Posts classified under: Neuroepigenetics Interest Group

Penn Epigenetics > Faculty > Neuroepigenetics Interest Group

Marisa Bartolomei, Ph.D.

Contributions to Science

The work in my laboratory focuses on elucidating the mechanisms governing genomic imprinting in mammals. Imprinted genes number in the hundreds, are largely located in domains and are expressed from a single parental allele. This monoallelic gene expression pattern is set in the gametes and maintained during development using epigenetic mechanisms such as DNA methylation and posttranslational histone modifications. Genomic imprinting is an excellent model for studying epigenetic gene regulation during mammalian development. We have used mouse models with mutations in cis-acting regulatory sequences and trans-acting epigenetic factors to study imprinted gene regulation, including examining tissue-specific effects and higher order chromatin structure and architecture. Historically we conducted in depth analyses of the H19Igf2 imprinted locus but have more recently expanded to Grb10Ddc1 locus to reveal cis-acting regulatory elements. For elucidating establishment and maintenance of imprinted gene expression we have studied most of the imprinted loci and incorporated genome-wide approaches and mutations in the DNA methylation machinery. Specifically, we have studied the role of oxidase TET1 in reprogramming of iPSCs and genomic imprints, more recently expanding to study reprogramming of the male germline using a series of Tet1 mutant mice. We have also studied X inactivation in many of these model systems.

Additionally, we use mouse models to study the epigenetic consequences of environmental perturbations such as in utero exposure to endocrine disrupting compounds (EDCs) and Assisted Reproductive Technologies (ART). With respect to EDCs, we have used a mouse model to show that BPA exerts an abnormal metabolic, skeletal health and behavior phenotypes, largely observed in males. In these models we have focused on placenta as well as fetal and postnatal phenotypes. For the ART mouse model, we have studied the long-term outcomes of procedures used in assisted reproduction and have observed sex-specific metabolic and cardiovascular phenotypes and behavioral perturbations as mice age. Moreover, we have shown that embryo culture in the most significant procedure with respect to conferring abnormal DNA methylation profiles in ART-conceived offspring. Finally, we have employed high throughput technologies to study DNA methylation, transcription, chromatin structure and proteomics in a variety of cell types.

Research Interest

The research in the Bartolomei laboratory focuses epigenetic control of genomic imprinting. They also study how the environment can perturb genomic imprinting and other epigenetic processes important in reproduction and health.

Elizabeth Heller, Ph.D.

Contribution to Science

Proteomic characterization of inhibitory synapses. During doctoral training at The Rockefeller University under the mentorship of Dr. Nathaniel Heintz, I aimed to genetically tag and purify individual synapse types in the mammalian brain, in order to characterize their protein content using an innovative biochemical enrichment strategy coupled with high throughput proteomic analysis. In pursuit of this goal, I developed the first protocol for the specific biochemical isolation and characterization of the elusive inhibitory synapse.  We made a remarkable discovery, namely, that inhibitory synapses consist of structural proteins and ion channels, yet are completely lacking in the signaling molecules that comprise the major component of excitatory synapses.

Selimi F, Cristea IM, Heller E, Chait BT, Heintz N. Proteomic studies of a single CNS synapse type: the parallel fiber/purkinje cell synapse. PLoS Biol. 2009 Apr 14;7(4):e83. PubMed PMID: 19402746; PubMed Central PMCID: PMC2672601.
Heller EA, Zhang W, Selimi F, Earnheart JC, Ślimak MA, Santos-Torres J, Ibañez-Tallon I, Aoki C, Chait BT, Heintz N. The biochemical anatomy of cortical inhibitory synapses. PLoS One. 2012;7(6):e39572. PubMed PMID: 22768092; PubMed Central PMCID: PMC3387162.

Identification of critical period for sleep-consolidated spatial memory. During my undergraduate training I conducted an independent study under Dr. Ted Abel, aimed at elucidating the time course of sleep-induced memory formation in mice by examining memory deficits that result from sleep deprivation during discrete times following learning. We found that fear conditioning is blocked by sleep deprivation during a time period 5-10 hours post training, but unaffected by sleep deprivation for five hours immediately following training. This finding provided critical insights into the time-course of sleep-induced memory consolidation.

Graves LA, Heller EA, Pack AI, Abel T. Sleep deprivation selectively impairs memory consolidation for contextual fear conditioning. Learn Mem. 2003 May-Jun;10(3):168-76. PubMed PMID: 12773581; PubMed Central PMCID: PMC202307.

Locus-specific epigenetic editing for the study of addiction and depression. My postdoctoral research aimed to investigate the causal molecular mechanisms by which chromatin modifications contribute to reward-related pathology in the mammalian brain. There is a preponderance of compelling evidence implicating epigenetic modifications in the pathology of addiction and depression, in both human patients and animal models, yet previous studies have been unable to distinguish between the mere presence and the functional relevance of epigenetic modifications at relevant loci. To elucidate the molecular function of epigenetic regulation relevant to reward pathology, I have developed the use of engineered transcription factors to deliver histone modifications to a specific gene of interest in reward-related regions of the mammalian brain (major publications listed in Personal Statement).
Identification of cellular and molecular mechanisms underlying addiction and stress. In addition to pursuing my main postdoctoral research project, described above, I have also worked with others both inside and outside of the Nestler lab to investigate the molecular basis of drug addiction. For example, I have studied the role of serum- and glucocorticoid-inducible kinase 1 (SGK1) in regulating morphine and cocaine reward, and found that while its transcription and activity are upregulated in vivo by morphine and cocaine, exogenous SGK1 overexpression causes opposite behavioral responses to these two drugs. I have also contributed to several additional studies on the epigenetics of addiction, such as the role of nucleosome remodeling and the Sirtuin family of histone deacetylase.

