Extensive transduction of nonrepetitive DNA mediated by L1 retrotransposition in cancer genomes

Introduction The human genome is peppered with mobile repetitive elements called long interspersed nuclear element–1 (L1) retrotransposons. Propagating through RNA and cDNA intermediates, these molecular parasites copy and insert themselves throughout the genome, with potentially disruptive effects on neighboring genes or regulatory sequences. In the germ line, unique sequence downstream of L1 elements can also be retrotransposed if transcription continues beyond the repeat, a process known as 3′ transduction. There has been growing interest in retrotransposition and 3′ transduction as a possible source of somatic mutations during tumorigenesis. The activity of individual L1 elements fluctuates during tumor evolution. In a lung tumor, hundreds of 3′ transductions arose from a small number of active L1 source elements (colored circles on outer rim of circle). As the tumor evolved from the preinvasive common ancestor to invasive cancer, individual elements exhibited variable activity over time. Rationale To explore whether 3′ transductions are frequent in cancer, we developed a bioinformatic algorithm for identifying somatically acquired retrotranspositions in cancer genomes. We applied our algorithm to 290 cancer samples from 244 patients across 12 tumor types. The unique downstream sequence mobilized with 3′ transductions effectively fingerprints the L1 source element, providing insights into the activity of individual L1 loci across the genome. Results Across the 290 samples, we identified 2756 somatic L1 retrotranspositions. Tumors from 53% of patients had at least one such event, with colorectal and lung cancers being most frequently affected (93% and 75% of patients, respectively). Somatic 3′ transductions comprised 24% of events, half of which represented mobilizations of unique sequence alone, without any accompanying L1 sequence. Overall, 95% of 3′ transductions identified derived from only 72 germline L1 source elements, with as few as four loci accounting for 50% of events. In a given sample, the same source element could generate 50 or more somatic transductions, scattered extensively across the genome. About 5% of somatic transductions arose from L1 source elements that were themselves somatic retrotranspositions. In three of the cases in which we sequenced more than one sample from a patient’s tumor, we were able to place 3′ transductions on the phylogenetic tree. We found that the activity of individual source elements fluctuated during tumor evolution, with different subclones exhibiting much variability in which elements were “on” and which were “off.” The ability to identify the individual L1 source elements active in a given tumor enabled us to study the promoter methylation of those elements specifically. We found that 3′ transduction activity in a patient’s tumor was always associated with hypomethylation of that element. Overall, 2.3% of transductions distributed exons or entire genes to other sites in the genome, and many more mobilized deoxyribonuclease I (DNAse-I) hypersensitive sites or transcription factor binding sites identified by the ENCODE project. Occasionally, somatic L1 insertions inserted near coding sequence and redistributed these exons elsewhere in the genome. However, we found no general effects of retrotranspositions on transcription levels of genes at the insertion points and no evidence for aberrant RNA species resulting from somatically acquired transposable elements. Indeed, as with germline retrotranspositions, somatic insertions exhibited a strong enrichment in heterochromatic, gene-poor regions of the genome. Conclusion Somatic 3′ transduction occurs frequently in human tumors, and in some cases transduction events can scatter exons, genes, and regulatory elements widely across the genome. Dissemination of these sequences appears to be due to a small number of highly active L1 elements, whose activity can wax and wane during tumor evolution. The majority of the retrotransposition events are likely to be harmless “passenger” mutations. Hitchhiking through the tumor genome Retrotransposons are DNA repeat sequences that are constantly on the move. By poaching certain cellular enzymes, they copy and insert themselves at new sites in the genome. Sometimes they carry along adjacent DNA sequences, a process called 3′ transduction. Tubio et al. found that 3′ transduction is a common event in human tumors. Because this process can scatter genes and regulatory sequences across the genome, it may represent yet another mechanism by which tumor cells acquire new mutations that help them survive and grow. Science, this issue p. 10.1126/science.1251343 Tumor genomes are peppered with mobile repeat sequences that carry along adjacent DNA when they insert into new genomic sites. Long interspersed nuclear element–1 (L1) retrotransposons are mobile repetitive elements that are abundant in the human genome. L1 elements propagate through RNA intermediates. In the germ line, neighboring, nonrepetitive sequences are occasionally mobilized by the L1 machinery, a process called 3′ transduction. Because 3′ transductions are potentially mutagenic, we explored the extent to which they occur somatically during tumorigenesis. Studying cancer genomes from 244 patients, we found that tumors from 53% of the patients had somatic retrotranspositions, of which 24% were 3′ transductions. Fingerprinting of donor L1s revealed that a handful of source L1 elements in a tumor can spawn from tens to hundreds of 3′ transductions, which can themselves seed further retrotranspositions. The activity of individual L1 elements fluctuated during tumor evolution and correlated with L1 promoter hypomethylation. The 3′ transductions disseminated genes, exons, and regulatory elements to new locations, most often to heterochromatic regions of the genome.

