in Chromosome Stability and Cell Survival-Is It All about Replication Forks?

The conserved nuclease-helicase DNA2 has been linked to mitochondrial myopathy, Seckel syndrome, and cancer. Across species, the protein is indispensable for cell proliferation. On the molecular level, DNA2 has been implicated in DNA double-strand break (DSB) repair, checkpoint activation, Okazaki fragment processing (OFP), and telomere homeostasis.

Limiting homologous recombination at stalled replication forks is essential for cell viability: DNA2 to the rescue.

The disease-associated nuclease-helicase DNA2 has been implicated in DNA end-resection during DNA double-strand break repair, Okazaki fragment processing, and the recovery of stalled DNA replication forks (RFs). Its role in Okazaki fragment processing has been proposed to explain why DNA2 is indispensable for cell survival across organisms. Unexpectedly, we found that DNA2 has an essential role in suppressing homologous recombination (HR)-dependent replication restart at stalled RFs.

Disease-associated DNA2 nuclease-helicase protects cells from lethal chromosome under-replication.

DNA2 is an essential nuclease-helicase implicated in DNA repair, lagging-strand DNA synthesis, and the recovery of stalled DNA replication forks (RFs). In Saccharomyces cerevisiae, dna2Δ inviability is reversed by deletion of the conserved helicase PIF1 and/or DNA damage checkpoint-mediator RAD9. It has been suggested that Pif1 drives the formation of long 5'-flaps during Okazaki fragment maturation, and that the essential function of Dna2 is to remove these intermediates.

Compartmentalized DNA repair: Rif1 -acylation links DNA double-strand break repair to the nuclear membrane.

DNA double-strand breaks (DSBs) disrupt the structural integrity of chromosomes. Proper DSB repair pathway choice is critical to avoid the type of gross chromosomal rearrangements that characterize cancer cells. Recent findings reveal -fatty acylation and membrane anchorage of Rap1-interacting factor 1 (Rif1) as a mechanism providing spatial control over DSB repair pathway choice.

Rif1 S-acylation mediates DNA double-strand break repair at the inner nuclear membrane.

Rif1 is involved in telomere homeostasis, DNA replication timing, and DNA double-strand break (DSB) repair pathway choice from yeast to human. The molecular mechanisms that enable Rif1 to fulfill its diverse roles remain to be determined. Here, we demonstrate that Rif1 is S-acylated within its conserved N-terminal domain at cysteine residues C466 and C473 by the DHHC family palmitoyl acyltransferase Pfa4.

Structure-Specific Endonucleases and the Resolution of Chromosome Underreplication.

Complete genome duplication in every cell cycle is fundamental for genome stability and cell survival. However, chromosome replication is frequently challenged by obstacles that impede DNA replication fork (RF) progression, which subsequently causes replication stress (RS). Cells have evolved pathways of RF protection and restart that mitigate the consequences of RS and promote the completion of DNA synthesis prior to mitotic chromosome segregation.

Shepherding DNA ends: Rif1 protects telomeres and chromosome breaks.

Cells have evolved conserved mechanisms to protect DNA ends, such as those at the termini of linear chromosomes, or those at DNA double-strand breaks (DSBs). In eukaryotes, DNA ends at chromosomal termini are packaged into proteinaceous structures called telomeres. Telomeres protect chromosome ends from erosion, inadvertent activation of the cellular DNA damage response (DDR), and telomere fusion.

Rif1 maintains telomeres and mediates DNA repair by encasing DNA ends.

In yeast, Rif1 is part of the telosome, where it inhibits telomerase and checkpoint signaling at chromosome ends. In mammalian cells, Rif1 is not telomeric, but it suppresses DNA end resection at chromosomal breaks, promoting repair by nonhomologous end joining (NHEJ). Here, we describe crystal structures for the uncharacterized and conserved ∼125-kDa N-terminal domain of Rif1 from Saccharomyces cerevisiae (Rif1-NTD), revealing an α-helical fold shaped like a shepherd's crook.

A new role for Holliday junction resolvase Yen1 in processing DNA replication intermediates exposes Dna2 as an accessory replicative helicase.

DNA replication is mediated by a multi-protein complex known as the replisome. With the hexameric MCM (minichromosome maintenance) replicative helicase at its core, the replisome splits the parental DNA strands, forming replication forks (RFs), where it catalyses coupled leading and lagging strand DNA synthesis. While replication is a highly effective process, intrinsic and oncogene-induced replication stress impedes the progression of replisomes along chromosomes.

Replication intermediates that escape Dna2 activity are processed by Holliday junction resolvase Yen1.

Cells have evolved mechanisms to protect, restart and repair perturbed replication forks, allowing full genome duplication, even under replication stress. Interrogating the interplay between nuclease-helicase Dna2 and Holliday junction (HJ) resolvase Yen1, we find the Dna2 helicase activity acts parallel to homologous recombination (HR) in promoting DNA replication and chromosome detachment at mitosis after replication fork stalling. Yen1, but not the HJ resolvases Slx1-Slx4 and Mus81-Mms4, safeguards chromosome segregation by removing replication intermediates that escape Dna2.

DNA repair defects ascribed to pby1 are caused by disruption of Holliday junction resolvase Mus81-Mms4.

PBY1 continues to be linked with DNA repair through functional genomics studies in yeast. Using the yeast knockout (YKO) strain collection, high-throughput genetic interaction screens have identified a large set of negative interactions between PBY1 and genes involved in genome stability. In drug sensitivity screens, the YKO collection pby1Δ strain exhibits a sensitivity profile typical for genes involved in DNA replication and repair.

