Active Motif's Podcast

In this episode of the Epigenetics Podcast, we caught up with Active Motif scientists Casidee McDonough from Epigenetic Services and Kyle Tanguay from R&D to talk about technical details of the CUT&Tag protocol and current developments around this method in our R&D Team.  CUT&Tag, which is short for Cleavage Under Targets and Tagmentation, is a molecular biology method that is used to investigate interactions between proteins and DNA and to identify DNA binding sites for their protein of interest. Although CUT&Tag is similar in some ways to ChIP assays, the starting material for CUT&Tag is live, permeabilized cells or isolated cell nuclei, rather than cells or tissue that have been crosslinked with formaldehyde as is the case when performing ChIP. The CUT&Tag method is very sensitive and has been reported to work with as few as 60 cells for some histone modifications. The ability to work with such small numbers of cells is an advantage for researchers working on specific cell types

In this episode of the Epigenetics Podcast, we caught up with Ian Maze from Ichan School of Medicine at Mount Sinai and a Howard Hughes Medical Institute (HHMI) Investigator to talk about his work on the role of histone dopaminylation and serotinylation in neuronal plasticity. The Maze group focuses on understanding the complex interplay between chromatin regulatory mechanisms in brain and neuronal plasticity. The lab places an emphasis on psychiatric disorders associated with monoaminergic (e.g., serotonin, dopamine, etc.) dysfunction, such as major depressive disorder and drug addiction. In particular the Maze team has investigated cocaine addiction and its effect on chromatin by serotonylation and dopaminylation of Histone H3 Tails.   References Maze, I., Covington, H. E., Dietz, D. M., LaPlant, Q., Renthal, W., Russo, S. J., Mechanic, M., Mouzon, E., Neve, R. L., Haggarty, S. J., Ren, Y., Sampath, S. C., Hurd, Y. L., Greengard, P., Tarakhovsky, A., Schaefer, A., & Nestler, E. J. (2010). Essential Rol

In this episode of the Epigenetics Podcast, we caught up with Erna Magnúsdóttir from the University of Iceland to talk about her work on the role of Blimp-1 in immune-cell differentiation. The Magnúsdóttir Lab is interested in how the mammalian genome is interpreted in a context dependent manner, leading to different cellular states, by using mouse primordial germ cells as well as mouse and human B-cells as model systems. More specifically, the team is interested in the Transcription Factor Blimp-1 and its effect on immune cell differentiation. Next to its function in immune cells, Blimp-1 also plays a role in Waldenström’s macroglobulinemia. The lab hopes to reveal the intricacies in disease progression and alteration in cellular states to increasingly aggressive tumor behavior.   References Magnúsdóttir, E., Dietmann, S., Murakami, K. et al. A tripartite transcription factor network regulates primordial germ cell specification in mice. Nat Cell Biol 15, 905–915 (2013). https://doi.org/10.1038/ncb2798 And

In this episode of the Epigenetics Podcast, we speak with Peter Smibert, Vice President of Biology at 10X Genomics to talk about an exciting new method in Multimodal Characterization of Cellular Identity using Barcoding. During his time at the New York Genome Center, Peter Smibert was instrumental in the development of a new method called "Cellular Indexing of Transcriptomes and Epitopes by Sequencing" short CITE-Seq. This method enables the characterization of a cell's transcriptome, while at the same time, also allows the characterization of the cell's protein surface markers - at the single cell level. In CITE-Seq, sequencing adapters are coupled to antibodies that recognize surface proteins, which can then be detected by sequencing. Further advancements of the CITE-Seq method led to the launch of BioLegend’s TOTAL-Seq and the integration of scATAC-Seq into the workflow. With the integration of scATAC-Seq in the CITE-Seq protocol, it is now possible to characterize single-cells along the path of the centr

In this episode of the Epigenetics Podcast, we caught up with Sara Wickström, Director at the Max Planck Institute for Molecular Biomedicine in Münster, to talk about her work on the effect of mechanotransduction on chromatin structure and transcription in stem cells. Sara Wickström and her team focus on the stem cell niche and how that niche affects stem cell function. In order to study the native niche and to even be able to manipulate it, the Wickström Lab was able to develop a ex vivo culture system, allowing systematic identification of factors driving stem cell dynamics and plasticity. Stem cells in the stem cell niche are exposed to external stimuli such as physical forces which control their growth, fate and self renewal. Recent work in the Wickström lab showed how mechanical signals influence transcriptional regulation, chromatin organization, and nuclear architecture and how this affects aging or lineage commitment. In this Episode we also discuss how chromatin can act as a sensor of mechanical sign

