利用PCR方法鉴定hiTAIL-PCR扩增产物中的质粒骨架片段

T-DNA突变体是研究基因功能的重要资源。高效热不对称交错PCR (hiTAIL-PCR)是克隆突变体中T-DNA插入位点侧翼序列的常用方法。然而我们发现, 利用hiTAIL-PCR克隆到的一些侧翼序列并不对应于宿主的染色体DNA序列, 而是质粒的骨架DNA片段。通过设置1组RB-S4/AC1或者LB-A4/AC1对照反应, 用PCR方法鉴定了hiTAIL-PCR扩增产物中位于T-DNA侧翼的质粒骨架片段。在后续分析中, 通过排除这些片段, 提高了利用hiTAIL-PCR获得宿主染色体DNA片段的效率。同时, 通过调整反应程序, 使得整个PCR的反应时间也大为缩短。在拟南芥(Arabidopsis thaliana) T-DNA突变体drf1侧翼序列的克隆实例中, 对照反应的引入将hiTAIL-PCR中需鉴定的22条扩增产物降至4条, 效率提高了81.8%。     

修饰性肽核酸的细胞转运

肽核酸是人工合成的寡核苷酸类似物,以N-(2-氨乙基)甘氨酸结构单元替代DNA分子中的戊糖-磷酸结构。与天然核酸相比,肽核酸可以更高效地与DNA或RNA特异性杂交,在分子生物学和基因药物领域具有良好的应用前景。但是,肽核酸骨架呈电中性,难以高效穿过细胞膜,这成为工程应用的最大障碍。为了改善肽核酸的细胞转运性能,对肽核酸进行化学修饰是近年来的研究热点。结合近十年来文献报道和本实验室的工作,对肽核酸的骨架修饰和配合物结合修饰两类增强细胞转运的修饰方法进行综述,并对修饰性肽核酸细胞转运研究中存在的问题以及未来的研究趋势及其应用提出了见解。     

Molecular flexibility in protein-DNA interactions

In living cells protein-DNA interactions are fundamental processes. Here, we compare the 3D structures of several DNA-binding proteins frequently determined with and without attached DNA. We studied the global structure (backbone-traces) as well as the local structure (binding sites) by comparing pair-wise the related atoms. The DNA-interaction sites of uncomplexed proteins show conspicuously high local structural flexibility. Binding to DNA results in specific local conformations, which are clearly distinct from the unbound states. The adaptation of the protein's binding site to DNA can never be described by the lock and key model but in all cases by the induced fit model. Conformational changes in the seven protein backbone traces take place in different ways. Two of them dock onto DNA without a significant change, while the other five proteins are characterized by a backbone conformation change caused by DNA docking. In the case of three proteins of the latter group the DNA-complexed conformation also occurs in a few uncomplexed structures. This behavior can be described by a conformational ensemble, which is narrowed down by DNA docking until only one single DNA-complexed conformation occurs. Different docking models are discussed and each of the seven proteins is assigned to one of them.     

Backbone assignment of the binary complex of the full length <Emphasis Type="Italic">Sulfolobus solfataricus</Emphasis> DNA polymerase IV and DNA

Sulfolobus solfataricus DNA polymerase IV (Dpo4), a model Y-family DNA polymerase, bypasses a wide range of DNA lesions in vitro and in vivo. In this paper, we report the backbone chemical shift assignments of the full length Dpo4 in its binary complex with a 14/14-mer DNA substrate. Upon DNA binding, several β-stranded regions in the isolated catalytic core and little finger/linker fragments of Dpo4 become more structured. This work serves as a foundation for our ongoing investigation of conformational dynamics of Dpo4 and future determination of the first solution structures of a DNA polymerase and its binary and ternary complexes.     

A multiscale dynamic model of DNA supercoil relaxation by topoisomerase IB

In this study, we report what we believe to be the first multiscale simulation of the dynamic relaxation of DNA supercoils by human topoisomerase IB (topo IB). We leverage our previous molecular dynamics calculations of the free energy landscape describing the interaction between a short DNA fragment and topo IB. Herein, this landscape is used to prescribe boundary conditions for a computational, elastodynamic continuum rod model of a long length of supercoiled DNA. The rod model, which accounts for the nonlinear bending, twisting, and electrostatic interaction of the (negatively charged) DNA backbone, is extended to include the hydrodynamic drag induced by the surrounding physiological buffer. Simulations for a 200-bp-long DNA supercoil in complex with topo IB reveal a relaxation timescale of ∼0.1–1.0 μs. The relaxation follows a sequence of cascading reductions in the supercoil linking number (Lk), twist (Tw), and writhe (Wr) that follow companion cascading reductions in the supercoil elastic and electrostatic energies. The novel (to our knowledge) multiscale modeling method may enable simulations of the entire experimental setup that measures DNA supercoiling and relaxation via single molecule magnetic trapping.     

