In this episode, Professor Asim Surani, shares how his extensive research has significantly advanced the understanding of how the mammalian germline is specified, the mechanisms governing epigenetic reprogramming, and the critical conditions that maintain genomic integrity during early development. The discussion, led by Dr. Stefan Dillinger, provides an overview of Surani's journey into biology, the evolution of his research interests, and the pivotal discoveries that have shaped the field of epigenetics. Dr. Surani discusses the groundbreaking experiment he co-conducted in 1984 that led to the discovery of genomic imprinting. Initially a student involved in in vitro fertilization at Cambridge, he became intrigued by the implications of parthenogenesis in mammals. Challenging the prevailing cytoplasmic theory of development, Surani and his collaborators demonstrated that normal mammalian development requires contributions from both parental genomes, leading to the introduction of the concept of genomic imprinting—a term Surani defended to describe the phenomenon that he and his team observed. Surani's research then evolved toward understanding the mechanisms of genomic imprinting, particularly the role of DNA methylation. Throughout the interview, he details specific experiments that elucidated how genes could exhibit imprinted expression depending on the parental lineage, highlighting the importance of epigenetic factors in gene regulation. The revelation that DNA methylation marks were responsible for imprinting solidified the connection between genetic information and epigenetic influence in development. The conversation dives deeper into the mechanisms involved in germline specification and epigenetic reprogramming. Surani explains his transition into studying mammalian germline development and the intricacies of primordial germ cell specification. Working with his team, he utilized single-cell approaches to investigate gene expression profiles specific to germ cells, identifying critical factors like PRDM1 and PRDM14 that repress somatic gene programs while initiating germline-specific pathways. This work underscored the complex interplay of genetic and epigenetic factors that govern the development of germ cells. Another focus of the interview is the comparison of epigenetic resetting between mouse and human germlines. Surani addresses key differences in the timing and mechanisms of epigenetic reprogramming in humans, particularly the involvement of specific factors such as SOX17, which emerged as a crucial player in human germline specification, contrary to his earlier expectations. The discussion also highlights the technical challenges researchers face when studying human embryos due to ethical constraints, driving innovation in model systems such as stem cells to explore germline development.   References Surani MA, Barton SC, Norris ML. Development of reconstituted mouse eggs suggests imprinting of the genome during gametogenesis. Nature. 1984 Apr 5-11;308(5959):548-50. doi: 10.1038/308548a0. PMID: 6709062. Surani MA, Barton SC, Norris ML. Nuclear transplantation in the mouse: heritable differences between parental genomes after activation of the embryonic genome. Cell. 1986 Apr 11;45(1):127-36. doi: 10.1016/0092-8674(86)90544-1. PMID: 3955655. Ohinata Y, Payer B, O'Carroll D, Ancelin K, Ono Y, Sano M, Barton SC, Obukhanych T, Nussenzweig M, Tarakhovsky A, Saitou M, Surani MA. Blimp1 is a critical determinant of the germ cell lineage in mice. Nature. 2005 Jul 14;436(7048):207-13. doi: 10.1038/nature03813. Epub 2005 Jun 5. PMID: 15937476. Hajkova P, Ancelin K, Waldmann T, Lacoste N, Lange UC, Cesari F, Lee C, Almouzni G, Schneider R, Surani MA. Chromatin dynamics during epigenetic reprogramming in the mouse germ line. Nature. 2008 Apr 17;452(7189):877-81. doi: 10.1038/nature06714. Epub 2008 Mar 19. PMID: 18354397; PMCID: PMC3847605.   Related Episodes Epigenetic Reprogramming During Mammalian

In this episode of the Epigenetics Podcast, we talked with Petra Hajkova from the MRC Laboratory of Medical Sciences about her work on epigenetics research on mammalian development, highlighting DNA methylation, histone modifications, and TET enzymes, along with her journey in molecular genetics and future research on epigenetic maintenance. Dr. Hajkova's early work focused on DNA methylation and resulted in innovative collaboration that allowed her to develop bisulfide sequencing techniques. We discuss her transition to the UK, where she began working in Azim Surani's lab at the University of Cambridge. Dr. Hajkova describes the excitement of researching chromatin dynamics in the mouse germline, leading to significant findings published in Nature. Her story highlights the intense yet rewarding nature of postdoctoral research as she navigated the complexities of working with embryos for the first time. As her research progressed, Dr. Hajkova established her own lab at the MRC London Institute of Medical Sciences, where she became a professor in 2017. We delve into her investigations on the differences between embryonic stem cells and embryonic germ cells regarding their distinct developmental origins. Dr. Hajkova outlines the challenges she faced in understanding the mechanisms behind global DNA demethylation in germline cells and the role of hydroxymethylation during early development. The discussion further covers her exciting findings regarding the specific functions of TET enzymes and their regulatory roles in maintaining epigenetic states. We explore her recent research published in Nature, which provides insights into the transition from primordial germ cells to gonocytes, emphasizing the significance of various epigenetic mechanisms in germline development.   References Hajkova P, Ancelin K, Waldmann T, Lacoste N, Lange UC, Cesari F, Lee C, Almouzni G, Schneider R, Surani MA. Chromatin dynamics during epigenetic reprogramming in the mouse germ line. Nature. 2008 Apr 17;452(7189):877-81. doi: 10.1038/nature06714. Epub 2008 Mar 19. PMID: 18354397; PMCID: PMC3847605. Hajkova P, Jeffries SJ, Lee C, Miller N, Jackson SP, Surani MA. Genome-wide reprogramming in the mouse germ line entails the base excision repair pathway. Science. 2010 Jul 2;329(5987):78-82. doi: 10.1126/science.1187945. PMID: 20595612; PMCID: PMC3863715. Hill PWS, Leitch HG, Requena CE, Sun Z, Amouroux R, Roman-Trufero M, Borkowska M, Terragni J, Vaisvila R, Linnett S, Bagci H, Dharmalingham G, Haberle V, Lenhard B, Zheng Y, Pradhan S, Hajkova P. Epigenetic reprogramming enables the transition from primordial germ cell to gonocyte. Nature. 2018 Mar 15;555(7696):392-396. doi: 10.1038/nature25964. Epub 2018 Mar 7. PMID: 29513657; PMCID: PMC5856367. Huang TC, Wang YF, Vazquez-Ferrer E, Theofel I, Requena CE, Hanna CW, Kelsey G, Hajkova P. Sex-specific chromatin remodelling safeguards transcription in germ cells. Nature. 2021 Dec;600(7890):737-742. doi: 10.1038/s41586-021-04208-5. Epub 2021 Dec 8. PMID: 34880491.   Related Episodes Epigenetic Mechanisms of Mammalian Germ Cell Development (Mitinori Saitou) Epigenetic Reprogramming During Mammalian Development (Wolf Reik) DNA Methylation and Mammalian Development (Déborah Bourc'his)   Contact Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Dr. Stefan Dillinger on LinkedIn Active Motif on LinkedIn Active Motif on Bluesky Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Ani Deshpande from Sanford Burnham Prebys about his work on epigenetic regulation and developing small molecules through high throughput screens for AML. Throughout our discussion, we delve into Dr. Despande's journey into the field of biology and science, tracing his evolution from a literature enthusiast in Mumbai to a dedicated cancer researcher. He reflects on his formative experiences during his PhD at Ludwig Maximilian University in Munich, where she developed murine models for refractory acute myeloid leukemia (AML). We examine these models' contributions to therapeutic discovery and understanding the intricate mechanisms underscoring AML's complexities. Transitioning to his postdoctoral work at Scott Armstrong's lab in Boston, Dr. Despande shares his insights on the importance of epigenetic regulators, such as DOT1L, in leukemias, and how they can serve as strategic therapeutic targets. His ambitious pursuit of translational research is further highlighted through his efforts in developing a conditional knockout mouse model and his collaborative work utilizing CRISPR technology to refine our understanding of epigenetic regulation in