概要

Ratiometric Calcium Imaging of Individual Neurons in Behaving Caenorhabditis Elegans

Published: February 07, 2018
doi:

概要

This protocol describes the use of genetically encoded Ca2+ reporters to record changes in neural activity in behaving Caenorhabditis elegans worms.  

Abstract

It has become increasingly clear that neural circuit activity in behaving animals differs substantially from that seen in anesthetized or immobilized animals. Highly sensitive, genetically encoded fluorescent reporters of Ca2+ have revolutionized the recording of cell and synaptic activity using non-invasive optical approaches in behaving animals. When combined with genetic and optogenetic techniques, the molecular mechanisms that modulate cell and circuit activity during different behavior states can be identified.

Here we describe methods for ratiometric Ca2+ imaging of single neurons in freely behaving Caenorhabditis elegans worms. We demonstrate a simple mounting technique that gently overlays worms growing on a standard Nematode Growth Media (NGM) agar block with a glass coverslip, permitting animals to be recorded at high-resolution during unrestricted movement and behavior. With this technique, we use the sensitive Ca2+ reporter GCaMP5 to record changes in intracellular Ca2+ in the serotonergic Hermaphrodite Specific Neurons (HSNs) as they drive egg-laying behavior. By co-expressing mCherry, a Ca2+-insensitive fluorescent protein, we can track the position of the HSN within ~ 1 µm and correct for fluctuations in fluorescence caused by changes in focus or movement. Simultaneous, infrared brightfield imaging allows for behavior recording and animal tracking using a motorized stage. By integrating these microscopic techniques and data streams, we can record Ca2+ activity in the C. elegans egg-laying circuit as it progresses between inactive and active behavior states over tens of minutes.

Introduction

A central goal of neuroscience is to understand how neurons communicate in circuits to drive animal behavior. Neural circuits integrate a range of diverse sensory cues in order to change circuit activity, thereby driving behavioral changes necessary for animals to respond to their environments. The nematode, C. elegans, has a simple nervous system with 302 neurons whose synaptic connections have been completely mapped1. Additionally, genes that encode for proteins involved in neurotransmission are highly conserved between C. elegans and mammals2. Despite the anatomical simplicity of its nervous system, it displays a complex repertoire of conserved behaviors providing a fertile platform to understand how neurons regulate behavior3.

C. elegans is amenable to the application of a wide range of approaches such as genetic manipulation, laser cell ablation, electrophysiological techniques, as well as in vivo optical imaging4,5. Recent studies have produced detailed maps of the major neurotransmitter signaling systems in C. elegans including the cholinergic and GABAergic neuronal networks. These studies, along with ongoing studies to map the expression of all neuronal G-protein coupled receptors place this model in a unique position to leverage highly detailed structural and functional neuronal connectivity maps to fully understand how these different neurotransmitters signal through different receptors and timescales to drive different aspects of animal behavior.

In order to study dynamic neuronal activity patterns in any system, an essential prerequisite is to develop robust methodologies to record activity in individual neurons or entire circuits during behaviors. Especially important is the amenability of such optical approaches to visualize presynaptic activity that drives synaptic vesicle fusion. Fast and highly sensitive fluorescent reporters of intracellular Ca2+, along with the increasing availability of sensitive photodetectors, have revolutionized the recording of cell and synaptic activity in awake, living animals during behavior. Because a major outcome of synaptic electrical activity is to regulate Ca2+ channels, changes in intracellular Ca2+ are thought to faithfully report behaviorally relevant changes in cell activity.

In this study, we present an approach to perform ratiometric Ca2+ imaging in the serotonergic HSN motor neurons that promote egg-laying behavior in C. elegans6,7. This approach builds on previous efforts to visualize Ca2+ activity in C. elegans and the egg-laying circuit during behavior5,8,9,10,11. The method allows to simultaneously correlate the observed changes in cell/circuit activity with egg-laying events, as well as changes in animal locomotor state. Although we use this approach to study activity in adult worms, unpublished work from our laboratory shows this approach can be extended to juvenile animals at the fourth larval (L4) stage as well. It is likely that the activity of other C. elegans neurons that function in distinct circuits and behaviors should be similarly accessible with this technique. Other recently developed fast Ca2+ indicators with non-overlapping emission spectra12,13,14,15,16, optogenetic tools17, and genetically encoded optical indicators of membrane voltage18, should allow us to perform penetrating 'all-optical' investigations into how changes in neural circuit activity drive distinct behavior states.

Protocol

1. Strains, Culture Media, and Mounting of Animals

  1. Grow C. elegans worms at 20 °C on standard 60-mm Nematode Growth Medium (NGM) agar plates seeded with OP50 E. coli bacterial food19.
  2. Prepare two plasmids for each cell-specific promoter of interest: one, driving expression of GCaMP5 to record intracellular Ca2+, and the second, driving expression of mCherry to allow for ratiometric quantitation of GCaMP5 fluorescence changes and simplify object finding and measurement.
    NOTE: GCaMP5:mCherry ratiometric imaging corrects for fluctuations in GCaMP5 fluorescence that result from changes in focus and animal movement, not actual changes in intracellular Ca2+.
  3. Inject GCaMP5- and mCherry-expressing plasmids along with the pL15EK visible rescue marker plasmid into the gonads of LX1832 lite-1(ce314), lin-15(n765ts) X mutant animals and recover non-Muv lin-15(+) animals expressing GCaMP5 and mCherry from a high-copy transgene20,21,22. Use the lite-1 mutant background to reduce blue-light avoidance behavior23,24.
  4. Integrate transgenes to chromosomes to reduce mosaicism and simplify the generation of compound mutant strains25.
    NOTE: The LX2004 strain described here carries an integrated high-copy transgene that expresses GCaMP5 and mCherry in the HSNs from the nlp-3 promoter (see Table of Materials)26,27,28,29. The nlp-3 promoter was found to drive strong expression in the HSNs of late L4 and adult animals without causing significant defects in HSN development or egg-laying behavior compared to other promoters tested (e.g.,tph-1, egl-6, and unc-86). This strain and others that express GCaMP5 and mCherry in the ventral cord (VC) motor neurons, vulval muscles, and uv1 neuroendocrine cells are available from the Caenorhabditis Genetics Center and details of their construction have been described27.
  5. Apply OP50 bacterial food from a seeded NGM agar plate to the bottom of a platinum worm pick, and use it to transfer ~ 20 late L4 LX2004 animals that express GCaMP5 and mCherry in the HSNs from the nlp-3 promoter. Ensure that the developing vulva appears in a stereomicroscope as a clear dark spot surrounded by a white crescent. Incubate animals at 20 °C for 24-40 h.
  6. After the incubation, apply OP50 to the pick and transfer ~ 3 of the worms to an unseeded NGM plate, leaving a small amount of food behind for the worms to feed upon during imaging. Ensure sufficient food, as too little bacterial food will encourage the worms to wander away from the center of the plate while too much food will increase background fluorescence and cause hypoxia.
  7. Use a flat rounded spatula to cut a ~ 20 mm x 20 mm chunk from the plate carrying the worms and transfer the chunk face-down onto the center of a clean 24 mm x 60 mm #1.5 coverslip (Figure 1). Start the application from one side to keep bubbles from being trapped under the coverslip and interfering with imaging. Apply a 22 mm x 22 mm #1 coverslip to the top of the chunk to reduce sticking and evaporation.

