Yusé Martín scite author profile

Genotyping by high-resolution melting analysis of small amplicons is homogeneous and simple. However, this approach can be limited by physical and chemical components of the system that contribute to intersample melting variation. It is challenging for this method to distinguish homozygous G::C from C::G or A::T from T::A base-pair neutral variants, which comprise ∼16% of all human single nucleotide polymorphisms (SNPs). We used internal oligonucleotide calibrators and custom analysis software to improve small amplicon (42–86 bp) genotyping on the LightScanner®. Three G/C (PAH c.1155C>G, CHK2 c.1-3850G>C and candidate gene BX647987 c.261+22,290C>G) and three T/A (CPS1 c.3405-29A>T, OTC c.299-8T>A and MSH2 c.1511-9A>T) human single nucleotide variants were analyzed. Calibration improved homozygote genotyping accuracy from 91.7 to 99.7% across 1105 amplicons from 141 samples for five of the six targets. The average Tm standard deviations of these targets decreased from 0.067°C before calibration to 0.022°C after calibration. We were unable to generate a small amplicon that could discriminate the BX647987 c.261+22,290C>G (rs1869458) SNP, despite reducing standard deviations from 0.086°C to 0.032°C. Two of the sites contained symmetric nearest neighbors adjacent to the SNPs. Unexpectedly, we were able to distinguish these homozygotes by Tm even though current nearest neighbor models predict that the two homozygous alleles would be identical.

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USP29 controls the stability of checkpoint adaptor Claspin by deubiquitination

Martín

Cabrera

Amoedo

et al. 2014

Oncogene

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The DNA damage checkpoint is essential for the maintenance of genome integrity after genotoxic stress, and also for cell survival in eukaryotes. Claspin has a key role in the ATR (ATM and Rad3-related)-Chk1 branch of the DNA damage checkpoint and is also required for correct DNA replication. To achieve properly these functions, Claspin is tightly regulated by ubiquitinin-dependent proteasomal degradation, which controls Claspin levels in a DNA-damage- and cell-cycle-dependent manner. Here, we identified a new regulator of Claspin, the ubiquitin-specific peptidase 29, USP29. Downregulation of USP29 destabilizes Claspin, whereas its overexpression promotes an increase in Claspin levels. USP29 interacts with Claspin and is able to deubiquitinate it both in vivo and in vitro. Most importantly, USP29 knockdown results in an impaired phosphorylation of Chk1 after DNA damage and USP29-depleted cells show a major defect in the S-phase progression. With these results, we identified USP29 as a new player in the ATR-Chk1 pathway and the control of DNA replication.

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Mechanisms of ATR-mediated checkpoint signalling

Smits

Warmerdam²,

Martín³

et al. 2010

Front Biosci

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Cell cycle checkpoints maintain genomic integrity by delaying cell division in the presence of DNA damage or replication problems. A crucial player in this process is the ATR kinase. The rapid localisation of ATR to sites of genotoxic stress and the central role of this kinase in the checkpoint response lead to the suggestion that ATR functions as a sensor of DNA lesions. After activation, ATR phosphorylates and activates the effector kinase Chk1, thereby causing an inhibition in cell cycle progression. However, this would not be possible without the existence of many other proteins operating in this pathway. Here we review current progress in our understanding of the regulatory factors involved in the ATR-mediated checkpoint response, as well as resumption of cell cycle progression upon repair of the damage, thereby focussing on the mechanisms in mammalian cells.

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USP7 controls Chk1 protein stability by direct deubiquitination

Vega

Martín

Smits³

2014

Cell Cycle

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Chk1, an essential checkpoint kinase in the DNA damage response pathway (DDR), is tightly regulated by both ATRdependent phosphorylation and proteasome-mediated degradation. Here we identify ubiquitin hydrolase USP7 as a novel regulator of Chk1 protein stability. USP7 was shown before to regulate other DDR proteins such as p53, Hdm2 and Claspin, an adaptor protein in the ATR-Chk1 pathway required for Chk1 activation. Depletion or inhibition of USP7 leads to lower Chk1 levels. The decreased Chk1 protein after USP7 knock down cannot be rescued by simultaneously elevating Claspin levels, demonstrating that the effect of USP7 on Chk1 is independent of its known effect on Claspin. Conversely, overexpression of USP7 wild type, but not a catalytic mutant version, elevates Chk1 levels and increases the half-life of Chk1 protein. Importantly, wild type, but not catalytic mutant USP7 can deubiquitinate Chk1 in vivo and in vitro, confirming that USP7 directly regulates Chk1 protein levels. Finally we show that USP7 catalytic mutant is (mono-)ubiquitinated, which suggests auto-deubiquitination by this ubiquitin hydrolase, possibly important for its regulation.

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Yusé Martín

Wee1 controls genomic stability during replication by regulating the Mus81-Eme1 endonuclease

Base-pair neutral homozygotes can be discriminated by calibrated high-resolution melting of small amplicons

USP29 controls the stability of checkpoint adaptor Claspin by deubiquitination

Mechanisms of ATR-mediated checkpoint signalling

USP7 controls Chk1 protein stability by direct deubiquitination

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