Intrinsic Bent DNA Sites in the Developmentally Amplified C3-22 Gene Promoter of Rhynchosciara americana (Diptera: Sciaridae)

The Rhynchosciara americana C3-22 gene is located in an amplified domain and is developmentally expressed. The aim of the present work was to identify intrinsically bent DNA sites in a segment containing the gene promoter and downstream sequence. The results indicated that this gene is flanked by intrinsically bent DNA sites. Three bent DNA sites (b^?3, b^?2, and b^?1) were localized in the promoter, and one was localized downstream of the gene (b⁺¹). These sites had helical parameters that confirmed the curved structure, as well as segments with left-handed superhelical writhe. In silico analysis of the promoters of four other insect genes, which encode secreted polypeptides, showed that they all had curved structures and similar helical parameters. Correlation with other results indicates that the detected intrinsically bent DNA sites that flank the C3-22 gene might be a consensus feature of the gene structure in the amplified domains.     

Replication origins oriGNAI3 and oriB of the mammalian AMPD2 locus nested in a region of straight DNA flanked by intrinsically bent DNA sites

The aim of this work was to determine whether intrinsically bent DNA sites are present at, or close to, the mammalian replication origins oriGNAI3 and oriB in the Chinese hamster AMPD2 locus. Using an electrophoretic mobility shift assay and in silico analysis, we located four intrinsically bent DNA sites (b1 to b4) in a fragment that contains the oriGNAI3 and one site (b5) proximal to oriB. The helical parameters show that each bent DNA site is curved in a left-handed superhelical writhe. A 2D projection of 3D fragment trajectories revealed that oriGNAI3 is located in a relatively straight segment flanked by bent sites b1 and b2, which map in previously identified Scaffold/Matrix Attachment Region. Sites b3 and b4 are located approximately 2 kb downstream and force the fragment into a strong closed loop structure. The b5 site is also located in an S/MAR that is found just downstream of oriB.     

Straight core structure of DNA replication origins in the mammalian AMPD2 locus

Identification of the nucleotide consensus sequence in mammalian replication origins is a difficult and controversial problem. The hypothesis that local DNA topology could be involved in recognition by replication proteins is an exciting possibility. Secondary DNA structures, including intrinsically bent DNA, can be easily detected, and they may indicate a specific pattern in or near mammalian replication origins. This work presents the entire mapping of the intrinsically bent DNA sites (IBDSs), using in silico analysis and a circular permutation assay, of the DNA replication origins oriGNAI3, oriC, oriB, and oriA in the mammalian amplified AMPD2 gene domain. The results show that each origin presents an IBDS that flanks the straight core of these DNA replication sites. In addition, the in silico prediction of the nucleosome positioning reveals a strong indication that the center of an IBDS is localized in a nucleosome-free region (NFR). The structure of each of these curved sites is presented together with their helical parameters and topology. Together, the data that we present here indicate that the oriGNAI3 origin where preferential firing to the replication initiation events in the amplified AMPD2 domain occurs is the only origin that presents a straight, narrow region that is flanked on both sides by two intrinsically bent DNA sites within a short distance (～300 bp); however, all of the origins present at least one IBDS, which is localized in the NFR region. These results indicate that structural features could be implicated in the mammalian DNA replication origin and support the possibility of detecting and characterizing these segments.     

Differential structure of the intronic promoter of the Bombyx mori A3 actin gene correlated with silkworm sensitivity/resistance to nucleopolyhedrovirus

Previous reports demonstrated that actin is necessary for nucleocapsid transport and viral gene expression during nucleopolyhedrovirus infection of Bombyx mori. The first intron of B. mori A3 actin contains a cryptic promoter that drives expression of a rare isoform. We detected differences in the size and nucleotide composition of the first intron of the A3 actin gene from B. mori strain C24A, which is more resistant to nucleopolyhedrovirus than the M11A strain (22 and 95% lethality, respectively). We sought to determine if resistance to BmMNPV infection and the A3 actin promoter structure are correlated. Intrinsically bent DNA sites in these sequences, which determine curved structures, were analyzed by electrophoretic mobility assays and the helical parameters ENDS ratio, roll and twist. We found both fragments to have non-centralized bent DNA sites with distinct ENDS ratio values, nucleotide positions and two-dimensional structures. Additionally, a conformational-sensitive gel electrophoresis assay identified an allelic variation found in strain M11A that is absent in strain C24A. These data suggest that A3 actin intronic sequence variations impair virus propagation and are markers of BmMNPV-resistant populations.     

