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Chilling discovery: Cold-sensing protein may pave the way for safer pain relief

New ASU study reveals evolution of human cold and menthol sensing protein, offering hope for future non-addictive pain therapies.

News — Chronic pain affects millions worldwide, and current treatments often rely on opioids, which carry risks of addiction and overdose. 

Non-addictive alternatives could revolutionize pain management, and new research targeting the human protein which regulates cold sensations, brings scientists closer to developing pain medications that don't affect body temperature and don't carry the risks of addiction. 

Research published in Science Advances on June 21, led by , professor in Arizona State University’s and , has uncovered new insights into the main human cold and menthol sensor TRPM8 (transient receptor potential melastatin 8). Using techniques from many fields like biochemistry and biophysics, their study revealed that it was a chemical sensor before it became a cold temperature sensor.

“If we can start to understand how to decouple the chemical sensing of cold from actual cold sensing, in theory, we could make side-effect-free drugs,” said Van Horn whose research focuses on membrane proteins involved in human health and disease. "By understanding the evolutionary history of TRPM8, we hope to contribute to designing better drugs that offer relief without the dangerous side effects associated with current painkillers." 

When a person touches a metal desk and it feels cold, the human body activates TRPM8. For cancer patients who are on certain kinds of chemotherapeutics, touching a desk can hurt. TRPM8 is also involved in many other types of pain as well, including chronic neuropathic and inflammatory pain. 

By further understanding this specificity of the chemical sensing of cold versus physically sensing cold, scientists can target relief without triggering the temperature regulation side effects often seen in TRPM8 clinical trials for pain treatments. 

In the research, the team used ancestral sequence reconstruction, a time machine for proteins of sorts, compiling the family tree of TRPM8 that exists today and then used that information to determine what the proteins from long-extinct animals might have looked like. 

Using computational methods to resurrect ancestral primate, mammalian, and vertebrate TRPM8, the researchers were able to understand how TRPM8 has changed over hundreds of millions of years by comparing the sequences of current proteins to predict the sequences of their ancient ancestors. Additionally, the combination of lab experiments and computational studies enable the researchers to identify critical places in TRPM8 that allow a more clear understanding of temperature sensing, which can be tested in subsequent experiments. 

“Comparative dynamics analysis of ancestral and human TRPM8 also supports the experimental data and will allow us to identify critical sites in temperature sensing, which we will be testing soon,” said Banu Ozkan, professor in ASU’s Department of Physics, who was involved in the study.

The team then expressed these ancestral TRPM8s in human cells and characterized them using various cellular and electrophysiology techniques.

“Ancestral protein-based studies allow us to focus on the lineage of most interest, such as human TRPM8, to alleviate concerns arising in drug discovery from speciation differences, like in mice and humans,” said first author on the study Dustin Luu, an ASU School of Molecular Sciences doctoral alumnus, and current postdoctoral fellow in ASU’s Biodesign Center for Personalized Diagnostics.

Luu continued: “We discovered that surprisingly menthol sensing appeared way before cold sensing. The difference in appearance and attenuation of these activation modes suggest they are separate and can be disentangled with further research enabling new pain therapies without the adverse side effect in thermal sensing and thermal regulation, which has plagued TRPM8-targeted clinical trials.”

As science continues to uncover the mysteries of our biological mechanisms, studies like this exemplify how evolutionary biology and modern pharmacology can collaborate to address pressing medical needs and improve the quality of life for those suffering from chronic pain.

Additional researchers involved in the study include Nikhil Ramesh, and I. Can Kazan from Arizona State University’s Department of Physics; Karan Shah from ASU’s School of Molecular Sciences; Gourab Lahiri and Miyeko Mana from ASU’s School of Life Sciences. 

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Science Advances, June-2024