Your search keyword '"Richardson, Julia M."' showing total 6 results

1. Structural basis for DNA 3'-end processing by human tyrosyl-DNA phosphodiesterase 1.

Author

Flett FJ, Ruksenaite E, Armstrong LA, Bharati S, Carloni R, Morris ER, Mackay CL, Interthal H, and Richardson JM

Subjects

Base Sequence, Catalytic Domain, Crystallography, X-Ray, DNA chemistry, DNA genetics, Humans, Models, Molecular, Nucleic Acid Conformation, Phosphoric Diester Hydrolases chemistry, Protein Binding, Protein Domains, DNA metabolism, DNA Damage, DNA Repair, Phosphoric Diester Hydrolases metabolism

Abstract

Tyrosyl-DNA phosphodiesterase (Tdp1) is a DNA 3'-end processing enzyme that repairs topoisomerase 1B-induced DNA damage. We use a new tool combining site-specific DNA-protein cross-linking with mass spectrometry to identify Tdp1 interactions with DNA. A conserved phenylalanine (F259) of Tdp1, required for efficient DNA processing in biochemical assays, cross-links to defined positions in DNA substrates. Crystal structures of Tdp1-DNA complexes capture the DNA repair machinery after 3'-end cleavage; these reveal how Tdp1 coordinates the 3'-phosphorylated product of nucleosidase activity and accommodates duplex DNA. A hydrophobic wedge splits the DNA ends, directing the scissile strand through a channel towards the active site. The F259 side-chain stacks against the -3 base pair, delimiting the junction of duplexed and melted DNA, and fixes the scissile strand in the channel. Our results explain why Tdp1 cleavage is non-processive and provide a molecular basis for DNA 3'-end processing by Tdp1.

Published

2018

2. A bend, flip and trap mechanism for transposon integration.

Author

Morris ER, Grey H, McKenzie G, Jones AC, and Richardson JM

Subjects

Crystallography, X-Ray, Models, Molecular, Nucleic Acid Conformation, Protein Binding, Protein Conformation, DNA chemistry, DNA metabolism, DNA Transposable Elements, DNA-Binding Proteins chemistry, DNA-Binding Proteins metabolism, Recombination, Genetic, Transposases chemistry, Transposases metabolism

Abstract

Cut-and-paste DNA transposons of the mariner/Tc1 family are useful tools for genome engineering and are inserted specifically at TA target sites. A crystal structure of the mariner transposase Mos1 (derived from Drosophila mauritiana), in complex with transposon ends covalently joined to target DNA, portrays the transposition machinery after DNA integration. It reveals severe distortion of target DNA and flipping of the target adenines into extra-helical positions. Fluorescence experiments confirm dynamic base flipping in solution. Transposase residues W159, R186, F187 and K190 stabilise the target DNA distortions and are required for efficient transposon integration and transposition in vitro. Transposase recognises the flipped target adenines via base-specific interactions with backbone atoms, offering a molecular basis for TA target sequence selection. Our results will provide a template for re-designing mariner/Tc1 transposases with modified target specificities.

Published

2016

3. Structural Basis for the Inverted Repeat Preferences of mariner Transposases.

Author

Trubitsyna M, Grey H, Houston DR, Finnegan DJ, and Richardson JM

Subjects

Adenine chemistry, Animals, Base Sequence, Crystallography, X-Ray, DNA genetics, DNA-Binding Proteins genetics, Gene Expression Regulation, Enzymologic, Guanine chemistry, Models, Molecular, Molecular Sequence Data, Protein Conformation, Transposases genetics, DNA metabolism, DNA-Binding Proteins chemistry, DNA-Binding Proteins metabolism, Drosophila enzymology, Inverted Repeat Sequences genetics, Plasmids genetics, Transposases chemistry, Transposases metabolism

Abstract

The inverted repeat (IR) sequences delimiting the left and right ends of many naturally active mariner DNA transposons are non-identical and have different affinities for their transposase. We have compared the preferences of two active mariner transposases, Mos1 and Mboumar-9, for their imperfect transposon IRs in each step of transposition: DNA binding, DNA cleavage, and DNA strand transfer. A 3.1 Å resolution crystal structure of the Mos1 paired-end complex containing the pre-cleaved left IR sequences reveals the molecular basis for the reduced affinity of the Mos1 transposase DNA-binding domain for the left IR as compared with the right IR. For both Mos1 and Mboumar-9, in vitro DNA transposition is most efficient when the preferred IR sequence is present at both transposon ends. We find that this is due to the higher efficiency of cleavage and strand transfer of the preferred transposon end. We show that the efficiency of Mboumar-9 transposition is improved almost 4-fold by changing the 3' base of the preferred Mboumar-9 IR from guanine to adenine. This preference for adenine at the reactive 3' end for both Mos1 and Mboumar-9 may be a general feature of mariner transposition., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015

