Integrating transposable elements in the 3D genome

doi:10.1186/s13100-020-0202-3

Editorial

. 2020 Feb 4:11:8.

doi: 10.1186/s13100-020-0202-3. eCollection 2020.

Integrating transposable elements in the 3D genome

Alexandros Bousios^#¹, Hans-Wilhelm Nützmann^#², Dorothy Buck³, Davide Michieletto^{3

4

5}

Affiliations

¹ 1School of Life Sciences, University of Sussex, Falmer, UK.
² 2Milner Centre for Evolution, Department of Biology and Biochemistry, University of Bath, North Rd, Bath, BA2 7AY UK.
³ 3Centre for Mathematical Biology and Department of Mathematical Sciences, University of Bath, North Rd, Bath, BA2 7AY UK.
⁴ 4School of Physics and Astronomy, University of Edinburgh, Edinburgh, EH9 3FD UK.
⁵ 5MRC Human Genetics Unit, Institute of Genetics and Molecular Medicine, University of Edinburgh, Edinburgh, EH4 2XU UK.

^# Contributed equally.

PMID: 32042316
PMCID: PMC7001275
DOI: 10.1186/s13100-020-0202-3

Editorial

Integrating transposable elements in the 3D genome

Alexandros Bousios et al. Mob DNA. 2020.

. 2020 Feb 4:11:8.

doi: 10.1186/s13100-020-0202-3. eCollection 2020.

Authors

Alexandros Bousios^#¹, Hans-Wilhelm Nützmann^#², Dorothy Buck³, Davide Michieletto^{3

4

5}

Affiliations

¹ 1School of Life Sciences, University of Sussex, Falmer, UK.
² 2Milner Centre for Evolution, Department of Biology and Biochemistry, University of Bath, North Rd, Bath, BA2 7AY UK.
³ 3Centre for Mathematical Biology and Department of Mathematical Sciences, University of Bath, North Rd, Bath, BA2 7AY UK.
⁴ 4School of Physics and Astronomy, University of Edinburgh, Edinburgh, EH9 3FD UK.
⁵ 5MRC Human Genetics Unit, Institute of Genetics and Molecular Medicine, University of Edinburgh, Edinburgh, EH4 2XU UK.

^# Contributed equally.

PMID: 32042316
PMCID: PMC7001275
DOI: 10.1186/s13100-020-0202-3

Abstract

Chromosome organisation is increasingly recognised as an essential component of genome regulation, cell fate and cell health. Within the realm of transposable elements (TEs) however, the spatial information of how genomes are folded is still only rarely integrated in experimental studies or accounted for in modelling. Whilst polymer physics is recognised as an important tool to understand the mechanisms of genome folding, in this commentary we discuss its potential applicability to aspects of TE biology. Based on recent works on the relationship between genome organisation and TE integration, we argue that existing polymer models may be extended to create a predictive framework for the study of TE integration patterns. We suggest that these models may offer orthogonal and generic insights into the integration profiles (or "topography") of TEs across organisms. In addition, we provide simple polymer physics arguments and preliminary molecular dynamics simulations of TEs inserting into heterogeneously flexible polymers. By considering this simple model, we show how polymer folding and local flexibility may generically affect TE integration patterns. The preliminary discussion reported in this commentary is aimed to lay the foundations for a large-scale analysis of TE integration dynamics and topography as a function of the three-dimensional host genome.

PubMed Disclaimer

Conflict of interest statement

Competing interestsThe authors declare that they have no competing interests.

