Environmental Effects on Guanine-Thymine Mispair Tautomerization Explored with Quantum Mechanical/Molecular Mechanical Free Energy Simulations.

DNA bases can adopt energetically unfavorable tautomeric forms that enable the formation of Watson-Crick-like (WC-like) mispairs, which have been proposed to give rise to spontaneous mutations in DNA and misincorporation errors in DNA replication and translation. Previous NMR and computational studies have indicated that the population of WC-like guanine-thymine (G-T) mispairs depends on the environment, such as the local nucleic acid sequence and solvation. To investigate these environmental effects, herein G-T mispair tautomerization processes are studied computationally in aqueous solution, in A-form and B-form DNA duplexes, and within the active site of a DNA polymerase λ variant. The wobble G-T (wG-T), WC-like G-T*, and WC-like G*-T forms are considered, where * indicates the enol tautomer of the base. The minimum free energy paths for the tautomerization from the wG-T to the WC-like G-T* and from the WC-like G-T* to the WC-like G*-T are computed with mixed quantum mechanical/molecular mechanical (QM/MM) free energy simulations. The reaction free energies and free energy barriers are found to be significantly influenced by the environment. The wG-T→G-T* tautomerization is predicted to be endoergic in aqueous solution and the DNA duplexes but slightly exoergic in the polymerase, with Arg517 and Asn513 providing electrostatic stabilization of G-T*. The G-T*→G*-T tautomerization is also predicted to be slightly more thermodynamically favorable in the polymerase relative to these DNA duplexes. These simulations are consistent with an experimentally driven kinetic misincorporation model suggesting that G-T mispair tautomerization occurs in the ajar polymerase conformation or concertedly with the transition from the ajar to the closed polymerase conformation. Furthermore, the order of the associated two proton transfer reactions is predicted to be different in the polymerase than in aqueous solution and the DNA duplexes. These studies highlight the impact of the environment on the thermodynamics, kinetics, and fundamental mechanisms of G-T mispair tautomerization, which plays a role in a wide range of biochemically important processes.

A packing for A-form DNA in an icosahedral virus.

Studies on viruses infecting archaea living in the most extreme environments continue to show a remarkable diversity of structures, suggesting that the sampling continues to be very sparse. We have used electron cryo-microscopy to study at 3.7-Å resolution the structure of the Sulfolobus polyhedral virus 1 (SPV1), which was originally isolated from a hot, acidic spring in Beppu, Japan. The 2 capsid proteins with variant single jelly-roll folds form pentamers and hexamers which assemble into a T = 43 icosahedral shell. In contrast to tailed icosahedral double-stranded DNA (dsDNA) viruses infecting bacteria and archaea, and herpesviruses infecting animals and humans, where naked DNA is packed under very high pressure due to the repulsion between adjacent layers of DNA, the circular dsDNA in SPV1 is fully covered with a viral protein forming a nucleoprotein filament with attractive interactions between layers. Most strikingly, we have been able to show that the DNA is in an A-form, as it is in the filamentous viruses infecting hyperthermophilic acidophiles. Previous studies have suggested that DNA is in the B-form in bacteriophages, and our study is a direct visualization of the structure of DNA in an icosahedral virus.

Tunable DNA Hybridization Enables Spatially and Temporally Controlled Surface-Anchoring of Biomolecular Cargo.

The controlled immobilization of biomolecules onto surfaces is relevant in biosensing and cell biological research. Spatial control is achieved by surface-tethering molecules in micro- or nanoscale patterns. Yet, there is an increasing demand for temporal control over how long biomolecular cargo stays immobilized until released into the medium. Here, we present a DNA hybridization-based approach to reversibly anchor biomolecular cargo onto micropatterned surfaces. Cargo is linked to a DNA oligonucleotide that hybridizes to a sequence-complementary, surface-tethered strand. The cargo is released from the substrate by the addition of an oligonucleotide that disrupts the duplex interaction via toehold-mediated strand displacement. The unbound tether strand can be reloaded. The generic strategy is implemented with small-molecule or protein cargo, varying DNA sequences, and multiple surface patterning routes. The approach may be used as a tool in biological research to switch membrane proteins from a locally fixed to a free state, or in biosensing to shed biomolecular receptors to regenerate the sensor surface.