Backbone assignment of the little finger domain of a Y-family DNA polymerase

Sulfolobus solfataricus DNA polymerase IV (Dpo4), a prototype Y-family DNA polymerase, contains a unique little finger domain besides a catalytic core. Here, we report the chemical shift assignments for the backbone nitrogens, α and β carbons, and amide protons of the little finger domain of Dpo4. This work and our published backbone assignment for the catalytic core provide the basis for investigating the conformational dynamics of Dpo4 during catalysis using solution NMR spectroscopy.     

DNA binding and mutation spectra of the carcinogen N-2-aminofluorene in Escherichia coli. A correlation between the conformation of the premutagenic lesion and the mutation specificity

When the chemical carcinogen N-2-acetylaminofluorene binds to DNA in vivo, two major adducts are formed, both at position C-8 of the guanine residue. One of these (the acetylaminofluorene adduct) retains the acetyl group, while the other (the aminofluorene adduct) is the corresponding deacetylated form. Unlike -AAF adducts, which trigger important structural changes of the DNA secondary structure (either the insertion-denaturation model or the induction of a Z-DNA structure, depending upon the local nucleotide sequence), -AF adducts bind to the C-8 of guanine residues without causing any major conformational change of the B-DNA structure. Well-defined adducts (either -AF or -AAF) can be formed in vitro by reacting DNA with either N-hydroxy-N-2-aminofluorene or N-acetoxy-N-2-acetylaminofluorene. Specific cleavage of the phosphodiester backbone at -AF adducts can be achieved by treating -AF-modified DNA in 1 M-piperidine at 90 degrees C. This observation led us to construct the spectrum for -AF binding to a defined DNA restriction fragment. It is found that only guanine residues react to form alkali-labile lesions and that the reactivity among the different guanines is similar. In a forward mutation assay, namely the inactivation of the tetracycline resistance gene, we found previously that more than 90% of mutations induced by -AAF adducts are frameshift mutations. Using the same assay, we show here that -AF adducts induce primarily base substitution mutations (85%), mainly of the G to T transversion type. There is therefore a strong correlation between the nature of the carcinogen-induced conformational change of the DNA structure and the corresponding mutation specificity. The -AF-induced base substitution mutations depend upon the umuC gene function(s). The data obtained in our forward mutation assay are compared to the data previously obtained in the histidine reversion assay (Ames test).     

Solution structure of an oligonucleotide containing an abasic site: evidence for an unusual deoxyribose conformation

The antitumor antibiotic bleomycin causes two major lesions in the deoxyribose backbone of DNA: formation of 4′-keto abasic sites and formation of strand breaks with 3′-phosphoglycolate and 5′-phosphate ends. As a model for the 4′-keto abasic site, we have characterized an abasic site (X) in d(CCAAAGXACTGGG)·d(CCCAGTACTTTGG) by two-dimensional NMR spectroscopy. A total of 475 NOEs and 101 dihedral angles provided the restraints for molecular modeling. Four unusual NOEs were observed between each anomer of the abasic site and the neighboring bases. In addition, four coupling constants for adjacent protons of the deoxyribose of both the α and β anomers of the abasic site were observed. The modeling suggests that for both anomers the abasic site is extrahelical, without significant distortion of the backbone opposite the lesion. The coupling constants further allowed assignment of an unusual sugar pucker for each anomer. The unique position of the abasic site in our structural model for each anomer is discussed in terms of repair of such lesions in vivo.     