cancer pathogenesis. Moreover, we engage in a conversation about the challenges and opportunities that arise when establishing his lab at Sanford Burnham Prebys. Dr. Despande candidly discusses the delicate balance between pursuing topics of genuine interest versus adhering to grant fundability, underlining the tension researchers face in the current scientific landscape. His emphasis on the critical need for innovation within lab settings serves as a motivational call for emerging scientists to venture beyond the established templates that often inhibit groundbreaking discoveries. We conclude our dialogue with an exploration of his recent projects, which involve targeting specific epigenetic modifiers and how his lab’s findings can contribute to greater understanding and potential treatments for not only AML but also other pediatric cancers driven by gene fusions. Dr. Despande's insights into the integration of modern technologies, such as CRISPR libraries, exemplify his commitment to pushing the boundaries of cancer research. In addition to discussing his scientific contributions, we touch upon Dr. Despande's foray into podcasting (The Discovery Dialogues), shedding light on his motivation to bridge the communication gap between scientists and the broader public. He articulates his desire to demystify scientific discoveries and promote awareness about the intricate journey of research that lays the groundwork for medical advancements. This multidimensional discussion not only highlights his scientific achievements but also emphasizes the importance of effective science communication in fostering public understanding and appreciation of research.   References Deshpande AJ, Cusan M, Rawat VP, Reuter H, Krause A, Pott C, Quintanilla-Martinez L, Kakadia P, Kuchenbauer F, Ahmed F, Delabesse E, Hahn M, Lichter P, Kneba M, Hiddemann W, Macintyre E, Mecucci C, Ludwig WD, Humphries RK, Bohlander SK, Feuring-Buske M, Buske C. Acute myeloid leukemia is propagated by a leukemic stem cell with lymphoid characteristics in a mouse model of CALM/AF10-positive leukemia. Cancer Cell. 2006 Nov;10(5):363-74. doi: 10.1016/j.ccr.2006.08.023. PMID: 17097559. Deshpande AJ, Deshpande A, Sinha AU, Chen L, Chang J, Cihan A, Fazio M, Chen CW, Zhu N, Koche R, Dzhekieva L, Ibáñez G, Dias S, Banka D, Krivtsov A, Luo M, Roeder RG, Bradner JE, Bernt KM, Armstrong SA. AF10 regulates progressive H3K79 methylation and HOX gene expression in diverse AML subtypes. Cancer Cell. 2014 Dec 8;26(6):896-908. doi: 10.1016/j.ccell.2014.10.009. Epub 2014 Nov 20. PMID: 25464900; PMCID: PMC4291116. Sinha S, Barbosa K, Cheng K, Leiserson MDM, Jain P, Deshpande A, Wilson DM 3rd, Ryan BM, Luo J, Ronai ZA, Lee JS, Deshpande AJ, Ruppin E. A systematic genome-wide ma

In this episode Dr. Raffaele Teperino shares insights from his ongoing research focused on developmental programming, particularly how paternal health before conception influences not only offspring health but also maternal health outcomes. As we trace his academic journey from studying biotechnology and pharmacology to leading his own lab, Dr. Teperino reflects on his early fascination with medicine, the pivotal experiences that shaped his career, and the integration of epigenetics into understanding metabolic diseases. We discuss the nuances of epigenetics—going beyond simple chromatin biology to examine its wider implications on phenotypic variation. Dr. Teperino emphasizes his approach of modeling relevant physiological phenomena in the lab to better understand the underlying mechanisms driving conditions like obesity and metabolic disruption. A particular focus is placed on his experiences during his postdoctoral years, where he investigated the developmental pathways of hedgehog signaling and its metabolic implications in adipogenesis. Our talk shifts towards the practical implications of his research, highlighting recent investigations into how circadian rhythms and paternal lifestyles influence offspring health. Dr. Teperino reveals his findings on how disturbances in circadian rhythms can lead to intergenerational health issues, showcasing the surprising effects observed in offspring of fathers experiencing circadian misalignment. We delve into the significance of seminal fluid as a potential medium for intergenerational transfer of stress responses, examining the role of stress hormones and their impacts on fetal development. As we explore a fascinating recent study highlighting the impact of paternal diets on future generations, Dr. Teperino underscores the importance of understanding the shorter exposure periods sufficient to trigger these health changes. He presents data that links paternal obesity and preconception health to an increased risk of obesity and insulin resistance in children, challenging traditional narratives around maternal responsibility for offspring health.   References Darr J, Tomar A, Lassi M, Gerlini R, Berti L, Hering A, Scheid F, Hrabě de Angelis M, Witting M, Teperino R. iTAG-RNA Isolates Cell-Specific Transcriptional Responses to Environmental Stimuli and Identifies an RNA-Based Endocrine Axis. Cell Rep. 2020 Mar 3;30(9):3183-3194.e4. doi: 10.1016/j.celrep.2020.02.020. PMID: 32130917. Lassi M, Tomar A, Comas-Armangué G, Vogtmann R, Dijkstra DJ, Corujo D, Gerlini R, Darr J, Scheid F, Rozman J, Aguilar-Pimentel A, Koren O, Buschbeck M, Fuchs H, Marschall S, Gailus-Durner V, Hrabe de Angelis M, Plösch T, Gellhaus A, Teperino R. Disruption of paternal circadian rhythm affects metabolic health in male offspring via nongerm cell factors. Sci Adv. 2021 May 26;7(22):eabg6424. doi: 10.1126/sciadv.abg6424. PMID: 34039610; PMCID: PMC8153725. Tomar A, Gomez-Velazquez M, Gerlini R, Comas-Armangué G, Makharadze L, Kolbe T, Boersma A, Dahlhoff M, Burgstaller JP, Lassi M, Darr J, Toppari J, Virtanen H, Kühnapfel A, Scholz M, Landgraf K, Kiess W, Vogel M, Gailus-Durner V, Fuchs H, Marschall S, Hrabě de Angelis M, Kotaja N, Körner A, Teperino R. Epigenetic inheritance of diet-induced and sperm-borne mitochondrial RNAs. Nature. 2024 Jun;630(8017):720-727. doi: 10.1038/s41586-024-07472-3. Epub 2024 Jun 5. PMID: 38839949; PMCID: PMC11186758.   Related Episodes The Impact of Paternal Diet on Offspring Metabolism (Upasna Sharma) Transgenerational Inheritance and Evolution of Epimutations (Peter Sarkies) The Role of Small RNAs in Transgenerational Inheritance in C. elegans (Oded Rechavi)   Contact Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Dr. Stefan Dillinger on LinkedIn Active Motif on LinkedIn Active Motif on Bluesky Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Dr. Frank Johannes from the Technical University of Munich in Freising about his work on evolutionary clocks and epigenetic inheritance in plants. In this episode we discuss Dr. Johannes pursuits in understanding how heritable epigenetic variations, particularly through DNA methylation, affect phenotypic diversity in plants. He shared insights about groundbreaking research initiatives he has led, including one of the first population epigenetic studies in plants that effectively linked heritable DNA methylation changes to critical traits like flowering time and root length. This work underscored the importance of epigenetic factors that extend beyond traditional genetic sequences, illustrating a significant shift in how we comprehend inheritance and trait variation in organisms. As we dug deeper into the science, we examined Dr. Johannes's innovative approaches to studying chromatin-based mechanisms of genome regulation, allowing for a nuanced understanding of epigenetic inheritance. His lab’s extensive phenotyping of Arabidopsis plants highlighted how inducing heritable variations in DNA methylation could lead to significant trait outcomes – results that have substantial implications for agriculture and understanding complex characteristics across generations. The dialogue continued to unravel the dynamics between forward and backward epimutations, delving into their heritable nature and their rapid accumulation compared to traditional genetic mutations. Dr. Johannes overturned conventional understanding by presenting epigenetic processes that are not as static as once thought, providing compelling evidence that these spontaneous changes could inform evolutionary clocks; a concept that offers new avenues for studying the relationships between species over relatively short timeframes. Moreover, we discussed the exciting concept of epigenetic clocks, which play a role in assessing the age of various species, including trees. The potential applications for such clocks in environmental management and the assessment of tree vitality further illuminated the practical impacts of Dr. Johannes's research. These insights also pave the way for sophisticated non-invasive methods of understanding plant biology, which can revolutionize forest management practices in the face of climate change and other ecological pressures.   