Effect of a mechanical tension on the hydration of DNA in fibres.

Fiber X-ray diffraction and measurement of fibre dimensions yield information about the effects of a mechanical tension on hydration of DNA in fibres. At a given relative humidity, the mechanical tension changes the DNA conformation but does not modify the number of water molecules associated to a nucleotide. The number of water molecules per nucleotide necessary to maintain B form decreases for increasing tensions applied to the DNA fibre. Form transitions can be opposed by mechanical tensions; an energy of 1 Kcal per mole of nucleotide pairs is sufficient to prevent the B to A transition.     

Influence of a Mechanical Tension on the B-C and B-C Conformational Transitions in DNA Fibres

Abstract

In the present fibre X-ray study we attempt to quantify the effect of a mechanical tension on the conformations, and transitions between the structural forms of DNA A simple experimental device has been realized in order to apply precise mechanical forces on DNA fibres during X-ray exposure. It is shown that, as the applied tension is increased, the B→A transition can be prevented as well as with a decrease of the sodium salt content A kind of distorted B form is then observed the helical parameters of which change with the relative humidity. On the contrary, the mechanical tension does not prevent the B→C transition; it only slows down the form change and improves the X-ray patterns up to a relative humidity of 0%.     

Neutron fibre diffraction study of DNA hydration

Interactions with water are crucial to the conformation assumed by the DNA double helix. The location of water around the D conformation has been investigated in a neutron fibre diffraction study which shows that water is ordered in the minor groove of the DNA. The D conformation is important since its occurrence is limited to specific DNA base pair sequences which have been identified as functionally significant. This study is of particular interest because the D conformation has not been reported in single crystal studies of oligonucleotides.     

Influence of a mechanical tension on the B-A and B-C conformational transitions in DNA fibres

In the present fibre X-ray study we attempt to quantify the effect of a mechanical tension on the conformations, and transitions between the structural forms of DNA. A simple experimental device has been realized in order to apply precise mechanical forces on DNA fibres during X-ray exposure. It is shown that, as the applied tension is increased, the B----A transition can be prevented as well as with a decrease of the sodium salt content. A kind of distorted B form is then observed the helical parameters of which change with the relative humidity. On the contrary, the mechanical tension does not prevent the B----C transition; it only slows down the form change and improves the X-ray patterns up to a relative humidity of 0%.     

X-ray diffraction studies of the RNA tetramer GpGpCpUp

The synthetic RNA tetramer GpGpCpUp has been studied by X-ray diffraction of single crystals and fibres. A preliminary crystallographic analysis of single crystals implies that two GpGpCpUp strands form a short antiparallel double helix with G · U base-pairs at the ends of it. As diffraction intensities of single crystals fall into decay, the diffraction pattern gradually changes into a fibre pattern similar to that of A-RNA or of the A form of DNA.     

A new D-DNA form of poly(dA-dT).poly(dA-dT): an A-DNA type structure with reversed Hoogsteen pairing

The D-DNA double helix model of poly(dA-dT).poly(dA-dT) proposed in the literature is not in accordance with some notable experimental facts and physicochemical conditions to which it is related. Thus, the fibre X-ray diffraction pattern of D-DNA obtained at a relative humidity lower than that giving the A-DNA form is singularly not taken into account when one assumes that there is only one D structure of B-DNA type. We rather suggest that there are actually two different forms of D-DNA, namely D(A) which partakes in the D-A-B transitions and D(B) associated with the D-B change of conformation. Although these two DNA structures have the same helical parameters (pitch and number of residues per turn), in agreement with X-ray data, their detailed conformations are considerably different. Whereas D(B) is indeed the structure generally defined as D-DNA, a critical analysis based on a comparison between different possible DNA double helices leads us to propose dihedral angles, a set of atomic coordinates and a stereo view of another new form of D-DNA, the D(A) structural model. It is a right-handed double helix with a dinucleotide as the repeat unit. The furanose rings are of the A-DNA type (C3' endo) and the bases are hydrogen bonded according to the reversed Hoogsteen pairing. Such a disposition renders the D(A) model unsuitable for poly(dI-dC).poly(dI-dC), the other alternating polynucleotide observed in the D(B) structure. The consistency of these two different D-DNA structures of poly(dA-dT).poly(dA-dT) with the general aspects of hydration and helix-helix transitions of DNA, as well as with the conformational variability of AT base sequences, is discussed.     

