132 Impact of sticky end length on the diffraction of self-assembled DNA crystals

Our laboratory has reported a self-assembled 3-D crystal based on a DNA tensegrity triangle. The tensegrity triangle is a rigid DNA motif with three-fold rotational symmetry consisting of three helices whose axes are directed along three linearly independent directions (1). The triangles form a crystalline lattice stabilized via sticky ends (2). The length of the sticky ends reported previously was two nucleotides (nt) GA:TC. Although diffracting to 4 Å resolution at the APS-ID19 beam line, they diffract only to 4.9 Å at the NSLS-X25 beam line. In the current study, we have analysed the effect of sticky end length and sequence on crystal formation and the resolution of the X-ray diffraction pattern on NSLS-X25. Tensegrity triangle motifs having 1-, 2-, and 3-nt sticky ends have all formed crystals. X-ray diffraction data from the same beam line revealed that the crystal resolution was somewhat better for the 2-nt sticky end having an AA:TT base pair (4.75 Å) than GA:CT and CC:GG (8.0 Å). Moreover, the 1-nt sticky end (C:G) yielded a diffraction pattern whose resolution (3.5 Å) compared favorably with all the three 2-nt sticky end systems. However, the triangle motif having a 1-nt sticky end with an A:T base pair did not yield any crystals. For motifs with 3-nt sticky ends, the sequence GAG:CTC produced small crystals (10–20?μm), while larger crystals (150?μm) were obtained with the sequences TAG:ATC and TAT:ATA. Our results indicate that not only do the lengths and sequences of the sticky ends define the interactions between motifs, but they also have an impact on the resulting resolution. We expect redesigned assemblies to form 3-D crystals with better resolution that can aid in the scaffolding of biological macromolecules for crystallographic structure determination. Applications in many areas of DNA nanotechnology are expected to benefit from a complete analysis of the effects of sticky end length, sequence, and free energy.     

The absence of tertiary interactions in a self-assembled DNA crystal structure

DNA is a highly effective molecule for controlling nanometer-scale structure. The convenience of using DNA lies in the programmability of Watson-Crick base-paired secondary interactions, useful both to design branched molecular motifs and to connect them through sticky-ended cohesion. Recently, the tensegrity triangle motif has been used to self-assemble three-dimensional crystals whose structures have been determined; sticky ends were reported to be the only intermolecular cohesive elements in those crystals. A recent communication in this journal suggested that tertiary interactions between phosphates and cytosine N(4) groups are responsible for intermolecular cohesion in these crystals, in addition to the secondary and covalent interactions programmed into the motif. To resolve this issue, we report experiments challenging this contention. Gel electrophoresis demonstrates that the tensegrity triangle exists in conditions where cytosine-PO(4) tertiary interactions seem ineffective. Furthermore, we have crystallized a tensegrity triangle using a junction lacking the cytosine suggested for involvement in tertiary interactions. The unit cell is isomorphous with that of a tensegrity triangle crystal reported earlier. This structure has been solved by molecular replacement and refined. The data presented here leave no doubt that the tensegrity triangle crystal structures reported earlier depend only on base pairing and covalent interactions for their formation.     

Structure of Three-Way DNA Junctions 1. Non-Planar DNA Geometry

Abstract

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°. 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° between the arms. Computer modeling of the three-way junction with 60° 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.     

Studying DNA Looping by Single-Molecule FRET

Bending of double-stranded DNA (dsDNA) is associated with many important biological processes such as DNA-protein recognition and DNA packaging into nucleosomes. Thermodynamics of dsDNA bending has been studied by a method called cyclization which relies on DNA ligase to covalently join short sticky ends of a dsDNA. However, ligation efficiency can be affected by many factors that are not related to dsDNA looping such as the DNA structure surrounding the joined sticky ends, and ligase can also affect the apparent looping rate through mechanisms such as nonspecific binding. Here, we show how to measure dsDNA looping kinetics without ligase by detecting transient DNA loop formation by FRET (Fluorescence Resonance Energy Transfer). dsDNA molecules are constructed using a simple PCR-based protocol with a FRET pair and a biotin linker. The looping probability density known as the J factor is extracted from the looping rate and the annealing rate between two disconnected sticky ends. By testing two dsDNAs with different intrinsic curvatures, we show that the J factor is sensitive to the intrinsic shape of the dsDNA.     

