Perforated Patch-Clamp Recording of Olfactory Sensory Neurons in Mice

Published: October 31, 2024

Abstract

Source: Jarriault, D., et al. Perforated Patch-clamp Recording of Mouse Olfactory Sensory Neurons in Intact Neuroepithelium: Functional Analysis of Neurons Expressing an Identified Odorant Receptor. J. Vis. Exp. (2015).

This video demonstrates electrophysiological recording of olfactory sensory neurons (OSNs) in mice using a perforated patch-clamp technique. The olfactory epithelium, containing OSNs with fluorophore-tagged odor receptors, is isolated from a mouse and secured in a recording chamber. A recording pipette is clamped to the dendritic knob of an OSN, and nystatin within the pipette perforates the membrane to form electrical connectivity with the cell. Finally, another pipette is used to deliver an odor stimulant, and the electrophysiological activity of the patched cell is recorded.

Protocol

All procedures involving animal models have been reviewed by the local institutional animal care committee and the JoVE veterinary review board.

1. Animals

  1. Use genetically engineered OR-IRES-tauGFP (OR = Olfactory receptor, IRES = Internal ribosome entry site, tauGFP = tau-green fluorescent protein) mice available at the Jackson Laboratory. These mice were developed in Dr. Peter Mombaerts' laboratory in order to analyze axon targeting and development of the olfactory system. For example, the MOR23-IRES-tauGFP line, stock number 006643, bears the official strain name B6;129P2-Olfr16tm2Mom/MomJ; similarly, the SR1-IRES-tauGFP line, stock number 6717 bears the official name B6;129P2-Olfr124tm1Mom/MomJ.
  2. Regarding the age of the animals: for a better outcome of the protocol, use animals between 2 and 4 weeks of age. In this age group, the dissection is easier (softer bones, firmer olfactory epithelium) and the dendritic knobs are bigger compared to older animals.

2. Preparation of Electrodes and Solutions

  1. For the stimulating pipettes: purchase pre-pulled stimulating pipettes. Otherwise, manually prepare them.
    1. Using a flame, bend six 1 mm glass pipettes at about 1 cm from the tip. Insert these six pipettes plus a straight 7th in 1.5 cm heat-shrink tubing strengthened by an eyelet.
    2. Heat shrinks the tubing to maintain the barrels attached together. Attach an additional heat-shrink tubing to the other extremity of the barrels. Pull this stimulating pipette with a multi-barrel puller.
    3. Add some white liquid glue around the eyelet to strengthen the bent tips. Let dry overnight (O/N).
  2. Prepare 1 or 2 L of normal Ringer's extracellular solution (in mM: NaCl 124, KCl 3, MgSO4 1.3, CaCl2 2, NaHCO3 26, NaH2PO4 1.25, glucose 15; pH 7.6 and 305 mOsm). Keep at 4 °C until use.
  3. Prepare intracellular stock solution (in mM): KCl 70, KOH 53, methanesulfonic acid 30, ethylene glycol tetraacetic acid (EGTA) 5, 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (HEPES) 10, sucrose 70; pH 7.2 (KOH) and 310 mOsm. Keep at 4 °C until use. Good for several weeks.
  4. Prepare intracellular recording solution with nystatin extemporaneously (at the last minute) before experiment.
    1. Weigh 3 mg of nystatin, add 50 µl of dimethyl sulfoxide (DMSO); vortex 20 sec then sonicate 2-3 min until entirely diluted.
    2. Add 20 µl of DMSO-nystatin solution in 5 ml of intracellular stock solution. Vortex 20 sec, then sonicate 3 min. Keep this solution at 4 °C and protect from direct light, nystatin is light sensitive. This solution can be used for a few hours. Replace every day.
    3. Once the olfactory epithelium preparation is under the microscope, take some of this solution in a 1 ml syringe with a flame-elongated yellow tip to fill the electrodes; protect from direct light. Once at room temperature (RT), the nystatin solution is not stable; replace the solution in the 1 ml syringe every hour or keep it in ice.
  5. Pull recording electrodes with a puller to obtain long neck and small tip (~2 µm) with a resistance of 15-20 MΩ with the internal nystatin solution.
  6. Prepare odorant solution at 0.5 M in DMSO under fume hood; aliquot and keep at -20 °C until use. Dilute odorant in Ringer's solution until the desired concentration. Fill the stimulating pipette.

