eNpHR: a Natronomonas halorhodopsin enhanced for optogenetic applications
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Temporally precise inhibition of distinct cell types in the intact nervous system has been enabled by the microbial halorhodopsin NpHR, a fast light-activated electrogenic Cl− pump. While neurons can be optically hyperpolarized and inhibited from firing action potentials at moderate NpHR expression levels, we have encountered challenges with pushing expression to extremely high levels, including apparent intracellular accumulations. We therefore sought to molecularly engineer NpHR to achieve strong expression without these cellular side effects. We found that high expression correlated with endoplasmic reticulum (ER) accumulation, and that under these conditions NpHR colocalized with ER proteins containing the KDEL ER retention sequence. We screened a number of different putative modulators of membrane trafficking and identified a combination of two motifs, an N-terminal signal peptide and a C-terminal ER export sequence, that markedly promoted membrane localization and ER export defined by confocal microscopy and whole-cell patch clamp. The modified NpHR displayed increased peak photocurrent in the absence of aggregations or toxicity, and potent optical inhibition was observed not only in vitro but also in vivo with thalamic single-unit recording. The new enhanced NpHR (eNpHR) allows safe, high-level expression in mammalian neurons, without toxicity and with augmented inhibitory function, in vitro and in vivo.
KeywordsFUDR Endoplasmic Reticulum Retention Mammalian Neuron Endoplasmic Reticulum Export Adult Mouse Hippocampus
A subset of naturally-occurring microbial opsin genes, originally characterized in non-neural systems, encode light-sensitive transmembrane ion conductance regulators (e.g., Hegemann et al., 1985; Kalaidzidis et al., 1998; Nagel et al., 2003; Zhang et al., 2008). If successfully adapted as a neuroscience technology, these proteins could be enormously significant, since controlling the membrane potential of targeted cell types with high temporal resolution may allow elucidation of cellular codes underlying neural circuit computation and behavior. Three functionally distinct classes of these microbial opsin genes have now been introduced to and adapted for neurobiology (VChR1, NpHR, and ChR2; discussed below). Among other important properties, all three operate on the millisecond timescale and can function in mammalian neurons without addition of exogenous chemical cofactors, since the chromophore for these proteins, all-trans retinal, appears to be already present at sufficient levels in mammalian brains (Zhang et al., 2006). Moreover, light and gene delivery challenges have been overcome, as integrated genetic, fiberoptic, and solid-state optical approaches have provided complementary technology to allow specific cell types, deep within the brain, to be controlled in freely behaving mammals (Adamantidis et al., 2007; Aravanis et al., 2007; Gradinaru et al., 2007).
First to be brought to neuroscience, the channelrhodopsin ChR2 allows blue light-induced action potentials to be triggered with millisecond-precision in neurons (Boyden et al., 2005), due to depolarizing cation flux through a light-gated pore (Nagel et al., 2003); this approach has since been shown to be versatile in many experimental systems (Li et al., 2005; Nagel et al., 2005; Bi et al., 2006; Deisseroth et al., 2006; Ishizuka et al., 2006; Schroll et al., 2006; Zhang et al., 2006; Airan et al., 2007; Aravanis et al., 2007; Gradinaru et al., 2007; Hwang et al., 2007; Petreanu et al., 2007; Zhang and Oertner, 2007; Zhang et al., 2007a, b; Huber et al., 2008), including generation of transgenic mouse lines (Arenkiel et al., 2007; Wang et al., 2007) and probing neural codes underlying complex behavioral state transitions important in neuropsychiatric disease (Adamantidis et al., 2007). Second, we found that neurons targeted to express the light-activated chloride pumping halorhodopsin from Natronomonas pharaonis (NpHR) can be hyperpolarized and inhibited from firing action potentials when exposed to yellow light (Zhang et al., 2007a); because of the excitation wavelength difference, ChR2 and NpHR can be coexpressed for bidirectional control and integrated with imaging and behavior (Gradinaru et al., 2007; Han and Boyden, 2007; Zhang et al., 2007a) even in intact tissue and behaving animals (Zhang et al., 2007a), and may turn out to be versatile across a range of in vitro and in vivo applications (reviewed in Gradinaru et al., 2007; Zhang et al., 2007b). Third, a yellow light-activated channelrhodopsin gene was discovered and tested in mammalian neurons (VChR1; Zhang et al., 2008) that opens the door to combinatorial excitation experiments when used together with ChR2, described below. The properties of this third microbial tool also allow for deep penetration of redshifted excitation light, use of well-tolerated low-energy photons for excitation, and improved integration with existing Ca2+ indicators.