The stacked-X DNA Holliday junction and protein recognition

The crystal structure of the four-stranded DNA Holliday junction has now been determined in the presence and absence of junction binding proteins, with the extended open-X form of the junction seen in all protein complexes, but the more compact stacked-X structure observed in free DNA. The structures of the stacked-X junction were crystallized because of an unexpected sequence dependence on the stability of this structure. Inverted repeat sequences that contain the general motif NCC or ANC favor formation of stacked-X junctions, with the junction cross-over occurring between the first two positions of the trinucleotides. This review focuses on the sequence dependent structure of the stacked-X junction and how it may play a role in structural recognition by a class of dimeric junction resolving enzymes that themselves show no direct sequence recognition.     

Evolution of Tandemly Repeated Sequences: What Happens at the End of an Array?

Tandemly repeated sequences are a major component of the eukaryotic genome. Although the general characteristics of tandem repeats have been well documented, the processes involved in their origin and maintenance remain unknown. In this study, a region on the paternal sex ratio (PSR) chromosome was analyzed to investigate the mechanisms of tandem repeat evolution. The region contains a junction between a tandem array of PSR2 repeats and a copy of the retrotransposon NATE, with other dispersed repeats (putative mobile elements) on the other side of the element. Little similarity was detected between the sequence of PSR2 and the region of NATE flanking the array, indicating that the PSR2 repeat did not originate from the underlying NATE sequence. However, a short region of sequence similarity (11/15 bp) and an inverted region of sequence identity (8 bp) are present on either side of the junction. These short sequences may have facilitated nonhomologous recombination between NATE and PSR2, resulting in the formation of the junction. Adjacent to the junction, the three most terminal repeats in the PSR2 array exhibited a higher sequence divergence relative to internal repeats, which is consistent with a theoretical prediction of the unequal exchange model for tandem repeat evolution. Other NATE insertion sites were characterized which show proximity to both tandem repeats and complex DNAs containing additional dispersed repeats. An ``accretion model' is proposed to account for this association by the accumulation of mobile elements at the ends of tandem arrays and into ``islands' within arrays. Mobile elements inserting into arrays will tend to migrate into islands and to array ends, due to the turnover in the number of intervening repeats. Received: 18 August 1997 / Accepted: 18 September 1998     

The structure of the human AGT protein bound to DNA and its implications for damage detection

O6-Alklyguanine-DNA alkyltransferase (AGT) is an important DNA repair protein that protects cells from mutagenesis and toxicity arising from alkylating agents. We present an X-ray crystal structure of the wild-type human protein (hAGT) bound to double-stranded DNA with a chemically modified cytosine base. The protein binds at two different sites: one at the modified base, and the other across a sticky-ended DNA junction. The protein molecule that binds the modified cytosine base flips the base and recognizes it in its active site. The one that binds ends of neighboring DNA molecules partially flips an overhanging thymine base. This base is not inserted into the active-site pocket of the protein. These two different hAGT/DNA interactions observed in the structure suggest that hAGT may not detect DNA lesions by searching for the adduct itself, but rather for weakened and/or distorted base-pairs caused by base damage in the duplex DNA. We propose that hAGT imposes a strain on the DNA duplex and searches for DNA regions where the native structure is destabilized. The structure provides implications for pyrimidine recognition, improved inhibitor design, and a possible protein/protein interaction patch on hAGT.     

Structural basis of the properties of an industrially relevant thermophilic xylanase

A thermophilic xylanase from Bacillusstrain D3 suitable for use as a bleach booster in the paper pulping industry has been identified and characterized. The enzyme is suited to the high temperature and alkaline conditions needed for using xylanases in the pulp industry. The xylanase is stable at 60°C and relatively stable at high temperatures, with a temperature optimum of 75°C. The pH optimum is 6, but the enzyme is active over a broad pH range. The xylanase has been cloned and sequenced, and the crystal structure has been determined. The structure of BacillusD3 xylanase reveals an unusual feature of surface aromatic residues, which form clusters or “sticky patches” between pairs of molecules. These “sticky patches” on the surface of the enzyme are responsible for the tendency of the protein to aggregate at high concentrations in the absence of reagents such as ethylene glycol. The formation of dimers and higher order polymers via these hydrophobic contacts may also contribute to the thermostability of this xylanase. Proteins 29:77–86, 1997. © 1997 Wiley-Liss, Inc.     