References Colomé-Tatché M, Cortijo S, Wardenaar R, Morgado L, Lahouze B, Sarazin A, Etcheverry M, Martin A, Feng S, Duvernois-Berthet E, Labadie K, Wincker P, Jacobsen SE, Jansen RC, Colot V, Johannes F. Features of the Arabidopsis recombination landscape resulting from the combined loss of sequence variation and DNA methylation. Proc Natl Acad Sci U S A. 2012 Oct 2;109(40):16240-5. doi: 10.1073/pnas.1212955109. Epub 2012 Sep 17. PMID: 22988127; PMCID: PMC3479620. Cortijo S, Wardenaar R, Colomé-Tatché M, Gilly A, Etcheverry M, Labadie K, Caillieux E, Hospital F, Aury JM, Wincker P, Roudier F, Jansen RC, Colot V, Johannes F. Mapping the epigenetic basis of complex traits. Science. 2014 Mar 7;343(6175):1145-8. doi: 10.1126/science.1248127. Epub 2014 Feb 6. PMID: 24505129. van der Graaf A, Wardenaar R, Neumann DA, Taudt A, Shaw RG, Jansen RC, Schmitz RJ, Colomé-Tatché M, Johannes F. Rate, spectrum, and evolutionary dynamics of spontaneous epimutations. Proc Natl Acad Sci U S A. 2015 May 26;112(21):6676-81. doi: 10.1073/pnas.1424254112. Epub 2015 May 11. PMID: 25964364; PMCID: PMC4450394. Yao N, Zhang Z, Yu L, Hazarika R, Yu C, Jang H, Smith LM, Ton J, Liu L, Stachowicz JJ, Reusch TBH, Schmitz RJ, Johannes F. An evolutionary epigenetic clock in plants. Science. 2023 Sep 29;381(6665):1440-1445. doi: 10.1126/science.adh9443. Epub 2023 Sep 28. PMID: 37769069.   Related Episodes Transgenerational Inheritance and Epigenetic Imprinting in Plants (Mary Gehring) Epigenetic Clocks and Biomarkers of Ageing (Morgan Levine)   Contact Epigenetics

In this episode of the Epigenetics Podcast, we talked with Boyan Bonev from the HelmholtzZetrum in Munich about his work on neuroepigenetics, focusing on gene regulation, chromatin architecture, and primate epigenome evolution, This Episode focuses on Dr. Bonev’s recent research, particularly focusing on how chromatin architecture and gene regulation influence neural cell identity and function. He discusses his work investigating transcriptional activity in relation to chromatin insulation, highlighting a critical finding that induced expression of genes does not necessarily lead to chromatin insulation—a point that complicates prior assumptions about the relationship between gene expression and chromatin organization. This study aimed to determine the causal versus correlative aspects of chromatin architecture in brain development and links it to developmental processes and neurodevelopmental disorders. Building on his findings in gene regulation, Dr. Bonev elaborates on a significant study he conducted in his own lab, where he mapped the regulatory landscape of neural differentiation in the mouse neocortex. Here, he employed cutting-edge single-cell sequencing methodologies to analyze intricate gene and enhancer interactions, revealing that selective enhancer-promoter interactions are primarily cell-type specific. This nuanced understanding aids in deciphering the complexities associated with gene expression as it relates to neural stem cells and differentiated neurons, emphasizing the importance of single-cell analyses over bulk sequencing methods. Moreover, Dr. Bonev reveals a novel methodology developed in his lab that allows for the simultaneous assessment of spatial genome organization, chromatin accessibility, and DNA methylation at high resolution. This advancement not only reduces costs but also enhances the potential to correlate higher-dimensional genomic data with specific biological questions, fostering a more integrative approach to understanding genetic regulation. The discussion then shifts focus towards Dr. Bonev's recent project profiling primate epigenome evolution, where he investigated the 3D genome organization, chromatin accessibility, and gene expression among iPSCs and neural stem cells from various species, including humans, chimpanzees, gorillas, and macaques. In this research, he identifies trends related to transcription factor evolution and chromatin modifications across species. The insights gleaned from this work underscore the evolutionary significance of structural variations in the 3D genome, pointing to a possible link between chromatin dynamics and the evolutionary development of the primate brain.   References Bonev B, Mendelson Cohen N, Szabo Q, Fritsch L, Papadopoulos GL, Lubling Y, Xu X, Lv X, Hugnot JP, Tanay A, Cavalli G. Multiscale 3D Genome Rewiring during Mouse Neural Development. Cell. 2017 Oct 19;171(3):557-572.e24. doi: https://doi.org/10.1016/j.cell.2017.09.043. PMID: 29053968; PMCID: PMC5651218. Noack, F., Vangelisti, S., Raffl, G. et al. Multimodal profiling of the transcriptional regulatory landscape of the developing mouse cortex identifies Neurog2 as a key epigenome remodeler. Nat Neurosci 25, 154–167 (2022). https://doi.org/10.1038/s41593-021-01002-4 Noack F, Vangelisti S, Ditzer N, Chong F, Albert M, Bonev B. Joint epigenome profiling reveals cell-type-specific gene regulatory programmes in human cortical organoids. Nat Cell Biol. 2023 Dec;25(12):1873-1883. doi: 10.1038/s41556-023-01296-5. Epub 2023 Nov 23. PMID: 37996647; PMCID: PMC10709149.   Related Episodes Characterization of Epigenetic States in the Oligodendrocyte Lineage (Gonçalo Castelo-Branco) Polycomb Proteins, Gene Regulation, and Genome Organization in Drosophila (Giacomo Cavalli) The Effect of lncRNAs on Chromatin and Gene Regulation (John Rinn)   Contact Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Dr. Stefan Dillinger on LinkedIn Active Motif on Linke

In this episode of the Epigenetics Podcast, we talked with Dr. Eva Hörmanseder from the HelmholtzZentrum in Munich about her work on epigenetic mechanisms in cellular memory and gene regulation. In this episode, we delve into the fascinating world of cellular memory and gene regulation with Dr. Eva Hermanns-Eder from the Helmholtz Zentrum in Munich. Her research centers on how cells maintain their identity through the process of mitotic divisions, which is crucial for understanding both development and various diseases. We explore the role of chromatin dynamics and epigenetic modifications in switching genes on and off over time, which has significant implications for fields like cancer biology and regenerative medicine. The discussion starts with Dr. Hörmanseder's recent studies on epigenetic memories, particularly focusing on the concept of transcriptional memory in nuclear transfer embryos. She explains her work with H3K4 trimethylation, a crucial epigenetic mark associated with active transcription states, detailing experiments that demonstrate the significance of this mark in the context of gene expression during reprogramming. She elaborates on her findings regarding how active genes can remain in a state of transcriptional memory and the implications of such persistence for cellular identity. We also dive into Dr. Hörmanseder's exploration of how transcription factors and chromatin modifications shape the differentiation success of reprogrammed cells. Through her research, she uncovers that different cell types exhibit varying degrees of plasticity and memory retention, which can lead to disparities in successful differentiation. Her innovative use of single-cell sequencing technology reveals surprising insights into the dynamics of cellular reprogramming, especially when comparing reprogrammed cells to their fertilized counterparts.   References Hörmanseder E, Simeone A, Allen GE, Bradshaw CR, Figlmüller M, Gurdon J, Jullien J. H3K4 Methylation-Dependent Memory of Somatic Cell Identity Inhibits Reprogramming and Development of Nuclear Transfer Embryos. Cell Stem Cell. 2017 Jul 6;21(1):135-143.e6. doi: 10.1016/j.stem.2017.03.003. Epub 2017 Mar 30. PMID: 28366589; PMCID: PMC5505866. Zikmund, T., Fiorentino, J., Penfold, C., Stock, M., Shpudeiko, P., Agarwal, G., Langfeld, L., Petrova, K., Peshkin, L., Hamperl, S., Scialdone, A., & Hoermanseder, E. (2025). Differentiation success of reprogrammed cells is heterogeneous in vivo and modulated by somatic cell identity memory. Stem Cell Reports, 102447. https://doi.org/10.1016/j.stemcr.2025.102447   Related Episodes H3K4me3, SET Proteins, Isw1, and their Role in Transcription (Jane Mellor) DNA Replication, Transcription and R-loops (Stephan Hamperl) Inheritance of Transcriptional Memory by Mitotic Bookmarking (Sheila Teves)   Contact Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Dr. Stefan Dillinger on LinkedIn Active Motif on LinkedIn Active Motif on Bluesky Email: podcast@activemotif.com  

