3D Printing Cells with DNA Velcro


The complex, 3D micro-anatomy of the human liver. (Image source: WikiMedia Commons)

One of the Holy Grails of stem cell research is growing body parts to replace those damaged by disease or injury. Enormous strides have been made in a key first step: mastering recipes for maturing stem cells into various specialized cell types. But a lawn of, say, liver cells in a petri dish is not a functioning liver. Organs have complex, three-dimensional structures with intricate communication between multiple cell types.

Scientists are actively devising methods to overcome this challenge. For instance, cultivating cells onto biological scaffolds help mold the cells into the shape of a particular organ or tissue. And retooled 3D printers using “bio ink” can seed layers of different cells onto these scaffolds to create specified structures.

This week, a UCSF team added an ingenious new tool to this tissue engineering tool kit.  As reported on Monday in Nature Methods, the lab of Zev Gartner took advantage of DNA’s Velcro-like chemistry to build layers of different cell types in a specified pattern.

DNA – it’s not just for genetics anymore


A DNA fragment is made of two complimentary strands that bind together with high specificity. (Image source: Visionlearning)

DNA is a molecule made of two thin strands. Each strand is specifically attracted to the other based on a unique sequence of genetic information. So if two strands of a short DNA fragment are peeled apart, they will only rejoin to each other and not some other fragment with a different sequence.  While DNA usually resides in the nucleus of a cell, the team worked out a method to temporarily attach copies of a strand of DNA on the outside of, let’s call it, “cell A”. The opposite strand of that DNA fragment was attached to “cell B”. When mixed together the two cells became attached to each other via the matching DNA sequences. Other cells with different DNA fragments floated on by.

The screen shot below from a really neat time-lapse video, which accompanies the research publication, shows how a rudimentary 3D cell structure could be built with a series of different cell-DNA fragment combinations. In this case, the team first attached DNA fragments onto a petri dish in a specific pattern. At the thirty-second mark in the video, you can see that cells with matching DNA fragments have attached to the DNA on the dish.

Screen Shot 2015-09-02 at 8.48.16 AM

This video demonstrates the assembly of 3D cell structures with the help of DNA “Velcro” (image source: Todhunter et al. Nature Methods 2015 Aug 31st)

The new technique, dubbed DNA programmed assembly of cells (DPAC), opens up a lot possibilities according to Gartner in a UCSF press release:

 “We can take any cell type we want and program just where it goes. We can precisely control who’s talking to whom and who’s touching whom at the earliest stages. The cells then follow these initially programmed spatial cues to interact, move around, and develop into tissues over time.”

The Quest still continues with possible victories along the way

 Of course, this advance is still a far cry from the quest for whole organs derived from stem cells. The cell assemblies using DPAC can only be grown up to about 100 microns, the thickness of a human hair. Beyond that size, the innermost cells get starved of oxygen and nutrients. Gartner says that obstacle is a current focus in the lab:

“We’re working on building functional blood vessels into these tissues. We can get the right cells in the right positions but haven’t figured out how to perfuse them with blood or a substitute efficiently yet.”

In the meantime, building these small 3D “organoids” from stem cells certainly could be put to good use as a means to test drug toxicity on human tissue or as a way to study human disease.

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Going back to figure out how the embryo makes muscles led team to way to mass produce muscle fibers

Sometimes in science what seems like the simpler task turns out to be the hardest. We have written extensively about research teams building mini-organs in lab dishes turning stem cells into multiple layers of tissues organized and functioning, at least in part, like the kidney, liver or stomach they mimic. Given these successes and the relative simplicity of our muscles, you would have thought we would have petri dishes with bulging biceps by now. We don’t. But a team at Harvard and Brigham and Women’s hospital has made a major stride toward that goal.

Smooth muscle cells grown from embryonic stem cells (courtesy Sanford-Burnham Institute).

Smooth muscle cells grown from embryonic stem cells (courtesy Sanford-Burnham Institute).

While previous work has created small amounts of short muscle fibers from stem cells, the Brigham group created large quantities of millimeter-long muscle fibers. This level of muscle development could produce therapeutic quantities of new muscle that would be needed to treat patients with muscular dystrophy. This goal has sent many teams back to the lab looking for better ways to direct stem cells to become muscle.

