Ian D. Hickson

The Bloom's syndrome helicase suppresses crossing over during homologous recombination

Mutations in BLM, which encodes a RecQ helicase, give rise to Blooms syndrome, a disorder associated with cancer predisposition and genomic instability. A defining feature of Blooms syndrome is an elevated frequency of sister chromatid exchanges. These arise from crossing over of chromatid arms during homologous recombination, a ubiquitous process that exists to repair DNA double-stranded breaks and damaged replication forks. Whereas crossing over is required in meiosis, in mitotic cells it can be associated with detrimental loss of heterozygosity. BLM forms an evolutionarily conserved complex with human topoisomerase IIIα (hTOPO IIIα), which can break and rejoin DNA to alter its topology. Inactivation of homologues of either protein leads to hyper-recombination in unicellular organisms. Here, we show that BLM and hTOPO IIIα together effect the resolution of a recombination intermediate containing a double Holliday junction. The mechanism, which we term double-junction dissolution, is distinct from classical Holliday junction resolution and prevents exchange of flanking sequences. Loss of such an activity explains many of the cellular phenotypes of Blooms syndrome. These results have wider implications for our understanding of the process of homologous recombination and the mechanisms that exist to prevent tumorigenesis.

RecQ helicases: caretakers of the genome

RecQ helicases are highly conserved from bacteria to man. Germline mutations in three of the five known family members in humans give rise to debilitating disorders that are characterized by, amongst other things, a predisposition to the development of cancer. One of these disorders — Blooms syndrome — is uniquely associated with a predisposition to cancers of all types. So how do RecQ helicases protect against cancer? They seem to maintain genomic stability by functioning at the interface between DNA replication and DNA repair.

The Bloom’s Syndrome Helicase Unwinds G4 DNA

BLM, the gene that is defective in Bloom’s syndrome, encodes a protein homologous to RecQ subfamily helicases that functions as a 3′-5′ DNA helicase in vitro. We now report that the BLM helicase can unwind G4 DNA. The BLM G4 DNA unwinding activity is ATP-dependent and requires a short 3′ region of single-stranded DNA. Strikingly, G4 DNA is a preferred substrate of the BLM helicase, as measured both by efficiency of unwinding and by competition. These results suggest that G4 DNA may be a natural substrate of BLM in vivo and that the failure to unwind G4 DNA may cause the genomic instability and increased frequency of sister chromatid exchange characteristic of Bloom’s syndrome.

XRCC1 coordinates the initial and late stages of DNA abasic site repair through protein-protein interactions.

The major human AP endonuclease APE1 (HAP1, APEX, Ref1) initiates the repair of abasic sites generated either spontaneously, from attack of bases by free radicals, or during the course of the repair of damaged bases. APE1 therefore plays a central role in the base excision repair (BER) pathway. We report here that XRCC1, another essential protein involved in the maintenance of genome stability, physically interacts with APE1 and stimulates its enzymatic activities. A truncated form of APE1, lacking the first 35 amino acids, although catalytically proficient, loses the affinity for XRCC1 and is not stimulated by XRCC1. Chinese ovary cell lines mutated in XRCC1 have a diminished capacity to initiate the repair of AP sites. This defect is compensated by the expression of XRCC1. XRCC1, acting as both a scaffold and a modulator of the different activities involved in BER, would provide a physical link between the incision and sealing steps of the AP site repair process. The interaction described extends the coordinating role of XRCC1 to the initial step of the repair of DNA abasic sites.

Sgs1: A eukaryotic homolog of E. coil RecQ that interacts with topoisomerase II in vivo and is required for faithful chromosome segregation

Topoisomerase II (topo II) catalyzes the decatenation of interlinked DNA molecules and is essential for chromosome segregation. To test the hypothesis that the noncatalytic C-terminal domain of topo II is necessary for mediating interactions with other proteins required for chromosome segregation, we used a two-hybrid cloning strategy to identify proteins that interact with S. cerevisiae topo II in vivo. One protein identified (Sgs1p) is structurally related to E. coli RecQ protein and contains helicase signature motifs. Strains lacking Sgs1p exhibit elevated levels of chromosome misseggregation during both mitotic and meiotic division. We propose a model to account for the interaction of a topoisomerase and a helicase in the faithful segregation of newly replicated eukaryotic chromosomes.