Resolving branched DNA intermediates with structure-specific nucleases during replication in eukaryotes.

Genome duplication requires that replication forks track the entire length of every chromosome. When complications occur, homologous recombination-mediated repair supports replication fork movement and recovery. This leads to physical connections between the nascent sister chromatids in the form of Holliday junctions and other branched DNA intermediates.

Rif1 and Rif2 shape telomere function and architecture through multivalent Rap1 interactions.

Yeast telomeres comprise irregular TG₁₋₃ DNA repeats bound by the general transcription factor Rap1. Rif1 and Rif2, along with Rap1, form the telosome, a protective cap that inhibits telomerase, counteracts SIR-mediated transcriptional silencing, and prevents inadvertent recognition of telomeres as DNA double-strand breaks. We provide a molecular, biochemical, and functional dissection of the protein backbone at the core of the yeast telosome.

Mechanism of Holliday junction resolution by the human GEN1 protein.

Holliday junction (HJ) resolution is essential for chromosome segregation at meiosis and the repair of stalled/collapsed replication forks in mitotic cells. All organisms possess nucleases that promote HJ resolution by the introduction of symmetrically related nicks in two strands at, or close to, the junction point. GEN1, a member of the Rad2/XPG nuclease family, was isolated recently from human cells and shown to promote HJ resolution in vitro and in vivo.

Functional overlap between the structure-specific nucleases Yen1 and Mus81-Mms4 for DNA-damage repair in S. cerevisiae.

In eukaryotic cells, multiple DNA repair mechanisms respond to a wide variety of DNA lesions. Homologous recombination-dependent repair provides a pathway for dealing with DNA double-strand breaks and replication fork demise. A key step in this process is the resolution of recombination intermediates such as Holliday junctions (HJs).

Identification of Holliday junction resolvases from humans and yeast.

Four-way DNA intermediates, also known as Holliday junctions, are formed during homologous recombination and DNA repair, and their resolution is necessary for proper chromosome segregation. Here we identify nucleases from Saccharomyces cerevisiae and human cells that promote Holliday junction resolution, in a manner analogous to that shown by the Escherichia coli Holliday junction resolvase RuvC. The human Holliday junction resolvase, GEN1, and its yeast orthologue, Yen1, were independently identified using two distinct experimental approaches: GEN1 was identified by mass spectrometry following extensive fractionation of HeLa cell-free extracts, whereas Yen1 was detected by screening a yeast gene fusion library for nucleases capable of Holliday junction resolution.

Molecular mechanism of DNA deadenylation by the neurological disease protein aprataxin.

The human neurological disease known as ataxia with oculomotor apraxia 1 is caused by mutations in the APTX gene that encodes Aprataxin (APTX) protein. APTX is a member of the histidine triad superfamily of nucleotide hydrolases and transferases but is distinct from other family members in that it acts upon DNA. The target of APTX is 5'-adenylates at DNA nicks or breaks that result from abortive DNA ligation reactions.

Defective DNA repair and neurodegenerative disease.

Defects in cellular DNA repair processes have been linked to genome instability, heritable cancers, and premature aging syndromes. Yet defects in some repair processes manifest themselves primarily in neuronal tissues. This review focuses on studies defining the molecular defects associated with several human neurological disorders, particularly ataxia with oculomotor apraxia 1 (AOA1) and spinocerebellar ataxia with axonal neuropathy 1 (SCAN1).

Actions of aprataxin in multiple DNA repair pathways.

Mutations in the Aptx gene lead to a neurological disorder known as ataxia oculomotor apraxia-1. The product of Aptx is Aprataxin (Aptx), a DNA-binding protein that resolves abortive DNA ligation intermediates. Aprataxin catalyzes the nucleophilic release of adenylate groups covalently linked to 5' phosphate termini, resulting in termini that can again serve as substrates for DNA ligases.

The neurodegenerative disease protein aprataxin resolves abortive DNA ligation intermediates.

Ataxia oculomotor apraxia-1 (AOA1) is a neurological disorder caused by mutations in the gene (APTX) encoding aprataxin. Aprataxin is a member of the histidine triad (HIT) family of nucleotide hydrolases and transferases, and inactivating mutations are largely confined to this HIT domain. Aprataxin associates with the DNA repair proteins XRCC1 and XRCC4, which are partners of DNA ligase III and ligase IV, respectively, suggestive of a role in DNA repair.

Synthetic junctions as tools to identify and characterize Holliday junction resolvases.

Genetic exchanges between chromosomes can lead to the formation of DNA intermediates known as Holliday junctions. The structure of these intermediates has been determined both biochemically and structurally, and their interactions with Holliday junction processing enzymes have been well characterized. A number of proteins, from both prokaryotic and eukaryotic sources, have been identified that promote the nucleolytic resolution of junctions.

Crp1p, a new cruciform DNA-binding protein in the yeast Saccharomyces cerevisiae.

A synthetic cruciform DNA (X-DNA) was used for screening cellular extracts of Saccharomyces cerevisiae for X-DNA-binding activity. Three X-DNA-binding proteins with apparent molecular mass of 28kDa, 26kDa and 24kDa, estimated by SDS-PAGE, were partially purified. They were identified as N-terminal fragments originating from the same putative protein, encoded by the open reading frame YHR146W, which we named CRP1 (cruciform DNA-recognising protein 1).