The current work, published this week in Nature Biotechnology, went back to the basics and tried to understand each step that a stem cell goes through on the way to becoming muscle in the embryo. Medical Daily wrote a piece on the work, and used a quote in the Brigham press release from the senior author Olivier Pourquie:

“We analyzed each stage of early development and generated cell lines that glowed green when they reached each stage. Going step by step, we managed to mimic each stage of development and coax cells toward muscle cell fate.”

Stem cell scientist often find that going back to learn and mimic the natural steps of development works better than guessing what factors are most important in a cell’s fate. Now that they hold a map to the path between stem cell and muscle fibers, they can use it to study many different muscle diseases and work toward therapies for those often-untreatable conditions.

“This has been the missing piece: the ability to produce muscle cells in the lab could give us the ability to test out new treatments and tackle a spectrum of muscle diseases,” Pourquie said.

CIRM funds a dozen projects working to understand and develop therapies for muscle disease.

Two studies show genes and their switches critical to brain cancer’s resistance to therapy

Two California teams discovered genetic machinery that cancer stem cells in high-grade brain cancers use to evade therapy. One CIRM-funded team at Cedars-Sinai in Los Angeles pinpointed a family of genes that turn off other genes that chemotherapy targets —effectively hiding them from the chemo. The other team at the University of California, San Diego (UCSD), found a culprit switch among the molecules that surround genes in the DNA.

Chemical switches like those found at UCSD control much of how our cells function. These so called epigenetic markers can toggle between on and off states and result in two cells with the same genes behaving differently. That is what the San Diego team found when they transplanted cells from the same glioblastoma brain cancer into different mice. Some readily formed new tumors and some did not.

“One of the most striking findings in our study is that there are dynamic and reversible transitions between tumorigenic and non-tumorigenic states in glioblastoma that are determined by epigenetic regulation,” said senior author Clark Chen. “This plasticity represents a mechanism by which glioblastoma develops resistance to therapy.”

The switch the cancer stem cells used in this case is called LSD1 and the researchers hope to be able to learn how to manipulate that switch to make the brain cancer stem cells more vulnerable to therapy.

Brain caner cells (left) that don’t readily form new tumors can spontaneously acquire cancer stem cell characteristics (right).

Brain caner cells (left) that don’t readily form new tumors can spontaneously acquire cancer stem cell characteristics (right).

The family of genes fingered by the Cedars team control the on-off status of a number of genes associated with cancer stem cells. That family, called Ets factors, is quite large but the brain tumor model used by the team allows them to quickly determine which genes are being impacted by the Ets factors.

“The ability to rapidly model unique combinations of driver mutations from a patient’s tumor enhances our quest to create patient-specific animal models of human brain tumors,” said Moise Danielpour the senior author on the study

The team’s next step: testing the function of the various Ets factors to see what their specific roles are in tumor progression.

Given the dismal five-year survival rate for high-grade brain cancers these advances in understanding their genetic machinery should push the field toward better therapy.

The Cedars team published in the journal Cell Reports and Health Canal picked up the hospital’s press release. The UCSD team published in the Proceedings of the National Academy of Sciences and Science Daily picked up the university’s press release. CIRM funds a number of projects working on new therapies for brain cancer.

New tech tool speeds up stem cell research

It’s hard to do a good job if you don’t have the right tools. Now researchers have access to a great new tool that could really help them accelerate their work, a tool its developers say “will revolutionize the way cell biologists develop” stem cell models to test in the lab.

Fluidigm's Castillo system

Fluidigm’s Callisto system

The device is called Callisto™. It was created by Fluidigm thanks to two grants from CIRM. The goal was to develop a device that would allow researchers more control and precision in the ways that they could turn stem cells into different kinds of cell. This is often a long, labor-intensive process requiring round-the-clock maintenance of the cells to get them to make the desired transformation.

Callisto changes that. The device has 32 chambers, giving researchers more control over the conditions that cells are stored in, even allowing them to create different environmental conditions for different groups of cells. All with much less human intervention.

Lila Collins, Ph.D., the CIRM Science Officer who has worked closely with Fluidigm on this project over the years, says this system has some big advantages over the past:

“Creating the optimal conditions for reprogramming, stem cell culture and stem cells has historically been a tedious and manually laborious task. This system allows a user to more efficiently test a variety of cellular stimuli at various times without having to stay tied to the bench. Once the chip is set up in the instrument, the user can go off and do other things.”