4. Structural role of the flanking DNA in mariner transposon excision

Author

Dornan, Jacqueline, Grey, Heather, and Richardson, Julia M

Subjects

DNA-Binding Proteins, Models, Molecular, Structural Biology, Amino Acid Motifs, Mutation, Genetics, Biocatalysis, DNA Transposable Elements, Transposases, DNA, DNA Cleavage, Protein Binding

Abstract

During cut-and-paste mariner/Tc1 transposition, transposon DNA is cut precisely at its junction with flanking DNA, ensuring the transposon is neither shortened nor lengthened with each transposition event. Each transposon end is flanked by a TpA dinucleotide: the signature target site duplication of mariner/Tc1 transposition. To establish the role of this sequence in accurate DNA cleavage, we have determined the crystal structure of a pre-second strand cleavage mariner Mos1 transpososome. The structure reveals the route of an intact DNA strand through the transposase active site before second strand cleavage. The crossed architecture of this pre-second strand cleavage paired-end complex supports our proposal that second strand cleavage occurs in trans. The conserved mariner transposase WVPHEL and YSPDL motifs position the strand for accurate DNA cleavage. Base-specific recognition of the flanking DNA by conserved amino acids is revealed, defining a new role for the WVPHEL motif in mariner transposition and providing a molecular explanation for in vitro mutagenesis data. Comparison of the pre-TS cleavage and post-cleavage Mos1 transpososomes with structures of Prototype Foamy Virus intasomes suggests a binding mode for target DNA prior to Mos1 transposon integration.

Published

2015

5. Crystallization of a Mos1 transposase–inverted-repeat DNA complex: biochemical and preliminary crystallographic analyses.

Author

Richardson, Julia M., Finnegan, David J., and Walkinshaw, Malcolm D.

Subjects

*CRYSTALLIZATION, *DNA, *GENES, *X-ray diffraction, *PROTEIN analysis, *SPECTRUM analysis

Abstract

A complex formed between Mos1 transposase and its inverted-repeat DNA has been crystallized. The crystals diffract to 3.25 Å resolution and exhibit monoclinic ( P21) symmetry, with unit-cell parameters a = 120.8, b = 85.1, c = 131.6 Å, β = 99.3°. The X-ray diffraction data display noncrystallographic twofold symmetry and characteristic dsDNA diffraction at ∼3.3 Å. Biochemical analyses confirmed the presence of DNA and full-length protein in the crystals. The relationship between the axis of noncrystallographic symmetry, the unit-cell axes and the DNA diffraction pattern are discussed. The data are consistent with the previously proposed model of the paired-ends complex containing a dimer of the transposase. [ABSTRACT FROM AUTHOR]

Published

2007

6. Mechanism of Mos1 transposition: insights from structural analysis.

Author

Richardson, Julia M., Dawson, Angela, O'Hagan, Natasha, Taylor, Paul, Finnegan, David J., and Walkinshaw, Malcolm D.

Subjects

*RIBONUCLEASES, *DNA-binding proteins, *BINDING sites, *CHROMOSOMAL translocation, *DNA

Abstract

We present the crystal structure of the catalytic domain of Mos1 transposase, a member of the Tc1/mariner family of transposases. The structure comprises an RNase H-like core, bringing together an aspartic acid triad to form the active site, capped by N- and C-terminal α-helices. We have solved structures with either one Mg2+ or two Mn2+ ions in the active site, consistent with a two-metal mechanism for catalysis. The lack of hairpin-stabilizing structural motifs is consistent with the absence of a hairpin intermediate in Mos1 excision. We have built a model for the DNA-binding domain of Mos1 transposase, based on the structure of the bipartite DNA-binding domain of Tc3 transposase. Combining this with the crystal structure of the catalytic domain provides a model for the paired-end complex formed between a dimer of Mos1 transposase and inverted repeat DNA. The implications for the mechanisms of first and second strand cleavage are discussed. [ABSTRACT FROM AUTHOR]

Published

2006