociation following denaturation.     

Preparative isolation and study of the reassociation kinetics of a T2 phage DNA fraction containing readily melting regions]

A DNA fraction comprising 6% of total DNA and containing readily-melting regions is isolated from phage T2 DNA using preparative chromatography on MAK columns at T congruent to T m--3 degrees C. Two denaturation regions, differing in the stability for 7 degrees, were observed on this DNA melting curve. A sharp increase of the reassociation rate at initial moments under reassociation temperatures T r approximately less than m --25 degrees C was observed. Thermodynamic characteristics obtained under the repeated melting of DNA fragments after reassociation confirm the fact, that under these reassociation temperatures the incorporation of readily-melting regions into spiral duplexes takes place.     

The reassociation of factor Va from its isolated subunits

Factor Va is an essential cofactor for the activation of prothrombin catalyzed by factor Xa. The cofactor is a heterodimer composed of a light chain and a heavy chain that are associated noncovalently in the presence of divalent metal ions. The kinetics of the formation of factor Va from the isolated and separated subunits was examined by the time-dependent regain in cofactor activity using direct assays of prothrombin activation catalyzed by prothrombinase. The rate of reassociation at saturating concentrations of calcium ions was slow with a strong temperature dependence. The product of the association reaction was indistinguishable from native factor Va on the basis of activity. The second order rate constant for the process at 37 degrees C in the presence of 2 mM CaCl2 was 1.58 X 10(5) M-1.min-1. Manganese ion increased the rate of regain of activity without influencing the extent of the reaction. The previous identification of a single reactive sulfhydryl in each subunit of factor Va permitted the modification of the separated subunits with sulfhydryl-directed fluorophores. Subunit reassociation was directly measured by fluorescence energy transfer using light chain modified with 6-acryloyl-2-dimethylaminonaphthalene (fluorescence donor) and heavy chain modified with fluorescein 5-maleimide (fluorescence acceptor). Fluorescence measurements indicate that the heavy and light chains associate tightly (Kd = 5.9 x 10(-9) M) and reversibly with a stoichiometry of 1:1. The dissociation of the subunits from the cofactor is first order with a rate constant of 1.03 X 10(-3) min-1. These interpretations were confirmed by physical measurements of subunit reassociation by sedimentation velocity studies.     

Sequence arrangement in satellite DNA from the muskmelon

Two fractions of a satellite DNA from the muskmelon (Cucumis melo L.) isolated as a unimodal peak from CsCl gradients, differ in melting properties and complexity as estimated by reassociation kinetics. At 49.8 C, all of the low melting fraction was denatured and all of the high melting fraction was native. There were almost no partially denatured molecules detected in the electron microscope at this temperature. This observation provides direct evidence that the two fractions are not closely linked. We conclude that satellite I, the high t_m, low complexity fraction, exists as a 600-nucleotide sequence in blocks of at least 67 tandem repeats. Since the complexity of the low melting fraction, satellite II, is greater than the size of the molecules in our assay, we can only say that the minimum size of each unit of satellite II is 2.5 × 10⁷ daltons. It is unlikely that any spacer sequences are interspersed with either satellite.     

Isolation and characterization of DNA-DNA and DNA-RNA.

A simple method for the isolation and characterization of DNA-DNA and DNA-RNA hybrid molecules formed in solution was developed. It was based on the fact that, in appropriate salt concentration, such as 5% Na2HPO4, DNA in either double-stranded (DNA-DNA or DNA-RNA) or single-stranded forms, but not free nucleotides, can bind to diethylaminoethylcellulose disc filters (DE81). Thus tested samples were treated with the single-strand-specific nuclease S1 and then applied to DE81 filters. The free nucleotides, resulting from degrading the single-stranded molecules, were removed by intensive washing with 5% Na2HPO4, leaving only the hybrid molecules on the filters. The usefulness of this method was illustrated in dissociation and reassociation studies of viral (SV40) or cellular (NIH/3T3) DNAs and DNA-RNA hybrid molecules. Using this technique the reassociation of denatured SV40 DNA was found to be a very rapid process. Dissociation studies revealed that the melting curves of tested DNAs were dependent on salt concentration. Thus the melting temperatures (tm) obtained for SV40 DNA were 76 degrees C at 1 X SSC (0.15 M NaCl-0.015 M sodium citrate) and 65 degrees C at 0.1 X SSC, and for NIH/3T3 DNA 82 degrees C at 1 X SSC and 68 degrees C at 0.1 X SSC. MuLV DNA-RNA hybrid molecules were formed by annealing in vitro synthesized MuLV DNA with 70S MuLV RNA at 68 degrees C. The melting temperature of this hybrid in the annealing solution was 87 degrees C. Another important feature of this procedure was that, after being selectively bound to the filters, the hybrid molecules could efficiently be recovered by heating the filters for 5 min at 60 degrees C in 1.5-1.7 M KCl. The recovered molecules were intact hybrids as they were found to be completely resistant to S1 nuclease.     