Technical challenges still remain, including refining optical and cell type-specific targeting strategies, as well as tuning activation wavelengths and ion permeabilities for different classes of experiments. One major challenge in adapting tools across large evolutionary distances (e.g., to mammals from prokaryotes and simple eukaryotes such as Volvox carteri, Natronomonas pharaonis, and Chlamydomonas reinhardtii) is that expressing heterologous membrane proteins in mammalian cells can lead to poor folding, assembly, and trafficking. We have previously reported that at high expression levels, NpHR (codon optimized for mammalian expression) forms aggregates that could cause cellular toxicity (Gradinaru et al., 2007), and noted that this problem could be alleviated by returning to moderate expression levels, but this was not an ideal solution because large photocurrents are useful for efficient inhibition in a variety of experiments, especially for in vivo applications. Therefore, we report here on a strategy to increase the efficiency of NpHR membrane targeting to maximize photocurrents without aggregations or toxicity, even for high expression levels under strong promoters, in vitro and in vivo.
Transport along the secretory pathway, with ER export being the first step in the pathway, is crucial for surface expression of integral membrane proteins. Although some proteins can exit the ER by bulk flow, ER export of membrane proteins can be impaired if the protein is either misfolded or lacks specific export signals (Li et al., 2000; Ellgaard and Helenius, 2003). Because NpHR is functional in mammalian neurons even in vivo (Zhang et al., 2007a) we hypothesized that aggregate formation might be due to lack of an ER export signal rather than frank misfolding, and therefore sought to determine if adding different ER export signals to the NpHR sequence would abolish aggregate formation. C-terminal ER export signals have been shown to be important for efficient processing and surface expression of many membrane proteins (Farhan et al., 2008). Additionally, previous work has found that when the C-terminal ER export signals on Kv1.4 (VXXSL) or Kir2.1 (FCYENEV) are either mutated or deleted, the resulting protein forms large spheroidal intracellular accumulations similar to NpHR aggregates, and corresponding channel activity is reduced due to lower protein levels in the plasma membrane (Levitan and Takimoto, 2000; Ma et al., 2001; Stockklausner et al., 2001). Moreover, suggesting that functionality can be transferred solely with these motifs, the FCYENEV sequence accelerated surface expression and increased current levels for the lobster shal potassium channel (Kv4) when added to the C-terminus (Zhang and Harris-Warrick, 2004). Indeed, in the course of our modification screen we found that adding FCYENEV to the NpHR C-terminus along with the signal peptide from the β subunit of the nAChR to the NpHR N-terminus prevented aggregate formation (Fig. 1B, asterisk), with such markedly improved properties that we named the resulting tool eNpHR (enhanced NpHR; Fig. 2A) and studied its behavior further (summarized in Figs. 2–4).
In this study we have identified and corrected a major limiting factor in the application of optogenetic inhibition (complementary results have been obtained with our colleagues at Duke University; Zhao et al., 2008). We traced the problem associated with high NpHR expression back to a membrane trafficking complication (Figs. 1 and 2), tested a large number of possible solutions (Fig. 1), and validated the efficacy of the best strategy both in vitro (Figs. 1–3) and in vivo (Fig. 4). We found that eNpHR completely abolished accumulations seen at very high expression levels with the original NpHR, apparently in part by allowing normal export of NpHR from the ER (assessed by confocal imaging) and by driving increased surface membrane expression (validated by quantified photocurrents). At this point we recommend use of eNpHR for all applications, and certainly those involving high expression levels in mammalian neurons, including transgenic mouse line generation (Zhao et al., 2008) and viral transduction approaches. We also anticipate that these modifications may enhance the expression of other microbial opsins at high levels and over long durations, pointing to the likely utility of generating similarly enhanced versions of ChR2 and VChR1.
