Phoebe A. Rice

Mobile DNA III

This new edition of the bestselling series on movable genetic elements highlights the many exciting advances in the field over the last decade, including conservative site-specific recombination, programmed rearrangements, DNA-only transposons, and LTR, and non-LTR retrotransposons. Virtually all organisms contain multiple mobile DNAs that can move from place to place, and in some organisms, mobile DNA elements make up a significant portion of the genome. Mobile DNA III provides a comprehensive review of recent research, revealing the many important roles that mobile DNAs play in genome structure, function, and evolution. This book is part three of a series on mobile DNA. This title is published by the American Society of Microbiology Press and distributed by Taylor and Francis in rest of world territories.

Crystal Structure of an IHF-DNA Complex: A Protein-Induced DNA U-Turn

Integration host factor (IHF) is a small heterodimeric protein that specifically binds to DNA and functions as an architectural factor in many cellular processes in prokaryotes. Here, we report the crystal structure of IHF complexed with 35 bp of DNA. The DNA is wrapped around the protein and bent by >160 degrees, thus reversing the direction of the helix axis within a very short distance. Much of the bending occurs at two large kinks where the base stacking is interrupted by intercalation of a proline residue. IHF contacts the DNA exclusively via the phosphodiester backbone and the minor groove and relies heavily on indirect readout to recognize its binding sequence. One such readout involves a six-base A tract, providing evidence for the importance of a narrow minor groove.

Crystal structure of a Rad51 filament.

Rad51, the major eukaryotic homologous recombinase, is important for the repair of DNA damage and the maintenance of genomic diversity and stability. The active form of this DNA-dependent ATPase is a helical filament within which the search for homology and strand exchange occurs. Here we present the crystal structure of a Saccharomyces cerevisiae Rad51 filament formed by a gain-of-function mutant. This filament has a longer pitch than that seen in crystals of Rad51s prokaryotic homolog RecA, and places the ATPase site directly at a new interface between protomers. Although the filament exhibits approximate six-fold symmetry, alternate protein-protein interfaces are slightly different, implying that the functional unit of Rad51 within the filament may be a dimer. Additionally, we show that mutation of His352, which lies at this new interface, markedly disrupts DNA binding.

Structure of the bacteriophage Mu transposase core: a common structural motif for DNA transposition and retroviral integration.

The crystal structure of the core domain of bacteriophage Mu transposase, MuA, has been determined at 2.4 A resolution. The first of two subdomains contains the active site and, despite very limited sequence homology, exhibits a striking similarity to the core domain of HIV-1 integrase, which carries out a similar set of biochemical reactions. It also exhibits more limited similarity to other nucleases, RNase H and RuvC. The second, a beta barrel, connects to the first subdomain through several contacts. Three independent determinations of the monomer structure from two crystal forms all show the active site held in a similar, apparently inactive configuration. The enzymatic activity of MuA is known to be activated by formation of a DNA-bound tetramer of the protein. We propose that the connections between the two subdomains may be involved in the cross-talk between the active site and the other domains of the transposase that controls the activity of the protein.

Crystal structure of a Flp recombinase-Holliday junction complex: assembly of an active oligomer by helix swapping.

Abstract The crystal structure of a Flp recombinase tetramer bound to a Holliday junction intermediate has been determined at 2.65 A resolution. Only one of Flps two domains, containing the active site, is structurally related to other λ integrase family site-specific recombinases, such as Cre. The Flp active site differs, however, in that the helix containing the nucleophilic tyrosine is domain swapped, such that it cuts its DNA target in trans. The Flp tetramer displays pseudo four-fold symmetry matching that of the square planar Holliday junction substrate. This tetramer is stabilized by additional novel trans interactions among monomers. The structure illustrates how mechanistic unity is maintained on a chemical level while allowing for substantial variation on the structural level within a family of enzymes.

Comparative architecture of transposase and integrase complexes

Transposases and retroviral integrases promote the movement of DNA segments to new locations within and between genomes. These recombinases function as multimeric protein–DNA complexes. Recent success in solving the crystal structure of a Tn5 transposase–DNA complex provides the first detailed structural information about a member of the transposase/integrase superfamily in its active, DNA-bound state. Here, we summarize the reactions catalyzed by transposases and integrases and review the Tn5 transposase–DNA co-crystal structure. The insights gained from the Tn5 structure and other available structures are considered together with biochemical and genetic data to discuss features that are likely to prove common to the catalytic complexes used by members of this important protein family.