Replication stress induces sister-chromatid bridging at fragile site loci in mitosis

Several inherited syndromes in humans are associated with cancer predisposition. The gene products defective in two of these disorders, BLM (a helicase defective in Blooms syndrome) and FANC A–N (defective in Fanconi anaemia), associate in a multienzyme complex called BRAFT. How these proteins suppress tumorigenesis remains unclear, although both conditions are associated with chromosome instability. Here we show that the Fanconi anaemia proteins FANCD2 and FANCI specifically associate with common fragile site loci irrespective of whether the chromosome is broken. Unexpectedly, these loci are frequently interlinked through BLM-associated ultra-fine DNA bridges (UFBs) even as cells traverse mitosis. Similarly to fragile site expression, fragile site bridging is induced after partial inhibition of DNA replication. We propose that, after replication stress, sister chromatids are interlinked by replication intermediates primarily at genetic loci with intrinsic replication difficulties, such as fragile sites. In Blooms syndrome cells, inefficient resolution of DNA linkages at fragile sites gives rise to increased numbers of anaphase UFBs and micronuclei containing fragile site DNA. Our data have general implications concerning the contribution of fragile site loci to chromosomal instability and tumorigenesis.

Werner's syndrome protein (WRN) migrates Holliday junctions and co-localizes with RPA upon replication arrest

Individuals affected by the autosomal recessive disorder Werners syndrome (WS) develop many of the symptoms characteristic of premature ageing. Primary fibroblasts cultured from WS patients exhibit karyotypic abnormalities and a reduced replicative life span. The WRN gene encodes a 3′–5′ DNA helicase, and is a member of the RecQ family, which also includes the product of the Blooms syndrome gene (BLM). In this work, we show that WRN promotes the ATP‐dependent translocation of Holliday junctions, an activity that is also exhibited by BLM. In cells arrested in S‐phase with hydroxyurea, WRN localizes to discrete nuclear foci that coincide with those formed by the single‐stranded DNA binding protein replication protein A. These results are consistent with a model in which WRN prevents aberrant recombination events at sites of stalled replication forks by dissociating recombination intermediates.

53BP1 nuclear bodies form around DNA lesions generated by mitotic transmission of chromosomes under replication stress

Completion of genome duplication is challenged by structural and topological barriers that impede progression of replication forks. Although this can seriously undermine genome integrity, the fate of DNA with unresolved replication intermediates is not known. Here, we show that mild replication stress increases the frequency of chromosomal lesions that are transmitted to daughter cells. Throughout G1, these lesions are sequestered in nuclear compartments marked by p53-binding protein 1 (53BP1) and other chromatin-associated genome caretakers. We show that the number of such 53BP1 nuclear bodies increases after genetic ablation of BLM, a DNA helicase associated with dissolution of entangled DNA. Conversely, 53BP1 nuclear bodies are partially suppressed by knocking down SMC2, a condensin subunit required for mechanical stability of mitotic chromosomes. Finally, we provide evidence that 53BP1 nuclear bodies shield chromosomal fragile sites sequestered in these compartments against erosion. Together, these data indicate that restoration of DNA or chromatin integrity at loci prone to replication problems requires mitotic transmission to the next cell generations.

RecQ helicases: suppressors of tumorigenesis and premature aging.

The RecQ helicases represent a subfamily of DNA helicases that are highly conserved in evolution. Loss of RecQ helicase function leads to a breakdown in the maintenance of genome integrity, in particular hyper-recombination. Germ-line defects in three of the five known human RecQ helicases give rise to defined genetic disorders associated with cancer predisposition and/or premature aging. These are Blooms syndrome, Werners syndrome and Rothmund-Thomson syndrome, which are caused by defects in the genes BLM, WRN and RECQ4 respectively. Here we review the properties of RecQ helicases in organisms from bacteria to humans, with an emphasis on the biochemical functions of these enzymes and the range of protein partners that they operate with. We will discuss models in which RecQ helicases are required to protect against replication fork demise, either through prevention of fork breakdown or restoration of productive DNA synthesis.

The Bloom’s Syndrome Gene Product Is a 3′-5′ DNA Helicase

Bloom’s syndrome (BS) is an autosomal recessive condition characterized by short stature, immunodeficiency, and a greatly elevated frequency of many types of cancer. The gene mutated in BS, BLM, encodes a protein containing seven “signature” motifs conserved in a wide range of DNA and RNA helicases. BLM is most closely related to the subfamily of DEXH box-containing DNA helicases of which the prototypical member is Escherichia coli RecQ. To analyze its biochemical properties, we have overexpressed an oligohistidine-tagged version of the BLMgene product in Saccharomyces cerevisiae and purified the protein to apparent homogeneity using nickel chelate affinity chromatography. The recombinant BLM protein possesses an ATPase activity that is strongly stimulated by either single- or double-stranded DNA. Moreover, BLM exhibits ATP- and Mg2+-dependent DNA helicase activity that displays 3′-5′ directionality. Because many of the mutations in BS individuals are predicted to truncate the BLM protein and thus eliminate the “helicase” motifs or map to conserved positions within these motifs, our data strongly suggest that these mutations will disable the 3′-5′ helicase function of the BLM protein.