Signatures of DNA flexibility, interactions and sequence-related structural variations in classical X-ray diffraction patterns

The theory of X-ray diffraction from ideal, rigid helices allowed Watson and Crick to unravel the DNA structure, thereby elucidating functions encoded in it. Yet, as we know now, the DNA double helix is neither ideal nor rigid. Its structure varies with the base pair sequence. Its flexibility leads to thermal fluctuations and allows molecules to adapt their structure to optimize their intermolecular interactions. In addition to the double helix symmetry revealed by Watson and Crick, classical X-ray diffraction patterns of DNA contain information about the flexibility, interactions and sequence-related variations encoded within the helical structure. To extract this information, we have developed a new diffraction theory that accounts for these effects. We show how double helix non-ideality and fluctuations broaden the diffraction peaks. Meridional intensity profiles of the peaks at the first three helical layer lines reveal information about structural adaptation and intermolecular interactions. The meridional width of the fifth layer line peaks is inversely proportional to the helical coherence length that characterizes sequence-related and thermal variations in the double helix structure. Analysis of measured fiber diffraction patterns based on this theory yields important parameters that control DNA structure, packing and function.     

Helix-helix transitions in DNA: fibre X-ray study of the particular cases poly(dG-dC) · poly(dG-dC) and poly(dA) · 2poly(dT)

The helix-helix transitions which occur in poly(dG-dC) · poly(dG-dC) and in poly (dG-m⁵dC) · poly(dG-m⁵dC) are commonly assumed to be changes between the right-handed A- or B-DNA double helices and the left-handed Z-DNA structure. The mechanisms for such transconformations are highly improbable, especially when they are supposed to be active in long polynucleotide chains organised in semicrystalline fibres. The present alternative possibility assumes that rather than the Z-DNA it is a right-handed double helix (S-DNA) which actually takes part in these form transitions. Two molecular models of this S form, in good agreement with X-ray measurements, are proposed. They present alternating C(2′)-endo and C(3′)-endo sugar puckering like the “alternating B-DNA” put forward some years ago. Dihedral angles, sets of atomic coordinates and stereo views of the two S-DNA structures are given, together with curves of calculated diffracted intensities. Furthermore, we question the possibility of obtaining semicrystalline fibres with triple helices of poly(dA) · 2poly(dT) in a way which renders X-ray diffraction efficient. It is suggested that, up to now, only double helices of poly(dA) · poly(dT) can actually be observed by fibre X-ray diffraction measurements. Received: 30 March 1999 / Revised version: 30 June 1999 / Accepted: 30 June 1999     

Polymer conformation: 3. Rapid methods for seeking contact-free double helices

A methodology for mapping helix constraint surfaces and contact-free molecular structures, as introduced in parts 1 and 2 of the series^1,2, has been developed and extended to include investigation of stability and stereochemical feasibility of double helices. The motivation for this development was prompted by practical considerations concerning the interpretation of new X-ray fibre diffraction patterns obtained from the gelling polysaccharide agarose³, in the light of previous interpretations⁴ favouring a double helix model for this biopolymer. The method may be of use for objectively scrutinizing double helix structures the interpretation of a number of which, e.g. carrageenan^5,6, poly(methyl methacrylate)^7,10, isotactic polystyrene^11,12, xanthan gum^13,16, appear to be controversial issues.     

BII nucleotides in the B and C forms of natural-sequence polymeric DNA: A new model for the C form of DNA

A combination of solid-state (31)P and (13)C NMR, X-ray diffraction, and model building is used to show that the B and C forms of fibrous macromolecular DNA consist of two distinct nucleotide conformations, which correspond closely to the BI and BII nucleotide conformations known from oligonucleotide crystals. The proportion of the BII conformation is higher in the C form than in the B form. We show structural models for a 10(1) double helix involving BI nucleotides and a 9(1) double helix involving BII nucleotides. The 10(1) BI model is similar to a previous model of B-form DNA, while the 9(1) BII model is novel. The BII model has a very deep and narrow minor groove, a shallow and wide major groove, and highly inclined bases. This work shows that the B to C transition in fibers corresponds to BI to BII conformational changes of the individual nucleotides.     