Ferguson D, Koo JW, Feng J, Heller E, Rabkin J, Heshmati M, Renthal W, Neve R, Liu X, Shao N, Sartorelli V, Shen L, Nestler EJ. Essential role of SIRT1 signaling in the nucleus accumbens in cocaine and morphine action. J Neurosci. 2013 Oct 9;33(41):16088-98. PubMed PMID: 24107942; PubMed Central PMCID: PMC3792451.
Cates HM, Thibault M, Pfau M, Heller E, Eagle A, Gajewski P, Bagot R, Colangelo C, Abbott T, Rudenko G, Neve R, Nestler EJ, Robison AJ. Threonine 149 phosphorylation enhances ΔFosB transcriptional activity to control psychomotor responses to cocaine. J Neurosci. 2014 Aug 20;34(34):11461-9. PubMed PMID: 25143625; PubMed Central PMCID: PMC4138349.
Koo JW, Lobo MK, Chaudhury D, Labonté B, Friedman A, Heller E, Peña CJ, Han MH, Nestler EJ. Loss of BDNF signaling in D1R-expressing NAc neurons enhances morphine reward by reducing GABA inhibition. Neuropsychopharmacology. 2014 Oct;39(11):2646-53. PubMed PMID: 24853771; PubMed Central PMCID: PMC4207344.
Heller EA, Kaska S, Fallon B, Ferguson D, Kennedy PJ, Neve RL, Nestler EJ, Mazei-Robison MS. Morphine and cocaine increase serum- and glucocorticoid-inducible kinase 1 activity in the ventral tegmental area. J Neurochem. 2015 Jan;132(2):243-53. PubMed PMID: 25099208; PubMed Central PMCID: PMC4302038.

Research Interest

The Heller Lab studies the mechanisms by which remodeling of the epigenome leads to aberrant neuronal gene function and behavior.  To approach this problem, we directly manipulate histone and DNA modifications at specific genes in vivo, using viral delivery of epigenetic editing tools.  We focus on uncovering the mechanisms by which chromatin modifications interact with the transcriptional machinery following exposure to psychostimulants, such as drugs of abuse and stress. Because the behavioral disease traits of addiction and depression persist long after cessation of the harmful experience,  stable epigenetic remodeling is an attractive mechanism for such long-lasting effects and presents an intriguing target for therapeutic intervention.

Jennifer E. Phillips-Cremins, Ph.D.

Contributions to Science

The Cremins Lab focuses on higher-order genome folding and how chromatin works through long-range, spatial mechanisms to govern neural specification and synaptic plasticity in healthy and diseased neural circuits. We have developed molecular and computational technologies to create kilobase-resolution maps of chromatin folding and have built synthetic architectural proteins to engineer loops with light, together catalyzing new understanding of the genome’s structure-function relationship. We applied our technologies to discover that topologically associating domains (TADs), nested subTADs, and loops undergo marked reconfiguration during neural lineage commitment, somatic cell reprogramming, neuronal activity stimulation, and in models of repeat expansion disorders. We have demonstrated that loops induced by neural circuit activation, engineered through synthetic architectural proteins, and miswired in fragile X syndrome (FXS) are tightly connected to transcription, thus providing early insight into the genome’s structure-function relationship. Moreover, we have also demonstrated that cohesin-mediated loop extrusion can position the location of human replication origins which fire in early S phase, revealing a role for genome structure beyond gene expression in DNA replication. Recently, we have discovered that nearly all unstable short tandem repeat tracts in trinucleotide expansion disorders are localized to the boundaries between TADs, suggesting they are hotspots for pathological instability. We have identified that Mb-scale H3K9me3 domains decorating autosomes and the X chromosome in FXS are exquisitely sensitive to the length of the CGG STR tract. H3K9me3 domains spatially connect via inter-chromosomal interactions to silence synaptic genes and stabilize STRs prone to instability on autosomes. Together, our work uncovers a link between subMegabase-scale genome folding and genome function in the mammalian brain, thus providing the foundation upon which we will dissect the functional role for chromatin mechanisms in governing defects in synaptic plasticity and long-term memory in currently intractable and poorly understood neurological disorders.

Research Interest

The Cremins lab aims to understand how chromatin works through long-range physical folding mechanisms to encode neuronal specification and long-term synaptic plasticity in healthy and diseased neural circuits. We pursue a multi-disciplinary approach integrating data across biological scales in the brain, including molecular Chromosome-Conformation-Capture sequencing technologies, single-cell imaging, optogenetics, genome engineering, induced pluripotent stem cell differentiation to neurons/organoids, and in vitro and in vivo electrophysiological measurements.

Our long-term scientific goal is to dissect the fundamental mechanisms by which chromatin architecture causally governs genome function and, ultimately, long-term synaptic plasticity and neural circuit features in healthy mammalian brains as well as during the onset and progression of neurodegenerative and neurodevelopmental disease states

Our long-term mentorship goal is to develop a diverse cohort of next-generation scientific thinkers and leaders cross-trained in molecular and computational approaches. We seek to create a positive, high-energy environment with open and honest communication to empower individuals to discover and refine their purpose and grow into the best versions of themselves.

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