Study reveals non-image light sensing mechanism of circadian neurons

UCI-led study reveals non-image light sensing mechanism of circadian neurons
UCI Professor Todd C. Holmes, PhD, and his team use the laboratory genetic 'workhorse' Drosophila melanogaster, commonly known as fruit flies, to discover how Cryptochrome non-image-forming vision averages environmental light levels for setting the circadian clock. Credit: UCI School of Medicine

University of California, Irvine researchers reveal how an ancient flavoprotein response to ultra violet (UV), blue and red light informs internal circadian processes about the time of day.

The study, led by Todd C. Holmes, Ph.D., a professor in the Department of Physiology and Biophysics at the UCI School of Medicine, is titled, "Distinct mechanisms of Drosophila CRYPTOCHROME mediated light-evoked membrane depolarization and in vivo clock resetting," and was published in Proceedings of the National Academy of Sciences.

Phototransduction is relatively well characterized in the eyes and other external photoreceptors in animals for image-forming vision. Much less understood are phototransduction mechanisms in non-eye photosensitive cells, including central brain neurons. In the UCI School of Medicine-led study, researchers revealed how blue and ultra violet (UV) light create a sustained light response which is key to a form of non-image-forming vision that averages environmental light levels to determine the time of day and inform internal circadian processes. Red light evokes a light response but less sustained.

"Image-forming vision works so rapidly that humans and likely other animals perceive the visual world as a continuous process," said Holmes. "Our eyes capture moment to moment changes in light that enable us to see objects and movement, even when moving from bright to dark surroundings. An entirely different type of vision, the non-image-forming vision, is important for informing us about the time of day, based on the color and intensity of light. It is a slower visual process that captures an average of light levels rather than moment to moment changes in light."

Using Drosophila melanogaster, commonly known as , researchers discovered that non-image-forming vision in invertebrates relies on redox chemistry of a light sensitive protein called Cryptochrome. Biological redox chemistry is typically associated with metabolism.

"The protein ancestors of Cryptochromes were -activated DNA repair enzymes that appeared in evolution well over 3 billion years ago before the appearance of our present day oxygen rich atmosphere that protects us from harmful ultraviolet radiation. These first light sensing mechanisms evolved when single cell organisms developed the ability to repair their DNA damaged from UV light after coming too close to the surface of water. At that time, there was no life on land. It is remarkable that this ancient form of non-image forming persists to the present day."

Light is the primary regulator of circadian rhythms and evokes a wide range of time-of-day specific behaviors. By gaining an understanding of how insects respond to short wavelength , researchers hope to develop new, environmentally friendly alternatives to controlling harmful insects, such as mosquitoes and flies, and reduce the need for toxic pesticides.

More information: Lisa S. Baik et al, Distinct mechanisms of Drosophila CRYPTOCHROME-mediated light-evoked membrane depolarization and in vivo clock resetting, Proceedings of the National Academy of Sciences (2019). DOI: 10.1073/pnas.1905023116

Citation: Study reveals non-image light sensing mechanism of circadian neurons (2019, November 7) retrieved 21 February 2024 from
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