Temperature and salt dependence of the gel migration anomaly of curved DNA fragments.

A series of oligonucleotides of different sequences have been cloned to study DNA curvature. Several DNA fragments containing these oligonucleotides in various numbers of repeats were analyzed in 10% polyacrylamide gels. A strong gel migration anomaly was found for dA4 sequences; a comparably very small but clearly detectable anomaly was observed for dA3 (both in a repeat length of 10 base-pairs). The temperature and salt (NaCl, MgCl2) dependence of the gel migration anomaly of these DNA fragments was measured. While a similar behaviour of all sequences is observed for the addition of NaCl, the temperature and MgCl2 dependence of the anomaly varies with the oligonucleotide sequence. These data are interpreted in terms of local DNA structure changes induced by changes in the temperature and the MgCl2 concentration which affect the planarity of the curved DNA fragments.     

Formation, stability and core histone positioning of nucleosomes reassembled on bent and other nucleosome-derived DNA

DNA originating from chicken erythrocyte mononucleosomes was cloned and sequenced. The properties of nucleosome reconstruction were compared for two cloned inserts, selected on account of their interesting sequence organization, length and difference in DNA bending. Cloned fragment 223 (182 base-pairs) carries alternatively (A)3-4 and (T)4-5 runs approximately every ten base-pairs and is bent; cloned fragment 213 (182 base-pairs) contains a repeated C4-5ATAAGG consensus sequence and is apparently not bent. Our experiments indicate the preference of the bent DNA fragment 223 over fragment 213 to associate in vitro with an octamer of histones under stringent conditions. We provide evidence that the in vitro nucleosome formation is hampered in the case of fragment 213, whereas the reconstituted nucleosomes were equally stable once formed. For the correct determination of the positioning of the histone octamer with regard to the two nucleosome-derived cloned DNA sequences, the complementary use of micrococcal nuclease, exonuclease III and DNase I is a prerequisite. No unique, but rotationally related, positions of the histone octamer were found on these nucleosome-derived DNA fragments. The sequence-dependent anisotropic flexibility, as well as intrinsic bending of the DNA, resulting in a rotational setting of the DNA fragments on the histone core, seems to be a strong determinant for the allowed octamer positions, Exonuclease III digestion indicates a different histone-DNA association when oligo(d(C.G)n) stretches are involved. The apparent stagger near oligo(d(A.T)n) stretches generated by DNase I digestion on reconstituted nucleosome 223 was found to be inverted from the normal two-base 3' overhang to a two-base 5' overhang. Two possibilities of the oligo(d(A.T)n) minor groove location relative to the histone core are envisaged to explain this anomaly in stagger.     

The anomalous gel migration of a stable cruciform: temperature and salt dependence, and some comparisons with curved DNA.

We have made an analysis of the gel electrophoretic properties of a pseudo-cruciform fragment, a linear DNA molecule containing a stable cruciform. The migration of this construct was analysed in polyacrylamide gels at a various temperatures in the range 5 degrees to 55 degrees C, and in the presence of NaCl, MgCl2 or ethidium bromide. The magnitude of the anomalous migration (retardation) was almost temperature independent up to 40 degrees C, but decreased strongly beyond this point, extrapolating to normal migration at 70 degrees C. Addition of salts reduced the anomaly. This took the form of a continuous reduction in anomalous migration with the addition of NaCl up to 60 mM, while with MgCl2 there was a sharp reduction in the anomaly to a constant value which is reached by 10 mM. Under these conditions, moreover, the migration of the fragment became almost temperature-independent over the entire range. These results have been interpreted to reflect the influence of ion binding at the four-way junction on the relative disposition of the cruciform arms. The detailed electrophoretic properties of the pseudo-cruciform are in marked contrast to those of sequence-directed curved DNA fragments. In particular, the response to the addition of 1 microgram/ml ethidium bromide offers a convenient method for distinguishing between anomalous retardation arising from curvature (greatly reduced anomaly) or a cruciform junction (enhanced anomaly).     

Centromere parC of plasmid R1 is curved

The centromere sequence parC of Escherichia coli low-copy-number plasmid R1 consists of two sets of 11 bp iterated sequences. Here we analysed the intrinsic sequence-directed curvature of parC by its migration anomaly in polyacrylamide gels. The 159 bp long parC is strongly curved with anomaly values (k-factors) close to 2. The properties of the parC curvature agree with those of other curved DNA sequences. parC contains two regions of 5-fold repeated iterons separated by 39 bp. We modified 4 bp within this intermediate sequence so that we could analyse the two 5-fold repeated regions independently. The analysis shows that the two repeat regions are not independently curved parts of parC but that the overall curvature is a property of the whole fragment. Since the centromere sequence of an E.coli plasmid as well as eukaryotic centromere sequences show DNA curvature, we speculate that curvature might be a general property of centromeres.     

