Molecular mechanism and clinical impact of APOBEC3B-catalyzed mutagenesis in breast cancer

Cancer genomic DNA sequences enable identification of all mutations and suggest targets for precision medicine. The identities and patterns of the mutations themselves also provide critical information for deducing the originating DNA damaging agents, causal molecular mechanisms, and thus additional therapeutic targets. A classic example is ultraviolet light, which crosslinks adjacent pyrimidines and leads to C-to-T transitions. A new example is the DNA cytosine deaminase APOBEC3B, which was identified recently as a source of DNA damage and mutagenesis in breast, head/neck, cervix, bladder, lung, ovary, and to lesser extents additional cancer types. This enzyme is normally an effector protein in the innate immune response to virus infection but upregulation in these cancer types causes elevated levels of genomic C-to-U deamination events, which manifest as C-to-T transitions and C-to-G transversions within distinct DNA trinucleotide contexts (preferentially 5’-TCA and 5’-TCG). Genomic C-to-U deamination events within the same trinucleotide contexts also lead to cytosine mutation clusters (kataegis), and may precipitate visible chromosomal aberrations such as translocations. Clinical studies indicate that APOBEC3B upregulation correlates with poorer outcomes for estrogen receptor-positive breast cancer patients, including shorter durations of disease-free survival and overall survival after surgery. APOBEC3B may therefore have both diagnostic and prognostic potential. APOBEC3B may also be a candidate for therapeutic targeting because inhibition of this non-essential enzyme is predicted to decrease tumor mutation rates and diminish the likelihood of undesirable mutation-dependent outcomes such as recurrence, metastasis, and the development of therapy resistant tumors.

[1]  Keith C. Norris,et al.  DNA cytosine methylation and heat-induced deamination , 1986, Bioscience reports.

[2]  J. Taylor,et al.  Apolipoprotein B mRNA-editing protein induces hepatocellular carcinoma and dysplasia in transgenic animals. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[3]  M. Diaz,et al.  Enzymatic cytosine deamination: friend and foe. , 2002, Molecular cell.

[4]  M. Neuberger,et al.  AID mutates E. coli suggesting a DNA deamination mechanism for antibody diversification , 2002, Nature.

[5]  Reuben S Harris,et al.  RNA editing enzyme APOBEC1 and some of its homologs can act as DNA mutators. , 2002, Molecular cell.

[6]  J. Cleaver,et al.  UV damage, DNA repair and skin carcinogenesis. , 2002, Frontiers in bioscience : a journal and virtual library.

[7]  Nicholas O. Davidson,et al.  C-to-U RNA Editing: Mechanisms Leading to Genetic Diversity* , 2003, The Journal of Biological Chemistry.

[8]  M. Neuberger,et al.  In Vitro Deamination of Cytosine to Uracil in Single-stranded DNA by Apolipoprotein B Editing Complex Catalytic Subunit 1 (APOBEC1)* , 2003, Journal of Biological Chemistry.

[9]  Reuben S Harris,et al.  Comparison of the differential context-dependence of DNA deamination by APOBEC enzymes: correlation with mutation spectra in vivo. , 2004, Journal of molecular biology.

[10]  D. Nissley,et al.  APOBEC3G hypermutates genomic DNA and inhibits Ty1 retrotransposition in yeast. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[11]  Andrew D. Yates,et al.  A screen of the complete protein kinase gene family identifies diverse patterns of somatic mutations in human breast cancer , 2005, Nature Genetics.

[12]  G. Parmigiani,et al.  The Consensus Coding Sequences of Human Breast and Colorectal Cancers , 2006, Science.

[13]  A. Sparks,et al.  The Genomic Landscapes of Human Breast and Colorectal Cancers , 2007, Science.

[14]  M. Neuberger,et al.  Molecular mechanisms of antibody somatic hypermutation. , 2007, Annual review of biochemistry.

[15]  E. Eichler,et al.  Population Stratification of a Common APOBEC Gene Deletion Polymorphism , 2007, PLoS genetics.

[16]  P. Peltomäki,et al.  Lynch syndrome and related familial colorectal cancers. , 2008, Critical reviews in oncogenesis.

[17]  Y. Miki,et al.  Identification of novel deletion polymorphisms in breast cancer. , 2008, International journal of oncology.

[18]  L. Prakash,et al.  Highly error-free role of DNA polymerase η in the replicative bypass of UV-induced pyrimidine dimers in mouse and human cells , 2009, Proceedings of the National Academy of Sciences.

