Abolition of Intrinsically Bent DNA Structure Components in AT Clusters by Netropsin Interaction; Titration Viscometric Investigations

Abstract

It is argued that the enhancement of the apparent DNA contour length by the specifically binding non-intercalating drug netropsin (Nt) (Reinert et al., NAR 9,2335, 1981) at very low Nt/DNA-phosphate ratios essentially is the result of an abolition of periodically arranged intrinsic helix bends in A · T rich tracts of base pairs.

In the preceding paper the existence of pronounced DNA tertiary structure components has been postulated for (two species of) natural eukaryotic DNA. The resulting model suggests local apparent solenoid-related DNA tertiary structure components at high sodium ion concentration c_s, partly/totally molten out at 45/60 C. With decreasing c_s the tertiary structure components have been found to be gradually reduced, at least below c_s = 0.010 M, as titration viscometrically revealed by a gradual rise of the apparent DNA contour length (Reinert et al., JBSD 9, 537, 1991).

Hence, we performed titration viscometric analyses about Nt interaction with calf thymus DNA (ctDNA) at c_s = 0.075 M, 0.010 M and 0.004 M Na⁺. The concomitant DNA conformational changes are quantitatively described in terms of the relative changes of both DNA persistence length and hydrodynamically operative apparent DNA contour length for the three first resolved interaction modes below a Nt/DNA-P ratio of 0.03.

These experiments, together with previous respective analyses at c_s = 0.20 M Na⁺ and different temperatures (I.e.), suggest that those DNA sites binding Nt most strongly predominantly are responsible for the formation of solenoid-related DNA tertiary structure components. Most probably these are A tract-containing sequences. As the essential factor for their apparent elongation effect at low Na⁺ concentrations, a gradual alteration of the number of base pairs per helix turn seems to occur below c_s = 0.010 M Na⁺ and, concomitantly, a change in phasing between intrinsic helix bends and helix screw.     

Counterion-Type Characteristic Effects on Intrinsic Bending Components of Calf Thymus DNA; Hydrodynamic Investigations

Abstract

This paper stresses structural differences in A · T clusters of the ammonium salt of calf thymus (et) DNA (ctNH₄DNA) and the respective sodium salt, ctNaDNA Sequence mediated intrinsic helix bends of ctNaDNA distributed along the molecule partially randomly and partially phased with the helix screw (accompanying paper), are enhanced in ctNH₄DNA. Additionally, the number of the most strongly bent segments (of A-tract character) is raised in ctNH₄NA by a counterion mediated shift of the equilibrium between at least two local DNA conformations. Nevertheless, the apparent DNA elongation, induced by the abolition of a single apparent solenoid-related DNA tertiary structure component which generates a special intrinsic DNA bend, is the same for NH₄DNA and NaDNA.

These conclusions follow from two independent sets of experimental results:

(1.) Titration viscometric measurements with ctNH₄DNA as a function of the cation concentration in comparison to ctNaDNA (KER et al. JBSD 9, 537 (1991)) and respective DNA conformational analyses.

(2.) Quantitative viscometric analysis of DNA conformational changes on netropsin (Nt) interaction of ctNHjDNA at different temperatures and comparison with the respective data for ctNaDNA (KER et al., NAR 9, 2335 (1981).     

Prokaryotic DNA Methyltransferases: The Structure and the Mechanism of Interaction with DNA

The review considers current views on the function of DNA methyltransferases (MTases) that belong to prokaryotic type II restriction–modification systems. A commonly accepted classification of MTases is described along with their primary and tertiary structures and molecular mechanisms of their specific interaction with DNA (including methylation). MTase inhibitors are also considered. Special emphasis is placed on the flipping of the target heterocyclic base out of the double helix and on the methods employed in its analysis. Base flipping is a fundamentally new type of DNA conformational changes and is also of importance in the case of other DNA-operating enzymes. MTases show unique sequence homology, and are similar in structure of functional centers and in the mechanism of methylation. These data contribute to the understanding of the general biological significance of methylation, since prokaryotic and eukaryotic MTases are structurally and functionally similar.     

