Formation, translocation and resolution of Holliday junctions during homologous genetic recombination

Computational Insights into the Dynamic Structural Features and Binding Characteristics of Recombinase UvsX Compared with RecA

RecA family recombinases are the core enzymes in the process of homologous recombination, and their normal operation ensures the stability of the genome and the healthy development of organisms. The UvsX protein from bacteriophage T4 is a member of the RecA family recombinases and plays a central role in T4 phage DNA repair and replication, which provides an important model for the biochemistry and genetics of DNA metabolism. UvsX shares a high degree of structural similarity and function with RecA, which is the most deeply studied member of the RecA family. However, the detailed molecular mechanism of UvsX has not been resolved. In this study, a comprehensive all-atom molecular dynamics simulation of the UvsX protein dimer complex was carried out in order to investigate the conformational and binding properties of UvsX in combination with ATP and DNA, and the simulation of RecA was synchronized with the property comparison learning for UvsX. This study confirmed the highly conserved molecular structure characteristics and catalytic centers of RecA and UvsX, and also discovered differences in regional conformation, volatility and the ability to bind DNA between the two proteins at different temperatures, which would be helpful for the subsequent understanding and application of related recombinases.

Resolution of the Holliday junction recombination intermediate by human GEN1 at the single-molecule level

Human GEN1 is a cytosolic homologous recombination protein that resolves persisting four-way Holliday junctions (HJ) after the dissolution of the nuclear membrane. GEN1 dimerization has been suggested to play key role in the resolution of the HJ, but the kinetic details of its reaction remained elusive. Here, single-molecule FRET shows how human GEN1 binds the HJ and always ensures its resolution within the lifetime of the GEN1-HJ complex. GEN1 monomer generally follows the isomer bias of the HJ in its initial binding and subsequently distorts it for catalysis. GEN1 monomer remains tightly bound with no apparent dissociation until GEN1 dimer is formed and the HJ is fully resolved. Fast on- and slow off-rates of GEN1 dimer and its increased affinity to the singly-cleaved HJ enforce the forward reaction. Furthermore, GEN1 monomer binds singly-cleaved HJ tighter than intact HJ providing a fail-safe mechanism if GEN1 dimer or one of its monomers dissociates after the first cleavage. The tight binding of GEN1 monomer to intact- and singly-cleaved HJ empowers it as the last resort to process HJs that escape the primary mechanisms.

Suppression of spontaneous genome rearrangements in yeast DNA helicase mutants

Saccharomyces cerevisiae mutants lacking two of the three DNA helicases Sgs1, Srs2, and Rrm3 exhibit slow growth that is suppressed by disrupting homologous recombination. Cells lacking Sgs1 and Rrm3 accumulate gross-chromosomal rearrangements (GCRs) that are suppressed by the DNA damage checkpoint and by homologous recombination-defective mutations. In contrast, rrm3, srs2, and srs2 rrm3 mutants have wild-type GCR rates. GCR types in helicase double mutants include telomere additions, translocations, and broken DNAs healed by a complex process of hairpin-mediated inversion. Spontaneous activation of the Rad53 checkpoint kinase in the rrm3 mutant depends on the Mec3/Rad24 DNA damage sensors and results from activation of the Mec1/Rad9-dependent DNA damage response rather than the Mrc1-dependent replication stress response. Moreover, helicase double mutants accumulate Rad51-dependent Ddc2 foci, indicating the presence of recombination intermediates that are sensed by checkpoints. These findings demonstrate that different nonreplicative helicases function at the interface between replication and repair to maintain genome integrity.

Requirement of Rrm3 helicase for repair of spontaneous DNA lesions in cells lacking Srs2 or Sgs1 helicase

The Rrm3 DNA helicase of Saccharomyces cerevisiae interacts with proliferating cell nuclear antigen and is required for replication fork progression through ribosomal DNA repeats and subtelomeric and telomeric DNA. Here, we show that rrm3 srs2 and rrm3 sgs1 mutants, in which two different DNA helicases have been inactivated, exhibit a severe growth defect and undergo frequent cell death. Cells lacking Rrm3 and Srs2 arrest in the G(2)/M phase of the cell cycle with 2N DNA content and frequently contain only a single nucleus. The phenotypes of rrm3 srs2 and rrm3 sgs1 mutants were suppressed by disrupting early steps of homologous recombination. These observations identify Rrm3 as a new member of a network of pathways, involving Sgs1 and Srs2 helicases and Mus81 endonuclease, suggested to act during repair of stalled replication forks.

