VIENNA: A novel dopaminergic system organoid model offers information on its complicated operation and possible implications for Parkinson’s disease.
The model, built by Jurgen Knoblich’s group at the Austrian Academy of Sciences’ Institute of Molecular Biotechnology (IMBA), mimics the structure, connection, and functionality of the dopaminergic system.
The study, published in Nature Methods, also reveals that chronic cocaine exposure has long-term consequences on the dopaminergic circuit, even after abstinence.
A completed run, the early morning hit of caffeine, the smell of cookies in the oven – these rewarding moments are all due to a hit of the neurotransmitter dopamine, released by neurons in a neural network in our brain, called the “dopaminergic reward pathway”. Apart from mediating the feeling of “reward”, dopaminergic neurons also play a crucial role in fine motor control, which is lost in diseases such as Parkinson’s disease. Despite dopamine’s importance, key features of the system are not yet understood, and no cure for Parkinson’s disease exists. In their new study, the group of Jurgen Knoblich at IMBA developed an organoid model of the dopaminergic system, which not only recapitulates the system’s morphology and nerve projections, but also its functionality.
Tremor and a loss of motor control are characteristic symptoms of Parkinson’s disease and are due to a loss of neurons that release the neurotransmitter dopamine, called dopaminergic neurons. When dopaminergic neurons die, fine motor control is lost and patients develop tremors and uncontrollable movements. Although the loss of dopaminergic neurons is crucial in the development of Parkinson’s disease, the mechanisms how this happens, and how we can prevent – or even repair – the dopaminergic system is not yet understood.
Animal models for Parkinson’s disease have provided some insight into Parkinsons disease, however as rodents do not naturally develop Parkinson’s disease, animal studies proved unsatisfactory in recapitulating hallmark features of the disease. In addition, the human brain contains many more dopaminergic neurons, which also wire up differently within the human brain, sending projections to the striatum and the cortex. “We sought to develop an in vitro model that recapitulates these human features in so called brain organoids”, explains Daniel Reumann, previously a PhD student in the lab of Jurgen Knoblich at IMBA, and first author of the paper. “Brain organoids are human stem cell derived three-dimensional structures, which can be used to understand both human brain development, as well as function”, he explains further.
The team first developed organoid models of the so-called ventral midbrain, striatum and cortex – the regions linked by neurons in the dopaminergic system – and then developed a method for fusing these organoids together. As happens in the human brain, the dopaminergic neurons of the midbrain organoid send out projections to the striatum and the cortex organoids. “Somewhat surprisingly, we observed a high level of dopaminergic innervation, as well as synapses forming between dopaminergic neurons and neurons in striatum and cortex”, Reumann recalls.
To assess whether these neurons and synapses are functional, the team collaborated with Cedric Bardy’s group at SAHMRI and Flinders University, Australia, to investigate if neurons in this system would start to form functional neural networks. And indeed, when the researchers stimulated the midbrain which contains dopaminergic neurons, neurons in the striatum and cortex responded to the stimulation. “We successfully modelled the dopaminergic circuit in vitro, as the cells not only wire correctly, but also function together”, Reumann sums up.
The organoid model of the dopaminergic system could be used to improve cell therapies for Parkinson’s disease. In first clinical studies, researchers have injected precursors of dopaminergic neurons into the striatum, to try and make up for the lost natural innervation. However, these studies have had mixed success. In collaboration with the lab of Malin Parmar at Lund University, Sweden, the team demonstrated that dopaminergic progenitor cells injected into the dopaminergic organoid model mature into neurons and extend neuronal projections within the organoid. “Our organoid system could serve as a platform to test conditions for cell therapies, allowing us to observe how precursor cells behave in a three-dimensional human environment”, Jurgen Knoblich, the study’s corresponding author, explains. “This allows researchers to study how progenitors can be differentiated more efficiently and provides a platform which allows to study how to recruit dopaminergic axons to target regions, all in a high-throughput manner.”
Dopaminergic neurons also fire whenever we feel rewarded, thus forming the basis of the “reward pathway” in our brains. But what happens when dopaminergic signaling is perturbed, such as in addiction? To investigate this question, the researchers made use of a well-known dopamine reuptake inhibitor, cocaine. When the organoids were exposed to cocaine chronically, over 80 days, the dopaminergic circuit changed functionally, morphologically and transcriptionally. These changes persisted, even when cocaine exposure was stopped 25 days before the end of the experiment, which simulated the withdrawal condition. “Even after almost a month after stopping cocaine exposure, the effects of cocaine on the dopaminergic circuit were still visible, which means that we can now investigate what the long-term effects of dopaminergic overstimulation are in a human-specific in vitro system”, Reumann summarizes.