2. Hardware and Instrumentation Setup

  1. Place the staged, transgenic worms onto the stage of an inverted microscope with a ≥ 0.7 Numerical Aperture Plan-Apochromat 20x objective, motorized XY stage controllable with a joystick, an image splitter, and fluorescence filters for simultaneous GCaMP5 and mCherry excitation and emission, cameras for fluorescence and infrared brightfield imaging, and a triggerable Light Emitting Diode (LED) illumination system (Figure 2A).
    ​NOTE: An 80/20 beam-splitter sends 80% of the image signal to the fluorescence camera and 20% to the brightfield camera. An upright microscope can also be used, but the NGM chunk should be placed in between a glass slide and the large coverslip in this case.
    1. Use the binocular eyepieces to select a worm for imaging. When an animal is selected, slide the infrared filter in place above the condenser.
  2. Transistor-transistor logic (TTL) triggers
    1. Attach coaxial cables from each of the three TTL trigger output lines on the fluorescence camera. Connect the first output to the BNC input #3 of the LED illumination system.
    2. Connect the second output to a BNC 'banana' adapter with green and brown wires from the 8-pin GPIO connector running to GPIO input #3 (pin 4) and ground (pin 5) of the infrared camera, respectively.
    3. Connect the third output to a BNC 'banana' adapter with jumper wires running to the #8 digital input and ground in the digital acquisition device (Figure 2B).
  3. Digital acquisition device (DAQ)
    1. Connect the DAQ microcontroller board (see Table of Materials) to the PC via a USB cable. Update the firmware with the standard Firmata protocol (see Table of Materials) and configure the USB port to communicate at 57600 baud.
  4. LEDs
    1. Run the LED Controller software (see Table of Materials). Switch the Trigger Mode from 'Continuous' to 'Gated' and select Trigger Channel '3' for both the 470 and 590 nm LEDs.
    2. Turn on and enter LED power for each LED (e.g., set the 470 nm LED to 20% and the 590 nm LED to 40%).
  5. Run the serial-stage communication script 'XY-stage-final' in Bonsai (see Table of Materials)30. Click on the grey 'CsvWriter' node and select a folder to save the recorded X and Y stage information (Figure 3). Press the green arrowhead in the toolbar to initialize the DAQ.
    NOTE: The script will start recording the X and Y stage position when the fluorescence camera sends a TTL signal. This script outputs four columns of data: frame number, X position (µm), Y position (µm), and the interval between frames (s).
  6. In the infrared camera recording software (see Table of Materials) under 'Custom Video Modes,' select "Mode 1" (2 x 2 binning; 1,024 x 1,024 pixels), and "Pixel Format Raw 8". Under 'Trigger / Strobe', set the trigger input line (GPIO) to "3", the polarity to "High", the 'Mode' to "14". Toggle 'Enable' to stop frame acquisition until a TTL trigger signal is received.
    1. Leaving that window open, click the red "Record" button on the main camera view toolbar. Select the folder for image sequences to be saved. Select 'Buffered' Recording mode, and save 'Images' in JPEG format. Click "Start Recording" to initialize the acquisition.
  7. Fluorescence camera and image splitter
    NOTE: GCaMP5 and mCherry fluorescence channels must be collected simultaneously to ensure proper image registration for ratiometric quantitation. An image splitter allows two-channel acquisition of the GCaMP5 and mCherry fluorescence onto one sensor.
    1. In the 'Capture' tab of the image acquisition software (see Table of Materials), set exposure time to 10 ms, binning to 4x, and image depth to 16-bit. Select a centered camera subarray of 512 pixels wide by 256 pixels high. Click 'Show Output Trigger Options' and set all Triggers to 'Positive.'
      ​NOTE: The DAQ can occasionally miss TTL triggers if they are 10 ms or less.
    2. Ensure that 'Trigger 1' and 'Trigger 2' are set to 'Exposure' while 'Trigger 3' is set to 'Programmable' with a 'Period' of 25 ms. Under the 'Sequence' tab, select 'Time Lapse' with a 'Field Delay1' of 50 ms to collect images at 20 Hz. Select 'Save to Temporary Buffer.'
  8. PMT gain and laser intensity during three channel confocal imaging
    1. Set the PMT gain so the background fluorescence is at a level just above the minimum (black level). Increase 561 nm (green) laser power until a single saturated 12-bit or 16-bit pixel is observed at the presynaptic terminus in the mCherry channel.
    2. Adjust 488 nm (blue) laser intensity so that GCaMP5 fluorescence is just visible at the presynaptic terminus above background. This low setting prevents the saturation of the GCaMP5 pixels when the fluorescence increases in response to strong Ca2+ transients. Open the confocal pinhole all the way to maximize light capture.

3. Ratiometric Ca2+ Imaging and Behavior Recording

  1. Under the 'Sequence' tab in the fluorescence acquisition software, click "Start" to begin recording. Track the worm with the joystick, keeping the cell(s) and synapses of interest in focus and in the center of the field of view (FOV). Click the 'Stats' button in the histogram window to show pixel statistics of each channel.
  2. Adjust the LED power to ensure a maximum single-pixel mCherry fluorescence at the presynaptic terminus of ≥ 8,000 counts (~ 4,000 photoelectrons), giving a ~ 12-bit dynamic range above background (~ 100 photoelectrons). GCaMP5 signals at the presynaptic terminus during resting (low) Ca2+ should be around ~ 2,500 counts – just visible above background.
  3. Record until one egg-laying active state is reached; typically this occurs every 20-30 min in a wild-type worm7. Save a 10-min subset (12,001 frames), 6,000 frames before and after the first egg-laying event (frame 6,001). Be sure to keep the same subset of brightfield images of worm behavior and timepoints of XY stage position, or the precise synchronization of data streams will be lost.
  4. Use ImageJ and the BioFormats plugin (see Table of Materials) to convert image sequences to Image Cytometry Standard (.ics) format so that it can be imported into the Ratiometric Quantitation software.

