Molecular 'Piggyback Ride' Carries Alzheimer’s Protein Into Brain [potential breakthrough]

University of Rochester Medical Center ^ | 6/24/2003

[B.Bumbleberry]

Scientists studying the brains of mice have discovered how the toxic protein that destroys the brain cells of Alzheimer's patients enters the brain. When the researchers gave mice a drug that blocked the process, flow of the protein into the brain was virtually halted and existing accumulations of it in the brain plummeted by more than 70 percent. The results of the research will be published in the July 1 issue of Nature Medicine.

The new findings center on amyloid beta, a tiny protein molecule that accumulates over time to form tell-tale plaques in the brain tissue of Alzheimer's patients. While various cells within the brain itself produce amyloid beta, that amount may be just the tip of the iceberg. Mounting evidence suggests that the bulk of amyloid beta is produced in cells throughout the body and gets circulated in the blood. The new study reveals for the first time how the protein gets from the blood into the brain, thwarting the brain's elaborate filtration mechanism that normally keeps away toxins. In mice that had been genetically engineered to develop Alzheimer's, the process ran wild, pouring amyloid beta into the brain at eight times the rate of healthy mice.

"For more than a decade we've known that this protein wreaks havoc in the brains of Alzheimer's patients, but we haven't known how it gets there or how to prevent it from getting there. This study answers both of those basic questions, and opens an entirely new avenue for the treatment of Alzheimer's disease," said lead author Berislav Zlokovic, M.D., Ph.D., of the University of Rochester Medical Center.

Since 1992, Zlokovic's research has focused on how amyloid beta protein in the blood is able to pass through the blood-brain barrier, a thin layer of cells that lines the inner walls of the brain's blood vessels. The blood-brain barrier blocks the passage of toxins while allowing the flow of oxygen, sugar, and other nutrients to brain cells. In the current study, Zlokovic and his colleagues found that amyloid beta protein molecules cannot flow through the blood-brain barrier unaided. Rather, they get through by riding piggyback on a much larger molecule, called RAGE, which is nontoxic and moves unfettered across the blood-brain barrier. Normally, RAGE is produced in small amounts by the cells that form the blood-brain barrier. But in mice that were genetically engineered to develop Alzheimer's disease, Zlokovic found that RAGE was produced in huge amounts – eight times normal – and ferried an avalanche of amyloid beta into the brain.

Zlokovic became interested in RAGE several years ago while studying amyloid beta proteins that had been culled from the brains of Alzheimer's patients who, years before their deaths, had agreed to donate their brains to the University's Alzheimer's research program. In the donated brain tissue, Zlokovic spotted something he hadn't seen before: Some of the amyloid beta proteins were attached to much larger molecules. The larger molecules turned out to be RAGE (short for receptor for advanced glycation end products), which had been observed in brain tissue by other researchers, but whose function was a mystery. Zlokovic's new study was conceived as a series of experiments designed to solve it.

In the first experiment, he injected mice with an agent, called anti-RAGE, that binds to RAGE molecules and disables them, making them unable to bind with amyloid beta proteins. Then he injected amyloid beta proteins into the mice and observed that, with the RAGE molecules disabled, transport of the amyloid beta proteins across the blood-brain barrier came to a sudden halt.

In another experiment, he administered a RAGE look-alike, called soluble RAGE. The soluble RAGE molecules attached themselves to amyloid beta proteins, but unlike RAGE, were unable to transport the proteins across the blood-brain barrier. With the amyloid beta proteins bound to the soluble RAGE molecules, however, the RAGE molecules naturally present in the mice were not able to bind to the proteins. In this experiment, like the first, the flow of amyloid beta across the blood-brain barrier also stopped abruptly.

With evidence that RAGE was involved in the transport of amyloid beta across the blood-brain barrier, the research team obtained mice in which the gene that produces the RAGE molecule was disabled or "knocked out" by genetic engineering. When the researchers injected amyloid beta protein into these mice, none of it crossed the blood-brain barrier, confirming RAGE's function.