Prokaryotic DNA methyltransferases: the structure and the mechanism of interaction with DNA

The review considers current views on the function of DNA methyltransferases (MTases) that belong to prokaryotic type II restriction-modification systems. A commonly accepted classification of MTases is described along with their primary and tertiary structures and molecular mechanisms of their specific interaction with DNA (including methylation). MTase inhibitors are also considered. Special emphasis is placed on the flipping of the target heterocyclic base out of the double helix and on the methods employed in its analysis. Base flipping is a fundamentally new type of DNA conformational changes and is also of importance in the case of other DNA-operating enzymes. MTases show unique sequence homology, and are similar in structure of functional centers and in the mechanism of methylation. These data contribute to the understanding of the general biological significance of methylation, since prokaryotic and eukaryotic MTases are structurally and functionally similar.     

Interaction of the Escherichia coli HU protein with DNA. Evidence for formation of nucleosome-like structures with altered DNA helical pitch

Nuclease digestion studies of DNA bound to the histone-like protein HU show that cuts in each strand of the DNA double helix are made with a periodicity of 8.5 base-pairs. By contrast, similar digestions of DNA in eukaryotic nucleosomes show a repeat of 10.4 base-pairs. This and other results (including circular dichroism studies) are consistent with the proposal that the pitch of the DNA double helix in the HU complex is reduced from a repeat length of 10.5 to 8.5 base-pairs per helical turn. Simultaneously, the DNA in the HU-DNA complex containing two dimers of HU per 60 base-pairs has its linking number decreased by 1.0 turn per 290 base-pairs. From these changes it is calculated that HU imposes a DNA writhe of 1.0 per three to four monomers of HU. The results suggest a model in which DNA is coiled in left-handed toroidal supercoils on the HU complex, having a stoichiometry resembling that of the half-nucleosome of eukaryotic chromatin. An important distinction is that HU complexes can restrain the same number of DNA superhelical turns as eukaryotic nucleosomes, yet the DNA retains more negative torsional tension, just as is observed in prokaryotic chromosomes in vivo. Another distinction is that HU-DNA complexes are less stable, having a dissociation half-life of 0.6 min in 50 mM-NaCl. This last property may explain prior difficulties in detecting prokaryotic nucleosome-like structures.     

Computer graphics program to reveal the dependence of the gross three-dimensional structure of the B-DNA double helix on primary structure.

Programs are presented to plot the gross three-dimensional structure of the DNA double helix with the base sequence as input information. The rules that determine the overall structure of the double helix are those that predict the dependence of local helix parameters (specifically, helix twist angle and relative basepair roll angle) on sequence. For this purpose, the user can select either the Calladine-Dickerson parameters or the Tung-Harvey parameters. These programs can be used as tools to investigate the variation of DNA tertiary structure with sequence, which may play an important role in the sequence-specific recognition of DNA by proteins.     

A new class of site-specific endodeoxyribonucleases. Endo.Sce I isolated from a eukaryote, Saccharomyces cerevisiae

We had found that yeasts had intracellular endodeoxyribonucleases that cut phage DNA into a set of double-stranded fragments with discrete chain lengths. We purified one of them to apparent homogeneity from Saccharomyces cerevisiae and designated it Endo.Sce I. Sequence analysis around 5 cleavage sites in plasmid DNA and phage DNA revealed that Endo.Sce I cuts a defined phosphodiester bond in each strand of double helix at the cleavage sites and produces free cohesive ends consisting of 4 nucleotides protruding at 3'-termini. However, unlike in the case of prokaryotic type II-restriction endonucleases, (i) Endo.Sce I seems to consist of two nonidentical subunits, (ii) no common palindrome or consensus sequence including more than 5 base pairs is detected at or near these cleavage sites, and (iii) Endo.Sce I can cut the DNA isolated from the cells that produced Endo.Sce I. All of the 5 cleavage sites are included in inverted repeats, but these inverted repeats are variable in size, nucleotide sequence, and distance between repeating units. An inverted repeat itself is not a structure recognized by Endo.Sce I. This study shows that Endo.Sce I is the first example of eukaryotic site-specific endonuclease and has properties, as described above, which distinguish it from prokaryotic restriction endonucleases.     