In this episode of the Epigenetics Podcast, we caught up with Ben Hindson, Chief Scientific Officer at 10X Genomics, to talk about single-cell technologies using microfluidics. Epigenetics has moved well past a simple understanding of a single epigenetic layer of control at genomic regions of interest, thanks to advances in many techniques and the application of “multiomics”. We can now analyze genome-wide histone modification patterns, transcription factor binding profiles, chromatin accessibility profiles, three-dimensional chromosomal conformation, and DNA methylation dynamics combined with transcriptomic analyses and associated analytical platforms. Bulk Assays, like ATAC-Seq or ChIP, despite all their advantages, do not provide information about the chromatin states of individual subpopulations of cells within a sample. To identify chromatin features in heterogeneous populations, such as blood, pancreas, and brain, those analysis need to be performed at a single-cell level. 10X Genomics has been at t

In this episode of the Epigenetics Podcast, we caught up with Eleni Tomazou from St. Anna Children's Cancer Research Institute in Vienna to talk about her work on Epigenome-based precision medicine. The Tomazou lab studies Ewing sarcoma and the effects of Epigenetic factors on this disease. Ewing sarcoma is a type of cancer that affects bone and soft tissue of children and young adults, with a peak incidence at the age of 15. Ewing sarcoma is among the pediatric cancer types with the lowest survival rates and the development of novel therapies was obstructed by the limited understanding of the mechanisms behind the disease. Work done in Eleni Tomazou's group identified an epigenetic signature of Ewing sarcoma which, ultimately, lead to the possibility to diagnose Ewing sarcoma from liquid biopsies. The team is now looking to find actionable targets like enhancers to develop therapies, finding biomarkers to enable disease monitoring, and to further characterize these tumors to decipher intra-tumor epigenetic

In this episode of the Epigenetics Podcast, we caught up with Manel Esteller, Director of the Josep Carreras Leukemia Research Institute to talk about his work on Epigenetics and Epitranscriptomics in Cancer. The focus of Manel Esteller's research career and the focus of his current team is to characterize the epigenome and epitranscriptome of cancer cells in comparison to healthy cells, and their interplay. Ultimately, their goal is to use this knowledge to develop new therapies for cancer. Key achievements from the Esteller lab began with the discovery of the first miRNA that undergoes specific cancer-methylation associated silencing. The team further identified many more miRNAs that also play a role in cancer. Next to miRNAs, Manel Esteller studied the influence of lncRNAs, enhancers and DNA methylation on cancer development and progression, insights that may be used to develop cancer biomarkers and potential treatments.     References Guil, S., Soler, M., Portela, A., Carrère, J., Fonalleras, E., Góm

In this episode of the Epigenetics Podcast, we caught up with Yad Ghavi-Helm from the Institut de Génomique Functionnelle de Lyon to talk about her work on enhancer-promoter interactions during development. The Laboratory of Yad Ghavi-Helm focuses on how developmental genes are regulated by enhancers. Their work shows that developmental genes are often regulated by more than one enhancer and that those enhancers can often be located many kilobases away on the linear chromosome. Furthermore, their research also indicates that the interactions between promoters and their respective enhancers are usually established before the expression of the target gene is switched on, and that those interactions are generally stable during embryogenesis. In addition, those stable interactions seem to coincide with paused RNA Pol II being located at those promoters before gene activation. References Ghavi-Helm, Y., Michaut, M., Acker, J., Aude, J.-C., Thuriaux, P., Werner, M., & Soutourina, J. (2008). Genome-wide lo

In this episode of the Epigenetics Podcast, we caught up with Folami Ideraabdullah from the University of Chapel Hill to talk about her work on the environmental modulation of the epigenome during development. The lab of Folami Ideraabdullah focuses on studying how environmental factors modulate the epigenome. In particular the team investigates how Vitamin D levels influence epigenetic processes and, hence, the susceptibility for diseases like adipositas. Folami Ideraabdullah started with a genome-wide screen of DNA Methylation patterns that are observed after Vitamin D depletion. This work was then followed up by investigating the impact of Vitamin D depletion on mouse sperm DNA methylation.   References Xue, J., Schoenrock, S. A., Valdar, W., Tarantino, L. M., & Ideraabdullah, F. Y. (2016). Maternal vitamin D depletion alters DNA methylation at imprinted loci in multiple generations. Clinical Epigenetics, 8(1), 107. https://doi.org/10.1186/s13148-016-0276-4 Xue, J., Gharaibeh, R. Z., Pietryk,

