Anisotropic flexibility of DNA and the nucleosomal structure.

Potential energy calculations of the DNA duplex dimeric subunit show that the double helix may be bent in the direction of minor and major grooves much more easily than in other directions. It is found that the total winding angle of DNA decreases upon such bending. A new model for DNA folding in the nucleosome is proposed on the basis of these findings according to which the DNA molecule is kinked each fifth base pair to the side of the minor and major grooves alternatively. The model explains the known contradiction between a C-like circular dichroism for the nucleosomal DNA and the nuclease digestion data, which testify to the B-form of DNA.     

Lamin activity is essential for nuclear envelope assembly in a Drosophila embryo cell-free extract

The role of the Drosophila lamin protein in nuclear envelope assembly was studied using a Drosophila in vitro assembly system that reconstitutes nuclei from added sperm chromatin or naked DNA. Upon incubation of the embryonic assembly extract with anti-Drosophila lamin antibodies, the attachment of nuclear membrane vesicles to chromatin surface and nuclear envelope formation did not occur. Lamina assembly and nuclear membrane vesicles attachment to the chromatin were inhibited only when the activity of the 75-kD lamin isoform was inhibited in both soluble and membrane-vesicles fractions. Incubation of decondensed sperm chromatin with an extract that was depleted of nuclear membranes revealed the presence of lamin molecules on the chromatin periphery. In addition, high concentrations of bacterially expressed lamin molecules added to the extract, were able to associate with the chromatin periphery, and did not inhibit nuclear envelope assembly. After nuclear reconstitution, a fraction of the lamin pool was converted into the typical 74- and 76-kD isoforms. Together, these data strongly support an essential role of the lamina in nuclear envelope assembly.     

The influence of tertiary structural restraints on conformational transitions in superhelical DNA.

This paper examines theoretically the effects that restraints on the tertiary structure of a superhelical DNA domain exert on the energetics of linking and the onset of conformational transitions. The most important tertiary constraint arises from the nucleosomal winding of genomic DNA in vivo. Conformational transitions are shown to occur at equilibrium at less extreme superhelicities in DNA whose tertiary structure is restrained than in unrestrained molecules where the residual linking difference alpha res (that part of the superhelical deformation which is not absorbed by transitions) may be freely partitioned between twisting and bending. In the extreme case of a rigidly held tertiary structure, this analysis predicts that the B-Z transition will occur at roughly half the superhelix density needed to drive the same transition in solution, other factors remaining fixed. This suggests that superhelical transitions may occur at more moderate superhelical deformations in vivo than in solution. The influence on transition behavior of the tertiary structural restraints imposed by gel conditions also are discussed.     

Nuclear membrane vesicle targeting to chromatin in a Drosophila embryo cell-free system.

A Drosophila cell-free system was used to characterize proteins that are required for targeting vesicles to chromatin and for fusion of vesicles to form nuclear envelopes. Treatment of vesicles with 1 M NaCl abolished their ability to bind to chromatin. Binding of salt-treated vesicles to chromatin could be restored by adding the dialyzed salt extract. Lamin Dm is one of the peripheral proteins whose activity was required, since supplying interphase lamin isoforms Dm1, and Dm2 to the assembly extract restored binding. As opposed to the findings in Xenopus, okadaic acid had no effect on vesicle binding. Trypsin digestion of the salt-stripped vesicles eliminated their association with chromatin even in the presence of the dialyzed salt extract. One vesicles attached to chromatin surface, fusion events took place were found to be sensitive to guanosine 5'-[gamma-thio]triphosphate (GTP gamma S). These chromatin-attached vesicles contained lamin Dm and otefin but not gp210. Thus, these results show that in Drosophila there are two populations of nuclear vesicles. The population that interacts first with chromatin contains lamin and otefin and requires both peripheral and integral membrane proteins, whereas fusion of vesicles requires GTPase activity.     

