A time for metabolism and hormones
Item
Title
A time for metabolism and hormones
Creator
Sassone-Corsi, Paolo
Christen, Yves
Date
2016
Publisher
Springer
Description
Each morning we wake up from a night of sleep, and each day we eat our regularly timed meals, go through our normal routines, and fall asleep again for another night. This rhythm, so-called circadian—after the Latin words circa diem (“about a day”)—underlies a wide variety of human physiological functions, including sleep–wake cycles, body temperature, hormone secretion, exercise activity, and feeding behavior. Circadian rhythms are remarkably conserved throughout evolu-tion, and it is becoming commonly appreciated that circadian rhythms represent an exquisite example of systems biology.
At the heart of all cyclic biological functions is the circadian clock, a highly conserved molecular system that enables organisms to adapt to common daily changes, such as the day–night cycle and food availability. The mammalian ana-tomical structure in the brain that governs circadian rhythms consists of a small area of the anterior hypothalamus, called the suprachiasmatic nucleus (SCN). For decades, this “central pacemaker” was thought to be the unique circadian clock of the organism. This dogma was challenged when peripheral tissues were also found to contain functional circadian oscillators that are self-sustained at the single cell level. This notion, together with the discovery that a remarkable fraction of the genome is transcriptionally controlled by the clock, illustrated that circadian control must play a key role in governing the metabolism and physiology of all organisms.
This concept was recently validated by studies of the metabolome revealing that a large fraction of metabolites oscillate in a given tissue. Recent years have seen spectacular advances in the field of circadian biology.
These have attracted the interest of researchers in many fields, including endocri-nology, neurosciences, cancer, and behavior. By integrating a circadian view within the fields of endocrinology and metabolism, researchers will be able to reveal many, yet-unsuspected aspects of how organisms cope with changes in the environment and subsequent control of homeostasis.
At the heart of all cyclic biological functions is the circadian clock, a highly conserved molecular system that enables organisms to adapt to common daily changes, such as the day–night cycle and food availability. The mammalian ana-tomical structure in the brain that governs circadian rhythms consists of a small area of the anterior hypothalamus, called the suprachiasmatic nucleus (SCN). For decades, this “central pacemaker” was thought to be the unique circadian clock of the organism. This dogma was challenged when peripheral tissues were also found to contain functional circadian oscillators that are self-sustained at the single cell level. This notion, together with the discovery that a remarkable fraction of the genome is transcriptionally controlled by the clock, illustrated that circadian control must play a key role in governing the metabolism and physiology of all organisms.
This concept was recently validated by studies of the metabolome revealing that a large fraction of metabolites oscillate in a given tissue. Recent years have seen spectacular advances in the field of circadian biology.
These have attracted the interest of researchers in many fields, including endocri-nology, neurosciences, cancer, and behavior. By integrating a circadian view within the fields of endocrinology and metabolism, researchers will be able to reveal many, yet-unsuspected aspects of how organisms cope with changes in the environment and subsequent control of homeostasis.
Subject
Circadian rhythms
Medicine
Cytology
Language
English
isbn
978-3-319-27069-2