Flexible DNA bending in HU–DNA cocrystal structures

HU and IHF are members of a family of prokaryotic proteins that interact with the DNA minor groove in a sequence‐specific (IHF) or non‐specific (HU) manner to induce and/or stabilize DNA bending. HU plays architectural roles in replication initiation, transcription regulation and site‐specific recombination, and is associated with bacterial nucleoids. Cocrystal structures of Anabaena HU bound to DNA (1P71, 1P78, 1P51) reveal that while underlying proline intercalation and asymmetric charge neutralization mechanisms of DNA bending are similar for IHF and HU, HU stabilizes different DNA bend angles (∼105–140°). The two bend angles within a single HU complex are not coplanar, and the resulting dihedral angle is consistent with negative supercoiling. Comparison of HU–DNA and IHF–DNA structures suggests that sharper bending is correlated with longer DNA binding sites and smaller dihedral angles. An HU‐induced bend may be better modeled as a hinge, not a rigid bend. The ability to induce or stabilize varying bend angles is consistent with HUs role as an architectural cofactor in many different systems that may require differing geometries.

THE PHAGE MU TRANSPOSOSOME CORE : DNA REQUIREMENTS FOR ASSEMBLY AND FUNCTION

The two chemical steps of phage Mu transpositional recombination, donor DNA cleavage and strand transfer, take place within higher order protein‐DNA complexes called transpososomes. At the core of these complexes is a tetramer of MuA (the transposase), bound to the two ends of the Mu genome. While transpososome assembly normally requires a number of cofactors, under certain conditions only MuA and a short DNA fragment are required. DNA requirements for this process, as well as the stability and activity of the ensuing complexes, were established. The divalent cation normally required for assembly of the stable complex could be omitted if the substrate was prenicked, if the flanking DNA was very short or if the two flanking strands were non‐complementary. The presence of a single nucleotide beyond the Mu genome end on the non‐cut strand was critical for transpososome stability. Donor cleavage additionally required at least two flanking nucleotides on the strand to be cleaved. The flanking DNA double helix was destabilized, implying distortion of the DNA near the active site. Although donor cleavage required Mg2+, strand transfer took place in the presence of Ca2+ as well, suggesting a conformational difference in the active site for the two chemical steps.

Crystal structures of DNA/RNA repair enzymes AlkB and ABH2 bound to dsDNA

Escherichia coli AlkB and its human homologues ABH2 and ABH3 repair DNA/RNA base lesions by using a direct oxidative dealkylation mechanism. ABH2 has the primary role of guarding mammalian genomes against 1-meA damage by repairing this lesion in double-stranded DNA (dsDNA), whereas AlkB and ABH3 preferentially repair single-stranded DNA (ssDNA) lesions and can repair damaged bases in RNA. Here we show the first crystal structures of AlkB–dsDNA and ABH2–dsDNA complexes, stabilized by a chemical cross-linking strategy. This study reveals that AlkB uses an unprecedented base-flipping mechanism to access the damaged base: it squeezes together the two bases flanking the flipped-out one to maintain the base stack, explaining the preference of AlkB for repairing ssDNA lesions over dsDNA ones. In addition, the first crystal structure of ABH2, presented here, provides a structural basis for designing inhibitors of this human DNA repair protein.

A G-quadruplex–containing RNA activates fluorescence in a GFP-like fluorophore

Spinach is an in vitro selected RNA aptamer that binds a GFP-like ligand and activates its green fluorescence.Spinach is thus an RNA analog of GFP, and has potentially widespread applications for in vivo labeling and imaging. We used antibody-assisted crystallography to determine the structures of Spinach both with and without bound fluorophore at 2.2 and 2.4 Å resolution, respectively. Spinach RNA has an elongated structure containing two helical domains separated by an internal bulge that folds into a G-quadruplex motif of unusual topology. The G-quadruplex motif and adjacent nucleotides comprise a partially pre-formed binding site for the fluorophore.The fluorophore binds in a planar conformation and makes extensive aromatic stacking and hydrogen bond interactions with the RNA. Our findings provide a foundation for structure-based engineering of new fluorophore-binding RNA aptamers.