[19]  J. Stivers,et al.  Detection of damaged DNA bases by DNA glycosylase enzymes. , 2010, Biochemistry.

[20]  M. Stenglein,et al.  APOBEC3 proteins mediate the clearance of foreign DNA from human cells , 2010, Nature Structural &Molecular Biology.

[21]  A. Lehmann DNA polymerases and repair synthesis in NER in human cells. , 2011, DNA repair.

[22]  M. Weitzman,et al.  APOBEC3A can activate the DNA damage response and cause cell‐cycle arrest , 2011, EMBO reports.

[23]  D. Hanahan,et al.  Hallmarks of Cancer: The Next Generation , 2011, Cell.

[24]  P. Pineau,et al.  Somatic hypermutation of human mitochondrial and nuclear DNA by APOBEC3 cytidine deaminases, a pathway for DNA catabolism , 2011, Proceedings of the National Academy of Sciences.

[25]  Michael M. Mwangi,et al.  Transcriptome-wide sequencing reveals numerous APOBEC1 mRNA editing targets in transcript 3′ UTRs , 2010, Nature Structural &Molecular Biology.

[26]  A. Børresen-Dale,et al.  The landscape of cancer genes and mutational processes in breast cancer , 2012, Nature.

[27]  A. Børresen-Dale,et al.  The Life History of 21 Breast Cancers , 2012, Cell.

[28]  Steven A. Roberts,et al.  Clustered mutations in yeast and in human cancers can arise from damaged long single-strand DNA regions. , 2012, Molecular cell.

[29]  N. Makridakis,et al.  Translesion DNA Polymerases and Cancer , 2012, Front. Gene..

[30]  D. Largaespada,et al.  Extensive somatic L1 retrotransposition in colorectal tumors , 2012, Genome research.

[31]  M. Malim,et al.  HIV Restriction Factors and Mechanisms of Evasion. , 2012, Cold Spring Harbor perspectives in medicine.

[32]  P. Vidalain,et al.  Human Tribbles 3 Protects Nuclear DNA from Cytidine Deamination by APOBEC3A* , 2012, The Journal of Biological Chemistry.

[33]  N. Krogan,et al.  First-in-class small molecule inhibitors of the single-strand DNA cytosine deaminase APOBEC3G. , 2012, ACS chemical biology.

[34]  C. Schiffer,et al.  Methylcytosine and Normal Cytosine Deamination by the Foreign DNA Restriction Enzyme APOBEC3A* , 2012, The Journal of Biological Chemistry.

[35]  J. Reis-Filho,et al.  Breast cancer intratumor genetic heterogeneity: causes and implications , 2012, Expert review of anticancer therapy.

[36]  D. Gordenin,et al.  Base Damage within Single-Strand DNA Underlies In Vivo Hypermutability Induced by a Ubiquitous Environmental Agent , 2012, PLoS genetics.

[37]  Steven J. M. Jones,et al.  Comprehensive molecular portraits of human breast tumors , 2012, Nature.

[38]  Stephen S Hecht,et al.  Lung carcinogenesis by tobacco smoke , 2012, International journal of cancer.

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

[40]  Steven A. Roberts,et al.  An APOBEC cytidine deaminase mutagenesis pattern is widespread in human cancers , 2013, Nature Genetics.

[41]  Ming Li,et al.  Small‐Molecule APOBEC3G DNA Cytosine Deaminase Inhibitors Based on a 4‐Amino‐1,2,4‐triazole‐3‐thiol Scaffold , 2013, ChemMedChem.

[42]  David T. W. Jones,et al.  Signatures of mutational processes in human cancer , 2013, Nature.

[43]  Terumasa Ikeda,et al.  Intrinsic immunity against retrotransposons by APOBEC cytidine deaminases , 2013, Front. Microbio..

[44]  K. Kinzler,et al.  Cancer Genome Landscapes , 2013, Science.

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

[46]  S. Wain-Hobson,et al.  Human APOBEC3A Isoforms Translocate to the Nucleus and Induce DNA Double Strand Breaks Leading to Cell Stress and Death , 2013, PloS one.

[47]  Reuben S Harris,et al.  The APOBEC3 family of retroelement restriction factors. , 2013, Current topics in microbiology and immunology.

[48]  Steven J. M. Jones,et al.  Comprehensive molecular portraits of human breast tumours , 2013 .