DNA methylation can enhance or induce DNA curvature.

Oligomers of different palindromic sequences (EcoRI, BamHI, and ClaI linkers) were ligated to form distributions of multimers. These long ligation ladders were methylated using corresponding methylases. The migration of the unmethylated as well as the methylated multimer distributions was analysed in 10% polyacrylamide gels. The migration anomaly of these sequences is interpreted in terms of the curvature of the DNA helix axis. The double-stranded oligomer dCGGAATTCCG is considerably curved in its unmodified form. Its curvature is strongly enhanced when the central dAs are methylated. This result is predicted by a model for DNA curvature. Multimers of the closely related sequence dCGGGATCCCG are straight. When methylated at the central dAs or at the most central dCs, a small curvature of the helix axis is induced. The double-stranded oligomer dCCATCGATGG is straight in its unmodified form as well as when it is methylated. Thus, DNA curvature can be induced or enhanced by methylation. However, DNA methylation at palindromic sequences seems not always to influence the linear path of the DNA helix axis.     

Molecular mechanics calculations of dA12·dT12 and of the curved molecule d(GCTCGAAAAA)4·d(TTTTTCGAGC)4

Using the AMBER software package (Weiner and Kollman 1981) substantially modified for electrostatic contributions, the structural energies of the double-stranded oligonucleotides dA₁₂·dT₁₂ and d(GCTCGAAAAA)₄·d(TTTTTCGAGC)₄ were minimized. Using various starting structures for the molecule dA₁₂·dT₁₂, one final structure is obtained which possesses the experimentally determined properties of poly(dA)·poly(dT). This structure is an A-form-B-form-hybrid structure similar to that of Arnott et al. (1983). The dA-strand is similar to an A-form while the dT-strand is similar to normal B-form. This structure and separately optimized B-form sequence stretches were used to construct the double-stranded fragment d(GCTCGAAAAA)₄ which again was optimized. This sequence, when imbedded in a DNA fragment as contiguous repeats, shows a gel migration anomaly which has been interpreted as stable curvature of the DNA (Diekmann 1986). The calculated structure of this sequence indeed has a curved helix axis and is discussed as a model for curved DNA. A theoretical formalism is presented which allows one to calculate the structural parameters of any nucleic acid double helix in two different geometrical representations. This formalism is used to determine the parameters of the base-pair orientations of the curved structure in terms of wedge as well as cylindrical parameters. In the structural model presented here, the curvature of the helix axis results from an alternation of two different DNA structures in which the base-pairs possess different angles with the helix axis (cylinder tilt). Resulting from geometric restraints, a negative cylinder tilt angle correlates strongly with the closing of the minor groove (wedge roll). The blocks with different structure are not exactly coincident with the dA₅-blocks and the B-DNA stretches. Within the dA₅ block, base-pair tilt and wedge roll adopt large values which proceed into the 3 flanking B-DNA sequence by about one base-pair. These properties of the structure calculated here are discussed in terms of different models explaining DNA curvature.     

A quantitative measure of DNA curvature enabling the comparison of predicted structures

A growing body of data indicates that the equilibrium structures of some DNA fragments are curved and that curvature is sequence-directed. We describe a quantitative measure of DNA curvature that can be used for evaluating and comparing current proposed models for the molecular basis of DNA curvature. We demonstrate that this measure, in conjunction with any given prediction model, enables both the comparison of experimental data to predictions and the scanning of nucleotide sequence databases for potential curved regions.     

A Quantitative Measure of DNA Curvature Enabling the Comparison of Predicted Structures

Abstract

A growing body of data indicates that the equilibrium structures of some DNA fragments are curved and that curvature is sequence-directed. We describe a quantitative measure of DNA curvature that can be used for evaluating and comparing current proposed models for the molecular basis of DNA curvature. We demonstrate that this measure, in conjunction with any given prediction model, enables both the comparison of experimental data to predictions and the scanning of nucleotide sequence databases for potential curved regions.     

Pyrimidine 5-methyl groups influence the magnitude of DNA curvature

DNA containing short sequences of the form (dA)n.(dT)n can exhibit pronounced degrees of stable curvature of the helix axis, provided that these homooligomeric stretches are approximately in phase with the helix repeat. However, the precise origin of this effect is unknown. We have observed that pyrimidine 5-methyl groups can have a significant effect on the degree of curvature, depending on their locations within the homooligomeric sequences. Such effects are observed in both (dA)n.(dT/dU)n and (dI)n.(dC/d5meC)n sequence motifs, arguing for a general structural perturbation due to the methyl group. The current observations suggest that pyrimidine methyl groups could influence protein-DNA interactions not only through direct protein-methyl group contacts but also by methyl group induced alterations in local DNA structure.     