4. Image Segmentation and Quantitative Analysis

  1. Import image sequences into the Ratiometric Quantitation software (see Table of Materials). Click 'Auto Contrast' in the 'Tools' menu, and adjust contrast of each channel to establish appropriate black (~ 1,800) and white levels (10,000). Select 'Change Colors…' in the Tools menu to confirm that mCherry and GCaMP5 channel color assignments are correct (Figure 4A – C).
    1. Right click on the Time Series in the 'Sequence' tab and set it to 20 frames/s and 1.25 µm/pixel.
  2. Select 'Ratio' from the 'Tools' menu and select "GCaMP5" for 'Channel A' and "mCherry" for 'Channel B'. Click "Calculate" next to 'Threshold' to subtract the background from each image sequence. Select "Apply a rainbow LUT to the ratio channel".
    NOTE: For a recording with a mean baseline ratio of 0.3 (low Ca2+) and a max ratio of 2-3 (high Ca2+), a suitable lookup table would be from 0 (blue) to 1 (red).
  3. Generate an Intensity Modulated Ratio channel using the mCherry channel (Figure 4D). The Intensity Modulated Ratio channel is a millions-of-colors image where the ratio color is mapped onto the brightness of the mCherry channel.
  4. Under the 'Measurements' tab, create an object-finding protocol by dragging the 'Find Objects Using Intensity' tool to the 'Protocol' pane. Click the 'cog' to set the window of mCherry intensity values and find objects.
    1. Select intensity values ≥ 2 standard deviations (SD) above background (e.g., lower limit of ~ 2,500, upper limit of 65,535). Make sure the presynaptic terminus is detected and that 'automatically update feedback' is selected from the Measurements menu.
      NOTE: The software can also identify objects by their standard deviation from background using a related protocol 'SD Intensity.' However, if an especially bright object enters the FOV, it can dramatically change the mean intensity during those timepoints, affecting the intensity cutoffs used to find the HSN. This variability will not occur if raw intensity values are used to find objects.
  5. Add additional filters targeting only the mCherry channel (size, Max intensity, etc.) if necessary to exclude undesired objects like head, tail, and gut fluorescence. Select 'Make Measurement Item' from the Measurements menu and choose 'All Timepoints.'
    NOTE: This will execute the protocol, writing all measurements to a comma-separated value (.csv) file that should be exported using the 'export' command in the File menu.
  6. Open exported.csv file and copy Timepoint, Area (µm2), Mean (Ratio Channel), Centroid X (µm), and Centroid Y (µm) data into a new sheet. Export a.csv file without column headers. The Ratiometric Quantitation software may classify a cell of interest as one or more objects per timepoint.
    1. To recombine these objects, use a custom script 'AnalzyeGCaMP_2017.m'.
      NOTE: The script also identifies Ca2+ (ratio) peaks in the data, and saves a.csv file of their timepoints, peak amplitudes, and peak widths. It also generates postscript files for the raw and annotated ratio traces. With this information, Ca2+ transient amplitude and inter-transient interval should be determined.
  7. Add the output X and Y centroid values from each fluorescence object to the X and Y values recorded by the XY-stage script from Bonsai. Use the net XY position to generate a worm locomotion trace and to calculate cell displacement and velocity that accompany different behavior states31.
  8. Import the recorded brightfield images into ImageJ as a virtual stack. Annotate egg-laying events and other behaviors. Compare the timing of these events to Ca2+ peaks from the ratio trace.

Representative Results

The simple mounting technique described here (Figure 1) causes minimal changes to the culture environment of L4 and adult C. elegans while allowing high resolution recording in behaving animals through a glass coverslip (Figure 4). Synchronization of LED light sources, stage controllers, and camera exposures allows for data acquisition from multiple streams at 20 frames/s for up to 1 h. Intermediate magnification (20x) with high numerical aperture objectives (0.7-0.8) provides good spatial resolution of the synaptic region in the egg-laying behavior circuit, even with 4 x 4 pixel binning (1.25 µm/pixel). Simultaneous acquisition of GCaMP5 and mCherry fluorescence signals (Figure 4A, B) is used to generate a pixel-by-pixel ratio channel that compensates for changes in animal movement and focus (Figure 4D). The HSN presynaptic terminus is as large as many neuronal cell bodies in C. elegans, and changes in presynaptic HSN Ca2+ can be clearly visualized. The large FOV of the infrared brightfield camera allows the worm to be manually tracked during recording (Figure 4E). For each animal, changes in intracellular Ca2+ can be correlated with behaviors evident in brightfield imaging including egg release and changes in locomotion (Figure 4E).

Quantitation of HSN Ca2+ and speed confirms that worms change their locomotion as they transition to egg-laying behavior. There are significant differences in worm speed before, during, and after the egg-laying active state (Figure 5A). This is not caused by noise inherent to the imaging or tracking system. Zooming into one egg-laying event, we observe a strong change in GCaMP5 fluorescence (ΔF/F) prior to the egg-laying event while mCherry fluorescence is relatively unchanged (Figure 5B). Measured changes in the GCaMP5:mCherry ratio (ΔR/R) clearly show an HSN Ca2+ transient ~ 4 s prior to egg release (Figure 5B). Coincident with vulval muscle contraction, a clear slowing of worm locomotion occurs that ends with egg release. Previous results have shown that the cholinergic VC motor neurons, which are innervated by the HSNs, show peak activity during strong vulval muscle contractions and during egg release 8,10,27. We have also shown that optogenetic activation of the VC neurons drives an immediate slowing of locomotion, suggesting that the VC neurons may be activated by vulval muscle contraction, thereby slowing locomotion until receiving feedback of egg release27.

The imaging and tracking system described allows visualization of the spatial organization of egg-laying behavior (Figure 5C). As previously shown, worms enter sustained runs of forward locomotion just prior to the active state32. Worms spend the majority of their time foraging on bacteria at the center of the agar chunk. Prior to entry into the active state, worms move away from the food, which is coincident with the appearance of infrequent HSN Ca2+ transients. HSN activity then transitions into burst firing, with several closely spaced HSN Ca2+ transients that sustain egg-laying events. The worms then often turn around, resume forward locomotion, and lay eggs on the way back toward their starting position near the OP50 bacteria. We presume that changes in local O2 and/or CO2 concentration may be influencing where the worms decide to lay eggs33,34.

Figure 1
Figure 1. C. elegans mounting technique for high-resolution imaging of egg-laying circuit activity and behavior. Top, the final mount from the side. Bottom, the final mount as viewed through the bottom of the large coverslip. Arrows indicate OP50 bacterial food, C. elegans worms and eggs, sandwiched between the NGM agar chunk and the large 24 mm x 60 mm coverslip. Please click here to view a larger version of this figure.

Figure 2
Figure 2. Widefield ratiometric Ca2+ imaging and behavior recording on an inverted epifluorescence microscope. (A) Worm position and behavior is captured in brightfield via a 20x (0.8 NA) Plan-Apochromat objective using infrared (750-790 nm) light (purple arrows) emitted from a halogen lamp through the NGM chunk. A joystick and motorized stage controller is used to maintain the worm in the field of view during recording. Stage position (Δx, Δy) is sent to the PC by the serial port. GCaMP5 and mCherry proteins expressed in the worm are excited using 470 nm (blue arrows) and 590 nm (yellow arrows) Light Emitting Diodes (LED). Emitted GCaMP5 (green arrows) and mCherry (orange arrows) fluorescence along with the infrared light passes through a multi-band dichroic mirror (see Table of Materials). An 80/20 beam-splitter sends 20% of the light through a 0.63x demagnifer for capture on an infrared-sensitive CMOS camera (purple arrow). The remaining 80% of the light is sent through the side-port of the microscope to an image splitter that separates the GCaMP5 and mCherry fluorescence onto separate halves of an sCMOS camera while removing infrared brightfield light. Data from both cameras are transferred to a PC via USB3 cables. The trigger ports from the fluorescence sCMOS camera (blue) are used to send +5V TTL triggers to the LED illumination system, the infrared brightfield CMOS camera, and the Digital Acquisition Device (DAQ). (B) Trigger 3 output TTL signals are detected by the DAQ at digital pin #8 and sent to the PC through a USB connection. These digital inputs trigger a 'where XY' serial command from a Bonsai software script (XY-stage-final) which reads the X and Y stage position for each GCaMP5/mCherry fluorescence/infrared image captured. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Layout of the Bonsai serial-stage communication script XY-stage-final. The top DigitalInput node (pink) reads TTL triggers coming into pin #8 of the DAQ. For each positive TTL voltage (green), the DAQ makes a timestamp (blue) and writes a 'Where XY?' string (pink) to the stage controller via the serial port (grey). The SerialStringRead node (pink) reads the X and Y coordinate response from the stage controller. This string is then converted into microns and separated into X and Y stage coordinates. Finally, these four streams are combined using a zip node (blue) and a four column.csv file is written: a frame count of the TTL signals received (Range node, pink), the X and Y coordinates, and the interval between subsequent timepoints (typically ~ 50 ms when recording at 20 Hz). Please click here to view a larger version of this figure.