Evaluating the Effect of Ionic Strength on Duplex Stability for PNA Having Negatively or Positively Charged Side Chains

The enhanced thermodynamic stability of PNA:DNA and PNA:RNA duplexes compared with DNA:DNA and DNA:RNA duplexes has been attributed in part to the lack of electrostatic repulsion between the uncharged PNA backbone and negatively charged DNA or RNA backbone. However, there are no previously reported studies that systematically evaluate the effect of ionic strength on duplex stability for PNA having a charged backbone. Here we investigate the role of charge repulsion in PNA binding by synthesizing PNA strands having negatively or positively charged side chains, then measuring their duplex stability with DNA or RNA at varying salt concentrations. At low salt concentrations, positively charged PNA binds more strongly to DNA and RNA than does negatively charged PNA. However, at medium to high salt concentrations, this trend is reversed, and negatively charged PNA shows higher affinity for DNA and RNA than does positively charged PNA. These results show that charge screening by counterions in solution enables negatively charged side chains to be incorporated into the PNA backbone without reducing duplex stability with DNA and RNA. This research provides new insight into the role of electrostatics in PNA binding, and demonstrates that introduction of negatively charged side chains is not significantly detrimental to PNA binding affinity at physiological ionic strength. The ability to incorporate negative charge without sacrificing binding affinity is anticipated to enable the development of PNA therapeutics that take advantage of both the inherent benefits of PNA and the multitude of charge-based delivery technologies currently being developed for DNA and RNA.     

Mutational analysis of the base-flipping mechanism of uracil DNA glycosylase

The DNA repair enzyme uracil DNA glycosylase (UDG) locates unwanted uracil bases in genomic DNA using a remarkable base-flipping mechanism in which the entire deoxyuridine nucleotide is rotated from the DNA base stack into the enzyme active site. Enzymatic base flipping has been described as a three-step process involving phosphodiester backbone pinching, base extrusion through active pushing and plugging by a leucine side chain that inserts in the DNA minor groove, and, finally, pulling by hydrogen-bonding groups that interact with the extrahelical base. Here we employ mutagenesis in combination with transient kinetic approaches to assess the functional roles of six conserved enzymatic groups of UDG that have been implicated in the "pinch, push, plug, and pull" base-flipping mechanism. Our results show that these mutant enzymes are capable of flipping the uracil base from the duplex, but that many of these mutations prevent a subsequent induced fit conformational step in which catalytic groups of UDG dock with the flipped-out base. These studies support our previous model for base flipping in which a conformational gating step closely follows base extrusion from the DNA duplex [Stivers, J. T., et al. (1999) Biochemistry 38, 952-963]. A model that accounts for the temporal and functional roles of these side chain interactions along the reaction pathway for base flipping is presented.     

Hydration effects on the duplex stability of phosphoramidate DNA-RNA oligomers.

Recent studies on uniformly modified oligonucleotides containing 3'-NHP(O)(O-)O-5'internucleoside linkages (3'amidate) and alternatively modified oligonucleotides containing 3'-O(O-)(O)PNH-5'internucleoside linkages (5'amidate) have shown that 3'amidate duplexes, formed with DNA or RNA complementary strands, are more stable in water than those of the corresponding phosphodiesters. In contrast, 5'amidates do not form duplexes at all. There is no steric reason that the 5'amidate duplex should not form. We demonstrate that these differences arise from differential solvation of the sugar-phosphate backbones. By molecular dynamics calculations on models of 10mer single-stranded DNA and double-stranded DNA-RNA molecules, both with and without the phosphoramidate backbone modifications, we show that the single-stranded 3'amidate and 5'amidate backbones are equally well solvated, but the 5'amidate backbone is not adequately solvated in an A-form duplex. These results are supported by quantum chemical free energy of solvation calculations which show that the 3'amidate backbone is favored relative to the 5'amidate backbone.     

Rearrangement of side-chains in a Zif268 mutant highlights the complexities of zinc finger-DNA recognition.

Structural and biochemical studies of Cys(2)His(2) zinc finger proteins initially led several groups to propose a "recognition code" involving a simple set of rules relating key amino acid residues in the zinc finger protein to bases in its DNA site. One recent study from our group, involving geometric analysis of protein-DNA interactions, has discussed limitations of this idea and has shown how the spatial relationship between the polypeptide backbone and the DNA helps to determine what contacts are possible at any given position in a protein-DNA complex. Here we report a study of a zinc finger variant that highlights yet another source of complexity inherent in protein-DNA recognition. In particular, we find that mutations can cause key side-chains to rearrange at the protein-DNA interface without fundamental changes in the spatial relationship between the polypeptide backbone and the DNA. This is clear from a simple analysis of the binding site preferences and co-crystal structures for the Asp20-->Ala point mutant of Zif268. This point mutation in finger one changes the specificity of the protein from GCG TGG GCG to GCG TGG GC(G/T), and we have solved crystal structures of the D20A mutant bound to both types of sites. The structure of the D20A mutant bound to the GCG site reveals that contacts from key residues in the recognition helix are coupled in complex ways. The structure of the complex with the GCT site also shows an important new water molecule at the protein-DNA interface. These side-chain/side-chain interactions, and resultant changes in hydration at the interface, affect binding specificity in ways that cannot be predicted either from a simple recognition code or from analysis of spatial relationships at the protein-DNA interface. Accurate computer modeling of protein-DNA interfaces remains a challenging problem and will require systematic strategies for modeling side-chain rearrangements and change in hydration.     