Having a machine that is faster and easier to use is not the only advantage Callisto offers, it also gives researchers the ability to systematically and simultaneously test different combinations of factors, to see which ones are most effective at changing stem cells into different kinds of cell. And once they know which combinations work best they can use Callisto to reproduce them time after time. That consistency means researchers in different parts of the world can create cells under exactly the same conditions, so that results from one study will more readily support and reflect results from another.

In a news release about Callisto,  Fluidigm’s President and CEO Gajus Worthington, says this could be tremendously useful in developing new therapies:

“Fluidigm aims to enable important research that would otherwise be impractical. The Callisto system incorporates some of our finest microfluidic technology to date, and will allow researchers to quickly and easily create complex cell culture environments. This in turn can help reveal how stems cells make fate decisions. Callisto makes challenging applications, such as cellular reprogramming and analysis, more accessible to a wide range of scientists. We believe this will move biological discovery forward significantly.”

And as Collins points out, Callisto doesn’t just do this on a bulk level, working with millions of cells at a time, the way the current methods do:

“Using a bulk method it’s possible that one might miss an important event in the mixture. The technology in this system allows the user to stimulate and study individual cells. In this way, one could measure changes in small sub-populations and find ways to increase or decrease them.”

Having the right tools doesn’t always mean you are going to succeed, but it certainly makes it a lot easier.

Old brains in mice given a trait of young brains with embryonic nerve transplant

As we age our brains become less adept at making new nerve connections or repairing broken ones. A CIRM-funded team at the University of California, Irvine, restored this youthful ability, called nerve plasticity, to adult mice by transplanting embryonic nerve cells.

old to young

Specifically, they worked with mice that had a form of blurred vision known as amblyopia and the nerve cells they transplanted were ones that produce the nerve signal GABA. That amino acid helps regulate many aspects of brain function, including vision. The transplanted nerve cells allowed the brain to rewire itself and make connections that were missing and causing the poor vision. Several weeks later, the mice started to see normally.

The researchers transplanted the new cells directly into the visual cortex where the new nerve connections were needed. The mice had developed amblyopia, like humans, because the proper nerve connections failed to develop during a critical period when they were young. At the point in time that the transplanted embryonic cells would be going through that same critical period is when the researchers saw the improvement in vision for the adult mice. In a press release picked up at MedMerits.com the leader of the team, Sonil Gandhi explained what they saw:

“These experiments make clear that developmental mechanisms located within these GABA cells control the timing of the critical period.”

Gandhi added that the work should open up the possibility of trying to use GABA cell transplants to retrain the brain after injury or to repair congenital defects.

The news site NewsMax wrote an article on the research adding a bit more analysis.

A hopeful sight: therapy for vision loss cleared for clinical trial

Rosalinda Barrero

Rosalinda Barrero, has retinitis pigmentosa

Rosalinda Barrero says people often thought she was rude, or a snob, because of the way she behaved, pretending not to see them or ignoring them on the street. The truth is Rosalinda has retinitis pigmentosa (RP), a nasty disease, one that often attacks early in life and slowly destroys a person’s vision. Rosalinda’s eyes look normal but she can see almost nothing.

“I’ve lived my whole life with this. I told my daughters [as a child] I didn’t like to go Trick or Treating at Halloween because I couldn’t see. I’d trip; I’d loose my candy. I just wanted to stay home.”

Rosalinda says she desperately wants a treatment:

“Because I’m a mom and I would be so much a better mom if I could see. I could drive my daughters around. I want to do my part as a mom.”

Now a promising therapy for RP, funded by the stem cell agency, has been cleared by the Food and Drug Administration (FDA) to start a clinical trial in people.

The therapy was developed by Dr. Henry Klassen at the University of California, Irvine (UCI). RP is a relatively rare, inherited condition in which the light-sensitive cells at the back of the retina, cells that are essential for vision, slowly and progressively degenerate. Eventually it can result in blindness. There is no cure and no effective long-term treatment.

Dr. Klassen’s team will inject patients with stem cells, known as retinal progenitors, to help replace those cells destroyed by the disease and hopefully to save those not yet damaged.

In a news release about the therapy Dr. Klassen said the main goal of this small Phase I trial will be to make sure this approach is safe:

“This milestone is a very important one for our project. It signals a turning point, marking the beginning of the clinical phase of development, and we are all very excited about this project.”