Comparison of bacteriophage T4 UvsX and human Rad51 filaments suggests that RecA-like polymers may have evolved independently

The UvsX protein from bacteriophage T4 is a member of the RecA/Rad51/RadA family of recombinases active in homologous genetic recombination. Like RecA, Rad51 and RadA, UvsX forms helical filaments on DNA. We have used electron microscopy and a novel method for image analysis of helical filaments to show that UvsX-DNA filaments exist in two different conformations: an ADP state and an ATP state. As with RecA protein, these two states have a large difference in pitch. Remarkably, even though UvsX is only weakly homologous to RecA, both UvsX filament states are more similar to the RecA crystal structure than are RecA-DNA filaments. We use this similarity to fit the RecA crystal structure into the UvsX filament, and show that two of the three previously described blocks of similarity between UvsX and RecA are involved in the subunit-subunit interface in both the UvsX filament and the RecA crystal filament. Conversely, we show that human Rad51-DNA filaments have a different subunit-subunit interface than is present in the RecA crystal, and this interface involves two blocks of sequence similarity between Rad51 and RecA that do not overlap with those found between UvsX and RecA. This suggests that helical filaments in the RecA/Rad51/RadA family may have arisen from convergent evolution, with a conserved core structure that has assembled into multimeric filaments in a number of different ways.

Rings and filaments of beta protein from bacteriophage lambda suggest a superfamily of recombination proteins

The beta protein of bacteriophage lambda acts in homologous genetic recombination by catalyzing the annealing of complementary single-stranded DNA produced by the lambda exonuclease. It has been shown that the beta protein binds to the products of the annealing reaction more tightly than to the initial substrates. We find that beta protein exists in three structural states. In the absence of DNA, beta protein forms inactive rings with approximately 12 subunits. The active form of the beta protein in the presence of oligonucleotides or single-stranded DNA is a ring, composed of approximately 15-18 subunits. The double-stranded products of the annealing reaction catalyzed by the rings are bound by beta protein in a left-handed helical structure, which protects the products from nucleolytic degradation. These observations suggest structural homology for a family of proteins, including the phage P22 erf, the bacterial RecT, and the eukaryotic Rad52 proteins, all of which are involved in homologous recombination.

Bacterial helicases

Helicases are proteins that use the energy of ATP hydrolysis to open double-stranded DNA, RNA, or RNA-DNA hybrids into two single strands. Based upon sequence analysis, at least 12 helicases exist in Escherichia coli. We know that these proteins play important roles in DNA replication, recombination, repair, and transcription, as well as in RNA processing. Recent crystallographic studies have revealed a highly conserved catalytic core in the helicases, shared with the RecA protein and the F1-ATPase. However, evidence suggests that the functional divergence may be large.

Identification of a defined epitope on the surface of the active RecA-DNA filament using a monoclonal antibody and three-dimensional reconstruction

Studies of the Escherichia coli RecA protein are expected to illuminate mechanisms of DNA recombination and repair in bacteria, and in all higher organisms as well, due to the functional and structural homology with the eukaryotic Rad51 protein. The active form of the RecA protein is a helical filament formed on DNA in the presence of ATP or ATP analogs, and this has been studied at low-resolution by electron microscopy. An atomic model of the protein comes from an X-ray crystallographic study of a filament formed in the absence of DNA and ATP. This filament is believed to be an inactive, storage form of the protein. A key step in generating an atomic model of the active filament, and a detailed model for function, is to understand the large conformational changes that occur between these two states. Towards this end, we have decorated active RecA-DNA filaments with monoclonal antibodies (ARM191) against a known epitope (residues 285 to 320) to determine the position of this epitope in the low-resolution structure. Electron microscopy and three-dimensional reconstruction of the RecA-antibody complex reveal that the lobe containing the epitope is very disordered on the surface of the filament, but in a position similar to that in the inactive crystal filament. The antibody binding also induces a significant conformational change in the RecA filament. This study shows that the basic orientation of the subunit is likely to be similar within the inactive and active filaments, and that the large movement of mass that occurs between these two states must involve other residues than the 285-320 region.

Three-way and four-way junctions in DNA: a conformational viewpoint

DNA junctions are potential intermediates in various important genetic processes, including mutagenesis and recombination. The quantity of research carried out in this area is rapidly increasing. Examples of three-way and four-way junctions are now relatively well characterized and a few common properties have been recognized, of which the most important is the tendency of junctions to fold into one or more coaxially stacked helical conformations or cross-over structures.

Cloning, sequencing, and expression of ruvB and characterization of RuvB proteins from two distantly related thermophilic eubacteria

The ruvB genes of the highly divergent thermophilic eubacteria Thermus thermophilus and Thermotoga maritima were cloned, sequenced, and expressed in Escherichia coli. Both thermostable RuvB proteins were purified to homogeneity. Like E. coli RuvB protein, both purified thermostable RuvB proteins showed strong double-stranded DNA-dependent ATPase activity at their temperature optima (> or = 70 degrees C). In the absence of ATP, T. thermophilus RuvB protein bound to linear double-stranded DNA with a preference for the ends. Addition of ATP or gamma-S-ATP destabilized the T. thermophilus RuvB-DNA complexes. Both thermostable RuvB proteins displayed helicase activity on supercoiled DNA. Expression of thermostable T. thermophilus RuvB protein in the E. coli ruvB recG mutant strain N3395 partially complemented the UV-sensitive phenotype, suggesting that T. thermophilus RuvB protein has a function similar to that of E. coli RuvB in vivo.