Biochemistry and structural DNA nanotechnology: an evolving symbiotic relationship

Structural DNA nanotechnology is derived from naturally occurring structures and phenomena in cellular biochemistry. Motifs based on branched DNA molecules are linked together by sticky ends to produce objects, periodic arrays, and nanomechanical devices. The motifs include Holliday junction analogues, double and triple crossover molecules, knots, and parallelograms. Polyhedral catenanes, such as a cube or a truncated octahedron, have been assembled from branched junctions. Stiff motifs have been used to produce periodic arrays, containing topographic features visible in atomic force microscopy; these include deliberately striped patterns and cavities whose sizes can be tuned by design. Deliberately knotted molecules have been assembled. Aperiodic arrangements of DNA tiles can be used to produce assemblies corresponding to logical computation. Both DNA structural transitions and branch migration have been used as the basis for the operation of DNA nanomechanical devices. Structural DNA nanotechnology has been used in a number of applications in biochemistry. An RNA knot has been used to establish the existence of RNA topoisomerase activity. The sequence dependence of crossover isomerization and branch migration at symmetric sites has been established through the use of symmetric immobile junctions. DNA parallelogram arrays have been used to determine the interhelical angles for a variety of DNA branched junctions. The relationship between biochemistry and structural DNA nanotechnology continues to grow.     

Bioprospecting for novel oxylipins in fungi: The presence of 3-hydroxy oxylipins in Pilobolus

As previously found in various members of the Mucorales, 3-hydroxy oxylipins in Mucor genevensis are associated with the sporangia, i.e. mainly the columella structure and between aggregating sporangiospores. To determine if this phenomenon is also true in distantly related members, the mucoralean fungus Pilobolus was examined. This fungus is characterized by relatively large sub sporangial-columella structures which actively eject sporangia in a sticky liquid for attachment onto herbage surrounding its growth medium – in this case horse dung. Strikingly, this fungus produced a novel oxylipin i.e. a 3-hydroxy monounsaturated fatty acid, possibly a nonenoic acid, which is mainly associated with the sub sporangial-columella structure and aggregating sporangiospores. The specificity of the antibody against 3-hydroxy oxylipins used in immunofluorescence mapping of the mucoralean fungi, was further confirmed in the yeast, Saccharomycopsis malanga which produces 3-hydroxy palmitate in crystal form. These crystals occur between aggregating yeast cells. On the basis of the available data, we hypothesize that 3-hydroxy oxylipins probably function as adhesives, attaching fungal cells to each other or to other surfaces through entropic based hydrophobic forces and/or hydrogen bonds.     

Isolation and characterization of simple repeat sequences from the yellow fin sea bream Acanthopagrus latus (Sparidae)

We isolated DNA fragments containing various repetitive elements from the genome of a sea bream Acanthopagrus latus. Sequence analysis indicated that two fragments have particularly interesting features. Fragment AL87 contained a tetranucleotide repeat and a quasipalindromic sequence. Sequence comparison suggested that AL87 may be a part of a gene encoding a serine/threonine protein kinase, and that the quasipalindrome is situated at the junction of an intron and an exon. Moreover, the quasipalindrome is conserved in several other fishes, even though it has the potential to form a stem-loop structure at the splicing site. Fragment AL79 contained a minisatellite sequence made up of six 30-bp units in tandem. DNase I sensitivity assays and statistical analyses showed the repeat region to be flexible when subjected to bending stress. In addition, atomic force microscopic imaging of AL79 showed the presence of highly curved (kinked) segments flanking the repeat region. The structural features of these repetitive elements may be key factors facilitating the amplification of the repeats.     