Jonathan Thomas, the Chair of our Board, says that CIRM has invested almost $20 million to help support this work through early stage research and now, into the clinic.

“One of the goals of the agency is to provide the support that promising therapies need to progress and ultimately to get into clinical trials in patients. RP affects about 1.5 million people worldwide and is the leading cause of inherited blindness in the developed world. Having an effective treatment for it would transform people’s lives in extraordinary ways.”

Dr. Klassen says without that support it is doubtful that this work would have progressed as quickly as it has. And the support doesn’t just involve money:

“CIRM has played a critical and essential role in this project. While the funding is extremely important, CIRM also tutors and guides its grantees in the many aspects of translational development at every step of the way, and this accelerates during the later pre-clinical phase where much is at stake.”

This is now the 12th project that we are funding that has been approved by the FDA for clinical trials. It’s cause for optimism, but cautious optimism. These are small scale, early phase trials that in many cases are the first time these therapies have been tested in people. They look promising in the lab. Now it’s time to see if they are equally promising in people.

Considering we didn’t really start funding research until 2007 we have come a long way in a short time. Clearly we still have a long way to go. But the news that Dr. Klassen’s work has been given the go-ahead to take the next, big step, is a hopeful sign for Rosalinda and others with RP that we are at least heading in the right direction.

One of our recent Spotlight on Disease videos features Dr. Klassen and Rosalinda Barrero talking about RP.

This work will be one of the clinical trials being tested in our new Alpha Stem Cell Clinic Network. You can read more about that network here.

Scientists Sink their Teeth into Stem Cell Evolution

Sometimes, answers to biology’s most important questions can be found in the most unexpected of places.

As reported in the most recent issue of the journal Cell Reports, researchers at the University of California, San Francisco (UCSF) and the University of Helsinki describe how studying fossilized rodent teeth has helped them inch closer to grasping the origins of a particular type of stem cell.

Rodents' ever-growing teeth hold clues to the evolution of stem cells, according to a new study.

Rodents’ ever-growing teeth hold clues to the evolution of stem cells, according to a new study.

Understanding the microenvironment that surrounds each stem cell, known as a stem cell niche, is key to grasping the key mechanisms that drive stem cell growth. But as UCSF scientist Ophir Klein explained, many aspects remain a mystery.

“Despite significant recent strides in the field of stem cell biology, the evolutionary mechanisms that give rise to novel stem cell niches remain essentially unexplored,” said Klein, who served as the study’s senior author. “In this study, we have addressed this central question in the fields of evolutionary and developmental biology.”

In this study, Klein and his team focused on the teeth of extinct rodent species. Why? Because many species of rodent—both extinct species and those alive today—have what’s called ‘ever-growing teeth.’

Unlike most mammals, including we humans, the teeth of some rodent species continue to grow as adults—with the help of stem cell ‘reservoir’ hidden inside the root.

And by analyzing the fossilized teeth of extinct rodent species, the researchers could gain some initial insight into how these reservoirs—which were essentially a type of stem cell niche—evolved.

Most stem cell niche studies take cell samples from hair, blood or other live tissue. Teeth, as it turns out, are the only stem cell niches that can be found in fossil form.

In fact, teeth are “the only proxy…for stem cell behavior in the fossil record,” says Klein.

After analyzing more than 3,000 North American rodent fossils that varied in age between 2 and 50 million years ago, the researchers began to notice a trend. The earlier fossils showed short molar teeth. But over the next few million years, the molars began to increase in length. Interestingly, this coincided with the cooling of the climate during the Cenozoic Period. The types of food available in this cooler, drier climate likely became tougher and more abrasive—leading to evolutionary pressures that selected for longer teeth. By 5 million years ago, three-quarters of all species studied had developed the capability for ever-growing teeth.

The team’s models suggest that this trend has little chance of slowing down, and predicts that more than 80% of rodents will adopt the trait of ever-growing teeth.

The next step, says Klein, is to understand the genetic mechanism that is behind the evolutionary change. He and his team, including the study’s first author Vagan Tapaltsyan, will study mice to test the link between the genetics of tooth height and the appearance of stem cell reservoirs.