Bent DNA structures associated with several origins of replication are recognized by a unique enzyme from trypanosomatids.

Sequence-directed bending of the DNA double helix is a conformational variation found in both prokaryotic and eukaryotic organisms. The utilization of bent DNA structures from various sources as specific signals recognized by an enzyme is demonstrated here using a unique endonuclease purified from trypanosomatid cells. Crithidia fasciculata nicking enzyme was previously shown to recognize specifically the bent structure found in kinetoplast DNA minicircles. The binding constant measured for this specific interaction is of two orders of magnitude higher than that measured for the binding of the enzyme to a non-curved sequence. As determined by binding competition and mobility shift electrophoresis analyses, this enzyme recognizes the sequence-directed bends associated with the origins of replication of bacteriophage lambda and simian virus 40 (SV40), as well as that located within the autonomously replicating sequence (ARS1) region of the yeast S. cerevisiae.     

Cdc45: the missing RecJ ortholog in eukaryotes?

DNA replication is one of the most ancient of cellular processes and functional similarities among its molecular machinery are apparent across all cellular life. Cdc45 is one of the essential components of the eukaryotic replication fork and is required for the initiation and elongation of DNA replication, but its molecular function is currently unknown. In order to trace its evolutionary history and to identify functional domains, we embarked on a computational sequence analysis of the Cdc45 protein family. Our findings reveal eukaryotic Cdc45 and prokaryotic RecJ to possess a common ancestry and Cdc45 to contain a catalytic site within a predicted exonuclease domain. The likely orthology between Cdc45 and RecJ reveals new lines of enquiry into DNA replication mechanisms in eukaryotes.     

Elucidation of the Biosynthesis of Eicosapentaenoic Acid in the Microalga Porphyridium cruentum (II. Studies with Radiolabeled Precursors)

In the course of the study of the biosynthesis of the fatty acid eicosapentaenoic acid (EPA) in the microalga Porphyridium cruentum, cells were pulse-labeled with various radiolabeled fatty acid precursors. Our data show that the major end products of the biosynthesis are EPA-containing galactolipids of a eukaryotic and prokaryotic nature. The prokaryotic molecular species contain EPA and arachidonic acid at the sn-1 position and C16 fatty acids, mainly 16:0, at the sn-2 positions, whereas in the eukaryotic species both positions are occupied by EPA or arachidonic acid. However, we suggest that both the eukaryotic and prokaryotic molecular species are formed in two pathways, [omega]6 and [omega]3, which involve cytoplasmic and chloroplastic lipids. In the [omega]6 pathway, cytoplasmic 18:2-phosphatidylcholine (PC) is converted to 20:4[omega]6-PC by a sequence that includes a [delta]6 desaturase, an elongation step, and a [delta]5 desaturase. In the minor [omega]3 pathway, 18:2-PC is presumably desaturated to 18:3[omega]3, which is sequentially converted by the enzymatic sequence of the [omega]6 pathway to 20:5[omega]3-PC. The products of both pathways are exported, as their diacylglycerol moieties, to the chloroplast to be galactosylated into their respective monogalactosyldiacylglycerol molecular species. The 20:4[omega]6 in both eukaryotic and prokaryotic monogalactosyldiacylglycerol can be further desaturated to EPA by a chloroplastic [delta]17 ([omega]3) desaturase.     

The structure of the Antennapedia homeodomain determined by NMR spectroscopy in solution: comparison with prokaryotic repressors

The structure of the Antennapedia homeodomain from Drosophila melanogaster was determined by nuclear magnetic resonance spectroscopy in solution. It includes three well-defined helices (residues 10-21, 28-38, and 42-52) and a more flexible fourth helix (residues 53-59). Residues 30-50 form a helix-turn-helix motif virtually identical to those observed in various prokaryotic repressors. Further comparisons of the homeodomain with prokaryotic repressors showed that there are also significant differences in the molecular architectures. Overall, these studies support the view that the third helix of the homeodomain may function as the DNA recognition site. The elongation of the third helix by the fourth helix is a structured element that so far appears to be unique to the Antennapedia homeodomain.     

