
Has a "wonder drug" for dementia been discovered? (Spoiler alert: no.)
Media reports of a wonder drug for neurodegenerative diseases like Huntington's disease are overhyped
If media reports of a âwonder-drugâ that could âstop all neurodegenerativeneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons) brain diseases, including dementiaâ seem too good to be true, thatâs because they are. The truth behind the headlines is that researchers tested thousands of already-licensed drugs in worms, and a couple that went on to show beneficial effects in mouse models of two rare forms of dementia. While it gives researchers two new leads, this research doesnât prove anything about these drugs in patients with neurodegenerativeneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons) diseases, and has virtually nothing to do with Huntingtonâs disease at all.
Studying neurodegenerationneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons)
This research was led by Prof. Giovanna Malluci from the university of Leicester. Her team uses various cell and animal models to study neurodegenerativeneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons) diseases, which is a term covering lots of conditions that cause neuronsneuron Brain cells that store and transmit information in the brain to die too quickly. Huntingtonâs is one of these, alongside Alzheimerâs, Parkinsonâs and rarer conditions like prionprion special proteins that can become harmful, and cause disease called prion disease. Like falling dominoes, prion proteins can 'infect' other proteins, making them become harmful. disease (sometimes called “mad cow diseaseâ). In lots of these illnesses, when we look at brain cells under a microscope we see that clumps of protein form. Scientists call these clumps aggregatesaggregate Lumps of protein that form inside cells in Huntingtonâs disease and some other degenerative diseases.

How cells handle damaged proteins
Proteins are the building blocks and machinery of our cells. Proteins start as a long string of molecules, which is then folded into a complex shape. These steps are all vital for the protein to be able to work normally.
Lots of proteins end up getting damaged in the hurly burly of a busy cell. Damaged proteins are tagged, then transported to the cellâs waste recycling plant, called the proteasome, where theyâre stripped down and their components used to build new proteins.
Different proteins form clumps in different neurodegenerativeneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons) diseases. In Huntingtonâs disease, itâs the huntingtin protein, but in Alzheimerâs itâs amyloidamyloid The main protein that builds up in the brains of Alzheimer's disease patients and tau. In Parkinsonâs itâs alpha-synuclein â and so on.
Surprisingly, we still donât know whether the clumping up of proteins is something that harms neuronsneuron Brain cells that store and transmit information, or protects them from harm by hiding poisonous proteins away. It may even differ according to disease, stage and protein.
When proteins build up, it stresses cells out, so theyâre evolved ways of dealing with it. One such self-defence mechanism is called the unfolded protein response. When a cell detects proteins building up, it puts the brakes on making new proteins, allowing the cell time to deal with the clump thatâs already amassed. A sensor called PERK is responsible for putting the brakes on making new proteins.
This self defence mechanism is vital to help cells deal with a build up of damaged proteins.
However, in several neurodegenerativeneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons) diseases, evidence from animal models suggests the unfolded protein response stays too active for too long. For all this time, the neuronneuron Brain cells that store and transmit information isnât making new proteins, starving it of vital machinery it needs to function properly.
Malluci suggests that this ultimately kills neuronsneuron Brain cells that store and transmit information, and reducing the unfolded protein response might be beneficial.
However, itâs important to realise we still only know a little bit about the unfolded protein response. For example, there are some diseases where itâs actually beneficial, and switching it off is bad for neuronsneuron Brain cells that store and transmit information. Already, itâs more complicated than the headlines suggest!
Drugs to tone down the unfolded protein response
âExperience tells us that success in mice is far from a guarantee of success in human patients.â
In 2013, Mallucciâs team put this idea to the test by giving the catchily-named GSK2606414 to mouse models of two neurodegenerativeneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons) diseases â prionprion special proteins that can become harmful, and cause disease called prion disease. Like falling dominoes, prion proteins can 'infect' other proteins, making them become harmful. disease and fronto-temporal dementia. GSK2606414 blocks the PERK sensor â the one that puts the brakes on protein production.
This treatment restored protein synthesis in the mice, kept their neuronsneuron Brain cells that store and transmit information alive and improved symptoms and survival.
Unfortunately, whilst this was good for neuronsneuron Brain cells that store and transmit information, it turned out to be bad for other organs. GSK2606414 was toxic to the pancreas, causing the mice to lose weight and have dangerously high sugar levels, like in diabetes.
Using worms to fish for drugs
In the study thatâs grabbed headlines recently, Mallucciâs team went fishing for drugs that could reduce the unfolded protein response in neuronsneuron Brain cells that store and transmit information, without poisoning other organs.
The sea they trawled was a collection of a thousand existing drugs, many of which are already licenced for use in humans, for other conditions.