Melting and reassociation of double-stranded RNA of the encephalomyocarditis virus]

The processes of melting and reassociation of double-stranded RNA in dimethylsulfoxide were studied. The addition of a small amount of LiCl results in great results in great reduction of Tm (temperature of melting), whereas the NaCl produces the opposite effect. It is suggested, that LiCl coordinates the molecules of H2O, reducing their activity, and consequently destabilises dsRNA. Mild conditions for melting and reassociation of RNA can be created. It was found that under optimal conditions for dsRNA melting, the degree of strand separation depends on the overall concentration of RNA, irrespective of the type of RNA added to the dsRNA preparation. Reassociation of dsRNA of EMC virus proceeds much faster than that of dsRNA of a related poliovirus. Addition of poly(C) to an annealing mixture slows down the rate of reassociation of EMC dsRNA, producing no effect on the poliovirus dsRNA reassociation. It is suggested that the presence of large poly(C) and poly(G) tracts in the complementary strands of the RNA determines its anomalous fast reassociation. Upon incubation of completely separated strands of EMC dsRNA in a water solution with high ionic strength partially double-stranded aggregates are formed. The formation of aggregates is prevented by addition of poly(A), which indicates that they are produced by "zippening" of a molecule starting with poly(A):poly(U) region. The significance of homopolymeric regions for stability of dsRNA of the EMC virus as well as their role in viral multiplication are discussed.     

Stability of isoenzyme and kinetoplast DNA (k-DNA) patterns in successively cloned Trypanosoma cruzi populations.

Four Trypanosoma cruzi strains from zymodemes A, B, C and D were successively cloned on BHI-LIT-agar-blood (BLAB). Twenty clones from the first generation (F1), 10 from the second (F2) and 4 from the third (F3) from the strains A138, B147 and C231 were isolated. The D150 strain provided 29 F1 and 23 F2 clones. The strains and clones had their isoenzyme and k-DNA patterns determined. The clones from A138, B147 and C231 strains presented isoenzyme and k-DNA patterns identical between themselves and their respective parental strains. Therefore showing the homogeneity and stability of isoenzyme and k-DNA patterns after successive cloning. The D150 strain from zymodeme D (ZD) showed heterogeneity. Twenty-eight out of 29 clones of the first generation were of zymodeme A and only one was of zymodeme C, confirming previous reports that ZD strains consisted of ZA and ZC parasite populations. The only D150 strain clone of zymodeme C showed a k-DNA pattern identical to its parental strain. The remaining clones although similar among themselves were different from the parental strain. Thus the T. cruzi strains had either homonogeneus or heterogeneous populations. The clones produced by successive cloning provided genetically homogeneous populations. Their experimental use will make future results more reliable and reproducible.     

Molecular characterization of an insect genome: Chironomus thummi.

DNA extracted from Chironomus thummi larvae was studied by isopycnic centrifugation in CsCl, thermal denaturation and DNA-DNA reassociation techniques. The mean G+C content of the C. thummi DNA is 28-29% as indicated both by centrifugation in CsCl and thermal denaturation. According to optical reassociation analysis of total DNA and of isolated DNA fractions the C. thummi genome is composed of at least four components. About 80% of the DNA is classified as unique with a kinetic complexity of nearly 7 X 10(10) daltons. 6-8% intermediate DNA exhibits a kinetic complexity slightly above 10(8) daltons with a mean repetition frequency of 35. 11-13% fast-reassociating DNA has a kinetic complexity slightly above 10(6) daltons with a mean repetition frequency of 6000. 3-5% of the DNA cannot be properly studied by the optical reassociation technique and probably contains inverted repeats. The thermal denaturation behaviour of isolated DNA fractions indicated that most of the repetitive sequences in the C. thummi genome are tightly interspersed.     