Tissue-specific distribution of DNA-binding nuclear proteins

The DNA-binding capacity of nuclear proteins of mouse cells was examined by the protein-blotting method. Under conditions in which the lac repressor specifically binds to the lac operator, the DNA-binding nuclear proteins from different tissues showed a tissue-specific distribution, suggesting that the species and amounts of nuclear proteins with DNA binding activity differ in different tissues. When cloned eukaryotic genes were used for binding, eukaryotic DNA showed stronger binding than prokaryotic DNA. Competition experiments suggested that many nuclear proteins have different DNA binding properties from that of the prokaryotic repressor.     

Nuclease S1 analysis of eubacterial 5S rRNA secondary structure

Summary Single-strand-specific nuclease S₁ was employed as a structural probe to confirm locations of unpaired nucleotide bases in 5S rRNAs purified from prokaryotic species of rRNA superfamily I. Limited nuclease S₁ digests of 3- and 5-end-labeled [³²P]5S rRNAs were electrophoresed in parallel with reference endoribonuclease digests on thin allel with reference endoribonuclease digests on thin sequencing gels. Nuclease S₁ primary hydrolysis patterns were comparable for 5S rRNAs prepared from all 11 species examined in this study. The locations of base-paired regions determined by enzymatic analysis corroborate the general features of the proposed universal five-helix model for prokaryotic 5S rRNA, although the results of this study suggest a significant difference between prokaryotic and eukaryotic 5S rRNAs in the evolution of helix IV. Furthermore, the extent of base-pairing predicted by helix IV needs to be reevaluated for eubacterial species. Clipping patterns in helices II and IV appear to be consistent with a secondary structural model that undergoes a conformational rearrangement between two (or more) structures. Primary clipping patterns in the helix II region, obtained by S₁ analysis, may provide useful information concerning the tertiary structure of the 5S rRNA molecule.     

Structure of E. coli 5'-methylthioadenosine/S-adenosylhomocysteine nucleosidase reveals similarity to the purine nucleoside phosphorylases

BACKGROUND: 5'-methylthioadenosine/S-adenosyl-homocysteine (MTA/AdoHcy) nucleosidase catalyzes the irreversible cleavage of 5'-methylthioadenosine and S-adenosylhomocysteine to adenine and the corresponding thioribose, 5'-methylthioribose and S-ribosylhomocysteine, respectively. While this enzyme is crucial for the metabolism of AdoHcy and MTA nucleosides in many prokaryotic and lower eukaryotic organisms, it is absent in mammalian cells. This metabolic difference represents an exploitable target for rational drug design. RESULTS: The crystal structure of E. coli MTA/AdoHcy nucleosidase was determined at 1.90 A resolution with the multiwavelength anomalous diffraction (MAD) technique. Each monomer of the MTA/AdoHcy nucleosidase dimer consists of a mixed alpha/beta domain with a nine-stranded mixed beta sheet, flanked by six alpha helices and a small 3(10) helix. Intersubunit contacts between the two monomers present in the asymmetric unit are mediated primarily by helix-helix and helix-loop hydrophobic interactions. The unexpected presence of an adenine molecule in the active site of the enzyme has allowed the identification of both substrate binding and potential catalytic amino acid residues. CONCLUSIONS: Although the sequence of E. coli MTA/AdoHcy nucleosidase has almost no identity with any known enzyme, its tertiary structure is similar to both the mammalian (trimeric) and prokaryotic (hexameric) purine nucleoside phosphorylases. The structure provides evidence that this protein is functional as a dimer and that the dual specificity for MTA and AdoHcy results from the truncation of a helix. The structure of MTA/AdoHcy nucleosidase is the first structure of a prokaryotic nucleoside N-ribohydrolase specific for 6-aminopurines.     

Electroporation of nucleic acids into prokaryotic and eukaryotic cells by square wave pulses

A novel electroporator is presented that generates adjustable square wave pulses with a maximal pulse strength of 2500 V / 100 A and a pulse length between 0.1 and 15 ms and that efficiently transfects prokaryotic and eukaryotic cells. Various factors influencing DNA transfer into tissue culture cells, embryonic stem cells and E. coli K12 cells were optimized and the respective electrical pulse profiles monitored.     