The altered properties of eNpHR as described here clearly do not simply represent a subtle quantitative change in performance, but rather a distinct step in the development of this optogenetic technology. Future improvements could incrementally further advance eNpHR function, perhaps including the Golgi export signals from Kir2.1 (Stockklausner and Klocker, 2003; Hofherr et al., 2005), subcellular localization motifs (as in Gradinaru et al., 2007), and mutations that shift wavelength dependence, kinetics, light sensitivity, and ion selectivity. For example, blueshifting ChR2 and redshifting eNpHR and VChR1 will improve the ease with which combinatorial experiments are conducted, and a roadmap for the key residues likely to be involved and the type of changes likely to be helpful in this regard has been described (Zhang et al., 2008).
Finally, it has been noted (Zhang et al., 2008) that VChR1 and ChR2 (representing yellow light excitation and blue light excitation, respectively) when used together will allow combinatorial tests of the importance of specific activity patterns in interacting cell types. For example, a principal cell population can be recruited with VChR1/yellow light, in the presence or absence of precisely patterned activity in a candidate modulatory cell type driven by added blue light/ChR2. Combinatorial experiments are important to consider now for eNpHR as well, given its improved functionality in vitro and in vivo. For example, coexpression of eNpHR and ChR2 in the same cell type could allow testing the necessity and sufficiency of that specific cell type in neural circuit or animal behavior. Moreover, epistatic relationships among different cell groups within a neuronal network could be probed by expressing eNpHR and ChR2 in different cell types and determining if the functional significance of cell population A excitation is expressed through or “read out” via a candidate downstream cell population B; this hypothesis could be tested by reversibly inhibiting cell population B (yellow light/eNpHR) in the presence of population A activation (blue light/ChR2). In this way the causal neural codes underlying circuit computation and behavior may be slowly assembled, moving toward the long term goal of understanding how neural system properties emerge from component dynamics, both in health and disease.
All NpHR variants were produced by PCR amplification of the NpHR-EYFP construct previously published (Zhang et al., 2007a) and cloned in-frame into the AgeI and EcoRI restriction sites of a lentivirus carrying the CaMKIIα promoter according to standard molecular biology protocols. All constructs were fully sequenced to check for accuracy of the cloning procedure. The map for eNpHR is available online at http://www.optogenetics.org.
Lentivirus preparation and titering
Lentiviruses for cultured neuron infection and for in vivo injection were produced as previously described (Zhang et al., 2007a). Viral titering was performed in HEK293 cells that were grown in 24-well plates and inoculated with 5-fold serial dilutions in the presence of polybrene (8 μg/μl). After 4 days, cultures were resuspended in PBS and sorted for EYFP fluorescence on a FACScan flow cytometer (collecting 20,000 events per sample) followed by analysis using FlowJo software (Ashland, OR). The titer of the virus was determined as follows: [(% of infected cells) × (total number of cells in well) × (dilution factor)]/(volume of inoculum added to cells) = infectious units/ml. The titer of viruses for culture infection was 105 i.u./ml. The titer of concentrated virus for in vivo injection was 1010 i.u./ml.
Primary cultured hippocampal neurons were prepared from P0 Spague-Dawley rat pups. The CA1 and CA3 regions were isolated, digested with 0.4 mg/ml papain (Worthington, Lakewood, NJ), and plated onto glass coverslips precoated with 1:30 Matrigel (Beckton Dickinson Labware, Bedford, MA) at a density of 65,000/cm2. Cultures were maintained in a 5% CO2 humid incubator with Neurobasal-A media (Invitrogen Carlsbad, CA) containing 1.25% FBS (Hyclone, Logan, UT), 4% B-27 supplement (Gibco, Grand Island, NY), 2 mM Glutamax (Gibco), and FUDR (2 mg/ml, Sigma, St. Louis, MO).