Isolation and preliminary characterization of the small circular DNA present in African green monkey kidney (BSC-1) cells

The small polydisperse circular DNA (spc-DNA) previously identified in SV40-infected African green monkey kidney (BSC-1) cells (M. G. Rush, R. Eason, and J. Vinograd, 1971, Biochim. Biophys. Acta 228, 585–594.) has been isolated in pure form from uninfected cells. This double-stranded, covalently closed circular DNA contains species ranging in molecular weight from about 0.1 to 4 × 10⁶, although most of the molecules are distributed in an apparently polydisperse population with molecular weights of less than 1 × 10⁶. There are approximately 1000 to 2000 covalently closed small DNA molecules per cell, and their average buoyant density does not appear to differ significantly from that of chromosomal and mitochondrial DNAs. This spc-DNA was resolved by polyacrylamide gel electrophoresis into three distinct bands containing comparatively homogeneous circular DNAs with molecular weights of 200,000, 520,000, and 780,000. However, the reassociation rate of in vitro labeled, denatured spc-DNA suggested a molecular complexity in the range of 1 × 10⁸, and the ability of BSC-1 chromosomal DNA to accelerate greatly the reassociation of about one third of this material indicated the presence of some repetitive chromosomal DNA sequences in spc-DNA.     

DNA contained by two densonucleosis viruses.

The DNA contained by particles of densonucleosis viruses 1 and 2 were analyzed within the particle, and properties of DNA extracted from these particles were determined. The DNA appears to exist as a single-stranded molecule with limited secondary structure within particles, as assessed by spectral changes induced by formaldehyde, melting profiles, and circular dichroism studies. The single-stranded DNA had an apparent molecular weight of 1.9 X 10(6) to 2.2 X 10(6) as assessed by differences in the molecular weight of virus particles and top component and percentage of nucleic acid. DNA extracted from virus particles in low-salt buffers possessed properties typical of a single-stranded molecule. Double-stranded DNA could be extracted from virus particles under appropriate high salt and elevated temperature. The linear double-stranded DNA extracted from both viruses had a molecular weight of about 3.9 X 10(6) to 4.1 ZX 10(6) determined by neutral sedimentation and electron microscopy and an equivalent genome size determined by reassociation kinetics. About 87% of the DNA was homologous between the two viruses.     

Characterization of the genome of the basidiomycete Schizophyllum commune

DNA of Schizophyllum commune was isolated both from mycelial cells and from protoplasts. Nuclear DNA was isolated after solubilization of the mitochondria with the detergent Nonidet. The G + C content of the nuclear DNA was 57%, calculated from its buoyant density (1.7165 g/ml) and from the Tm (77.4 degrees C in 15 mM NaCl/1.5 mM trisodium citrate). The buoyant density of the ribosomal cistrons was 1.707 g/ml. DNA isolated from purified mitochondria had a very low G + C content: 22% (rho = 1.6845 g/ml, Tm = 61.8 degrees C in 15 mM NaCl/1.5 mM trisodium citrate). Analysis of CsCl profiles and melting patterns suggested that mitochondrial DNA contains interspersed (A + T)-rich sequences. From reassociation analysis of sheared nuclear DNA the genome size of S. commune was determined to be 22.8 . 10(9) daltons. A small amount of DNA (0.5 . 10(9) daltons) bound to hydroxyapatite at zero time Cot. 7% of the genome (1.6 . 10(9) daltons) represented repetitive DNA.     

