Length-dependent structure formation in Friedreich ataxia (GAA)n*(TTC)n repeats at neutral pH.

More than 15 human genetic diseases have been associated with the expansion of trinucleotide DNA repeats, which may involve the formation of non-duplex DNA structures. The slipped-strand nucleation of duplex DNA within GC-rich trinucleotide repeats may result in the changes of repeat length; however, such a mechanism seems less likely for the AT-rich (GAA)n*(TTC)n repeats. Using two-dimensional agarose gels, chemical probing and atomic force microscopy, we characterized the formation of non-B-DNA structures in the Friedreich ataxia-associated (GAA)n*(TTC)n repeats from the FRDA gene that were cloned with flanking genomic sequences into plasmids. For the normal genomic repeat length (n = 9) our data are consistent with the formation of a very stable protonated intramolecular triplex (H-DNA). Its stability at pH 7.4 is likely due to the high proportion of the T.A.T triads which form within the repeats as well as in the immediately adjacent AT-rich sequences with a homopurine. homopyrimidine bias. At the long normal repeat length (n = 23), a family of H-DNAs of slightly different sizes has been detected. At the premutation repeat length (n = 42) and higher negative supercoiling, the formation of a single H-DNA structure becomes less favorable and the data are consistent with the formation of a bi-triplex structure.

Structure and dynamics of three-way DNA junctions: atomic force microscopy studies.

We have used atomic force microscopy (AFM) to study the conformation of three-way DNA junctions, intermediates of DNA replication and recombination. Immobile three-way junctions with one hairpin arm (50, 27, 18 and 7 bp long) and two relatively long linear arms were obtained by annealing two partially homologous restriction fragments. Fragments containing inverted repeats of specific length formed hairpins after denaturation. Three-way junctions were obtained by annealing one strand of a fragment from a parental plasmid with one strand of an inverted repeat-containing fragment, purified from gels, and examined by AFM. The molecules are clearly seen as three-armed molecules with one short arm and two flexible long arms. The AFM analysis revealed two important features of three-way DNA junctions. First, three-way junctions are very dynamic structures. This conclusion is supported by a high variability of the inter-arm angle detected on dried samples. The mobility of the junctions was observed directly by imaging the samples in liquid (AFM in situ). Second, measurements of the angle between the arms led to the conclusion that three-way junctions are not flat, but rather pyramid-like. Non-flatness of the junction should be taken into account in analysis of the AFM data.

A cruciform structural transition provides a molecular switch for chromosome structure and dynamics.

The interaction between specific sites along a DNA molecule is often crucial for the regulation of genetic processes. However, mechanisms regulating the interaction of specific sites are unknown. We have used atomic force microscopy to demonstrate that the structural transition between cruciform conformations can act as a molecular switch to facilitate or prevent communication between distant regions in DNA. Cruciform structures exist in vivo and they are critically involved in the initiation of replication and the regulation of gene expression in different organisms. Therefore, structural transitions of the cruciform may play a key role in these processes.

Structure of branched DNA molecules: gel retardation and atomic force microscopy studies.

DNA heteroduplexes as models for slipped strand DNA have been analyzed by polyacrylamide gel migration and atomic force microscopy (AFM). All heteroduplexes containing one hairpin or loop have reduced electrophoretic mobilities compared with that expected for their molecular weights. The retarded gel mobility correlates with the formation of a sharp kink detected by AFM. Increasing the hairpin length from 7 bp to 50 bp results in a monotonous decrease in gel mobility of heteroduplexes. This secondary retardation effect appears to depend only on the hairpin size since the AFM data show no dependence of the kink angle on the hairpin length. Heteroduplex isomers with a loop or hairpin in opposite strands migrate with distinct mobilities. Analysis of gel migration of heteroduplexes with altered hairpin orientations as well as of truncated heteroduplexes indicates that the difference in mobility is due to an inherent curvature in one of the long arms. This is confirmed by the end-to-end distance measurements from AFM images. In addition, significant variation of the end-to-end distances is consistent with a dynamic structure of heteroduplexes at the three-way junction. Double heteroduplexes containing one hairpin in each of the complementary strands also separate in a gel as two isomers. Their appearance in AFM showed a complicated pattern of flat representations of the three-dimensional structure and may indicate a certain degree of interaction between complementary parts of the hairpins that are several helical turns apart.

