SNV/indel hypermutator phenotype in biallelic RAD51C variant - Fanconi anemia

We previously reported a fetus with Fanconi anemia (FA), complementation group O due to compound heterozygous variants involving RAD51C. Interestingly, the trio exome sequencing analysis also detected eight apparent de novo mosaic variants with variant allele fraction (VAF) ranging between 11.5%−37%. Here, using whole genome sequencing and a ‘home-brew’ variant filtering pipeline and DeepMosaic module, we investigated the number and signature of de novo heterozygous and mosaic variants and the rare phenomenon of hypermutation. Eight-hundred-thirty apparent dnSNVs and 21 de novo indels had VAFs below 37.41% and were considered postzygotic somatic mosaic variants. The VAFs showed a bimodal distribution, with one component with an average VAF of 25% (range: 18.7–37.41%) (n=446), representing potential postzygotic first mitotic events, and the other component with an average VAF of 12.5% (range: 9.55–18.69%) (n=384), describing potential second mitotic events. No increased rate of CNV formation was observed. The mutational pattern analysis for somatic single base substitution showed SBS40, SBS5, and SBS3 as the top recognized signatures. SBS3 is a known signature associated with homologous recombination-based DNA damage repair error. Our data demonstrate that biallelic RAD51C variants show evidence for defective genomic DNA damage repair and thereby result in a hypermutator phenotype with the accumulation of postzygotic de novo mutations, at least in the prenatal period. This ‘genome hypermutator phenomenon’ might contribute to the observed hematological manifestations and the predisposition to tumors in patients with FA, and pregnancy loss in general. We propose that other FA groups should be investigated for genome-wide de novo variants.

[1]  Ryan E. Mills,et al.  Control-independent mosaic single nucleotide variant detection with DeepMosaic , 2023, Nature Biotechnology.

[2]  Thomas E Heineman,et al.  Genomic signature of Fanconi anaemia DNA repair pathway deficiency in cancer. , 2022, Nature.

[3]  J. Lupski,et al.  The multiple de novo copy number variant (MdnCNV) phenomenon presents with peri-zygotic DNA mutational signatures and multilocus pathogenic variation , 2022, Genome Medicine.

[4]  Patrick J. Short,et al.  Genetic and chemotherapeutic influences on germline hypermutation , 2022, Nature.

[5]  S. Taraviras,et al.  Fanconi anemia proteins and genome fragility: unraveling replication defects for cancer therapy. , 2022, Trends in cancer.

[6]  W. Foulkes,et al.  A decade of RAD51C and RAD51D germline variants in cancer , 2021, Human mutation.

[7]  E. Cuppen,et al.  MutationalPatterns: the one stop shop for the analysis of mutational processes , 2021, BMC Genomics.

[8]  M. Stratton,et al.  Extensive phylogenies of human development inferred from somatic mutations , 2021, Nature.

[9]  F. Suárez-Obando,et al.  An update on Fanconi anemia: Clinical, cytogenetic and molecular approaches (Review) , 2021, Biomedical reports.

[10]  M. Herbert,et al.  Parental genome unification is highly error-prone in mammalian embryos , 2021, Cell.

[11]  C. Walsh,et al.  MIPP-Seq: ultra-sensitive rapid detection and validation of low-frequency mosaic mutations , 2021, BMC medical genomics.

[12]  Thomas M. Keane,et al.  Twelve years of SAMtools and BCFtools , 2020, GigaScience.

[13]  M. Stratton,et al.  The mutational landscape of human somatic and germline cells , 2020, Nature.

[14]  D. Hong,et al.  Clonal dynamics in early human embryogenesis inferred from somatic mutation , 2020, Nature.

[15]  A. Mastronuzzi,et al.  Canonical and Noncanonical Roles of Fanconi Anemia Proteins: Implications in Cancer Predisposition , 2020, Cancers.

[16]  M. Lopes,et al.  Sequential role of RAD51 paralog complexes in replication fork remodeling and restart , 2020, Nature Communications.

[17]  Justyna A. Karolak,et al.  Low-level parental somatic mosaic SNVs in exomes from a large cohort of trios with diverse suspected Mendelian conditions , 2020, Genetics in Medicine.

[18]  Wayne M Crismani,et al.  Emerging functions of Fanconi Anemia genes in replication fork protection pathways. , 2020, Human molecular genetics.

[19]  C. Hermans,et al.  Genetic mosaicism in haemophilia: A practical review to help evaluate the risk of transmitting the disease , 2020, Haemophilia : the official journal of the World Federation of Hemophilia.