Low molecular weight RNAs hydrogen-bonded to nuclear and cytoplasmic poly(a)-terminated RNA from cultured chinese hamster ovary cells

A group of RNAs 90–100 nucleotides long were isolated by melting them from poly(A)-terminated nuclear or cytoplasmic RNA from cultured Chinese hamster ovary cells. Conditions that favor hydrogen bond formation allowed the reassociation of these low molecular weight RNAs with poly(A)-terminated RNA. The nuclear poly(A)-terminated molecules contained 1.3 moles of the low molecular weight RNAs per mole of poly(A), while the cytoplasmic poly(A)-terminated RNA contained only one seventh as much. These low molecular weight RNAs were also isolated from the total 4S RNA of either the nucleus or cytoplasm by polyacrylamide gel electrophoresis. They formed a prominantly labeled band of RNA in the gels after cells had been labeled with H₃³²PO₄ for 4 hr. The low molecular weight RNAs melted from the nuclear poly(A)-terminated RNA were slightly different (although not necessarily in primary nucleotide sequence) from those melted from the cytoplasmic poly(A)-terminated RNA.     

High diversity in DNA of soil bacteria.

Soil bacterium DNA was isolated by minor modifications of previously described methods. After purification on hydroxyapatite and precipitation with cetylpyridinium bromide, the DNA was sheared in a French press to give fragments with an average molecular mass of 420,000 daltons. After repeated hydroxyapatite purification and precipitation with cetylpyridinium bromide, high-pressure liquid chromatography analysis showed the presence of 2.1% RNA or less, whereas 5-methylcytosine made up 2.9% of the total deoxycytidine content. No other unusual bases could be detected. The hyperchromicity was 31 to 36%, and the melting curve in 1 X SSC (0.15 M NaCl plus 0.015 M sodium citrate) corresponded to 58.3 mol% G+C. High-pressure liquid chromatography analysis of two DNA samples gave 58.6 and 60.8 mol% G+C. The heterogeneity of the DNA was determined by reassociation of single-stranded DNA, measured spectrophotometrically. Owing to the high complexity of the DNA, the reassociation had to be carried out in 6 X SSC with 30% dimethyl sulfoxide added. Cuvettes with a 1-mm light path were used, and the A275 was read. DNA concentrations as high as 950 micrograms ml-1 could be used, and the reassociation rate of Escherichia coli DNA was increased about 4.3-fold compared with standard conditions. C0t1/2 values were determined relative to that for E. coli DNA, whereas calf thymus DNA was reassociated for comparison. Our results show that the major part of DNA isolated from the bacterial fraction of soil is very heterogeneous, with a C0t1/2 about 4,600, corresponding to about 4,000 completely different genomes of standard soil bacteria.(ABSTRACT TRUNCATED AT 250 WORDS)     

High diversity in DNA of soil bacteria

Soil bacterium DNA was isolated by minor modifications of previously described methods. After purification on hydroxyapatite and precipitation with cetylpyridinium bromide, the DNA was sheared in a French press to give fragments with an average molecular mass of 420,000 daltons. After repeated hydroxyapatite purification and precipitation with cetylpyridinium bromide, high-pressure liquid chromatography analysis showed the presence of 2.1% RNA or less, whereas 5-methylcytosine made up 2.9% of the total deoxycytidine content. No other unusual bases could be detected. The hyperchromicity was 31 to 36%, and the melting curve in 1 X SSC (0.15 M NaCl plus 0.015 M sodium citrate) corresponded to 58.3 mol% G+C. High-pressure liquid chromatography analysis of two DNA samples gave 58.6 and 60.8 mol% G+C. The heterogeneity of the DNA was determined by reassociation of single-stranded DNA, measured spectrophotometrically. Owing to the high complexity of the DNA, the reassociation had to be carried out in 6 X SSC with 30% dimethyl sulfoxide added. Cuvettes with a 1-mm light path were used, and the A275 was read. DNA concentrations as high as 950 micrograms ml-1 could be used, and the reassociation rate of Escherichia coli DNA was increased about 4.3-fold compared with standard conditions. C0t1/2 values were determined relative to that for E. coli DNA, whereas calf thymus DNA was reassociated for comparison. Our results show that the major part of DNA isolated from the bacterial fraction of soil is very heterogeneous, with a C0t1/2 about 4,600, corresponding to about 4,000 completely different genomes of standard soil bacteria.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reduction in the rate of DNA reassociation by sequence divergence

An estimate is made of the effect of imperfectly complementary sequences on the rate of reassociation of DNA. Rate measurements are reported for the reassociation of deaminated DNA and for the pairing of DNAs from related bacteria. A method is presented for separating the effect of the incubation temperature on the rate from the effect of sequence divergence. After correction to the optimum incubation temperature, the rate of DNA reassociation appears to be reduced by a factor of two for each 10 deg. C reduction in melting temperature due to sequence divergence. For most typical cases this effect is modest. However it can be quite important for measurements of the relation between the DNAs of different species.     