Structural basis for a novel mechanism of DNA bridging and alignment in eukaryotic DSB DNA repair

Eukaryotic DNA polymerase mu of the PolX family can promote the association of the two 3′‐protruding ends of a DNA double‐strand break (DSB) being repaired (DNA synapsis) even in the absence of the core non‐homologous end‐joining (NHEJ) machinery. Here, we show that terminal deoxynucleotidyltransferase (TdT), a closely related PolX involved in V(D)J recombination, has the same property. We solved its crystal structure with an annealed DNA synapsis containing one micro‐homology (MH) base pair and one nascent base pair. This structure reveals how the N‐terminal domain and Loop 1 of Tdt cooperate for bridging the two DNA ends, providing a templating base in trans and limiting the MH search region to only two base pairs. A network of ordered water molecules is proposed to assist the incorporation of any nucleotide independently of the in trans templating base. These data are consistent with a recent model that explains the statistics of sequences synthesized in vivo by Tdt based solely on this dinucleotide step. Site‐directed mutagenesis and functional tests suggest that this structural model is also valid for Pol mu during NHEJ.     

Self-assembly of precursors in single-crystal growth of biopolymers

Self-assembly of precursors in dilute solution single-crystal growth of poly[(R)-3-hydroxyvalerate] (PHV) and the fungal polysaccharide mycodextran were studied by transmission electron microscopy, especially at the early stages of crystallization. Precursors for PHV, such as small primary nuclei and tiny square tiles, consolidate to a large square crystal composed of orthogonally arranged tiles. By contrast, the precursors of mycodextran were lath-shaped, which suggests that the crystal growth is mainly in the longitudinal direction. Needlelike precursors were observed either free or as protrusions at the lath ends. In general, single-crystal shape and morphology are dependent on the type of precursor and on the manner of crystallization.     

The ligation and flexibility of four-arm DNA junctions

Four-arm DNA branched junctions are stable analogs of Holliday recombination intermediates, constructed from oligonucleotides. The conformational flexibility of junctions can be estimated by ligating them together and determining the set of closed macrocyclic products that are obtained among the linked units. We have performed a series of these experiments, using pairs of sticky ends that flank each of the six angles of a four-arm junction. In every case, the ligated junctions are separated by 20 nucleotide pairs, about two turns of DNA. All expected short linear products, starting with dimers, are observed for all ligations. All ligations result in a macrocyclic series that begins with trimers. Thus, over the time scale of these reactions, the arms of this junction can form angles as low as 60°. The response of this junction to torsional stress has been tested in a companion experiment. A smaller version of this same four-arm junction has been oligomerized so that successive junctions are separated by 16 nucleotide pairs, approximately 1.5 turns of DNA. If junctions were as rigid as linear duplex DNA, this system would not be expected to form macrocycles until the continuous chain approaches the Shore–Baldwin limit, ca. 160 base pairs. However, macrocyclic closure is observed in a regular ligation ladder, starting from tetramers. Model building suggests that the most likely explanation for the observed closure is that the junction adopts two different conformations, which bend the continuous strand toward opposite grooves. The junction structures formed by these ligations represent fluctuations from equilibrium structures.     

End association and segregation of the achiasmatic X and Y chromosomes of the sand rat,Psammomys obesus

In Psammomys obesus there is no pairing between the X and Y chromosomes and no chiasma formation (Solari and Ashley, 1977). It is demonstrated that ends of the axial elements of the X and Y chromosomes come together during pachytene, and regularly form at least one end-to-end junction. This achiasmatic physical connection between the ends of the X and Y persists until anaphase I, thus assuring the normal distribution of the sex chromosomes observed by light microscopy. In addition, there are no differentiations of the axes of the X and Y similar to those observed in other mammalian species thus far examined, a fact that could influence chromatid cohesiveness and disjunction.     

Realizing directional cloning using sticky ends produced by 3′-5′ exonuclease of Klenow fragment

The Klenow fragment (KF) has been used to make the blunt end as a tool enzyme. Its 5′-3′ polymerase activity can extend the 5′ overhanging sticky end to the blunt end, and 3′-5′ exonuclease activity can cleave the 3′ overhanging sticky end to the blunt end. The blunt end is useful for cloning. Here, we for the first time determined that a sticky end can be made by using the 3′-5′ exonuclease activity of KF. We found that KF can cleave the blunt end into certain sticky ends under controlled conditions. We optimized enzyme cleavage conditions, and characterized the cleaved sticky ends to be mainly 2 nt 5′ overhang. By using these sticky ends, we realized ligation reaction in vitro, and accomplished cloning short oligonucleotides directionally with high cloning efficiency. In some cases, this method can provide sticky end fragments in large scale for subsequent convenient cloning at low cost.     