Histone hyperacetylation facilitates chromatin remodelling in a Drosophila embryo cell-free system

We found that Drosophila embryo extract contains a protein activity (or activities) that can destabilize nucleosomes, resulting in increased sensitivity to DNase I, release of nucleosomal supercoiling, high levels of conformational flexibility of DNA and more diffuse micrococcal nuclease digestion patterns. Incorporation of histone H1 did not significantly affect this nucleosome remodelling. Remodelling occurs more efficiently in hyperacetylated chromatin. It was shown previously that hyperacetylated chromatin, reconstituted in a Drosophila embryo cell-free system, exhibits increased DNase I sensitivity and a high degree of conformational flexibility of DNA. The present data suggest that the more diffuse structure of acetylated chromatin is a result of chromatin remodelling by protein activities in the Drosophila embryo extract. Received: 4 November 1998 / Accepted: 10 May 1999     

DNA replication in cell-free extracts from Drosophila melanogaster.

We have developed an efficient in vitro replication system from 0-2 h Drosophila melanogaster embryos. Demembranated Xenopus sperm DNA when incubated in such an extract first becomes enclosed in a nucleus-like structure with a nuclear envelope and a karyoskeleton. It then undergoes one round of semiconservative replication--this replication appears completely dependent on nuclear formation. Up to 30% of input DNA is nucleated in one reaction. Efficient nuclear formation and replication are dependent on a cold treatment step, prior to disruption of the embryos. They also depend on the age of the embryos used. Extracts from older embryos (0-5 h) are capable of nuclear formation, although at a much reduced efficiency, and repair synthesis, but seem to have lost the ability to initiate DNA replication. In addition to replicating sperm DNA this system appears capable of carrying out semi-conservative replication on some plasmids. However, it cannot use these to trigger nuclear formation; replication is only seen if the plasmids are coincubated with sperm DNA. The in vitro formed nuclei have not been observed to trigger nuclear envelope breakdown and entry into mitosis. However, they can re-replicate the DNA if the nuclei are permeabilized. This system should be a useful complement to the previously isolated Xenopus in vitro replication system. In addition the amenability of Drosophila to genetic study should open up new approaches not previously possible with Xenopus.     

Chromatin reconstitution on small DNA rings. V. DNA thermal flexibility of single nucleosomes.

The thermal flexibility of DNA minicircles reconstituted with single nucleosomes was measured relative to the naked minicircles. The measurement used a new method based on the electrophoretic properties of these molecules, whose mobility strongly depended on the DNA writhe, either of the whole minicircle, when naked, or of the extranucleosomal loop, when reconstituted. The experiment was as follows. The DNA length was first increased by one base-pair (bp), and the correlative shift in mobility resulting from the altered DNA writhe was recorded. Second, the gel temperature was increased so that the former mobility was restored. Under these conditions, the untwisting of the thermally flexible DNA due to the temperature shift exactly compensates for the increase in the DNA mean twist number resulting from the one bp addition. The relative thermal flexibility was then calculated as the ratio between the increases in temperature measured for the naked and the reconstituted DNAs, respectively. The figure, 0.69 (+/- 0.07), was used to derive the length of DNA in interaction with the histones, 109 (+/- 25) bp. Such length was in good agreement with the mean value of 115 bp we have previously obtained from the distribution of the angles between DNAs at the entrance and exit of similar nucleosomes measured from high resolution electron microscopy. This consistency further reinforces our previous conclusion that minicircle-reconstituted nucleosomes, with 1.3(109/83) to 1.4(115/83) turns of superhelical DNA, show no crossing of entering and exiting DNAs when the loop is in its most probable configuration, and therefore, that these nucleosomes behave topologically as "single-turn" particles. The present data are also within the range of values, 50 to 100 bp of thermally rigid DNA per nucleosome, obtained by others for yeast plasmid chromatin, suggesting that the "single-turn" particle notion may be extended to this particular case of naturally-occurring H1-free chromatin. However, these data are quite different from the 230 bp figure derived from thermal measurements of reconstituted H1-free minichromosomes. It is proposed that nucleosome interactions occurring in this chromatin, but not in yeast chromatin, may be partly responsible for the discrepancy.     