Studies on the interaction of altromycin B and its platinum(II) and palladium(II) metal complexes with calf thymus DNA and nucleotides

The interaction of the anticancer antibiotic altromycin B and its isostructrural Pt(II) and Pd(II) metal complexes with native calf thymus (CT) DNA was studied using UV-thermal denaturation experiments, circular dichroism spectroscopy and temperature controlled spectrophotometric titrations. Altromycin B stabilizes the double helix by raising the T(m), mainly by intercalation of its chromophore between the base pairs and interacting electrostatically via its sugar moieties with the edges of the DNA helix. Moreover, altromycin B induces a B-->A structural transition of CT DNA. The effect on DNA stability and conformation depends on the metal ion. Pt(II) and Pd(II) complexes induce the B-->A structural transition and stabilize the double helix similarly but they present lower final hyperchromicity due to premelting effects which were caused by intra- and interstrand crosslinking. Thus, a synergic effect of the metal ions to altromycin B-CT DNA interaction is observed in both cases. Altromycin B interacts with 5'-GMP, 5'-AMP and 5'-CMP by electrophilic attack of the opened epoxide ring to the N(7)G, N(1)/N(7)A and N(3)C. Thus, covalent binding between these nucleotides and altromycin B takes place and explain the multiple binding mode suggested by the studies of the interaction of altromycin B and its complexes with DNA. The [Pd(II)-altroB] complex dissociates in the presence of the nucleotides, and various species of Pd(II)-nucleotide complexes, especially with 5'-GMP, are formed. The [Pt(II)-altroB] complex dissociates too, but only one or two species of Pt(II)-nucleotide complexes are formed, and in the case of 5'-AMP interaction the formation of a tertiary altroB-Pt(II)-5'AMP complex is proposed. 5'-TMP reacts very weakly in comparison with the other three nucleotides. These interactions were followed by 1H-NMR.     

Nucleic acid helix-coil transitions mediated by helix-unwinding proteins from calf thymus.

We have studied nucleic acid double helix destabilization mediated by purified calf helix-unwinding proteins, measuring ultraviolet hyperchromicity to detect helix melting. Both calf unwinding protein 1 (UP1) and a high salt eluting protein fraction are found to depress strongly the helix melting temperature (Tm) of the synthetic alternating copolymers poly[d(AT)] and poly[r(AU)], indicating that both DNA and RNA are recognized by these proteins. UP1 also destabilizes natural, GC-containing DNA helices, but to a smaller extent than observed with the above polymers. A simple model is presented to aid in the qualitative interpretation of the data, outlining the expected effect on the helix-coil transition of a protein ligand with differential affinity for the helix or coil form of nucleic acid. The observed helix-destabilizing effect of UP1 is dependent on the protein to nucleic acid ratio in an expected manner. Competition studies demonstrate a low, but appreciable affinity of UP1 for native DNA, opening the possibility that protein-mediated denaturation might be initiated by protein binding to the double helix. "Hairpin" helical regions of denatured DNA are strongly destabilized by UP1. Despite the fact that removal of these hairpin helices might greatly facilitate DNA renaturation, we failed to observe renaturation from the UP1-DNA complex after a switch to helix-stabilizing conditions. Thus, UP1 shows an important difference from its presumed prokaryotic analogue, T4 gene 32-protein. Possible in vivo functions of the calf proteins are discussed in light of these observations.     

DNA polymerase delta: a second eukaryotic DNA replicase

During the past few years significant progress has been made in our understanding of the structure and function of the proteins involved in eukaryotic DNA replication. Data from several laboratories suggest that, in contrast to prokaryotic DNA replication, two distinct DNA polymerases are required for eukaryotic DNA replication, i.e. DNA polymerase delta for the synthesis of the leading strand and DNA polymerase alpha for the lagging strand. Several accessory proteins analogous to prokaryotic replication factors have been identified and some of these are specific for pol delta whereas others affect both DNA replicases. The replicases and their accessory proteins appear to be highly conserved in eukaryotes, as homologous proteins have been found in species ranging from humans to yeast.