Epigenetics Podcast

In this episode of the Epigenetics Podcast, we caught up with Paul Shiels from the University of Glasgow to talk about his work on the effects of environmental cues on the epigenome and longevity. Paul Shiels and his team focus on the question on how age related health is influenced by the environment. Factors like the socio-economic position, nutrition, lifestyle and the environment can influence the microbiome and the inflammation burden on the body which in turn can alter individual trajectories of ageing and health. The lab also tries to understand the epigenetic, molecular and cellular mechanisms that link the exposome to chronic age related diseases of older people. They have shown that (1)  imbalanced nutrition is associated with a microbiota-mediated accelerated ageing in the general population, (2) a significantly higher abundance of circulatory pathogenic bacteria is found in the most biologically aged, while those less biologically aged possess more circulatory salutogenic bacteria with a capacity to metabolise and produce cytoprotective Nrf2 agonists, (3) those at lower socioeconomic position possess significantly lower betaine levels indicative of a poorer diet and poorer health span and consistent with reduced global DNA methylation levels in this group.   References Harris, S. E., Deary, I. J., MacIntyre, A., Lamb, K. J., Radhakrishnan, K., Starr, J. M., Whalley, L. J., & Shiels, P. G. (2006). The association between telomere length, physical health, cognitive ageing, and mortality in non-demented older people. Neuroscience Letters, 406(3), 260–264. https://doi.org/10.1016/j.neulet.2006.07.055 Paul G. Shiels, Improving Precision in Investigating Aging: Why Telomeres Can Cause Problems, The Journals of Gerontology: Series A, Volume 65A, Issue 8, August 2010, Pages 789–791, https://doi.org/10.1093/gerona/glq095 Mafra D, Ugochukwu SA, Borges NA, et al. Food for healthier aging: power on your plate. Critical Reviews in Food Science and Nutrition. 2022 Aug:1-14. DOI: 10.1080/10408398.2022.2107611. PMID: 35959705. Shiels PG, Stenvinkel P, Kooman JP, McGuinness D. Circulating markers of ageing and allostatic load: A slow train coming. Practical Laboratory Medicine. 2017 Apr;7:49-54. DOI: 10.1016/j.plabm.2016.04.002. PMID: 28856219; PMCID: PMC5574864.   Related Episodes Transposable Elements in Gene Regulation and Evolution (Marco Trizzino) Epigenetic Clocks and Biomarkers of Ageing (Morgan Levine) Aging and Epigenetics (Peter Tessarz)   Contact Epigenetics Podcast on Twitter Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Active Motif on Twitter Active Motif on LinkedIn Email: [email protected]

In this episode of the Epigenetics Podcast, we caught up with Sarah Kimmins from Université de Montreal to talk about her work on the epigenetics of human sperm cells. The focus of Sarah Kimmins and her lab is how sperm and offspring health is impacted by the father's environment. The core of this is the sperm epigenome, which has been implicated in complex diseases such as infertility, cancer, diabetes, schizophrenia and autism. The Kimmins lab is interested which players play a role in this and came across the Histone post-translational modification H3K4me3. In this interview we talk about how the father's life choices can impact offspring health, which can also be inherited transgenerationally and how this can be used to develop intervention strategies to improve child and adult health.   References Siklenka, K., Erkek, S., Godmann, M., Lambrot, R., McGraw, S., Lafleur, C., Cohen, T., Xia, J., Suderman, M., Hallett, M., Trasler, J., Peters, A. H., & Kimmins, S. (2015). Disruption of histone methylation in developing sperm impairs offspring health transgenerationally. Science (New York, N.Y.), 350(6261), aab2006. https://doi.org/10.1126/science.aab2006 Lismer, A., Siklenka, K., Lafleur, C., Dumeaux, V., & Kimmins, S. (2020). Sperm histone H3 lysine 4 trimethylation is altered in a genetic mouse model of transgenerational epigenetic inheritance. Nucleic acids research, 48(20), 11380–11393. https://doi.org/10.1093/nar/gkaa712 Lismer, A., Dumeaux, V., Lafleur, C., Lambrot, R., Brind'Amour, J., Lorincz, M. C., & Kimmins, S. (2021). Histone H3 lysine 4 trimethylation in sperm is transmitted to the embryo and associated with diet-induced phenotypes in the offspring. Developmental cell, 56(5), 671–686.e6. https://doi.org/10.1016/j.devcel.2021.01.014   Related Episodes H3K4me3, SET Proteins, Isw1, and their Role in Transcription (Jane Mellor) The Effects of Early Life Stress on Mammalian Development (Catherine J. Peña) DNA Methylation and Mammalian Development (Déborah Bourc'his)   Contact Epigenetics Podcast on Twitter Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Active Motif on Twitter Active Motif on LinkedIn Email: [email protected].com