Figures

**Fig. 1**
a Coarse graining of microscopic details of double stranded DNA into a bead-spring polymer. b A polymer model for the nucleosome: highlighted are the features of DNA stiffness (set by penalising large angles θ between consecutive pairs of monomers) and connectivity (set by penalising large extensions x between consecutive beads). We also account for excluded volume interactions and pair-attraction represented by the wrapping of the orange segment around the histone octamer (here a blue spherical bead). c Schematics showing that integration events on DNA deform the substrate. d Snapshots from molecular dynamics simulations showing an integration event within a nucleosome. Color scheme: orange = wrapped host DNA, green= viral DNA, grey = non-wrapped host DNA. Adapted from Ref. [54]

**Fig. 2**
a Copy-and-paste transposition explores the nuclear space by diffusing from the periphery towards the interior, i.e. outside-in. The large-scale nuclear architecture, i.e. inverted or conventional [95], Lamin Associated Domains (LADs) [21], compartments [71] and enhancers hot-spots [83, 86], are expected to play the biggest roles in the integration site selection. b–c Cut-and-paste transposition explores the nuclear interior inside-out. In this case, TAD-scale (∼1 Mbp) genome folding is expected to dominate and in particular open conformations will yield short range de novo re-integration whereas collapsed ones will lead to longer range re-integration. Duplication of the transposon is also possible by homologous DNA repair of the broken strands

**Fig. 3**
a Sketch of the original simulations performed in this work where we consider a segment of DNA 1.6 kbp long (or N=200 beads, each bead representing 8 bp) with rigidity l_p=150 bp. The DNA is interspersed with “soft” sites which display a different rigidity l_f. The length of these weak sites is 8 bp, or 1 bead. b We compute the frequency of integration events per each segment of the substrate by counting the number of events occurring at a specific locus over the total integration events. We average over 1000 independent simulations. One can notice that the patterns, which are roughly uniform for l_f=l_p become more and more periodic and reflecting the positions of the soft sites (denoted by the black arrows) when we reduce l_f. The dotted line shows the expected frequency for random events 1/N, with N=200 the length of the substrate. For clarity we report only the segment 0.5–1 kbp. c Integration enhancement in soft sites over the expected random frequency. Each box represents a different value of the rigidity of the soft sites l_f. Recall that l_f=l_p=150 bp reflects a uniformly stiff substrate and indeed we recover the expected value (unity) for the enhancement

See this image and copyright information in PMC

Cited by

Broken, silent, and in hiding: tamed endogenous pararetroviruses escape elimination from the genome of sugar beet (Beta vulgaris).
Schmidt N, Seibt KM, Weber B, Schwarzacher T, Schmidt T, Heitkam T. Schmidt N, et al. Ann Bot. 2021 Aug 26;128(3):281-299. doi: 10.1093/aob/mcab042. Ann Bot. 2021. PMID: 33729490 Free PMC article.
Structure-specific nucleases in genome dynamics and strategies for targeting cancers.
Sun H, Luo M, Zhou M, Zheng L, Li H, Esworthy RS, Shen B. Sun H, et al. J Mol Cell Biol. 2024 Oct 21;16(5):mjae019. doi: 10.1093/jmcb/mjae019. J Mol Cell Biol. 2024. PMID: 38714348 Free PMC article. Review.
Toxic Y chromosome: Increased repeat expression and age-associated heterochromatin loss in male Drosophila with a young Y chromosome.
Nguyen AH, Bachtrog D. Nguyen AH, et al. PLoS Genet. 2021 Apr 22;17(4):e1009438. doi: 10.1371/journal.pgen.1009438. eCollection 2021 Apr. PLoS Genet. 2021. PMID: 33886541 Free PMC article.
Where the Wild Things Are: Transposable Elements as Drivers of Structural and Functional Variations in the Wheat Genome.
Bariah I, Keidar-Friedman D, Kashkush K. Bariah I, et al. Front Plant Sci. 2020 Sep 18;11:585515. doi: 10.3389/fpls.2020.585515. eCollection 2020. Front Plant Sci. 2020. PMID: 33072155 Free PMC article. Review.
Plant biosynthetic gene clusters in the context of metabolic evolution.
Smit SJ, Lichman BR. Smit SJ, et al. Nat Prod Rep. 2022 Jul 20;39(7):1465-1482. doi: 10.1039/d2np00005a. Nat Prod Rep. 2022. PMID: 35441651 Free PMC article. Review.

