Chromatin-based Mechanisms of Renal Epithelial Differentiation

被引:7
|
作者
Surendran, Kameswaran [1 ]
Kopan, Raphael [1 ]
机构
[1] Washington Univ, Sch Med, Dept Dev Biol, St Louis, MO 63110 USA
来源
JOURNAL OF THE AMERICAN SOCIETY OF NEPHROLOGY | 2011年 / 22卷 / 07期
关键词
NEPHRON PROGENITOR POPULATION; GENE-EXPRESSION; KIDNEY DEVELOPMENT; INTERMEDIATE MESODERM; EPIGENETIC REGULATION; METANEPHRIC KIDNEY; MAMMALIAN KIDNEY; MOUSE KIDNEY; CELLS; NOTCH;
D O I
10.1681/ASN.2010101018
中图分类号
R5 [内科学]; R69 [泌尿科学(泌尿生殖系疾病)];
学科分类号
1002 ; 100201 ;
摘要
Successful regenerative renal medicine depends on understanding the molecular mechanisms by which diverse phenotypes of epithelial cells differentiate from metanephric mesenchyme to populate nephrons. Whereas many genes are maintained in a poised state within the population of pluripotent progenitors, specialized epithelial functions reflect the selective expression of a subset of genes and the repression of all others. Here we highlight some common mechanisms of cell differentiation and epigenetic regulation to discuss their implications for renal epithelial development, repair, and disease.
引用
收藏
页码:1208 / 1212
页数:5
相关论文
共 50 条
  • [31] The chromatin remodelers RSC and ISW1 display functional and chromatin-based promoter antagonism
    Parnell, Timothy J.
    Schlichter, Alisha
    Wilson, Boris G.
    Cairns, Bradley R.
    ELIFE, 2015, 4
  • [32] The epigenetic chromatin-based regulation of somatic heat stress memory in plants
    Haider, Saqlain
    Iqbal, Javed
    Shaukat, Muzaffar
    Naseer, Sana
    Mahmood, Tariq
    PLANT GENE, 2021, 27
  • [33] Chromatin-based memory as a self-stabilizing influence on cell identity
    Bell, Charles C.
    Faulkner, Geoffrey J.
    Gilan, Omer
    GENOME BIOLOGY, 2024, 25 (01):
  • [34] Chromatin-based gene silencing by RNA interference machinery in the Drosophila germline
    Klenov, MS
    Natalin, PB
    Stolyarenko, AD
    Lavrov, SA
    Gvozdev, VA
    FEBS JOURNAL, 2005, 272 : 476 - 477
  • [35] Non-canonical chromatin-based functions for the threonine metabolic pathway
    Chik, Jennifer K.
    Su, Xue Bessie
    Klepin, Stephen
    Raygoza, Jessica
    Pillus, Lorraine
    SCIENTIFIC REPORTS, 2024, 14 (01):
  • [36] Chromatin-based reprogramming of a courtship regulator by concurrent pheromone perception and hormone signaling
    Zhao, Songhui
    Deanhardt, Bryson
    Barlow, George Thomas
    Schleske, Paulina Guerra
    Rossi, Anthony M.
    Volka, Pelin C.
    SCIENCE ADVANCES, 2020, 6 (21):
  • [37] Chromatin-based variant to gene mapping of osteoarthritis GWAS loci in primary chondrocytes
    Pahl, Matthew
    Pippin, James
    Villani, David
    Favazzo, Lacey J.
    Wells, Andrew D.
    Ackert-Bicknell, Cheryl L.
    Zuscik, Michael J.
    Grant, Struan F. A.
    JOURNAL OF BONE AND MINERAL RESEARCH, 2024, 39 : 193 - 193
  • [38] The 3′ processing of antisense RNAs physically links to chromatin-based transcriptional control
    Fang, Xiaofeng
    Wu, Zhe
    Raitskin, Oleg
    Webb, Kimberly
    Voigt, Philipp
    Lu, Tiancong
    Howard, Martin
    Dean, Caroline
    PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 2020, 117 (26) : 15316 - 15321
  • [39] Chromatin-based control of effector gene expression in plant-associated fungi
    Soyer, Jessica L.
    Rouxel, Thierry
    Fudal, Isabelle
    CURRENT OPINION IN PLANT BIOLOGY, 2015, 26 : 51 - 56
  • [40] Transcription and chromatin-based surveillance mechanism controls suppression of cryptic antisense transcription
    Heo, Dong-Hyuk
    Kus, Krzysztof
    Grzechnik, Pawel
    Tan-Wong, Sue Mei
    Birot, Adrien
    Kecman, Tea
    Nielsen, Soren
    Zenkin, Nikolay
    Vasiljeva, Lidia
    CELL REPORTS, 2021, 36 (10):
12345