Hole Transport in A-form DNA/RNA Hybrid Duplexes.

DNA/RNA hybrid duplexes are prevalent in many cellular functions and are an attractive target form for electrochemical biosensing and electric nanodevice. However the electronic conductivities of DNA/RNA hybrid duplex remain relatively unexplored and limited further technological applications. Here cyclopropyl-modified deoxyribose- and ribose-adenosines were developed to explore hole transport (HT) in both DNA duplex and DNA/RNA hybrids by probing the transient hole occupancies on adenine tracts. HT yields through both B-form and A-form double helixes displayed similar shallow distance dependence, although the HT yields of DNA/RNA hybrid duplexes were lower than those of DNA duplexes. The lack of oscillatory periods and direction dependence in HT through both helixes implied efficient hole propagation can be achieved via the hole delocalization and coherent HT over adenine tracts, regardless of the structural variations.

Premeltons in DNA.

Premeltons are examples of emergent-structures (i.e., structural-solitons) that arise spontaneously in DNA due to the presence of nonlinear-excitations in its structure. They are of two kinds: B-B (or A-A) premeltons form at specific DNA-regions to nucleate site-specific DNA melting. These are stationary and, being globally-nontopological, undergo breather-motions that allow drugs and dyes to intercalate into DNA. B-A (or A-B) premeltons, on the other hand, are mobile, and being globally-topological, act as phase-boundaries transforming B- into A-DNA during the structural phase-transition. They are not expected to undergo breather motions. A key feature of both types of premeltons is the presence of an intermediate structural-form in their central regions (proposed as being a transition-state intermediate in DNA-melting and in the B- to A-transition), which differs from either A- or B-DNA. Called beta-DNA, this is both metastable and hyperflexible--and contains an alternating sugar-puckering pattern along the polymer backbone combined with the partial unstacking (in its lower energy-forms) of every-other base-pair. Beta-DNA is connected to either B- or to A-DNA on either side by boundaries possessing a gradation of nonlinear structural-change, these being called the kink and the antikink regions. The presence of premeltons in DNA leads to a unifying theory to understand much of DNA physical chemistry and molecular biology. In particular, premeltons are predicted to define the 5' and 3' ends of genes in naked-DNA and DNA in active-chromatin, this having important implications for understanding physical aspects of the initiation, elongation and termination of RNA-synthesis during transcription. For these and other reasons, the model will be of broader interest to the general-audience working in these areas. The model explains a wide variety of data, and carries with it a number of experimental predictions--all readily testable--as will be described in this review.

The scrunchworm hypothesis: transitions between A-DNA and B-DNA provide the driving force for genome packaging in double-stranded DNA bacteriophages.

Double-stranded DNA bacteriophages have motors that drive the genome into preformed capsids, using the energy released by hydrolysis of ATP to overcome the forces opposing DNA packaging. Viral packaging motors are the strongest of all biological motors, but it is not known how they generate these forces. Several models for the process of mechanochemical force generation have been put forward, but there is no consensus on which, if any, of these is correct. All the existing models assume that protein-generated forces drive the DNA forward. The scrunchworm hypothesis proposes that the DNA molecule is the active force-generating core of the motor, not simply a substrate on which the motor operates. The protein components of the motor dehydrate a section of the DNA, converting it from the B form to the A form and shortening it by about 23%. The proteins then rehydrate the DNA, which converts back to the B form. Other regions of the motor grip and release the DNA to capture the shortening-lengthening motions of the B→A→B cycle ("scrunching"), so that DNA is pulled into the motor and pushed forward into the capsid. This DNA-centric mechanism provides a quantitative physical explanation for the magnitude of the forces generated by viral packaging motors. It also provides a simple explanation for the fact that each of the steps in the burst cycle advances the DNA by 2.5 base pairs. The scrunchworm hypothesis is consistent with a large body of published data, and it makes four experimentally testable predictions.