See all "Cited by" articles

References

1. Deniz Özgen, Frost Jennifer M., Branco Miguel R. Regulation of transposable elements by DNA modifications. Nature Reviews Genetics. 2019;20(7):417–431. doi: 10.1038/s41576-019-0106-6. - DOI - PubMed
1. Schnable PS, Pasternak S, Liang C, Zhang J, Fulton L, Graves TA, Minx P, Reily AD. Courtney L, Kruchowski SS, Tomlinson C, Strong C, Delehaunty K, Fronick C, Courtney B, Rock SM, Belter E, Du F, Kim K, Abbott RM, Cotton M, Levy A, Marchetto P, Ochoa K, Jackson SM, Gillam B, Chen W, Yan L, Higginbotham J, Cardenas M, Waligorski J, Applebaum E, Phelps L, Falcone J, Kanchi K, Thane T, Scimone A, Thane N, Henke J, Wang T, Ruppert J, Shah N, Rotter K, Hodges J, Ingenthron E, Cordes M, Kohlberg S, Sgro J, Delgado B, Mead K, Chinwalla A, Leonard S, Crouse K, Collura K, Kudrna D, Currie J, He R, Angelova A, Rajasekar S, Mueller T, Lomeli R, Scara G, Ko A, Delaney K, Wissotski M, Lopez G, Campos D, Braidotti M, Ashley E, Golser W, Kim H, Lee S, Lin J, Dujmic Z, Kim W, Talag J, Zuccolo A, Fan C, Sebastian A, Kramer M, Spiegel L, Nascimento L, Zutavern T, Miller B, Ambroise C, Muller S, Spooner W, Narechania A, Ren L, Wei S, Kumari S. The B73 Maize Genome: Complexity, Diversity, and Dynamics. J Sci. 2009;326:1112. - PubMed
1. Lee HE, Ayarpadikannan S, Kim HS. Role of transposable elements in genomic rearrangement, evolution, gene regulation and epigenetics in primates. Genes Genet Syst. 2016;90(18805779):245. - PubMed
1. Chuong EB, Elde NC, Feschotte C. Regulatory activities of transposable elements: From conflicts to benefits. Nat Rev Genet. 2017;18(14710064):71. doi: 10.1038/nrg.2016.139. - DOI - PMC - PubMed
1. Bousios A, Gaut BS. ScienceDirect Mechanistic and evolutionary questions about epigenetic conflicts between transposable elements and their plant hosts. Curr Opin Plant Biol. 2016;30(1369-5266):123. doi: 10.1016/j.pbi.2016.02.009. - DOI - PubMed

Publication types

Actions

LinkOut - more resources

Full Text Sources

[1] Deniz Özgen, Frost Jennifer M., Branco Miguel R. Regulation of transposable elements by DNA modifications. Nature Reviews Genetics. 2019;20(7):417–431. doi: 10.1038/s41576-019-0106-6. - DOI - PubMed

[2] Deniz Özgen, Frost Jennifer M., Branco Miguel R. Regulation of transposable elements by DNA modifications. Nature Reviews Genetics. 2019;20(7):417–431. doi: 10.1038/s41576-019-0106-6. - DOI - PubMed

[3] Schnable PS, Pasternak S, Liang C, Zhang J, Fulton L, Graves TA, Minx P, Reily AD. Courtney L, Kruchowski SS, Tomlinson C, Strong C, Delehaunty K, Fronick C, Courtney B, Rock SM, Belter E, Du F, Kim K, Abbott RM, Cotton M, Levy A, Marchetto P, Ochoa K, Jackson SM, Gillam B, Chen W, Yan L, Higginbotham J, Cardenas M, Waligorski J, Applebaum E, Phelps L, Falcone J, Kanchi K, Thane T, Scimone A, Thane N, Henke J, Wang T, Ruppert J, Shah N, Rotter K, Hodges J, Ingenthron E, Cordes M, Kohlberg S, Sgro J, Delgado B, Mead K, Chinwalla A, Leonard S, Crouse K, Collura K, Kudrna D, Currie J, He R, Angelova A, Rajasekar S, Mueller T, Lomeli R, Scara G, Ko A, Delaney K, Wissotski M, Lopez G, Campos D, Braidotti M, Ashley E, Golser W, Kim H, Lee S, Lin J, Dujmic Z, Kim W, Talag J, Zuccolo A, Fan C, Sebastian A, Kramer M, Spiegel L, Nascimento L, Zutavern T, Miller B, Ambroise C, Muller S, Spooner W, Narechania A, Ren L, Wei S, Kumari S. The B73 Maize Genome: Complexity, Diversity, and Dynamics. J Sci. 2009;326:1112. - PubMed

