Abstract
Although DNA replication is a fundamental aspect of biology, it is not known what determines where DNA replication starts and stops in the human genome. We directly identified and quantitatively compared sites of replication initiation and termination in untransformed human cells. We found that replication preferentially initiates at the transcription start site of genes occupied by high levels of RNA polymerase II, and terminates at their polyadenylation sites, thereby ensuring global co-directionality of transcription and replication, particularly at gene 5′ ends. During replication stress, replication initiation is stimulated downstream of genes and termination is redistributed to gene bodies; this globally reorients replication relative to transcription around gene 3′ ends. These data suggest that replication initiation and termination are coupled to transcription in human cells, and propose a model for the impact of replication stress on genome integrity.
This is a preview of subscription content, access via your institution
Access options
Access Nature and 54 other Nature Portfolio journals
Get Nature+, our best-value online-access subscription
$29.99 / 30 days
cancel any time
Subscribe to this journal
Receive 12 print issues and online access
$209.00 per year
only $17.42 per issue
Buy this article
- Purchase on SpringerLink
- Instant access to full article PDF
Prices may be subject to local taxes which are calculated during checkout
Similar content being viewed by others
References
Stinchcomb, D. T., Struhl, K. & Davis, R. W. Isolation and characterisation of a yeast chromosomal replicator. Nature 282, 39–43 (1979).
Hyrien, O. Peaks cloaked in the mist: the landscape of mammalian replication origins. J. Cell Biol. 208, 147–160 (2015).
Prioleau, M. N. & MacAlpine, D. M. DNA replication origins-where do we begin. Genes Dev. 30, 1683–1697 (2016).
Besnard, E. et al. Unraveling cell type-specific and reprogrammable human replication origin signatures associated with G-quadruplex consensus motifs. Nat. Struct. Mol. Biol. 19, 837–844 (2012).
Dellino, G. I. et al. Genome-wide mapping of human DNA-replication origins: levels of transcription at ORC1 sites regulate origin selection and replication timing. Genome Res. 23, 1–11 (2013).
Langley, A. R., Gräf, S., Smith, J. C. & Krude, T. Genome-wide identification and characterisation of human DNA replication origins by initiation site sequencing (ini-seq). Nucleic Acids Res. 44, 10230–10247 (2016).
Petryk, N. et al. Replication landscape of the human genome. Nat. Commun. 7, 10208 (2016).
Donovan, S., Harwood, J., Drury, L. S. & Diffley, J. F. Cdc6p-dependent loading of Mcm proteins onto pre-replicative chromatin in budding yeast. Proc. Natl Acad. Sci. USA 94, 5611–5616 (1997).
Edwards, M. C. et al. MCM2-7 complexes bind chromatin in a distributed pattern surrounding the origin recognition complex in Xenopus egg extracts. J. Biol. Chem. 277, 33049–33057 (2002).
Ge, X. Q., Jackson, D. A. & Blow, J. J. Dormant origins licensed by excess Mcm2-7 are required for human cells to survive replicative stress. Genes Dev. 21, 3331–3341 (2007).
Rocha, E. P. C. Gene essentiality determines chromosome organisation in bacteria. Nucleic Acids Res. 31, 6570–6577 (2003).
Osmundson, J. S., Kumar, J., Yeung, R. & Smith, D. J. Pif1-family helicases cooperatively suppress widespread replication-fork arrest at tRNA genes. Nat. Struct. Mol. Biol. 24, 162–170 (2017).
Pourkarimi, E., Bellush, J. M. & Whitehouse, I. Spatiotemporal coupling and decoupling of gene transcription with DNA replication origins during embryogenesis in C. elegans. eLife 5, e21728 (2016).
Hamperl, S., Bocek, M. J., Saldivar, J. C., Swigut, T. & Cimprich, K. A. Transcription-replication conflict orientation modulates r-loop levels and activates distinct dna damage responses. Cell 170, 774–786.e19 (2017).
Tran, P. L. T. et al. PIF1 family DNA helicases suppress R-loop mediated genome instability at tRNA genes. Nat. Commun. 8, 15025 (2017).
