Eric Van Dyck

Binding of double-strand breaks in DNA by human Rad52 protein

Double-strand breaks (DSBs) in DNA are caused by ionizing radiation. These chromosomal breaks can kill the cell unless repaired efficiently, and inefficient or inappropriate repair can lead to mutation, gene translocation and cancer. Two proteins that participate in the repair of DSBs are Rad52 and Ku: in lower eukaryotes such as yeast, DSBs are repaired by Rad52-dependent homologous recombination, whereas vertebrates repair DSBs primarily by Ku-dependent non-homologous end-joining. The contribution of homologous recombination to vertebrate DSB repair, however, is important. Biochemical studies indicate that Ku binds to DNA ends and facilitates end-joining. Here we show that human Rad52, like Ku, binds directly to DSBs, protects them from exonuclease attack and facilitates end-to-end interactions. Amodel for repair is proposed in which either Ku or Rad52 binds the DSB. Ku directs DSBs into the non-homologous end-joining repair pathway, whereas Rad52 initiates repair by homologous recombination. Ku and Rad52, therefore, direct entry into alternative pathways for the repair of DNA breaks.

The human Rad52 protein exists as a heptameric ring

The RAD52 epistasis group was identified in yeast as a group of genes required to repair DNA damaged by ionizing radiation [1]. Genetic evidence indicates that Rad52 functions in Rad51-dependent and Rad51-independent recombination pathways [2] [3] [4]. Consistent with this, purified yeast and human Rad52 proteins have been shown to promote single-strand DNA annealing [5] [6] [7] and to stimulate Rad51-mediated homologous pairing [8] [9] [10] [11]. Electron microscopic examinations of the yeast [12] and human [13] Rad52 proteins have revealed their assembly into ring-like structures in vitro. Using both conventional transmission electron microscopy and scanning transmission electron microscopy (STEM), we found that the human Rad52 protein forms heptameric rings. A three-dimensional (3D) reconstruction revealed that the heptamer has a large central channel. Like the hexameric helicases such as Escherichia coli DnaB [14] [15], bacteriophage T7 gp4b [16] [17], simian virus 40 (SV40) large T antigen [18] and papilloma virus E1 [19], the Rad52 rings show a distinctly chiral arrangement of subunits. Thus, the structures formed by the hexameric helicases may be a more general property of other proteins involved in DNA metabolism, including those, such as Rad52, that do not bind and hydrolyze ATP.

The meiosis‐specific recombinase hDmc1 forms ring structures and interacts with hRad51

Eukaryotic cells encode two homologs of Escherichia coli RecA protein, Rad51 and Dmc1, which are required for meiotic recombination. Rad51, like E.coli RecA, forms helical nucleoprotein filaments that promote joint molecule and heteroduplex DNA formation. Electron microscopy reveals that the human meiosis‐specific recombinase Dmc1 forms ring structures that bind single‐stranded (ss) and double‐stranded (ds) DNA. The protein binds preferentially to ssDNA tails and gaps in duplex DNA. hDmc1–ssDNA complexes exhibit an irregular, often compacted structure, and promote strand‐transfer reactions with homologous duplex DNA. hDmc1 binds duplex DNA with reduced affinity to form nucleoprotein complexes. In contrast to helical RecA/Rad51 filaments, however, Dmc1 filaments are composed of a linear array of stacked protein rings. Consistent with the requirement for two recombinases in meiotic recombination, hDmc1 interacts directly with hRad51.

G-quadruplex structures in TP53 intron 3: role in alternative splicing and in production of p53 mRNA isoforms

The tumor suppressor gene TP53, encoding p53, is expressed as several transcripts. The fully spliced p53 (FSp53) transcript encodes the canonical p53 protein. The alternatively spliced p53I2 transcript retains intron 2 and encodes Δ40p53 (or ΔNp53), an isoform lacking first 39 N-terminal residues corresponding to the main transactivation domain. We demonstrate the formation of G-quadruplex structures (G4) in a GC-rich region of intron 3 that modulates the splicing of intron 2. First, we show the formation of G4 in synthetic RNAs encompassing intron 3 sequences by ultraviolet melting, thermal difference spectra and circular dichroism spectroscopy. These observations are confirmed by detection of G4-induced reverse transcriptase elongation stops in synthetic RNA of intron 3. In this region, p53 pre-messenger RNA (mRNA) contains a succession of short exons (exons 2 and 3) and introns (introns 2 and 4) covering a total of 333 bp. Site-directed mutagenesis of G-tracts putatively involved in G4 formation decreased by ~30% the excision of intron 2 in a green fluorescent protein-reporter splicing assay. Moreover, treatment of lymphoblastoid cells with 360A, a synthetic ligand that binds to single-strand G4 structures, increases the formation of FSp53 mRNA and decreases p53I2 mRNA expression. These results indicate that G4 structures in intron 3 regulate the splicing of intron 2, leading to differential expression of transcripts encoding distinct p53 isoforms.