In this episode of the Epigenetics Podcast, we talked with Viviana Risca from Rockefeller University about her work on RICC-Seq and how it's used to probe DNA-DNA contacts in intact or fixed cells using ionizing radiation. This Interview covers Dr. Viviana Risca's cutting-edge methodologies, such as RICC-seq, which enables high-resolution analysis of chromatin structures without traditional cross-linking biases. We engage in a detailed discussion about how different techniques, such as RICC-seq and Micro-C, complement each other to provide robust insights into nucleosome interactions and chromatin dynamics. Dr. Risca articulates the challenges and innovations within her lab as it navigates through the complexities of chromatin mapping. The episode takes an exciting turn toward traversing the landscape of her future research directions, particularly studying the role of linker histones and other chromatin architectural proteins in regulating gene expression. Dr. Risca emphasizes the importance of understanding chromatin's mechanical properties and how these influence cellular processes like transcriptional regulation, DNA replication, and cellular responses to damage. We also explore her collaborative work that bridges the gap between basic research and clinical applications, particularly in cancer therapy. Dr. Risca shares insights into her investigations into how chromatin dynamics change during cell cycle arrest and their implications for cancer therapy resistance. Our discussion culminates in her reflections on the definition of epigenetics, framing it as the exploration of how cellular mechanisms encode and process information.   References Risca VI, Denny SK, Straight AF, Greenleaf WJ. Variable chromatin structure revealed by in situ spatially correlated DNA cleavage mapping. Nature. 2017 Jan 12;541(7636):237-241. doi: 10.1038/nature20781. Epub 2016 Dec 26. PMID: 28024297; PMCID: PMC5526328. Soroczynski J, Anderson LJ, Yeung JL, Rendleman JM, Oren DA, Konishi HA, Risca VI. OpenTn5: Open-Source Resource for Robust and Scalable Tn5 Transposase Purification and Characterization. bioRxiv [Preprint]. 2024 Jul 13:2024.07.11.602973. doi: 10.1101/2024.07.11.602973. PMID: 39026714; PMCID: PMC11257509. Prescott, N. A., Biaco, T., Mansisidor, A., Bram, Y., Rendleman, J., Faulkner, S. C., Lemmon, A. A., Lim, C., Tiersky, R., Salataj, E., Garcia-Martinez, L., Borges, R. L., Morey, L., Hamard, P.-J., Koche, R. P., Risca, V. I., Schwartz, R. E., & David, Y. (2025). A nucleosome switch primes hepatitis B virus infection. Cell, S0092867425001023. https://doi.org/10.1016/j.cell.2025.01.033   Related Episodes Hi-C and Three-Dimensional Genome Sequencing (Erez Lieberman Aiden) Split-Pool Recognition of Interactions by Tag Extension (SPRITE) (Mitch Guttman) Effects of Non-Enzymatic Covalent Histone Modifications on Chromatin (Yael David)   Contact Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Dr. Stefan Dillinger on LinkedIn Active Motif on LinkedIn Active Motif on Bluesky Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Geeta Narlikar from UCSF about her work on chromatin remodeling, Heterochromatin Protein 1, and the molecular mechanisms that influence the genome. The conversation starts with a pivotal paper from the early days of Dr. Narlikars research career, titled "Distinct Strategies to Make Nucleosomal DNA Accessible," focused on two ATP-dependent remodelers, BRG1 and SNF2H. Here, she notes that while both enzymes operate similarly, they generate different outputs and play distinct biological roles within the cell. The research revealed that BRG1 is more aggressive in altering nucleosome configuration, aligning with its role in transcription activation, while SNF2H showed a more refined approach in the formation of heterochromatin. Transitioning to her work at UCSF, she emphasized the importance of collaboration and mentoring within a research group. Her focus then shifted towards the ACF ATP-dependent chromatin assembly factor, hypothesizing how ACF measures nucleosome distance—an inquiry that led to exciting insights regarding dynamic enzyme behavior. This includes findings that ACF operates not through a static ruler mechanism but rather through a kinetic mechanism, thus continuously adjusting nucleosome positioning based on DNA length during chromatin assembly. Dr. Narlikar also delved into her studies on heterochromatin protein 1 (HP1), highlighting how HP1 recognizes methylation marks and assembles on chromatin to facilitate gene silencing. This segment of the discussion underscored her shift to studying phase separation and its implications in the organization of chromatin. Notably, her lab made significant advancements in understanding how HP1 forms phase-separated droplets, a finding that was independently corroborated by other laboratories, demonstrating the utility of collaborative scientific inquiry. In discussing the nuances of chromatin dynamics, Dr. Narlikar also introduced her investigations into the INO80 complex, detailing its distinct mechanism for nucleosome movement compared to other remodelers. Each remodeling complex, as she elucidated, has unique catalytic capabilities while still utilizing similar biochemical foundations, highlighting the diverse regulatory roles these proteins play within cells.   References Racki LR, Yang JG, Naber N, Partensky PD, Acevedo A, Purcell TJ, Cooke R, Cheng Y, Narlikar GJ. The chromatin remodeller ACF acts as a dimeric motor to space nucleosomes. Nature. 2009 Dec 24;462(7276):1016-21. doi: 10.1038/nature08621. PMID: 20033039; PMCID: PMC2869534. Canzio D, Liao M, Naber N, Pate E, Larson A, Wu S, Marina DB, Garcia JF, Madhani HD, Cooke R, Schuck P, Cheng Y, Narlikar GJ. A conformational switch in HP1 releases auto-inhibition to drive heterochromatin assembly. Nature. 2013 Apr 18;496(7445):377-81. doi: 10.1038/nature12032. Epub 2013 Mar 13. PMID: 23485968; PMCID: PMC3907283. Sinha KK, Gross JD, Narlikar GJ. Distortion of histone octamer core promotes nucleosome mobilization by a chromatin remodeler. Science. 2017 Jan 20;355(6322):eaaa3761. doi: 10.1126/science.aaa3761. PMID: 28104838; PMCID: PMC5656449. Larson AG, Elnatan D, Keenen MM, Trnka MJ, Johnston JB, Burlingame AL, Agard DA, Redding S, Narlikar GJ. Liquid droplet formation by HP1α suggests a role for phase separation in heterochromatin. Nature. 2017 Jul 13;547(7662):236-240. doi: 10.1038/nature22822. Epub 2017 Jun 21. PMID: 28636604; PMCID: PMC5606208. Sanulli S, Trnka MJ, Dharmarajan V, Tibble RW, Pascal BD, Burlingame AL, Griffin PR, Gross JD, Narlikar GJ. HP1 reshapes nucleosome core to promote phase separation of heterochromatin. Nature. 2019 Nov;575(7782):390-394. doi: 10.1038/s41586-019-1669-2. Epub 2019 Oct 16. PMID: 31618757; PMCID: PMC7039410.   Related Episodes Enhancers and Chromatin Remodeling in Mammary Gland Development (Camila dos Santos) Heterochromatin Protein 1 and its Influence on the Structure of Chromatin (Serena Sanull