3. Preparation of Olfactory Epithelium

Note: OR-IRES-tauGFP mice express the tauGFP under the control of the OR promoter. In these mice, all neurons expressing the OR of interest are labeled with GFP. This protocol is adapted for ORs expressed in all zones. However, dissections and recordings are easier for ORs expressed in the dorsal zone.

  1. Anesthetize the animal by injecting a mix of ketamine and xylazine (150 mg/kg and 10 mg/kg body weight, respectively). Decapitation can be performed with sharp scissors for young mice or with a properly maintained rodent guillotine for older mice.
    1. Using ring dissecting scissors make a longitudinal medial incision through the dorsal skin. Remove the skin by pulling it apart. Using the scissors, cut the lower jaws at the jaw joint. Remove the upper front teeth by a coronal cut parallel to the teeth.
    2. Make a coronal cut of the head behind the eyes and keep only the anterior part of the head. Dip it in an ice-cold Ringer solution for the dissection under the scope.
  2. Dissect under the scope: in the ventral side, make a longitudinal cut along the upper jaw/the teeth. Cut the dorsal bones longitudinally, following the dorsolateral side of the nasal cavity. Remove most bones and palate; transfer the septum and the epithelium attached to it in oxygenated Ringer at RT.
  3. For the final dissection: Right before starting the recording session, peel away the epithelium from the underlying septum with forceps. Detach the epithelium with forceps and with two 4-5 mm scissor cuts (use micro-vannas scissors) at the anterior part of the septum where the adhesion is stronger.
    1. Carefully remove the vomeronasal organ by cutting it out along its dorsal connection to the septal epithelium. Transfer the epithelium to a recording chamber with the mucus layer facing up; keep it flat in the chamber with a harp.
  4. Install chamber under an upright microscope equipped with fluorescence optics and a sensitive camera. Visualize the preparation on the computer screen at high magnification through a 40X water-immersion objective (numerical aperture 0.8) and an extra 2X or 4X magnification achieved by a magnifying lens. Perfuse continuously with oxygenated Ringer at RT (1-2 ml/min).

4. Recording Session

  1. Search for fluorescent cells: excite the preparation at 480 nm for EGFP, which emits light in the 530-550 nm range; target one dendritic knob which is reliably visible in fluorescence and under bright field.
  2. Fill the electrode with intracellular solution with nystatin; remove bubbles by gently tapping on the electrode.
  3. Insert electrode on electrode holder, apply positive pressure in the pipette; Resistance should be 15-20 MΩ.
  4. Bring electrode close to the cell; once resistance reaches ~40 MΩ, release positive pressure and apply slight negative pressure to reach a gigaseal.
  5. Once seal is reached, set the membrane potential at about -75 mV;
  6. Once the cell is opened, proceed with stimulation protocols, pharmacological treatments. To measure the response to a single odorant stimulation, record 200-500 msec of spontaneous activity, stimulate for 500 msec and measure the response of the cell for up to 10 sec. For pharmacological treatments, perfuse the pharmacological agents at the desired concentration.

Açıklamalar

The authors have nothing to disclose.

