NEUROLOGY/LIGHT-TISSUE INTERACTION: In-vivo precision targeting with optogenetics
Operating with precision at millisecond speed, optogenetics uses low-level light to selectively activate proteins administered to live tissues-even in freely moving animals. This nascent and versatile biophotonic application holds paradigm-shifting promise for both research and treatment.
Operating with precision at millisecond speed, optogenetics uses low-level light to selectively activate proteins administered to live tissues—even in freely moving animals. This nascent and versatile biophotonic application holds paradigm-shifting promise for both research and treatment.
“Optogenetics is shining light on everything from animal behavior to the interactions of proteins inside cells,” says the narrator of a video produced by the journal Nature Methods. The video provides a brief introduction to the captivating and versatile biophotonics approach, as an explanation for “why Nature Methods has selected optogenetics as its ‘Method of the Year 2010.’”
Describing the technique, Stanford University associate professor of Bioengineering and Psychiatry Karl Deisseroth explains, “Optogenetics is a technology that allows targeted, fast control of precisely defined events in biological systems as complex as freely moving mammals. By delivering optical control at the speed (millisecond-scale) and with the precision (cell type-specific) required for biological processing, optogenetic approaches have opened new landscapes for the study of biology, both in health and disease.”1
It was Deisseroth who coined the term “optogenetics” in 2006. Today, some 500 laboratories worldwide are applying the approach to animal models.2 Early studies using low-level light to control the movement of nematode worms and fruit flies through neural stimulation have since been extended to mice and even primates. These more advanced applications have enabled optogenetics to help researchers understand the spatial capabilities related to animal locomotion, and for wireless neural implants that are activated by miniature light-emitting diodes (LEDs). Because optogenetics promises to restore vision to the blind, the Association in Research for Vision and Ophthalmology (ARVO) Foundation for Eye Research has named Deisseroth the first recipient of the Ludwig von Sallman clinician-scientist award in recognition of his groundbreaking work in developing and using optogenetic approaches to study neuronal function. Noting the far-reaching impact of the advance, spokesperson Gary W. Abrams, M.D. said, “We have great expectations that his pioneering work will lead to real advances in understanding basic retinal function and the restoration of vision in the future.”
In addition, the approach promises to rescue nerve functions in patients with spinal-cord injuries; researchers have used optogenetics to correct the gait of rats with Parkinson’s Disease.3 It also shows potential to control the fear, motivation, and reward centers of the brain for possible addiction treatments, and as a treatment for depression, among other conditions.4,5,6
Neuroscience isn’t the only discipline to exploit the advance, either: Scientists have used it to control the beating of heart muscle, among other applications.
This emerging field combines both optical and genetic techniques: Here, the term “genetic” refers to introduction of light-sensitive proteins called rhodopsins into biological tissues.
How it works
The algae protein channelrhodopsin can be introduced into neurons and activated with green light to turn them “on,” while halorhodopsin can be introduced and activated with yellow light to turn these neurons “off” at the frequency at which neurons operate.
“Unlike electrical stimulation, introducing a genetically encoded light responder such as channelrhodopsin allows neuroscientists to ‘choose’ to excite a subset of neurons within the region of stimulation,” says John Y. Lin, a postdoctoral research fellow with professor Roger Tsien at the University of California–San Diego (UCSD). “Because the limitation of the optical approach is the attenuation of light in mammalian tissues, I’ve been working to modify channelrhodopsins to improve their properties and move beyond 600 nm light for stimulation; this would reduce the light absorption by blood and tissue, allowing stimulation directly through the skull or skin without the need to insert fiber-optic probes,” he adds.7 Recently, David Tank and colleagues from Princeton University (Princeton, NJ) showed that two-photon stimulation of channelrhodopsin was possible at 920 nm infrared wavelengths.8
Besides wavelength modifications, Lin points out that improvements are needed in the production of virus-carrying channelrhodopsin for the introduction of these proteins into tissue: “Most physiology labs are not equipped to make the virus and viral production is typically labor-intensive and costly. Purchasing an off-the-shelf stock of virus at a low price would be beneficial for optogenetics researchers.” Some non-profit groups such as Addgene (Cambridge, MA) are distributing DNA and viruses that encode for light-gated proteins.