In this episode of the Epigenetics Podcast, we caught up with Peter Sarkies from University of Oxford Biochemistry to talk about his work on Transgenerational Inheritance of Epimutations. The team in the Sarkies lab focuses on investigating the connections between epigenetic gene regulation and evolution. The lab performs evolution experiments in the nematode C. elegans to determine if evolution can be influenced by epigenetic differences between individuals in a given population when no changes in the underlying DNA sequence are observed. A second area of interest of the team is evolution of piRNAs, which are present in metazoans but have been lost in nematodes during evolution.   References The Selfish Gene Sarkies, P., & Miska, E. A. (2013). Is There Social RNA? Science, 341(6145), 467–468. https://doi.org/10.1126/science.1243175 Beltran, T., Shahrezaei, V., Katju, V., & Sarkies, P. (2020). Epimutations driven by small RNAs arise frequently but most have limited duration in Caenorhabditis elegans. Nature ecology & evolution, 4(11), 1539–1548. https://doi.org/10.1038/s41559-020-01293-z Beltran, T., Pahita, E., Ghosh, S., Lenhard, B., & Sarkies, P. (2021). Integrator is recruited to promoter-proximally paused RNA Pol II to generate Caenorhabditis elegans piRNA precursors. The EMBO journal, 40(5), e105564. https://doi.org/10.15252/embj.2020105564   Related Episodes The Role of Small RNAs in Transgenerational Inheritance in C. elegans (Oded Rechavi) Epigenetic Influence on Memory Formation and Inheritance (Isabelle Mansuy)   Contact Epigenetics Podcast on Twitter Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Active Motif on Twitter Active Motif on LinkedIn Email: [email protected]

In this episode of the Epigenetics Podcast, we caught up with Karen Arndt from the University of Pittsburgh to talk about her work on transcription elongation control by the Paf1 complex. Karen Arndt and her lab investigate the process of transcriptional elongation and how RNA polymerase II overcomes obstacles like nucleosomes. One of the proteins that helps overcome those obstacles is the Paf1 complex. This complex associates with the transcribing polymerase and helps in modifying the chromatin template by ubiquitinating Histone H2B and methylating Histone H3.   References Squazzo, S. L., Costa, P. J., Lindstrom, D. L., Kumer, K. E., Simic, R., Jennings, J. L., Link, A. J., Arndt, K. M., & Hartzog, G. A. (2002). The Paf1 complex physically and functionally associates with transcription elongation factors in vivo. The EMBO journal, 21(7), 1764–1774. https://doi.org/10.1093/emboj/21.7.1764 Van Oss, S. B., Shirra, M. K., Bataille, A. R., Wier, A. D., Yen, K., Vinayachandran, V., Byeon, I. L., Cucinotta, C. E., Héroux, A., Jeon, J., Kim, J., VanDemark, A. P., Pugh, B. F., & Arndt, K. M. (2016). The Histone Modification Domain of Paf1 Complex Subunit Rtf1 Directly Stimulates H2B Ubiquitylation through an Interaction with Rad6. Molecular cell, 64(4), 815–825. https://doi.org/10.1016/j.molcel.2016.10.008 Cucinotta, C. E., Hildreth, A. E., McShane, B. M., Shirra, M. K., & Arndt, K. M. (2019). The nucleosome acidic patch directly interacts with subunits of the Paf1 and FACT complexes and controls chromatin architecture in vivo. Nucleic acids research, 47(16), 8410–8423. https://doi.org/10.1093/nar/gkz549 Hildreth, A. E., Ellison, M. A., Francette, A. M., Seraly, J. M., Lotka, L. M., & Arndt, K. M. (2020). The nucleosome DNA entry-exit site is important for transcription termination and prevention of pervasive transcription. eLife, 9, e57757. https://doi.org/10.7554/eLife.57757   Related Episodes Targeting COMPASS to Cure Childhood Leukemia (Ali Shilatifard) H3K4me3, SET Proteins, Isw1, and their Role in Transcription (Jane Mellor)   Contact Epigenetics Podcast on Twitter Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Active Motif on Twitter Active Motif on LinkedIn Email: [email protected]

