Adipose tissue has a central role in controlling mammalian metabolism. Whilewhite adipose tissue (WAT) is to store excess in the form of triglycerides, brown adipose
tissue (BAT) is specialized in burning calories and generating heat. Brown adipose
tissue is a key thermogenic organ and functions as a mechanism to combat
hypothermia in small mammals such as rodents as well as in humans. Classic brown
adipocytes contain a high density of mitochondria that constitutively express a protein
called Uncoupling protein 1 (UCP1), which dissipates chemical energy by combusting
energy and generating heat instead. Mice housed in the cold environment undergo a
marked remodeling of their white fat and form beige fat, a third class of inducible cells
that appears within white adipose depot that expresses UCP1 in response to cold
stimulus. Importantly, there is emerging evidence of thermogenic tissues in human
adults after chronic cold, and it is inversely correlated with body mass index and visceral
fat. The aim of this dissertation work was to identify and characterize critical
thermogenic factors that activate the UCP1 promoter and increase thermogenesis
which may serve as promising avenues to combat obesity and associated metabolic
diseases.
Chapter 1 reviews advances made in understanding the molecular mechanism
underlying the thermogenic gene program. A number of key transcriptional regulators
critical for the thermogenic gene program centering on activating the UCP1 promoter,
have been discovered. Thermogenic gene expression in brown adipocytes relies on
coordinated actions of a multitude of transcription factors, including EBF2, PPARγ,
Zfp516 and Zc3h10. Moreover, these transcription factors recruit epigenetic factors,
such as LSD1 and Dot1l, for specific histone signatures to establish the favorable
chromatin landscape. Additionally, this chapter discusses environmental signals that
affect gene expression via various signaling pathways and by changes in intracellular
metabolites, hence altering epigenome.
Chapter 2 demonstrates my effort to characterize a key thermogenic transcription
factor, Zc3h10 and discusses its molecular significance in thermogenesis both in vitro
and in vivo. As a member of CCCH zinc finger proteins, Zc3h10 directly binds to the
distal UCP1 promoter and increases the UCP1 gene expression. Upon sympathetic
2
stimulation, Zc3h10 is phosphorylated at S126 by p38 mitogen-activated protein kinase
to increase binding to the distal region of the UCP1 promoter. Zc3h10 overexpression in
mice increases thermogenic gene expression and energy expenditure, resulting in a
lean phenotype. Conversely, Zc3h10 ablation in mice impairs thermogenic capacity,
leading to weight gain.
Chapter 3 focuses on the function of the epigenetic factor, Dot1l, the only known
H3K79 methyltransferase, in the Zc3h10-mediated activation of the thermogenic
program. Through a direct interaction, Dot1l is recruited by Zc3h10 to the promoter
regions of thermogenic genes to function as a coactivator by methylating H3K79, and
Dot1l and its H3K79 methyltransferase activity are required for activating the
thermogenic gene program. Dot1l ablation in Ucp1+ cells in mice prevents activation of
Ucp1 and other target genes to reduce thermogenic capacity and energy expenditure,
promoting adiposity.
Chapter 4 concludes my work describing the importance of key factors identified
for thermogenesis and presents future directions and remaining questions.