Brain’s Own Activity Can Fuel Growth of Deadly Brain Tumors, CIRM-Funded Study Finds

Not all brain tumors are created equal—some are far more deadly than others. Among the most deadly is a type of tumor called high-grade glioma or HGG. Most distressingly, HGG’s are the leading cause of brain tumor death in both children and adults. And despite extraordinary progress in cancer research as a whole, survival rates for those diagnosed with an HGG have yet to improve.


But recent research from Stanford University scientists could one day help move the needle—and give renewed hope to the patients and their families affected by this devastating disease.

The study, published today in the journal Cell, found that one key driver for HGG’s deadly diagnosis is that the tumor can be stimulated to grow by the brain’s own neural activity—specifically the nerve activity in the brain’s cerebral cortex.

Michelle Monje, senior author of the study that was funded in part by two grants from CIRM, was initially surprised by these results, as they run counter to how most types of tumors grow. As she explained in today’s press release:

“We don’t think about bile production promoting liver cancer growth, or breathing promoting the growth of lung cancer. But we’ve shown that brain function is driving these brain cancers.”

By analyzing tumor cells extracted from HGG patients, and engrafting it onto mouse models in the lab, the researchers were able to pinpoint how the brain’s own activity was driving tumor growth.

The culprit: a protein called neuroligin-3 that appeared to be calling the shots. There are four distinct types of HGGs that affect the brain in vastly different ways—and have vastly different molecular and genetic characteristics. Interestingly, says Monje, neuroligin-3 played the same role in all of them.

What was so disturbing to the research team, says Monje, is that neuroligin-3 is an essential protein for overall brain development. Specifically, it helps maintain healthy growth and repair of brain tissue over time. In order to grow, HGG tumors hijack this critical protein.

The research team came to this conclusion after a series of experiments that delved deep into the molecular mechanisms that guide both brain activity and brain tumor development. They first employed a technique called optogenetics, whereby scientists use genetic manipulation to insert light-sensitive proteins into the brain cells, or neurons, of interest. This allowed scientists to activate these neurons—or deactivate them—at the ‘flick of a switch.’

When applying this technique to the tumor-engrafted mouse models, the team could then see that tumors grew significantly better when the neurons were switched on. The next step was to narrow it down to why. Additional biochemical analyses and testing on the mouse models confirmed that neuroligin-3 was being hijacked by the tumor to spur growth.

And when they dug deeper into the connection between neuroligin-3 and cancer, they found something even more disturbing. A detailed look at the Cancer Genome Atlas (a large public database of the genetics of human cancers), they found that HGG patients with higher levels of neuroligin-3 in their brain had shorter survival rates than those with lower levels of the same protein.

These results, while highlighting the particularly nefarious nature of this class of brain tumors, also presents enormous opportunity for researchers. Specifically, Monje hopes her team and others can find a way to block or nullify the presence of neuroligin-3 in the regions surrounding the tumor, creating a kind of barrier that can keep the size of the tumor in check. 

Molecular Trick Diminishes Appearance of Scars, Stanford Study Finds

Every scar tells a story, but that story may soon be coming to a close, as new research from Stanford University reveals clues to why scars form—and offers clues on how scarring could become a thing of the past.

Reported last week in the journal Science, the research team pinpointed the type of skin cell responsible for scarring and, importantly, also identified a molecule that, when activated, can actually prevent the skin cells from forming a scar. As one of the study’s senior authors Michael Longaker explained in a press release, the biomedical burden of scarring is vast.

Scars, both internal and external, present a significant biomedical burden.

Scars, both internal and external, present a significant biomedical burden.

“About 80 million incisions a year in this country heal with a scar, and that’s just on the skin alone,” said Longaker, who also co-directs Stanford’s Institute for Stem Cell Biology and Regenerative Medicine. “Internal scarring is responsible for many medical conditions, including liver cirrhosis, pulmonary fibrosis, intestinal adhesions and even the damage left behind after a heart attack.”

Scars are normally formed when a type of skin cell called a fibroblast secretes a protein called collagen at the injury site. Collagen acts like a biological Band-Aid that supports and stabilizes the damaged skin.

In this study, which was funded in part by a grant from CIRM, Longaker, along with co-first authors Yuval Rinkevich and Graham Walmsley, as well as co-senior author and Institute Director Irving Weissman, focused their efforts on a type of fibroblast that appeared to play a role in the earliest stages of wound healing.