Another experiment was conducted in mice that were genetically engineered to develop Alzheimer's disease. In half of the mice the team administered soluble RAGE once a day; the remaining mice were not given the agent. After three months, the researchers compared the amyloid beta levels in the brains of each group. In the group that had received soluble RAGE, both the amount of amyloid beta protein in their brains and the size of amyloid plaques were reduced by 70 percent compared to the mice that did not receive the agent.

The researchers also found that as RAGE transported increased levels of amyloid beta into the brain, blood flow within the brain was reduced by half. When soluble RAGE was administered to block the process, blood flow to the brain returned to normal. The new finding – that blood flow to the brain is sharply reduced in Alzheimer's mice – suggests that decreased cerebral blood flow may partially account for the confusion and dementia that plague Alzheimer's patients.

"The experiments in this study revealed a great deal of new information about Alzheimer's disease," said Zlokovic. "First, it is now very clear that the body regulates the movement of amyloid beta proteins across the blood-brain barrier. Second, we've shown that that we can use a drug to stop the flow of amyloid beta from the blood to the brain. Finally, we learned that when we block the flow of amyloid beta over time, the brain substantially rids itself of amyloid beta and the amyloid plaques shrink dramatically.

"For patients with Alzheimer's disease, these findings suggest that we can develop a new class of drugs that work by blocking the flow of the toxic Alzheimer's protein into the brain," said Zlokovic.

The researchers are looking ahead to clinical trials of new drug candidates. They are planning studies to determine whether soluble RAGE is likely to be safe when administered to people, and are working to identify other molecules that work in the same way as soluble RAGE.

Collaborators in the study, which was funded by a grant from the National Institutes of Health, included Mark Kindy, Ph.D., from the University of South Carolina and David Stern, Ph.D. and Shi Du Yan, Ph.D. from Columbia University.

[B.Bumbleberry]

Someone with better background can judge whether this represents a true milestone. It appears so from a lay perspective. Wonder what the "anti-RAGE" and "soluable RAGE" chemicals consisted of.

[lepton]

It's also interesting why RAGE molecules would be produced by the cells in the barrier layer, and what is supposed to be happening, but isn't, when the molecules are disabled.

[RippleFire]

bump

[SierraWasp]

"...get through by riding piggyback on a much larger molecule, called RAGE."

I don't know, but I'll bet that punk-rock band will have to change it's name from "Rage Against the Machine," to "Rage against the Molecule!"

No kidding... This is a great breakthrough!!!

Just wish it had been found in time for Ronaldus Magnus!

[The Old Hoosier]

[Grampa Dave]

Lets hope that this works out.

Years ago a neurologists I knew, made an interesting comment about a large % of patients with Alzheimer’s that he had seen and was seeing.

He said that they had incredible immune systems. They were the ones who seldom had colds, viruses and pneumonias were very rare in their lifetime before Alzheimer’s. He wondered if their immune system hadn't turned against them in areas of the brain. He was one of the first to theorize that MS was due to an over response of the immune system on the myelin sheathes.

Hopefully we will make some great breakthroughs here.

[CDHart]

From the article: "Finally, we learned that when we block the flow of amyloid beta over time, the brain substantially rids itself of amyloid beta and the amyloid plaques shrink dramatically. "

Looks like maybe it's reversible, if I'm understanding this properly? What a blessing that would be. I'm an accountant in a skilled nursing facility, and we have a "secure" unit for Alzheimer's/dementia residents. Sad thing.

Carolyn

[RonF]

B.S. in Biology and M.S. in Biochemistry with an emphasis on protein chemistry:

Yes, I'd say that this is definitely a huge milestone. Understanding how the beta amyloid got transported past the blood-brain barrier is big in itself. Coming up with a method for inhibiting it is even bigger.

