Photo by Andrea Piacquadio: https://www.pexels.com/photo/young-man-in-sleepwear-suffering-from-headache-in-morning-3771115/
A new study from the University of Surrey and the University of Aberdeen has found that disruptions to our body clock, such as those experienced during jetlag, impact our metabolism – but to a lesser extent than sleepiness and the primary clock in the brain.
Led by Professor Jonathan Johnston at the University of Surrey and Professor Alexandra Johnstone at the University of Aberdeen, the research involved a controlled experiment where participants experienced a 5-hour delay in their bedtime and mealtimes.
The study, published on iScience, highlights that the time shifts lead to:
Reduced energy spent processing meals.
Changes in blood sugar and fat levels.
Slower release of breakfast contents from the stomach.
These metabolic effects were temporary, however, and mostly recovered within 2-3 days of the 5-hour time delay. This was in marked contrast to the main clock in the brain, plus feelings of sleepiness and alertness, which had not recovered within 5 days of the 5-hour time delay.
Our research underscores the importance of maintaining a consistent sleep schedule, particularly in our fast-paced world in which long trips and shift work are ever so common. Even a small time shift can impact many aspects of metabolism, but it now seems that metabolic consequences of jetlag recover far more quickly than impairment of sleep and alertness. Understanding the impact of circadian rhythms on our health can help us make informed choices about our lifestyle. By optimising our sleep and eating patterns, we can improve our overall wellbeing.
Professor Jonathan Johnston, Professor of Chronobiology and Integrative Physiology
A team of scientists in Singapore and the US uncovered how a protein that controls our biological clock modifies its own function, offering new ways for treating jet lag and seasonal adjustments
Scientists from Duke-NUS Medical School and the University of California, Santa Cruz, have discovered the secret to regulating our internal clock. They identified that this regulator sits right at the tail end of Casein Kinase 1 delta (CK1δ), a protein which acts as a pace setter for our internal biological clock or the natural 24-hour cycles that control sleep-wake patterns and other daily functions, known as circadian rhythm.
Published in the journal PNAS, their findings could lead to new treatments for circadian rhythm disorders.
CK1δ regulates circadian rhythms by tagging other proteins involved in circadian rhythm to fine-tune the timing of these rhythms. In addition to modifying other proteins, CK1δ itself can be tagged, thereby altering its own ability to regulate the proteins involved in running the body’s internal clock.
Previous research identified two distinct versions of CK1δ, known as isoforms δ1 and δ2, which vary by just 16 building blocks or amino acids right at the end of the protein in a part called the C-terminal tail. Yet these small differences significantly impact CK1δ’s function. While it was known that when these proteins are tagged, their ability to regulate the body clock decreases, no one knew exactly how this happened.
Using advanced spectroscopy and spectrometry techniques to zoom in on the tails, the researchers found that how the proteins are tagged is determined by their distinct tail sequences.
Professor Carrie Partch at the University of California, Santa Cruzand corresponding author of the study explained:
“Our findings pinpoint to three specific sites on CK1δ’s tail where phosphate groups can attach, and these sites are crucial for controlling the protein’s activity. When these spots get tagged with a phosphate group, CK1δ becomes less active, which means it doesn’t influence our circadian rhythms as effectively. Using high-resolution analysis, we were able to pinpoint the exact sites involved—and that’s really exciting.”
Having first studied this protein more than 30 years ago while investigating its role in cell division, Professor David Virshup, the director of the Cancer and Stem Cell Biology Programme at Duke-NUS and co-corresponding author of the study, elaborated:
“With the technology we have available now, we were finally able to get to the bottom of a question that has gone unanswered for more than 25 years. We found that the δ1 tail interacts more extensively with the main part of the protein, leading to greater self-inhibition compared to δ2. This means that δ1 is more tightly regulated by its tail than δ2. When these sites are mutated or removed, δ1 becomes more active, which leads to changes in circadian rhythms. In contrast, δ2 does not have the same regulatory effect from its tail region.”
This discovery highlights how a small part of CK1δ can greatly influence its overall activity. This self-regulation is vital for keeping CK1δ activity balanced, which, in turn, helps regulate our circadian rhythms.
The study also addressed the wider implications of these findings. CK1δ plays a role in several important processes beyond circadian rhythms, including cell division, cancer development, and certain neurodegenerative diseases. By better understanding how CK1δ’s activity is regulated, scientists could open new avenues for treating not just circadian rhythm disorders but also a range of conditions.
The researchers plan to further investigate how real-world factors, such as diet and environmental changes, affect the tagging sites on CK1δ. This could provide insights into how these factors affect circadian rhythms and might lead to practical solutions for managing disruptions.
