Abstract
Chromatin is known to undergo extensive remodeling during nuclear reprogramming. However, the factors and mechanisms involved in this remodeling are still poorly understood and current experimental approaches to study it are not best suited for molecular and genetic analyses. Here we report on the use of Drosophila preblastodermic embryo extracts (DREX) in chromatin remodeling experiments. Our results show that incubation of somatic nuclei in DREX induces changes in chromatin organization similar to those associated with nuclear reprogramming, such as rapid binding of the germline specific linker histone dBigH1 variant to somatic chromatin, heterochromatin reorganization, changes in the epigenetic state of chromatin, and nuclear lamin disassembly. These results raise the possibility of using the powerful tools of Drosophila genetics for the analysis of chromatin changes associated with this essential process.
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Introduction
Chromatin remodeling is essential for nuclear reprogramming. Experimental approaches to study chromatin remodeling during nuclear reprogramming include ectopic expression of Yamanaka transcription factors, nuclear transfer to eggs or oocytes, cell fusion with embryonic stem cells and in vitro treatment with oocyte or egg extracts1,2,3,4,5,6,7,8,9. Here we address the potential use of cell-free extracts prepared from Drosophila preblastoderm embryos (DREX) to study chromatin remodeling. DREX has been extensively used in exploring DNA replication10, chromatin assembly11,12 and decondensation13,14, nuclear formation15, nuclear envelope assembly16,17, and for the study of mitosis ex vivo18. We show that, upon incubation in DREX, somatic nuclei undergo important structural changes reminiscent of nuclear reprogramming. One of the earliest events during nuclear reprogramming is the exchange of somatic linker histones H1 by oocyte specific variants7,19,20,21,22. Metazoans usually contain multiple somatic23,24 and germline specific H1 variants25. However, in Drosophila, histone H1 complexity is reduced to a single somatic dH1 variant26,27,28, and a second germline specific dBigH1 isoform, which is also present in the early embryo until activation of the zygotic genome (ZGA) at cellularization29. Our results show that incubation of somatic nuclei in DREX results in rapid binding of dBigH1. In addition, we also show that DREX induces heterochromatin reorganization, nuclear lamin disassembly and changes in the pattern of histone modifications, all of which are associated with reprogramming of somatic nuclei. These results suggest that DREX induces partial remodeling of somatic chromatin, opening up the possibility of using the powerful tools of Drosophila genetics to study this central step in somatic cells reprogramming.
Results
Incubation of somatic nuclei in DREX induces dBigH1 incorporation
An early event in reprogramming of somatic nuclei transplanted into oocytes is the binding to chromatin of the oocyte specific linker histones H17,19,20,21,22. In this regard, incubation of somatic nuclei prepared from Drosophila S2 cells in DREX, which is enriched in dBigH1, resulted in its incorporation to chromatin. Immunofluorescence analyses (IF) showed a clear association of dBigH1 with S2 nuclei after incubation in DREX (Fig. S1a). Notice that no dBigH1 was detected in S2 nuclei prior to incubation. Furthermore, fractionation into soluble nuclear and chromatin bound material, detected the presence of dBigH1 in the chromatin bound fraction (Fig. 1a). dBigH1 binding was detected as early as 1′ after incubation in DREX and increased progressively during incubation (Fig. 1a). ChIP-qPCR analysis confirmed these results since, after incubation in DREX, significant dBigH1 occupancy was detected at multiple genomic sites, both single-copy and repetitive (Fig. 1b), suggesting that dBigH1 binding occurred across chromatin.
In nuclear transfer (NT) experiments, binding of the oocyte specific H1s usually results in displacement of the corresponding somatic H1s8,19,20,21,30,31. In this regard, no significant reduction in the amount of chromatin bound dH1 was detected after incubation in DREX for up to 2 h (Fig. 1c). In addition, ChIP-qPCR experiments showed that dH1 occupancy was not impaired upon dBigH1 binding (Fig. 1d). Furthermore, IF experiments detected only a weak negative correlation between dBigH1 and dH1 content in DREX-treated nuclei (Fig. S1b). Altogether, these results suggest that dBigH1 binding occurs without significant dH1 displacement. Notice, however, that after 1′ of incubation dH1 content significantly decreased though dBigH1 binding was only weak (Fig. 1c).
