Medical

Stanford team develops brain-rejuvenating antibodies that let old mice think like youngsters

Stanford team develops brain-rejuvenating antibodies that let old mice think like youngsters
Researchers were able to improve the cognitive function of older mice after blocking a protein's activity on brain cells known as microglia
Researchers were able to improve the cognitive function of older mice after blocking a protein's activity on brain cells known as microglia
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Neuroscientist Tony Wyss-Coray and his team discovered that they were able to improve the cognitive function of older mice after blocking a protein's activity on brain cells known as microglia
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Neuroscientist Tony Wyss-Coray and his team discovered that they were able to improve the cognitive function of older mice after blocking a protein's activity on brain cells known as microglia
Researchers were able to improve the cognitive function of older mice after blocking a protein's activity on brain cells known as microglia
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Researchers were able to improve the cognitive function of older mice after blocking a protein's activity on brain cells known as microglia

In a stunning piece of research, Stanford neuroscientists have hunted down a single gene that encodes a protein responsible for age-related cognitive losses, targeted it with special blocking antibodies, and shown in mice that these antibodies can rejuvenate old brains to work as well as young ones.

It all starts with the microglia, a class of brain cells responsible for immune responses and routine cleanup. Among many other functions, microglia spend their time gobbling up bits of protein deposits and cellular debris that result from normal brain activity, and it's long been known that their garbage-collecting performance deteriorates with age.

Tony Wyss-Coray, Ph.D, professor of neurology and neurological sciences at the Stanford University School of Medicine, thought it was a "decent bet" that the decline in microglial cleanup performance might be linked to the kinds of cognitive declines we see with aging. Both Alzheimer's and Parkinson's diseases, for example, are linked with abnormal activation patterns for genes associated with the microglia.

The hunt for a cognitive decline gene

So Wyss-Coray and his team set off on two concurrent lines of investigation. In one set of experiments, the team chose about 3,000 microglia-related genes they judged could be targeted with drugs. They filled Petri dishes with cultured mouse microglia cells, and gave them a fluorescently-marked latex to chew on, and set about blocking those 3,000 genes one by one to see which ones made the microglia better or worse garbage eaters.

In another set of experiments, the team took the same 3,000 genes, and took measurements of each one's activity levels in young and old mice, looking for which genes changed their activity levels substantially with age.

And when they compared results between the two studies, expecting to find a long list of genes that both change microglial eating patterns and significantly change gene activity levels with age, they were stunned to find just one that fit both categories: a gene known as CD22 that's found in both mice and humans. They followed up and found the CD22 protein was three times as prevalent on the surface of old mice's microglia as on those of young mice.

Blocking the effects of CD22

With a possible culprit identified, the team set about blocking CD22 proteins using specially designed antibodies – ones that are too bulky to break through into cells, but can easily target cell-surface proteins. They injected these antibodies into one side of mice's hippocampuses, and for a control they injected a different antibody that couldn't bind with CD22 into the other side of the hippocampus.

This time, they used fluorescence-labeled bits of myelin to track the brain halves' performance in scavenging waste – myelin being one of the microglia's chief scavenging targets, and also representing something that accumulates in aging brains. Sure enough, 48 hours later, there were far less of these myelin bits left on the side with the CD22-blocking antibodies. They tried the experiment again to see if the scavenging effect would be just as strong for Alzheimer's-related beta-amyloid and Parkinson's-related alpha-synuclein protein debris as it was for those bits of myelin. It was.

So by this stage the team had zeroed in on a gene protein that both decreases microglial scavenging performance and increases its activity with age. It had managed to block the activity of this gene, and shown that the administration of special antibodies could rejuvenate the ability of old brains to clean up a range of garbage proteins that begin to build up in older brains – ones heavily associated with serious cognitive illnesses. So how did these antibodies affect brain performance?

Turning back the hands of time

After a month of continuous CD22 antibody infusion on both sides of mice's brains, the researchers achieved a stunning result. The mice improved their performance on two different learning and memory tests to the point where they significantly outperformed control mice of the same age.

"The mice became smarter," says Wyss-Coray. "Blocking CD22 on their microglia restored their cognitive function to the level of younger mice. CD22 is a new target we think can be exploited for treatment of neurodegenerative diseases."

Stanford immediately rushed to file patents on IP related to the study. As always, it's much too early to get excited about the possibility of this research producing a fountain of youth-style drug that can let octogenarians enjoy the mental acuity of 25 year olds again. But the fact that CD22 is found in both the human and mouse genome certainly makes this a promising research area to keep an eye on.

The team's research appears in the journal Nature.

Source: Stanford Medicine

8 comments
8 comments
BrianK56
This new technology should be administered to an Alzheimer's patient that is in severe decline. This would serve two functions one to save a person's life and two to verify the effectiveness of the trial. So far everything that I have been reading says these breakthroughs are years away for one reason or another.
piperTom
I agree with BrianK56. We could easily find volunteers for such an experimental treatment; these people have nothing to lose. However, I can explain in three letters why (in the US), this is not done: "FDA". Bureaucracy grinds slowly.
itsmeagain
The problem with human studies is that persons with severe dementia, and possibly even mild dementia, are not deemed able to give informed consent.
adelaine
@itsmeagain: sign up for such circumstances when they're diagnosed. I would.
Veronica Roach
Considering the enormity of this potential resolution to something that is going to bankrupt the country if a cure is not found, I would think some kind of 'special consent by caretaker or spokesperson' could be arranged for a human trial. Those with a parent who has the disease would be more than happy for a possible chance to test this ! But there are people who have early-onset of Alzheimer's, not yet fully incapacitated & they might also be willing to try this out. So many potential wonderful discoveries just disappear never to be heard from again, and you have to wonder where they went ! In whose interest is something being squashed ?
Nik
All they need now is a treatment that works for the whole body, and Whoopee! Eternal life! The elixir that has been sought for millennia. However, dont jump for joy yet, because it will probably be withheld, [except for the rich and influential] for the worlds ''protection.''
guzmanchinky
I'm amazed that this isn't already being experimented on old patients with severe mental decline. What in the world would they say no for???
buzzclick
I realize that this might be an over-simplification but, people who, as they age, watch more and more television and consequently veg out daily instead of exercising their brains socially and constructively with demanding tasks, are more likely to develop different kinds of dementia. This is my personal observation.