This protocol describes the surgical exposure of the dorsal root ganglion (DRG) followed by GCaMP3 (genetically-encoded Ca2+ indicator; Green Fluorescent Protein-Calmodulin-M13 Protein 3) Ca2+ imaging of the neuronal ensembles using Pirt-GCaMP3 mice while applying a variety of stimuli to the ipsilateral hind paw.
Ca2+ imaging can be used as a proxy for cellular activity, including action potentials and various signaling mechanisms involving Ca2+ entry into the cytoplasm or the release of intracellular Ca2+ stores. Pirt-GCaMP3-based Ca2+ imaging of primary sensory neurons of the dorsal root ganglion (DRG) in mice offers the advantage of simultaneous measurement of a large number of cells. Up to 1,800 neurons can be monitored, allowing neuronal networks and somatosensory processes to be studied as an ensemble in their normal physiological context at a populational level in vivo. The large number of neurons monitored allows the detection of activity patterns that would be challenging to detect using other methods. Stimuli can be applied to the mouse hindpaw, allowing the direct effects of stimuli on the DRG neuron ensemble to be studied. The number of neurons producing Ca2+ transients as well as the amplitude of Ca2+ transients indicates sensitivity to specific sensory modalities. The diameter of neurons provides evidence of activated fiber types (non-noxious mechano vs. noxious pain fibers, Aβ, Aδ, and C fibers). Neurons expressing specific receptors can be genetically labeled with td-Tomato and specific Cre recombinases together with Pirt-GCaMP. Therefore, Pirt-GCaMP3 Ca2+ imaging of DRG provides a powerful tool and model for the analysis of specific sensory modalities and neuron subtypes acting as an ensemble at the populational level to study pain, itch, touch, and other somatosensory signals.
Primary sensory neurons directly innervate the skin and carry somatosensory information back to the central nervous system1,2. Dorsal root ganglia (DRGs) are cell body clusters of 10,000-15,000 primary sensory neurons3,4. DRG neurons present diverse size, myelination levels, and gene and receptor expression patterns. Smaller diameter neurons include pain-sensing neurons and larger diameter neurons typically respond to non-painful mechanical stimuli5,6. Disorders in the primary sensory neurons such as injury, chronic inflammation, and peripheral neuropathies can sensitize these neurons to various stimuli and contribute to chronic pain, allodynia, and pain hypersensitivity7,8. Therefore, the study of DRG neurons is important in understanding both somatosensation generally and many pain and itch disorders.
Neurons firing in vivo are essential to somatosensation, but until recently, tools to study intact ganglia in vivo have been limited to relatively small numbers of cells9. Here, we describe a powerful method for studying the action potentials or activities of neurons on a population level in vivo as an ensemble. The method employs imaging based on cytoplasmic Ca2+ dynamics. The Ca2+ sensitive fluorescent indicators are good proxies for measuring cellular activity due to the normally low concentration of cytoplasmic Ca2+. These indicators have allowed simultaneous monitoring of hundreds to several thousands of primary sensory neurons in mice9,10,11,12,13,14,15,16 and rats17. The method of in vivo Ca2+ imaging described in this study can be used to directly observe populational level responses to mechanical, cold, thermal, and chemical stimuli.
The phosphoinositide-binding membrane protein, Pirt is expressed at high levels in almost all (>95%) primary sensory neurons18,19 and can be used to drive the expression of the Ca2+ sensor, GCaMP3, to monitor neuron activity in vivo20. In this protocol, techniques are described for performing in vivo DRG surgery, Ca2+ imaging, and analysis in the right side lumbar 5 (L5) DRG of Pirt-GCaMP3 mice14 using confocal laser scanning microscopy (LSM).
All procedures described here were performed in accordance with a protocol approved by the Institutional Animal Care and Use Committee of the University of Texas Health Science Center at San Antonio.
NOTE: Once started, animal surgery (step 1) and imaging (step 2) must be completed in a continuous manner. Data analysis (step 3) may be performed later.