Incubation in DREX induces histone acetylation
Nuclear reprogramming is usually accompanied by changes in the epigenetic state of chromatin32,33,34,35. In this regard, we observed that incubation in DREX resulted in a significant increase of global H3Ac (Fig. 2a). ChIP-qPCR experiments confirmed that H3Ac levels increased at multiple loci after incubation in DREX for 2 h (Fig. 2b). Increased H3Ac observed upon incubation in DREX was not associated with dBigH1 binding since a similar increase was also observed when dBigH1 binding was strongly impaired by the addition of αdBigH1 antibodies to DREX (Fig. S2). Increased histone acetylation suggests that incubation in DREX induces transition to a more active chromatin conformation. Thus, we also analyzed whether incubation in DREX affected the levels of H3K4me3, a modification accumulating at promoters of active genes. In this regard, although incubation in DREX did not significantly affect global H3K4me3 levels (Fig. 2c), we detected increased H3K4me3 levels at promoters of several genes (Fig. 2d). This increase was higher at promoters of developmentally regulated genes, highly expressed during early embryogenesis but silent in S2 cells, than at ubiquitously expressed genes (Fig. 2d). We noticed that global H3K4me3 showed a tendency to increase at short incubation times (p-value = 0.1309 at 1′) (Fig. 2c). Similarly, although global levels of the chromatin bound active RNApol II forms were not significantly affected (Fig. S3a and S3b), they showed a tendency to increase at short incubation times, in particular those of the promoter-proximal IIoser5 form (Fig. S3a) (p-value = 0.1779 at 20′). H3K27me3 also showed a tendency to increase (Fig. S3c). Altogether, these results suggest that incubation in DREX alters the epigenetic landscape of somatic chromatin.
DREX induces heterochromatin reorganization and nuclear lamin disassembly
Next, we analyzed whether incubation in DREX affected heterochromatin organization. For this purpose, we performed IF experiments using αHP1a antibodies, which mark heterochromatin. In somatic S2 cells, HP1a is distributed in distinct heterochromatic foci (Fig. 3a, top and Fig. S4a). Upon incubation in DREX, the αHP1a immunostaining pattern was altered, showing a more uniform staining along the nuclei with slight accumulation on the periphery (Fig. 3a, bottom and Fig. S4b). After 2 h of incubation, only ~15% of nuclei preserve the normal HP1a foci pattern. Loss of HP1a foci was not the consequence of a global reduction in HP1a content since global HP1a levels were not significantly reduced upon incubation in DREX (Fig. 3c), but, on the contrary, they tend to increase at long incubation times (p-value = 0.0879 at 2 h). We also observed that incubation in DREX induced the formation of aberrant HP1a foci extruding from the nuclear surface in ~30% of nuclei (Fig. 3b). Similar results were obtained when immunostaining was performed with αH3K9me3 antibodies, which also mark heterochromatin (Fig. S5). Also in this case, a uniform αH3K9me3 pattern was observed upon incubation in DREX (Fig. S5a) and ~30% of nuclei showed extruded H3K9me3 foci (Fig. S5b). It has been reported that somatic nuclei incubated in Xenopus egg extracts eventually disassemble and undergo apoptosis36. However, the major heterochromatin reorganization observed upon incubation in DREX did not reflect general chromatin destabilization and/or apoptosis since release of histones H3 and dH1 was not detected upon incubation in DREX for as long as 24 h (Fig. 3d, bottom). In contrast, chromatin disassembly was observed in control nuclei after 6 h of incubation in the absence of DREX (Fig. 3d, top). Furthermore, ChIP-qPCR experiments showed that incubation in DREX did not significantly reduce H3K9me2 occupancy at several heterochromatic elements, including different types of transposable elements (TE) and satellite DNAs (Fig. 3e), suggesting that heterochromatin stability was not significantly compromised.