In this episode of the Epigenetics Podcast, we talked with Giacomo Cavalli from the Institute of Human Genetics in Montpellier about his work on critical aspects of epigenetic regulation, particularly the role of Polycomb proteins and chromatin architecture. We start the Interview by talking about Dr. Cavalli's work on Polycomb function in maintaining chromatin states and how it relates to gene regulation. He shares insights from his early lab experiences, where he aimed to understand the inheritance mechanisms of chromatin states through various models, including the FAB7 cellular memory module. The discussion uncovers how Polycomb proteins can silence gene expression and the complex interplay between different epigenetic factors that govern this process. Dr. Cavalli also addresses how he has investigated the recruitment mechanisms of Polycomb complexes, highlighting the roles of several DNA-binding proteins, including DSP-1 and GAGA factor, in this intricate regulatory landscape. He emphasizes the evolution of our understanding of Polycomb recruitment, illustrating the multifactorial nature of this biological puzzle. As the conversation progresses, we explore Dr. Cavalli's fascinating research into the three-dimensional organization of the genome. He explains his contributions to mapping chromosomal interactions within Drosophila and the distinctions observed when performing similar studies in mammalian systems. Key findings regarding topologically associated domains (TADs) and their association with gene expression are presented, alongside the implications for our understanding of gene regulation in development and disease.   References Déjardin, J., Rappailles, A., Cuvier, O., Grimaud, C., Decoville, M., Locker, D., & Cavalli, G. (2005). Recruitment of Drosophila Polycomb group proteins to chromatin by DSP1. Nature, 434(7032), 533–538. https://doi.org/10.1038/nature03386 Sexton, T., Yaffe, E., Kenigsberg, E., Bantignies, F., Leblanc, B., Hoichman, M., Parrinello, H., Tanay, A., & Cavalli, G. (2012). Three-dimensional folding and functional organization principles of the Drosophila genome. Cell, 148(3), 458–472. https://doi.org/10.1016/j.cell.2012.01.010 Bonev, B., Mendelson Cohen, N., Szabo, Q., Fritsch, L., Papadopoulos, G. L., Lubling, Y., Xu, X., Lv, X., Hugnot, J. P., Tanay, A., & Cavalli, G. (2017). Multiscale 3D Genome Rewiring during Mouse Neural Development. Cell, 171(3), 557–572.e24. https://doi.org/10.1016/j.cell.2017.09.043 Szabo, Q., Donjon, A., Jerković, I., Papadopoulos, G. L., Cheutin, T., Bonev, B., Nora, E. P., Bruneau, B. G., Bantignies, F., & Cavalli, G. (2020). Regulation of single-cell genome organization into TADs and chromatin nanodomains. Nature genetics, 52(11), 1151–1157. https://doi.org/10.1038/s41588-020-00716-8   Related Episodes BET Proteins and Their Role in Chromosome Folding and Compartmentalization (Kyle Eagen) Long-Range Transcriptional Control by 3D Chromosome Structure (Luca Giorgetti) Epigenetic Landscapes During Cancer (Luciano Di Croce)   Contact Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Dr. Stefan Dillinger on LinkedIn Active Motif on LinkedIn Active Motif on Bluesky Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Ferdinand von Meyenn from ETH Zürich about his work on the interplay of nutrition, metabolic pathways, and epigenetic regulation. To start Dr. Meyenn recounts his pivotal research on DNA methylation in naive embryonic stem cells during his time with Wolf Reick. He explains the dynamics of global demethylation in naive stem cells, revealing the key enzymes involved and the unexpected findings surrounding UHF1—its role in maintaining DNA methylation levels and influencing the methylation landscape during early embryonic development. Dr. Meyenn then shares his perspective on the scientific transition to establishing his own lab at ETH. He reflects on his ambitions to merge the fields of metabolism and epigenetics, which is a recurring theme throughout his research. By investigating the interplay between metabolic changes and epigenetic regulation, he aims to uncover how environmental factors affect cellular dynamics across various tissues. This leads to a discussion of his recent findings on histone lactylation and its implications in cellular metabolism, as well as the intricacies of epigenetic imprinting in stem cell biology. Last but not least we touch upon Dr. Meyenn’s most recent study, published in Nature, investigating the epigenetic effects of obesity. He provides a detailed overview of how adipose tissue undergoes transcriptional and epigenetic rearrangements during weight fluctuations. The conversation highlights the notion of epigenetic memory in adipocytes, showing how obesity is not just a temporary state but leaves lasting cellular changes that can predispose individuals to future weight regain after dieting. This exploration opens avenues for potential therapeutic interventions aimed at reversing adverse epigenetic modifications.   References von Meyenn, F., Iurlaro, M., Habibi, E., Liu, N. Q., Salehzadeh-Yazdi, A., Santos, F., Petrini, E., Milagre, I., Yu, M., Xie, Z., Kroeze, L. I., Nesterova, T. B., Jansen, J. H., Xie, H., He, C., Reik, W., & Stunnenberg, H. G. (2016). Impairment of DNA Methylation Maintenance Is the Main Cause of Global Demethylation in Naive Embryonic Stem Cells. Molecular cell, 62(6), 848–861. https://doi.org/10.1016/j.molcel.2016.04.025 Galle, E., Wong, C. W., Ghosh, A., Desgeorges, T., Melrose, K., Hinte, L. C., Castellano-Castillo, D., Engl, M., de Sousa, J. A., Ruiz-Ojeda, F. J., De Bock, K., Ruiz, J. R., & von Meyenn, F. (2022). H3K18 lactylation marks tissue-specific active enhancers. Genome biology, 23(1), 207. https://doi.org/10.1186/s13059-022-02775-y Agostinho de Sousa, J., Wong, C. W., Dunkel, I., Owens, T., Voigt, P., Hodgson, A., Baker, D., Schulz, E. G., Reik, W., Smith, A., Rostovskaya, M., & von Meyenn, F. (2023). Epigenetic dynamics during capacitation of naïve human pluripotent stem cells. Science advances, 9(39), eadg1936. https://doi.org/10.1126/sciadv.adg1936 Bonder, M. J., Clark, S. J., Krueger, F., Luo, S., Agostinho de Sousa, J., Hashtroud, A. M., Stubbs, T. M., Stark, A. K., Rulands, S., Stegle, O., Reik, W., & von Meyenn, F. (2024). scEpiAge: an age predictor highlighting single-cell ageing heterogeneity in mouse blood. Nature communications, 15(1), 7567. https://doi.org/10.1038/s41467-024-51833-5 Hinte, L. C., Castellano-Castillo, D., Ghosh, A., Melrose, K., Gasser, E., Noé, F., Massier, L., Dong, H., Sun, W., Hoffmann, A., Wolfrum, C., Rydén, M., Mejhert, N., Blüher, M., & von Meyenn, F. (2024). Adipose tissue retains an epigenetic memory of obesity after weight loss. Nature, 636(8042), 457–465. https://doi.org/10.1038/s41586-024-08165-7   Related Episodes Nutriepigenetics: The Effects of Diet on Behavior (Monica Dus) Epigenetic and Metabolic Regulation of Early Development (Jan Żylicz) Effects of Environmental Cues on the Epigenome and Longevity (Paul Shiels)   Contact Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Dr. Stefan Dilli

In this episode of the Epigenetics Podcast, we talked with Vijay Ramani from the Gladstone Institute about his work on Single-Molecule Adenine Methylated Oligonucleosome Sequencing Assay (SAMOSA). Our discussion starts with Vijay Ramani's impactful contributions to the field during his time in Jay Shendure's lab, where he worked on several innovative methods, including RNA proximity ligation. This project was conceived during his graduate studies, aiming to adapt techniques from DNA research to investigate RNA structures—a largely unexplored area at the time. We delved into the nuances of his experiences in graduate school, emphasizing how critical it was to have mentors who provided room for creativity and autonomy in experimental design. Dr. Ramani then shares insights about his foray into developing more refined methodologies, such as in-situ DNA Hi-C, a revolutionary protocol tailored for three-dimensional genomic mapping. He explained the rationale behind his projects, comparing the outcomes with contemporaneous advancements in methods like Micro-C. The discussion highlighted the importance of understanding enzyme bias in chromatin studies and the need for meticulous experimental design to ensure the validity of biological interpretations. We further explored exciting advancements in single-cell genomics, specifically Ramani's work on developing sci-Hi-C. This innovative technique leverages combinatorial indexing to allow high-resolution mapping of chromatin architecture at the single-cell level, a significant leap forward in understanding the complexities of gene regulation. As we progress, Ramani detailed his transition from graduate student to independent investigator starting his own lab. He elaborated on the challenges and excitements associated with establishing his research focus in chromatin structure and function using advanced sequencing technologies. Employing various strategies, including the innovative SAMOSA assay, his research seeks to elucidate the mechanisms by which chromatin structure influences transcriptional regulation. We also discussed the heterogeneity of chromatin and its implications for gene expression. Ramani provided a fascinating perspective on how variations in chromatin structure could affect gene activity, highlighting potential avenues for future research that aims to untangle the complex dynamics at play in both healthy and diseased states.   