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Saturday, October 8, 2016
New Tool Will Help Expand Scope of Neural Circuit Research
Summary: According to researchers, a new viral vector will help better understanding of large scale neural networks.
Source: Howard Hughes Medical Institute.
The image shows a section of mouse brain in which scientists have injected rAAV2-retro viruses carrying a red fluorescent protein. The red fluorescent protein labels the long-range output projections between two regions of the brain, the cortex and the pons, located in the brainstem. The site of the injection is shown with a co-injection of a virus carrying green fluorescent protein. NeuroscienceNews.com image is credited to the researchers.
Scientists at the Howard Hughes Medical Institute’s Janelia Research Campus and the University of California, Berkeley have developed a powerful new tool for neuroscientists—a viral vector called rAAV2-retro, which efficiently enters and travels through the long neuronal projections that connect different regions of the brain. Genetically-encoded tools for labeling cells or monitoring or manipulating their activity can be packaged inside the virus and delivered to groups of neurons that signal to a specific part of the brain, creating new opportunities to study large-scale neural networks.
Chemical dyes have long been used to trace neuronal projections. However, a viral vector that is transported to neuronal cell bodies as efficiently as dyes carries a distinct advantage: it delivers a genetic payload to the cells that it infects. “We have performed rigorous analysis to establish that this tool is more effective than anything available, and, based on feedback from our colleagues in neuroscience, we believe that it will expand the scope of neural circuit research,” says Janelia group leader Alla Karpova, who led the large-scale effort to develop and test rAAV2-retro. Eventually, Karpova and her colleagues say, rAAV2-retro might also enable efficient delivery of gene therapies to cells affected by neurodegenerative disease. Karpova and her colleagues reported on rAAV2-retro on October 6, 2016, in the journal Neuron.
Karpova says the new tool helps solve a frustration many neuroscientists experience as they try to unravel how neural circuits process and relay information across the brain. The projection neurons that connect distant parts of the brain are intimately intermingled with one another, and it is difficult to manipulate specific groups of cells selectively to study their function. “It’s pretty clear that projection neurons are a critical component of large-scale networks. But understanding their specific role is hard. It requires being able to distinguish and genetically access different subpopulations,” Karpova says.
With the support of the Janelia Visiting Scientist Program, Janelia scientists partnered with David Schaffer’s team at the University of California, Berkeley, to begin their search. Schaffer, had previously developed a diverse collection of variants of adeno-associated viruses (rAAVs), non-toxic viruses that are widely used in neuroscience research. Naturally occurring adeno-associated viruses are tremendously variable, and can infect different types of cells depending on the precise structure of their outer protein shell, or capsid. The researchers suspected that the right alterations to the capsid might give an adeno-associated virus just the properties they were looking for.
Postdoctoral researcher Gowan Tervo led the effort to find a virus that exhibited efficient retrograde transport in the brains of mice. Together with members of the Dudman, Hantman and Looger labs at Janelia, he devised a screen that would test viruses’ ability to travel through two different sets of neurons that traverse long distances. After injecting the full set of viral variants into the sites where those cells send their signals, Tervo and his colleagues waited three weeks, giving the virus time to spread. Then they collected any viruses that had reached the distant part of the brain where the neurons’ signals originated.
To make those kinds of studies possible, Karpova and her collaborators set out to engineer a virus that would be efficient at retrograde transport: entering a neuron’s axon—the long, thin projection that sends signals to other cells—and traveling all the way back to the cell body, where signals originate.
With the help of Schaffer’s team, an enriched viral pool was then generated, and injected into the same sites in the brain, beginning the selection process again. The procedure was repeated several times, each time generating viral variants better suited for the task at hand.
At the end of that process, the team had several viral vectors that were very good at traveling through the particular neurons he had used in his screen. But to be the type of versatile tool the researchers were looking for, a virus needed to perform equally well in neurons elsewhere in the brain. Together, the team selected 15 contenders, and with the support of Janelia’s core facilities, examined each variant’s ability to trace many different neuronal paths through the brain. When they were used to deliver fluorescent proteins to neurons, the viral vectors that worked best generated clear maps of cells’ courses through the brain, showing groups of labeled cells converging on the site where the virus had been injected.
