A research team led by scientists from the University of California, Irvine (UCI) published a study that discusses how the circadian clock controls various aspects of homeostasis, and how organs coordinate their function over the course of a day.
“What is fascinating is that nearly every cell that makes up our organs has its own clock, and thus timing is a crucial aspect of biology,” said Kevin B. Koronowski, PhD, lead author and a postdoctoral fellow in Biological Chemistry at the UCI School of Medicine. “Understanding how daily timing is integrated with function across organs has implications for human health, as disruption of the clock and circadian rhythms can be both a cause and effect of diseases from diabetes to cancer.”
The circadian clock generates a ~24-hour rhythm that controls behavior, hormones, the immune system and metabolism. Using human cells and mice, researchers from the Paolo Sassone-Corsi Laboratory at UCI’s Center for Epigenetics and Metabolism aim to uncover the physiological circuits, for example between the brain and liver, whereby biological clocks achieve coherence. Their paper “Communicating clocks shape circadian homeostasis” appears in Science.
“Circadian clocks temporally coordinate physiology and align it with geophysical time, which enables diverse life-forms to anticipate daily environmental cycles. In complex organisms, clock function originates from the molecular oscillator within each cell and builds upward anatomically into an organism-wide system,” write the investigators.
“ Recent advances have transformed our understanding of how clocks are connected to achieve coherence across tissues. Circadian misalignment, often imposed in modern society, disrupts coordination among clocks and has been linked to diseases ranging from metabolic syndrome to cancer. Thus, uncovering the physiological circuits whereby biological clocks achieve coherence will inform on both challenges and opportunities in human health.”
Circadian clocks align internal processes with external time, which enables diverse lifeforms to anticipate daily environmental changes such as the light-dark cycle. In complex organisms, clock function starts with the genetically encoded molecular clock or oscillator within each cell and builds upward anatomically into an organism-wide system. Circadian misalignment, often imposed in modern society, can disrupt this system and induce adverse effects on health if prolonged.
“Strategies to tune our clocks and boost rhythms have been promising in pre-clinical studies, which illustrates the importance of unraveling this aspect of our biology and unlocking the potential it holds for treatments and medicines of the future,” said Koronowski.
Without electrical light, high-speed travel, constant food availability and around the clock work-life schedules, our ancestors’ clocks were in constant harmony with the environment. However, due to these pressures of modern society, aligning our internal time with geophysical time has become a challenge in today’s world. Chronic misalignment—when eating and sleeping patterns conflict with the natural light-dark cycle—is associated with an increased risk of metabolic syndrome, cardiovascular disease, neurological conditions, and cancer. A large portion of the global workforce has atypical hours and may be particularly vulnerable.
“It has become urgent that we uncover the molecular underpinnings of the relationship between the circadian clock and disease,” explained Koronowski. “Deciphering the means by which clocks communicate across metabolic organs has the potential to transform our understanding of metabolism, and it may hold therapeutic promise for innovative, noninvasive strategies to promote health.”