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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

The pedunculopontine nucleus (PPN) is located in the brainstem and its neurons are maximally activated during waking and rapid eye movement (REM) sleep brain states. This work describes the experimental approach to record in vitro gamma band subthreshold membrane oscillation in PPN neurons.

Abstract

Synaptic efferents from the PPN are known to modulate the neuronal activity of several intralaminar thalamic regions (e.g., the centrolateral/parafascicular; Cl/Pf nucleus). The activation of either the PPN or Cl/Pf nuclei in vivo has been described to induce the arousal of the animal and an increment in gamma band activity in the cortical electroencephalogram (EEG). The cellular mechanisms for the generation of gamma band oscillations in Reticular Activating System (RAS) neurons are the same as those found to generate gamma band oscillations in other brains nuclei. During current-clamp recordings of PPN neurons (from parasagittal slices from 9 - 25 day-old rats), the use of depolarizing square steps rapidly activated voltage-dependent potassium channels that prevented PPN neurons from being depolarized beyond -25 mV.

Injecting 1 - 2 sec long depolarizing current ramps gradually depolarized PPN membrane potential resting values towards 0 mV. However, injecting depolarizing square pulses generated gamma-band oscillations of membrane potential that showed to be smaller in amplitude compared to the oscillations generated by ramps. All experiments were performed in the presence of voltage-gated sodium channels and fast synaptic receptors blockers. It has been shown that the activation of high-threshold voltage-dependent calcium channels underlie gamma-band oscillatory activity in PPN neurons. Specific methodological and pharmacological interventions are described here, providing the necessary tools to induce and sustain PPN subthreshold gamma band oscillation in vitro.

Introduction

PPN nucleus is anatomically included in the caudal mesencephalic tegmentum. The PPN is a key component of RAS1. The PPN participates in the maintenance of behavioral activated states (i.e., waking, REM sleep)2. Electrical stimulation of the PPN in vivo induced fast oscillation (20 - 40 Hz) in the cortical EEG3, while bilateral PPN lesions in the rat reduced or eliminated REM sleep4. While a majority of PPN neurons fire action potentials at beta/gamma-band frequency (20 - 80 Hz), some neurons presented low rates of spontaneous firing (< 10 Hz) 5. Furthermore, the PPN seems to be involved in other aspects of behavior such as motivation and attention6. Direct high frequency (40 - 60 Hz)7 electrical stimulation of PPN nucleus in decerebrate animals can promote locomotion. In recent years, deep brain stimulation (DBS) of PPN has been used to treat patients suffering from disorders involving gait deficits such as Parkinson's disease (PD)8.

Previous reports demonstrated that almost all PPN neurons can fire action potentials at gamma band frequency when depolarized using square current pulses9. Because of the drastic activation of voltage-gated potassium channels during square pulses depolarizations up to or under -25 mV. As a consequence, no robust gamma oscillations were observed after blocking action potentials generation using tetrodotoxin10. In an effort to bypass such a problem, 1 - 2 sec long depolarizing current ramps were used. Ramps gradually depolarized the membrane potential from resting values up to 0 mV, while partially inactivating voltage-gated potassium channels. Clear gamma band membrane oscillations were evident within the voltage dependence window of high threshold calcium channels (i.e., between -25 mV and -0 mV) 10. In conclusion, gamma band activity was observed in PPN neurons9, and both P/Q- and N-type voltage-gated calcium channels need to be activated in order to generate gamma band oscillations in the PPN10.

A series of studies determined the location of high threshold calcium channels in PPN neurons. Injecting the combination of dyes, ratiometric fluorescence imaging showed calcium transients through voltage-gated calcium channels that are activated in different dendrites when depolarized using current ramps11.

Intrinsic properties of PPN neurons have been suggested to allow simultaneous activation of these cells during waking and REM sleep, thus inducing high-frequency oscillatory neuronal activity between the RAS and thalamocortical loops. Such long-reaching interaction is considered to support a brain state capable of reliably assessing the world around us on a continuous basis12. Here, we describe the experimental conditions necessary to generate and maintain gamma band oscillation in PPN cells in vitro. This protocol has not been described previously, and would help a number of groups to study intrinsic membrane properties mediating gamma band activity at other brain areas. Moreover, current steps might lead to the erroneous conclusion that gamma band activity cannot be generated in these cells.

Protocol

All experimental protocols were approved by the Institutional Animal Care and Use Committee of the University of Arkansas for Medical Sciences (Protocol number #3593) and were in agreement with the National Institutes of Health guidelines for the care and use of laboratory animals.