APTE: identification of indirect read-out A-DNA promoter elements in genomes.

BACKGROUND: Transcriptional regulation is normally based on the recognition by a transcription factor of a defined base sequence in a process of direct read-out. However, the nucleic acid secondary and tertiary structure can also act as a recognition site for the transcription factor in a process known as indirect read-out, although this is much less understood. We have previously identified such a transcriptional control mechanism in early Xenopus development where the interaction of the transcription factor ilf3 and the gata2 promoter requires the presence of both an unusual A-form DNA structure and a CCAAT sequence. Rapid identification of such promoters elsewhere in the Xenopus and other genomes would provide insight into a less studied area of gene regulation, although currently there are few tools to analyse genomes in such ways. RESULTS: In this paper we report the implementation of a novel bioinformatics approach that has identified 86 such putative promoters in the Xenopus genome. We have shown that five of these sites are A-form in solution, bind to transcription factors and fully validated one of these newly identified promoters as interacting with the ilf3 containing complex CBTF. This interaction regulates the transcription of a previously uncharacterised downstream gene that is active in early development. CONCLUSIONS: A Perl program (APTE) has located a number of potential A-form DNA promotor elements in the Xenopus genome, five of these putative targets have been experimentally validated as A-form and as targets for specific DNA binding proteins; one has also been shown to interact with the A-form binding transcription factor ilf3. APTE is available from http://www.port.ac.uk/research/cmd/software/ under the terms of the GNU General Public License.

The Zα domain of fish PKZ converts DNA hairpin with d(GC)(n) inserts to Z-conformation.

PKZ, protein kinase containing Z-DNA domains, is a novel member of the vertebrate eIF2α kinase family. Containing a catalytic domain in C-terminus and two Z-DNA binding domains (Zα1 and Zα2) in N-terminus, PKZ can be activated through the binding of Zα to Z-DNA. However, the regulatory function of PKZ Zα remains to be established. Here, to understand the impact of PKZ Zα on DNA conformational transition, wild-type Zα1Zα2 and 11 mutant proteins were expressed and purified. At the same time, several different lengths of DNA hairpins-d(GC)nT4(GC)n (n = 2-6) and an RNA hairpin-r(GC)6T4(GC)6 were synthesized. The effects of Zα1Zα2 and mutant proteins on the conformation of these synthetic DNA or RNA hairpins were investigated by using circular dichroism spectrum and gel mobility shift assays. The results showed that DNA hairpins retained a conventional B-DNA conformation in the absence of Zα1Zα2, while some of the DNA hairpins (n≥3) were converted to Z-conformation under Zα1Zα2 induction. The tendency was proportionally associated with the increasing amount of GC repeat. In comparison with Zα1Zα2, Zα1Zα1 rather than Zα2Zα2 displayed a higher ability in converting d(GC)6T4(GC)6 from B- to Z-DNA. These results demonstrated that Zα1 sub-domain played a more essential role in the process of B-Z conformational transition than Zα2 sub-domain did. Mutant proteins (K34A, N38A, R39A, Y42A, P57A, P58A, and W60A) could not convert d(GC)6T4(GC)6 into Z-DNA, whereas S35A or K56A retained some partial activities. Interestingly, Zα1Zα2 was also able to induce r(GC)6T4(GC)6 RNA from A-conformation to Z-conformation under appropriate conditions.

DNA self-assembly: from chirality to evolution.