The team used a technique called high-throughput screening, which involves testing lots of drugs quickly to look for a specific effect.
The âbaitâ they used was a small worm called C. elegans. These worms stop growing when the unfolded protein response is activated. So Mallucciâs team tested to see whether any of these drugs could allow the worms to start growing again â and they found twenty drugs that did.
The next step was to check whether these drugs had their effect on the worms by the desired mechanism â namely, by reducing the activity of the PERK sensor. They made some cells in the lab that produce light when PERK is activated. Five of the twenty drugs were able to diminish the amount of light produced, suggesting that they were reducing PERK activity.
Three were discounted straight away because of side effects or because they didnât get into the brain, leaving two potential drugs: trazodone and dibenzoylomethane (known as DBM to its friends).
The dynamic duo

Trazodone is a licensed treatment for depression and anxiety but itâs never been studied as a way to slow neurodegenerativeneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons) diseases in humans. Its main side effect is sleepiness, which can be useful in insomnia, but limits its use, particularly in depression where people often already feel low in energy. It can also cause abnormal heart rhythms and low blood pressure when people stand up.
DBM is a a chemical extracted from licorice that has potential as an anti-cancer drug. Itâs unclear at the moment exactly how it works. Unlike trazodone, DBM is not yet licensed for use in humans.
Testing in mice
These two drugs were then tested in mouse models of two neurodegenerativeneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons) diseases â prionprion special proteins that can become harmful, and cause disease called prion disease. Like falling dominoes, prion proteins can 'infect' other proteins, making them become harmful. disease (mad cow) and frontotemporal dementiafrontotemporal dementia a degenerative brain disease that can cause problems with speech and behavior â the same mice in which GSK2606414 had looked good in 2013. The treated mice showed improved symptoms and lived slightly longer than untreated mice.
So these are wonder drugs, right?
Now weâve explained the work in detail, you can hopefully see why we donât think itâs appropriate for the news media, or the scientific community, to herald these two drugs as âwonder drugsâ.
So far all this research has only got as far as being done in animals â worms, to be precise, followed by mice genetically engineered to show features of two rare forms of neurodegenerationneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons).
Experience tells us that success in mice is far from a guarantee of success in human patients.
In fact, so far, no drug that slowed neurodegenerationneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons) in a mouse model has worked when tested in adult human patients.
Though trazodone has already the passed the hurdles to get licensed for depression, it doesnât necessarily follow that it is safe and effective in patients â especially those where a mouse model hasnât yet been tested, like Huntingtonâs disease.
Drugs that work in mice fail in humans for many reasons. The unfolded protein response may be very different in human brain, or may be altered differently in the various forms of neurodegenerationneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons).
âThough trazodone has already the passed the hurdles to get licensed for depression, it doesnât necessarily follow that it is safe and effective in HD patientsâ
At this point, as ever, our advice is to read about the research with a mixture of enthusiasm and skepticism. Weâve been in this situation many times before and, when scaled up and repeated, promising results have often failed to pan out. One upside is that on the whole, we are better at predicting failures in advance and avoiding them.
Enough HDBuzzkill⊠COULD these work in HD?
Letâs pause for a moment, turn our frown upside-down and figure out how we could show that trazodone or DBM does work for Huntingtonâs disease.
The first step would be to test them in a genetic mouse model of HD. There are lots of different HD mice available, and because every case of HD is caused by the same basic genetic mutation, it may be that âourâ mice will turn out to be better than those of other diseases, at predicting success in human patients. However, even HD mice share that zero percent success rate, so far.
If either drug looks good in one HD mouse, it would be wise to test it again, in at least one different mouse model, to make sure the benefit is big enough and consistent across models â and also to look in the brains of the mice to make sure the drug was doing what it was supposed to do in cells.
The final step would be moving to human trials. Itâs likely the regulatory agencies would give trazodone a bit of a break because itâs already widely used. But it would still need to be tested first for safety in people with Huntingtonâs disease, before a bigger trial to see whether it slows the disease. DBM would probably need to be fully tested from scratch.
Itâs possible that somewhere, a team of researchers is already testing these drugs in HD mice, or is planning to. But even mouse research is expensive and time consuming, so these potential new leads need to be considered alongside every other treatment approach under investigation when resources are allocated.
Thankfully, the Huntingtonâs disease research community is well connected and well-placed to assess the whole scientific picture, not just over-hyped headlines, in deciding what drugs to test and how.
If we hear anything about this work advancing in HD, weâll be sure to let you know. For now, in an era of âfake newsâ, we can draw real hope from looking beyond the headlines and exploring out together what progress is actually being made in fighting dementia and neurodegenerationneurodegenerative A disease caused by progressive malfunctioning and death of brain cells (neurons).
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