Atomic force microscopy imaging of DNA covalently immobilized on a functionalized mica substrate.

A procedure for covalent binding of DNA to a functionalized mica substrate is described. The approach is based on photochemical cross-linking of DNA to immobilized psoralen derivatives. A tetrafluorphenyl (TFP) ester of trimethyl psoralen (trioxalen) was synthesized, and the procedure to immobilize it onto a functionalized aminopropyl mica surface (AP-mica) was developed. DNA molecules were cross-linked to trioxalen moieties by UV irradiation of complexes. The steps of the sample preparation procedure were analyzed with x-ray photoelectron spectroscopy (XPS). Results from XPS show that an AP-mica surface can be formed by vapor phase deposition of silane and that this surface can be derivatized with trioxalen. The derivatized surface is capable of binding of DNA molecules such that, after UV cross-linking, they withstand a thorough rinsing with SDS. Observations with atomic force microscopy showed that derivatized surfaces remain smooth, so DNA molecules are easily visualized. Linear and circular DNA molecules were photochemically immobilized on the surface. The molecules are distributed over the surface uniformly, indicating rather even modification of AP-mica with trioxalen. Generally, the shapes of supercoiled molecules electrostatically immobilized on AP-mica and those photocross-linked on trioxalen-functionalized surfaces remain quite similar. This suggests that UV cross-linking does not induce formation of a noticeable number of single-stranded breaks in DNA molecules.

Evidence for nonrandom behavior in 208-12 subsaturated nucleosomal array populations analyzed by AFM.

Atomic force microscopy was used to determine the population distributions in reconstituted, subsaturated 208-12 nucleosomal arrays. The features found in these distributions vary with the average nucleosome loading per template molecule (n(av)): at n(av) < 4, the distributions show a single peak whose breadth is equal to that expected for a random loading process; at n(av) = 4-8, the distributions are broader than random distributions and are complex; i.e., they contain multiple peaks and/or shoulders. Moreover, the peaks/shoulders typically occur at two nucleosome intervals, i.e., 2, 4, 6 or 3, 5, 7 nucleosomes. This two-nucleosome periodicity is statistically significant. The precise cause for such discrete features within the distributions is unknown, but at least these features would seem to indicate some pairwise preference in nucleosome occupation at these loading levels. In these intermediate-level (n(av) = 4-8) distributions, the major peak contains a larger fraction of the total templates than a random nucleosome loading process would produce. This feature indicates that at these intermediate population levels there is some tendency for correlated nucleosome loading among the templates. Hyperacetylated nucleosomal arrays show only subtle differences in their population distributions compared to nonacetylated arrays and demonstrate the above features. AFM allows one to study unfixed chromatin arrays; we find that nucleosomes on the 208-12 template demonstrate significant lability when they are not glutaraldehyde-fixed.

Structure and dynamics of supercoil-stabilized DNA cruciforms.

Understanding DNA function requires knowledge of the structure of local, sequence-dependent conformations that can be dramatically different from the B-form helix. One alternative DNA conformation is the cruciform, which has been shown to have a critical role in the initiation of DNA replication and the regulation of transcription in certain systems. In addition, cruciforms provide a model system for structural studies of Holliday junctions, intermediates in homologous DNA recombination. Cruciforms are not thermodynamically stable in linear DNA due to branch point migration, which makes their study using many biophysical techniques problematic. Atomic Force Microscopy (AFM) was applied to visualize cruciforms in negatively supercoiled plasmid DNA. Cruciforms are seen as clear-cut extrusions on the DNA filament with the lengths of the arms consistent with the size of the hairpins expected from a 106 bp inverted repeat. The cruciform exists in two different conformations, an extended one with the angle of ca. 180 degrees between the hairpin arms and a compact, X-type conformation, with acute angles between the hairpin arms and the main DNA strands. The ratio of molecules with the different conformations of cruciforms depends on ionic conditions. In the presence of high salt or Mg cations, a compact, X-type conformation is highly preferable. Remarkably, the X-conformation was highly mobile allowing the cruciform arms to adopt a parallel orientation. The structure observed is consistent with a model of the Holliday junction with a parallel orientation of the exchanging strands.