Incubation in DREX also induced nuclear lamin disassembly as judged by IF (Fig. 4a). After 2 h of incubation, ~50% of nuclei showed no detectable αlamin reactivity at the nuclear envelope (NE), compared to only 2% in control nuclei (Fig. 4c). Interestingly, αlamin reactivity was generally not detected in nuclei showing diffuse αH3K9me3 immunostaining, while it was intense in nuclei with preserved αH3K9me3 foci (Fig. 4b). After 2 h of incubation in DREX, all nuclei with αH3K9me3 foci showed αlamin reactivity, while this proportion was reduced to ~45% in nuclei lacking usual αH3K9me3 foci (Fig. 4c). Altogether, these results suggest a correlation between heterochromatin reorganization and nuclear lamin disassembly.
Discussion
Here we report that incubation of somatic nuclei in DREX induces changes in chromatin organization similar to those associated with nuclear reprogramming. On one hand, we observed rapid incorporation of the Drosophila germline specific linker histone dBigH1 into the somatic nuclei. NT experiments performed in Xenopus and mammals showed that incorporation of the oocyte specific linker histone variants B4 and H1oo into the donor nuclei is an early event in nuclear reprogramming8,19,20,21,22,30,31. B4 binding precedes loading of oocyte RNApol II and expression of a dominant negative B4 form significantly inhibits transcription of many reprogrammed genes19. Along the same lines, expression of H1oo in mouse ESCs impairs differentiation37 although it does not improve iPSC formation38. How oocyte specific H1s might contribute to nuclear reprogramming remains not well understood. Oocyte specific H1s are less positively charged than their somatic counterparts and, therefore, their interaction with DNA is weaker and condense chromatin less than somatic H1s25, rendering it more accessible to chromatin modifiers, remodelers and transcription factors8,19,39. In this regard, Xenopus B4 is more mobile than somatic H18 and B4-containing chromatin is more accessible to remodeling factors39. B4 binds pervasively across chromatin of the donor nuclei and, concomitantly, somatic H1s are released8,19, suggesting competition of somatic H1s by the oocyte specific variants. However, this competition does not appear to play an important role in reprogramming since overexpression of somatic H1s does not interfere with B4 binding and subsequent activation of pluripotency genes8. Moreover, in mouse fibroblasts, binding of H1oo is detected 10′ after NT, while release of somatic H1s occurs later at 30′ after NT20. Similarly, somatic H1s replacement can last hours in NT experiments with bovine cells21. Finally, our results indicate that, upon incubation in DREX, dBigH1 binds along chromatin without affecting somatic dH1 occupancy. In fact, dH1 occupancy is significantly reduced only at short incubation times when dBigH1 binding is very low.
Our results also show that DREX induces changes in the epigenetic landscape of chromatin, which are in agreement with the global epigenetic remodeling of chromatin observed during reprogramming of somatic cells to iPSCs32,33,34,35. In particular, we observed increased global H3Ac that is maintained throughout the incubation time course. Increased histone acetylation is observed in fully reprogrammed iPSCs40 and ESC chromatin is hyperacetylated compared to differentiated cells41,42,43,44,45. We also observed that H3K4me3 levels increased more intensively at promoters of developmentally regulated genes that are silent in S2 cells but highly expressed in early embryogenesis, suggesting their reactivation. Interestingly, pluripotency-related and developmentally regulated genes are known to acquire H3K4me3 at promoters during nuclear reprogramming32,33,34,35. Finally, though not statistically significant, global levels of H3K4me3 and the chromatin bound promoter-proximal active RNApol IIoser5 form tend to increase at short incubation times. In this regard, NT experiments in Xenopus showed loading of oocyte basal transcription factors and RNApol II leading to genome-wide transcriptional reprogramming and selective activation of pluripotency genes19,46. Notably, our results showed that increased histone acetylation induced by DREX does not require binding of dBigH1, suggesting that, at least in part, the epigenetic changes occurring during reprogramming do not depend only on the activities of the oocyte specific H1s.