Figure 4
Figure 4: Representative micrographs of HSN fluorescence and whole animal brightfield during egg-laying behavior. (AD) Simultaneous ratiometric imaging of GCaMP5 and mCherry fluorescence in the HSNs just prior to egg release. HSN presynaptic termini are indicated with arrowheads. (C) Merge of GCaMP5 and mCherry fluorescence. (D) Intensity-modulated GCaMP5:mCherry ratio; a high ratio (red) indicates high intracellular Ca2+ at the presynaptic terminus. (E) Brightfield image of the entire worm just after eggs have been laid. Arrowheads indicate the anterior and posterior halves of the vulva from which eggs are laid. Scale bar for all images is 50 µm. Please click here to view a larger version of this figure.

Figure 5
Figure 5: Recording of HSN Ca2+ and locomotion speed during egg-laying behavior. (A) Traces of GCaMP5:mCherry ratio changes in response to intracellular Ca2+ transients (ΔR/R; red) along with instantaneous worm speed (µm/s; blue). Egg-laying events are indicated by arrowheads. (B) Traces of HSN GCaMP5 fluorescence (green; ΔF/F), mCherry fluorescence (red; ΔF/F), GCaMP5:mCherry fluorescence ratio (black; ΔR/R), and worm speed (blue) around the moment of egg release. (C) Spatial organization of egg-laying and locomotion behaviors during the entire 10-min recording. The worm track was obtained from the XY stage information which was added to the centroid position of the HSN obtained from the mCherry fluorescence recording. The timing of HSN transients (red circles), egg-laying events (black arrowheads), and the start and end of the recording (green and blue diamonds) are indicated. Scale bar is 1 mm. Please click here to view a larger version of this figure.

Discussion

Transgenes:

Because mCherry expression has been improved through codon-optimization and intron insertion (and most available GCaMP reporters have not), inject ~ 4x the amount of GCaMP5-expressing plasmid to ensure comparable levels of GCaMP5 fluorescence during strong Ca2+ transients. Rescue of the lin-15(n765ts) mutation allows for the facile recovery of transgenic animals with minimal effects on egg-laying and other behaviors35. Transgenes should be integrated to ensure uniform expression and imaging conditions between different animals25. Selectable markers including antibiotic resistance36,37 and rescue of temperature-sensitive lethals38 should also work, but, because non-transgenic animals are dead, confirmation of transgene integration and homozygosity is more difficult compared to markers that present a visible phenotype25. Dominant markers that disrupt normal locomotion and decrease fitness, such as rol-6(dm), should be avoided39. Imaging in the lite-1 mutant background is essential to reduce blue light escape responses during imaging23,40,41. Additional mutation of gur-3, which acts in parallel to lite-1, may further minimize residual behavior and physiological changes caused by blue light42. Conveniently, gur-3, lite-1, and lin-15 are all situated on the right half of chromosome X, which should simplify the construction of new strains for Ca2+ imaging and optogenetic experiments.

Because exposure times are short and images are collected at 20 Hz, GCaMP5 and mCherry signals must be bright. The most likely explanation for noisy Ca2+ recordings is dim fluorescence caused by weak reporter expression. Promoters should also be reasonably specific for the region being imaged. Because the HSN cell body and synapses onto the vulval muscles are in the center of the body, additional expression from the nlp-3 promoter in the head and tail is typically outside the field of view and can be excluded using additional filters in the Ratiometric Quantitation software. To ensure that observed changes in GCaMP5 fluorescence result from actual changes in intracellular Ca2+, control transgenes expressing GFP instead of GCaMP5 should be independently prepared and analyzed26. Newer Ca2+ reporters with different Ca2+ sensitivities, kinetics, and colors have expanded the choice of imaging tools available, but each new reporter should be validated using the Ca2+-insensitive fluorescent variant14,16.

Media:

NGM plates for imaging should be prepared with high quality agar. Lower quality agar will not completely dissolve upon autoclaving, leaving small particulates that scatter light during imaging, and increasing background fluorescence. Molecular biology grade agarose can be used instead, but the amount added should be reduced to maintain equivalent plate firmness.

Comparisons to Other Mounting Methods:

Previous approaches to image activity in the egg-laying behavior circuit have used worms immobilized with glue to an agarose pad. Under these conditions, circuit activity and egg-laying behavior is not favored without a reduction in culture media osmolarity8,10,44,45. Recent evidence suggests that several worm behaviors are modulated by locomotion state, raising questions about the relationship of cell activity observed in immobilized animals to that seen in freely behaving animals. We have recently shown that egg-laying circuit activity is unexpectedly phased with locomotion26,27. Similarly, compartmentalized Ca2+ signaling in the RIA interneuron integrates activity from sensory neurons and head motor neurons during foraging movements46. Defecation behavior is also accompanied by a precise and stereotypical change in locomotion that allows animals to move away from their foraging spot before expelling waste47. Together, these results suggest that brief recordings of circuit activity from immobilized animals may be fundamentally different from those obtained in freely behaving animals.

Despite being directly beneath a coverslip, the worm's behavior resembles that seen on standard NGM plates. Laid eggs will go on to hatch, and the small amount of food deposited allows the L1 larvae to grow into adults (data not shown). The large agar chunk size allows for reasonable gas exchange and resists dehydration, although too much food will increase background fluorescence. While this method works best for adults, the technique can also be used to image L4 animals. However, the thickness of the aqueous layer between the chunk and the coverslip is such that smaller larvae have difficulty crawling, and can often get trapped in the wake of a moving adult.

A limitation of this mounting technique is that direct mechanical or chemical stimulation to precise regions of the body is difficult. Recent developments in patterned illumination techniques allow for the separate excitation of head or tail-expressed microbial opsins with separate illumination and detection of GCaMP/mCherry fluorescence in the midbody48,49. As a result, it may be possible to overcome this issue using optogenetic approaches.

