Scientists have discovered a compound that restores the capacity to form new memories in aging rats, likely by improving the survival of newborn neurons(神经原,神经细胞) in the brain's memory hub. The research, funded in part by the National Institutes of Health, has turned up clues to a neuroprotective mechanism1 that could lead to a treatment for Alzheimer's disease. "This neuroprotective compound, called P7C3, holds special promise because of its medication-friendly properties," explained Steven McKnight, Ph.D., who co-led the research with Andrew Pieper, M.D., Ph.D., both of University of Texas Southwestern Medical Center, Dallas. "It can be taken orally, crosses the blood-brain barrier with long-lasting effects, and is safely tolerated by mice during many stages of development."
The researchers report on their findings July 9, 2010 in the journal Cell. Their work was funded, in part, by the NIH's National Institute of Mental Health (NIMH), a NIH Director's Pioneer Award funded through the Common Fund and managed by the National Institute of General Medical Sciences, and National Cancer Institute.
"This striking demonstration4 of a treatment that stems age-related cognitive5(认知的,认识的) decline in living animals points the way to potential development of the first cures that will address the core illness process in Alzheimer's disease," said NIMH Director Thomas Insel, M.D.
Physical activity, social, or other enriching experiences promote neurogenesis(神经发生,神经形成) – the birth and maturation of new neurons. This growth takes place in the dentate gyrus(齿状回,齿状圆) , a key area of the brain's memory hub, the hippocampus(海马) . But even in the normal adult brain, most of these newborn neurons die during the month it takes to develop and get wired into brain circuitry. To survive, the cells must run a gauntlet(长手套,严酷考验) of challenges. Newborn hippocampus neurons fare much worse in aging-related disorders7 like Alzheimer's, marked by runaway8 cell death.
In hopes of finding compounds that might protect such vulnerable neurons during this process, Pieper, McKnight and colleagues tested more than 1000 small molecules9 in living mice. One of the compounds, designated P7C3, corrected deficits10 in the brains of adult mice engineered to lack a gene3 required for the survival of newborn neurons in the hippocampus. Giving P7C3 to the mice reduced programmed death of newborn cells – normalizing stunted11 growth(生长萎缩,矮化生长) of branch-like neuronal extensions and thickening an abnormally thin layer of cells by 40 percent. Among clues to the mechanism by which P7C3 works, the researchers discovered that it protects the integrity(完整,正直) of machinery12 for maintaining a cell's energy level.
To find out if P7C3 could similarly stem aging-associated neuronal death and cognitive decline, the researchers gave the compound to aged2 rats. Rodents13 treated with P7C3 for two months significantly outperformed their placebo14(对照剂) -treated peers on a water maze15 task, a standard assay16 of hippocampus-dependent learning. This was traced to a threefold higher-than-normal level of newborn neurons in the dentate gyrus of the treated animals. Rats were used instead of mice for this phase of the study because the genetically17 engineered mice could not swim.
The researchers pinpointed18(准确地找到) a derivative19 of P7C3, called A20, which is even more protective than the parent compound. They also produced evidence suggesting that two other neuroprotective compounds eyed as possible Alzheimer's cures may work through the same mechanism as P7C3. The A20 derivative proved 300 times more potent6(有效的,强有力的) than one of these compounds currently in clinical trials for Alzheimer's disease. This suggested that even more potent neuroprotective agents could potentially be discovered using the same methods. Following up on these leads, the researchers are now searching for the molecular20 target of P7C3 – key to discovering the underlying21(潜在的,根本的) neuroprotective mechanism.