The Zalpha domain from human ADAR1 binds to the Z-DNA conformer of many different sequences.

Z-DNA, the left-handed conformer of DNA, is stabilized by the negative supercoiling generated during the movement of an RNA polymerase through a gene. Recently, we have shown that the editing enzyme ADAR1 (double-stranded RNA adenosine deaminase, type 1) has two Z-DNA binding motifs, Zalpha and Zbeta, the function of which is currently unknown. Here we show that a peptide containing the Zalpha motif binds with high affinity to Z-DNA as a dimer, that the binding site is no larger than 6 bp and that the Zalpha domain can flip a range of sequences, including d(TA)3, into the Z-DNAconformation. Evidence is also presented to show that Zalpha and Zbeta interact to form a functional DNA binding site. Studies with atomic force microscopy reveal that binding of Zalpha to supercoiled plasmids is associated with relaxation of the plasmid. Pronounced kinking of DNA is observed, and appears to be induced by binding of Zalpha. The results reported here support a model where the Z-DNA binding motifs target ADAR1 to regions of negative supercoiling in actively transcribing genes. In this situation, binding by Zalpha would be dependent upon the local level of negative superhelicity rather than the presence of any particular sequence.

Atomic force microscopic demonstration of DNA looping by GalR and HU.

Regulation of gene transcription in both prokaryotes and eukaryotes involves formation of various DNA-multiprotein complexes of higher order structure through communication between distant regions of DNA. The communication between distant DNA sites occurs by interaction between proteins bound to the sites by looping out the intervening DNA segments. The repression of transcription of two overlapping promoters of the gal operon in Escherichia coli requires Gal repressor (GalR) and the histone-like protein HU. Both in vivo and in vitro data support a proposed HU containing complex responsive to induction in which GalR molecules bound to two distant operator sites interact by looping out DNA. We successfully applied atomic force microscope (AFM) imaging to visualize galDNA complexes with proteins. We report GalR mediated DNA looping in which HU plays an obligatory role by helping GalR tetramerization. Supercoiling of DNA, which is also critical for GalR action, may stabilize the DNA loops by providing an energetically favorable geometry of the DNA.

Visualization of supercoiled DNA with atomic force microscopy in situ.

Tertiary structure of supercoiled DNA is a significant factor in a number of genetic functions and is apparently affected by environmental conditions. We applied atomic force microscopy (AFM) for imaging the supercoiled DNA deposited at different ionic conditions. We have employed a technique for the sample preparation that permits high-resolution AFM imaging of DNA bound to the surface in buffer solutions without drying the sample (AFM in situ). The AFM data show that at low ionic strength, DNA molecules are loosely interwound supercoils with an irregular shape. Plectonemic superhelices are formed in high-concentration, near-physiological salt solutions. At such ionic conditions, superhelical loops are typically separated by regions of close helix-helix contacts. The data obtained show directly and unambiguously that overall geometry of supercoiled DNA depends dramatically on ionic conditions. This fact and the formation of close contacts between DNA helices are important features of supercoiled DNA related to its biological functions.

Scanning tunneling microscopy of mercapto-hexyl-oligonucleotides attached to gold.

6-mercapto hexyl-oligonucleotides bind to a gold surface strongly enough to permit imaging by a scanning tunneling microscope (STM). STM images showed worm-like chains that were approximately 12-(A-wide for single-stranded DNA and 20-(A-wide for double-stranded DNA. The chain lengths corresponded to 3.4 +/- 0.4 A per basepair for double-stranded DNA and 2.2 +/- 0.4 A per base for single-stranded DNA. This unexpectedly short length for single-stranded DNA was confirmed using oligomers with both single- and double-stranded regions. When the attachment of the samples was weakened (by imaging in water or scraping with the STM tip) the images changed to pairs of "blobs," apparently reflecting the attachment points of the molecules to the gold surface. Given this interpretation, images of DNA containing a five-base bulge imply that the bulge bends the oligomer by 90 degrees +/- 20 degrees.

