Changing jobs: converting other cell types into neurons

Because HD causes a loss of neurons in the brain, some researchers are exploring ways to replace them. Working with HD mice, scientists recently showed that supportive brain cells called glia can be coaxed into becoming new neurons.

Researchers have known for quite some time that HD causes a progressive loss of neurons. But what if we could find a way to fill their place? In a new report, researchers used an intriguing strategy in living mice to do just that – they converted a different type of brain cell into neurons, with very promising results.

Neurons aren’t alone

In HD research we spend a lot of time talking about neurons. And understandably so! Neurons are the cell type in the brain most affected by HD, and they are the cells that exchange messages to drive our movements, moods, and memories. You can think of neurons like the computer programmers of the brain – they convert information into action.

In particular, neurons in an area of the brain called the striatum – striatal neurons – tend to be most vulnerable to the mutation that causes HD. Right now no one knows exactly why those cells are especially vulnerable. But researchers know that many of the symptoms of HD are related to the loss of neurons in this area of the brain.

Brain cells: There are lots of different cell types in the brain; neurons are just one. But neurons happen to be a particularly vulnerable cell type in HD.
Brain cells: There are lots of different cell types in the brain; neurons are just one. But neurons happen to be a particularly vulnerable cell type in HD.

But there are lots of different types of cells in the brain. In fact, the most abundant cell type in the brain isn’t neurons – it’s a cell type called glia. Glia is a general term that describes several kinds of cells in the brain and spinal cord that provide support, insulation, and protection. You can think of glia like the body guard of the brain – they make sure other cell types have the support they need to function.

One type of glia are brain cells called astrocytes. A lot of the nervous system is made up of astrocytes – 30% in fact! Because astrocytes are everywhere in the brain, they’re also present in the areas where neurons degenerate due to HD – the striatum. And unlike neurons that stop dividing when they’re fully mature, glia continue to divide.

Recently, scientists took advantage of the abundance of glia in the brain and their ability to reproduce. They used an experimental technique in the brains of mice to turn astrocytes into new, functioning neurons. So to stick with our analogy, they encouraged the body guards of the brain to change jobs and become computer programmers.

neuron by any other name

The work was led by Dr. Gong Chen, a former professor at Penn State University, who is now leading the Institute of CNS Regeneration at Jinan University in China. His team took advantage of a technique to turn cells that aren’t neurons into neurons – something called direct conversion.

Recently, scientists took advantage of the abundance of glia in the brain and their ability to reproduce. They used an experimental technique in the brains of mice to turn astrocytes into new, functioning neurons. 

This technique allows researchers to coax different cell types, such as astrocytes, into becoming neurons, by adding chemical cocktails to boost the action of genes that influence a cell’s role. This is a bit like changing the job description of a certain cell type – but this has been done before. Many times in fact. It’s old news that scientists can take one cell type grown in a laboratory dish and directly turn it into a neuron.

So what did this report add, and why was it worthy of publication in the prestigious journal Nature Communications? Because these authors did direct conversion inside the brains of living mice! They used a harmless virus to deliver their chemical cocktail that gave a genetic nudge to the astrocytes, encouraging them to change jobs and become neurons. In this way, they were able to turn abundant astrocytes into potentially valuable striatal neurons– a very cool accomplishment!

We know what you may be thinking – “Did you just say virus?!” We all get a little weary when we hear that word, especially in the days of COVID-19! But rest assured, this is a very harmless method used frequently in biology.

It’s actually just the outside of the virus that’s used, without any of the inside bits that typically make viruses so harmful. Similar to a letter in an envelope – researchers here are repurposing an envelope and adding something new inside. So the old message is removed, and the envelope is sent with new instructions that body guards should change jobs and become computer programmers!

Encouraging cells within the brain to change jobs allows other cell types to become neurons. This approach provides a source of new, potentially valuable, neurons to replace those that are lost in HD.
Encouraging cells within the brain to change jobs allows other cell types to become neurons. This approach provides a source of new, potentially valuable, neurons to replace those that are lost in HD.

Changing jobs within your company vs, going to a new company

An important finding from the paper was that the overall number of astrocytes didn’t decrease over time. This is related to the point we made above about astrocytes – they continue to divide. So even though the researchers turned some of the astrocytes into neurons, the astrocytes that remained produced more astrocytes to replace them. This approach provided a source of new striatal neurons for these HD mice without affecting the astrocyte population! And because these astrocytes are already located in the striatum, the intervention occurs in the exact area of the brain that could use more neurons.

Chen and colleagues also showed that these new neurons in the striatum fired signals just like native neurons. They also connected with other areas of the brain, just like native neurons. Most compellingly, with the addition of these new neurons in the striatum, the HD mice performed better on movement tests and had an extended lifespan. All very exciting and promising results!

The idea of adding back lost neurons in HD isn’t new. The big difference is that previous studies have added new cells through surgery, performing what’s called cell transplantation. So while direct conversions, like the experiments performed by Chen and his team, are like changing jobs within the same company, cell transplantations are like getting a job at a new company.

Several research groups have experimented with cell transplantation as a therapy for HD, and some of these options are moving toward clinical trials. More recently, cell transplantations have been done with immature cells known as stem cells or neural progenitor cells that haven’t fully committed to becoming a specific cell type yet. The benefit of using immature cells is that they can obtain cues from the surrounding environment, letting them know what cell type is needed.

Most compellingly, with the addition of these new neurons in the striatum, the HD mice performed better on movement tests and had an extended lifespan. 

Cell transplantations have shown promise, but can come with some risks. There’s no guarantee that the cells will become exactly the type of neuron you want. And there’s no guarantee that the cells will survive long-term because that’s not their native environment.

Chen’s group got around these issues by triggering specific biological machinery to convert astrocytes into striatal neurons. The researchers knew exactly what type of neuron they were going to get in the end. And because the astrocytes they targeted were already present in the striatum, they knew the new neurons would be in exactly the right place!

Ready for prime time?

One thing to keep in mind with this approach is that the astrocytes used to make the neurons come from the HD mouse. That means the new striatal neurons also contain the genetic error (mutation) that causes HD. Researchers don’t yet know what that means for the lifespan of those neurons.

While the results from this study are very exciting and potentially provide another tool in our belt to combat HD, this study was done as a proof-of-concept and still has a long way to go before it reaches the clinic. But so far, even though the new neurons carry the HD mutation, the direct conversion technique seems to improve HD-related symptoms in the mice.

Follow up studies are likely to try this technique in larger animals or to test it in combination with huntingtin lowering, which will undoubtedly provide interesting results. We’ll be eagerly waiting!

Dr. Leora Fox works for the Huntington’s Disease Society of America. HDSA has been in touch with and has a nondisclosure agreement with NeuExcell, the company that funded the work described in this article.
Source: HDBuzz



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