Incubation in DREX also induces profound changes in chromatin/nuclear organization. On one hand, at short incubation times, DREX induces heterochromatin reorganization since HP1a/H3K9me3 foci disassemble. A decrease in the number of HP1a foci has also been reported during reprogramming to iPSC40. In this regard, chromatin of pluripotent cells is largely decondensed and heterochromatin is organized in larger and fewer domains that become smaller, more abundant and hypercondensed as cells differentiate41,47,48,49,50. Interestingly, incubation in DREX did not decrease H3K9me2 occupancy at multiple heterochromatic elements, suggesting that DREX affects condensation but not the actual heterochromatin content of somatic nuclei. Oocyte specific H1s might be one of the factors contributing to heterochromatin decondensation since, in humans, H1oo is required for decondensation of sperm chromatin51. At long incubation times, HP1a foci reform and extrude from nuclei. Interestingly, extrusion of heterochromatic sequences was also reported in somatic plant cells undergoing meiosis52. Finally, we also observed that DREX induces disassembly of nuclear lamin, a nuclear envelope component of differentiated cells that is absent in ESCs53. Similar results were reported earlier using a Drosophila oocyte cell-free extract54. Nuclear lamin disassembly is considered a marker of reprogrammed cells, since it is detected at the nuclear envelope in partial iPSCs, but not in fully reprogrammed iPSCs40. Interestingly, nuclear lamin disassembly strongly correlates with heterochromatin reorganization, which might account for the heterochromatin extrusion observed after long-term exposure to DREX.
In summary, our results show that DREX induces several changes associates with gain of pluripotency, such as binding of the germline specific linker histone dBigH1, epigenetic remodeling, heterochromatin reorganization and nuclear lamin disassembly. However, it is highly unlikely that DREX induces full reprogramming of somatic nuclei. Nevertheless, the use of DREX offers the possibility of applying the powerful genetics techniques developed in Drosophila to the analysis of factors and mechanisms involved in chromatin remodeling during this essential process.
Materials and Methods
Antibodies
Rabbit αdBigH1 antibodies are described in29 (1:5000 (WB), 1:4000 (IF)). Rabbit αdH1 antibodies were kindly provided by Dr. J. Kadonaga and are described in55 (1:20000 (WB), 1:4000 (IF)). Rat αHP1a antibodies are described in56 (1:10000 (WB), 1:400 (IF)). The rest of antibodies were commercially available: rabbit αH4 (Abcam ab10158, 1:15000 (WB)), rabbit αH3K4me3 (Abcam ab8580, 1:2000 (WB)), rabbit αH3Ac (Mill 06-599, 1:20000 (WB)), mouse αH3K9me2 (Abcam ab1220, ChIP 2 μl), rabbit αH3K9me3 (Mill 07-442, 1:75 (IF)), rabbit αPol II Ser2P (Abcam ab5095, 1:5000 (WB)), rabbit αPol II Ser5P (Abcam ab5131, 1:5000 (WB)), and mouse αlamin (DSHB ADL67.10, 1:1000 (WB)). Jackson and ThermoFisher commercial secondary antibodies were used for immunofluorescence, while IRDye 680LT and 800CW conjugates (LI-COR) and horseradish peroxidase-coupled antibody (Jackson) were used for WB detection.
Incubation in DREX and cellular fractionation
DREX was prepared in Exb50 buffer (10 mM HEPES pH 7.6, 50 mM KCl, 1.5 mM MgCl2, 0.5 mM EGTA pH 8, 10 mM β-glicerophosphate, 10% Glycerol), as described in57. S2 cells were maintained in Schneider medium at 25 °C. Nuclei were isolated using Dounce homogenizer and Buffer A containing: 0.23 M sucrose, 15 mM Tris pH 7.4, 60 mM KCl, 0.25 mM MgCl2, 15 mM NaCl, 0.15 M spermine, 0.5 M spermidine, 0.2 mM PMSF, 14 mM β-MetOH. Purified nuclei were incubated in DREX for the indicated times. In control experiments, nuclei were incubated under the same experimental conditions in Exb50 buffer. After incubation nuclear fractionation was performed. Nuclear pellet was washed in Exb50 buffer and then lysed for 30 min in 10 mM HEPES pH 7.9, 3 mM EDTA, 0.2 mM EGTA, 1 mM DTT, Protease Inhibitor Cocktail. Centrifugation was carried out at 3000 g for 5 min resulting in supernatant (soluble nuclear fraction) and in pellet (chromatin).