Comparisons to Other Ca2+ Imaging Approaches:

This method works very well for recording changes in cytoplasmic Ca2+ from single, resolved cells and their synaptic regions. Real-time, volumetric imaging of neurons in the head has recently been achieved using the position of cell nuclei for cell identification and to quantitate changes in nucleoplasmic calcium50,51,52. The relationship between nuclear and synaptic Ca2+ remains unclear. Our data suggest the most conspicuous changes in HSN intracellular Ca2+ occur at the presynaptic termini away from the cell soma (Figure 4D). The presynaptic termini of the HSN and the VC neurons are embedded in the postsynaptic vulval muscles26. It is not clear whether there would be sufficient resolution in the Z dimension even with spinning disk or light sheet techniques to ascribe presynaptic Ca2+ signals to specific cells without relying in some way on somatic calcium for cell identification. Using the techniques described here, each 10 min, two-channel recording with 12,001 256 x 256 16-bit pixel TIFF images is ~ 4 GB. The ratio and intensity modulated ratio channels double the file size to ~ 8 GB. A typical experiment recording 10 animals from each of two genotypes (wild-type and experimental) generates nearly 150 GB of primary data and requires 20 h to collect and analyze. Volumetric analyses with 10 Z slices per timepoint would require an order of magnitude more data and analytical time, explaining why so few such studies have been completed.

Hardware:

We record and analyze image sequences on dual processor workstations with high-performance (e.g., gaming) graphics cards, 64 GB of RAM, and high performance solid-state drives (see Table of Materials). Data should be stored on networked redundant array of independent disks (RAID) and backed up to the cloud at an off-site data center.

We recommend using high-power collimated LEDs for pulsed fluorescence excitation over metal halide or mercury-based light sources. Several commercially available multi-color LED systems are available. While some of these LED systems have a higher upfront cost, they have a long-life (> 20,000 h), can simultaneously excite four or more different fluorophores, and offer precise temporal control using a serial and/or TTL interface with low latency (10-300 µs switch time). Triggering ensures that the sample is only illuminated when data are actually being collected. We typically use a 10 ms exposure every 50 ms (20% duty rate). This reduces phototoxicity and motion blur during image capture, as previously reported43.

We use sCMOS cameras for their speed and large array of small, sensitive pixels. An EM-CCD camera is a more expensive alternative, but 'bloom' effects can result in captured photoelectrons spilling into adjacent pixels. New back-illuminated sCMOS cameras have similar photosensitivity of EM-CCDs at significantly reduced cost. Regardless which sensor is used, the GCaMP5 and mCherry channels must be obtained simultaneously. Sequential capture in moving worms will lead to poorly registered images unsuitable for ratiometric quantitation. Dual channel imaging can be accomplished onto a single camera after splitting of channels using an image splitter (Figure 2) or using two identical cameras. The dynamic range of 16-bit images is recommended over 8-bit images for accurate ratiometric quantitation. For brightfield images of worm behavior, we capture using a 1 in. 4.1 MP near-infrared USB3 camera to capture large 2 x 2 binned 1,024 x 1,024 8-bit image sequences after JPEG compression. The larger FOV available on newer microscope models allows an adult worm to be visualized at 20x after 0.63x demagnification with only slight vignetting (Figure 4E).

We recommend using standard TTL voltage signals to synchronize illumination and frame capture. Because of potential latencies in different software programs, we recommend users configure the fluorescence camera with trigger outputs as master with TTL outputs driving all other devices. In this way, brightfield and stage position information will be collected for each Ca2+ measurement.

Slit- or resonant point-scanning confocal microscopes typically found in shared confocal facilities also give excellent performance during ratiometric Ca2+ imaging. Such instruments can be used to capture two or more fluorescence channels along with brightfield24. In this case, the confocal pinhole should be opened to its maximum diameter, and a spectral detector should be used to separate GCaMP5, mCherry, and infrared brightfield signals. This maximizes light collection from a thick (~ 20 µm) slice while still allowing rejection of out-of-focus fluorescence. One downside is the smaller FOV and more restrictions for hardware and software customization.

Software:

Most manufacturers ship and install their cameras and microscopes with proprietary software, including configuration of triggering inputs and outputs. The features and performance of this software during recording can vary. Because fast moving worms can be challenging to track, image display during recording needs to be smooth and stable at 20 Hz. To improve performance, image sequences can be temporarily saved in RAM with behaviorally relevant subsets saved at the end of the experiment. These two-channel image sequence files can be converted to the open Image Cytometry Standard format (.ics) for import into the Ratiometric Quantitation software. OME-TIFF is a more recent open-source image format, although different installations may be unable to save TIFF image sequences greater than 4 GB.

A key feature of the quantitation pipeline is the generation of the ratio channel and then an unbiased image segmentation procedure using mCherry fluorescence to find cells of interest. From each found object, the object size, XY centroid position, and the minimum, mean, and maximum fluorescence intensity values for each channel (including the ratio channel) are calculated. Together, these values are used to quantitate changes in intracellular Ca2+ at each timepoint in the recording. Object measurements for each timepoint are then exported as a.csv file for subsequent analyses.

A major limitation of the protocol described here is the dependence on moving the data in different forms through a patchwork of software products. An additional irritation is that some of the software is open-source and free while others are closed, expensive, and unevenly updated. A major improvement would be to use or develop one piece of software (ideally open-source) that provides similar levels of performance and ease-of-use from acquisition to analysis. As noted above, ratiometric analysis doubles both the file size and time required to complete an experiment. Generation of camera drivers that can be integrated into user-customizable frameworks like Bonsai would allow images and other data streams to be collected and analyzed in real-time, significantly improving throughput.

Future Prospects:

While we typically track worm movements manually, tracking of the worm centroid detected in infrared bright- or dark-field recordings should allow for additional image processing nodes that provide closed-loop adjustment of stage position and automated tracking (Figure 3 and data not shown). The majority of the fluorescence recordings obtained with this method is dark and devoid of biologically interesting data. On-sensor or real-time post-acquisition image processing techniques that crop image sequences to relevant objects would allow for increased spatial resolution and expedite the data analysis pipeline, particularly if additional Z-slices are collected for each timepoint to visualize activity within all pre- and postsynaptic cells in the circuit.

開示

The authors have nothing to disclose.

Acknowledgements

This work was funded by a grant from NINDS to KMC (R01 NS086932). LMN was supported by a grant from the NIGMS IMSD program (R25 GM076419). Strains used in this study C. elegans Genetics Center, which is funded by NIH Office of Research Infrastructure Programs (P40 OD010440). We thank James Baker and Mason Klein for helpful discussions.

