Arun Mouli Kolinjivadi scite author profile

SummaryBrca2 deficiency causes Mre11-dependent degradation of nascent DNA at stalled forks, leading to cell lethality. To understand the molecular mechanisms underlying this process, we isolated Xenopus laevis Brca2. We demonstrated that Brca2 protein prevents single-stranded DNA gap accumulation at replication fork junctions and behind them by promoting Rad51 binding to replicating DNA. Without Brca2, forks with persistent gaps are converted by Smarcal1 into reversed forks, triggering extensive Mre11-dependent nascent DNA degradation. Stable Rad51 nucleofilaments, but not RPA or Rad51T131P mutant proteins, directly prevent Mre11-dependent DNA degradation. Mre11 inhibition instead promotes reversed fork accumulation in the absence of Brca2. Rad51 directly interacts with the Pol α N-terminal domain, promoting Pol α and δ binding to stalled replication forks. This interaction likely promotes replication fork restart and gap avoidance. These results indicate that Brca2 and Rad51 prevent formation of abnormal DNA replication intermediates, whose processing by Smarcal1 and Mre11 predisposes to genome instability.

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Moonlighting at replication forks – a new life for homologous recombination proteins BRCA1, BRCA2 and RAD51

Kolinjivadi

et al. 2017

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Edited by Wilhelm JustCoordination between DNA replication and DNA repair ensures maintenance of genome integrity, which is lost in cancer cells. Emerging evidence has linked homologous recombination (HR) proteins RAD51, BRCA1 and BRCA2 to the stability of nascent DNA. This function appears to be distinct from double-strand break (DSB) repair and is in part due to the prevention of MRE11-mediated degradation of nascent DNA at stalled forks. The role of RAD51 in fork protection resembles the activity described for its prokaryotic orthologue RecA, which prevents nuclease-mediated degradation of DNA and promotes replication fork restart in cells challenged by DNA-damaging agents. Here, we examine the mechanistic aspects of HR-mediated fork protection, addressing the crosstalk between HR and replication proteins.Keywords: DNA recombination; DNA replication; genome stability BRCA1, BRCA2, RAD51 and the RAD51 paralogs family, which consists of five proteins (RAD51B, RAD51C, RAD51D, XRCC2 and XRCC3) in mammalian cells, are required to repair DNA damage by homologous recombination (HR). Mutations in most of these genes predispose to cancer, indicating an important role of DNA damage repair in preventing cell transformation. Intriguingly, complete loss of function of most of HR proteins is incompatible with life in vertebrate organisms [1,2,3]. These features together with their ability to form foci in unperturbed and challenged S-phase nuclei indicate a role for HR proteins in chromosomal DNA replication even in unchallenged conditions [4,5].The mechanisms underlying the function of DNA repair proteins in unchallenged chromosomal DNA replication are poorly understood. This is in part due to the fact that many of the genes involved in DNA metabolism are essential for cell viability, which complicate their study, especially in higher eukaryotes [1,2,3]. The reasons why HR genes are essential for cell viability in higher eukaryotes are unclear. One explanation might be that they have a specific and direct role in the replication of complex eukaryotic genomes. Alternatively, complex genomes might be more vulnerable to spontaneous DNA damage, which might irreversibly halt replication progression inducing chromosomes breakage. HR factors might be therefore required to repair the damage and to complete whole genome duplication. Here we review the links between HR proteins and the DNA replication machinery, some of which appear to be conserved between prokaryotes and eukaryotes.

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RUNX Poly(ADP-Ribosyl)ation and BLM Interaction Facilitate the Fanconi Anemia Pathway of DNA Repair

et al. 2018

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The Fanconi anemia (FA) pathway is a pivotal genome maintenance network that orchestrates the repair of DNA interstrand crosslinks (ICLs). The tumor suppressors RUNX1 and RUNX3 were shown to regulate the FA pathway independent of their canonical transcription activities, by controlling the DNA damage-dependent chromatin association of FANCD2. Here, in further biochemical characterization, we demonstrate that RUNX3 is modified by PARP-dependent poly(ADP-ribosyl)ation (PARylation), which in turn allows RUNX binding to DNA repair structures lacking transcription-related RUNX consensus motifs. SILAC-based mass spectrometric analysis revealed significant association of RUNX3 with core DNA repair complexes, including PARP1, even in unstressed cells. After DNA damage, the increased interaction between RUNX3 and BLM facilitates efficient FANCD2 chromatin localization. RUNX-Walker motif mutations from breast cancers are impaired for DNA damage-inducible PARylation, unveiling a potential mechanism for FA pathway inactivation in cancers. Our results reinforce the emerging paradigm that RUNX proteins are tumor suppressors with genome gatekeeper function.

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Functional relationship between p53 and RUNX proteins

Bae

Kolinjivadi

Ito

2018

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RUNX genes belong to a three-membered family of transcription factors, which are well established as master regulators of development. Of them, aberrations in RUNX3 expression are frequently observed in human malignancies primarily due to epigenetic silencing, which is often overlooked. At the G1 phase of the cell cycle, RUNX3 regulates the restriction (R)-point, a mechanism that decides cell cycle entry. Deregulation at the R-point or loss of RUNX3 results in premature entry into S phase, leading to a proliferative advantage. Inactivation of Runx1 and Runx2 induce immortalization of mouse embryo fibroblast. As a consequence, RUNX loss induces pre-cancerous lesions independent of oncogene activation. p53 is the most extensively studied tumour suppressor. p53 plays an important role to prevent tumour progression but not tumour initiation. Therefore, upon oncogene activation, early inactivation of RUNX genes and subsequent mutation of p53 appear to result in tumour initiation and progression. Recently, transcription-independent DNA repairing roles of RUNX3 and p53 are emerging. Being evolutionarily old genes, it appears that the primordial function of p53 is to protect genome integrity, a function that likely extends to the RUNX gene as well. In this review, we examine the mechanism and sequence of actions of these tumour suppressors in detail.

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