[20]  Hyungjin Kim,et al.  Fanconi Anemia and the Underlying Causes of Genomic Instability. , 2020, Environmental and molecular mutagenesis.

[21]  J. Lupski,et al.  Distinct patterns of complex rearrangements and a mutational signature of microhomeology are frequently observed in PLP1 copy number gain structural variants , 2019, Genome Medicine.

[22]  P. Stankiewicz,et al.  A clinical survey of mosaic single nucleotide variants in disease-causing genes detected by exome sequencing , 2019, Genome Medicine.

[23]  C. Shaw,et al.  Megabase Length Hypermutation Accompanies Human Structural Variation at 17p11.2 , 2019, Cell.

[24]  Ville Mustonen,et al.  The repertoire of mutational signatures in human cancer , 2018, Nature.

[25]  Melissa M. Harrison,et al.  Mechanisms regulating zygotic genome activation , 2018, Nature Reviews Genetics.

[26]  R. Gibbs,et al.  Clinical exome sequencing for fetuses with ultrasound abnormalities and a suspected Mendelian disorder , 2018, Genome Medicine.

[27]  D. Phillips Mutational spectra and mutational signatures: Insights into cancer aetiology and mechanisms of DNA damage and repair , 2018, DNA repair.

[28]  G. Nalepa,et al.  Fanconi anaemia and cancer: an intricate relationship , 2018, Nature Reviews Cancer.

[29]  P. Liu,et al.  Expanding the FANCO/RAD51C associated phenotype: Cleft lip and palate and lobar holoprosencephaly, two rare findings in Fanconi anemia. , 2017, European journal of medical genetics.

[30]  Brent S. Pedersen,et al.  Mosdepth: quick coverage calculation for genomes and exomes , 2017, bioRxiv.

[31]  F. Supek,et al.  Clustered Mutation Signatures Reveal that Error-Prone DNA Repair Targets Mutations to Active Genes , 2017, Cell.

[32]  A. Shimamura,et al.  Recent discoveries in the molecular pathogenesis of the inherited bone marrow failure syndrome Fanconi anemia. , 2017, Blood reviews.

[33]  M. Hurles,et al.  Somatic mutations reveal asymmetric cellular dynamics in the early human embryo , 2017, Nature.

[34]  Klaudia Walter,et al.  An Organismal CNV Mutator Phenotype Restricted to Early Human Development , 2017, Cell.

[35]  Alexander Hoischen,et al.  New insights into the generation and role of de novo mutations in health and disease , 2016, Genome Biology.

[36]  J. Roach,et al.  Parent-of-origin-specific signatures of de novo mutations , 2016, Nature Genetics.

[37]  A. D’Andrea,et al.  The Fanconi anaemia pathway: new players and new functions , 2016, Nature Reviews Molecular Cell Biology.

[38]  D. Kutler,et al.  Natural history and management of Fanconi anemia patients with head and neck cancer: A 10‐year follow‐up , 2016, The Laryngoscope.

[39]  M. Miyajima,et al.  Ultra–sensitive droplet digital PCR for detecting a low–prevalence somatic GNAQ mutation in Sturge–Weber syndrome , 2016, Scientific Reports.

[40]  J. Lupski,et al.  Mechanisms underlying structural variant formation in genomic disorders , 2016, Nature Reviews Genetics.

[41]  Arthur Wuster,et al.  Timing, rates and spectra of human germline mutation , 2015, Nature Genetics.

[42]  L. Hood,et al.  A novel Fanconi anaemia subtype associated with a dominant-negative mutation in RAD51 , 2015, Nature Communications.

[43]  J. Walter,et al.  What is the DNA repair defect underlying Fanconi anemia? , 2015, Current opinion in cell biology.

[44]  M. Akbari,et al.  Genetic testing for RAD51C mutations: in the clinic and community , 2015, Clinical genetics.

[45]  Kumar Somyajit,et al.  Mammalian RAD51 paralogs protect nascent DNA at stalled forks and mediate replication restart , 2015, Nucleic acids research.

[46]  S. Gabriel,et al.  A Dominant Mutation in Human RAD51 Reveals Its Function in DNA Interstrand Crosslink Repair Independent of Homologous Recombination. , 2015, Molecular cell.

[47]  L. Vissers,et al.  Post-zygotic Point Mutations Are an Underrecognized Source of De Novo Genomic Variation. , 2015, American journal of human genetics.

[48]  Magalie S Leduc,et al.  Clinical whole-exome sequencing for the diagnosis of mendelian disorders. , 2013, The New England journal of medicine.