Andrew Menzies | Adam P. Butler | Jon W. Teague | Peter J. Campbell | Michael R. Stratton | P. Andrew Futreal | Keiran Raine | Carlos Caldas | Adrienne M. Flanagan | Daniel Brewer | Inigo Martincorena | Sam M. Janes | Andy G. Lynch | Rosalind Eeles | Anne Vincent-Salomon | Young Seok Ju | Serena Nik-Zainal | Christine Desmedt | Christos Sotiriou | Elizabeth Anderson | David C. Wedge | Sunil R. Lakhani | Ola Myklebost | Peter Van Loo | Tapio Visakorpi | Elli Papaemmanuil | Mark Maddison | Yilong Li | Jose M. C. Tubio | Jorge Zamora | Andrea L. Richardson | Helen R. Davies | Jórunn Erla Eyfjörd | John A. Foekens | Stian Knappskog | Sancha Martin | Manasa Ramakrishna | Paul N. Span | Lucy R. Yates | Ultan McDermott | Colin Cooper | Gunes Gundem | Moritz Gerstung | Sarah O’Meara | Stephen Gamble | Anne Y. Warren | Hayley Whitaker | William B. Isaacs | Claire Hardy | Christopher Foster | Stuart McLaren | Adam Shlien | A. Børresen-Dale | M. Stratton | M. J. van de Vijver | P. Futreal | P. Campbell | S. O'meara | C. Hardy | J. Teague | A. Menzies | C. Sotiriou | C. Desmedt | J. Foekens | R. Eeles | D. Neal | C. Cooper | O. Myklebost | T. Visakorpi | P. Tarpey | D. Wedge | S. Nik-Zainal | Sancha Martin | L. Yates | E. Papaemmanuil | A. Butler | S. McLaren | L. Mudie | K. Raine | G. Thomas | S. Lakhani | C. Caldas | S. Aparicio | A. Richardson | M. Gerstung | N. Bolli | G. Gundem | P. Van Loo | I. Martincorena | H. Davies | J. Marshall | J. Tubío | L. Alexandrov | S. Behjati | J. Eyfjörd | S. Knappskog | Manasa Ramakrishna | P. Span | A. Vincent-Salomon | U. McDermott | W. Isaacs | M. Maddison | G. G. Van den Eynden | A. Shlien | G. Bova | A. Lynch | Elizabeth Anderson | S. Cooke | Yilong Li | A. Flanagan | D. Brewer | Stephen J. Gamble | A. Warren | S. Janes | H. Whitaker | M. Tojo | C. Foster | A. Fullam | Anne-Lise Børresen-Dale | David Neal | Gilles Thomas | C. Pipinikas | Susanna L. Cooke | John Marshall | Christodoulos P. Pipinikas | Laura Mudie | Niccolo Bolli | Patrick S. Tarpey | Sam Behjati | Gert G. Van den Eynden | Marta Tojo | Marc Van de Vijver | G. Steven Bova | Laura van't Veer | Anthony Fullam | P. Román-García | Sam Aparicio | Ludmil Alexandrov | Pablo Roman-Garcia | J. Zamora | Y. Ju | L. V. van‘t Veer | L. V. van’t Veer | Stuart McLaren | Pablo Román-García | Claire W. Hardy

[1]  H. Kazazian,et al.  High-throughput sequencing reveals extensive variation in human-specific L1 content in individual human genomes. , 2010, Genome research.

[2]  J. McDonald,et al.  L1 and HERV-W retrotransposons are hypomethylated in human ovarian carcinomas , 2004, Molecular Cancer.

[3]  Deepak Grover,et al.  dbRIP: A highly integrated database of retrotransposon insertion polymorphisms in humans , 2006, Human mutation.

[4]  Steven J. M. Jones,et al.  Comprehensive molecular characterization of human colon and rectal cancer , 2012, Nature.

[5]  Richard Durbin,et al.  Sequence analysis Fast and accurate short read alignment with Burrows – Wheeler transform , 2009 .

[6]  International Human Genome Sequencing Consortium Initial sequencing and analysis of the human genome , 2001, Nature.

[7]  T. Bestor,et al.  Meiotic catastrophe and retrotransposon reactivation in male germ cells lacking Dnmt3L , 2004, Nature.

[8]  Long-Cheng Li,et al.  MethPrimer: designing primers for methylation PCRs , 2002, Bioinform..

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

[10]  Fred H. Gage,et al.  L1 retrotransposition in neurons is modulated by MeCP2 , 2010, Nature.

[11]  Daniel R. Zerbino,et al.  Pebble and Rock Band: Heuristic Resolution of Repeats and Scaffolding in the Velvet Short-Read de Novo Assembler , 2009, PloS one.

[12]  A. Sivachenko,et al.  Punctuated Evolution of Prostate Cancer Genomes , 2013, Cell.