I haven't looked up RAGE yet, but judging by it's name it's going to be a complex glyco-protein (a protein molecule with pieces of carbohydrate attached, both having specific makeup and structure). Such things can be synthesized once the structure and sequences are completely determined (grunt work, but highly doable). Or, they can find a way to genetically engineer some other organism to produce it biologically. We're taking expensive but effective therapy.

[Cicero]

It sounds very promising. There are still questions to be answered. Does it have side effects? Playing with a protein that governs transfers through the body/brain barrier is obviously a delicate matter. It might affect other transfers or balances, perhaps in some subtle, long-term way. But still very promising, especially for people who are clearly Alzheimer's prone.

[B.Bumbleberry]

Well, they already applied an "anti-RAGE" molecule and a "soluable RAGE" molecule, so they already seem to have the chemistry down. Just what these are is what interests me.

My mother died of Alzheimer's, Cindy. A horrible fate for a family, who suffer more than the person with the disease as they watch their loved slowly disappear.

[B.Bumbleberry]

Sorry Carolyn. I meant you, not "Cindy". My brain is slipping. Hope it's not you know what.

[cajungirl]

This is exciting. And if you have early altzheimers, you may be willing to take a chance on something with long term effects. This is very hopeful. For a long time the beta amyloid and other substances, tau protein, have been known as part of the process of developing plaque and tangles in the brain. It may be that the amyloid is the most important. And possibly reversible. This would be an incredible thing, hope it comes soon. Think of the effects.

[RonF]

The anti-RAGE molecule could have been developed experimentally, by either taking RAGE molecules isolated from mice, inducing mice to make antibodies to them, and then using those antibodies to affect the RAGE molecules, or else by simply testing simple molecules until they found one that blocked the beta-amyloid from binding to RAGE. The "soluble" RAGE could have been created by treating the RAGE molecule with an agent that removed the lipophilic moiety of it without understanding exactly what portion was removed or what the extent was.

Both of which are a ways from understanding the exact sequence and 3-D structure of the protein, the sequences of the carbohydrate portions, and where on the protein the carbohydrate portions bind. All of which will have to be understood if the molecule is to be synthesized, especially if that synthesis is chemical, not totally biological. And it would be quite helpful to understand the location and chemistry of the beta amyloid binding site as well. As a previous poster stated, we don't know what other effects administering RAGE, or the soluble RAGE, will have on other blood-brain processes. There's a lot of biochemistry yet to be done to take this out of the lab and into a production facility.

But this is a wonderful start, and Alzheimer's is no orphan drug situation. An effective therapy for this is something that the drug companies will jump all over.

[cajungirl]

HMMM,,,I wonder what drug co funded the research if any did,,,if so, now is the time to buy!

[cajungirl]

NIH funded it,,drats!

[RonF]

Get yourself a copy of the July 1 issue of Nature; there should be information in there about where the funding came from. If a foundation is named, you might have to drill down some.

There may be no drug company funding this at all. It could all be funding from NIH, the school, and various foundations.

[kms61]

And I certainly can't see any reason why someone wouldn't want to take a chance on it. Whatever the side effects might be, that surely can't be worse than Alzheimers.

A former girlfriend's mother contracted a disease similar to Alzheimer's (Pick's disease, I think) in her early forties. Very sad for the whole family.

[CDHart]

That's OK -- Cindy's a prettier name, IMO, anyway. What I don't understand about Alzheimer's is that years ago, you never heard about it at all. And I don't think that those who were called "senile" were nearly as large a percentage of the population as Alzheimer's patients are. Unless it's just that I work here and see more of them.

Carolyn

[RonF]

Drilling down into the original press release reveals that the whole thing was funded by NIH. Patents will be forthcoming, probably owned by the University, once the whold system becomes better characterized.

[KC Burke]

.....I almost hate to do this...but not enough to avoid it....

Hey, Laz! There is hope for you yet!