Scientists grow human serotonin neurons in petri dish

Induced serotonergic neuron.

Cells with a nucleus (labelled blue), were originally human fibroblasts, some of which have been converted to neurons that produce serotonin (green) while others have been converted to produce another neuron-specific protein. Yellows, greens and other colors result from overlapping labels.  Credit: Jian Feng, UB.

The advance could facilitate the discovery of new antidepressants and drugs for illnesses involving serotonin

Release Date: August 5, 2015 This content is archived.

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“Our work demonstrates that the precious serotonin neurons hidden deep inside the human brain can now be created in a petri dish. ”
Jian Feng, PhD, Professor
UB Department of Physiology and Biophysics

BUFFALO, N.Y. — Serotonin, a neurotransmitter involved in regulating mood and mental states, has been linked to numerous neurological and mental illnesses, including depression. But because there has been no way to obtain live human serotonin neurons to study these diseases, most serotonin research has been done on lab animals.

Now, University at Buffalo researchers have generated human serotonin neurons from human fibroblasts, the cells that give rise to connective tissue in the body.

The researchers say that their findings are applicable to generating many other previously inaccessible human cell types, providing a boon to medical research and drug discovery.

“Our work demonstrates that the precious serotonin neurons hidden deep inside the human brain can now be created in a petri dish,” said lead author Jian Feng, PhD, professor in the Department of Physiology and Biophysics in the UB School of Medicine and Biomedical Sciences. Feng also has an appointment at the Veterans Affairs Western New York Healthcare System in Buffalo.

The paper was published online on July 28. A future issue of the print journal will feature an image from the UB research on the cover. The work builds on previous studies showing that human fibroblasts can be converted to neurons, using specialized transcription factors that bind to genes, turning them on or off.

Generating serotonin neurons

The UB research demonstrates the first direct conversion of human fibroblasts into serotonergic neurons, Feng said. These “induced serotonergic neurons” behave like serotonin neurons in the human brain.

“We know the cells were converted to serotonergic neurons because they express proteins that are only found in neurons that produce serotonin,” Feng explained. “They are electrophysiologically active and demonstrate both the controlled release and the selective uptake of serotonin.”

The researchers found that they could produce induced serotonergic neurons from fibroblasts by introducing four genes that control the development of serotonin neurons. “These genes change how the human genome, which is like a computer hard drive, is read, so that the cell switches from a lung cell to a serotonin neuron,” said Feng.

 “With this new technology, scientists can generate serotonin neurons from patients who suffer from serotonin-related mental illnesses,” said Feng.

While the paper focuses on converting lung fibroblasts to serotonin neurons, Feng’s group at UB also has been working on generating serotonin neurons from human skin cells, which would be an even easier and less invasive process.

A versatile technology

Such induced serotonin neurons would be extremely beneficial since they can be generated from individual patients suffering from illnesses involving the neurotransmitter.

“These patient-specific serotonin neurons will be very useful to the discovery of new drugs for diseases ranging from depression and anxiety to obsessive-compulsive disorder and many others,” said Feng. “They will not only allow researchers to study why certain individuals develop a disease but also to find out what can be done to treat it.”

Feng is optimistic that the same technology is versatile enough that it can be used to generate other new cells and tissues: “This research shows that it is possible to convert one type of cell into other types that have been difficult to access, such as neurons or heart cells,” he said. “All we need to do is find out the combination of transcription factors that is necessary. Sooner or later, we will find out what those combinations are so that we can regenerate cells and eventually tissues that will mimic the real cells and tissues in the body.”

Feng’s UB co-authors are Zhen Yan, PhD, professor, and Ping Zhong, PhD and Houbo Jiang, PhD, both research assistant professors, all in the Department of Physiology and Biophysics. Other co-authors are Zhimin Xu and Shengdi Chen, both of Ruijin Hospital and Shanghai Jiao Tong University School of Medicine.

The work was supported by grants from the National Key Basic Research Program of China, the National Natural Science Foundation of China, the U.S. Department of Veterans Affairs, NYSTEM and the National Institutes of Health.   

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Ellen Goldbaum
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