References Ramani, V., Cusanovich, D., Hause, R. et al. Mapping 3D genome architecture through in situ DNase Hi-C. Nat Protoc 11, 2104–2121 (2016). https://doi.org/10.1038/nprot.2016.126 Nour J Abdulhay, Colin P McNally, Laura J Hsieh, Sivakanthan Kasinathan, Aidan Keith, Laurel S Estes, Mehran Karimzadeh, Jason G Underwood, Hani Goodarzi, Geeta J Narlikar, Vijay Ramani (2020) Massively multiplex single-molecule oligonucleosome footprinting eLife 9:e59404. https://doi.org/10.7554/eLife.59404 Abdulhay, N.J., Hsieh, L.J., McNally, C.P. et al. Nucleosome density shapes kilobase-scale regulation by a mammalian chromatin remodeler. Nat Struct Mol Biol 30, 1571–1581 (2023). https://doi.org/10.1038/s41594-023-01093-6 Nanda, A.S., Wu, K., Irkliyenko, I. et al. Direct transposition of native DNA for sensitive multimodal single-molecule sequencing. Nat Genet 56, 1300–1309 (2024). https://doi.org/10.1038/s41588-024-01748-0   Related Episodes Epigenetic Mechanisms in Genome Regulation and Developmental Programming (James Hackett) Chromatin Profiling: From ChIP to CUT&RUN, CUT&Tag and CUTAC (Steven Henikoff) Split-Pool Recognition of Interactions by Tag Extension (SPRITE) (Mitch Guttman)   Contact Epigenetics Podcast on X Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Epigenetics Podcast on Threads Active Motif on X Active Motif on LinkedIn Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Maxim Greenberg from the Institute Jacob Monot about his work on epigenetic consequences of DNA methylation in development. In this interview we explore how Dr. Greenberg’s work at UCLA involved pioneering experiments on DNA methylation mechanisms and how this period was marked by significant collaborative efforts within a highly competitive yet supportive lab environment that ultimately lead to publications in high impact journals. His transition to a postdoctoral position at the Institut Curie with Deborah Bourc'his harnessed his expertise in mammalian systems, examining chromatin changes and the implications for embryonic development. Dr. Greenberg explained the nuances of his research, particularly how chromatin modifications during early development can influence gene regulatory mechanisms later in life, providing a compelling narrative about the potential long-term impacts of epigenetic changes that occur in utero. Throughout our conversation, we examined the intricate relationship between DNA methylation and Polycomb repression, discussing how these epigenetic mechanisms interact and the functional outcomes of their regulation. Dr. Greenberg's insights into his recent studies reveal a commitment to unraveling the complexities of enhancer-promoter interactions in the context of epigenetic regulation.   References Greenberg, M. V., Ausin, I., Chan, S. W., Cokus, S. J., Cuperus, J. T., Feng, S., Law, J. A., Chu, C., Pellegrini, M., Carrington, J. C., & Jacobsen, S. E. (2011). Identification of genes required for de novo DNA methylation in Arabidopsis. Epigenetics, 6(3), 344–354. https://doi.org/10.4161/epi.6.3.14242 Greenberg, M. V., Glaser, J., Borsos, M., Marjou, F. E., Walter, M., Teissandier, A., & Bourc'his, D. (2017). Transient transcription in the early embryo sets an epigenetic state that programs postnatal growth. Nature genetics, 49(1), 110–118. https://doi.org/10.1038/ng.3718 Greenberg, M., Teissandier, A., Walter, M., Noordermeer, D., & Bourc'his, D. (2019). Dynamic enhancer partitioning instructs activation of a growth-related gene during exit from naïve pluripotency. eLife, 8, e44057. https://doi.org/10.7554/eLife.44057 Monteagudo-Sánchez, A., Richard Albert, J., Scarpa, M., Noordermeer, D., & Greenberg, M. V. C. (2024). The impact of the embryonic DNA methylation program on CTCF-mediated genome regulation. Nucleic acids research, 52(18), 10934–10950. https://doi.org/10.1093/nar/gkae724 Richard Albert, J., Urli, T., Monteagudo-Sánchez, A., Le Breton, A., Sultanova, A., David, A., Scarpa, M., Schulz, M., & Greenberg, M. V. C. (2024). DNA methylation shapes the Polycomb landscape during the exit from naive pluripotency. Nature structural & molecular biology, 10.1038/s41594-024-01405-4. Advance online publication. https://doi.org/10.1038/s41594-024-01405-4   Related Episodes DNA Methylation and Mammalian Development (Déborah Bourc'his) Circulating Epigenetic Biomarkers in Cancer (Charlotte Proudhon) Epigenetic Mechanisms in Genome Regulation and Developmental Programming (James Hackett)   Contact Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Dr. Stefan Dillinger on LinkedIn Active Motif on LinkedIn Active Motif on Bluesky Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Natalia Gromak from the University of Oxford about her work on R-Loop biology in health and disease. In this interview Dr. Gromak delves into her significant research on transcription and RNA biology, particularly focusing on the molecular mechanisms involved at transcriptional pause sites. She describes her early work in understanding transcription termination and how her team investigated the role of specific RNA and DNA structures, including R-loops, that could influence polymerase progression. This exploration into R-loops—complexes formed by RNA and DNA interactions—was a key turning point in her research, as she and her colleagues identified their regulatory functions within the human genome. Discussion transitions into her findings regarding the implications of R-loops in diseases like Friedrich's ataxia and Fragile X syndrome. Dr. Gromak then elucidates how the pathological expansion of repeat sequences in these conditions interferes with normal gene expression, and how R-loops exacerbate transcriptional silencing. Throughout her reflection on these discoveries, she emphasizes the importance of studying R-loops beyond merely being a transcriptional byproduct, but as players in gene regulation and potential contributors to disease pathology. The episode also covers her innovative work in characterizing the R-loop interactome through various experimental techniques. She highlights the complexity of R-loop dynamics, including the discovery of protein factors that interact with R-loops and could influence their stability and regulatory functions. Furthermore, she discusses the exciting intersection of RNA modifications, such as m6A, which plays a role in R-loop regulation and presents new avenues for research, particularly pertaining to how disease-specific modifications might alter R-loop behavior.   References Cristini, A., Groh, M., Kristiansen, M. S., & Gromak, N. (2018). RNA/DNA Hybrid Interactome Identifies DXH9 as a Molecular Player in Transcriptional Termination and R-Loop-Associated DNA Damage. Cell reports, 23(6), 1891–1905. https://doi.org/10.1016/j.celrep.2018.04.025 Abakir, A., Giles, T. C., Cristini, A., Foster, J. M., Dai, N., Starczak, M., Rubio-Roldan, A., Li, M., Eleftheriou, M., Crutchley, J., Flatt, L., Young, L., Gaffney, D. J., Denning, C., Dalhus, B., Emes, R. D., Gackowski, D., Corrêa, I. R., Jr, Garcia-Perez, J. L., Klungland, A., … Ruzov, A. (2020). N6-methyladenosine regulates the stability of RNA:DNA hybrids in human cells. Nature genetics, 52(1), 48–55. https://doi.org/10.1038/s41588-019-0549-x   Related Episodes DNA Replication, Transcription and R-loops (Stephan Hamperl)   Contact Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Dr. Stefan Dillinger on LinkedIn Active Motif on LinkedIn Active Motif on Bluesky Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Yadira Soto-Feliciano from MIT about her work on the Menin-MLL complex and the effect of small molecules on its stability in leukemia. We explore the pivotal moments that led her to cancer biology during her graduate studies, where her work included ground-breaking research on the role of the plant homeodomain Finger protein-6 (PHF-6) in leukemia. This work bridged the realms of chromatin accessibility, transcription factors, and cancer cell lineage, providing critical evidence for the concept of lineage plasticity in cancer biology—a topic that has gained significant traction in recent years. Dr. Soto-Feliciano discusses how advances in techniques like CRISPR and ChIP-sequencing have shaped her research, enabling deeper insights into the mechanisms underlying cancer cell identity. As our discussion transitions, Dr. Soto-Feliciano shares her experience in David Allis's lab, illustrating how the collaboration across diverse scientific disciplines enhanced her understanding of chromatin biology and generated significant insights into the mechanics of epigenetic regulation. Highlighting a recent 2023 publication, we unpack her findings related to the conserved molecular switch between MLL1 and MLL3 complexes. These discoveries revealed how the application of small-molecule inhibitors of the menin-MLL interaction can alter gene expression and affect leukemia cells’ responses to treatments. We also touch on the operational dynamics within her lab at MIT, established during challenging times marked by the pandemic. Yadira is dedicated to fostering a collaborative and respectful environment among her team, comprised of PhD candidates and research technicians, all sharing a commitment to unraveling the complexities of chromatin regulation. She emphasizes the significance of understanding chromatin scaffold proteins and their role in regulating gene expression and genome organization.   