Polymorphism of Natural DNA

X-ray fibre diffraction shows that natural very AT-rich DNA exists in at least four novel and distinct conformations depending on the sequence and salt content.     

Coiled Supercoiled DNA in Critical Point Dried and Thin Sectioned Human Chromosome Fibres

SUPERCOILING of the DNA double helix in the deoxynucleo-histone fibril (100 Â in diameter with a pitch of 120 Â) has been well documented by X-ray diffraction^1–3. The main structural element of eukaryotic metaphase chromosomes and inactive interphase chromatin, however, is a long, irregularly folded fibre, 200 to 300 Â in diameter, as electron microscopy has shown^4–10. The arrangement of DNA within this fibre has not yet been established clearly. I wish to present electron micrographs of critical point dried and thin sectioned fibres of human metaphase chromosomes, which demonstrate more or less regularly distributed electron densities which could be explained by supercoiling of the 100 Â deoxynucleohistone fibril.     

A Gaussian disorientation model for interpreting linear dichroism measurements of DNA-drug fibres and films

The optical linear dichroism of DNA-drug fibres and films can provide valuable information on the geometry of the binding and its extent, especially when used in conjunction with X-ray diffraction data from the same specimens. We have considered the macroscopic orientation of the helices within a fibre or film to be characterized by a Gaussian distribution of the helix axes about the fibre (or film) axis. Using this model we have obtained analytical expressions for the dichroic ratio without resorting to computer simulation techniques or numerical integration methods, and used them to interpret the results of experiments using DNA-phenanthridine fibres. As the humidity is increased, ethidium and dimidium bromide show an increased fraction of binding perpendicular to the helix axis, consistent with intercalation. Prothidium shows little preferred orientation in its binding, and the occurrence of a significant proportion of intercalation can be excluded.     

DNA models for A, B, C and D conformations related to fiber X-ray, infrared and NMR measurements

A conformational analysis of the A, B, C and D DNA forms was made in order to establish molecular models presenting a good agreement with experimental data obtained from fiber X-ray, infrared linear dichroism and 31P NMR. The proposed models have been refined and do present good stereochemistry and optimized H-bond distances between bases associated with the Watson-Crick pairing. The DNA conformations proposed are a left handed double helix for the C form and right handed helices for A, B and D. Relations to conformational transitions between these forms are discussed.     

The agarose double helix and its function in agarose gel structure

Agarose and eight different derivatives carrying O-methyl, O-sulphate, O-hydroxyethyl or O-carboxyethylidene substituents in various positions were studied by optical rotation, X-ray diffraction and computerised molecular model building methods. All samples showed essentially the same order-disorder transition during gel-sol interconversion. In addition, all the samples that could be made into oriented films or fibres gave X-ray diffraction diagrams corresponding to a common molecular structure. A double helix model for this structure is proposed that has the 0.95 nm axial periodicity observed and a calculated cylindrically averaged Fourier transform in good agreement with the observed (continuous) layer line intensities. Each chain in the double helix forms a lefthanded 3-fold helix of pitch 1.90 nm and is translated axially relative to its partner by exactly half this distance. This model accounts for the sign and magnitude of the optical rotation shift that accompanies the sol-gel transitions and is sterically accessible to each of the various substituted forms. The relationship between agarose gel properties and the double helix is discussed and the structure compared with i-carrageenan.     

Polymorphism in B-DNA: X-ray diffraction studies on Li-DNA fibres

From X-ray diffraction studies it is generally believed that B-DNA has the structural parameters n = 10 and h = 3.4 Å. However, for the first time we report that polymorphism in the B-form can be observed in DNA fibres. This was achieved by the precise control of salt and humidity in fibres and by the application of the precession method of X-ray diffraction to DNA fibres. The significant result obtained is that n = 10 is not observed for crystalline fibre patterns. In fact, n = 10 and h = 3.4 Å are not found to occur simultaneously. Instead, a range of values, n = 9.6–10.0 and h = 3.35 Å–3.41 Å is observed.     

