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Written by Binghao Zhang
Editor-in-charge - Wang Sizhen
Editor—Summer Leaf
The pandemic of pain and opioid addiction has highlighted the need for new non-opioid treatments for pain (Figure 1).
。 Many non-opioid receptors are involved in pain processing (nociceptive sensing), but only a few of them are therapeutic and proven analgesic targets
.
α 2A-adrenergic receptors (α2AAR) are one Class A G-protein coupled receptors, whose activation in the central nervous system has a pain-relieving effect [1,2].
。 Drugs known to act α 2AAR, such as the imidazoles clonidine (clonidine) and dexmedetomidine (dexmedetomidine), has an analgesic effect[3].
Unfortunately, they also have a strong sedative effect; This sedative effect is important for the primary indications of these drugs, but limits their widespread use
as analgesics in hospitals.
Since α2AAR can bind to a variety of downstream signaling proteins (such as G proteins, inhibitory protein arrestin, etc.
), This produces different physiological effects (eg, analgesia, sedative) [1].
Therefore, the development of a new agonist that is structurally different from traditional imidazoles such as clonidine and dexmedetomidine, and that selectively (biasedly) activates specific signaling pathways downstream, may eliminate or reduce its sedative effect and thus be used
as a non-opioid analgesic.
Figure 1 Opioid analgesic abuse crisis
(Source: https://avanospainmanagement.
com/posts/reducing-postoperative-opioids/).
Professor Du Yang's team, Hong Kong Chinese University (Shenzhen) School of Medicine/Kobilka Institute for Innovative Drug Development, and Professor Peter Gmeiner's team at the University of Erlangen-Nuremberg and Brian of the University of California, San Francisco Professor Shoichet's team and other common communications were published in the international leading scientific journal Science (IF=63.
71) entitled " Structure-based discovery of nonopioid analgesics acting through the α 2A-adrenergic receptor"
.
Jun Xu, postdoctoral fellow at Stanford University School of Medicine and former research assistant at the Kobilka Institute, Elissa Fink, PhD student at the University of California, San Francisco, and Dr.
Harald of the University of Erlangen-Nuremberg Hubner et al.
tied for first author
.
The work reported the development
of non-opioid-free analgesics targeting α 2A adrenergic receptors based on structural guidance.
(Further reading: The latest research results of Du Yang's team can be found in the "Logical Neuroscience" report (click to read): Nat Commun.
) —Du Yang's team in revealing the activation and allosteric regulation mechanism of human orphan receptor GPR88).
Based on the resolved cryo-EM structure of α2A adrenergic receptors, this study uses leading molecular docking technology, medicinal chemical modification, structure-assisted design, animal experiments and other comprehensive means to obtain drug candidates with strong analgesic effects in animal
experiments.
This research strategy has also achieved some successful work in the past and represents the future direction of drug discovery based on GPCR structure [4].
Specifically, the authors screened 17 ligands α2AAR from 301 million virtual molecules through molecular docking, with affinities as low as possible 12 nM, many of which are partial agonists and biased towards theGi and Go signaling pathways
.
The researchers analyzed the structure of two ligands, the α2AAR complex, by single-molecule cryo-EM, confirmed the prediction of molecular docking, and used this as a template to further optimize the ligand structure
.
' 9087 (initially screened agonist, median effective concentration (EC50) 52 nM) and its two analogues, '7075 and PS75 (EC 50 4.
1 and 4.
8 nM, respectively), Analgesic effects were shown in several in vivo pain models without sedative and off-target effects (Figure 2).
These newly discovered agonists exhibit abundant druggable potential and exhibit advantages
over drug dependence (compared to opioids) and sedation (compared to imidazoles dexmedetomidine, etc.
).
Fig.
2 Development process of non-addictive painkillers targeting adrenergic receptors
(Source: Fink EA, et al.
) , Science, 2022)
The work revealed three key findings
.
First, effective agonists can be screened directly from large databases and can be independent
of known agonists.
Molecular docking can identify molecules with in vitro activity and make them active in vivo through structural activity optimization
.
Although direct detection of an effective agonist is rare, direct hits of an effective ligand in this experiment do indicate the advantages of a large virtual screening library, especially the efficacy
of a different chemotype from a known ligand.
Second, although the '9087 and its analogues '7075 and PS75' are not biased towards the Gi/o/z pathway β suppress protein pathway activity, but was not designed with functional selectivity as the design criterion, possibly because of their new chemotype
.
Although similar situations often occur in other studies, the logic that uncharacterized chemical forms cause new signaling pathways needs to be studied
more.