[49]  Evan E Eichler,et al.  Properties and rates of germline mutations in humans. , 2013, Trends in genetics : TIG.

[50]  J. Lupski,et al.  Replicative mechanisms for CNV formation are error prone , 2013, Nature Genetics.

[51]  L. Aaltonen,et al.  Diagnostic Cancer Genome Sequencing and the Contribution of Germline Variants , 2013, Science.

[52]  M. Stratton,et al.  Deciphering Signatures of Mutational Processes Operative in Human Cancer , 2013, Cell reports.

[53]  Molly C. Kottemann,et al.  Fanconi anaemia and the repair of Watson and Crick DNA crosslinks , 2013, Nature.

[54]  Helga Thorvaldsdóttir,et al.  Integrative Genomics Viewer (IGV): high-performance genomics data visualization and exploration , 2012, Briefings Bioinform..

[55]  S. Powell,et al.  Rad51 Paralog Complexes BCDX2 and CX3 Act at Different Stages in the BRCA1-BRCA2-Dependent Homologous Recombination Pathway , 2012, Molecular and Cellular Biology.

[56]  A. D’Andrea,et al.  Molecular pathogenesis and clinical management of Fanconi anemia. , 2012, The Journal of clinical investigation.

[57]  S. Steinberg,et al.  Rate of de novo mutations and the importance of father’s age to disease risk , 2012, Nature.

[58]  Efrat Oron,et al.  Cell fate regulation in early mammalian development , 2012, Physical biology.

[59]  J. Veltman,et al.  De novo mutations in human genetic disease , 2012, Nature Reviews Genetics.

[60]  A. Børresen-Dale,et al.  Mutational Processes Molding the Genomes of 21 Breast Cancers , 2012, Cell.

[61]  Kumar Somyajit,et al.  Distinct Roles of FANCO/RAD51C Protein in DNA Damage Signaling and Repair , 2011, The Journal of Biological Chemistry.

[62]  Kay-Hooi Khoo,et al.  Human Sperm Binding Is Mediated by the Sialyl-Lewisx Oligosaccharide on the Zona Pellucida , 2011, Science.

[63]  Helga Thorvaldsdóttir,et al.  Integrative Genomics Viewer , 2011, Nature Biotechnology.

[64]  A. D’Andrea,et al.  Susceptibility pathways in Fanconi's anemia and breast cancer. , 2010, The New England journal of medicine.

[65]  Franca Fraternali,et al.  Mutation of the RAD51C gene in a Fanconi anemia–like disorder , 2010, Nature Genetics.

[66]  P. Shannon,et al.  Analysis of Genetic Inheritance in a Family Quartet by Whole-Genome Sequencing , 2010, Science.

[67]  A. D’Andrea,et al.  How the fanconi anemia pathway guards the genome. , 2009, Annual review of genetics.

[68]  A. Auerbach,et al.  Fanconi anemia and its diagnosis. , 2009, Mutation research.

[69]  Geert Verbeke,et al.  Chromosome instability is common in human cleavage-stage embryos , 2009, Nature Medicine.

[70]  D. Haines,et al.  Loss of Rad51c leads to embryonic lethality and modulation of Trp53-dependent tumorigenesis in mice. , 2009, Cancer research.

[71]  N. Carter,et al.  Germline rates of de novo meiotic deletions and duplications causing several genomic disorders , 2008, Nature Genetics.

[72]  J. Lupski,et al.  A DNA Replication Mechanism for Generating Nonrecurrent Rearrangements Associated with Genomic Disorders , 2007, Cell.

[73]  J. Lupski,et al.  Genomic rearrangements and sporadic disease , 2007, Nature Genetics.

[74]  S. West,et al.  RAD51C deficiency in mice results in early prophase I arrest in males and sister chromatid separation at metaphase II in females , 2007, The Journal of cell biology.

[75]  Marianne Berwick,et al.  A 20-year perspective on the International Fanconi Anemia Registry (IFAR). , 2003, Blood.

[76]  L. Loeb,et al.  A mutator phenotype in cancer. , 2001, Cancer research.

[77]  K. Kinzler,et al.  A Naturally Occurring hPMS2 Mutation Can Confer a Dominant Negative Mutator Phenotype , 1998, Molecular and Cellular Biology.

[78]  T. Miyake Mutator Factor in Salmonella Typhimurium. , 1960, Genetics.

[79]  H. H. Plough SPONTANEOUS MUTABILITY IN DROSOPHILA , 1941 .