Resolving Holliday junctions with Escherichia coli UvrD helicase

The Escherichia coli UvrD helicase is known to function in the mismatch repair and nucleotide excision repair pathways and has also been suggested to have roles in recombination and replication restart. The primary intermediate DNA structure in these two processes is the Holliday junction. UvrD has been shown to unwind a variety of substrates including partial duplex DNA, nicked DNA, forked DNA structures, blunt duplex DNA and RNA-DNA hybrids. Here, we demonstrate that UvrD also catalyzes the robust unwinding of Holliday junction substrates. To characterize this unwinding reaction we have employed steady-state helicase assays, pre-steady-state rapid quench helicase assays, DNaseI footprinting, and electron microscopy. We conclude that UvrD binds initially to the junction compared with binding one of the blunt ends of the four-way junction to initiate unwinding and resolves the synthetic substrate into two double-stranded fork structures. We suggest that UvrD, along with its mismatch repair partners, MutS and MutL, may utilize its ability to unwind Holliday junctions directly in the prevention of homeologous recombination. UvrD may also be involved in the resolution of stalled replication forks by unwinding the Holliday junction intermediate to allow bypass of the blockage.     

Structural mechanism of ATP‐dependent DNA binding and DNA end bridging by eukaryotic Rad50

The Mre11–Rad50–Nbs1 (MRN) complex is a central factor in the repair of DNA double‐strand breaks (DSBs). The ATP‐dependent mechanisms of how MRN detects and endonucleolytically processes DNA ends for the repair by microhomology‐mediated end‐joining or further resection in homologous recombination are still unclear. Here, we report the crystal structures of the ATPγS‐bound dimer of the Rad50^NBD (nucleotide‐binding domain) from the thermophilic eukaryote Chaetomium thermophilum (Ct) in complex with either DNA or CtMre11^RBD (Rad50‐binding domain) along with small‐angle X‐ray scattering and cross‐linking studies. The structure and DNA binding motifs were validated by DNA binding experiments in vitro and mutational analyses in Saccharomyces cerevisiae in vivo. Our analyses provide a structural framework for the architecture of the eukaryotic Mre11–Rad50 complex. They show that a Rad50 dimer binds approximately 18 base pairs of DNA along the dimer interface in an ATP‐dependent fashion or bridges two DNA ends with a preference for 3′ overhangs. Finally, our results may provide a general framework for the interaction of ABC ATPase domains of the Rad50/SMC/RecN protein family with DNA.     

The role of tandem IS dimers in IS911 transposition

Using a combined in vivo and in vitro approach, we demonstrated that the transposition products generated by IS911 from a dimeric donor plasmid are different from those generated from a plasmid monomer. When carried by a monomeric plasmid donor, free IS911 transposon circles are generated by intra-IS recombination in which one IS end undergoes attack by the other. These represent transposition intermediates that undergo integration using the abutted left (IRL) and right (IRR) ends of the element, the active IRR-IRL junction, to generate simple insertions. In contrast, the two IS911 copies carried by a dimeric donor plasmid not only underwent intra-IS recombination to generate transposon circles but additionally participated in inter-IS recombination. This also creates an active IRR-IRL junction by generating a head-to-tail IS tandem dimer ([IS]2) in which one of the original plasmid backbone copies is eliminated in the formation of the junction. Both transposon circles and IS tandem dimers are generated from an intermediate in which two transposon ends are retained by a single strand joint to generate a figure 8 molecule. Inter-IS figure 8 molecules generated in vitro could be resolved into the [IS]2 form following introduction into a host strain by transformation. Resolution did not require IS911 transposase. The [IS]2 structure was stable in the absence of transposase but was highly unstable in its presence both in vivo and in vitro. Previous studies had demonstrated that the IRR-IRL junction promotes efficient intermolecular integration and intramolecular deletions both in vivo and in vitro. Integration of the [IS]2 derivative would result in a product that resembles a co-integrate structure. It is also shown here that the IRR-IRL junction of the [IS]2 form and derivative structures can specifically target one of the other ends in an intramolecular transposition reaction to generate transposon circles in vitro. These results not only demonstrate that IS911 (and presumably other members of the IS3 family) is capable of generating a range of transposition products, it also provides a mechanistic framework which explains the formation and activity of such structures previously observed for several other unrelated IS elements. This behaviour is probably characteristic of a large number of IS elements.