Transient or long-term DNA self-assembly participates in essential genetic functions. The present review focuses on tight DNA-DNA interactions that have recently been found to play important roles in both controlling DNA higher-order structures and their topology. Due to their chirality, double helices are tightly packed into stable right-handed crossovers. Simple packing rules that are imposed by DNA geometry and sequence dictate the overall architecture of higher order DNA structures. Close DNA-DNA interactions also provide the missing link between local interactions and DNA topology, thus explaining how type II DNA topoisomerases may sense locally the global topology. Finally this paper proposes that through its influence on DNA self-assembled structures, DNA chirality played a critical role during the early steps of evolution.

Expansion of microsatellites on evolutionary young Y chromosome.

Sex chromosomes are an ideal system to study processes connected with suppressed recombination. We found evidence of microsatellite expansion, on the relatively young Y chromosome of the dioecious plant sorrel (Rumex acetosa, XY1Y2 system), but no such expansion on the more ancient Y chromosomes of liverwort (Marchantia polymorpha) and human. The most expanding motifs were AC and AAC, which also showed periodicity of array length, indicating the importance of beginnings and ends of arrays. Our data indicate that abundance of microsatellites in genomes depends on the inherent expansion potential of specific motifs, which could be related to their stability and ability to adopt unusual DNA conformations. We also found that the abundance of microsatellites is higher in the neighborhood of transposable elements (TEs) suggesting that microsatellites are probably targets for TE insertions. This evidence suggests that microsatellite expansion is an early event shaping the Y chromosome where this process is not opposed by recombination, while accumulation of TEs and chromosome shrinkage predominate later.

Herbaspirillum seropedicae rfbB and rfbC genes are required for maize colonization.

In this study we disrupted two Herbaspirillum seropedicae genes, rfbB and rfbC, responsible for rhamnose biosynthesis and its incoporation into LPS. GC-MS analysis of the H. seropedicae wild-type strain LPS oligosaccharide chain showed that rhamnose, glucose and N-acetyl glucosamine are the predominant monosaccharides, whereas rhamnose and N-acetyl glucosamine were not found in the rfbB and rfbC strains. The electrophoretic pattern of the mutants LPS was drastically altered when compared with the wild type. Knockout of rfbB or rfbC increased the sensitivity towards SDS, polymyxin B sulfate and salicylic acid. The mutants attachment capacity to maize root surface plantlets was 100-fold lower than the wild type. Interestingly, the wild-type capacity to attach to maize roots was reduced to a level similar to that of the mutants when the assay was performed in the presence of isolated wild-type LPS, glucosamine or N-acetyl glucosamine. The mutant strains were also significantly less efficient in endophytic colonization of maize. Expression analysis indicated that the rfbB gene is upregulated by naringenin, apigenin and CaCl(2). Together, the results suggest that intact LPS is required for H. seropedicae attachment to maize root and internal colonization of plant tissues.

A-form DNA structure is a determinant of transcript levels from the Xenopus gata2 promoter in embryos.

We have previously shown that a critical region of the gata2 promoter contains an inverted CCAAT box and adopts a partial A-form DNA structure in vitro. At gastrula stages of development transcription requires binding of CBTF (CCAAT box transcription factor), a multi-subunit transcription factor, to this region. Xilf3 is one component of CBTF and the double stranded RNA binding domains (dsRBDs) of Xilf3 must be active for both binding to, and transcription from, this promoter. Here we determine the contribution of DNA sequence and structure at the gata2 promoter to transcriptional activity. In all the constructs we tested a CCAAT box was a requirement for full activity. However, base substitutions that increase B-form structure propensity in the sequences flanking the CCAAT box are equally able to decrease activity even if a CCAAT box is present. In contrast, mutations that maintain A-form propensity in these regions also maintain, or increase, transcription factor binding and transcriptional activity. We propose a two-component model for the interaction of CBTF with the gata2 promoter, requiring both a CCAAT sequence and flanking A-form DNA structures. These results support a novel role for dsRBDs in transcriptional regulation and suggest a function for A-form DNA in vivo.

Oral cancer and genetic polymorphism of DNA double strand break gene Ku70 in Taiwan.