Materials

Heavy equipment
vibration table with Faraday cage TMC 63-500 SERIES required : isolates the recording system from vibrations induced by the environment (movements of experimenter, vibrations of equipment such as fans for cooling computers, etc); can also be purchased with a Faraday cage, or equipped by a custom made Faraday cage; this cage is recommended to avoid electric noise from the environment
optics
microscope Olympus BX51WI upright microcope equipped with epifluorescence; fixed or moving stage depending on the user's preference
objectives Olympus LUMPLFL40XW at least 2 objectives required: a 4X or 10X for coarse approach to the cell; and a 40X immersion long distance example Olympus LUMPLFL40XW / IR /0,8 / WD:3.3 MM
magnifier Olympus U-TVCAC ABSOLUTELY REQUIRED: placed in the light path between the objective and the camera; allows to magnify the image on the screen in order to reach precisely the knob with the recording electrode
camera Olympus DP72 a good camera is required to see the neurons in fluorescence as well as in bright field; the controlling software is simple and allows to take pictures and do live camera image to monitor the approach of the electrode to the cell. An ultrasensitive camera is not necessary
filters Olympus/Chroma depending on the fluorescent protein used in the mice; example for GFP: excitation : BP460-490: emission: HQ530/50m
Recording electrodes/system
amplifier HEKA EPC10 USB monitors the currents flowing through the recording electrode and also controls the puffing by sending a TTL signal to the spritzer; the EPC10 setup is
controled by computer
software HEKA Patchmaster controls the amplifier during the experiment
micromanipulator Sutter MP225 precision micromanipulator, allows precise movements down to 1/10th of a micrometer; this model is very stable; avoid hydraulic manipulators that may drift
electrode puller Sutter P97 with a FT345-B wide trough filament; to prepare recording pipets of about 2µm diameter with a long tip to reach the cells; the resistance should be 15 to 20Mohm with perforated patch clamp solution
glass Sutter BF120-69-10 in our recording conditions, this glass is ideal for recording pipets
recording chamber Warner Instruments RC-26G a chamber is needed to set the preparation under the microscope. To maintain the preparation in the center of the chamber, a net/ anchor should be used.
Stimulation
glass WPI TW100F-4 attached in groups of 7, these pipettes are used to prepare prepulled stimulating pipettes
multibarrel puller MDI PMP-107-Z by association of pull and twist, this puller allows us to prepare puffing electrodes with 7 barrels
precision pressure injector Toohey Company P/N T25-1-900 Single Channel this precision pressure injector controls the pressure ejected in the multibarrel puller; it is controlled manually or by the amplifier by a 5V TTLs
micromanipulator Narishige YOU-1 a coarse manipulator is enough to bring the puffing electrode close to the recording site
tubings
solutions/perfusion/chemicals
vacuum pump gardner denver
perfusion system N/A N/A
nystatin Sigma-Aldrich N3503 mandatory to perpare internal solution for perforated patch clamp
Dimethyl sulfoxide Sigma-Aldrich D5879 used to disolve nystatin for internal solution for perforated patch
Sodium chloride Sigma-Aldrich S9625 extracellular solution
Potassium chloride Sigma-Aldrich P4504 intracellular/extracellular solution
Calcium chloride dihydrate Sigma-Aldrich C7902 extracellular solution
Sodium phosphate monobasic monohydrate (NaH2PO4) Sigma-Aldrich S9638 extracellular solution
Magnesium sulfate heptahydrate (MgSO4 7H2O) Sigma-Aldrich 63140 extracellular solution
Glucose Sigma-Aldrich G8270 extracellular solution
Sodium bicarbonate Sigma-Aldrich S6297 extracellular solution
EGTA (Ethylene glycol-bis(2- aminoethylether)-N,N,N′,N′- tetraacetic acid) Sigma-Aldrich E3889  internal solution
Potassium hydroxyde Sigma-Aldrich P1767  internal solution
Methyl Sulfoxide Sigma-Aldrich W387509 intracellular solution
Hepes-Na Sigma-Aldrich H7006 intracellular solution
Sucrose Sigma-Aldrich S0389 intracellular solution

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Bu Makaleden Alıntı Yapın
Perforated Patch-Clamp Recording of Olfactory Sensory Neurons in Mice. J. Vis. Exp. (Pending Publication), e22737, doi: (2024).

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