In vitro electrophysiology
Hippocampal cultures grown on coverslips were transduced at 4 div with titer-matched viruses for all CaMKIIα-NpHR-EYFP constructs (final dilution 104 i.u./ml in neuronal growth media) and allowed to express for 10 days. Whole-cell patch clamp recordings were performed as previously described (Gradinaru et al., 2007) (intracellular solution: 129 mM K-gluconate, 10 mM HEPES, 10 mM KCl, 4 mM MgATP, 0.3 mM Na3GTP, titrated to pH 7.2; extracellular solution, tyrode: 125 mM NaCl, 2 mM KCl, 3 mM CaCl2, 1 mM MgCl2, 30 mM glucose, and 25 mM HEPES, titrated to pH 7.3). Light (7 mW/mm2) was delivered from a 300 W DG-4 lamp (Sutter Instruments, Novato, CA) through a 593 nm ± 20 nm filter (Semrock, Rochester, NY) and a 20X/0.45NA air objective (Olympus, Center Valley, PA).
Immunostaining and aggregate count
Primary hippocampal cultures grown on coverslips were infected at 4 div with titer matched virus (final dilution 104 i.u./ml in neuronal growth media). At 14 div cultures were fixed for 30 min with ice-cold 4% paraformaldehyde and then permeabilized for 30 min with 0.4% saponin in 2% normal donkey serum (NDS). Primary antibody incubations were performed overnight at 4°C using a monoclonal marker of endoplasmic reticulum recognizing endogenous ER-resident proteins containing the KDEL retention signal (KDEL 1:200, Abcam, Cambridge, MA). For detection we used Cy3-conjugated secondary antibodies (Jackson Laboratories, West Grove, PA) in 2% NDS for 1 h at room temperature. Close-up images of neurons were taken on a Leica confocal microscope using a 63X/1.4NA oil objective. The percentage of cells with aggregates was estimated by an unbiased count over multiple fields and coverslips.
Stereotactic injection into the rodent brain
Adult C57BL/6 mice were housed according to the Laboratory Vertebrate Animal protocols at Stanford. All surgeries were performed under aseptic conditions. The animals were anesthetized with intraperitoneal injections of ketamine (80 mg/kg)/xylazine (15–20 mg/kg) cocktail (Sigma). The head was shaved, cleaned with 70% ethanol and betadine and then placed in a stereotactic apparatus (Kopf Instruments, Tujunga, CA; Olympus stereomicroscope). Ophthalmic ointment was applied to prevent eye drying. A midline scalp incision was made and then a small craniotomy was performed using a drill mounted on the stereotactic apparatus (Fine Science Tools, Foster City, CA). The virus was delivered using a 10 μl syringe and a thin 34 gauge metal needle; the injection volume and flow rate (1 μl at 0.1 μl/min) was controlled with an injection pump from World Precision Instruments (Sarasota, FL). After injection the needle was left in place for 10 additional minutes and then slowly withdrawn. The skin was glued back with Vetbond tissue adhesive. The animal was kept on a heating pad until it recovered from anesthetic. Buprenorphine (0.03 mg/kg) was given subcutaneously following the surgical procedure to minimize discomfort. For hippocampal slice imaging: 1 μl of concentrated lentivirus (1010 i.u./ml) carrying NpHR or eNpHR under the CaMKIIα promoter was microinjected into the CA1 region of the left and right adult mouse hippocampus, respectively (anteroposterior, −2.0 mm from bregma; lateral, ±1.5 mm; ventral, 2 mm). For in vivo electrophysiology: 1 μl of eNpHR (1010 i.u./ml) virus was injected in the adult mouse thalamus (anteroposterior −1.8, mm from bregma; lateral, 1.5 mm; ventral, 3.5 mm).