Herpes simplex virus type 1 Angelotti and a defective viral genotype: analysis of genome structures and genetic relatedness by DNA-DNA reassociation kinetics.

DNA-DNA reassociation kinetics of herpes simplex virus type 1 Angelotti DNA and a class of defective viral DNA revealed that the viral standard genome has a total sequence complexity of about 93 X 10(6) daltons and that a portion of 11 X 10(6) daltons occurs twice on the viral genome. These results agree with structural features of herpes simplex virus type 1 DNA derived from electron microscopic studies and restriction enzyme analyses by several investigators. The defective viral DNA (molecular weight, about 97 X 10(6)) displays a sequence complexity of about 11 X 10(6) daltons, suggesting that the molecule is built up by repetitions of standard DNA sequences comprising about 15,000 base pairs. A 2 X 10(6)-dalton portion of these sequences maps in the redundant region and a 9 X 10(6)-dalton portion maps in the unique part of the standard herpes simplex virus type 1 Angelotti DNA, as could be shown by reassociation of viral standard DNA in the presence of defective DNA and vice versa. No cellular DNA sequences could be detected in defective DNA. A 12% molar fraction of the defective DNA consists of highly repetitive sequences of about 350 to 500 base pairs in length.     

Physico-chemical characteristics of the DNA of the nuclear polyhedrosis virus of the moth Porthetria dispar L

DNA preparations were obtained after dissolving the inclusion bodies, polyhedra virus particles, from the purified bundle virus of Porthetria dispar L. nuclear polyhedrosis. The DNA molecules in the preparations obtained are of different conformation and separate within the CsCl density gradient in the presence of ethidium bromide into supercoiled catenated and relaxed circular molecules (with the admixture of linear molecules). The circular DNA was studied by electron microscopy. The size of virus genome according to the data of reassociation kinetics of DNA is about 100 MD. Estimated on the basis of the values of buoyant density (p) and the melting temperature (Tmelt.) the content of guanine-cytosine pairs (GC pairs) in the viral DNA varies from 61 up to 65 mol%, and in the insect cell DNA--from 38 up to 40 mol%. The viral and cellular DNA are distinctly separated by centrifugation within the CsCl density gradient.     

Association of double-stranded DNA fragments into multistranded DNA structures.

We have previously observed that double-stranded DNA fragments containing a tract of the tandemly repeated sequence poly(CA). poly(TG) can associate in vitro to form stable complexes of low electrophoretic mobility, which are recognized with high specificity by proteins HMG1 and HMG2. The formation of such complexes has since been observed to depend on interactions of DNA with polypropylene surfaces, with the suggestion that the formation of low mobility complexes might be the result of strand dissociation followed by misaligned reassociation of the repetitive sequences. The data presented here show that at high ionic strength the interactions of DNA with polypropylene are sufficiently strong for DNA to remain bound to the polypropylene surface, which suggests that DNA might also be involved in interactions with hydrophobic molecules in vivo. Under such conditions, low-mobility complexes are found only in the material adsorbed to the polypropylene surface, and all DNA fragments are able to form low-mobility structures, whether or not they contain repetitive sequences. Preventing the separation of strands by ligating hairpin loop oligonucleotides at both ends of the fragments does not prevent the formation of low-mobility complexes. Our results suggest two different pathways for the formation of complexes. In the first, dissociation is followed by misaligned reassociation of repetitive sequences, yielding duplexes with single-stranded end regions that associate to form multimeric complexes. In the second, repetitive as well as nonrepetitive DNA molecules bound to polypropylene adopt a conformation with locally unwound regions, which allows interactions between neighboring duplexes adsorbed on the surface, resulting in the formation of low-mobility complexes.