[49]  Jason B. Nikas,et al.  APOBEC3B upregulation and genomic mutation patterns in serous ovarian carcinoma. , 2013, Cancer research.

[50]  M. Nussenzweig,et al.  Chromosome translocation, B cell lymphoma, and activation-induced cytidine deaminase. , 2013, Annual review of pathology.

[51]  Steven A. Roberts,et al.  Mutational heterogeneity in cancer and the search for new cancer-associated genes , 2013 .

[52]  J. A. Halliday,et al.  Engineered proteins detect spontaneous DNA breakage in human and bacterial cells , 2013, eLife.

[53]  N. A. Temiz,et al.  Evidence for APOBEC3B mutagenesis in multiple human cancers , 2013, Nature Genetics.

[54]  N. A. Temiz,et al.  APOBEC3B is an enzymatic source of mutation in breast cancer , 2013, Nature.

[55]  Lela Lackey,et al.  Endogenous APOBEC3A DNA Cytosine Deaminase Is Cytoplasmic and Nongenotoxic* , 2013, The Journal of Biological Chemistry.

[56]  M. Stratton,et al.  DNA deaminases induce break-associated mutation showers with implication of APOBEC3B and 3A in breast cancer kataegis , 2013, eLife.

[57]  Wei Zheng,et al.  APOBEC3 deletion polymorphism is associated with breast cancer risk among women of European ancestry. , 2013, Carcinogenesis.

[58]  D. Gordenin,et al.  The choice of nucleotide inserted opposite abasic sites formed within chromosomal DNA reveals the polymerase activities participating in translesion DNA synthesis. , 2013, DNA repair.

[59]  Wei Lu,et al.  A common deletion in the APOBEC3 genes and breast cancer risk. , 2013, Journal of the National Cancer Institute.

[60]  S. Gabriel,et al.  Somatic rearrangements across cancer reveal classes of samples with distinct patterns of DNA breakage and rearrangement-induced hypermutability , 2012, Genome research.

[61]  Kenneth Offit,et al.  Two Decades After BRCA: Setting Paradigms in Personalized Cancer Care and Prevention , 2014, Science.

[62]  Adam P Butler,et al.  Association of a germline copy number polymorphism of APOBEC3A and APOBEC3B with burden of putative APOBEC-dependent mutations in breast cancer , 2014, Nature Genetics.

[63]  S. Mori,et al.  In Vivo and In Vitro Studies Suggest a Possible Involvement of HPV Infection in the Early Stage of Breast Carcinogenesis via APOBEC3B Induction , 2014, PloS one.

[64]  Steven J. M. Jones,et al.  Comprehensive molecular characterization of urothelial bladder carcinoma , 2014, Nature.

[65]  David N. Cooper,et al.  Mechanisms of Base Substitution Mutagenesis in Cancer Genomes , 2014, Genes.

[66]  The Cancer Genome Atlas Research Network,et al.  Comprehensive molecular characterization of urothelial bladder carcinoma , 2014, Nature.

[67]  Peilin Jia,et al.  Patterns and processes of somatic mutations in nine major cancers , 2014, BMC Medical Genomics.

[68]  Andreas Schlicker,et al.  Elevated APOBEC3B Correlates with Poor Outcomes for Estrogen-Receptor-Positive Breast Cancers , 2014, Hormones and Cancer.

[69]  S. Henderson,et al.  APOBEC-mediated cytosine deamination links PIK3CA helical domain mutations to human papillomavirus-driven tumor development. , 2014, Cell reports.

[70]  A. Venkitaraman Cancer Suppression by the Chromosome Custodians, BRCA1 and BRCA2 , 2014, Science.

[71]  V. C. Vieira,et al.  Human Papillomavirus E6 Triggers Upregulation of the Antiviral and Cancer Genomic DNA Deaminase APOBEC3B , 2014, mBio.

[72]  A. Furano,et al.  Repair of naturally occurring mismatches can induce mutations in flanking DNA , 2014, eLife.

[73]  C. Sala,et al.  The RNA editing enzyme APOBEC1 induces somatic mutations and a compatible mutational signature is present in esophageal adenocarcinomas , 2014, Genome Biology.

[74]  Simon Wain-Hobson,et al.  A prevalent cancer susceptibility APOBEC3A hybrid allele bearing APOBEC3B 3′UTR enhances chromosomal DNA damage , 2014, Nature Communications.