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- Challenges and Chances: A Review of the 1st Stem Cell Community Day
- Summertime, and the Livin’ Is Easy…
- Follow-on-Biologics – More than Simple Generics
- Bacteria Versus Body Cells: A 1:1 Tie
- Behind the Crime Scene: How Biological Traces Can Help to Convict Offenders
- Every 3 Seconds Someone in the World Is Affected by Alzheimer's
- HIV – It’s Still Not Under Control…
- How Many Will Be Convicted This Time?
- Malaria – the Battle is Not Lost
- Physicians on Standby: The Annual Flu Season Can Be Serious
- At the Forefront in Fighting Cancer
- Molecular Motors: Think Small and yet Smaller Again…
- Liquid Biopsy: Novel Methods May Ease Cancer Detection and Therapy
- They Are Invisible, Sneaky and Disgusting – But Today It’s Their Special Day!
- How Many Cells Are in Your Body? Probably More Than You Think!
- What You Need to Know about Antibiotic Resistance – Findings, Facts and Good Intentions
- Why Do Old Men Have Big Ears?
- The Condemned Live Longer: A Potential Paradigm Shift in Genetics
- From Research to Commerce
- Chronobiology – How the Cold Seasons Influence Our Biorhythms
- Taskforce Microbots: Targeted Treatment from Inside the Body
- Eyes on Cancer Therapy
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- 2008年の受賞者:イギリスの王立がん研究基金のロンドンリサーチインターナショナル、Simon Boulton博士
2008 Award Winner Dr. Simon Boulton, Cancer Research UK, London Research Institute, UK
Appointment at time of winning the Award
Senior Group Leader, Cancer Research UK, London Research Institute, Clare Hall Laboratories, South Mimms, UK.
Abstract
Our research is focused on the mechanisms that sense and repair DNA damage in cells, with an emphasis on DNA double-strand break (DSB) sensing and repair. DSBs represent a major threat to genome integrity and are predominantly repaired by homologous recombination (HR). Unscheduled or excessive HR can also lead to gross chromosomal rearrangements characteristic of cancer cells, but the mechanisms that restrain HR remain poorly understood. The yeast Srs2 helicase suppress aberrant recombination by disrupting a specific step in HR, however functional homologues are not obviously conserved in higher eukaryotes. We therefore performed a genetic screen in C. elegans to identify putative anti-recombinases functionally analogous to yeast Srs2. This screen identified a novel helicase, RTEL-1 that is conserved from C. elegans to humans. We find that rtel-1 mutant worms and RTEL1 depleted human cells share characteristic phenotypes with yeast srs2 mutants: lethality upon deletion of the sgs1/BLM homologue, hyper-recombination, and DNA damage sensitivity. Biochemical analysis of RTEL1 has revealed that it antagonises HR by promoting the disassembly of D loop recombination intermediates. Since Rtel knockout mice die due to dramatic genome instability and rapid telomere loss and Human RTEL1 is over-expressed in gastric tumours, we propose that loss of HR control following deregulation of RTEL1 may be a critical event that drives genome instability and cancer.
Senior Group Leader, Cancer Research UK, London Research Institute, Clare Hall Laboratories, South Mimms, UK.
Abstract
Our research is focused on the mechanisms that sense and repair DNA damage in cells, with an emphasis on DNA double-strand break (DSB) sensing and repair. DSBs represent a major threat to genome integrity and are predominantly repaired by homologous recombination (HR). Unscheduled or excessive HR can also lead to gross chromosomal rearrangements characteristic of cancer cells, but the mechanisms that restrain HR remain poorly understood. The yeast Srs2 helicase suppress aberrant recombination by disrupting a specific step in HR, however functional homologues are not obviously conserved in higher eukaryotes. We therefore performed a genetic screen in C. elegans to identify putative anti-recombinases functionally analogous to yeast Srs2. This screen identified a novel helicase, RTEL-1 that is conserved from C. elegans to humans. We find that rtel-1 mutant worms and RTEL1 depleted human cells share characteristic phenotypes with yeast srs2 mutants: lethality upon deletion of the sgs1/BLM homologue, hyper-recombination, and DNA damage sensitivity. Biochemical analysis of RTEL1 has revealed that it antagonises HR by promoting the disassembly of D loop recombination intermediates. Since Rtel knockout mice die due to dramatic genome instability and rapid telomere loss and Human RTEL1 is over-expressed in gastric tumours, we propose that loss of HR control following deregulation of RTEL1 may be a critical event that drives genome instability and cancer.
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