Immunostaining experiments
For immunostaining experiments nuclei incubated in DREX were washed, resuspended in PBS and placed on concanavalin slides for 30 min. Fixation was performed for 15 min in 4% paraformaldehyde, followed by washing in PBS. Nuclei were permeabilized in PBS with 0.3% Triton, and blocked in: PBS, 0.3% Triton, 2% BSA. Primary antibody incubation was performed over-night in PBS-T/BSA and appropriate secondary antibody incubation for 1 h. Slides were mounted in Mowiol (Calbiochem-Novabiochem) containing 0.2 ng/ml DAPI (Sigma), visualized in a Leica TCS SPE confocal microscope, and analyzed using FIJI software.
ChIP experiments
For preparing chromatin for ChIP, crosslinking of DREX-incubated and control nuclei was performed in 1.8% formaldehyde for 10 min at room temperature. Glycin (125 mM) was added to stop the reaction. Nuclei were washed with PBS, Wash Buffer A (10 mM HEPES pH 7.9, 10 mM EDTA, 0.5 mM EGTA and 0.25% Triton X-100) and Wash Buffer B (10 mM HEPES pH 7.9, 100 mM NaCl, 1 mM EDTA, 0.5 mM EGTA, 0.01% Triton X-100). The pellet was then resuspended in TE (10 mM Tris-HCl pH 8, 1 mM EDTA) and 1% SDS was added, followed by centrifugation at 3300 g/10 min, at 4 °C. TE wash was performed. Then TE buffer with 0.1% SDS and 1 mM PMSF was added. Sonication was performed in 15-ml tubes in Bioruptor sonicator where 26 sonication cycles of 30 s ON/30 s OFF were performed at high intensity. To check the size of the sonicated DNA part of the sample was checked on an agarose gel after de-crosslinking. In continuation, 1% Triton X-100, 0.1% Deoxycholate and 140 mM NaCl were added. Preclearing of chromatin samples was performed with Protein A sepharose for 1 h, followed by addition of antibody and overnight incubation at 4 °C. Incubation was continued for additional 4 h upon Protein A sepharose addition. Five washes with RIPA buffer (140 mM NaCl, 10 mM Tris-HCl pH 8, 1 mM EDTA, 1% Triton X-100, 0.1% SDS, 0.1% Deoxycholate), one wash with LiCl ChIP buffer (250 mM LiCl, 10 mM Tris-HCl pH 8, 1 mM EDTA, 0.5% NP-40 and 0.5% Deoxycholate) and two washes with TE buffer were performed. Samples were RNAse-treated. De-crosslinking was performed overnight at 65 °C upon addition of 0.1 M NaHCO3 and 1% SDS. In continuation, samples were treated with Proteinase K and DNA extraction with Phenol–Chloroform followed by EtOH precipitation was performed.
For ChIP-qPCR, triplicates were subjected to real-time PCR using SYBR Green I Master Mix and LightCycler® 480 Instrument (Roche). Percentages of immunoprecipitated material were calculated by the ΔΔCt method. Primers used in these experiments are listed in Supplementary Table S1.
Data availability
All data generated or analysed during this study are included in this published article (and its Supplementary Information files).
References
Dimitrov, S. & Wolffe, A. P. Remodeling somatic nuclei in Xenopus laevis egg extracts: molecular mechanisms for the selective release of histones HI and HI° from chromatin and the acquisition of transcriptional competence. EMBO J 15, 5897–906 (1996).