DNA curvature in native and modified EcoRI recognition sites and possible influence upon the endonuclease cleavage reaction

The ligation of a decadeoxynucleotide containing the EcoRI recognition site forms a series of multimers which appear to be curved based on observed anomalous gel migration in polyacrylamide gels. The degree of DNA curvature present in the recognition sequence, based upon the observed migration anomaly, can be altered by modifications to the purine functional groups at the 2- and 6-positions. Deletion of the guanine 2-amino group, occurring in the minor groove of the B-DNA helix, is most effective in increasing the observed DNA curvature. Conversely, the displacement of an amino group from the major groove to the minor groove eliminates curvature. DNA curvature is also modulated by the exocyclic group at the purine 6-position with decreasing curvature observed when changing the amino group to a carbonyl or proton substituent. Differences in the kinetic parameters characterizing the cleavage reaction by the endonuclease for many of the modified sequences are the result of modifications of functional groups in the major groove, which are likely to contact the endonuclease during catalysis. However, with two examples, significant decreases in the observed specificity constant (kcat/Km), characterizing the protein-nucleic acid interaction, cannot be easily explained in terms of such functional group contacts. It is more likely in these cases that the functional group modifications affect the efficiency of the endonuclease-DNA interaction by modulation of the structure of the double-stranded DNA helix. With both examples, modifications have been made to minor groove substituents. The extent of DNA curvature is increased significantly for one and decreased for the other, compared with that observed for the native recognition site. The results suggest that curvature of the DNA helix axis is an intrinsic property of the d(GAATTC) sequence which helps to optimize the protein-nucleic acid interactions observed for the EcoRI restriction endonuclease.     

Environmental influences on DNA curvature

DNA curvature plays an important role in many biological processes. To study environmental influences on DNA curvature we compared the anomalous migration on polyacrylamide gels of ligation ladders of 11 specifically-designed oligonucleotides. At low temperatures (25 degrees C and below) most of the sequences exhibited a degree of anomalous migration. Increased temperature had a significant effect on the anomalous migration (curvature) of some sequences but limited effects on others; at 50 degrees C only 1 sequence migrated anomalously. Mg2+ had a strong influence on the migration of certain sequences, whilst spermine enhanced the anomalous migration of a different set of sequences. Sequences with a GGC motif exhibited greater curvature than predicted by the presently-used angles for the nearest-neighbour wedge model and are especially sensitive to Mg2+. The data have implications for models for DNA curvature and for environmentally-sensitive DNA conformations in the regulation of gene expression.     

Rotational dynamics of curved DNA fragments studied by fluorescence polarization anisotropy

The rotational dynamics of short DNA fragments with or without intrinsic curvature were studied using time-resolved phase fluorimetry of intercalated ethidium with detection of the anisotropy. Parameters determined were the spinning diffusion coefficient of the DNA fragments about the long axis and the zero-time ethidium fluorescence anisotropy. We find a significant decrease in the spinning diffusion coefficient for all curved fragments compared to the straight controls. This decrease is likewise evident in rotational diffusion coefficients computed from DNA structures obtained by a curvature prediction program for these sequences. Using a hinged-cylinder model, we can identify the change in rotational diffusion coefficient with a permanent bend of 13-16 degrees per helix turn for the sequences studied. Moreover, for some of the curved fragments an increased flexibility has to be assumed in addition to the permanent bend in order to explain the data.     

Sequence-dependent kinks induced in curved DNA

In certain curved DNA fragments without AA dinucleotides, the gel retardation anomaly associated with curvature passes through a maximum with fragment length, indicating length (and electric field) dependent structural transitions in the DNA. We suggest that thermally induced stereochemical kinks in DNA are stabilized in the gel, thus relieving the effects of curvature. These kinks are shown to occur specifically at CA/TG and TA/TA stacks. Other physical and biological evidence points to frequent structural dislocations at CA and TA steps. These reversible sequence dependent kinks may therefore represent a novel class of structural protein-DNA recognition elements.     