1. Surgery and securing the animal for right side L5 DRG imaging
NOTE: Both male and female Pirt-GCaMP3 C57BL/6J mice 8 weeks of age or older were used in this study. While either sex can be imaged equally well, mice should be at least 8 weeks old due to weak or intermittent Pirt expression in younger mice. The Pirt-GCaMP3 C57BL/6J mice were generated at Johns Hopkins University14. Either side DRG may be imaged, and other lumbar DRGs (e.g., lumbar 4) may be imaged. The times given are estimates for an experienced surgeon. Occasional technical issues such as increased bleeding may increase the time required.
Figure 1: Example of DRG exposure surgery. (A) A small area was shaved and the skin was cut and folded back. The incision is ~10 mm on the rostral-caudal axis. (B) An incision was made on the right side of the spinal column and muscle and connective tissue were cut away, exposing the L5 right side transverse process. Blood was absorbed with gelfoam. (C) The transverse process was cleaned and the bone over the DRG was removed. Please click here to view a larger version of this figure.
Figure 2: Mounting the mouse on a custom stage for DRG imaging. (A) The custom stage is shown. It consists of a base plate and a plate for the animal. The animal mounting plate is on a locking ball and socket swivel joint. A nose cone with lines for delivering oxygen / isoflurane mixture and a waste gas line along with an aluminum foil wrapped heating pad are taped to the animal mounting plate. Two arms, each made from three locking ball and socket swivel joints, are bolted to the base plate. Each arm has a clamp made from forceps with a screw for tightening and loosening. (B) The animal is mounted on the animal mounting plate. Its nose is placed in the nose cone. Clamps are placed over the skin holding the spinal column and pelvic bone. The right (ipsilateral) hindpaw is taped to stick out for easy access for applying stimuli. (C) A closeup image of the clamped spinal column and pelvic bone. Please click here to view a larger version of this figure.
Figure 3: Animal on custom stage is placed below the microscope objective. (A) A wide angle view of the stage, animal, and microscope. Wires to the DC temperature controller and lines to oxygen / isoflurane intake and waste gas line are visible on the left. (B) A closeup view of the animal below the microscope objective. The DRG is ~8 mm below the objective. The rectal thermometer is inserted and the nose is inside the nose cone. Please click here to view a larger version of this figure.
2. DRG imaging
3. Data analysis
Figure 4: Representative images of L5 dorsal root ganglia of Pirt-GCaMP3 mice. (A,D) Single frame high resolution scans of L5 dorsal root ganglia of Pirt-GCaMP3 mice are shown. (B,E). Average intensity projections of 15 frames of Pirt-GCaMP3 L5 DRG ganglia from panel A and panel D, respectively, in the absence of stimuli. Some neurons that produced spontaneous Ca2+ transients are called out with yellow arrows. (C) Average intensity projection of two frames before stimulus and all five frames of stimulus of Pirt-GCaMP3 ganglion from panel A during 100 g hindpaw press. Some neurons that produced Ca2+ transients during the stimulus are called out with yellow arrows. (F–I) Average intensity projections of frames 4 and 5 (before stimulus) (panels A and D) and frames 6-9 (during 100 g press stimulus) of ganglion from panel D with the frames 4-6, frame 4 + 5 + 7, frames 4 + 5 + 8, and frames 4 + 5 + 9 of a 100 g hindpaw press, respectively. (J) Fluoresence intensity traces of three spontaneously active neurons from panel B (black) corresponding to the panel A ganglion and panel E (red) corresponding to the panel D ganglion. Each neuron's trace is normalized to its median intensity (shown by the line at Y = 0). (K) ΔF / F0 traces of three neurons activating in response to 100 g press from panel C (black) corresponding to the panel A ganglion and panels F-I (red) corresponding to the panel D ganglion. Note the X and Y axes are different than in panel J. Please click here to view a larger version of this figure.
Imaging of a large number of neurons using confocal scanning of Pirt-GCaMP L5 DRG
Surgical L5 DRG exposure followed by confocal microscopy allowed up to 1,800 neurons to be imaged at once using Pirt-GCaMP3 mice (Figure 4). This creates a powerful advantage of being able to simultaneously observe thousands of primary sensory neurons in an ensemble at a populational level in their normal physiological context, both in control and in abnormal conditions. Spontaneous Ca2+ transients in the absence of stimuli (Figure 4B,E and Movie 2) and Ca2+ transients in response to stimuli (Figure 4C,F-I, Movie 3, and Movie 4) can be monitored. The diameters of activating neurons are highly correlated with different nerve fiber groups.