The specificity of optogenetic devices also allows them to work in concert with such techniques as blood-oxygenation-level dependent (BOLD) functional magnetic resonance imaging (fMRI), a form of fMRI that relies on intrinsic changes in hemoglobin oxygenation. “Recent work by Lee and colleagues showed that optogenetic stimulation of excitatory neurons triggers a positive BOLD response that can be monitored using fMRI,” says Helen Palmer, a postdoc at the Norwegian University of Science and Technology (Trondheim, Norway).9,10 “The findings confirmed that it’s possible to study a genetically defined neuron population of a particular brain region using so-called ‘optrodes’—optical fibers fused to recording electrodes that can simultaneously deliver the desired light wavelength to an exposed cranium while recording neural signals [see Fig. 1]. Because our group has several projects using fMRI, including a large-scale project with traumatic brain injury survivors, it is important to validate the BOLD technique from a physiological standpoint in health and disease.” Palmer concludes, “Lee’s work gives physiologists and neuroscientists [who are skeptical of fMRI] empirical evidence to support the fact that the brain activation we ‘map’ in humans with fMRI is real!”
|FIGURE 1. An optogenetic functional magnetic resonance imaging (ofMRI) technique delivers 473 nm blue light to the motor cortex region of a rat’s brain (a). The channelrhodopsin (ChR2) expressing region in the brain is co-localized with the fluorescent tag as shown in the confocal microscopy images (b). A blood-oxygenation-level dependent (BOLD) signal appears in the light-activated brain (c; right) in the presence of ChR2, but not in the brain treated with a saline injection (c; left), indicating that selective stimulation of excitatory neurons expressing ChR2 is the source of the BOLD signal. (Courtesy of University of California–San Diego)|
Starting with sight restoration
Eos Neuroscience (San Francisco, CA) is working in close collaboration with MIT Media Lab and other optogenetics research facilities to apply optogenetic innovations to intractable neurologic diseases in humans. Its first therapy, demonstrated in mice as a proof-of-concept experiment in 2008, aims to restore functional sight to patients blind from photoreceptor diseases such as retinitis pigmentosa (RP) and age-related macular degeneration (AMD). The Eos therapy enables the expression of an AAV-virus-delivered light-activated protein in retinal bipolar cells—a specific sub-population of neurons in the retina that receives input from photoreceptors. Even though the natural photoreceptors are gone, this therapy would allow the eye to again be activated by light. Eos Neuroscience co-founder and CEO Ben Matteo predicts that this technology could be in human clinical trials within two years.
Trauma recovery and primate research
Other work promises advances further in the future. Four universities, including Stanford University (Stanford, CA), Brown University (Providence, RI), the University of California–San Francisco (UCSF), and University College London, were the recipients, in May 2010, of a Defense Advanced Research Projects Agency (DARPA) award that seeks to develop implantable therapies for brain trauma through optogenetics research.11 “By turning off certain parts of the brain to simulate a traumatic injury, we can study how the brain attempts to rewire itself and perhaps use this information to create prosthetic computer chips that could mimic the brain’s normal two-way communication to restore function,” says Krishna Shenoy, associate professor of electrical engineering at Stanford University and principal investigator of the REPAIR (Reorganization and Plasticity to Accelerate Injury Recovery) project, for which DARPA is providing $14.9 million for two years with an option to increase the project’s scope to $28.8 million and four years.
In 2009, MIT researchers demonstrated that light applied to the frontal cortex of fully awake macaque monkeys, which had been injected with lentivirus carrying the gene for channelrhodopsin-2, was expressed predominantly in excitatory pyramidal neurons.12 In layman’s terms, the research shows that particular neurons can be targeted, activated, and analyzed to understand brain/body function in a well-understood, well-studied, and trainable primate—and ultimately, in a human. Combined in-vivo optical stimulation and electrophysiological recordings showed that the activity of neurons in the illuminated area could be influenced with millisecond temporal precision. Furthermore, the researchers found that the activity level of many neurons was suppressed following light exposure and concluded that this was due to the activation of inhibitory interneurons activated by the pyramidal neurons. It is precisely these types of neural interactions that optogenetics can highlight for researchers.
“Recent work has shown that rhodopsins do not illicit an immune response or lead to cell death in primates—an extremely critical finding that paves the way for future optogenetic study using these light-activated proteins,” says Ed S. Boyden, assistant professor of the MIT Media Lab and leader of the Synthetic Neurobiology Group at MIT who contributed to this primate research and also worked with Stanford’s Deisseroth on early rhodopsin research. “We see our research lab as a core-technology provider to assist others with optogenetic research. To date, our achaerhodopsins, which overcome the fundamental limitations of nerve-quieting halorhodopsins such as weak signal and rundown over time, have been provided to around 250 research groups.”