McGuffee, S. R., Smith, D. J. & Whitehouse, I. Quantitative, genome-wide analysis of eukaryotic replication initiation and termination. Mol. Cell 50, 123–135 (2013).
Tubbs, A. et al. Dual roles of poly(dA:dT) tracts in replication initiation and fork collapse. Cell 174, 1127–1142.e19 (2018).
Smith, D. J. & Whitehouse, I. Intrinsic coupling of lagging-strand synthesis to chromatin assembly. Nature 483, 434–438 (2012).
Harenza, J. L. et al. Transcriptomic profiling of 39 commonly-used neuroblastoma cell lines. Sci. Data 4, 170033 (2017).
Macheret, M. & Halazonetis, T. D. Intragenic origins due to short G1 phases underlie oncogene-induced DNA replication stress. Nature 555, 112–116 (2018).
Almeida, R. et al. Chromatin conformation regulates the coordination between DNA replication and transcription. Nat. Commun. 9, 1590 (2018).
Sanchez, G. J. et al. Genome-wide dose-dependent inhibition of histone deacetylases studies reveal their roles in enhancer remodeling and suppression of oncogenic super-enhancers. Nucleic Acids Res. 46, 1756–1776 (2018).
Blow, J. J., Ge, X. Q. & Jackson, D. A. How dormant origins promote complete genome replication. Trends. Biochem. Sci. 36, 405–414 (2011).
Karnani, N. & Dutta, A. The effect of the intra-S-phase checkpoint on origins of replication in human cells. Genes Dev. 25, 621–633 (2011).
Ceccaldi, R., Sarangi, P. & D’Andrea, A. D. The Fanconi anaemia pathway: new players and new functions. Nat. Rev. Mol. Cell Biol. 17, 337–349 (2016).
Michl, J., Zimmer, J. & Tarsounas, M. Interplay between Fanconi anemia and homologous recombination pathways in genome integrity. EMBO J. 35, 909–923 (2016).
Chen, Y. H. et al. ATR-mediated phosphorylation of FANCI regulates dormant origin firing in response to replication stress. Mol. Cell 58, 323–338 (2015).
Proudfoot, N. J. Transcriptional termination in mammals: stopping the RNA polymerase II juggernaut. Science 352, aad9926 (2016).
Sanz, L. A. et al. Prevalent, dynamic, and conserved R-loop structures associate with specific epigenomic signatures in mammals. Mol. Cell 63, 167–178 (2016).
Merrikh, H. Spatial and temporal control of evolution through replication-transcription conflicts. Trends Microbiol. 25, 515–521 (2017).
Paul, S., Million-Weaver, S., Chattopadhyay, S., Sokurenko, E. & Merrikh, H. Accelerated gene evolution through replication-transcription conflicts. Nature 495, 512–515 (2013).
Srivatsan, A., Tehranchi, A., MacAlpine, D. M. & Wang, J. D. Co-orientation of replication and transcription preserves genome integrity. PLoS Genet. 6, e1000810 (2010).
Hansen, R. S. et al. Sequencing newly replicated DNA reveals widespread plasticity in human replication timing. Proc. Natl Acad. Sci. USA 107, 139–144 (2009).
Anderson, J. D. & Widom, J. Poly(dA-dT) promoter elements increase the equilibrium accessibility of nucleosomal DNA target sites. Mol. Cell. Biol. 21, 3830–3839 (2001).
Vashee, S. et al. Sequence-independent DNA binding and replication initiation by the human origin recognition complex. Genes Dev. 17, 1894–1908 (2003).
Glover-Cutter, K., Kim, S., Espinosa, J. & Bentley, D. L. RNA polymerase II pauses and associates with pre-mRNA processing factors at both ends of genes. Nat. Struct. Mol. Biol. 15, 71–78 (2008).
Mirkin, E. V., Castro Roa, D., Nudler, E. & Mirkin, S. M. Transcription regulatory elements are punctuation marks for DNA replication. Proc. Natl Acad. Sci. USA 103, 7276–7281 (2006).
Lang, K. S. et al. Replication-transcription conflicts generate R-loops that orchestrate bacterial stress survival and pathogenesis. Cell 170, 787–799.e18 (2017).