1. Preparation of Standard-artificial Cerebrospinal Fluid (aCSF)

  1. Preparation of Stock Solution A
    1. Add 700 ml of distilled water to a clean 1 L beaker before adding chemicals.
    2. While continuously stirring a volume of 500 ml, add 136.75 g of NaCl, 6.99 g of KCl, 2.89 g of MgSO4, and 2.83 g of NaH2PO4.
    3. Add more distilled water to reach a final volume of 1 L. After dilution, the final concentration of each compound is 117 mM NaCl, 4.69 mM KCl, 1.2 mM MgSO4, and 1.18 mM NaH2PO4.
    4. Keep refrigerated at 4 °C for up to 2 weeks.
  2. Preparation of Stock Solution B
    1. Add 700 ml of distilled water to a clean 1L beaker before adding chemicals.
    2. While continuously stirring a volume of 500 ml, add 41.45 g of D-glucose and 41.84 g of NaHCO3.
    3. Add more distilled water to reach a final volume of 1 L. After dilution, the final concentration of each compound is 11.5 mM D-glucose and 24.9 mM NaHCO3.
    4. Keep refrigerated at 4 °C for up to 2 weeks.
    5. Before each experiment mix 50 ml of stock A with 50 ml stock B and bring to 1 L with distilled water to obtain final concentration aCSF solution and leave at RT while continuously oxygenating it with carbogen (95% O2 - 5% CO2 mix) for at least 30 min. Prepare final concentration aCSF only at the beginning of each experiment and discard at the end of the day.

2. Preparation of Sucrose-artificial Cerebrospinal Fluid (Sucrose-aCSF)

  1. Preparation of Stock Solution C
    1. Add 700 ml of distilled water to a clean 1 L beaker before adding chemicals.
    2. While continuously stirring 500 ml of distilled water, add 240 g of sucrose, 6.55 g of NaHCO3, 0.671 g of KCl, 4.88 g of MgCl2, 0.22 g of CaCl2 and 0.21 g of ascorbic acid.
    3. Add more distilled water to reach a final volume of 1 L. After dilution, the final concentration of each compound is 701.1 mM sucrose, 78 mM NaHCO3, 9 mM KCl, 24 mM MgCl2, 1.5 mM CaCl2 and 1.2 mM ascorbic acid.
    4. Keep stock solution C at 4 °C for up to one week.
    5. Before each experiment mix 300 ml of 50 ml of stock C with 600 ml distilled water to obtain the sucrose-aCSF solution at the final concentration and leave at RT while continuously oxygenating it with carbogen (95% O2 - 5% CO2 mix) for at least 30 min.

3. Slice Preparation

  1. Place a clean beaker with 100 ml sucrose-aCSF solution in ice while oxygenating it with carbogen and fix the pH at 7.4 using a pH meter while adding few drops of 0.1 M NaOH solution (when pH < 7.4) or 0.1 M HCl solution (when pH > 7.4).
  2. Fill up a cutting chamber of a vibratome with sucrose-aCSF and oxygenate it. Turn on the glycerol-based refrigerating system coupled to the cutting chamber and wait 15 min to allow it to cool down to 0 - 4 °C.
  3. Anesthetize rat pups (aged 9 to 12 from adult timed-pregnant Sprague-Dawley rats) with Ketamine (70 mg/kg, i.p.; using < 50 µl final volume). When pup is calm, double check that tail pinch reflex is absent.
  4. Decapitate pups.
    1. Cut the head skin longitudinally from the front to back using a carbon steel scalpel blade, and pull the skin to the sides using forceps. Cut the bone covering the brain moving the scissors laterally and totally remove it to expose the brain.
    2. Then, rapidly remove the brain using a spatula (initially placed under the olfactory bulb in order to gently push out the brain from the most rostral towards the most caudal areas). Gently push the brain into ice-cooled oxygenated sucrose-artificial cerebrospinal fluid (sucrose-aCSF).
  5. Make a parasagittal cut on the right hemisphere (removing approximately one third of the hemisphere), and glue the trimmed side of the brain onto a metallic disk that will be magnetically fixed to the cutting chamber of a vibroslicer to cut sagittal 400 µm sections containing the pedunculopontine nucleus (PPN). Keep PPN slices at RT for 45 min prior to whole-cell patch-clamp recordings.