References Soto-Feliciano, Y. M., Bartlebaugh, J. M. E., Liu, Y., Sánchez-Rivera, F. J., Bhutkar, A., Weintraub, A. S., Buenrostro, J. D., Cheng, C. S., Regev, A., Jacks, T. E., Young, R. A., & Hemann, M. T. (2017). PHF6 regulates phenotypic plasticity through chromatin organization within lineage-specific genes. Genes & development, 31(10), 973–989. https://doi.org/10.1101/gad.295857.117 Soto-Feliciano, Y. M., Sánchez-Rivera, F. J., Perner, F., Barrows, D. W., Kastenhuber, E. R., Ho, Y. J., Carroll, T., Xiong, Y., Anand, D., Soshnev, A. A., Gates, L., Beytagh, M. C., Cheon, D., Gu, S., Liu, X. S., Krivtsov, A. V., Meneses, M., de Stanchina, E., Stone, R. M., Armstrong, S. A., … Allis, C. D. (2023). A Molecular Switch between Mammalian MLL Complexes Dictates Response to Menin-MLL Inhibition. Cancer discovery, 13(1), 146–169. https://doi.org/10.1158/2159-8290.CD-22-0416 Zhu, C., Soto-Feliciano, Y. M., Morris, J. P., Huang, C. H., Koche, R. P., Ho, Y. J., Banito, A., Chen, C. W., Shroff, A., Tian, S., Livshits, G., Chen, C. C., Fennell, M., Armstrong, S. A., Allis, C. D., Tschaharganeh, D. F., & Lowe, S. W. (2023). MLL3 regulates the CDKN2A tumor suppressor locus in liver cancer. eLife, 12, e80854. https://doi.org/10.7554/eLife.80854   Related Episodes MLL Proteins in Mixed-Lineage Leukemia (Yali Dou) Targeting COMPASS to Cure Childhood Leukemia (Ali Shilatifard)   Contact Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Dr. Stefan Dillinger on LinkedIn Active Motif on LinkedIn Active Motif on Bluesky Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Mary Anne Jelinek Associate Director of R&D at Active Motif about writing and reviewing grants in academia and industry. Learn from Dr. Jelinek’s years of experience writing and reviewing grants and get her best advice and insight for success. Hear about similarities and differences in preparing grants in academia vs. biotech or other industry settings. Key insights include: Finding Grant opportunities that exist for different sectors and countries, from the familiar ones like NIH and NSF in the United States grant funding offered by NATO for member countries.  Learn about grants targeted to small businesses and specific allocation of resources intended to foster and promote innovation and entrepreneurship and how to navigate confidentiality when writing grants in industry, being mindful of conflict of interest and best practices.  Coming up with ideas is easy – but how do you find institutes interested in funding those research areas? Get tips on how to submit a 1-page inquiry for feedback and guidance at early stages that will help your grant be robust and successful.  Think you can go from idea to funding in 4 weeks? She has and discusses the best strategy to do this - collaboration is key and you’ll learn why. Get tips on wording and writing for reviewers who may not be experts in your field and how to “paint a picture” that makes it both clear and persuasive, including your writing style and use of diagrams and figures for those complex concepts. Hear all of Dr. Jelinek’s “best advice” and encouragement for dealing with stress and frustration that can be part of the process.  Finally, as a co-developer for the first commercially available ChIP Kit, Dr. Jelinek tells the story of how this assay developed and became a gold-standard method for epigenetics. Tune in to this in depth and very helpful episode!   Contact Epigenetics Podcast on X Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Epigenetics Podcast on Threads Active Motif on X Active Motif on LinkedIn Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Carl Wu from John's Hopkins University about his work on nucleosome remodeling, histone variants, and the role of single-molecule imaging in gene regulation. Our discussion starts with Carl Wu sharing his first significant milestones, a paper in "Cell" and the serendipitous discovery of DNA hypersensitive sites, which transformed our understanding of chromatin accessibility and its implications for gene regulation. As we delve into Dr. Wu’s specific areas of research, he elaborates on the biochemistry of nucleosome remodeling and the intricate role of chromatin remodeling enzymes like NURF. We discuss how these enzymes employ ATP hydrolysis to reposition nucleosomes, making DNA accessible for transcription. He then explains the collaborative relationship between chromatin remodelers and transcription factors, showcasing the fascinating interplay that governs gene expression and regulatory mechanisms. The conversation takes a deeper turn as we explore Carl Wu’s groundbreaking studies on histone variants, particularly H2AZ. He elucidates the role of SWR1 in facilitating the exchange between H2A and H2AZ in nucleosome arrays. The high-resolution structural insights garnered from recent studies reveal how the enzyme mediates histone eviction and insertion with remarkable precision, providing a clearer picture of chromatin dynamics at a molecular level.   References Wu, C., Bingham, P. M., Livak, K. J., Holmgren, R., & Elgin, S. C. (1979). The chromatin structure of specific genes: I. Evidence for higher order domains of defined DNA sequence. Cell, 16(4), 797–806. https://doi.org/10.1016/0092-8674(79)90095-3 Wu, C., Wong, Y. C., & Elgin, S. C. (1979). The chromatin structure of specific genes: II. Disruption of chromatin structure during gene activity. Cell, 16(4), 807–814. https://doi.org/10.1016/0092-8674(79)90096-5 Wu C. (1980). The 5' ends of Drosophila heat shock genes in chromatin are hypersensitive to DNase I. Nature, 286(5776), 854–860. https://doi.org/10.1038/286854a0 Wu, C., Wilson, S., Walker, B., Dawid, I., Paisley, T., Zimarino, V., & Ueda, H. (1987). Purification and properties of Drosophila heat shock activator protein. Science (New York, N.Y.), 238(4831), 1247–1253. https://doi.org/10.1126/science.3685975 Mizuguchi, G., Shen, X., Landry, J., Wu, W. H., Sen, S., & Wu, C. (2004). ATP-driven exchange of histone H2AZ variant catalyzed by SWR1 chromatin remodeling complex. Science (New York, N.Y.), 303(5656), 343–348. https://doi.org/10.1126/science.1090701 Kim, J. M., Visanpattanasin, P., Jou, V., Liu, S., Tang, X., Zheng, Q., Li, K. Y., Snedeker, J., Lavis, L. D., Lionnet, T., & Wu, C. (2021). Single-molecule imaging of chromatin remodelers reveals role of ATPase in promoting fast kinetics of target search and dissociation from chromatin. eLife, 10, e69387. https://doi.org/10.7554/eLife.69387   Related Episodes Multiple challenges of ATAC-Seq, Points to Consider (Yuan Xue) Pioneer Transcription Factors and Their Influence on Chromatin Structure (Ken Zaret) ATAC-Seq, scATAC-Seq and Chromatin Dynamics in Single-Cells (Jason Buenrostro)   Contact Epigenetics Podcast on X Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Epigenetics Podcast on Threads Active Motif on X Active Motif on LinkedIn Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Mitinori Saitou from Kyoto University about his work on germ cell development, focusing on proteins like BLIMP1 and PRDM14, reprogramming iPSCs, and his vision to address infertility and genetic disorders through epigenetic insights. To start our discussion, Dr. Saitou shares the foundation of his research, which centers on the mechanisms of germ cell development across various species, including mice, non-human primates, and humans. He provides insight into his early work examining the roles of two key proteins: BLIMP1 and PRDM14. These proteins are essential for germline specification in mammals, and their functions are unveiled through detailed exploration of knockout models. In particular, Dr. Saitou elucidates the critical events in germ cell specification, highlighting how disruptions to the functions of these proteins lead to significant impairments in development. As the conversation deepens, we discuss Dr. Saitou’s groundbreaking advances in human-induced pluripotent stem cells (iPSCs). He elaborates on the processes involved in reprogramming these cells to form primordial germ cell-like cells, emphasizing the significance of understanding various cellular contexts and transcriptional regulation. Dr. Saitou then details how overexpression of certain factors in embryonic stem cells can induce these germline characteristics, presenting the promise of innovation in regenerative medicine and reproductive biology. We end our talk with the exploration of chromatin remodeling that occurs during germ cell development, including fascinating details about DNA and histone modification dynamics. Dr. Saitou articulates how the epigenetic landscape shifts during the transition from pluripotent states to germ cell specification, providing a detailed comparison between mouse and human systems. This highlights the complexity of gene regulation and the importance of specific epigenetic markers in establishing and maintaining cellular identity.   