In this episode of the Epigenetics Podcast, we caught up with Jane Mellor from the University of Oxford to talk about her work on H3K4me3, SET proteins, Isw1 and their role in transcription. Since the beginning of the century, Jane Mellor and her team have focused on H3K4 trimethylation and the factors that influence this mark. They discovered that H3K4me3 is an almost universal mark of the first nucleosome in every transcribed unit and all organisms. She could subsequently, together with the Kouzarides lab, identify SetD1, the enzyme that is responsible for writing this modification. Later on, the team characterized Isw1, a chromatin remodeler which “reads” H3K4me3. More recently the lab focuses on how the polymerase transcribes throughout the first nucleosomes of the transcribed region at the +2 nucleosome, with the help of Spt4.   References Santos-Rosa, H., Schneider, R., Bannister, A. J., Sherriff, J., Bernstein, B. E., Emre, N. C. T., Schreiber, S. L., Mellor, J., & Kouzarides, T. (2002). Activ

In this episode of the Epigenetics Podcast, we caught up with Katja Kobow from the Universitätsklinikum Erlangen to talk about her work on the role of DNA methylation in Epilepsy. Katja Kobow started studying the role of Epigenetics in Epilepsy by doing a genome wide Bisulfite-Sequencing screen that revealed a typical DNA methylation signature of epileptic patients versus healthy controls. After these initial results in human patient samples, she switched to an animal model to investigate this further. Now the focus of the Kobow Lab is to look for the same DNA methylation signature in blood samples, using this as a basis for the development of a potential prognostic marker for Epilepsy.   References Jablonski, Janos, Lucas Hoffmann, Ingmar Blümcke, Anna Fejtová, Steffen Uebe, Arif B. Ekici, Vadym Gnatkovsky, and Katja Kobow. 2021. “Experimental Epileptogenesis in a Cell Culture Model of Primary Neurons from Rat Brain: A Temporal Multi-Scale Study.” Cells 10(11):3004. doi: 10.3390/cells10113004. Jablo

In this episode of the Epigenetics Podcast, we caught up with Emily Bernstein from Icahn Schoon of Medicine at Mount Sinai to talk about her work on MacroH2A function and the role of Polycomb proteins in its epigenetic regulation, and how this affects in stem cell development and disease. The Bernstein Lab focuses on histone variants, in particular the variants of macroH2A. Chromatin architecture is influenced by the composition of the nucleosome and, hence, exchanging the core histones for histone variants can have a major impact on chromatin structure. MacroH2A is the histone with the most variants, due to a 30kDa non-histone domain (macro domain) at their C-termini. This variation leads to many macroH2A variants, which have been found to have regulatory roles in the cell. Among other things the Bernstein Lab has shown that macroH2A is enriched at a critical set of Utx target genes whose expression is critical for the early stages of induced pluripotency.   References Kapoor, A., Goldberg, M. S., Cumbe

In this episode of the Epigenetics Podcast, we caught up with Jane Skok from New York University School of Medicine to talk about her work on spatio-temporal alterations in chromosome dynamics. Studies demonstrating that nuclear organization and long-range chromatin interactions play essential roles in gene regulation have been the focus of the Skok Lab, where the team has played a leading role. Their initial studies focused on lymphocyte development and the control of V(D)J recombination, a key part of generating the diverse repertoire of B-cell antibodies and T-cell receptors. The Skok Lab was among the first to demonstrate the possibility of chromatin forming dynamic loops which lead to the formation of reversible intra-locus loops in the immunoglobulin and T-cell receptor loci and to a profound impact on the ability of B and T cells to generate receptor diversity.   References Roldán, E., Fuxa, M., Chong, W., Martinez, D., Novatchkova, M., Busslinger, M., & Skok, J. A. (2005). Locus “decontracti

In this episode of the Epigenetics Podcast, we caught up with Marieke Oudelaar from the Max Planck Institute for Biophysical Chemistry to talk about her work on chromatin organization during development and disease. Marieke Oudelaar and her team focus on on developing high-resolution Chromosome Conformation Capture (3C) based techniques, like low-input Capture-C, Tri-C, and Tiled-C. Those techniques are then used in combination with other genomic techniques, genetic perturbations, and computational approaches to investigate the 3D structure of chromatin in development and disease. The team focused on the interplay between genome organisation and regulation during mammalian differentiation, and how perturbations in these processes contribute to human disease, including cancer.   References Oudelaar, A. M., Davies, J. O. J., Downes, D. J., Higgs, D. R., & Hughes, J. R. (2017). Robust detection of chromosomal interactions from small numbers of cells using low-input Capture-C. Nucleic Acids Research, 45