Figure 5: Increasing intensity of stimuli enhances Ca2+ responses in ganglia of Pirt-GCaMP3 mice. (A) Graphs of the numbers of neurons in L5 DRG ganglia showing Ca2+ transients in response to stimuli from two different press intensities are shown: 100 g, n = 8 ganglia; 300 g, n = 5. (B) Graphs of ΔF / F0 areas under the curve of samples of Ca2+ transients from two different press intensities are shown: 100 g, n = 88 neurons; 300 g, n = 104. (C) Graphs of traces of ΔF / F0 of 100 g and 300 g press stimuli. Red trace is the mean ΔF / F0; 100 g, n = 60 neurons; 300 g, n = 57 neurons. (D) Graphs of the numbers of neurons in L5 DRG ganglia showing Ca2+ transients in response to three different non-noxious and one noxious temperature are shown: 21 °C, n = 4 ganglia; 10 °C, n = 6; 45 °C, n = 7; 57 °C, n = 3. (E) Graphs of ΔF / F0 areas under the curve of samples of Ca2+ transients from three different non-noxious and one noxious temperature stimulus intensities are shown: 21 °C, n = 40 neurons; 10 °C, n = 60; 45 °C, n = 61; 57 °C, n = 118. (F) Graphs of traces of ΔF / F0 of 10 °C and 57 °C stimuli. Red trace is the mean ΔF / F0; 10 °C, n = 60 neurons; 57 °C, n = 118. (G) Graph of percentages of neurons of different diameters (<20 µm, 20-25 µm, >25 µm) producing Ca2+ transients spontaneously and with thermal and mechanical stimuli. Spontaneous activity (Spon), n = 5 ganglia; 45 °C, n = 3; 300 g, n = 3. * p < 0.05, ** p < 0.01, *** p < 0.001. Bar graphs show the means and the SEM. Please click here to view a larger version of this figure.
Number of cells producing Ca2+ transients and Ca2+ transient area under the curve (AUC) in the presence of stimuli
Strong stimuli or noxious heat increased Ca2+ responses. Compared to pressing with 100 g, pressing with 300 g increased the number of neurons producing Ca2+ transients (Figure 5A, Student's t-test: t = 2.398, df = 11, p = 0.0354) and the ΔF / F0 area under the curve of Ca2+ transients (Figure 5B, Welch's t-test: t = 3.243, df = 187.4, p = 0.0014). Similarly, warm heat in a non-noxious temperature range (21 °C and 45 °C) increased the number of neurons producing Ca2+ transients (Figure 5C, one-way ANOVA F2,14 = 4.853, p = 0.0251, followed by Tukey's q = 4.380, df = 14, p = 0.0202) and the ΔF / F0 area under the curve of Ca2+ transients (Figure 5D, Brown-Forsythe ANOVA F2,151.6 = 60.76, p = 0.0029 followed by Welch's t-test: t = 3.333, df = 96.72, p = 0.0036). Compared to a noxious heat stimulus (57 °C), non-noxious temperatures (21 °C, 10 °C, and 45 °C) activated a smaller number of neurons producing Ca2+ transients (Figure 5E, one-way ANOVA F2,16 = 2.513, p < 0.001, Dunnett's test, 21°C: q = 9.594, df = 16, p < 0.001; 10 °C: q = 9.583, df = 16, p < 0.001; 45 °C: q = 9.160, df = 16, p < 0.001) and ΔF / F0 area under the curve of Ca2+ transients at 21 °C and 10 °C (Figure 5D, Brown-Forsythe ANOVA F3,268.4 = 12.98, p < 0.001, Dunnett's T3 test, 21 °C: t = 5.415, df = 128, p < 0.001; 10 °C: t = 4.398, df = 174.5, p < 0.001; 45 °C: t = 2.079, df = 161.9, p = 0.1127). In this experiment, smaller and medium diameter neurons produced Ca2+ transients spontaneously and under all stimuli, but larger diameter neurons only produced Ca2+ transients in response to the 300 g press stimulus (Figure 5G).