Intrinsically bent DNA in replication origins and gene promoters

Intrinsically bent DNA is an alternative conformation of the DNA molecule caused by the presence of dA/dT tracts, 2 to 6 bp long, in a helical turn phase DNA or with multiple intervals of 10 to 11 bp. Other than flexibility, intrinsic bending sites induce DNA curvature in particular chromosome regions such as replication origins and promoters. Intrinsically bent DNA sites are important in initiating DNA replication, and are sometimes found near to regions associated with the nuclear matrix. Many methods have been developed to localize bent sites, for example, circular permutation, computational analysis, and atomic force microscopy. This review discusses intrinsically bent DNA sites associated with replication origins and gene promoter regions in prokaryote and eukaryote cells. We also describe methods for identifying bent DNA sites for circular permutation and computational analysis.     

Intrinsically bent DNA sites in the <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> third chromosome amplified domain

Bent DNA sites promote the curvature of DNA in both eukaryotic and prokaryotic chromosomes. Here, we investigate the localization and structure of intrinsically bent DNA sites in the extensively characterized Drosophila melanogaster third chromosome DAFC-66D segment (Drosophila amplicon in the follicle cells). This region contains the amplification control element ACE3, which is a replication enhancer that acts in cis to activate the major replication origin ori-β. Through both electrophoretic and in silico analysis, we have identified three major bent DNA sites in DAFC-66D. The bent DNA site (b1) is localized in the ACE3 element, whereas the other two bent DNA sites (b2 and b3) are localized in the ori-β region. Four additional bent DNA sites were identified in the intron of the S18 gene and near the TATA box of the S15, S19, and S16 genes. The identification of DNA bent sites in genomic regions previously characterized as functionally relevant for DNA amplification further supports a function for DNA bent sites in DNA replication in eukaryotes. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

The conformation of constitutive DNA interaction sites for eukaryotic DNA topoisomerase I on intrinsically curved DNAs.

The analysis of the sites which are cleaved constitutively and preferentially by eukaryotic DNA topoisomerase I on two intrinsically curved DNAs reveals the conformational features that provoke the cleavage reaction on the curve-inducing sequence elements in the absence of supercoiling. This analysis is based on the observation (Caserta et al. (1989) Nucleic Acids Res. 17, 8521-8532 and (1990) Biochemistry 29, 8152-8157) that the reaction of eukaryotic DNA topoisomerase I occurs on two types of DNA sites: sites S (Supercoiled induced) and sites C (Constitutive, whose presence is topology-independent). We report that sites C are abundant on the intrinsically curved DNAs analyzed. The DNAs studied were two intrinsically curved segments of different origin: the Crithidia fasciculata kinetoplast DNA and the bent-containing domain B of the Saccharomyces cerevisiae ARS1. On these DNA segments DNA topoisomerase I cleaves at the junctions between the poly(A) tracts and mixed-sequence DNA. Analysis of the conformation of the double helix around the cleavage sites has revealed that the reaction occurs in correspondence of a defined DNA conformational motif. This motif is described by the set of Eulerian angular values that define the axial path of DNA (helical twist, deflection angle, direction) and of the orthogonal components of wedge (roll and tilt).     

Helical periodicity of (PNA)2.(DNA) triplexes in strand displacement complexes.

To study the helical structure in a P-loop formed by an invasion of oligopyrimidine peptide nucleic acid (PNA) into DNA duplex, bent DNA fragments containing a homopurine.homopyrimidine sequence between two bent DNA loci were prepared. As the spacer DNA length between the two bent loci varied by 1 bp over one helical turn, the electrophoretic mobility, reflecting the overall extent of DNA bending, was modulated sinusoidally in non-denaturing 5% polyacrylamide gel. When the bent DNA fragments differing in the spacer DNA length were preincubated with an oligopyrimidine PNA, the gel mobilities were changed due to a P-loop formation. By analyzing the gel mobility data with variations of the P-loop size, average helical parameters at the P-loop structure were determined. (PNA)2. (DNA) triplex within a P-loop had the helical periodicities of 15. 6(0.2) bp per turn at 20 degrees C and 17.4(0.7) bp per turn at 10 degrees C. In addition, the results indicate that a helical unwinding by 57(7) degrees at 20 degrees C and 37(13) degrees at 10 degrees C is present at the two junctions between a P-loop and its adjacent DNA duplex.     