In this episode of the Epigenetics Podcast, we caught up with Camila dos Santos from Cold Spring Harbor Laboratories to talk about her work on enhancers and chromatin remodeling in mammary gland development. The lab of Camila dos Santos focuses on epigenetic regulation of normal and malignant mammary gland development. After puberty, the next significant phase in mammary gland development occurs in pregnancy, including changes in cellular function, and tissue reorganization. A different and as significant change in mammary glands occurs in the development breast cancer. Camila dos Santos and her lab were recently able to show that the reaction of mammary glands to a second pregnancy is different than to a first one, which is accompanied by changes in the DNA methylome of the cells. Furthermore, the lab studies the connection of pregnancy-induced epigenetic changes of chromatin and the risk of cancer development.   References dos Santos, C. O., Rebbeck, C., Rozhkova, E., Valentine, A., Samuels, A., Kadi

In this episode of the Epigenetics Podcast, we caught up with Marnie Blewitt from the Walter and Eliza Hall Institute of Medical Research to talk about her work on the role of SMCHD1 in Development and Disease. The Laboratory of Marnie Blewitt focuses finding inhibitors or activators for the epigenetic regulator SMCHD1. Marnie Blewitt identified and characterized this protein during her PhD and the findings were published in 2008 in Nature Genetics. Since then, she and her team were able to investigate the function of this protein further. By doing so, they showed the involvement of SMCHD1 in cancer and several other diseases. Currently the lab is screening for small molecules that can act as inhibitors or activators of SMCHD1 the former as potential treatments for facioscapulohumeral muscular dystrophy, the latter for Prader Willi and Schaaf-Yang syndromes, both of which have no current targeted treatments.   References Blewitt, M. E., Gendrel, A.-V., Pang, Z., Sparrow, D. B., Whitelaw, N., Craig, J. M

In this episode of the Epigenetics Podcast, we caught up with Efrat Shema from the Weizmann Institute of Science to talk about her work on Single Molecule Imaging of chromatin, and the analysis of nucleosomes circulating in plasma. In ChIP-Seq experiments the peak you get as a read out represents an average over, most often, millions of cells. Furthermore, one often does not know if that peak represents one or more than one nucleosome. If you then want to study multiple marks at the same time, the question remains: do those modifications occur at the same time, in the same cell? The Laboratory of Efrat Shema works on answering those questions by developing methods to study the modification patterns on single nucleosomes with single molecule imaging. With that it is possible to study single nucleosomes in a high throughout manner to identify the modifications they are decorated with. A subsequent sequencing step makes it possible to identify the genomic location of that nucleosome.   References Shema, E

In this episode of the Epigenetics Podcast, we caught up with Serena Sanulli from Stanford University to talk about her work on Heterochromatin Protein 1 (HP1), the structure of chromatin on the atomic-scale and the meso-scale, and phase separation. The Laboratory of Serena Sanulli is interested in finding connections between changes that happen on the nucleosomal level and the resulting impact on chromatin conformation on the meso-scale. They combine methods like NMR and Hydrogen-Deuterium Exchange-MS with Cell Biology and Genetics. This enables them to dissect how cells use the diverse biophysical properties of chromatin to regulate gene expression across length and time scales. A second focus of the lab is HP1, which interacts with the nucleosome and changes its conformation, enabling the compaction of the genome into heterochromatin, effectively silencing genes in that region. A high concentration of HP1 leads to the phenomenon of phase separation in the nucleus, which the Sanulli lab is now investiga

In this episode of the Epigenetics Podcast, we caught up with Catherine Jensen Peña from Princeton University to talk about her work on early life stress and its effects on behavior. The Laboratory of Catherine Peña focuses on how early life experiences are encoded and maintained into adulthood, with a long-lasting impact on behavior. Recent work showed, that child maltreatment and other forms of early life stress increase the lifetime risk of depression and other mood, anxiety, and drug disorders by 2-4 fold. The Peña Lab uses genome wide approaches to investigate key brain regions with a two-hit stress model. Using RNA-Seq, the Peña Lab has shown that depression-like gene expression patterns are programmed by early life stress, similar to observations in mice exhibiting depression-like behavior after adult stress and are visible even before behavioral changes. Furthermore, latent and unique transcriptional responses to adult stress among a subset of genes is programmed by early life stress. The role of