Labeling of neurons expressing specific receptors with td-Tomato in Pirt-GCaMP3 mice
The cre-inducible reporter td-Tomato can be observed during Pirt-GCaMP3 imaging. Pirt-GCaMP3, td-Tomato mice that expressed Cre under the control of the TrpV1 promoter showed wide scale but not universal labeling of primary sensory neurons (Figure 6A,B). Spontaneous Ca2+ transients were observed in both td-Tomato-labeled neurons and neurons that are not labeled (Figure 6C). Noxious heat was not tested on this experiment, but will be tested in the future experiments.
Figure 6: Labeling of TrpV1-positive neurons with td-Tomato in Pirt-GCaMP3 mice. (A) A maximum intensity projection of spontaneous activity of primary sensory neurons of a TrpV1-Cre, td-Tomato, Pirt-GCaMP3 mouse imaged on the 495 nm excitation/519 nm emission (FITC, green) channel only. Some neurons producing Ca2+ transients are called out with yellow arrows (not labeled with td-Tomato) or red arrows (labeled with td-Tomato). (B) An average intensity projection of the same primary sensory neurons as panel A on the 592 nm excitation/614 nm emission red channel only. (C) A maximum intensity projection of simultaneous red and green channels of the same primary sensory neurons as in panel A is shown. Some neurons expressing GCaMP3 but not td-Tomato are called out with yellow arrows. White arrows indicate GCaMP positive with no Ca2+ transients and not td-Tomato postive. Please click here to view a larger version of this figure.
Movie 1: Spontaneous activity of a Pirt-GCaMP3 ganglion that has not been properly leveled or optimized for optical slice thickness causing waviness. 70 frames per second AVI. Optical slice thickness = 16 µm. Please click here to download this Movie.
Movie 2: Spontaneous activity of the same ganglion from movie 1 that has been properly leveled and optimized for optical slice thickness with less waviness. 70 frames per second AVI. Optical slice thickness = 13 µm. Please click here to download this Movie.
Movie 3: 100 g hindpaw press of Pirt-GCaMP3 ganglion. 3 frames per second AVI. Stimulus was applied during frames 6-10. Please click here to download this Movie.
Movie 4: 45 °C thermal stimulus to hindpaw of Pirt-GCaMP3 ganglion. 3 frames per second AVI. Stimulus was applied during frames 6-10. Please click here to download this Movie.
Supplementary File 1: Example analysis spreadsheet Please click here to download this File.
Persistent pain is present in a wide range of disorders, debilitating and/or reducing the quality of life for about 8% of people29. Primary sensory neurons detect noxious stimuli on the skin, and their plasticity contributes to persistent pain8. While neurons can be studied in cell culture and explants, doing so removes them from their normal physiological context. Surgical exposure of the DRG, followed by Pirt-GCaMP3 Ca2+ imaging, permits the study of primary sensory neurons in their normal physiological context using stimuli applied to the hindpaw. A major advantage of this method of Ca2+ imaging is that a large number of neurons can be monitored simultaneously. This method allows analysis at a populational level of modality, neuron diameter, and rare phenomena such as coupled activation10,11,12,13,14,15,16,17,30, providing insights into normal and pathological somatosensation. In addition to neuron diameter as an identifier, specific types of neurons can be genetically labeled with a red fluorophore such as td-Tomato for identification during imaging. This technique allows for observations of specific sensory modalities or of neurons expressing specific receptors14,31. Other applications include imaging other sensory ganglia such as the trigeminal ganglion24,32 or geniculate ganglion23,26 and imaging innervation of the spinal dorsal horn by primary sensory neurons in explants19,33.
Critical steps in the protocol include preventing excessive bleeding or bleeding onto the DRG, control of anesthesia during imaging, leveling of the DRG surface, selecting optimal optical slice thickness, and preventing movement of the DRG during application of stimuli. Excessive bleeding could cause death of the animal or artifacts due to physiological effects of blood loss. Blood loss may cause increases in brightness (cytoplasmic calcium) across vast areas of the DRG. Blood loss could also cause numbness, reducing the number of neurons activating in response to stimuli. Bleeding onto the DRG directly blocks imaging, limiting the number of neurons that can be successfully imaged. Since anesthesia affects neuronal activities and responses, a minimal level of isoflurane anesthesia should be used. A level DRG and optimal optical slice thickness are the most critical parts of the procedure. Incorrectly performing these steps can cause out of focus neurons and waviness during imaging (see Movie1 and Movie 2) that will confound the analysis or make the analysis impossible. Even small movements can make tracking individual neurons across frames impossible and/or create artifacts where a neuron appears to become darker or brighter, causing significant errors.