The model, built by Jurgen Knoblich’s group at the Austrian Academy of Sciences’ Institute of Molecular Biotechnology (IMBA), mimics the structure, connection, and functionality of the dopaminergic system.
The study, published in Nature Methods, also reveals that chronic cocaine exposure has long-term consequences on the dopaminergic circuit, even after abstinence.
A completed run, the early morning hit of caffeine, the smell of cookies in the oven – these rewarding moments are all due to a hit of the neurotransmitter dopamine, released by neurons in a neural network in our brain, called the “dopaminergic reward pathway”. Apart from mediating the feeling of “reward”, dopaminergic neurons also play a crucial role in fine motor control, which is lost in diseases such as Parkinson’s disease. Despite dopamine’s importance, key features of the system are not yet understood, and no cure for Parkinson’s disease exists. In their new study, the group of Jurgen Knoblich at IMBA developed an organoid model of the dopaminergic system, which not only recapitulates the system’s morphology and nerve projections, but also its functionality.
Tremor and a loss of motor control are characteristic symptoms of Parkinson’s disease and are due to a loss of neurons that release the neurotransmitter dopamine, called dopaminergic neurons. When dopaminergic neurons die, fine motor control is lost and patients develop tremors and uncontrollable movements. Although the loss of dopaminergic neurons is crucial in the development of Parkinson’s disease, the mechanisms how this happens, and how we can prevent – or even repair – the dopaminergic system is not yet understood.
Animal models for Parkinson’s disease have provided some insight into Parkinsons disease, however as rodents do not naturally develop Parkinson’s disease, animal studies proved unsatisfactory in recapitulating hallmark features of the disease. In addition, the human brain contains many more dopaminergic neurons, which also wire up differently within the human brain, sending projections to the striatum and the cortex. “We sought to develop an in vitro model that recapitulates these human features in so called brain organoids”, explains Daniel Reumann, previously a PhD student in the lab of Jurgen Knoblich at IMBA, and first author of the paper. “Brain organoids are human stem cell derived three-dimensional structures, which can be used to understand both human brain development, as well as function”, he explains further.
The team first developed organoid models of the so-called ventral midbrain, striatum and cortex – the regions linked by neurons in the dopaminergic system – and then developed a method for fusing these organoids together. As happens in the human brain, the dopaminergic neurons of the midbrain organoid send out projections to the striatum and the cortex organoids. “Somewhat surprisingly, we observed a high level of dopaminergic innervation, as well as synapses forming between dopaminergic neurons and neurons in striatum and cortex”, Reumann recalls.
To assess whether these neurons and synapses are functional, the team collaborated with Cedric Bardy’s group at SAHMRI and Flinders University, Australia, to investigate if neurons in this system would start to form functional neural networks. And indeed, when the researchers stimulated the midbrain which contains dopaminergic neurons, neurons in the striatum and cortex responded to the stimulation. “We successfully modelled the dopaminergic circuit in vitro, as the cells not only wire correctly, but also function together”, Reumann sums up.
The organoid model of the dopaminergic system could be used to improve cell therapies for Parkinson’s disease. In first clinical studies, researchers have injected precursors of dopaminergic neurons into the striatum, to try and make up for the lost natural innervation. However, these studies have had mixed success. In collaboration with the lab of Malin Parmar at Lund University, Sweden, the team demonstrated that dopaminergic progenitor cells injected into the dopaminergic organoid model mature into neurons and extend neuronal projections within the organoid. “Our organoid system could serve as a platform to test conditions for cell therapies, allowing us to observe how precursor cells behave in a three-dimensional human environment”, Jurgen Knoblich, the study’s corresponding author, explains. “This allows researchers to study how progenitors can be differentiated more efficiently and provides a platform which allows to study how to recruit dopaminergic axons to target regions, all in a high-throughput manner.”
Dopaminergic neurons also fire whenever we feel rewarded, thus forming the basis of the “reward pathway” in our brains. But what happens when dopaminergic signaling is perturbed, such as in addiction? To investigate this question, the researchers made use of a well-known dopamine reuptake inhibitor, cocaine. When the organoids were exposed to cocaine chronically, over 80 days, the dopaminergic circuit changed functionally, morphologically and transcriptionally. These changes persisted, even when cocaine exposure was stopped 25 days before the end of the experiment, which simulated the withdrawal condition. “Even after almost a month after stopping cocaine exposure, the effects of cocaine on the dopaminergic circuit were still visible, which means that we can now investigate what the long-term effects of dopaminergic overstimulation are in a human-specific in vitro system”, Reumann summarizes.