Atomic force microscopy of DNA, nucleoproteins and cellular complexes: the use of functionalized substrates.

Progress towards rapid and simple characterization of biomolecular samples by scanning probe microscopy is impeded mainly by limitations of the current approach to sample preparation. We are working on approaches based on chemical functionalization of mica. Treatment of mica with aminopropyltriethoxy silane (APTES) makes the surface positively charged (AP-mica) and able to hold DNA in place for imaging, even in water. We have shown that AP-mica is an appropriate substrate for numerous nucleoprotein complexes as well. The AFM images of the complex of DNA with RecA protein are stable and indicate a structural periodicity for this filament. AP-mica holds strongly such large DNA complexes as kinetoplast DNA (kDNA) and is an appropriate substrate for their imaging with AFM. We have further develop this approach for making hydrophobic substrates. Silylation of mica surface with hexamethyldisilazane (Me-mica) allowed us to get AFM images of chlorosomes, an antenna complex isolated from green photosynthetic bacteria. Me-mica may be converted into a positively charged substrate after treatment with water solutions of tetraethylammonium bromide or cetyltrimethylammonium bromide. These activated surfaces show high activity towards binding the DNA molecules.

Structure of three-way DNA junctions. 2. Effects of extra bases and mismatches.

The structure of three-way DNA junctions, containing two linear double helices (arms) and a hairpin as a third arm, was studied by means of a cyclization technique. In addition to branched molecules containing perfect base-pairing in helical parts, three-way junctions with mismatches and extra non-complementary nucleotides (bulges) at junction points were studied. Molecules thus designed were ligated at identical conditions and their geometry was compared through the analysis of the efficiency of circle formation. The analysis showed that irregularities in base pairing listed above dramatically change the static and dynamic structural characteristics of the three-way junctions. All mismatches facilitate the kink between linear arms, but quantitatively, the effect depends on the position of the mismatch. The effect is maximal for GG-mismatch placed at the hairpin junction point. The results for bulges are of different kind, and they lead us to conclude that the three-way DNA junction with unpaired nucleotides adopts a T-like geometry with an angle around 90 degrees between arms containing the bulge and two other arms coaxially stacked. Broad distribution of circles indicates that this T-form geometry of bulge-containing junction is more flexible than initial pyramidal structure predominantly due to high mobility of the third arm.

Structure of three-way DNA junctions. 1. Non-planar DNA geometry.

Three-way junctions were obtained by annealing two synthetic DNA-oligomers. One of the strands contains a short palindrome sequence, leading to the formation of a hairpin with four base pairs in the stem and four bases in the loop. Another strand is complementary to the linear arms of the first hairpin-containing strand. Both strands were annealed to form a three-way branched structure with sticky ends on the linear arms. The branched molecules were ligated, and the ligation mixture was analysed on a two-dimensional gel in conditions which separated linear and circular molecules. Analysis of 2D-electrophoresis data shows that circular molecules with high mobility are formed. Formation of circular molecules is indicative of bends between linear arms. We estimate the magnitude of the angle between linear arms from the predominant size of the circular molecules formed. When the junction-to-junction distance is 20-21 bp, trimers and tetramers are formed predominately, giving an angle between linear arms as small as 60-90 degrees. Rotation of the hairpin position in the three-way junction allowed us to measure angles between other arms, yielding similar values. These results led us to conclude that the three-way DNA junction possesses a non-planar pyramidal geometry with 60-90 degrees between the arms. Computer modeling of the three-way junction with 60 degrees pyramidal geometry showed a predominantly B-form structure with local distortions at the junction points that diminish towards the ends of the helices. The size distributions of circular molecules are rather broad indicating a dynamic flexibility of three-way DNA junctions.

Structure of hydrated oligonucleotides studied by in situ scanning tunneling microscopy.