After this massive effort, the team selected a single virus that excelled in their tests, efficiently diffusing through projection neurons in many different parts of the brain. That vector also successfully delivered a genetically-encoded sensor of neural activity to target cells, causing those cells to light up when they fired.
Still, Tervo says, additional testing was needed. Together with Sarada Viswanathan, a postdoctoral researcher in Loren Looger’s laboratory at Janelia, he developed sensitive assays to measure the performance of the virus, and after spending more than a year comparing rAAV2-retro to alternative tracers and viral vectors, the team concluded that it is the best tool available for selectively accessing groups of neurons based on their projection patterns. “Now we’re in the position where we can confidently recommend this for the vast majority of circuits,” Tervo says.
Karpova and her colleagues are making rAAV2-retro freely available to the neuroscience community, and hope it will be used for a wide range of scientific applications. “We altered the capsid of the virus. The payload that you put into it is up to you,” Tervo says.
ABOUT THIS NEUROSCIENCE AND GENETICS RESEARCH ARTICLE
Image Source: NeuroscienceNews.com image is credited to the researchers.
Video Source: The video is credited to Howard Hughes Medical Institute.
Original Research:Abstract for “A Designer AAV Variant Permits Efficient Retrograde Access to Projection Neurons” by D. Gowanlock R. Tervo, Bum-Yeol Hwang, Sarada Viswanathan, Thomas Gaj, Maria Lavzin, Kimberly D. Ritola, Sarah Lindo, Susan Michael, Elena Kuleshova, David Ojala, Cheng-Chiu Huang7, Charles R. Gerfen, Jackie Schiller, Joshua T. Dudman, Adam W. Hantman, Loren L. Looger, David V. Schaffer, and Alla Y. Karpova in Neuron. Published online October 6 2016 doi:10.1016/j.neuron.2016.09.021
Abstract
A Designer AAV Variant Permits Efficient Retrograde Access to Projection Neurons
Highlights
•AAV can be endowed with robust retrograde functionality through directed evolution
•Up to two orders of magnitude increase in retrograde transport over existing variants
•Efficiency comparable to synthetic tracers
•Sufficient payload expression for circuit interrogation and gene manipulation
Summary
Efficient retrograde access to projection neurons for the delivery of sensors and effectors constitutes an important and enabling capability for neural circuit dissection. Such an approach would also be useful for gene therapy, including the treatment of neurodegenerative disorders characterized by pathological spread through functionally connected and highly distributed networks. Viral vectors, in particular, are powerful gene delivery vehicles for the nervous system, but all available tools suffer from inefficient retrograde transport or limited clinical potential. To address this need, we applied in vivo directed evolution to engineer potent retrograde functionality into the capsid of adeno-associated virus (AAV), a vector that has shown promise in neuroscience research and the clinic. A newly evolved variant, rAAV2-retro, permits robust retrograde access to projection neurons with efficiency comparable to classical synthetic retrograde tracers and enables sufficient sensor/effector expression for functional circuit interrogation and in vivo genome editing in targeted neuronal populations.
“A Designer AAV Variant Permits Efficient Retrograde Access to Projection Neurons” by D. Gowanlock R. Tervo, Bum-Yeol Hwang, Sarada Viswanathan, Thomas Gaj, Maria Lavzin, Kimberly D. Ritola, Sarah Lindo, Susan Michael, Elena Kuleshova, David Ojala, Cheng-Chiu Huang7, Charles R. Gerfen, Jackie Schiller, Joshua T. Dudman, Adam W. Hantman, Loren L. Looger, David V. Schaffer, and Alla Y. Karpova in Neuron. Published online October 6 2016 doi:10.1016/j.neuron.2016.09.021
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