Miyamoto, K. et al. Reprogramming events of mammalian somatic cells induced by Xenopus laevis egg extracts. Mol Reprod Dev 74, 1268–1277 (2007).
Collas, P. Nuclear reprogramming in cell-free extracts. Philos Trans R Soc Lond B Biol Sci 358, 1389–95 (2003).
Jaenisch, R. & Young, R. Stem cells, the molecular circuitry of pluripotency and nuclear reprogramming. Cell 132, 567–82 (2008).
Jullien, J., Pasque, V., Halley-Stott, R. P., Miyamoto, K. & Gurdon, J. B. Mechanisms of nuclear reprogramming by eggs and oocytes: a deterministic process? Nat Rev Mol Cell Biol 12, 453–9 (2011).
Pasque, V., Miyamoto, K. & Gurdon, J. B. Efficiencies and mechanisms of nuclear reprogramming. Cold Spring Harb Symp Quant Biol 75, 189–200 (2010).
Yamanaka, S. & Blau, H. M. Nuclear reprogramming to a pluripotent state by three approaches. Nature 465, 704–12 (2010).
Jullien, J., Astrand, C., Halley-Stott, R. P., Garrett, N. & Gurdon, J. B. Characterization of somatic cell nuclear reprogramming by oocytes in which a linker histone is required for pluripotency gene reactivation. Proc Natl Acad Sci USA 107, 5483–8 (2010).
Maki, N. et al. Oocyte-type linker histone B4 is required for transdifferentiation of somatic cells in vivo. FASEB J 24, 3462–67 (2010).
Crevel, G. & Cotterill, S. DNA replication in cell-free extracts from Drosophila melanogaster. EMBO J 10, 4361–9 (1991).
Becker, P. B., Tsukiyama, T. & Wu, C. Chromatin assembly extracts from Drosophila embryos. Methods Cell Biol 44, 207–23 (1994).
Becker, P. B. & Wu, C. Cell-free system for assembly of transcriptionally repressed chromatin from Drosophila embryos. Mol Cell Biol 12, 2241–9 (1992).
Clausell, J., Happel, N., Hale, T. K., Doenecke, D. & Beato, M. Histone H1 subtypes differentially modulate chromatin condensation without preventing ATP-dependent remodeling by SWI/SNF or NURF. PLoS One 4, e0007243 (2009).
Kawasaki, K., Philpott, A., Avilion, A. A., Berrios, M. & Fisher, P. A. Chromatin decondensation in Drosophila embryo extracts. J Biol Chem 269, 10169–76 (1994).
Berrios, M. & Avilion, A. A. Nuclear formation in a Drosophila cell-free system. Exp Cell Res 191, 64–70 (1990).
Ulitzur, N. & Gruenbaum, Y. Nuclear envelope assembly around sperm chromatin in cell-free preparations from Drosophila embryos. FEBS Lett 259, 113–6 (1989).
Ulitzur, N., Harel, A., Goldberg, M., Feinstein, N. & Gruenbaum, Y. Nuclear membrane vesicle targeting to chromatin in a Drosophila embryo cell-free system. Mol Biol Cell 8, 1439–48 (1997).
Telley, I. A., Gáspár, I., Ephrussi, A. & Surrey, T. A single Drosophila embryo extract for the study of mitosis ex vivo. Nat Protoc 8, 310–24 (2013).
Jullien, J. et al. Hierarchical molecular events driven by oocyte-specific factors lead to rapid and extensive reprogramming. Mol Cell 55, 524–36 (2014).
Teranishi, T. et al. Rapid replacement of somatic linker histones with the oocyte-specific linker histone H1foo in nuclear transfer. Dev Biol 266, 76–86 (2004).
Yun, Y., Zhao, G. M., Wu, S. J., Li, W. & Lei, A. M. Replacement of H1 linker histone during bovine somatic cell nuclear transfer. Theriogenology 78, 1371–80 (2012).