Preparation and characteristics of a wheat embryo cell-free extract active in the synthesis of high molecular weight viral polypeptides

Wheat embryo extracts are commonly used in cell-free protein synthesis studies. Soluble inhibitor(s) that diminish aminoacylation of tRNA exist in such extracts. These inhibitors can be effectively removed by prolonged dialysis, provided that proper salt conditions are maintained to ensure stability of the extract. The system, when only partially depleted of inhibitors, does not effectively support translation of certain classes of messengers, i.e., brome mosaic virus RNA 1 and RNA 2. All four proteins expected as the products of translation of BMV RNA, including peptides of molecular weight approaching 120,000, are formed in the fully active system. At limiting concentrations of template, the fully activated system incorporates the following amounts of [¹⁴C]leucine per microgram of template: Qβ RNA, 4.5 pmol; reovirus mRNA, 200 pmol, tobacco mosaic virus RNA, 227 pmol, and brome mosaic virus, up to 350 pmol.     

Competing B-Z and helix-coil conformational transitions in supercoiled plasmid DNA.

The formation of melted regions from A + T-rich sequences and left-handed Z-DNA by alternating purine-pyrimidine sequences will both be facilitated by negative supercoiling, and thus if the sequences are present within the same plasmid molecule they will compete for the free energy of supercoiling. We have studied a series of plasmids that contain either (CG)8 or (TG)12 sequences in either G + C or A + T-rich contexts, by means of two-dimensional gel electrophoresis and chemical modification. We observe both B-Z and helix-coil transitions in all plasmids at elevated temperatures and low ionic strength. The plasmids fall into a number of different classes, in terms of the conformational behavior. As the superhelix density is increased, pCG8/vec ((CG)8 in G + C-rich context) undergoes an initial B-Z transition, followed by melting transitions in sequences remote from the (CG)8 sequence. The two transitions are coupled through the topology of the molecule but are otherwise independent. When the (CG)8 sequence was placed in an A + T-rich context (pCG8/col), the helix-coil transition was perturbed by the presence of the Z-DNA segment. Replacement of the (CG)8 tracts by (TG)12 sequences resulted in a further level of interaction between the transitions. Statistical mechanical modeling of the transitions suggested that at intermediate levels of negative supercoiling the Z-DNA formed by the (TG)12 sequence has a lowered probability due to the helix-coil transition in the A + T-rich sequences. These studies illustrate the complexities of competing conformational equilibria in supercoiled DNA molecules.     

The translation of rabbit hemoglobin messenger RNA in a cell-free extract from chick embryo brain

The translation of rabbit hemoglobin messenger RNA in an unfractionated cytoplasmic extract from chick embryo brain was studied. This translation was not dependent upon reticulocyte-specific factors. An analysis of the product synthesized in vitro with the embryo brain cell-free extract and rabbit hemoglobin messenger RNA by carboxymethyl cellulose chromatography showed that the system was capable of synthesizing both the α and β globin chains. Analysis of the tryptic peptides of the in vitro synthesized α chain by ion-exchange chromatography showed that the embryo brain extract with rabbit hemoglobin messenger RNA was capable of synthesizing the complete α chain of rabbit hemoglobin. The results suggest that no stringent tissue-specific controls exist for the translation of globin messenger RNA and were discussed in this context.     

Applying the stochastic difference equation to DNA conformational transitions: a study of B-Z and B-A DNA transitions

Despite the existence of numerous models to account for the B-Z DNA transition, experimenters have not yet arrived at a conclusive answer to the structural and dynamical features of the B-Z transition. By applying the stochastic difference equation to simulate the B-Z DNA transition, we have shown that the stretched intermediate model of the B-Z transition is more probable than other B-Z transition models such as the Harvey model. This is accomplished by comparing potential energy profiles of various B-Z DNA transition models and calculating relative probabilities based on the stochastic difference equation with respect to length (SDEL) formalism. The results garnered in this article allow for new approaches in determining the structural transition of B-DNA to Z-DNA experimentally. We have also simulated the B-A DNA transition using the stochastic difference equation. Unlike the B-Z DNA transition, the mechanism for the B-A DNA transition is well established. The variation in the pseudorotation angle during the transition is in good agreement with experimental results. Qualitative features of the simulated B-A transition also agree well with experimental data. The SDEL approach is thus a suitable numerical technique to compute long-time molecular dynamics trajectory for DNA molecules.     