Materials

C. elegans growth, cultivation, and mounting
Escherichia coli bacterial strain, OP50 Caenorhabditis Genetic Center OP50 Food for C. elegans. Uracil auxotroph. E. coli B. Biosafety Level 1
HSN GCaMP5+mCherry worm strain Caenorhabditis Genetic Center LX2004 Integrated transgene using nlp-3 promoter to drive GCaMP5 and mCherry expression in HSN.  Full genotype:  vsIs183 [nlp-3p::GCaMP5::nlp-3 3'UTR + nlp-3p::mCherry::nlp-3 3'UTR + lin-15(+)], lite-1(ce314), lin-15(n765ts) X
lite-1(ce314), lin-15(n765ts) mutant strain for transgene preparation author LX1832 Strain for recovery of high-copy transgenes after microinjection with pL15EK lin-15(n765ts) rescue plasmid. Also bears the linked lite-1(ce314) mutation which reduces blue-light sensitivity. Available from author by request
pL15EK lin-15a/b genomic rescue plasmid author pL15EK Rescue plasmid for recovery of transgenic animals after injection into LX1832 lite-1(ce314), lin-15(n765ts) X strain. Available from author by request
pKMC299 plasmid author pKMC299 Plasmid for expression of mCherry in the HSNs from the nlp-3 promoter. Has nlp-3 3' untranslated region
pKMC300 plasmid author pKMC300 Plasmid for expression of GCaMP5 in the HSNs from the nlp-3 promoter. Has nlp-3 3' untranslated region
Potassium Phosphate Monobasic Sigma P8281 For preparation of NGM plates
Potassium Phosphate Dibasic Sigma P5655 For preparation of NGM plates
Magnesium Sulfate Heptahydrate Amresco 0662 For preparation of NGM plates
Calcium Chloride Dihydrate Alfa Aesar 12312 For preparation of NGM plates
Peptone Becton Dickinson 211820 For preparation of NGM plates
Sodium Chloride Amresco 0241 For preparation of NGM plates
Cholesterol Alfa Aesar A11470 For preparation of NGM plates
Agar, Bacteriological Type A, Ultrapure Affymetrix 10906 For preparation of NGM plates
60 mm Petri dishes VWR 25384-164  For preparation of NGM plates
24 x 60 mm micro cover glasses, #1.5 VWR 48393-251 Cover glass through which worms are imaged
22 x 22 mm micro cover glasses, #1 VWR 48366-067 Cover glass that covers the top of the agar chunk
Stereomicroscope with transmitted light base Leica M50 Dissecting microscope for worm strain maintenance, staging, and mounting
Platinum iridium wire, (80:20), 0.2mm ALFA AESAR AA39526-BW For worm transfer
Calcium imaging microscope
Anti-vibration air table TMC 63-544 Micro-g' Lab Table 30" x 48" anti-vibration table with 4" CleanTop M6 on 25mm top
Inverted compound microscope Zeiss 431007-9902-000 Axio Observer.Z1 inverted microscope
Sideport L80/R100 (3 position) Zeiss 425165-0000-000 To divert 20% of output to brightfield (CMOS) camera, 80% to fluorescence (sCMOS) camera
Tilt Back Illumination Carrier Zeiss 423920-0000-000 For infrared/behavior imaging
Lamphousing 12V/100W w/ Collector Zeiss 423000-9901-000 For infrared/behavior imaging
Halogen lamp 12V/100W Zeiss 380059-1660-000 For infrared/behavior imaging. White-light LEDs do not emit significant infrared light, so they will not allow brightfield imaging after the infrared bandpass filter
32 mm Infrared bandpass filter (750-790 nm) for Halogen lamp Zeiss 447958-9000-000 BP 750-790; DMR 32mm, for infrared illumination for brightfield and behavior
6-filter Condenser Turret (LD 0.55 H/DIC/Ph), Motorized Zeiss 424244-0000-000 For infrared/behavior imaging
Condenser & Shutter Zeiss 423921-0000-000 For infrared/behavior imaging
Binocular eyepiece with phototube for infrared CMOS camera Zeiss 425536-0000-000 For infrared/behavior imaging
Eyepiece 10x, 23mm Zeiss 444036-9000-000 For worm localization on the agar chunk
C-Mount Adapter 2/3" 0.63x demagnifier Zeiss 426113-0000-000 Mount for infrared CMOS camera
CMOS camera for infrared brightfield and behavior (1" sensor) FLIR (formerly Point Grey Research) GS3-U3-41C6NIR-C Camera for brightfield imaging
USB 3.0 Host Controller Card FLIR (formerly Point Grey Research) ACC-01-1202 Fresco FL1100, 4 Ports
8 pins, 1m GPIO Cable, Hirose HR25 Circular Connector  FLIR (formerly Point Grey Research) ACC-01-3000 Cable for TTL triggering. The green wire connects to GPIO3 / Pin 4 and the brown wire connects to Ground / Pin 5
Plan-Apochromat 20x/0.8 WD=0.55 M27 Zeiss 420650-9901-000 Best combination of magnification, numerical aperture, and working distance
6-cube Reflector Turret, Motorized Zeiss 424947-0000-000 For fluorescence imaging
Fluorescence Light Train, Motorized Zeiss 423607-0000-000 For fluorescence imaging
Fluorescence Shutter Zeiss 423625-0000-000 For fluorescence imaging
GFP and mCherry dual excitation and emission filter cube (for microscope) Zeiss 489062-9901-000 FL Filter Set 62 HE BFP+GFP+HcRed for fluorescence imaging
LED illumination system Zeiss 423052-9501-000 Triggerable Colibri.2 LED system for fluorescent illumination
GFP LED module (470 nm) Zeiss 423052-9052-000 Colibri.2 LED for GFP fluorescence excitation
mCherry LED module (590 nm) Zeiss 423052-9082-000 Colibri.2 LED for mCherry fluorescence excitation
Iris stop slider for incident-light equipment Zeiss 000000-1062-360 Field aperture iris to limit LED illumination to the camera field of view