References Yamaji, M., Seki, Y., Kurimoto, K. et al. Critical function of Prdm14 for the establishment of the germ cell lineage in mice. Nat Genet 40, 1016–1022 (2008). https://doi.org/10.1038/ng.186 Katsuhiko Hayashi et al., Offspring from Oocytes Derived from in Vitro Primordial Germ Cell–like Cells in Mice. Science 338, 971-975 (2012). DOI: 10.1126/science.1226889 Nakaki, F., Hayashi, K., Ohta, H. et al. Induction of mouse germ-cell fate by transcription factors in vitro. Nature 501, 222–226 (2013). https://doi.org/10.1038/nature12417 Nakamura, T., Okamoto, I., Sasaki, K. et al. A developmental coordinate of pluripotency among mice, monkeys and humans. Nature 537, 57–62 (2016). https://doi.org/10.1038/nature19096 Murase, Y., Yokogawa, R., Yabuta, Y. et al. In vitro reconstitution of epigenetic reprogramming in the human germ line. Nature 631, 170–178 (2024). https://doi.org/10.1038/s41586-024-07526-6   Contact Epigenetics Podcast on X Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Epigenetics Podcast on Threads Active Motif on X Active Motif on LinkedIn Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Karine Le Roch from the University of California at Riverside about her work on malaria chromatin structure and its transcriptional regulation. In this Interview Dr. Le Roch discusses her investigation of post-transcriptional controls and nucleosome positioning in Plasmodium falciparum, employing next-generation sequencing and chromatin profiling methods. Karin emphasizes how these methodologies contribute to a comprehensive understanding of gene regulation beyond mere transcription initiation, emphasizing the significance of mRNA binding proteins and their role in stabilizing gene transcripts for translation. This exploration of the interaction between chromatin structure, transcriptional dynamics, and post-transcriptional regulation reveals a multidimensional perspective of gene expression. Transitioning to her lab’s focus on high-throughput genomic technologies, we discuss how Karin and her team are uncovering conserved and species-specific genomic organization principles within various Plasmodium species. By generating 3D genomic models through Hi-C experiments, she describes how they have identified patterns that underline the parasite's immune evasion strategies. In particular, we learn how genes involved in antigenic variation are controlled through intricate epigenetic mechanisms, illuminating the pathways that allow these parasites to elude host immune responses.   References Le Roch, K. G., Zhou, Y., Blair, P. L., Grainger, M., Moch, J. K., Haynes, J. D., De La Vega, P., Holder, A. A., Batalov, S., Carucci, D. J., & Winzeler, E. A. (2003). Discovery of gene function by expression profiling of the malaria parasite life cycle. Science (New York, N.Y.), 301(5639), 1503–1508. https://doi.org/10.1126/science.1087025 Ponts, N., Harris, E. Y., Prudhomme, J., Wick, I., Eckhardt-Ludka, C., Hicks, G. R., Hardiman, G., Lonardi, S., & Le Roch, K. G. (2010). Nucleosome landscape and control of transcription in the human malaria parasite. Genome research, 20(2), 228–238. https://doi.org/10.1101/gr.101063.109 Bunnik, E. M., Cook, K. B., Varoquaux, N., Batugedara, G., Prudhomme, J., Cort, A., Shi, L., Andolina, C., Ross, L. S., Brady, D., Fidock, D. A., Nosten, F., Tewari, R., Sinnis, P., Ay, F., Vert, J. P., Noble, W. S., & Le Roch, K. G. (2018). Changes in genome organization of parasite-specific gene families during the Plasmodium transmission stages. Nature communications, 9(1), 1910. https://doi.org/10.1038/s41467-018-04295-5   Related Episodes Epigenetics in Human Malaria Parasites (Elena Gómez-Diaz)   Contact Epigenetics Podcast on X Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Epigenetics Podcast on Threads Active Motif on X Active Motif on LinkedIn Email: podcast@activemotif.com

In this episode of the Epigenetics Podcast, we talked with Bas van Steensel from the Netherlands Cancer Institute about his work on characterizing chromatin at the Nuclear Lamina. The Interview starts with discussing Bas van Steensel's significant contributions to understanding genome-nuclear lamina interactions. Bas detailed the development of the DAM-ID technique during his postdoctoral studies, which provided a novel way to map genome-wide occupancy and identify Lamina-Associated Domains (LADs). He elaborated on how LADs reveal a distinct domain architecture, often correlating with gene expression levels. This prompted an exploration of the dynamics of these domains during differentiation processes, allowing insights into how gene activation and repression are influenced by their positioning relative to the nuclear lamina. The conversation highlighted the intricate relationship between chromatin dynamics and gene regulation, with Bas sharing compelling findings on how LADs behave during cell differentiation. The research indicated that regions moving away from the lamina often correlated with increased gene expression, revealing a complex interplay of spatial genome organization and transcriptional activity. Additionally, we ventured into the significance of outreach and transparency in scientific research. Bas shared his philosophy regarding collaboration and the ethical responsibility of scientists to share knowledge and resources openly. He emphasized that making lab notebooks and research processes accessible can greatly enhance reproducibility and understanding in the scientific community.   References Open Science Policy of our lab Guelen, L., Pagie, L., Brasset, E., Meuleman, W., Faza, M. B., Talhout, W., Eussen, B. H., de Klein, A., Wessels, L., de Laat, W., & van Steensel, B. (2008). Domain organization of human chromosomes revealed by mapping of nuclear lamina interactions. Nature, 453(7197), 948–951. https://doi.org/10.1038/nature06947 Kind, J., Pagie, L., Ortabozkoyun, H., Boyle, S., de Vries, S. S., Janssen, H., Amendola, M., Nolen, L. D., Bickmore, W. A., & van Steensel, B. (2013). Single-cell dynamics of genome-nuclear lamina interactions. Cell, 153(1), 178–192. https://doi.org/10.1016/j.cell.2013.02.028 Kind, J., Pagie, L., de Vries, S. S., Nahidiazar, L., Dey, S. S., Bienko, M., Zhan, Y., Lajoie, B., de Graaf, C. A., Amendola, M., Fudenberg, G., Imakaev, M., Mirny, L. A., Jalink, K., Dekker, J., van Oudenaarden, A., & van Steensel, B. (2015). Genome-wide maps of nuclear lamina interactions in single human cells. Cell, 163(1), 134–147. https://doi.org/10.1016/j.cell.2015.08.040 Leemans, C., van der Zwalm, M. C. H., Brueckner, L., Comoglio, F., van Schaik, T., Pagie, L., van Arensbergen, J., & van Steensel, B. (2019). Promoter-Intrinsic and Local Chromatin Features Determine Gene Repression in LADs. Cell, 177(4), 852–864.e14. https://doi.org/10.1016/j.cell.2019.03.009 van Schaik, T., Liu, N. Q., Manzo, S. G., Peric-Hupkes, D., de Wit, E., & van Steensel, B. (2022). CTCF and cohesin promote focal detachment of DNA from the nuclear lamina. Genome biology, 23(1), 185. https://doi.org/10.1186/s13059-022-02754-3 van Steensel B. (2018). Scientific honesty and publicly shared lab notebooks: Sharing lab notebooks along with publication would increase transparency and help to improve honesty when reporting results. EMBO reports, 19(10), e46866. https://doi.org/10.15252/embr.201846866   Related Episodes scDamID, EpiDamID and Lamina Associated Domains (Jop Kind) Identification of Functional Elements in the Genome (Bing Ren) Chromatin Profiling: From ChIP to CUT&RUN, CUT&Tag and CUTAC (Steven Henikoff)   Contact Epigenetics Podcast on X Epigenetics Podcast on Instagram Epigenetics Podcast on Mastodon Epigenetics Podcast on Bluesky Epigenetics Podcast on Threads Active Motif on X Active Motif on LinkedIn Email: podcast@activemotif.com