Paulsen, R. D. et al. A genome-wide siRNA screen reveals diverse cellular processes and pathways that mediate genome stability. Mol. Cell 35, 228–239 (2009).
Stirling, P. C. et al. R-loop-mediated genome instability in mRNA cleavage and polyadenylation mutants. Genes Dev. 26, 163–175 (2012).
Gros, J., Devbhandari, S. & Remus, D. Origin plasticity during budding yeast DNA replication in vitro. EMBO J. 33, 621–636 (2014).
Gros, J. et al. Post-licensing specification of eukaryotic replication origins by facilitated Mcm2-7 sliding along DNA. Mol. Cell 60, 797–807 (2015).
Douglas, M. E., Ali, F. A., Costa, A. & Diffley, J. F. X. The mechanism of eukaryotic CMG helicase activation. Nature 555, 265–268 (2018).
Helmrich, A., Ballarino, M. & Tora, L. Collisions between replication and transcription complexes cause common fragile site instability at the longest human genes. Mol. Cell 44, 966–977 (2011).
Klein, K. et al. Genome-wide identification of early-firing human replication origins by optical replication mapping. Preprint at https://www.biorxiv.org/content/early/2017/11/06/214841 (2017).
Acknowledgements
We thank the NYU Genome Technology Center for assistance with TapeStation and sequencing. We thank D. Remus, I. Whitehouse, E. Mazzoni, and H. Klein for helpful discussions, and G Sanchez for sharing RPE-1 enhancer data. Y.-H.C. was funded in part by the Molecular Oncology and Immunology NCI training program through NYU School of Medicine (no. 5T32CA009161-40). Work in T.T.H.'s laboratory is supported by grants from the NIH (ES025166), V Foundation BRCA Research and Basser Innovation Award. Work in D.J.S.'s laboratory is supported by grants from the NIH (nos. GM127336, GM114340) and the Searle Scholars Program.
Author information
Authors and Affiliations
Contributions
Y.-H. C., M.K., and P.T. performed the experiments, S.K. and D.J.S. analyzed the data and D.F., T.T.H., and D.J.S. conceived and supervised the study. All of the authors interpreted the data. D.J.S. wrote the manuscript with input from all authors.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Integrated supplementary information
Supplementary Fig 1 Reproducibility of TSS data across replicate datasets.
a, Percentage of Okazaki fragments (OFs) mapping to the Crick strand across a region ±50 kb from random genomic loci. b, Percentage of OFs mapping to the Crick strand across a ±50-kb window around the TSS of Watson (W) or Crick (C) genes. Data were analyzed as in Fig. 1e for two replicate datasets. c, Percentage of replication forks moving left to right around TSS binned by transcriptional volume (FPKM from 19 × gene length). Data were analyzed as in Fig. 2g, for two replicate datasets. d, Percentage of replication forks moving left to right around TSS binned by transcriptional volume, for cells treated with siRNAs against FANCD2 (green), FANCI (blue), or mock-treated (black), grown in 0.2 mM hydroxyurea for 4 h before OF collection. Data were analyzed as in Fig. 4d, using the second replicate datasets for each knockdown condition.
Supplementary Fig 2 The effect of gene length on TSS-proximal origin firing efficiency is not solely a result of passive replication.
a, Percentage of replication forks moving left to right around the TSS of actively transcribed genes (FPKM > median), where the TSS of the most proximal upstream gene is under (black) or over (green) 50 kb from the TSS being analyzed. b, Percentage of replication forks moving left to right around the TSS of actively transcribed genes (FPKM > median), where the TTS of the most proximal upstream gene is under (black) or over (red) 50 kb from the TSS being analyzed. c, Percentage of replication forks moving left to right around the TSS of actively transcribed genes (FPKM > median), where the TSS of the most proximal downstream gene is under (black) or over (green) 50 kb from the TSS being analyzed. d, Percentage of replication forks moving left to right around the TSS of actively transcribed genes (FPKM > median), where the most proximal downstream TTS is under (black) or over (red) 50 kb from the TSS being analyzed. Note that this TSS–TTS distance is equivalent to the length of the gene.