The system described here also has some significant limitations. Anesthesia interferes with neuron and glial Ca2+ responses25. Because this method is terminal, the same animal cannot be monitored over multiple experiments. Ca2+ transients are an indirect proxy for neuron firing and activity. This method uses Ca2+ transients as a proxy for action potentials. However, other signals such as Gq protein or ryanodine receptor signaling can change cytoplasmic Ca2+ concentrations34,35,36. Other mechanisms have not been reported to cause Ca2+ transients in DRG neurons. However, application of chemical stimuli to the paw is known to increase Ca2+ in spinal dorsal horn astrocytes36.
In conclusion, intact DRG Pirt-GCaMP3 Ca2+ imaging is a powerful tool for studying somatosensation under normal and pathological conditions. The results shown here are representative for normal control mice. Control mice can be compared to pain and disease models or genetic mutants10,15,17,30,31,37. Furthermore, the method presented here can be adapted to other genetically encoded Ca2+ indicators10,11,16 and used to image other sensors such as voltage sensing38,39,40 and cyclic adenosine monophosphate sensing41. While confocal microscopy was used in this study, two-photon microscopy can be used as well11.
The authors have nothing to disclose.
This work was supported by National Institutes of Health Grants R01DE026677 and R01DE031477 (to Y.S.K.), UTHSCSA startup fund (Y.S.K.), a Rising STAR Award from University of Texas system (Y.S.K.), and Craniofacial Oral-biology Student Training in Academic Research (COSTAR) National Institute of Health Grant 5T32DE014318 (J.S.).
Anased Injection (Xylazine) | Covetrus, Akorn | 33197 | |
C Epiplan-Apochromat 10x/0.4 DIC | Cal Zeiss | 422642-9900-000 | |
Cotton Tipped Applicators | McKesson | 24-106-1S | |
Curved Hemostat | Fine Science Tools | 13007-12 | |
DC Temperature Controller | FHC | 40-90-8D | |
DC Temperature Controller Heating Pad | FHC | 40-90-2-05 | |
Dumont Ceramic Coated Forceps | Fine Science Tools | 11252-50 | |
FHC DC Temperature Controller | FHC | 40-90-8D | |
Fluriso (Isoflurane) | MWI Animal Health, Piramal Group | 501017 | |
Friedman-Pearson Rongeurs | Fine Science Tools | 16221-14 | |
GelFoam | Pfizer | 09-0353-01 | |
Ketaset (Ketamine) | Zoetis | KET-00002R2 | |
Luminescent Green Stage Tape | JSITON/ Amazon | B803YW8ZWL | |
Matrx VIP 3000 Isoflurane Vaporizer | Midmark | 91305430 | |
Micro dissecting scissors | Roboz | RS-5882 | |
Micro dissecting spring scissors | Fine Science Tools | 15023-10 | |
Micro dissecting spring scissors | Roboz | RS-5677 | |
Mini Rectal Thermistor Probe | FHC | 40-90-5D-02 | |
Operating scissors | Roboz | RS-6812 | |
Pirt-GCaMP3 C57BL/6J mice | Johns Hopkins Üniversitesi | N/A | Either sex can be imaged equally well. Mice should be at least 8 weeks old due to weak or intermittent Pirt promoter expression in younger mice. |
SMALGO small animal algometer | Bioseb In vivo Research Instruments | BIO-SMALGO | |
Stereotaxic frame | Kopf Model 923-B | 923-B | |
td-Tomato C57BL/6J mice | Jackson Laboratory | 7909 | |
Top Plate, 6 in x 10 in | Newport | 290-TP | |
TrpV1-Cre C57BL/6J mice | Jackson Laboratory | 17769 | |
Zeiss LSM 800 confocal microscope | Cal Zeiss | LSM800 | |
Zeiss Zen 2.6 Blue Edition Software | Cal Zeiss | Zen (Blue Edition) 2.6 |