Gao, S. et al. Rapid H1 linker histone transitions following fertilization or somatic cell nuclear transfer: evidence for a uniform developmental program in mice. Dev Biol 266, 62–75 (2004).
Happel, N. & Doenecke, D. Histone H1 and its isoforms: contribution to chromatin structure and function. Gene 431, 1–12 (2009).
Izzo, A., Kamieniarz, K. & Schneider, R. The histone H1 family: specific members, specific functions? Biol Chem 389, 333–43 (2008).
Pérez-Montero, S., Carbonell, A. & Azorín, F. Germline-specific H1 variants: the “sexy” linker histones. Chromosoma 125, 1–13 (2016).
Bayona-Feliu, A. et al. Lessons from Drosophila. Biochim Biophys Acta 1859, 526–32 (2016).
Lifton, R. P., Goldberg, M. L., Karp, R. W. & Hogness, D. S. The organization of the histone cluster in Drosophila melanogaster: Functional and evolutionary implications. Cold Spring Harb. Symp Quant Biol 42, 1047–51 (1978).
Nagel, S. & Grossbach, U. Histone H1 genes and histone clusters in the genus. Drosophila. J Mol Evol 51, 286–98 (2000).
Pérez-Montero, S., Carbonell, A., Morán, T., Vaquero, A. & Azorín, F. The embryonic linker histone H1 variant of Drosophila, dBigH1, regulates zygotic genome activation. Dev Cell 26, 578–90 (2013).
Adenot, P. G. et al. Somatic linker histone H1 is present throughout mouse embryogenesis and is not replaced by variant H10. J Cell Sci 113, 2897–907 (2000).
Bordignon, V., Clarke, H. J. & Smith, L. C. Developmentally regulated loss and reappearance of immunoreactive somatic histone H1 on chromatin of bovine morula-stage nuclei following transplantation into oocytes. Biol Reprod 61, 22–30 (1999).
Bernstein, B. E. et al. A bivalent chromatin structure marks key developmental genes in embryonic stem cells. Cell 125, 315–26 (2006).
Koche, R. P. et al. Reprogramming factor expression initiates widespread targeted chromatin remodeling. Cell Stem Cell 8, 96–105 (2011).
Maherali, N. et al. Directly reprogrammed fibroblasts show global epigenetic remodeling and widespread tissue contribution. Cell Stem Cell 1, 55–70 (2007).
Mikkelsen, T. S. et al. Dissecting direct reprogramming through integrative genomic analysis. Nature 454, 49–55 (2008).
Newmeyer, D. D., Farschon, D. M. & Reed, J. C. Cell-free apoptosis in Xenopus egg extracts: Inhibition by Bcl-2 and requirement for an organelle fraction enriched in mitochondria. Cell 79, 353–364 (1994).
Hayakawa, K., Ohgane, J., Tanaka, S., Yagi, S. & Shiota, K. Oocyte-specific linker histone H1foo is an epigenomic modulator that decondenses chromatin and impairs pluripotency. Epigenetics 7, 1029–36 (2012).
Shinagawa, T. et al. Histone variants enriched in oocytes enhance reprogramming to induced pluripotent stem cells. Cell Stem Cell 14, 217–27 (2014).
Saeki, H. et al. Linker histone variants control chromatin dynamics during early embryogenesis. Proc Natl Acad Sci USA 102, 5697–702 (2005).
Mattout, A., Biran, A. & Meshorer, E. Global epigenetic changes during somatic cell reprogramming to iPS cells. J Mol Cell Biol 3, 341–50 (2011).
Efroni, S. et al. Global transcription in pluripotent embryonic stem cells. Cell Stem Cell 2, 437–47 (2008).
Hawkins, R. D. et al. Distinct epigenomic landscapes of pluripotent and lineage-committed human cells. Cell Stem Cell 6, 479–91 (2010).
Krejcí, J. et al. Genome-wide reduction in H3K9 acetylation during human embryonic stem cell differentiation. J Cell Physiol 219, 677–87 (2009).