Slice preparation and confocal imaging
For preparation of brain slices, mice were sacrificed 10 days after viral injection. Acute coronal brain slices (250 μm) were prepared in ice-cold cutting solution (64 mM NaCl, 25 mM NaHCO3, 10 mM glucose, 120 mM sucrose, 2.5 mM KCl, 1.25 mM NaH2PO4, 0.5 mM CaCl2, 7 mM MgCl2, and equilibrated with 95% O2/5% CO2) using a vibratome (VT1000S, Leica). The slices were then fixed for 1 h in 4% paraformaldehyde, washed with PBS, and mounted on microscope slides. Single confocal optical sections through the CA1 region or thalamus were acquired using a 40X/1.4NA oil objective on a Leica confocal microscope.
In vivo multiunit recordings
Simultaneous optical stimulation and electrical recording in living mice was done as described previously (Gradinaru et al., 2007) using an optrode composed of an extracellular tungsten electrode (1 MΩ, ~125 μm) tightly attached to an optical fiber (~200 μm, ThorLabs, Newton, NJ) with the tip of the electrode deeper (~0.3 mm) than the tip of the fiber, to ensure illumination of the recorded neurons. The fiberoptic was coupled to a 561 nm laser diode from CrystaLaser (Reno, NV). Single unit recordings were done in animals anesthetized with intraperitoneal injections of ketamine (80 mg/kg)/xylazine (15–20 mg/kg) cocktail (Sigma). pClamp 10 and a Digidata 1322A board (Axon Instruments, Sunnyvale, CA) were used to both collect data and generate light pulses through the fiber. The recorded signal was band pass filtered at 300 Hz low/5 kHz high (1800 Microelectrode AC Amplifier, A-M Systems). For precise placement of the fiber/electrode pair, stereotactic instrumentation (Kopf; Olympus stereomicroscope) was used. Immediately after recordings the animal was sacrificed and brain slices were prepared as described above to check for opsin expression and accurate placement of the optrode.
K.D. is supported by CIRM, McKnight, Coulter, Klingenstein, NSF, NIMH, NIDA, the NIH Pioneer Award, and the Kinetics Foundation. V.G. is supported by a Stanford Graduate Fellowship. K.R.T. is supported by NARSAD. We thank Feng Zhang and Joanna Mattis for providing us with the nhNpHR construct, and Andrew Hsu for assistance with cloning. We also thank the entire Deisseroth lab for useful discussions. The materials and methods described herein are freely distributed and supported by the authors (http://www.stanford.edu/group/dlab).
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- Hegemann P., Oesterhelt D., and Steiner M (1985). The photocycle of the chloride pump halorhodopsin. I: Azidecatalyzed deprotonation of the chromophore is a side reaction of photocycle intermediates inactivating the pump. EMBO J. 4z: 2347–2350.Google Scholar
- Li X, Gutierrez DV, Hanson MG, Han J, Mark MD, Chiel H, Hegemann P, Landmesser LT, Herlitze S (2005) Fast noninvasive activation and inhibition of neural and network activity by vertebrate rhodopsin and green algae channelrhodopsin. Proc Natl Acad Sci U S A 102:17816–17821.PubMedCrossRefGoogle Scholar
- Wang H, Peca, J, Matsuzaki M, Matsuzaki K, Noguchi J, Qiu L, Wang D, Zhang F, Boyden E, Deisseroth K, Kasai H, Hall WC, Feng G, Augustine GJ (2007). High-speed mapping of synaptic connectivity using photostimulation in Channelrhodopsin-2 transgenic mice. Proc. Natl. Acad. Sci. USA 104:8143–8148. PubMedCrossRefGoogle Scholar
- Zhang, F., Prigge, M., Beyriere, F., Tsunoda, S. P., Mattis, J., Yizhar, O., Hegemann, P., and Deisseroth, K. (2008). Red-shifted optogenetic excitation: A tool for fast neural control derived from Volvox carteri. Nat. Neurosci. 11, 631–633Google Scholar
- Zhao, S., Cunha, C., Zhang, F., Liu, Q., Gloss, B., Deisseroth, K., Augustine, G. J., and Feng, G. (2008). Improved expression of halorhodopsin for light-induced silencing of neuronal activity. Brain Cell Biol. 36, In this issueGoogle Scholar