A conformational rationale for the replication of nucleic acids under prebiotic conditions

The Watson-Crick model at once gave an explanation for the mechanism of replication of DNA. But the hydrogen-bonding forces between the bases alone are not enough for the specificity of base-pairing mechanisms, since any pair of bases can be positioned to have at least two hydrogen bonds. In the present-day biological organisms, sophisticated enzymatic machinery is supposed to constrain the ribose-phosphate backbone to have regular structure, aiding the self-templating duplication. For the prebiotic stage, whence sophisticated enzymes would not have been evolved, we propose a novel double helical conformation of DNA wherein the two sugar-phosphate backbones are pulled towards each other by (CH  O) hydrogen bonds conferring stereospecificity for the formation of (A : T)- and (G : C)-pairs, in the self-templating chains of DNA. Our model-building efforts and computer calculations endorse the stereochemical feasibility of the conformation. The pairing of homologous sequences of two double helices of DNA is explained by direct hydrogen-bonding interactions in our model and it is thus relevant to the present-day biological functions also, at least in some stages of the cell-cycle.     

Molecular dynamics simulations of DNA within a nanopore: arginine-phosphate tethering and a binding/sliding mechanism for translocation

Protein nanopores show great potential as low-cost detectors in DNA sequencing devices. To date, research has largely focused on the staphylococcal pore α-hemolysin (αHL). In the present study, we have developed simplified models of the wild-type αHL pore and various mutants in order to study the translocation dynamics of single-stranded DNA under the influence of an applied electric field. The model nanopores reflect the experimentally measured conductance values in planar lipid bilayers. We show that interactions between rings of cationic amino acids and DNA backbone phosphates result in metastable tethering of nucleic acid molecules within the pore, leading us to propose a "binding and sliding" mechanism for translocation. We also observe folding of DNA into nonlinear conformational intermediates during passage through the confined nanopore environment. Despite adopting nonlinear conformations, the DNA hexamer always exits the pore in the same orientation as it enters (3' to 5') in our simulations. The observations from our simulations help to rationalize experimentally determined trends in residual current and translocation efficiency for αHL and its mutants.     

Photo-induced hole transfer from base to sugar in DNA: relationship to primary radiation damage

This work presents the hypothesis that photo-excitation of G.+ in DNA and model systems results in the same electronic states expected from direct ionization of the sugar phosphate backbone and that these states lead to specific sugar radicals on the DNA sugar phosphate backbone. As evidence we show that visible photo-excitation of guanine cation radicals (G.+) in the dinucleoside phosphate TpdG results in high yields (about 85%) of deoxyribose sugar radicals at the C1' and C3' sites. Further, we have calculated transition energies of hole transfer from G.+ in TpdG using time-dependent density functional theory (TD-DFT) at the B3LYP/6-31G(d) level in gas phase as well as in a solvated environment. These calculations clearly predict that visible excitation of G.+ in TpdG causes transitions from only inner-shell filled molecular orbitals (MOs) to the singly occupied molecular orbital (SOMO) that effectively result in hole transfer from guanine either to the sugar phosphate backbone or to the adjacent base, thymine. The hole transfer is followed by rapid deprotonation from the sugar to form C1' and C3' radicals. These experimental and theoretical results are in agreement with our previously published experimental and theoretical results that photo-excitation of G.+ results in high yields of deoxyribose sugar radicals in DNA, guanine deoxyribonucleosides and deoxyribonucleotides. Photo-excitation of G.+ therefore provides a convenient method to produce and study sugar radicals that are expected to be formed in gamma-irradiated DNA systems unencumbered by the many other pathways involved in direct ionization.