A hot L1 retrotransposon evades somatic repression and initiates human colorectal cancer

Scott, Emma C.; Gardner, Eugene J.; Masood, Ashiq; Chuang, Nelson T.; Vertino, Paula M.; Devine, Scott E.

doi:10.1101/gr.201814.115

Cited by 236 publications

(301 citation statements)

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“…Exonic L1 insertions are highly detrimental to gene function (Kazazian et al 1988;Miki et al 1992;Scott et al 2016), and intronic insertions can compromise transcript integrity by introducing cryptic splice sites and polyadenylation signals and can interfere with RNA polymerase processivity, particularly when oriented in sense relative to the interrupted gene (Perepelitsa- Belancio and Deininger 2003;Han et al 2004;Belancio et al 2008). Furthermore, L1 insertions are occasionally associated with deletions and rearrangements to target site DNA, including extreme examples such as chromosomal translocations (Gilbert et al 2002(Gilbert et al , 2005.…”

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“…In 1992, Miki et al identified an exonic L1 insertion into the APC gene that very likely led to tumor initiation in a case of colorectal cancer, providing the first direct evidence for L1 involvement in oncogenesis (Miki et al 1992). Since then, spurred by the advent of high-throughput sequencing approaches for identifying endogenous somatic L1 insertions, L1 mobilization events have been uncovered in a plethora of tumor types, including lung, ovarian, breast, colorectal, prostate, liver, pancreatic, gastric, endometrial, and esophageal cancers (Iskow et al 2010;Lee et al 2012;Solyom et al 2012;Shukla et al 2013;Helman et al 2014;Tubio et al 2014;Doucet-O'Hare et al 2015, 2016Ewing et al 2015;Paterson et al 2015;Rodic et al 2015;Scott et al 2016). Although these studies have elucidated driver L1 mutations exonic to APC and PTEN, most of the cataloged tumor-specific L1 insertions represent likely passenger events (Helman et al 2014;Scott et al 2016).…”

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confidence: 99%

“…Since then, spurred by the advent of high-throughput sequencing approaches for identifying endogenous somatic L1 insertions, L1 mobilization events have been uncovered in a plethora of tumor types, including lung, ovarian, breast, colorectal, prostate, liver, pancreatic, gastric, endometrial, and esophageal cancers (Iskow et al 2010;Lee et al 2012;Solyom et al 2012;Shukla et al 2013;Helman et al 2014;Tubio et al 2014;Doucet-O'Hare et al 2015, 2016Ewing et al 2015;Paterson et al 2015;Rodic et al 2015;Scott et al 2016). Although these studies have elucidated driver L1 mutations exonic to APC and PTEN, most of the cataloged tumor-specific L1 insertions represent likely passenger events (Helman et al 2014;Scott et al 2016). Evidence for L1 mobilization in cancers is largely restricted to tumors of epithelial origin, with somatic L1 insertions conspicuously infrequent in brain and blood cancers (Iskow et al 2010;Lee et al 2012;Achanta et al 2016;Carreira et al 2016).…”

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L1 retrotransposition is a common feature of mammalian hepatocarcinogenesis

et al. 2018

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The retrotransposon Long Interspersed Element 1 (LINE-1 or L1) is a continuing source of germline and somatic mutagenesis in mammals. Deregulated L1 activity is a hallmark of cancer, and L1 mutagenesis has been described in numerous human malignancies. We previously employed retrotransposon capture sequencing (RC-seq) to analyze hepatocellular carcinoma (HCC) samples from patients infected with hepatitis B or hepatitis C virus and identified L1 variants responsible for activating oncogenic pathways. Here, we have applied RC-seq and whole-genome sequencing (WGS) to an Abcb4 (Mdr2)−/− mouse model of hepatic carcinogenesis and demonstrated for the first time that L1 mobilization occurs in murine tumors. In 12 HCC nodules obtained from 10 animals, we validated four somatic L1 insertions by PCR and capillary sequencing, including T F subfamily elements, and one G F subfamily example. One of the T F insertions carried a 3 ′ transduction, allowing us to identify its donor L1 and to demonstrate that this full-length T F element retained retrotransposition capacity in cultured cancer cells. Using RC-seq, we also identified eight tumor-specific L1 insertions from 25 HCC patients with a history of alcohol abuse. Finally, we used RC-seq and WGS to identify three tumor-specific L1 insertions among 10 intra-hepatic cholangiocarcinoma (ICC) patients, including one insertion traced to a donor L1 on Chromosome 22 known to be highly active in other cancers. This study reveals L1 mobilization as a common feature of hepatocarcinogenesis in mammals, demonstrating that the phenomenon is not restricted to human viral HCC etiologies and is encountered in murine liver tumors.