In this episode of the Epigenetics Podcast, we caught up with Karim-Jean Armache from New York University - Grossman School of Medicine to talk about his work on the structural analysis of Polycomb Complex Proteins and molecular mechanisms of chromatin modifying enzymes. Karim-Jean Armache started his research career with the structural characterization of the 12-subunit RNA Polymerase II. After starting his own lab he used this knowledge in x-ray crystallography and electron microscopy to study how gene silencing complexes like the PRC complex act on chromatin and influence transcription. Further work in the Armache Lab focused on Dot, a  histone H3K79 methyltransferase, and how it acts on chromatin, as well as how it is regulated by Histone-Histone crosstalk. References Armache, K. J., Garlick, J. D., Canzio, D., Narlikar, G. J., & Kingston, R. E. (2011). Structural basis of silencing: Sir3 BAH domain in complex with a nucleosome at 3.0 Å resolution. Science (New York, N.Y.), 334(6058), 977–982. https://doi.org/10.1126/science.1210915 Lee, C. H., Holder, M., Grau, D., Saldaña-Meyer, R., Yu, J. R., Ganai, R. A., Zhang, J., Wang, M., LeRoy, G., Dobenecker, M. W., Reinberg, D., & Armache, K. J. (2018). Distinct Stimulatory Mechanisms Regulate the Catalytic Activity of Polycomb Repressive Complex 2. Molecular cell, 70(3), 435–448.e5. https://doi.org/10.1016/j.molcel.2018.03.019 De Ioannes, P., Leon, V. A., Kuang, Z., Wang, M., Boeke, J. D., Hochwagen, A., & Armache, K. J. (2019). Structure and function of the Orc1 BAH-nucleosome complex. Nature communications, 10(1), 2894. https://doi.org/10.1038/s41467-019-10609-y Valencia-Sánchez, M. I., De Ioannes, P., Wang, M., Truong, D. M., Lee, R., Armache, J. P., Boeke, J. D., & Armache, K. J. (2021). Regulation of the Dot1 histone H3K79 methyltransferase by histone H4K16 acetylation. Science (New York, N.Y.), 371(6527), eabc6663. https://doi.org/10.1126/science.abc6663   Related Episodes Transcription and Polycomb in Inheritance and Disease (Danny Reinberg) From Nucleosome Structure to Function (Karolin Luger) Oncohistones as Drivers of Pediatric Brain Tumors (Nada Jabado)   Contact Epigenetics Podcast on Twitter Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Active Motif on Twitter Active Motif on LinkedIn eMail: [email protected]

In this episode of the Epigenetics Podcast, we caught up with Sarah Kinkley from the Max Planck Institute of Molecular Genetics to talk about her work on PHF13 and its role in chromatin and transcription. The Kinkley laboratory focuses mainly on unraveling the mechanism of action of the transcription factor PHF13 (PHC Finger Protein 13). PHF13 is a reader of the epigenetic mark H3K4 trimethylation which influences higher chromatin order, transcriptional regulation, and differentiation. The lab has shown that PHF13 plays a crucial role in phase separation and mitotic chromatin compaction.   References Kinkley, S., Staege, H., Mohrmann, G., Rohaly, G., Schaub, T., Kremmer, E., Winterpacht, A., & Will, H. (2009). SPOC1: a novel PHD-containing protein modulating chromatin structure and mitotic chromosome condensation. Journal of cell science, 122(Pt 16), 2946–2956. https://doi.org/10.1242/jcs.047365 Chung, H. R., Xu, C., Fuchs, A., Mund, A., Lange, M., Staege, H., Schubert, T., Bian, C., Dunkel, I., Eberharter, A., Regnard, C., Klinker, H., Meierhofer, D., Cozzuto, L., Winterpacht, A., Di Croce, L., Min, J., Will, H., & Kinkley, S. (2016). PHF13 is a molecular reader and transcriptional co-regulator of H3K4me2/3. eLife, 5, e10607. https://doi.org/10.7554/eLife.10607 Connecting the Dots: PHF13 and cohesin promote polymer-polymer phase separation of chromatin into chromosomes. Francesca Rossi, Rene Buschow, Laura V. Glaser, Tobias Schubert, Hannah Staege, Astrid Grimme, Hans Will, Thorsten Milke, Martin Vingron, Andrea M. Chiariello, Sarah Kinkley. bioRxiv 2022.03.04.482956; doi: https://doi.org/10.1101/2022.03.04.482956   Related Episodes The Role of Blimp-1 in Immune-Cell Differentiation (Erna Magnúsdóttir) H3K4me3, SET Proteins, Isw1, and their Role in Transcription (Jane Mellor) The Role of SMCHD1 in Development and Disease (Marnie Blewitt)   Contact Epigenetics Podcast on Twitter Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Active Motif on Twitter Active Motif on LinkedIn Email: [email protected]