C-Mount Adapter 1" 1.0x Zeiss 426114-0000-000 Adapter for image-splitter and sCMOS fluorescence camera
Image splitter Hamamatsu A12801-01 Gemini W-View, other image splitters may be used, but they may not be optimized for the large sensor size of the sCMOS cameras
GFP / mCherry dichroic mirror (image splitter) Semrock Di02-R594-25×36 Splitting GCaMP5 from mCherry and infrared signals
GFP emission filter (image splitter) Semrock FF01-525/30-25 Capturing GCaMP5 fluorescence
mCherry/ emission filter (image splitter) Semrock FF01-647/57-25 This filter is necessary to exclude the infrared light used for brightfield imaging
sCMOS camera for fluorescence (1" sensor) Hamamatsu A12802-01 / C11440-22CU Orca FLASH 4.0 V2. Newer models allow for separate image acquisition settings on separate halves of the sensor, allowing acquisition of two-channel images in combination with an image splitter
Motorized XY Stage Märzhäuser SCAN IM 130 x 100 Stage movement; the XY resolution of this stage is 0.2µm per step 
XY Stage controller with joystick LUDL MAC6000, XY joystick Manual tracking of worms. MAC6000 controller should be connected to the PC through the serial (RS-232) port configured to 115200 baud
Digital Acquisition board (DAQ) Arduino Uno Receiving TTL triggers from sCMOS camera. The Uno should be loaded with the standard Firmata package, and the computer USB port configured to 57600 baud
BNC Male to BNC Male Cable – 6 ft Hosa Technology HOBB6 BNC connectors for TTL triggering
Gold-Plated BNC Male to SMA male coaxial cable (8.8") uxcell 608641773651 To connect the fluorescence camera trigger outputs
BNC turn head adapter Hantek RRBNCTH21 BNC to Banana Plug Adapter (4mm)
BNC female to female connector Diageng 20130530009 Female to female BNC adapter to connect the BNC output from the camera to the Banana Plug
Solderless flexible breadboard jumper wires Z&T GK1212827 To connect the BNC trigger outputs to the Arduiono DAQ.  Male to male.
High performace workstation HP Z820 Windows 7, 64GB RAM, Dual Xeon processor, solid state C: drive, serial (RS-232) port, multiple PCIe3 slots for ethernet connectivity, USB 3.0 cards, and additional solid state drives
M.2 Solid state drive Samsung MZ-V5P512BW High-speed streaming and analysis of image data
M.2 Solid state drive adapter for workstations Lycom DT-120 M.2 to PCIe 3.0 4-lane adapter
Network attached storage Synology DS-2415+ Imaging data storage and analysis
Hard disk drives Western Digital WD80EFZX RED 8 TB, 5400 RPM Class SATA 6 Gb/s 128MB Cache 3.5 Inch. Storage of imaging data (10 drives + 2 drive redundancy)
Software
Fluorescence Acquisition Hamamatsu HCImage DIA Recording of two channel (GCaMP5 and mCherry) fluorescence image sequences at 20 fps
Brightfield Acquisition FLIR (formerly Point Grey Research) Flycapture Recording of brightfield JPEG image sequences
Stage Serial Port Reader Bonsai https://bitbucket.org/horizongir/bonsai Facilitates tracking of worms during behavior
LED controller software Zeiss Micro Toolbox Test 2011 To set up the intensity and trigger inputs for the different LEDs in the Colibri.2 unit
ImageJ  NIH https://imagej.net/Fiji/Downloads Simple review of image sequences and formatting changes for import into Ratiometric Quantitation software
Excel Microsoft  2002984-001-000001 For generating subsets of comma-separated value data from Volocity for MATLAB analysis
Peak Finding MATLAB R2017a Script used for Ratio peak feature calculations
Ratiometric Quantitation Perkin Elmer Volocity 6.3 Facilitates calculation of ratiometric image channels, image segmentation for object finding, and ratio measurement of found objects
Scripts
AnalyzeGCaMP_2017.m MATLAB Mean Ratio and XY centroid script Analyzes a ratiometric output in .csv format, consolidating objects and centroid positions, calculating ratio changes (∆R/R), identifying peaks and peak features, and writing plots (with and without annotated peaks) in postscript format. For matrix file import, the script will output data into three folders:  analyzed, peaks, and traces. 'Analyzed' output is a matrix file of the consolidated objects with six columns (units):  time (s), area (square microns), ratio, X centroid (microns), Y centroid (microns), and ∆R/R. 'Peaks' output is a matrix file of the timepoints of found peaks, the amplitude (in ∆R/R), the peak width (s), and the prominance of the peak. 'Traces' output are postscript files of calcium traces.
XY-stage-final.bonsai Bonsai TTL-triggered DAQ and stage position serial port reader Records X and Y stage position (in microns) when the attached Arduino receives a positive TTL signal from sCMOS camera during frame exposure. Script writes a .csv file with four columns: frame number, X position (microns), Y position (microns), and the time elapsed between frames (typically ~50 msec when recording at 20 fps).  X and Y stage position from this output (columns 2 and 3, respectively) are added to the X and Y centroid positions from the AnalyzeGCaMP_2017.m MATLAB script (columns 4 and 5, respectively), to give the final X and Y position of the fluorescent object for the recording. 