Boyden continues, “Numerous research groups are now visiting MIT and collaborating to understand and access our newest tool—a multiwaveguide probe that can deliver specific wavelengths of light to multiple locations within tissue.”13 The 1.45 cm long probe is microfabricated in the form of a 360 μm wide array of 12 parallel silicon oxynitride (SiON) multimode waveguides coated with aluminum. The waveguide array sends light from a set of sources at the input end down each waveguide to an aluminum corner mirror that efficiently deflects light away from the probe axis (see Fig. 2).
|FIGURE 2. A multiwaveguide probe transmits light from a series of LED or laser diode sources down a fiber where they are deflected by small corner cubes and distributed per the needs of optogenetic researchers. The custom device can deliver 1.5 mW of power from a 5 mW source to a tissue depth of 1 cm, improving greatly over previous fiber-optic probes that could only deliver a single wavelength of light to one localized tissue region. (Courtesy of MIT)|
The heart of the matter
Battery-operated electrical pacemakers that control the rhythmic operations of heart muscle are well understood. But a new optogenetic method is gaining traction not only as a less invasive research tool, but also as a potential light-based pacemaker that could outperform the conventional electrical alternative. “The new method allows us to silence or activate muscle and nervous tissues at will and with great temporal precision,” says Aristides Arrenberg from the neuroscience program at UCSF (see Fig. 3).14 “We can’t say at this point whether optical pacemakers will find a clinical application in the future. However, our recent results show the potential this new method could have if safe, therapeutic gene transfer becomes possible.”
|FIGURE 3. A microscope layout (a) shows how a sheet of laser light (488 nm or 561 nm) illuminates an embedded zebrafish, S, through objective lens OL1 or OL2. A computer-generated pattern is reflected off the digital micromirror device (DMD) and imaged onto the sample S through the detection lens OL3. The zebrafish heart stops beating (b) when illuminated with orange light and recovers instantaneously afterward (c). The heart was sequentially illuminated with overlapping squares (d), and a false-color image shows the observed atrial heart rate after illumination of 30 sampled areas (e). (Courtesy of University of California–San Francisco)|
Researchers at the University of Bonn (Bonn, Germany) are also applying optogenetics to cardiac research.15 In their work, pulsed 475 nm blue light induces cellular contractions in channelrhodopsin-expressing cardiomyocytes, both in-vitro in a laboratory and in-vivo within mice without side effects. By confined illumination of the ventricular and atrial regions of the beating heart of a mouse, the researchers were able to induce ventricular and supraventricular pacing, respectively. “Most importantly, we can now continuously activate cardiac tissue by constant illumination and therefore induce arrhythmias,” says Philipp Sasse, MD, at the University of Bonn. “Continuous activation of cardiac tissue is something completely new that cannot be done with electrical stimulation,” he adds.
While the technique is less than a decade old, optogenetics abounds with potential. Like friends and relatives of a genius child, we anticipate a promising future for this versatile approach.
1. K. Deisseroth, Nature Methods 8, 26–29 (2010).
3. A.V. Kravitz et al., Nature 466, 622–626 (2010); doi:10.1038/nature09159.
4. G.D. Stuber, Neuropsychopharmacology 35, 341–342 (2010); doi:10.1038/npp.2009.102.
5. K. Deisseroth, Scientific American, October 20, 2010, www.scientificamerican.com/article.cfm?id=optogenetics-controlling.
6. H.E. Covington III et al., Neuroscience 30 (48), 16082–16090 (2010).
7. John Y. Lin, Exper. Physiol. 96 (1), 19–25 (2010).
8. J. Rickgauer and D. Tank, PNAS 106 (35), 15025–15030 (2009).
9. Jin Hyung Lee et al., Nature 465, 788–792 (2010).
10. Helen S. Palmer, J. Neurophys. 104, 1838–1840 (2010).
12. X. Han et al., Neuron 2, 191–198 (2009).
13. A. N. Zorzos et al., Opt. Lett. 35 (24), 4133–4135 (2010).
14. A. Arrenberg et al., Science 330, 971–974 (2010).
15. T. Bruegmann et al., Nature Methods 7, 897–900 (2010) doi:10.1038/nmeth.1512.
GAIL OVERTONis Senior Editor for Laser Focus World and a contributing editor for BioOptics World; email@example.com.