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L1 retrotransposition is a common feature of mammalian hepatocarcinogenesis

et al. 2018

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“…In somatic tissues, both elevated L1 expression and retrotransposition have been strongly associated with many types of human cancers (6,7). In a few cases, specific retrotransposition events (i.e., insertions) have been determined to drive tumorigenesis (8,9). In the germline, retrotransposon insertions are responsible for sporadic cases of human genetic diseases, including hemophilia A (10) and neurofibromatosis 1 (11).…”

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Intact piRNA pathway prevents L1 mobilization in male meiosis

Newkirk

Lee

Grandi

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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The PIWI-interacting RNA (piRNA) pathway is essential for retrotransposon silencing. In piRNA-deficient mice, L1-overexpressing male germ cells exhibit excessive DNA damage and meiotic defects. It remains unknown whether L1 expression simply highlights piRNA deficiency or actually drives the germ-cell demise. Specifically, the sheer abundance of genomic L1 copies prevents reliable quantification of new insertions. Here, we developed a codon-optimized L1 transgene that is controlled by an endogenous mouse L1 promoter. Importantly, DNA methylation dynamics of a single-copy transgene were indistinguishable from those of endogenous L1s. Analysis of Mov10l1 −/− testes established that de novo methylation of the L1 transgene required the intact piRNA pathway. Consistent with loss of DNA methylation and programmed reduction of H3K9me2 at meiotic onset, the transgene showed 1,400-fold increase in RNA expression and consequently 70-fold increase in retrotransposition in postnatal day 14 Mov10l1 −/− germ cells compared with the wildtype. Analysis of adult Mov10l1 −/− germ-cell fractions indicated a stage-specific increase of retrotransposition in the early meiotic prophase. However, extrapolation of the transgene data to endogenous L1s suggests that it is unlikely insertional mutagenesis alone accounts for the Mov10l1 −/− phenotype. Indeed, pharmacological inhibition of reverse transcription did not rescue the meiotic defect. Cumulatively, these results establish the occurrence of productive L1 mobilization in the absence of an intact piRNA pathway but leave open the possibility of processes preceding L1 integration in triggering meiotic checkpoints and germ-cell death. Additionally, our data suggest that many heritable L1 insertions originate from individuals with partially compromised piRNA defense.LINE-1 reporter transgene | meiotic arrest | PIWI-interacting RNA | retrotransposition | spermatogenesis T he bulk of mammalian genomes are made up of transposable elements, the majority of which are retrotransposons (1). Retrotransposons are classified into long-interspersed elements (LINEs), short-interspersed elements (SINEs), and LTR retrotransposons, which collectively account for 43% and 37% of the human and mouse genomes, respectively (2). Retrotransposons amplify in the genome through an RNA intermediate, a process termed retrotransposition. LINEs are autonomous elements. An intact, full-length LINE-1 (L1) encodes two ORFs (i.e., ORF1 and ORF2); both are required for L1 mobilization (3). SINEs are nonautonomous elements and rely on L1's proteins for propagation in the genome (4). LTR retrotransposons are autonomous but appear to be inactivated in the human genome (5). Retrotransposition endangers the integrity of both somatic and germline genomes through insertional mutagenesis. In somatic tissues, both elevated L1 expression and retrotransposition have been strongly associated with many types of human cancers (6, 7). In a few cases, specific retrotransposition events (i.e., insertions) have been determined to drive t...

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“…Studies demonstrate that some cancers contain multiple somatic inserts that can be traced back to one individual "hot" element. 23,24 Another layer of complexity regarding somatic disease risk, such as cancer, derives from the evidence that TE content can also vary between different tissues due to somatic activity [25][26][27] or activity during early embryonic developmental stages. 28 Sequencing studies from a variety of cancer and matched normal tissues suggest that somatic retrotransposition occurs with varying efficiency, [29][30][31][32] which could reflect even another component contributing to more variation between individuals.…”

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confidence: 99%

Heavy metal and junk DNA

Roy-Engel

2016

Mobile Genetic Elements

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A hot L1 retrotransposon evades somatic repression and initiates human colorectal cancer

Cited by 236 publications

References 50 publications

L1 retrotransposition is a common feature of mammalian hepatocarcinogenesis

L1 retrotransposition is a common feature of mammalian hepatocarcinogenesis

Intact piRNA pathway prevents L1 mobilization in male meiosis

Heavy metal and junk DNA

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