参考文献

  1. White, J. G., Southgate, E., Thomson, J. N., Brenner, S. The structure of the nervous system of the nematode Caenorhabditis elegans. Phil Trans R. Soc. 314, 1-340 (1986).
  2. Bargmann, C. I. Neurobiology of the Caenorhabditis elegans genome. Science. 282, 2028-2033 (1998).
  3. Piggott, B. J., Liu, J., Feng, Z., Wescott, S. A., Xu, X. Z. S. The neural circuits and synaptic mechanisms underlying motor initiation in C. elegans. Cell. 147, 922-933 (2011).
  4. Chung, S. H., Sun, L., Gabel, C. V. In vivo neuronal calcium imaging in C. elegans. J. Vis. Exp. JoVE. , (2013).
  5. Kerr, R., et al. Optical imaging of calcium transients in neurons and pharyngeal muscle of C. elegans. Neuron. 26, 583-594 (2000).
  6. Desai, C., Garriga, G., McIntire, S. L., Horvitz, H. R. A genetic pathway for the development of the Caenorhabditis elegans HSN motor neurons. Nature. 336, 638-646 (1988).
  7. Waggoner, L. E., Zhou, G. T., Schafer, R. W., Schafer, W. R. Control of alternative behavioral states by serotonin in Caenorhabditis elegans. Neuron. 21, 203-214 (1998).
  8. Zhang, M., et al. A self-regulating feed-forward circuit controlling C. elegans egg-laying behavior. Curr. Biol. CB. 18, 1445-1455 (2008).
  9. Shyn, S. I., Kerr, R., Schafer, W. R. Serotonin and Go modulate functional states of neurons and muscles controlling C. elegans egg-laying behavior. Curr. Biol. CB. 13, 1910-1915 (2003).
  10. Zhang, M., Schafer, W. R., Breitling, R. A circuit model of the temporal pattern generator of Caenorhabditis egg-laying behavior. BMC Syst. Biol. 4, 81 (2010).
  11. Kerr, R. A., Schafer, W. R. Intracellular Ca2+ imaging in C. elegans. Methods Mol. Biol. Clifton NJ. 351, 253-264 (2006).
  12. Akerboom, J., et al. Optimization of a GCaMP calcium indicator for neural activity imaging. J. Neurosci. Off. J. Soc. Neurosci. 32, 13819-13840 (2012).
  13. Dana, H., et al. Sensitive red protein calcium indicators for imaging neural activity. eLife. 5, (2016).
  14. Inoue, M., et al. Rational design of a high-affinity, fast, red calcium indicator R-CaMP2. Nat. Methods. 12, 64-70 (2015).
  15. Oheim, M., et al. New red-fluorescent calcium indicators for optogenetics, photoactivation and multi-color imaging. Biochim. Biophys. Acta. 1843, 2284-2306 (2014).
  16. Chen, T. -. W., et al. Ultrasensitive fluorescent proteins for imaging neuronal activity. Nature. 499, 295-300 (2013).
  17. Kim, C. K., Adhikari, A., Deisseroth, K. Integration of optogenetics with complementary methodologies in systems neuroscience. Nat. Rev. Neurosci. 18, 222-235 (2017).
  18. Storace, D., et al. Toward Better Genetically Encoded Sensors of Membrane Potential. Trends Neurosci. 39, 277-289 (2016).
  19. Brenner, S. The genetics of Caenorhabditis elegans. 遺伝学. 77, 71-94 (1974).
  20. Mello, C., Fire, A. DNA transformation. Methods Cell Biol. 48, 451-482 (1995).
  21. Berkowitz, L. A., Knight, A. L., Caldwell, G. A., Caldwell, K. A. Generation of stable transgenic C. elegans using microinjection. J. Vis. Exp. JoVE. , (2008).
  22. Clark, S. G., Lu, X., Horvitz, H. R. The Caenorhabditis elegans locus lin-15, a negative regulator of a tyrosine kinase signaling pathway, encodes two different proteins. 遺伝学. 137, 987-997 (1994).
  23. Edwards, S. L., et al. A novel molecular solution for ultraviolet light detection in Caenorhabditis elegans. PLoS Biol. 6, 198 (2008).
  24. Thapaliya, E. R., et al. Bioimaging with Macromolecular Probes Incorporating Multiple BODIPY Fluorophores. Bioconjug. Chem. 28, 1519-1528 (2017).
  25. Mariol, M. -. C., Walter, L., Bellemin, S., Gieseler, K. A rapid protocol for integrating extrachromosomal arrays with high transmission rate into the C. elegans genome. J. Vis. Exp. JoVE. , e50773 (2013).
  26. Collins, K. M., Koelle, M. R. Postsynaptic ERG Potassium Channels Limit Muscle Excitability to Allow Distinct Egg-Laying Behavior States in Caenorhabditis elegans. J. Neurosci. Off. J. Soc. Neurosci. 33, 761-775 (2013).
  27. Collins, K. M., et al. Activity of the C. elegans egg-laying behavior circuit is controlled by competing activation and feedback inhibition. eLife. 5, e21126 (2016).
  28. Li, P., Collins, K. M., Koelle, M. R., Shen, K. LIN-12/Notch signaling instructs postsynaptic muscle arm development by regulating UNC-40/DCC and MADD-2 in Caenorhabditis elegans. eLife. 2, 00378 (2013).
  29. Banerjee, N., Bhattacharya, R., Gorczyca, M., Collins, K. M., Francis, M. M. Local neuropeptide signaling modulates serotonergic transmission to shape the temporal organization of C. elegans egg-laying behavior. PLoS Genet. 13, 1006697 (2017).
  30. Lopes, G., et al. Bonsai: an event-based framework for processing and controlling data streams. Front. Neuroinformatics. 9, 7 (2015).
  31. Flavell, S. W., et al. Serotonin and the neuropeptide PDF initiate and extend opposing behavioral states in C. elegans. Cell. 154, 1023-1035 (2013).
  32. Hardaker, L. A., Singer, E., Kerr, R., Zhou, G., Schafer, W. R. Serotonin modulates locomotory behavior and coordinates egg-laying and movement in Caenorhabditis elegans. J. Neurobiol. 49, 303-313 (2001).
  33. Ringstad, N., Horvitz, H. R. FMRFamide neuropeptides and acetylcholine synergistically inhibit egg-laying by C. elegans. Nat. Neurosci. 11, 1168-1176 (2008).
  34. Hallem, E. A., et al. Receptor-type guanylate cyclase is required for carbon dioxide sensation by Caenorhabditis elegans. Proc. Natl. Acad. Sci. U. S. A. 108, 254-259 (2011).
  35. Tanis, J. E., Moresco, J. J., Lindquist, R. A., Koelle, M. R. Regulation of serotonin biosynthesis by the G proteins Galphao and Galphaq controls serotonin signaling in Caenorhabditis elegans. 遺伝学. 178, 157-169 (2008).
  36. Giordano-Santini, R., et al. An antibiotic selection marker for nematode transgenesis. Nat. Methods. 7, 721-723 (2010).
  37. Semple, J. I., Garcia-Verdugo, R., Lehner, B. Rapid selection of transgenic C. elegans using antibiotic resistance. Nat. Methods. 7, 725-727 (2010).
  38. Granato, M., Schnabel, H., Schnabel, R. pha-1, a selectable marker for gene transfer in C. elegans. Nucleic Acids Res. 22, 1762-1763 (1994).
  39. Mello, C. C., Kramer, J. M., Stinchcomb, D., Ambros, V. Efficient gene transfer in C.elegans: extrachromosomal maintenance and integration of transforming sequences. EMBO J. 10, 3959-3970 (1991).
  40. Gong, J., et al. The C. elegans Taste Receptor Homolog LITE-1 Is a Photoreceptor. Cell. 167, 1252-1263 (2016).
  41. Liu, J., et al. C. elegans phototransduction requires a G protein-dependent cGMP pathway and a taste receptor homolog. Nat. Neurosci. 13, 715-722 (2010).
  42. Bhatla, N., Horvitz, H. R. Light and hydrogen peroxide inhibit C. elegans Feeding through gustatory receptor orthologs and pharyngeal neurons. Neuron. 85, 804-818 (2015).
  43. Larsch, J., Ventimiglia, D., Bargmann, C. I., Albrecht, D. R. High-throughput imaging of neuronal activity in Caenorhabditis elegans. Proc. Natl. Acad. Sci. U. S. A. 110, 4266-4273 (2013).
  44. Zang, K. E., Ho, E., Ringstad, N. Inhibitory peptidergic modulation of C. elegans serotonin neurons is gated by T-type calcium channels. eLife. 6, (2017).
  45. Branicky, R., Miyazaki, H., Strange, K., Schafer, W. R. The voltage-gated anion channels encoded by clh-3 regulate egg laying in C. elegans by modulating motor neuron excitability. J. Neurosci. Off. J. Soc. Neurosci. 34, 764-775 (2014).
  46. Hendricks, M., Ha, H., Maffey, N., Zhang, Y. Compartmentalized calcium dynamics in a C. elegans interneuron encode head movement. Nature. 487, 99-103 (2012).
  47. Nagy, S., Huang, Y. -. C., Alkema, M. J., Biron, D. Caenorhabditis elegans exhibit a coupling between the defecation motor program and directed locomotion. Sci. Rep. 5, 17174 (2015).
  48. Leifer, A. M., Fang-Yen, C., Gershow, M., Alkema, M. J., Samuel, A. D. T. Optogenetic manipulation of neural activity in freely moving Caenorhabditis elegans. Nat. Methods. 8, 147-152 (2011).
  49. Stirman, J. N., et al. Real-time multimodal optical control of neurons and muscles in freely behaving Caenorhabditis elegans. Nat. Methods. 8, 153-158 (2011).
  50. Kato, S., et al. Global brain dynamics embed the motor command sequence of Caenorhabditis elegans. Cell. 163, 656-669 (2015).
  51. Nguyen, J. P., et al. Whole-brain calcium imaging with cellular resolution in freely behaving Caenorhabditis elegans. Proc. Natl. Acad. Sci. U. S. A. 113, 1074-1081 (2016).
  52. Toyoshima, Y., et al. Accurate Automatic Detection of Densely Distributed Cell Nuclei in 3D Space. PLOS Comput. Biol. 12, 1004970 (2016).

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記事を引用
Ravi, B., Nassar, L. M., Kopchock III, R. J., Dhakal, P., Scheetz, M., Collins, K. M. Ratiometric Calcium Imaging of Individual Neurons in Behaving Caenorhabditis Elegans. J. Vis. Exp. (132), e56911, doi:10.3791/56911 (2018).

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