The DNA repair gene Ku70, an important caretaker of the overall genome stability, is thought to play a major role in the DNA double strand break repair system. It is known that defects in double strand break repair capacity can lead to irreversible genomic instability. However, the polymorphic variants of Ku70 and their association with oral cancer susceptibility has never been reported on. In this hospital-based case-control study, the association of Ku70 promoter T-991C (rs5751129), promoter G-57C (rs2267437), promoter A-31G (rs132770), and intron3 (rs132774) polymorphisms with oral cancer risk in a Taiwanese population was investigated. In total, 318 patients with oral cancer and 318 age- and gender-matched healthy controls recruited from the China Medical Hospital in Taiwan were genotyped. The results showed that there were significant differences between the oral cancer and control groups in the distribution of their genotypes (P=0.0031) and allelic frequency (P=0.0009) in the Ku70 promoter T-991C polymorphism. Individuals who carried at least one C allele (T/C or C/C) had a 2.15-fold increased risk of developing oral cancer compared to those who carried the T/T wild-type genotype (95% CI: 1.37-3.36). In the other three polymorphisms, there was no difference between both groups in the distribution of either genotype or allelic frequency. In conclusion, the Ku70 promoter T-991C, but not the Ku70 promoter C-57G, promoter A-31G or intron3, is connected to oral cancer susceptibility. This polymorphism may be a novel useful marker for primary prevention and anticancer intervention.

5-Bromouracil disrupts nucleosome positioning by inducing A-form-like DNA conformation in yeast cells.

5-Bromodeoxyuridine (BrdU) modulates expression of particular genes associated with cellular differentiation and senescence. Our previous studies have suggested an involvement of chromatin structure in this phenomenon. Here, we examined the effect of 5-bromouracil on nucleosome positioning in vivo using TALS plasmid in yeast cells. This plasmid can stably and precisely be assembled nucleosomes aided by the alpha2 repressor complex bound to its alpha2 operator. Insertion of AT-rich sequences into a site near the operator destabilized nucleosome positioning dependent on their length and sequences. Addition of BrdU almost completely disrupted nucleosome positioning through specific AT-tracts. The effective AT-rich sequences migrated faster on polyacrylamide gel electrophoresis, and their mobility was further accelerated by substitution of thymine with 5-bromouracil. Since this property is indicative of a rigid conformation of DNA, our results suggest that 5-bromouracil disrupts nucleosome positioning by inducing A-form-like DNA.

The dynamics of the B-A transition of natural DNA double helices.

The dynamics of the B-A transition of DNA double helices with different GC contents and various chain lengths has been characterized by an electric field pulse technique. The field-induced B-A reaction is separated from orientation effects using the magic angle technique. Amplitudes reflecting the B-A reaction are observed selectively in the limited range of ethanol contents, where CD spectra demonstrate the B-A transition. The maximum amplitude appears at 1-2% higher ethanol content than the center of the B-A transition observed by CD because electric field pulses induce a relatively large perturbation from the A- toward the B-form. The relaxation curves measured after pulse termination reflect a spectrum of up to three relaxation processes. For DNA's with approximately 50% GC, the main part of the amplitude ( approximately 75%) is associated with time constants of approximately 2 micros, and another major component appears with time constants of 50-100 micros. These relaxation effects have been observed for DNA samples with 859, 2629, 7160, and 48501 bp. The time constant associated with the main amplitude increases with decreasing GC content from approximately 2 micros at 50% GC to approximately 3 mus at 41% GC and approximately 10 micros at 0% GC at the center of the B-A transition. Model calculations on the kinetics of cooperative linear Ising lattices predict the appearance of a distinct maximum of the mean relaxation time at the center of the transition. The absence of such maximum in our experimental data indicates a low cooperativity of the B-A transition with a nucleation parameter of approximately 0.1. The rate of the B-A transition is lower by approximately 3 orders of magnitude than that predicted by molecular dynamics simulations.