Supplementary Fig 3 Replication initiation is most efficient at high-volume TSS in HeLa and GM06990 cells.
Data in a–f were analyzed using Ok-seq data from HeLa cells (7) and HeLa RNA-seq data. a, Percentage of HeLa OFs mapping to the Crick strand (indicating rightward-moving replication forks) across a ±50-kb window around annotated TSS. Data were analyzed as in Fig. 1d. b, Percentage of OFs mapping to the Crick strand across a ±50-kb window around the TSS of Watson (W) or Crick (C) genes. Data were analyzed as in Fig. 1e. c, Percentage of replication forks moving from left to right around the TSS of all genes, oriented such that transcription runs from left to right. Data were analyzed as in Fig. 1f. d, Replication initiation frequency, calculated as the first derivative of Okazaki fragment strand bias as a function of position, across a ±50-kb window around the TSS. Data were analyzed as in Fig. 1g. e, Percentage of replication forks moving left to right around TSS binned by RNA-seq read depth quartile. Data were analyzed as in Fig. 2a. f, Percentage of replication forks moving left to right around TSS binned by gene length. Data were analyzed as in Fig. 2e. g–l, Data were analyzed as in a–f, using Ok-seq data from GM06990 cells (7) and GM06990 RNA-seq data.
Supplementary Fig 4 Comparison of OF strand bias around enhancers and equivalently selected random sites at various distances from TSS.
Percentage of OFs mapping to the Crick strand around enhancer midpoints, for enhancers or random sites within the indicated distance of annotated TSS. Enhancers are binned according to transcription level (above or below median). Data were analyzed as in Fig. 3c.
Supplementary Fig 5 The effect of FANCI knockdown is not related to gene length or increased replication termination.
Percentage of replication forks moving left to right around TSS binned by transcriptional volume (FPKM from Harenza et al. × gene length) for cells treated with siRNAs against FANCI (blue) or mock-treated (black), grown in 0.2 mM hydroxyurea for 4 h before OF collection. The TSS is denoted by a gray dotted line: lower and upper bounds for gene length in each quartile are denoted by dotted and dashed black lines, respectively.
Supplementary Fig 6 Reproducibility of TTS data across replicate datasets.
a, Percentage of replication forks moving left to right around transcription termination sites (TTS) binned by RNA-seq read depth quartile. Data were analyzed as in Fig. 5a, for two replicate datasets. b, Percentage of replication forks moving left to right around (TTS) binned by RNA-seq read depth quartile, from cells grown in 0.2 mM HU for 4 h before OF collection. Data were analyzed as in Fig. 6a, for two replicate datasets.
Supplementary Fig 7 Transcription-dependent, R-loop-independent replication termination at TTS in HeLa and GM06990 cells.
Data in a–d were analyzed using Ok-seq data from HeLa cells (7) and HeLa RNA-seq data. DRIP-seq data are from HeLa cells (14). a, Percentage of replication forks moving left to right around transcription termination sites (TTS) binned by RNA-seq read depth quartile. Data were analyzed as in Fig. 5a. b, Replication initiation frequency, calculated as the first derivative of Okazaki fragment strand bias, around TTS binned by RNA-seq read density in the gene body. Data were analyzed as in Fig. 5c. c, Percentage of replication forks moving left to right around TTS of actively transcribed (FPKM > median) high-DRIP versus low-DRIP genes. Data were analyzed as in Fig. 5g. d, Replication initiation frequency, calculated as the first derivative of Okazaki fragment strand bias, around TTS of actively transcribed (FPKM > median) high-DRIP versus low-DRIP genes. Data were analyzed as in Fig. 5h. e–h, Data were analyzed as in a–d using Ok-seq data from GM06990 cells (7) and GM06990 RNA-seq data.
Supplementary information
Supplementary Text and Figures
Supplementary Figures 1–7
Rights and permissions
About this article
Cite this article
Chen, YH., Keegan, S., Kahli, M. et al. Transcription shapes DNA replication initiation and termination in human cells. Nat Struct Mol Biol 26, 67–77 (2019). https://doi.org/10.1038/s41594-018-0171-0
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/s41594-018-0171-0