November 10, 2013
Alcoholism and Drug Abuse Counselors Continuing Education The more detailed view could help scientists and pharmaceutical companies develop drugs that do a much better job of targeting what they're trying to target — and not create side effects caused by a broader blast at the brain proteins. "By learning as much as possible about the structure of the transporter and its complexes with antidepressants, we have laid the foundation for the design of new molecules with better therapeutic profiles and, hopefully, with fewer deleterious side effects," said Gouaux. Gouaux's latest dopamine transporter research is also important because it was done using the molecule from fruit flies, a dopamine transporter that is much more similar to those in humans than the bacteria models that previous studies had used. The dopamine transporter article was one of two articles Gouaux had published in today’s edition of Nature. The other article also dealt with a modified amino acid transporter that mimics the mammalian neurotransmitter transporter proteins targeted by antidepressants. It gives new insights into the pharmacology of four different classes of widely used antidepressants that act on certain transporter proteins, including transporters for dopamine, serotonin and noradrenaline. The second paper in part was validated by findings of the first paper — in how an antidepressant bound itself to a specific transporter. "What we ended up finding with this research was complementary and mutually reinforcing with the other work — so that was really important," Gouaux said. "And it told us a great deal about how these transporters work and how they interact with the antidepressant molecules." Gouaux's discoveries over the years in neurotransmission have established him as one of the top investigators in his field. His research has important implications for understanding the mechanisms of not just antidepressants, but also drugs used for the treatment of a wide range of psychiatric and neurological diseases. Gouaux's co-authors on the dopamine transporter paper were both members of his lab; Aravind Penmatsa, Ph.D., and Kevin Wang, Ph.D. Gouaux's co-authors on the second Nature paper were also members or former members of his lab: Hui Wang, Ph.D.; April Goehring, Ph.D.; Kevin Wang, Aravind Penmatsa and Ryan Ressler, Ph.D. Both papers were funded by the American Heart Association, the National Institute of Mental Health, (1F32MH093120 and 5R37MH070039) and the Howard Hughes Medical Institute. About the OHSU Vollum Institute The Vollum Institute is a privately endowed research institute at OHSU and is dedicated to basic research that will lead to new treatments for neurological and psychiatric diseases. Vollum scientists have transformed the field of neuroscience and, in particular, have been pioneers in the study of cellular signaling, neuronal development, gene regulation and the neurobiology of disease. About OHSU Oregon Health & Science University is a nationally prominent research university and Oregon’s only public academic health center. It serves patients throughout the region with a Level 1 trauma center and nationally recognized Doernbecher Children’s Hospital. OHSU operates dental, medical, nursing and pharmacy schools that rank high both in research funding and in meeting the university’s social mission. OHSU’s Knight Cancer Institute helped pioneer personalized medicine through a discovery that identified how to shut down cells that enable cancer to grow without harming healthy ones. OHSU Brain Institute scientists are nationally recognized for discoveries that have led to a better understanding of Alzheimer’s disease and new treatments for Parkinson’s disease, multiple sclerosis and stroke. OHSU’s Casey Eye Institute is a global leader in ophthalmic imaging, and in clinical trials related to eye disease.