Li, X. et al. The histone acetyltransferase MOF is a key regulator of the embryonic stem cell core transcriptional network. Cell Stem Cell 11, 163–78 (2012).
Meshorer, E. et al. Hyperdynamic plasticity of chromatin proteins in pluripotent embryonic stem cells. Dev Cell 10, 105–16 (2006).
Biddle, A., Simeoni, I. & Gurdon, J. B. Xenopus oocytes reactivate muscle gene transcription in transplanted somatic nuclei independently of myogenic factors. Development 136, 2695–703 (2009).
Aoto, T., Saitoh, N., Ichimura, T., Niwa, H. & Nakao, M. Nuclear and chromatin reorganization in the MHC-Oct3/4 locus at developmental phases of embryonic stem cell differentiation. Dev Biol 298, 354–67 (2006).
Kobayakawa, S., Miike, K., Nakao, M. & Abe, K. Dynamic changes in the epigenomic state and nuclear organization of differentiating mouse embryonic stem cells. Genes Cells 12, 447–60 (2007).
Meshorer, E. & Misteli, T. Chromatin in pluripotent embryonic stem cells and differentiation. Nat Rev Mol Cell Biol 7, 540–6 (2006).
Park, S. H. et al. Ultrastructure of human embryonic stem cells and spontaneous and retinoic acid-induced differentiating cells. Ultrastruct Pathol 28, 229–38 (2004).
Mizusawa, Y. et al. Expression of human oocyte-specific linker histone protein and its incorporation into sperm chromatin during fertilization. Fertil Steril 93, 1134–41 (2010).
Giorgetti, L., Castiglione, M., Martini, G. & Geri, C. Methylated DNA sequence extrusion during plant early meiotic prophase. Caryologia 60, 279–89 (2007).
Constantinescu, D., Gray, H. L., Sammak, P. J., Schatten, G. P. & Csoka, A. B. Lamin A/C expression is a marker of mouse and human embryonic stem cell differentiation. Stem Cells 24, 177–85 (2006).
Maus, N., Stuurman, N. & Fisher, P. A. Disassembly of the Drosophila nuclear lamina in a homologous cell-free system. J Cell Sci 108, 2027–35 (1995).
Vujatovic, O. et al. Drosophila melanogaster linker histone dH1 is required for transposon silencing and to preserve genome integrity. Nucleic Acids Res 40, 5402–14 (2012).
Font-Burgada, J., Rossell, D., Auer, H. & Azorin, F. Drosophila HP1c isoform interacts with the zinc-finger proteins WOC and Relative-of-WOC (ROW) to regulate gene expression. Genes Dev 22, 3007–23 (2008).
Bonte, E. & Becker, B. Preparation of chromatin assembly extracts from preblastoderm Drosophila embryos. Methods Mol Biol 523, 1–10 (1999).
Acknowledgements
We are thankful to Miloš Tatarski for help with the preparation of DREX and to Dr. J. Kadonaga for αdH1 antibodies. We are also thankful to Dr. J. Bernués for helpful discussions and advice. This work was supported by grants from MINECO (BFU2015-65082-P), the Generalitat de Catalunya (SGR2014-204), and the European Community FEDER program. This work was carried out within the framework of the “Centre de Referència en Biotecnologia” of the Generalitat de Catalunya. EŠ acknowledges receipt of a NEWFELPRO Fellowship of the Croatian Government and Ministry of Science and Education within EU FP7 Programme framework.
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F.A. and E.Š. designed the research, analyzed the data and wrote the manuscript. E.Š. performed most of the experiments, J.F.-M. prepared the DREX and A.C. performed experiments described in Figure 2d during revision of the manuscript. All authors have participated in data interpretation and discussion. All authors have read and approved the final manuscript.
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Šatović, E., Font-Mateu, J., Carbonell, A. et al. Chromatin remodeling in Drosophila preblastodermic embryo extract. Sci Rep 8, 10927 (2018). https://doi.org/10.1038/s41598-018-29129-8
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DOI: https://doi.org/10.1038/s41598-018-29129-8
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