Intrinsically bent DNA in the promoter regions of the yeast GAAL1-10 and GAL80 genes

Circular permutation analysis has detected fairly strong sites of intrinsic DNA bending on the promoter regions of the yeast GAL1-10 and GAL80 genes. These bends lie in functionally suggestive locations. On the promoter of the GAL1-10 structural genes, strong bends bracket nucleosome B, which lies between the UAS(G) and the GAL1 TATA. These intrinsic bends could help position nucleosome B. Nucleosome B plus two other promoter nucleosomes protect the TATA and start site elements in the inactive state of expression but are completely disrupted (removed) when GAL1-10 expression is induced. The strongest intrinsic bend ( approximately 70 degrees ) lies at the downstream edge of nucleosome B; this places it approximately 30 base pairs upstream of the GAL1 TATA, a position that could allow it to be involved in GAL1 activation in several ways, including the recruitment of a yeast HMG protein that is required for the normally robust level of GAL1 expression in the induced state (Paull, T., Carey, M., and Johnson, R. (1996) Genes Dev. 10, 2769-2781). On the regulatory gene GAL80, the single bend lies in the non-nucleosomal hypersensitive region, between a GAL80-specific far upstream promoter element and the more gene-proximal promoter elements. GAL80 promoter region nucleosomes contain no intrinsically bent DNA.     

KIN17, a mouse nuclear protein, binds to bent DNA fragments that are found at illegitimate recombination junctions in mammalian cells

Illegitimate recombination is the dominant mechanism of recombination in mammalian somatic cells. It is responsible for most genome rearrangements such as translocations, deletions and integrations. Little is known as yet about the mechanism of illegitimate recombination and the enzymes involved. Recently, it has been shown that intrinsically bent DNA, also known as curved DNA, is present at chromosomal sites of illegitimate recombination events. Here we report that KIN17, a new mouse nuclear protein, binds to the curved DNA fragments found at illegitimate recombination sites.     

Attenuation of DNA-protein interactions associated with intrinsic, sequence-dependent DNA curvature.

Inherently curved DNA segments, associated with short runs of adenines, have been identified in many gene regulatory regions, yet their physiological significance remains unknown. The observations reported in this study indicate that intrinsically bent nucleic acid fragments are characterized by substantially attenuated affinities toward DNA-binding proteins involved in structural functions, such as H1 histone and protamine, as well as toward various DNA-modifying enzymes including ligases and exo- and endonucleases. Two mechanisms might be responsible for the altered binding properties. According to the first mechanism, the attenuated binding affinities and the bending represent two independent consequences of the unique structural parameters exhibited by A-tracts. Indeed, analysis of the degradation products obtained upon exposure of the curved sequences to various chemical nucleases points toward the narrowing of the DNA minor groove, a conformational modulation known to characterize A-tracts and to run along the axially-bent motifs, as a potential determinant of the observed binding attenuation. Alternatively, the conformational constraints which result from the stable bending might act to modulate the strength of DNA-protein interactions. Although the factor directly responsible for the altered binding affinities revealed by the bent sequences cannot as yet be conclusively resolved, it is proposed that a reiteration of this specific factor, being either an A-tract or a bend, in phase with the DNA helical repeat acts to amplify the modulation of the binding.(ABSTRACT TRUNCATED AT 250 WORDS)     

利用温控载体构建碱性果胶酯裂解酶工程菌

从筛选出的Bacillus subtilisWSHB04-02菌株中扩增出编码碱性果胶酯裂解酶的结构基因PL,将其插入载体pET22b( )多克隆位点,得到带有前导序列PelB重组质粒pET22b( )PL。以pET22b( )PL为模板扩增出带前导序列的碱性果胶酯裂解酶的结构基因PL,将其插入温控载体pHsh,重组载体在大肠杆菌JM109中得到表达。其表达量与以T7为启动子的重组菌BL21DE3[(pET22b( )PL]相比,表达量相近。SDS-PAGE分析显示表达产物的分子量均为43kDa,同核酸序列测定所推导的值相符。研究表明利用pHsh构建的JM109(pHsh PL)诱导表达好,诱导方式简单廉价,这对该酶的大规模发酵具有重要意义。