Transposable element exaptation is the primary source of novelty in the primate gene regulatory landscape

Trizzino, Marco; Park, YoSon; Beltrame, Márcia Holsbach; Aracena, Katherine A.; Mika, Katelyn; Çalışkan, Minal; Perry, George H.; Lynch, Vincent J.; Brown, Christopher D.

doi:10.1101/083980

Cited by 10 publications

(10 citation statements)

References 126 publications

(4 reference statements)

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“…In this paper, we demonstrate that, even though TEs play important roles in remodeling regulatory networks and enabling functional innovation (Lynch et al 2011(Lynch et al , 2015Chuong 2013;Chuong et al 2016a;Trizzino et al 2016), they are depleted for regulatory activity compared with their prevalence across the human and mouse genomes. This should not be…”

Section: Discussionmentioning

confidence: 87%

Transposable Element Exaptation into Regulatory Regions Is Rare, Influenced by Evolutionary Age, and Subject to Pleiotropic Constraints

Simonti

Pavličev

Capra

2017

Molecular Biology and Evolution

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Transposable element (TE)-derived sequences make up approximately half of most mammalian genomes, and many TEs have been co-opted into gene regulatory elements. However, we lack a comprehensive tissue- and genome-wide understanding of how and when TEs gain regulatory activity in their hosts. We evaluated the prevalence of TE-derived DNA in enhancers and promoters across hundreds of human and mouse cell lines and primary tissues. Promoters are significantly depleted of TEs in all tissues compared with their overall prevalence in the genome (P < 0.001); enhancers are also depleted of TEs, though not as strongly as promoters. The degree of enhancer depletion also varies across contexts (1.5-3×), with reproductive and immune cells showing the highest levels of TE regulatory activity in humans. Overall, in spite of the regulatory potential of many TE sequences, they are significantly less active in gene regulation than expected from their prevalence. TE age is predictive of the likelihood of enhancer activity; TEs originating before the divergence of amniotes are 9.2 times more likely to have enhancer activity than TEs that integrated in great apes. Context-specific enhancers are more likely to be TE-derived than enhancers active in multiple tissues, and young TEs are more likely to overlap context-specific enhancers than old TEs (86% vs. 47%). Once TEs obtain enhancer activity in the host, they have similar functional dynamics to one another and non-TE-derived enhancers, likely driven by pleiotropic constraints. However, a few TE families, most notably endogenous retroviruses, have greater regulatory potential. Our observations suggest a model of regulatory co-option in which TE-derived sequences are initially repressed, after which a small fraction obtains context-specific enhancer activity, with further gains subject to pleiotropic constraints.

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Section: Discussionmentioning

confidence: 87%

Transposable Element Exaptation into Regulatory Regions Is Rare, Influenced by Evolutionary Age, and Subject to Pleiotropic Constraints

Simonti

Pavličev

Capra

2017

Molecular Biology and Evolution

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“…Contributions of TEs to regulatory landscapes are particularly pronounced when species-specific enhancers are considered, including through waves of repeat expansions [12]. For example, the majority of ape-specific and human-specific liver enhancers overlap TEs (77% of ape-specific enhancers compared with 16% of evolutionarily conserved enhancers) [50]. Quantitative comparisons of enhancer landscapes between chimpanzee and human cranial neural crest cells (CNCCs) showed that speciesspecific changes in enhancer activity can be explained by the underlying regulatory sequence divergence and is linked to expression differences in genes involved in development of craniofacial structures [51].…”

Section: Transposable Elements As a Substrate For Evolving New Enhancersmentioning

confidence: 99%

Transposable elements as a potent source of diverse cis -regulatory sequences in mammalian genomes

Sundaram

Wysocka

2020

Phil. Trans. R. Soc. B

163

153

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Eukaryotic gene regulation is mediated by cis -regulatory elements, which are embedded within the vast non-coding genomic space and recognized by the transcription factors in a sequence- and context-dependent manner. A large proportion of eukaryotic genomes, including at least half of the human genome, are composed of transposable elements (TEs), which in their ancestral form carried their own cis -regulatory sequences able to exploit the host trans environment to promote TE transcription and facilitate transposition. Although not all present-day TE copies have retained this regulatory function, the preexisting regulatory potential of TEs can provide a rich source of cis -regulatory innovation for the host. Here, we review recent evidence documenting diverse contributions of TE sequences to gene regulation by functioning as enhancers, promoters, silencers and boundary elements. We discuss how TE-derived enhancer sequences can rapidly facilitate changes in existing gene regulatory networks and mediate species- and cell-type-specific regulatory innovations, and we postulate a unique contribution of TEs to species-specific gene expression divergence in pluripotency and early embryogenesis. With advances in genome-wide technologies and analyses, systematic investigation of TEs' cis -regulatory potential is now possible and our understanding of the biological impact of genomic TEs is increasing. This article is part of a discussion meeting issue ‘Crossroads between transposons and gene regulation’.

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“…A growing body of evidence suggests that specific TE subfamilies have been coopted for transcriptional regulation in a number of biological contexts (12)(13)(14)(15)(16)(17)(18)(19)(20)(21)(22). In particular, TEassociated enhancers contributed to the evolution of early development (17), placentation (18), mammalian pregnancy (14),…”

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confidence: 99%

Specific subfamilies of transposable elements contribute to different domains of T lymphocyte enhancers

Goudot

Hoyler

et al. 2020

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

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Transposable elements (TEs) compose nearly half of mammalian genomes and provide building blocks forcis-regulatory elements. Using high-throughput sequencing, we show that 84 TE subfamilies are overrepresented, and distributed in a lineage-specific fashion in core and boundary domains of CD8+T cell enhancers. Endogenous retroviruses are most significantly enriched in core domains with accessible chromatin, and bear recognition motifs for immune-related transcription factors. In contrast, short interspersed elements (SINEs) are preferentially overrepresented in nucleosome-containing boundaries. A substantial proportion of these SINEs harbor a high density of the enhancer-specific histone mark H3K4me1 and carry sequences that match enhancer boundary nucleotide composition. Motifs with regulatory features are better preserved within enhancer-enriched TE copies compared to their subfamily equivalents located in gene deserts. TE-rich and TE-poor enhancers associate with both shared and unique gene groups and are enriched in overlapping functions related to lymphocyte and leukocyte biology. The majority of T cell enhancers are shared with other immune lineages and are accessible in common hematopoietic progenitors. A higher proportion of immune tissue-specific enhancers are TE-rich compared to enhancers specific to other tissues, correlating with higher TE occurrence in immune gene-associated genomic regions. Our results suggest that during evolution, TEs abundant in these regions and carrying motifs potentially beneficial for enhancer architecture and immune functions were particularly frequently incorporated by evolving enhancers. Their putative selection and regulatory cooption may have accelerated the evolution of immune regulatory networks.

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Transposable element exaptation is the primary source of novelty in the primate gene regulatory landscape

Cited by 10 publications

References 126 publications

Transposable Element Exaptation into Regulatory Regions Is Rare, Influenced by Evolutionary Age, and Subject to Pleiotropic Constraints

Transposable Element Exaptation into Regulatory Regions Is Rare, Influenced by Evolutionary Age, and Subject to Pleiotropic Constraints

Transposable elements as a potent source of diverse cis -regulatory sequences in mammalian genomes

Specific subfamilies of transposable elements contribute to different domains of T lymphocyte enhancers

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