Interaction of DNA with lysine-rich polypeptides and proteins. The influence of polypeptide composition and secondary structure

Using X-ray diffraction we have studied fibres obtained from complexes of DNA with lysine-rich polypeptides and with proteins that have different conformations, to ascertain whether the conformations of the polypeptides and the DNA are maintained upon interaction. Substances investigated include N-acetyl-Lys-Ala-Tyr-Ala-Lys-ethylamide, random poly(Leu50, Lys50), sequential poly(Leu-Lys), poly(Val-Lys), poly(Ala-Lys), poly(Lys-Ala-Ala-Lys), poly(Lys-Ala-Ala), poly(Lys-Leu-Ala), poly(Lys-Ala-Gly), protein phi 0 from sea cucumber spermatozoa, histone H1 and two fragments of this protein obtained by chemical cleavage. In general, the B form of DNA with ten base-pairs per helical turn is maintained upon interaction at high levels of humidity. The A form is never observed; it appears to be forbidden in a protein environment. No evidence for transition into any novel DNA conformation has been observed, although the B form is altered in some cases, in particular upon dehydration. Such alteration occurs always in the sense of tightening the double helix, so that the number of base-pairs per helical turn diminishes. The polypeptides may interact with DNA in both the alpha and beta conformations. We have found different types of complexes in which either a monolayer or a double layer of beta-pleated sheets is intercalated between layers of DNA molecules. Alternatively, the polypeptide chain may be wrapped around the DNA, following one of the grooves. The polypeptide conformation may be either maintained or changed upon interaction. The charge density of the polypeptide is an important parameter of the interaction. When it matches the charge density of the DNA, the polypeptide conformation is maintained in most cases; otherwise it is modified. The globular part of histone H1 gives a unique X-ray pattern upon interaction, indicative of a loss of order of DNA in the complex. On the other hand, the C-terminal part of histone H1 gives a very well-ordered complex, similar to a nucleoprotamine, in spite of its lower charge density.     

Conformational analysis of xyloglucans

Xyloglucan isolated from the elongating regions of pea stems was examined using X-ray diffraction and energy calculations. The X-ray fibre pattern suggested that the backbone (1----4)-beta-D-glucan takes an extended two-fold helix similar to common cellulose. In order to study side chains (xylosyl or fucosyl-galactosyl-xylosyl residues) of the polysaccharide, energetically preferable conformations were searched by calculation of interactions between non-bonded atom pairs. A stepwise calculation for the conformation of fucosyl-galactosyl-xylosyl residue gave 10 allowed area (phi-psi) maps which are useful to deduce xyloglucan conformations of both monocotyledons and dicotyledons in the walls of growing plant cells.     

Crystallization of macromolecular heparin

X-ray fibre-diffraction photographs were obtained from oriented films of the sodium salt of macromolecular heparin (molecular weight approx. 10(6)) prepared from rat skin. Two distinct molecular chain conformations corresponding to two different crystal lattices were observed as a function of relative humidity. The first conformation, obtained at 78% relative humidity, has a layer-line spacing of 1.73nm, which can be interpreted as an approximate twofold helix. On increasing the relative humidity to 84% a second phase with a layer-line repeat of 1.65nm is obtained with the reflexions indexing on a triclinic unit cell similar to that obtained previously (Nieduszynski & Atkins, 1973) for pig mucosal heparin.     

Conformational transitions and hydration of poly d (A-T) · poly d (A-T) in fibers

Conformational transitions of poly d(A-T) · poly d (A-T) have been studied by fiber X-ray diffraction and measurement of fiber dimensions. Results obtained for the D-A-B and D-B transitions are presented and analyzed. For all these form transitions, cooperativity effects are observed for the variation of the rise per nucleotide versus the relative humidity. Detailed information about hydration of the polynucleotide during form transitions and the numbers of water molecules per nucleotide necessary to stabilize the different helical conformations are presented. Offprint requests to: S. Premilat