DNA重复序列的宏观分布趋势

以ＧＣＧ软件和数学模型为工具,用观察到的某ＤＮＡ序列的频数（Ｏ）与理论计算出的此序列频数（Ｔ）的比值（Ｏ／Ｔ）为参数（即相对频数）,将基因资料库（包括ＧｅｎＢａｎｋ和ＥＭＢＬＤａｔａＢａｓｅ）的ＤＮＡ序列进行了分析．结果显示ＤＮＡ重复序列的分布存在着如下趋势：（１）越简单的ＤＮＡ重复序列,其相对频数越高,离平衡分布越远;（２）顺向重复序列的分布的相对频数高于反向重复序列的分布;（３）较长的保守序列的相对频数较高;（４）含ＡＴ碱基对的重复序列的相对频数高于含ＧＣ碱基对的重复序列,在较长的ＤＮＡ重复序列中尤其明显：（５）上述ＤＮＡ重复序列分布的趋势存在种属特异性．     

A refined prediction method for gel retardation of DNA oligonucleotides from dinucleotide step parameters: reconciliation of DNA bending models with crystal structure data

The development and assessment of a prediction method for gel retardation and sequence dependent curvature of DNA based on dinulcleotide step parameters are described. The method is formulated using the Babcock-Olson equations for base pair step geometry (1) and employs Monte Carlo simulated annealing for parameter optimization against experimental data. The refined base pair step parameters define a stuctural construct which, when the width of observed parameter distributions is taken into account, is consistent with the results of DNA oligonucleotide crystal structures. The predictive power of the method is demonstrated and tested via comparisons with DNA bending data on sets of sequences not included in the training set, including A-tracts with and without periodic helix phasing, phased A4T4 and T4A4 motifs, a sequence with a phased GGGCCC motif, some "unconventional" helix phasing sequences, and three short fragments of kinetoplast DNA from Crithidia fasiculata that exhibit significantly different behavior on non-denaturing polyacrylamide gels. The nature of the structural construct produced by the methodology is discussed with respect to static and dynamic models of structure and representations of bending and bendability. An independent theoretical account of sequence dependent chemical footprinting results is provided. Detailed analysis of sequences with A-tract induced axis bending forms the basis for a critical discussion of the applicability of wedge models,junction models and non A-tract, general sequence models for understanding the origin of DNA curvature at the molecular level.     

Characterization of inherent curvature in DNA lacking polyadenine runs.

Sequence-directed DNA curvature is most commonly associated with AA dinucleotides in the form of polyadenine runs. We demonstrate inherent curvature in DNA which lacks AA/TT dinucleotides using the criteria of polyacrylamide gel mobility and efficiency of DNA cyclization. These studies are based upon two 21-base pair synthetic DNA fragments designed to exhibit fixed curvature according to deflections made to the helical axis by non-AA dinucleotide stacks. Repeats of these sequences display anomalously slow migration in polyacrylamide gels. Moreover, both sequences describe helical conformations that are closed into circles by DNA ligase at much smaller sizes than is typical of nondeformed DNA. Chemical cleavage of these DNA molecules with hydroxyl radical is also consistent with local variation in helical conformation at specific dinucleotide steps.     

A small cosmid for efficient cloning of large DNA fragments

The production and use of the 6 kb cosmid pHC79, a derivative of pBR322, is described. It can be used for cloning of fragments cleaved by EcoRI, ClaI, BamHI (also BglII, BclI, Sau3A and MboI), SalI (also XhoI and AvaI), EcaI and PstI. Hybrid cosmids containing inserts in the size range of 40 kb are packaged in vitro and transduced with an efficiency of 5 X 10(4) - 5 X 10(5) clones/microgram of insert DNA. Prefractionation of the DNA fragments to be cloned into 40 kb sized fragments ensures the cloning of contiguous stretches of DNA. Proteins produced in vitro by the cosmid pHC79 are identical to the ones produced by its pBR322 parent.     

A Refined Prediction Method for Gel Retardation of DNA Oligonucleotides from Dinucleotide Step Parameters: Reconciliation of DNA Bending Models with Crystal Structure Data

Abstract

The development and assessment of a prediction method for gel retardation and sequence dependent curvature of DNA based on dinucleotide step parameters are described. The method is formulated using the Babcock-Olson equations for base pair step geometry (1) and employs Monte Carlo simulated annealing for parameter optimization against experimental data. The refined base pair step parameters define a structural construct which, when the width of observed parameter distributions is taken into account, is consistent with the results of DNA oligonucleotide crystal structures. The predictive power of the method is demonstrated and tested via comparisons with DNA bending data on sets of sequences not included in the training set, including A-tracts with and without periodic helix phasing, phased A₄T₄ and T₄A₄ motifs, a sequence with a phased GGGCCC motif, some “unconventional” helix phasing sequences, and three short fragments of kinetoplast DNA from Crithidia fasiculata that exhibit significantly different behavior on non-denaturing polyacrylamide gels. The nature of the structural construct produced by the methodology is discussed with respect to static and dynamic models of structure and representations of bending and bendability. An independent theoretical account of sequence dependent chemical footprinting results is provided. Detailed analysis of sequences with A-tract induced axis bending forms the basis for a critical discussion of the applicability of wedge models, junction models and non A-tract, general sequence models for understanding the origin of DNA curvature at the molecular level.