Precise binding of single‐stranded DNA termini by human RAD52 protein

The human RAD52 protein, which exhibits a heptameric ring structure, has been shown to bind resected double strand breaks (DSBs), consistent with an early role in meiotic recombination and DSB repair. In this work, we show that RAD52 binds single‐stranded and tailed duplex DNA molecules via precise interactions with the terminal base. When probed with hydroxyl radicals, ssDNA–RAD52 complexes exhibit a four‐nucleotide repeat hypersensitivity pattern. This unique pattern is due to the interaction of RAD52 with either a 5′ or a 3′ terminus of the ssDNA, is sequence independent and is phased precisely from the terminal nucleotide. Hypersensitivity is observed over ∼36 nucleotides, consistent with the length of DNA that is protected by RAD52 in nuclease protection assays. We propose that RAD52 binds DNA breaks via specific interactions with the terminal base, leading to the formation of a precisely organized ssDNA–RAD52 complex in which the DNA lies on an exposed surface of the protein. This protein–DNA arrangement may facilitate the DNA–DNA interactions necessary for RAD52‐mediated annealing of complementary DNA strands.

Visualization of recombination intermediates produced by RAD52-mediated single-strand annealing

Double‐strand breaks (DSBs) occur frequently during DNA replication. They are also caused by ionizing radiation, chemical damage or as part of the series of programmed events that occur during meiosis. In yeast, DSB repair requires RAD52, a protein that plays a critical role in homologous recombination. Here we describe the actions of human RAD52 protein in a model system for single‐strand annealing (SSA) using tailed (i.e. exonuclease resected) duplex DNA molecules. Purified human RAD52 protein binds resected DSBs and promotes associations between complementary DNA termini. Heteroduplex intermediates of these recombination reactions have been visualized by electron microscopy, revealing the specific binding of multiple rings of RAD52 to the resected termini and the formation of large protein complexes at heteroduplex joints formed by RAD52‐mediated annealing.

A PIF-dependent recombinogenic signal in the mitochondrial DNA of yeast

From their recombination properties, tandem rho‐ mutants of the mitochondrial genome of Saccharomyces cerevisiae were divided into two categories. In crosses between PIF‐independent rho‐ and rho+ strains, the recombination frequency is low and similar in PIF/pif and pif/pif diploids. In crosses between PIF‐dependent rho‐ and rho+ strains, the recombination frequency is stimulated 10‐50 times in PIF/pif diploids and is drastically decreased in pif/pif diploids. These results suggest that a recombinogenic signal is present in the mitochondrial (mt) DNA of PIF‐dependent rho‐ clones. This signal is not recognized in pif mutants. Sequence analysis of a series of small (<300 bp) overlapping tandem rho‐ genomes located in the ery region of the 21S rRNA gene led us to identify an essential element of this signal within a 41‐bp A+T sequence exhibiting over 26 bp a perfect dyad symmetry. However the recombinogenic signal is not sequence‐specific since the sequence described above does not characterize PIF‐dependent rho‐ clones located in the oli1 region. Our results rather suggest that the recombinogenic signal is related to the topology of rho‐ DNA. Denaturated sites in the double helix or cruciform structures elicited by local negative supercoiling might be preferred sites of the initiation of recombination.

Subcellular distribution of human RDM1 protein isoforms and their nucleolar accumulation in response to heat shock and proteotoxic stress

The RDM1 gene encodes a RNA recognition motif (RRM)-containing protein involved in the cellular response to the anti-cancer drug cisplatin in vertebrates. We previously reported a cDNA encoding the full-length human RDM1 protein. Here, we describe the identification of 11 human cDNAs encoding RDM1 protein isoforms. This repertoire is generated by alternative pre-mRNA splicing and differential usage of two translational start sites, resulting in proteins with long or short N-terminus and a great diversity in the exonic composition of their C-terminus. By using tagged proteins and fluorescent microscopy, we examined the subcellular distribution of full-length RDM1 (renamed RDM1α), and other RDM1 isoforms. We show that RDM1α undergoes subcellular redistribution and nucleolar accumulation in response to proteotoxic stress and mild heat shock. In unstressed cells, the long N-terminal isoforms displayed distinct subcellular distribution patterns, ranging from a predominantly cytoplasmic to almost exclusive nuclear localization, suggesting functional differences among the RDM1 proteins. However, all isoforms underwent stress-induced nucleolar accumulation. We identified nuclear and nucleolar localization determinants as well as domains conferring cytoplasmic retention to the RDM1 proteins. Finally, RDM1 null chicken DT40 cells displayed an increased sensitivity to heat shock, compared to wild-type (wt) cells, suggesting a function for RDM1 in the heat-shock response.