Third, '9087 and its analogues '7075, PS75 do not cause sedation or dyskinesia at analgesic doses, which has a wide range of application prospects and has been proven α2A AR agonists can be differentiated
according to two effects.
Fig.
3 Analgesic effect in mouse neuralgia models of the new agonists '9087 and PS75
(Source: Fink EA, et al.
) , Science, 2022)
Previously undiscovered ligand-receptor interactions confer new pharmacologies
.
Some previously uncharacterized agonists perform abnormal pain and analgesia in neuropathic and inflammatory pain models and relieve acute nociception
in normal animals.
The most promising are '9087 and PS75, both of which have a strong analgesic effect, do not have the sedative side effects of dexmedetomidine, and are orally
available.
Although cardiovascular side effects have not been well studied, these drug precursors are bringing new light to new non-opioid pain therapies
.
However, innovation and development from target identification, drug discovery, animal experiments, drug substitutes, clinical trials to marketing approval is a very long, high-risk and huge cost process
.
And the completely structure-based drug screening strategy is a new direction
for targeting GPCR drug discovery in recent years.
Although there is still a lot of work to be done before listing, we believe that the future can be expected
.
Original link:
Corresponding author: Professor Du Yang
(Photo courtesy of: Du Yang team, School of Medicine, Chinese University of Hong Kong, Shenzhen / Kobilka Institute of Innovative Drug Development).
Corresponding author bio (swipe up and down to read).
Du Yang, a national high-level talent, principal scholar, excellent teacher
in Shenzhen.
Researcher, School of Medicine, Chinese University of Hong Kong, Shenzhen/Kobilka Institute of Innovative Drug Development.
After receiving his Ph.
D.
from the University of Science and Technology of China, he went to Stanford University School of Medicine in the United States to work as a postdoctoral fellow and research scientist for many years under the 2012 Nobel Prize winner Professor Brian Kobilka, and received a full scholarship from the American Heart Association and the University of Michigan Ann Arbor School of Medicine tenure-track assistant professorship, etc
.
In the past three years, he has been working as a corresponding author (including co-authors) in Cell, Science, and Cell Research 、Nature Comm.
, Science Advances, etc.
have published more than a dozen cutting-edge works
in biomedicine.
It has been selected into the national high-level talent plan at all levels such as provinces and municipalities, and has undertaken a number of scientific research projects at all levels to carry out research
.
At present, the laboratory has abundant scientific research funds, and sincerely recruits colleagues interested in basic and translational research such as structural research of important drug targets, antibody development and new drug discovery, and actively apply for postdoctoral and doctoral/master students
.
Please send your CV and three letters of recommendation to yangdu@cuhk.
edu.
cn for further contact
.
[1] Ann Neurol-Chen Wanjin/Fan Dongsheng's research group revealed that heterozygous mutations in the SerRS gene cause peroneal muscular atrophy
[2] Sci ADV—astrocyte subset plasticity regulates heroin relapse, providing a basis for the treatment of drug addiction relapse
[3] J Neurosci-Hu Bo's research group revealed the role of dorsal hippocampal small albumin-positive interneurons in joint motor learning and their network activity mechanism
[4] CNSNT—Gu Xiaoping's team revealed that enhancing astrocyte networks can improve brain network abnormalities and cognitive dysfunction caused by long-term isoflurane anesthesia
[5] Nat Aging—Glial cells in mouse with Alzheimer's disease are involved in synaptic clearance through the complement pathway
[6] J Neuroinflammation—Chen Gang's research group revealed that Schwann cell Pannexin 1 regulates neuropathic pain by mediating inflammatory responses
[7] NPP-Luo Xiongjian's research group uses Mendelian randomization to screen potential drug targets for the treatment of mental illness
[8] Adv SCI-Chai Renjie's team has made important progress in the regeneration of functional hair cells of cochlear organoids
[9] J Neuroinflammation—Tang Yamei's team discovered the mechanism by which pregabalin mitigates microglia activation and neuronal damage in radiation brain injury
[10] Transl Psychiatry—Accelerated aging of brain function in patients with major depression: evidence from large Chinese participants
Recommended high-quality scientific research training courses[1] Symposium on Single Cell Sequencing and Spatial Transcriptomics Data Analysis (October 29-30, Tencent Online Conference)[2] Symposium on Patch-clamping and Optogenetics and Calcium Imaging Technology (October 15-16, 2022 Tencent Conference) Conference/Forum Preview & Review[1] Preview | Neuromodulation and Brain-Computer Interface Conference (October 13-14, Beijing time) (U.
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[2] Conference report - The human brain and the machine are gradually getting closer, and the brain-computer interface "black technology" is shining into reality
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End of this article