In this episode of the Epigenetics Podcast, we caught up with Akis Papantonis from the University Medical Center Göttingen to talk about his work on genome organisation mediated by RNA Polymerase II. The research of the Papantonis Laboratory focuses on investigating how environmental signalling stimuli are integrated by chromatin to control homeostatic to deregulated functional transitions. In more detail, the team is interested in how dynamic higher-order regulatory networks are influenced by the underlying linear DNA fiber. The ultimate goal of the laboratory is to understand general rules governing transcriptional and chromatin homeostasis and finally, how those rules might affect development, ageing or malignancies.   References Larkin, J. D., Cook, P. R., & Papantonis, A. (2012). Dynamic reconfiguration of long human genes during one transcription cycle. Molecular and cellular biology, 32(14), 2738–2747. https://doi.org/10.1128/MCB.00179-12 Diermeier, S., Kolovos, P., Heizinger, L., Schwartz, U., Georgomanolis, T., Zirkel, A., Wedemann, G., Grosveld, F., Knoch, T. A., Merkl, R., Cook, P. R., Längst, G., & Papantonis, A. (2014). TNFα signalling primes chromatin for NF-κB binding and induces rapid and widespread nucleosome repositioning. Genome biology, 15(12), 536. https://doi.org/10.1186/s13059-014-0536-6 Sofiadis, K., Josipovic, N., Nikolic, M., Kargapolova, Y., Übelmesser, N., Varamogianni-Mamatsi, V., Zirkel, A., Papadionysiou, I., Loughran, G., Keane, J., Michel, A., Gusmao, E. G., Becker, C., Altmüller, J., Georgomanolis, T., Mizi, A., & Papantonis, A. (2021). HMGB1 coordinates SASP-related chromatin folding and RNA homeostasis on the path to senescence. Molecular systems biology, 17(6), e9760. https://doi.org/10.15252/msb.20209760 Enhancer-promoter contact formation requires RNAPII and antagonizes loop extrusion. Shu Zhang, Nadine Übelmesser, Mariano Barbieri, Argyris Papantonis. bioRxiv 2022.07.04.498738; doi: https://doi.org/10.1101/2022.07.04.498738   Related Episodes Chromatin Organization During Development and Disease (Marieke Oudelaar) Biophysical Modeling of 3-D Genome Organization (Leonid Mirny) Hi-C and Three-Dimensional Genome Sequencing (Erez Lieberman Aiden)   Contact Epigenetics Podcast on Twitter Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Active Motif on Twitter Active Motif on LinkedIn Email: [email protected]

In this episode of the Epigenetics Podcast, we caught up with Melissa Harrison from the University of Wisconsin-Madison to talk about her work on the “Pioneer” Transcription Factors - Zelda and Grainyhead - and their role at the maternal-to-zygotic transition. The Harrison lab studies how differentiation and development are driven by coordinated changes in gene expression. To do this, the targets of choice are the transcription factors Zelda and Grainyhead that bind to the genome at specific and crucial points in development and differentiation. These specialised transcription factors have the ability to bind to DNA in the context of nucleosomes which defines regulatory elements and leads to subsequent binding of additional classical transcription factors. These properties allow pioneer factors to act at the top of gene regulatory networks and control developmental transitions.   References Harrison, M. M., Botchan, M. R., & Cline, T. W. (2010). Grainyhead and Zelda compete for binding to the promoters of the earliest-expressed Drosophila genes. Developmental biology, 345(2), 248–255. https://doi.org/10.1016/j.ydbio.2010.06.026 Harrison, M. M., Li, X. Y., Kaplan, T., Botchan, M. R., & Eisen, M. B. (2011). Zelda binding in the early Drosophila melanogaster embryo marks regions subsequently activated at the maternal-to-zygotic transition. PLoS genetics, 7(10), e1002266. https://doi.org/10.1371/journal.pgen.1002266 McDaniel, S. L., Gibson, T. J., Schulz, K. N., Fernandez Garcia, M., Nevil, M., Jain, S. U., Lewis, P. W., Zaret, K. S., & Harrison, M. M. (2019). Continued Activity of the Pioneer Factor Zelda Is Required to Drive Zygotic Genome Activation. Molecular cell, 74(1), 185–195.e4. https://doi.org/10.1016/j.molcel.2019.01.014 McDaniel, S. L., & Harrison, M. M. (2019). Optogenetic Inactivation of Transcription Factors in the Early Embryo of Drosophila. Bio-protocol, 9(13), e3296. https://doi.org/10.21769/BioProtoc.3296 Larson, E.D., Komori, H., Gibson, T.J. et al. Cell-type-specific chromatin occupancy by the pioneer factor Zelda drives key developmental transitions in Drosophila. Nat Commun 12, 7153 (2021). https://doi.org/10.1038/s41467-021-27506-y   Related Episodes Pioneer Transcription Factors and Their Influence on Chromatin Structure (Ken Zaret)   Contact Epigenetics Podcast on Twitter Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Active Motif on Twitter Active Motif on LinkedIn Email: [email protected]