[4] Schnable PS, Pasternak S, Liang C, Zhang J, Fulton L, Graves TA, Minx P, Reily AD. Courtney L, Kruchowski SS, Tomlinson C, Strong C, Delehaunty K, Fronick C, Courtney B, Rock SM, Belter E, Du F, Kim K, Abbott RM, Cotton M, Levy A, Marchetto P, Ochoa K, Jackson SM, Gillam B, Chen W, Yan L, Higginbotham J, Cardenas M, Waligorski J, Applebaum E, Phelps L, Falcone J, Kanchi K, Thane T, Scimone A, Thane N, Henke J, Wang T, Ruppert J, Shah N, Rotter K, Hodges J, Ingenthron E, Cordes M, Kohlberg S, Sgro J, Delgado B, Mead K, Chinwalla A, Leonard S, Crouse K, Collura K, Kudrna D, Currie J, He R, Angelova A, Rajasekar S, Mueller T, Lomeli R, Scara G, Ko A, Delaney K, Wissotski M, Lopez G, Campos D, Braidotti M, Ashley E, Golser W, Kim H, Lee S, Lin J, Dujmic Z, Kim W, Talag J, Zuccolo A, Fan C, Sebastian A, Kramer M, Spiegel L, Nascimento L, Zutavern T, Miller B, Ambroise C, Muller S, Spooner W, Narechania A, Ren L, Wei S, Kumari S. The B73 Maize Genome: Complexity, Diversity, and Dynamics. J Sci. 2009;326:1112. - PubMed

[5] Lee HE, Ayarpadikannan S, Kim HS. Role of transposable elements in genomic rearrangement, evolution, gene regulation and epigenetics in primates. Genes Genet Syst. 2016;90(18805779):245. - PubMed

[6] Lee HE, Ayarpadikannan S, Kim HS. Role of transposable elements in genomic rearrangement, evolution, gene regulation and epigenetics in primates. Genes Genet Syst. 2016;90(18805779):245. - PubMed

[7] Chuong EB, Elde NC, Feschotte C. Regulatory activities of transposable elements: From conflicts to benefits. Nat Rev Genet. 2017;18(14710064):71. doi: 10.1038/nrg.2016.139. - DOI - PMC - PubMed

[8] Chuong EB, Elde NC, Feschotte C. Regulatory activities of transposable elements: From conflicts to benefits. Nat Rev Genet. 2017;18(14710064):71. doi: 10.1038/nrg.2016.139. - DOI - PMC - PubMed

[9] Bousios A, Gaut BS. ScienceDirect Mechanistic and evolutionary questions about epigenetic conflicts between transposable elements and their plant hosts. Curr Opin Plant Biol. 2016;30(1369-5266):123. doi: 10.1016/j.pbi.2016.02.009. - DOI - PubMed

[10] Bousios A, Gaut BS. ScienceDirect Mechanistic and evolutionary questions about epigenetic conflicts between transposable elements and their plant hosts. Curr Opin Plant Biol. 2016;30(1369-5266):123. doi: 10.1016/j.pbi.2016.02.009. - DOI - PubMed

Save citation to file

Email citation

Add to Collections

Add to My Bibliography

Your saved search

Create a file for external citation management software

Your RSS Feed

Integrating transposable elements in the 3D genome

Affiliations

Integrating transposable elements in the 3D genome

Authors

Affiliations

Abstract

Conflict of interest statement

Figures

Similar articles

Cited by

References

Publication types

LinkOut - more resources

Full Text Sources