This type of fibroblast stands out because it secretes a particular protein called engrailed, which initial experiments revealed was responsible for laying down layers of collagen during healing. In laboratory experiments in mouse embryos, the researchers labeled these so-called ‘engrailed-positive fibroblast cells,’ or EPF cells, with a green fluorescent dye. This helped the team track how the cells behaved as the mouse embryo developed.

Interestingly, these cells were also engineered to self-destruct—activated with the application of diphtheria toxin—so the team could monitor what would happen in the absence of EPF cells entirely.

Their results revealed strong evidence that EPF cells were critical for scar formation. The scarring process was so tied to these EPF cells that when the team administered the toxin to shut them down, scarring reduced significantly.

Six days later the team found continued differences between mice with deactivated EPF cells, and a group of controls. Indeed, the experimental group had repaired skin that more closely resembled uninjured skin, rather than the distinctive scarring pattern that normally occurs.

Further examination of EPF cells’ precise function revealed a protein called CD26 and that blocking EPF’s production of CD26 had the same effect as shutting off EPF cells entirely. Wounds treated with a CD26 inhibitor had scars that covered only 5% of the original injury site, as opposed to 30%.

Pharmaceutical companies Merck and Novartis have already manufactured two types of CD26 inhibitor, originally developed to treat Type II diabetes, which could be modified to block CD26 production during wound healing—a prospect that the research team is examining more closely.

CIRM-Funded Scientists Build a Better Neuron; Gain New Insight into Motor Neuron Disease

Each individual muscle in our body—no matter how large or how small—is controlled by several types of motor neurons. Damage to one or more types of these neurons can give rise to some of the most devastating motor neuron diseases, many of which have no cure. But now, stem cell scientists at UCLA have manufactured a way to efficiently generate motor neuron subtypes from stem cells, thus providing an improved system with which to study these crucial cells.

“Motor neuron diseases are complex and have no cure; currently we can only provide limited treatments that help patients with some symptoms,” said senior author Bennett Novitch, in a news release. “The results from our study present an effective approach for generating specific motor neuron populations from embryonic stem cells to enhance our understanding of motor neuron development and disease.”

Normally, motor neurons work by transmitting signals between the brain and the body’s muscles. When that connection is severed, the individual loses the ability to control individual muscle movement. This is what happens in the case of amyotrophic lateral sclerosis, or ALS, also known as Lou Gehrig’s disease.

These images reveal the significance of the 'Foxp1 effect.' The Foxp1 transcription factor is crucial to the normal growth and function of motor neurons involved in limb-movement.

These images reveal the significance of the ‘Foxp1 effect.’ The Foxp1 transcription factor is crucial to the normal growth and function of motor neurons involved in limb-movement.

Recent efforts had focused on ways to use stem cell biology to grow motor neurons in the lab. However, such efforts to generate a specific type of motor neuron, called limb-innervating motor neurons, have not been successful. This motor-neuron subtype is particularly affected in ALS, as it supplies nerves to the arms and legs—the regions usually most affected by this deadly disease.

In this study, published this week in Nature Communications, Novitch and his team, including first author Katrina Adams, worked to develop a better method to produce limb-innervating motor neurons. Previous efforts had only had a success rate of about 3 percent. But Novitch and Adams were able to boost that number five-fold, to 20 percent.

Specifically, the UCLA team—using both mouse and human embryonic stem cells—used a technique called ‘transcriptional programming,’ in order to coax these stem cells into become fully functional, limb-innervating motor neurons.

In this approach, which was funded in part by a grant from CIRM, the team added a single transcription factor (a type of protein that regulates gene function), which would then guide the stem cell towards becoming the right type of motor neuron. Here, Novitch, Adams and the team used the Foxp1 transcription factor to do the job.

Normally, Foxp1 is found in healthy, functioning limb-innervating motor neurons. But in stem cell-derived motor neurons, Foxp1 was missing. So the team reasoned that Foxp1 might actually be the key factor to successfully growing these neurons.

Their initial tests of this theory, in which they inserted Foxp1 into a developing chicken spinal cord (a widely used model for neurological research), were far more successful. This result, which is not usually seen with most unmodified stem-cell-derived motor neurons, illustrates the important role played by Foxp1.

The most immediate implications of this research is that now scientists can now use this method to conduct more robust studies that enhance the understanding of how these cells work and, importantly, what happens when things go awry.