In this episode of the Epigenetics Podcast, we caught up with Elena Gomez-Diaz from the Institute of Parasitology and Biomedicine López-Neyra at the Spanish National Research Council. She share with us her work on the Epigenetics in Human Malaria Parasites. Elena Gómez-Díaz and her team are focusing on understanding how epigenetic processes are implicated in host-parasite interactions by regulating gene expression in the model of malaria. The team has started to investigate and uncover layers of chromatin regulation that control developmental transitions in Plasmodium falciparum, especially in the parts of the life cycle that take place in the mosquito. Furthermore, the lab has investigated epigenetic changes that are present in malaria-infected Anopheles mosquitos, this led to the identification of cis-regulatory elements and enhancer-promoter networks in response to infection.   References Gómez-Díaz E, Rivero A, Chandre F, Corces VG. Insights into the epigenomic landscape of the human malaria vector Anopheles gambiae. Front Genet. 2014 Aug 15;5:277. doi: 10.3389/fgene.2014.00277. PMID: 25177345; PMCID: PMC4133732. Gómez-Díaz, E., Yerbanga, R., Lefèvre, T. et al. Epigenetic regulation of Plasmodium falciparum clonally variant gene expression during development in Anopheles gambiae. Sci Rep 7, 40655 (2017). https://doi.org/10.1038/srep40655 José Luis Ruiz, Juan J Tena, Cristina Bancells, Alfred Cortés, José Luis Gómez-Skarmeta, Elena Gómez-Díaz, Characterization of the accessible genome in the human malaria parasite. Plasmodium falciparum, Nucleic Acids Research, Volume 46, Issue 18, 12 October 2018, Pages 9414–9431, https://doi.org/10.1093/nar/gky643 Women in Malaria 2021: A Conference Premier. (2021). Trends in Parasitology, 37(7), 573–580. https://doi.org/10.1016/j.pt.2021.04.001 Twitter Account: https://twitter.com/womeninmalaria   Related Episodes Multiple challenges of CUT&Tag (Cassidee McDonough, Kyle Tanguay) ATAC-Seq, scATAC-Seq and Chromatin Dynamics in Single-Cells (Jason Buenrostro)   Contact Epigenetics Podcast on Twitter Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Active Motif on Twitter Active Motif on LinkedIn Email: [email protected]

In this episode of the Epigenetics Podcast, we caught up with Nick Pervolarakis from Active Motif to talk about bioinformatic analysis in epigenetics research. While many “bench scientists” are familiar with the workflows of ChIP-Seq, ATAC-Seq and CUT&Tag, and even the preparation and analysis of the libraries, the steps between sequencing and fully analyzed data is sometimes thought of as a mystery known only to bioinformatic experts. Most of us have some understanding that the raw data is usually in a file format called a FASTQ. But how do we get from FASTQ files to peaks on a genome browser? This Podcast Episode will provide a peek behind the curtain of the informatic analysis we perform at Active Motif, as part of our end-to-end epigenetic services.   References Life in the FASTQ Lane Bioinformatics Resource Center Epigenetic Services   Related Episodes Multiple challenges of ATAC-Seq, Points to Consider (Yuan Xue) Multiple challenges of CUT&Tag (Cassidee McDonough, Kyle Tanguay) Multiple Challenges in ChIP (Adam Blattler)   Contact Active Motif on Twitter Epigenetics Podcast on Twitter Active Motif on LinkedIn Active Motif on Facebook Email: [email protected] c8dqseb1h2Zyf2blC15qkyPgu9sB5stin27nqhzP