Opioid receptors are of great pharmacological interest because opioid substances regulate the perception of pain. “Our findings provide insights into how an opioid receptor can perform different functions. It is able to reduce pain, but also to regulate digestion or breathing,” explains Dr Elgeti, co-first author of the study from the Institute for Drug Discovery at the Faculty of Medicine.
In the current study, the biophysicist collaborated with international scientists, including the research group of Nobel laureate Brian Kobilka from Stanford University. They discovered that superagonists, such as fentanyl, stabilise a state of the receptor that causes particularly effective and long-lasting signal transmission. This means that superagonists are particularly potent and therefore dangerous. In the current study, the researchers used electron spin resonance and single-molecule fluorescence spectroscopy to determine different states of the opioid receptor and the structural effects of different binding partners.
Opioid receptors are members of the large family of G protein-coupled receptors (GPCRs), which control many signalling processes in the body, such as taste and smell, while others bind neurotransmitters and hormones or are activated by light. Understanding the molecular interactions of these receptors with drugs and other signalling proteins is very important for drug development. As all GPCRs are structurally very similar, the researchers hope that their findings on the opioid receptor can be applied to other receptors.
“This study involved isolating the opioid receptors. They are normally found in the body’s cells, interacting with many other proteins and molecules. Further research into the molecular interactions is therefore needed to gain a full understanding of the regulatory mechanisms,” says Dr Elgeti. The new study is an important building block in basic research, with further studies needed to ultimately develop better and safer medicines.
Original publication in Nature: Ligand efficacy modulates conformational dynamics of the µ-opioid receptor. DOI: 10.1038/s41586-024-07295-2