Skip to comments.Researchers Build New Off Switch to Shut Down Neural Activity
Posted on 04/27/2014 7:38:55 PM PDT by 2ndDivisionVet
Much-Needed Tool for Neuroscience Emerges After Years of Work.
Nearly a decade ago, the era of optogenetics was ushered in with the development of channelrhodopsins, light-activated ion channels that can, with the flick of a switch, instantaneously turn on neurons in which they are genetically expressed. What has lagged behind, however, is the ability to use light to inactivate neurons with an equal level of reliability and efficiency. Now, Howard Hughes Medical Institute (HHMI) scientists have used an analysis of channelrhodopsins molecular structure to guide a series of genetic mutations to the ion channel that grant the power to silence neurons with an unprecedented level of control.
The new structurally engineered channel at last gives neuroscientists the tools to both activate and inactivate neurons in deep brain structures using dim pulses of externally projected light. HHMI early career scientist Karl Deisseroth and his colleagues at Stanford University published their findings April 25, 2014 in the journal Science. Were excited about this increased light sensitivity of inhibition in part because we think it will greatly enhance work in large-brained organisms like rats and primates, he says.
First discovered in unicellular green algae in 2002, channelrhodopsins function as photoreceptors that guide the microorganisms movements in response to light. In a landmark 2005 study, Deisseroth and his colleagues described a method for expressing the light-sensitive proteins in mouse neurons. By shining a pulse of blue light on those neurons, the researchers showed they could reliably induce the ion channel at channelrhodopsins core to open up, allowing positively charged ions to rush into the cell and trigger action potentials. Channelrhodopsins have since been used in hundreds of research projects investigating the neurobiology of everything from cell dynamics to cognitive functions.
A few years later came the deployment of halorhodopsins, light-sensitive proteins selective for the negatively charged ion chloride. These proteins, derived from halobacteria, provided researchers with a tool for the light-controlled inactivation of neurons. A major limitation of these proteins, however, is their inefficiency. Unlike channelrhodopsin, halorhodopsin is an ion pump, meaning that only one chloride ion moves across the neurons membrane per photon of light. What that translates into is you get partial inhibition, Deisseroth says. You can inhibit neurons, but in the living animal its not always complete.
Searches for a naturally occurring light-sensitive channel with a pore permeable to negatively charged ions have come up empty handed. We searched, Deisseroth says. We did big genomic searches and found many interesting channelrhodopsins and lots of pumps, but we never found an inhibitory channel in nature.
The teams fruitless exploration led them to try modifying the molecular structure of channelrhodopsin so that its pore would shuttle negative ions into the cell. To do that you need to know what the channel pore looks like at the angstrom level, Deisseroth says. What we really needed was the high-resolution crystal structure. In 2012, working with a group in Japan, Deisseroth and his colleagues captured the structure of a chimera of channelrhodopsin called C1C2 using X-ray crystallography.
A molecular analysis of channelrhodopsins pore suggested that swapping out certain negatively charged amino acid residues lining the pore with positive residues could reverse the electrostatic potential of the channel, making it more conductive to negatively charged ions such as chloride. To achieve this molecular switcheroo, the researchers performed dozens of single site-directed mutations. Several mutations conferred selectivity for chloride, but the channels failed to conduct current. So, the team screened hundreds of combinations of mutations. In a systematic process we found first a combination of four mutations, and then a group of five mutations, that seemed to change selectivity, says Deisseroth. We put those together into a nine-fold mutated channel and that one, amazingly, was chloride selective.
Not only does the new channeldubbed iC1C2 for inhibitory C1C2allow the selective passage of chloride ions, it greatly reduces the likelihood of action potentials by making the neuron more leaky, a function not possible in ion pumps like halorhodopsin.
Deisseroths team made a final mutation to a cysteine residue in iC1C2 that makes the channel both bi-stable and orders of magnitude more sensitive to light. When activated by blue light, the mutated channels remain open for up to minutes at a time, while exposing the channels to red light makes them close quickly. This level of long-term control is useful in developmental studies where events play out over minutes to hours. The long channel open times also mean that neurons can essentially integrate chloride currents over longer time scales and, therefore, weaker light can be used to inhibit the neurons. Increased light sensitivity translates to less light-induced damage to neural tissue, the ability to reach deep brain structures, and the possibility of controlling brain functions that involve large regions of the brain.
This is something weve sought for many years and its really the culmination of many streams of work in the labcrystal structure work, mutational work, behavioral work all of which have come together here, Deisseroth says.
My G-d! They’re going to turn us all into Democrats!
ROTFL. exactly why i come here every day. Thanks.
That’s standard equipment in America’s public schools.
Isn’t that what booze is for?
In his case, if only.
Glad you liked.
My black ops psychoological engineers tell me that if louis GAZES upon that image of his deep personal angst..that he will become permanently speechless...
I carry an “off switch” with me at work. It’s called a taser.
ROFLMTO...my first thought exactly.
Oh ,and did you get the blue light, red light thing? Wasn’t there a blue pill or red pill pic going around about Obama Care, when the death panels were discussed? Possible correlation there or co incidence?
I saw this article on Drudge labeled something lie “Scientists have made a turn off switch for the brain”, and I guess this is what it was about. Problem is some people don’t have their brain turned on, so that presents a problem already.
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