miércoles, 14 de septiembre de 2016

Designing more effective opioids | National Institutes of Health (NIH)

https://www.nih.gov/news-events/nih-research-matters/designing-more-effective-opioids

National Institutes of Health (NIH) - Turning Discovery into Health



Designing more effective opioids




At a Glance

  • Researchers used computer simulations to screen millions of molecules for opioid-like pain-relieving properties.
  • The analyses allowed scientists to create a molecule that effectively alleviates pain in mice, but with fewer side effects than the opioid morphine.
A computer model of the synthesized pain relieving compound PZM21 (blue) docked with the mu opioid receptor (grey).A computer model of the synthesized pain relieving compound PZM21 (blue) docked with the mu opioid receptor (grey).Dr. Bryan Roth, University of North Carolina
Opioids are a class of powerful pain-relieving drugs that work by activating opioid receptors on nerve cells in the body and brain. These pain relievers are generally safe when taken for a short time and as prescribed by a doctor, but are frequently misused because they also produce euphoria. When misused or abused, opioid pain relievers can be addictive and dangerous.
Scientists have identified 3 types of opioid receptors: mu, delta, and kappa. The mu receptors are responsible for opioids’ pleasurable effects and ability to relieve pain. Studies suggest that once activated, the mu receptor turns on 2 signaling pathways. One pathway, mediated by the G protein Gi, underlies opioids’ pain-relieving properties. The other, mediated by the beta-arrestin protein, leads to the undesirable side effects of opioids, such as constipation and slowed breathing.
To search for a potential pain reliever with fewer side effects than current opioids, a research team led by Dr. Bryan Roth at the University of North Carolina and Dr. Brian Shoichet at the University of California, San Francisco, screened more than 3 million compounds for those that may be able to turn on the Gi-mediated pathway, but not beta-arrestin. The study was funded by NIH’s National Institute of General Medical Sciences (NIGMS), National Institute on Drug Abuse (NIDA), and National Institute of Mental Health (NIMH). The findings were reported online in Nature on August 17, 2016.
Using computer modeling, the scientists evaluated each compound in over 1 million structural configurations to determine how well the molecules can physically interact with the mu receptor. The team chose 23 molecules for further pharmacological testing. The researchers then focused on optimizing the structure of the most potent molecule, which strongly activated the Gi pathway but had little effect on beta-arrestin. The resulting compound, called PZM21, was assessed for its effects on pain in mice.
Mice treated with PZM21 showed pain relief comparable to those treated with the opioid morphine, but the effects lasted longer. Unlike morphine, PZM21 did not slow the animals’ breathing, and it caused less constipation. Further, PZM21-treated mice didn’t display the drug-seeking behaviors of those given morphine, suggesting that the drug may have less addictive potential.
“This work demonstrates the power of structure-based design to speed up the development of drugs with optimal signaling and therapeutic properties” explains Dr. Laurie Nadler, who heads NIMH’s neuropharmacology program.
Further study will be needed to determine whether PZM21 could serve as a safe and effective pain reliever in people.

Related Links

Reference: Structure-based discovery of opioid analgesics with reduced side effects. Manglik A, Lin H, Aryal DK, McCorvy JD, Dengler D, Corder G, Levit A, Kling RC, Bernat V, Hübner H, Huang XP, Sassano MF, Giguère PM, Löber S, Da Duan, Scherrer G, Kobilka BK, Gmeiner P, Roth BL, Shoichet BK.Nature. 2016 Aug 17:1-6. doi: 10.1038/nature19112. [Epub ahead of print]. PMID: 27533032.
Funding: NIH’s National Institute of Mental Health (NIMH), National Institute of General Medical Sciences (NIGMS), and National Institute on Drug Abuse (NIDA); Michael Hooker Distinguished Professorship; German Research Foundation; Stanford University Medical Scientist Training Program; and the American Heart Association.

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