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  1. 1.   Structural insights into the cooperative nucleosome recognition and chromatin opening by FOXA1 and GATA4
  2. Zhou, Bing-Rui; Feng, Hanqiao; Huang, Furong; Zhu, Iris; Portillo-Ledesma, Stephanie; Shi,Dan; Zaret, Kenneth S; Schlick, Tamar; Landsman, David; Wang, Qianben; Bai, Yawen
  3. Molecular Cell. 2024, Jul 31;
  1. 2.   Distinct Structures and Dynamics of Chromatosomes with Different Human Linker Histone Isoforms
  2. Zhou, Bing-Rui; Feng, Hanqiao; Kale, Seyit; Fox,Tara; Khant,Htet; De Val Alda,Natalia; Ghirlando, Rodolfo; Panchenko, Anna R; Bai, Yawen
  3. Molecular cell. 2021, Jan 7; 81(1): 166-182.
  1. 3.   The chromatin remodeling protein Lsh alters nucleosome occupancy at putative enhancers and modulates binding of lineage specific transcription factors
  2. Ren, Jianke; Finney, Richard; Ni, Kai; Cam, Maggie; Muegge, Kathrin
  3. Epigenetics. 2019, MAR 4; 14(3): 277-293.
  1. 4.   Combined treatment with HMGN1 and anti-CD4 depleting antibody reverses T cell exhaustion and exerts robust anti-tumor effects in mice
  2. Chen, Chang-Yu; Ueha, Satoshi; Ishiwata, Yoshiro; Yokochi, Shoji; Yang,De; Oppenheim,Joost; Ogiwara, Haru; Shichino, Shigeyuki; Deshimaru, Shungo; Shand, Francis H W; Shibayama, Shiro; Matsushima, Kouji
  3. Journal for immunotherapy of cancer. 2019, Jan 29; 7(1): 21.
  1. 5.   High-Mobility Group Nucleosome-Binding Protein 1 as Endogenous Ligand Induces Innate Immune Tolerance in a TLR4-Sirtuin-1 Dependent Manner in Human Blood Peripheral Mononuclear Cells
  2. Arts, Rob J W; Huang, Po-Kai; Yang, De; Joosten, Leo A B; van der Meer, Jos W M; Oppenheim, Joost; Netea, Mihai G; Cheng, Shih-Chin
  3. Frontiers in Immunology. 2018, Mar 14; 9: 526.
  1. 6.   Tethering of Lsh at the Oct4 locus promotes gene repression associated with epigenetic changes.
  2. Ren, Jianke; Hathaway, Nathaniel A; Crabtree, Gerald R; Muegge, Kathrin
  3. Epigenetics. 2018, Feb 6; 13(2): 173-181.
  1. 7.   Impact of chromatin structure on sequence variability in the human genome
  2. Tolstorukov, M. Y.; Volfovsky, N.; Stephens, R. M.; Park, P. J.
  3. Nature Structural & Molecular Biology. 2011, Apr; 18(4): 510-U152.
  1. 8.   Lsh Mediated RNA Polymerase II Stalling at HoxC6 and HoxC8 Involves DNA Methylation
  2. Tao, Y. G.; Xi, S. C.; Briones, V.; Muegge, K.
  3. Plos One. 2010, Feb; 5(2): e9163.
  1. 9.   The p270 (ARID1A/SMARCF1) subunit of mammalian SWI/SNF-related complexes is essential for normal cell cycle arrest
  2. Nagl, N. G.; Patsialou, A.; Haines, D. S.; Dallas, P. B.; Beck, G. R.; Moran, E.
  3. Cancer Research. 2005, OCT 15; 65(20): 9236-9244.
  1. 10.   Nature of the nucleosomal barrier to RNA polymerase II
  2. Kireeva, M. L.; Hancock, B.; Cremona, G. H.; Walter, W.; Studitsky, V. M.; Kashlev, M.
  3. Molecular Cell. 2005, APR 1; 18(1): 97-108.
  1. 11.   Weak palindromic consensus sequences are a common feature found at the integration target sites of many retroviruses
  2. Wu, X. L.; Li, Y.; Crise, B.; Burgess, S. M.; Munroe, D. J.
  3. Journal of Virology. 2005, APR; 79(8): 5211-5214.
  1. 12.   Transcription through the nucleosome by mRNA-producing RNA polymerases
  2. Walter, W.; Kashlev, M.; Studitsky, V. M.
  3. CHROMATIN AND CHROMATIN REMODELING ENZYMES, PT C. 2004; 377 : 445-460.
  1. 13.   Chromatin remodeling by RNA polymerases
  2. Studitsky, V. M.; Walter, W.; Kireeva, M.; Kashlev, M.; Felsenfeld, G.
  3. Trends in Biochemical Sciences. 2004 29(3): 127-135.
  1. 14.   Assay of the fate of the nucleosome during transcription by RNA polymerase II
  2. Walter, W.; Kireeva, M. L.; Tchernajenko, V.; Kashlev, M.; Studitsky, V. M.
  3. RNA POLYMERASES AND ASSOCIATED FACTORS, PT D. 2003; 371 : 564-577.
  1. 15.   Bacterial polymerase and yeast polymerase II use similar mechanisms for transcription through nucleosomes
  2. Walter, W.; Kireeva, M. L.; Studitsky, V. M.; Kashlev, M.
  3. Journal of Biological Chemistry. 2003 278(38): 36148-36156.
  1. 16.   The octapeptidic end of the C-terminal tail of histone H2A is cleaved off in cells exposed to carcinogenic nickel(II)
  2. Karaczyn, A. A.; Bal, W.; North, S. L.; Bare, R. M.; Hoang, V. M.; Fisher, R. J.; Kasprzak, K. S.
  3. Chemical Research in Toxicology. 2003 16(12): 1555-1559.
  1. 17.   Molecular models in nickel carcinogenesis
  2. Bal, W.; Kozlowski, H.; Kasprzak, K. S.
  3. Journal of Inorganic Biochemistry. 2000 79(1-4): 213-218.
  1. 18.   Ni(II) specifically cleaves the C-terminal tail of the major variant of histone H2A and forms an oxidative damage mediating complex with the cleaved-off octapeptide
  2. Bal, W.; Liang, R. T.; Lukszo, J.; Lee, S. H.; Dizdaroglu, M.; Kasprzak, K. S.
  3. Chemical Research in Toxicology. 2000 13(7): 616-624.
  1. 19.   Interaction of nickel(II) with histones: In vitro binding of nickel(II) to the core histone tetramer
  2. Bal, W.; Karantza, V.; Moudrianakis, E. N.; Kasprzak, K. S.
  3. Archives of Biochemistry and Biophysics. 1999 364(2): 161-166.
  1. 20.   Interactions of Nickel(Ii) With Histones - Interactions of Nickel(Ii) With Ch3co-Thr-Glu-Ser-His-His-Lys-Nh2, a Peptide Modeling the Potential Metal Binding Site in the C-Tail Region of Histone H2a
  2. Bal, W.; Lukszo, J.; Bialkowski, K.; Kasprzak, K. S.
  3. Chemical Research in Toxicology. 1998 11(9): 1014-1023.
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