[13]  J. V. Moran,et al.  Transduction‐Specific ATLAS Reveals a Cohort of Highly Active L1 Retrotransposons in Human Populations , 2013, Human mutation.

[14]  J. V. Moran,et al.  Many human L1 elements are capable of retrotransposition , 1997, Nature Genetics.

[15]  Joshua F. McMichael,et al.  The Origin and Evolution of Mutations in Acute Myeloid Leukemia , 2012, Cell.

[16]  Philip M. Kim,et al.  Paired-End Mapping Reveals Extensive Structural Variation in the Human Genome , 2007, Science.

[17]  Piero Carninci,et al.  Edinburgh Research Explorer Endogenous Retrotransposition Activates Oncogenic Pathways in Hepatocellular Carcinoma Endogenous Retrotransposition Activates Oncogenic Pathways in Hepatocellular Carcinoma , 2022 .

[18]  J. Mattick,et al.  Somatic retrotransposition alters the genetic landscape of the human brain , 2011, Nature.

[19]  Steven L Salzberg,et al.  Fast gapped-read alignment with Bowtie 2 , 2012, Nature Methods.

[20]  Andrew Menzies,et al.  Processed pseudogenes acquired somatically during cancer development , 2014, Nature Communications.

[21]  Data production leads,et al.  An integrated encyclopedia of DNA elements in the human genome , 2012 .

[22]  D. Landsman,et al.  Identifying related L1 retrotransposons by analyzing 3' transduced sequences , 2003, Genome Biology.

[23]  Andrew F. Neuwald,et al.  Natural Mutagenesis of Human Genomes by Endogenous Retrotransposons , 2010, Cell.

[24]  Felix Krueger,et al.  Bismark: a flexible aligner and methylation caller for Bisulfite-Seq applications , 2011, Bioinform..

[25]  ENCODEConsortium,et al.  An Integrated Encyclopedia of DNA Elements in the Human Genome , 2012, Nature.

[26]  M. Stratton,et al.  Tandem duplication of chromosomal segments is common in ovarian and breast cancer genomes , 2012, The Journal of pathology.

[27]  Peter Donnelly,et al.  Germline mutations affecting the proofreading domains of POLE and POLD1 predispose to colorectal adenomas and carcinomas , 2013, Nature Genetics.

[28]  Evan E. Eichler,et al.  LINE-1 Retrotransposition Activity in Human Genomes , 2010, Cell.

[29]  J. Feliu,et al.  Hypomethylation of long interspersed nuclear element-1 (LINE-1) leads to activation of proto-oncogenes in human colorectal cancer metastasis , 2013, Gut.

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

[31]  C. Walsh,et al.  Single-Neuron Sequencing Analysis of L1 Retrotransposition and Somatic Mutation in the Human Brain , 2012, Cell.

[32]  Li Ding,et al.  Retrotransposition of gene transcripts leads to structural variation in mammalian genomes , 2013, Genome Biology.

[33]  J. V. Moran,et al.  Exon shuffling by L1 retrotransposition. , 1999, Science.

[34]  Adrian M. Stütz,et al.  A Comprehensive Map of Mobile Element Insertion Polymorphisms in Humans , 2011, PLoS genetics.

[35]  A. Sivachenko,et al.  Sequence analysis of mutations and translocations across breast cancer subtypes , 2012, Nature.

[36]  B. Schuster-Böckler,et al.  Chromatin organization is a major influence on regional mutation rates in human cancer cells , 2012, Nature.

[37]  H. Kazazian Mobile Elements: Drivers of Genome Evolution , 2004, Science.

[38]  Lovelace J. Luquette,et al.  Landscape of Somatic Retrotransposition in Human Cancers , 2012, Science.

[39]  A. McCullough Comprehensive genomic characterization of squamous cell lung cancers , 2013 .

[40]  C. Walsh,et al.  Cytosine methylation and the ecology of intragenomic parasites. , 1997, Trends in genetics : TIG.

[41]  J. V. Moran,et al.  Hot L1s account for the bulk of retrotransposition in the human population , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[42]  S. Gabriel,et al.  Discovery and saturation analysis of cancer genes across 21 tumor types , 2014, Nature.

[43]  K. Kinzler,et al.  Disruption of the APC gene by a retrotransposal insertion of L1 sequence in a colon cancer. , 1992, Cancer research.

[44]  W. J. Kent,et al.  BLAT--the BLAST-like alignment tool. , 2002, Genome research.

[45]  Gene W. Yeo,et al.  L1 retrotransposition in human neural progenitor cells , 2009, Nature.

[46]  Lichun Yang,et al.  Trans mobilization of genomic DNA as a mechanism for retrotransposon-mediated exon shuffling. , 2003, Human molecular genetics.

[47]  Andrew Menzies,et al.  The patterns and dynamics of genomic instability in metastatic pancreatic cancer , 2010, Nature.