Determinants of precatalytic conformational transitions in the DNA cytosine methyltransferase M.HhaI

The DNA methyltransferase M.HhaI is an excellent model for understanding how recognition of a nucleic acid substrate is translated into site-specific modification. In this study, we utilize direct, real-time monitoring of the catalytic loop position via engineered tryptophan fluorescence reporters to dissect the conformational transitions that occur in both enzyme and DNA substrate prior to methylation of the target cytosine. Using nucleobase analogues in place of the target and orphan bases, the kinetics of the base flipping and catalytic loop closure rates were determined, revealing that base flipping precedes loop closure as the rate-determining step prior to methyl transfer. To determine the mechanism by which individual specific hydrogen bond contacts at the enzyme-DNA interface mediate these conformational transitions, nucleobase analogues lacking hydrogen bonding groups were incorporated into the recognition sequence to disrupt the major groove recognition elements. The consequences of binding, loop closure, and catalysis were determined for four contacts, revealing large differences in the contribution of individual hydrogen bonds to DNA recognition and conformational transitions on the path to catalysis. Our results describe how M.HhaI utilizes direct readout contacts to accelerate extrication of the target base that offer new insights into the evolutionary history of this important class of enzymes.     

Initiation of DNA replication in nuclei and purified DNA by a cell-free extract of Xenopus eggs

We demonstrate that cell-free extracts prepared from activated eggs of X. laevis by a method similar to that of Lohka and Masui initiate and complete semiconservative DNA replication of sperm nuclei and plasmid DNA. The efficiency of replication is comparable to that in the intact egg. Under optimal conditions 70%-100% of nuclei, and up to 38% of naked DNA molecules replicate completely. Genuine initiation of replication occurs rather than elongation of preformed primers or priming of irreversibly denatured templates. Rereplication of templates is observed under certain conditions. In addition to replicating DNA, these extracts also assemble nucleus-like structures from naked DNA.     

The thermodynamic parameters of the conformational transitions in Mycoplasma DNA

DNA preparations have been isolated from 10 strains of phytopathogenic mycoplasms and collection culture Achole plasma laidlawii PG-8. Thermodynamic parameters of denaturation changes in the secondary structure (transconformation) of DNA of these mycoplasms have been determined. It is shown that denaturation temperature is 82.3-83.1 degree C and enthalpy of conformational DNA transitions calculated per 1 g of dry substance is 56.2-61.9 J/g. Changes in the enthalpy (delta H) and entropy (delta S) calculated per 1 mol of nucleotide pairs varied in the range of 35.6-39.0 J/m.p. and 995-109.6 J degree m.p. respectively. No linear dependence of transconformational thermal adsorption on the temperature of DNA denaturation of the studied strains of mycoplasms are revealed, which is probably connected with structural peculiarities of DNA of these microorganisms.     

Theoretical analysis of competitive conformational transitions in torsionally stressed DNA

This paper presents a theoretical analysis of the conformation of a torsionally deformed segment of DNA containing two sites susceptible to stress-induced transitions in secondary structure. A mechanical analysis of the ensuing competitive behavior is developed and applied to several phenomena of possible biological relevance. First, a molecular lesion which disrupts base pairing without strand breakage (such as a pyrimidine dimer) is shown to provide an effective nucleation site for further stress-induced denaturation. A competition is established between strand separation at this lesion site and at the A + T-richest portion of the molecule. The relative importance of these two forms of melting is shown to depend upon the A + T-content of the sites involved, segment length, local environmental conditions and the magnitude of the imposed torsional deformation. A possible alternative mode of behavior of a stressed segment of DNA involves transitions from B-form to Z-form. The second application of this theory analyzes the interplay between B → Z transitions and local denaturation in torsionally stressed DNA. Finally, local melting is shown to be energetically preferred over transitions to A-form under physiologically reasonable conditions in vitro, due primarily to the greater degree of unwinding involved in melting.The mechanical theory presented here makes several simplifying assumptions regarding the nature of the transitions and the sequences involved. First, the theory is developed explicitly for the competition between two sites of possible transition, with no further consideration given to conformational degeneracy or sequence effects. These sites are regarded as being uniform in composition. A multistate, heteropolymeric statistical mechanical transition theory is required to account rigorously for degeneracy and the influence of base sequence. A preliminary formulation of such a theory is used to analyze the denaturation of a segment containing a site of disrupted base pairing.