DNA-based compound may reduce damages of Alzheimer's disease: study

Source: Xinhua| 2017-12-07 05:56:48|Editor: yan
Video PlayerClose

CHICAGO, Dec. 6 (Xinhua) -- Researchers at Washington University School of Medicine in St. Louis have created a kind of DNA-base molecule targeting APOE protein. APOE is a major Alzheimer's risk gene.

The study has been published on Dec. 6 in the journal Neuron.

The molecule, known as an antisense oligonucleotide, interferes with the instructions for building the APOE protein.

The researchers injected the compound into the fluid surrounding the brains of newborn mice. For comparison, they gave other newborn mice either saltwater or a placebo "oligo" that does not interfere with the APOE instructions. Levels of APOE protein dropped by about half in mice given the APOE compound as compared with those that received the placebo oligo or saltwater.

Two months later, the researchers gave the mice a booster dose of the treatment or the saltwater. They examined the mice's brains at 4 months old. The mice that received the APOE antisense oligos had about half as many amyloid plaques as mice given saltwater. Each plaque triggered only half as much damage to nearby neurons, an indicator that the compound had prevented some of the neurological damage that leads to Alzheimer' s disease.

The researchers then tested whether giving the APOE compound after amyloid plaques appear could prevent further changes to the brain. They introduced either the APOE compound or saltwater into the fluid surrounding the brains of 6-week old mice, and then examined the mice's brains at 4 months old. They found no difference in the number of plaques or the total amount of amyloid beta between the mice that received the compound and those given just saltwater. The compound failed to reduce the amount of amyloid in the mice's brains.

However, in the mice treated with the APOE compound, each plaque triggered only about half as much damage to the surrounding neurons. This suggests that even a late start could reduce the harm posed by amyloid beta.

"If you wanted to target APOE to affect the amyloid process, the best thing would be to start before the plaques form," said senior author David Holtzman, professor and head of the Department of Neurology of Washington University at St. Louis. "But even if you start later, you still may reduce the amount of damage caused by the plaques."

Alzheimer's, which affects one in 10 people over age 65, is marked by brain plaques made of a sticky protein known as amyloid beta. The plaques start forming in the brains of Alzheimer's patients years before the characteristic symptoms of memory loss and confusion appear. APOE4 raises the risk of Alzheimer's partly by encouraging amyloid beta to collect into damaging plaques. People with APOE4 face up to 12 times the risk of developing Alzheimer's than the general population.

"Scientists have been interested in APOE for years but there are only a few examples where researchers have targeted it with a compound in living animals," said Holtzman. "Our findings indicate that APOE is not just involved in Alzheimer's risk and disease progression, but it could potentially be a real target for treatment or prevention."