Study in mice yields Angelman advance
In a new study in mice, a scientific collaboration centred at Brown University lays out in unprecedented detail a neurological signalling breakdown in Angelman syndrome, a disorder that affects thousands of children each year, characterised by developmental delay, seizures, and other problems. With the new understanding, the team demonstrated how a synthesised, peptide-like compound called CN2097 works to restore neural functions impaired by the disease.
‘I think we are really beginning to understand what’s going wrong. That’s what’s very exciting,’ said John Marshall, professor of medical science in the Department of Molecular Pharmacology, Physiology, and Biotechnology and the senior author of the study. However Marshall did caution that it is too early to predict how soon a clinical therapy might arise from the results.
In mice and people, Angelman syndrome arises from flaws in a gene called Ube3A. When it functions properly, the gene limits the amount of a protein called Arc in the brain. Left unchecked by the disease, Arc impairs the development of synapses in the hippocampus. Those neural connections may be essential for proper learning and memory function.
In the new study, Marshall and his colleagues report a series of experiments that show how the abundance of Arc creates such negative effects and how Arc might possibly be defeated and its ill-effects repaired in the lab.
Essentially, Arc interferes with the operation of a synaptic protein called PSD-95, that is required for the actions of a growth factor, known as brain-derived neurotrophic factor (BDNF). This growth factor is released at synaptic contacts and initiates a sequence of molecular interactions necessary for the strengthening of neuronal connections or synapses. In mice with the flawed Ube3A gene, the signals sent by BDNF for memory formation are disrupted.
Although the researchers were surprised by the details they discovered about how Arc hinders the signalling process, they didn’t come to the insight with complete naivete.
In other work, Marshall had been studying CN2097, designed by co-author Mark Spaller of Dartmouth College (Spaller synthesised it during earlier tenures at Wayne State University and Brown). The compound, which binds to PSD-95 was predicted to protect neurons under conditions of stroke and in disease states such as multiple sclerosis. With co-senior author Dennis Goebel of Wayne State, Marshall and Spaller found this to be the case. During the course of those studies the Marshall group learned that CN2097 enhanced the action of brain-derived neurotrophic factor (BDNF) which is known to be critically involved in long-term potentiation (LTP), a phenomenon believed by many neuroscientists to underlie learning.
Then, when University of North Carolina professor and former Brown postdoc Ben Philpot, now a leading expert on Angelman syndrome, returned to campus in 2008 to speak about Angelman syndrome, he showed how LTP is notably lacking in mice with the condition. After discussions with Philpot, Marshall and his group decided to test whether CN2097 might restore LTP in Angelman mice.
Early on, Marshall said, the team figured the defect in LTP in Angelman mice effect had to do with BDNF signalling.
‘We started studying BDNF signalling in the Angelman syndrome mouse and discovered the signalling was defective, so that really was the breakthrough,’ he said. ‘It was completely unexpected. It’s a new way of thinking about this disease.’
That led to the set of experiments now reported, in which the group found that CN2097 essentially protects PSD-95 from interference by Arc, helping to restore BDNF signaling and the formation of stronger synapses. In electrophysiological tests on hippocampal tissue of healthy and Angelman mice, the compound made obtaining LTP significantly easier, although observing LTP in Angelman mice is still more difficult than in normal mice, Marshall said.
Brown University