Mitzi Kuroda headshot

Mitzi I. Kuroda, Ph.D.

Professor of Genetics, Harvard Medical School

Analysis of chromatin organization and epigenetic gene regulation in health and disease

We study epigenetic regulators using genetics, genomics and proteomics. The factors we study include the MSL dosage compensation complex in fruit flies, the Polycomb Group in both flies and humans, and a translocation oncoprotein, BRD4-NUT, that drives an aggressive form of squamous cell cancer in humans. The common thread is that each is strongly implicated in the creation of active or silent chromatin domains that are integral to the fidelity of gene regulation. One serious obstacle to understanding the interactions of such factors with additional proteins and RNAs on chromatin has been the trade-off between removal from the DNA, to allow purification, and the resultant loss of interactions with key partners in function. Therefore, we have adapted a crosslinking approach that allows us to affinity-purify fragmented chromatin with protein and RNAs attached, to avoid disruption of interactions that may only occur on DNA. After reversal of crosslinks, the DNA, protein, histone peptides, and RNA fractions can be separately analyzed using comprehensive sequencing and mass spectrometry. Our current results are providing us with a rich and comprehensive view of key epigenetic complexes bound to their chromatin templates.

An example is our recent work with BRD4-NUT, a translocation-encoded fusion protein that plays a defining role in NUT midline carcinoma (NMC). In collaboration with Christopher French’s lab at BWH, we discovered that nuclear foci containing BRD4-NUT protein correspond to extremely broad, cell type-specific, hyperacetylated chromatin domains in patient tissue and cell lines. These are much larger than typical activated regions or ‘super-enhancers’, ranging from 100 kb to 2 Mb. These ‘megadomains’ appear to reflect a pathologic, feed-forward regulatory loop in which hyperacetylation drives further bromodomain-dependent binding and aberrant transcriptional activity. The novelty of megadomains is that they spread from select pre-existing enhancers, surprisingly not enriched for recently described ‘super-enhancers’, to fill individual topologically associating domains (TADs). Although the selected TADs generally differ by cell type, the c-MYC and TP63 regions are targeted in all NMC patient cells examined to date. The ability to spread to fill whole regulatory compartments surrounding genes encoding proteins like MYC and p63 is likely to explain the extremely aggressive nature of NUT midline carcinoma.

Correspondence of Drosophila polycomb group proteins with broad H3K27me3 silent domains.
Authors: Authors: Jung YL, Kang H, Park PJ, Kuroda MI.
Fly (Austin)
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Comparative analysis of metazoan chromatin organization.
Authors: Authors: Ho JW, Jung YL, Liu T, Alver BH, Lee S, Ikegami K, Sohn KA, Minoda A, Tolstorukov MY, Appert A, Parker SC, Gu T, Kundaje A, Riddle NC, Bishop E, Egelhofer TA, Hu SS, Alekseyenko AA, Rechtsteiner A, Asker D, Belsky JA, Bowman SK, Chen QB, Chen RA, Day DS, Dong Y, Dose AC, Duan X, Epstein CB, Ercan S, Feingold EA, Ferrari F, Garrigues JM, Gehlenborg N, Good PJ, Haseley P, He D, Herrmann M, Hoffman MM, Jeffers TE, Kharchenko PV, Kolasinska-Zwierz P, Kotwaliwale CV, Kumar N, Langley SA, Larschan EN, Latorre I, Libbrecht MW, Lin X, Park R, Pazin MJ, Pham HN, Plachetka A, Qin B, Schwartz YB, Shoresh N, Stempor P, Vielle A, Wang C, Whittle CM, Xue H, Kingston RE, Kim JH, Bernstein BE, Dernburg AF, Pirrotta V, Kuroda MI, Noble WS, Tullius TD, Kellis M, MacAlpine DM, Strome S, Elgin SC, Liu XS, Lieb JD, Ahringer J, Karpen GH, Park PJ.
Nature
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Heterochromatin-associated interactions of Drosophila HP1a with dADD1, HIPP1, and repetitive RNAs.
Authors: Authors: Alekseyenko AA, Gorchakov AA, Zee BM, Fuchs SM, Kharchenko PV, Kuroda MI.
Genes Dev
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Impact of sequencing depth in ChIP-seq experiments.
Authors: Authors: Jung YL, Luquette LJ, Ho JW, Ferrari F, Tolstorukov M, Minoda A, Issner R, Epstein CB, Karpen GH, Kuroda MI, Park PJ.
Nucleic Acids Res
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Are we there yet? Initial targeting of the Male-Specific Lethal and Polycomb group chromatin complexes in Drosophila.
Authors: Authors: McElroy KA, Kang H, Kuroda MI.
Open Biol
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Reciprocal interactions of human C10orf12 and C17orf96 with PRC2 revealed by BioTAP-XL cross-linking and affinity purification.
Authors: Authors: Alekseyenko AA, Gorchakov AA, Kharchenko PV, Kuroda MI.
Proc Natl Acad Sci U S A
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Transcriptional control of a whole chromosome: emerging models for dosage compensation.
Authors: Authors: Ferrari F, Alekseyenko AA, Park PJ, Kuroda MI.
Nat Struct Mol Biol
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"Jump start and gain" model for dosage compensation in Drosophila based on direct sequencing of nascent transcripts.
Authors: Authors: Ferrari F, Plachetka A, Alekseyenko AA, Jung YL, Ozsolak F, Kharchenko PV, Park PJ, Kuroda MI.
Cell Rep
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Conservation and de novo acquisition of dosage compensation on newly evolved sex chromosomes in Drosophila.
Authors: Authors: Alekseyenko AA, Ellison CE, Gorchakov AA, Zhou Q, Kaiser VB, Toda N, Walton Z, Peng S, Park PJ, Bachtrog D, Kuroda MI.
Genes Dev
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Chromatin proteins captured by ChIP-mass spectrometry are linked to dosage compensation in Drosophila.
Authors: Authors: Wang CI, Alekseyenko AA, LeRoy G, Elia AE, Gorchakov AA, Britton LM, Elledge SJ, Kharchenko PV, Garcia BA, Kuroda MI.
Nat Struct Mol Biol
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