Fruit Flies Reveal New Evolutionary Link for Studying Human Health How They Control Body Temperature Through Circadian Rhythm

Sep. 13, 2012 —
Science Daily/Cincinnati Children's Hospital Medical Center

https://www.sciencedaily.com/images/2012/09/120913123223_1_540x360.jpg
Male common fruit fly (Drosophila melanogaster). Drosophila fruit flies are a common tool in life sciences research for modeling human development and disease. Scientists continue learn more about how molecular processes in fruit flies may have similarities to human development that are conserved through the long process of evolution.
Credit: iStockphoto

New research reveals that fruit flies and mammals may share a surprising evolutionary link in how they control body temperature through circadian rhythm, unlocking new ways to study the insects as models of human development and disease.

The study posted online Sept. 13 by Current Biology reports that similar to people, Drosophila fruit flies -- a common research tool in life sciences -- have a genetically driven internal clock. This circadian clock prompts the insects to seek out warmer or cooler external temperatures according to the time of the day. Cold-blooded creatures change behavior to alter body temperature, usually by seeking out different external temperatures. But fruit flies are the first cold-blooded species to demonstrate their modification of temperature preference behavior is controlled by a circadian clock.

"We show that Drosophila fruit flies exhibit a daily temperature preference rhythm that is low in the morning, high in the evening and that follows a similar pattern as body temperature rhythms in humans," said Fumika N. Hamada, PhD, principal investigator and a researcher in the Division of Pediatric Ophthalmology at Cincinnati Children's Hospital Medical Center. "This study also reports the first systematic analysis of the molecular and neural mechanisms underlying temperature preference rhythm in fruit flies."

The research is important to understanding how regulation of daily body temperature is linked to homeostasis -- the body's ability to maintain a stable internal environment while exposed to changes in the external environment. Failure to manage related stress and maintain homeostasis can lead to abnormal function and disease, Hamada said.

The circadian clock's internal control of body temperature rhythm in warm-blooded mammals, including humans, allows them to maintain homeostasis by regulating sleep and metabolic energy use. The study by Hamada and colleagues is the first to demonstrate that fruit flies have a similar circadian clock system for temperature control, although one more influenced by external temperatures than for mammals. It also is the first to show that Drosophila's behavior modification to adjust body temperature is not controlled by a subset of pacemaker neurons in the brain responsible for locomotor activity.

By subjecting a variety of genetically altered flies to different degrees of light and darkness and then analyzing the insect's brains, the scientists identified a pacemaker neuron in the dorsal region of the fruit fly brain called DN2 that controls the bug's temperature preference rhythm. The function of this neural circuit had previously been unknown, the researchers said.

Hamada said continued study of the newly discovered circadian clock for Drosophila temperature preference rhythm may help explain mechanisms that underlie body temperature control in animals. It also could provide a better understanding of circadian rhythm's changeability from external influences.

Funding support for the study came from the National Institutes of Health (RO1grants GM079182 and NS052854), the March of Dimes, funding from the Precursor Research for Embryonic Science and Technology (PRESTO) program at the Japan Science Technology Agency, and a Trustee Grant from Cincinnati Children's Hospital Medical Center. The first author of the study was Haruna Kaneko, PhD., a member of Hamada's laboratory team. Also collaborating were Paul Hardin, Department of Biology and Center for Biological Clocks Research at Texas A&M University, and Patrick Emery, Department of Neurobiology and Program in Neuroscience, at the University of Massachusetts Medical School.
http://www.sciencedaily.com/releases/2012/09/120913123223.htm

 

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