Spectrum and significance of variants and mutations in the Fanconi anaemia group G gene in children with sporadic acute myeloid leukaemia
Stefan Meyer
Department of Paediatric Haematology and Oncology, Central Manchester and Manchester Children's University Hospital and Christie Hospital NHS Trusts, Manchester, UK
Search for more papers by this authorLisa M. Barber
Cancer-Immunogenetics Laboratory, University of Manchester, Manchester, UK
Search for more papers by this authorDaniel J. White
Cancer-Immunogenetics Laboratory, University of Manchester, Manchester, UK
Search for more papers by this authorAndrew M. Will
Department of Paediatric Haematology and Oncology, Central Manchester and Manchester Children's University Hospital and Christie Hospital NHS Trusts, Manchester, UK
Search for more papers by this authorJillian M. Birch
CRUK Paediatric and Familial Cancer Research Group, University of Manchester, Manchester, UK
Search for more papers by this authorJanice A. Kohler
Department of Child Health, Paediatric Haematology and Oncology, University of Southampton, Southampton, UK
Search for more papers by this authorKlaus Ersfeld
Department of Biology, University of Hull, Hull, UK
Search for more papers by this authorEric Blom
Department of Clinical Genetics and Human Genetics, Free University of Amsterdam, Amsterdam, the Netherlands
Search for more papers by this authorHans Joenje
Department of Clinical Genetics and Human Genetics, Free University of Amsterdam, Amsterdam, the Netherlands
Search for more papers by this authorTim O. B. Eden
Department of Paediatric Haematology and Oncology, Central Manchester and Manchester Children's University Hospital and Christie Hospital NHS Trusts, Manchester, UK
Search for more papers by this authorG. Malcolm Taylor
Cancer-Immunogenetics Laboratory, University of Manchester, Manchester, UK
Search for more papers by this authorStefan Meyer
Department of Paediatric Haematology and Oncology, Central Manchester and Manchester Children's University Hospital and Christie Hospital NHS Trusts, Manchester, UK
Search for more papers by this authorLisa M. Barber
Cancer-Immunogenetics Laboratory, University of Manchester, Manchester, UK
Search for more papers by this authorDaniel J. White
Cancer-Immunogenetics Laboratory, University of Manchester, Manchester, UK
Search for more papers by this authorAndrew M. Will
Department of Paediatric Haematology and Oncology, Central Manchester and Manchester Children's University Hospital and Christie Hospital NHS Trusts, Manchester, UK
Search for more papers by this authorJillian M. Birch
CRUK Paediatric and Familial Cancer Research Group, University of Manchester, Manchester, UK
Search for more papers by this authorJanice A. Kohler
Department of Child Health, Paediatric Haematology and Oncology, University of Southampton, Southampton, UK
Search for more papers by this authorKlaus Ersfeld
Department of Biology, University of Hull, Hull, UK
Search for more papers by this authorEric Blom
Department of Clinical Genetics and Human Genetics, Free University of Amsterdam, Amsterdam, the Netherlands
Search for more papers by this authorHans Joenje
Department of Clinical Genetics and Human Genetics, Free University of Amsterdam, Amsterdam, the Netherlands
Search for more papers by this authorTim O. B. Eden
Department of Paediatric Haematology and Oncology, Central Manchester and Manchester Children's University Hospital and Christie Hospital NHS Trusts, Manchester, UK
Search for more papers by this authorG. Malcolm Taylor
Cancer-Immunogenetics Laboratory, University of Manchester, Manchester, UK
Search for more papers by this authorSummary
Childhood acute myeloid leukaemia (AML) is uncommon. Children with Fanconi anaemia (FA), however, have a very high risk of developing AML. FA is a rare inherited disease caused by mutations in at least 12 genes, of which Fanconi anaemia group G gene (FANCG) is one of the commonest. To address to what extent FANCG variants contribute to sporadic childhood AML, we determined the spectrum of FANCG sequence variants in 107 children diagnosed with sporadic AML, using polymerase chain reaction (PCR), fluorescent single-strand conformational polymorphism (SSCP) and sequencing methodologies. The significance of variants was determined by frequency analysis and assessment of evolutionary conservation. Seven children (6·5%) carried variants in FANCG. Two of these carried two variants, including the known IVS2 + 1G>A mutation with the novel missense mutation S588F, and R513Q with the intronic deletion IVS12-38 (-28)_del11, implying that these patients might have been undiagnosed FA patients. R513Q, which affects a semi-conserved amino acid, was carried in two additional children with AML. Although not significant, the frequency of R513Q was higher in children with AML than unselected cord bloods. While FANCG mutation carrier status does not predispose to sporadic AML, the identification of unrecognised FA patients implies that FA presenting with primary AML in childhood is more common than suspected.
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