We have used the scanning tunneling microscope (STM) to image several synthetic oligonucleotides adsorbed onto a positively charged Au(111) electrode. The molecules were deposited and imaged in aqueous electrolyte under potential control, a procedure that eliminated the problem of the substrate artifacts that had limited some previous STM studies. Experiments were carried out with two types of single-stranded molecules (11 and 20 bases long) and three types of double-stranded molecules (20 and 61 base pairs and 31 bases with 25 bases paired and 6-base "sticky" ends). The molecules lie along symmetry directions on the reconstructed (23 x square root of 3) gold surface, and length measurements indicate that they adopt simple base-stacked structures. The base stacking distances are, within experimental uncertainty, equal to the 0.33 nm measured for polymeric aggregates of stacked purines by direct imaging in identical conditions. The images show features consistent with helical structures. Double helices have a major-groove periodicity that is consistent with a 36 degrees twist. The single helices appear to be more tightly twisted. A simple tunneling model of STM contrast generates good agreement between measured and calculated images.

CA runs increase DNA flexibility in the complex of lambda Cro protein with the OR3 site.

The alternating pyrimidine-purine elements CA, CAC, and CACA are anisotropically flexible, as deduced from gel circularization assays on point mutations and single-base mismatches in the OR3 site of lambda phage alone and in the specific complex with the Cro protein. These sequences evidently promote DNA bending in the specific binding region of the complex and may also facilitate overwinding in the central nonbinding region. Effects for CACA are exceptionally large and suggest that an alternative DNA structure may occur in this element.

Atomic force microscopy of long DNA: imaging in air and under water.

We have obtained striking atomic force microscopy images of the intact lambda bacteriophage genome and of several lambda restriction fragments both in air and under water. The DNA is unstained and the images are stable under continuous scanning for up to 30 min. Measured contour lengths of fully imaged restriction fragments and intact lambda DNA are accurate to within a few percent. The key to this development is the use of a process for binding unmodified double-stranded DNA to chemically treated mica surfaces. This procedure leads to strong DNA attachment and yields high-quality images that are stable under repeated scanning, even with the sample submerged in water. This allows normal hydration conditions to be maintained during scanning and in addition leads to a general improvement of image quality. Both the lateral resolution and the contrast increase by a factor of approximately 3 under water.

Atomic force microscopy imaging of double stranded DNA and RNA.

A procedure for imaging long DNA and double stranded RNA (dsRNA) molecules using Atomic Force Microscopy (AFM) is described. Stable binding of double stranded DNA molecules to the flat mica surface is achieved by chemical modification of freshly cleaved mica under mild conditions with 3-aminopropyltriethoxy silane. We have obtained striking images of intact lambda DNA, Hind III restriction fragments of lambda DNA and dsRNA from reovirus. These images are stable under repeated scanning and measured contour lengths are accurate to within a few percent. This procedure leads to strong DNA attachment, allowing imaging under water. The widths of the DNA images lie in the range of 20 to 80nm for data obtained in air with commercially available probes. The work demonstrates that AFM is now a routine tool for simple measurements such as a length distribution. Improvement of substrate and sample preparation methods are needed to achieve yet higher resolution.

Potentiostatic deposition of DNA for scanning probe microscopy.

We describe a procedure for reversible adsorption of DNA onto a gold electrode maintained under potential control. The adsorbate can be imaged by scanning probe microscopy in situ. Quantitative control of a molecular adsorbate for microscopy is now possible. We found a potential window (between 0 and 180 mV versus a silver wire quasi reference) over which a gold (111) surface under phosphate buffer is positively charged, but is not covered with a dense adsorbate. When DNA is present in these conditions, molecules adsorb onto the electrode and remain stable under repeated scanning with a scanning tunneling microscope (STM). They become removed when the surface is brought to a negative charge. When operated at tunnel currents below approximately 0.4 nA, the STM yields a resolution of approximately 1 nm, which is better than can be obtained with atomic force microscopy (AFM) at present. We illustrate this procedure by imaging a series of DNA molecules made by ligating a 21 base-pair oligonucleotide. We observed the expected series of fragment lengths but small fragments are adsorbed preferentially.