4. Recordings Gamma-band Oscillations in PPN Slices

  1. Preparation of Potassium-gluconate Intracellular Solution (High-K+ Solution)
    1. Place in ice a clean beaker with 10 ml distilled water. While continuously stirring add: K+-gluconate, 90.68 mg phosphocreatine di Tris salt, 47.66 mg HEPES, 1.5 mg EGTA, 40.58 mg Mg2+-ATP, and 4 mg Na+2-GTP.
    2. Adjust pH to 7.3 with KOH (100 mM in distilled water). Add distilled water to reach a final volume of 20 mL. If needed, adjust osmolarity with sucrose (100 mM in distilled water) to be 280 - 290 mOsm. After dilution, the final concentration of each compound is 124 mM K+-gluconate, 10 mM phosphocreatine di Tris salt, 10 mM HEPES, 0.2 mM EGTA, 4 mM Mg2+-ATP, and 0.3 mM Na+2-GTP.
    3. Aliquot intracellular solutions in 1 ml tubes and freeze at -20 °C. Use one aliquot per day and keep at 4 °C during experiments.
  2. Whole-cell Patch Clamp Recordings
    1. Place slices in an immersion chamber and perfuse them (1.5 ml/min) with oxygenated (95% O2 -  5% CO2) aCSF containing the following receptor antagonists: selective NMDA receptor antagonist 2-amino-5-phosphonovaleric acid (APV, 40 μM), competitive AMPA/Kainate glutamate receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 10μM), glycine receptor antagonist strychnine (STR, 10 μM), the specific GABAA receptor antagonist gabazine (GBZ, 10 μM), and sodium channel blocker tetrodotoxin (TTX, 3μM)
      NOTE: In the results and figures, these antagonists are collectively referred to as synaptic blockers or SBs.
    2. Fill the recording patch pipettes (Resistance 2-7 MΩ; made from regular, commercially available thick wall borosilicate glass capillaries of 1.0 mm outer diameter and 0.6 mm inner diameter) with intracellular high-K+ solution using commercially available patch-pipette fillers with a solution filter. Insert the pipette in its amplifier's holder. Apply a small positive pressure using a 1 ml syringe connected to the pipette holder using a silicon tube connected to a three-way valve. Connect the back of the pipette holder to a patch clamp amplifier.
    3. Move the recording pipette using a mechanical micromanipulator near the PPN nucleus using a 4X objective combined to near-infrared differential interference contrast optics.
      NOTE: PPN nucleus can be observed in slices dorsal to the superior cerebellar peduncle (SCP; observable as a thick bundle of axons). Recording pipettes were located in the PPN pars compacta, which is located immediately dorsal to the posterior end of the peduncle.
    4. Bring the recording pipette in contact with a PPN neuron while visualized using a 40X water immersion lens, and rapidly apply negative suction to form a seal with the cell.
    5. Use voltage-clamp seal software to monitor pipette resistance during negative suction using manufacturer's protocol.
      1. When negative suction is slowly increased and resistance values reading by the patch-clamp monitor at the tip of the pipette reach 80 - 100 MOhm, rapidly change the holding potential to -50 mV and release the negative pressure. Start continuously applying negative suction until rupturing the neuron's membrane and electrical access is achieved in the whole-cell configuration.
      2. If access resistance values measured by the voltage-clamp seal software are 10 MOhm or higher, then continue applying negative suction in smaller amounts.
    6. Compensate capacitance (i.e., slow and fast transients observed after rupturing the membrane of the cell) and series resistance in voltage-clamp mode. Switch recording mode to current clamp, and rapidly compensate bridge values (e.g., move amplifier knob or click on the automatic compensation menu using computer´s mouse).
      1. Continuously monitor resting membrane potential of PPN neuron being recorded using manufacturer's protocol. If resting membrane potential shift towards depolarizing or hyperpolarizing values, then use small amounts of direct current (up to 100 pA) to keep the optimum -50 mV final value.
        NOTE: Keep only PPN neurons with a stable resting membrane potential (RMP) of -48 mV or more hyperpolarized (i.e., RMP < -48 mV).

Results

Initially, gamma oscillations were evoked using square current pulses. Current clamp recording of PPN neurons in the presence of synaptic blockers and TTX was continuously monitored to assure that resting membrane potential was kept stable at ~-50 mV (Figure 1A). Two second long square current pulses were injected intracellularly by the patch clamp amplifier through the recording pipette, increasing their amplitude from 200 pA to 600 pA (Figure 1A). Membr...

Discussion

PPN neurons have intrinsic properties that allow them to fire action potentials at beta/gamma band frequencies during in vivo recordings from animals that are awake or during REM sleep, but not during slow wave sleep2,3,5,13-17. Other authors have showed that brainstem transections at more anterior levels than PPN reduced gamma frequencies during EEG recordings. However, when brainstem lesions posterior to where this nucleus is located, the direct stimulation of PPN allowed the manifestation of cortic...

Disclosures

The authors declare that they have no competing financial interests.

Acknowledgements

This work was supported by core facilities of the Center for Translational Neuroscience supported by NIH award P20 GM103425 and P30 GM110702 to Dr. Garcia-Rill. This work was also supported by grants from FONCYT-Agencia Nacional de Promociòn Cientìfica y Tecnològica; BID 1728 OC.AR. PICT-2012-1769 and UBACYT 2014-2017 #20120130101305BA (to Dr. Urbano).

Materials

NameCompanyCatalog NumberComments
SucroseSigma-AldrichS8501C12H22O11, molecular weight = 342.30
Sodium BicarbonateSigma-AldrichS6014NaHCO3, molecular weight = 84.01
Potassium ChlorideSigma-AldrichP3911KCl, molecular weight = 74.55
Magnesium Chloride HexahydrateSigma-AldrichM9272MgCl2 · 6H2O, molecular weight =  203.30
Calcium Chloride DihydrateSigma-AldrichC3881CaCl2 · 2H2O, molecular weight =147.02
D-(+)-GlucoseSigma-AldrichG5767C6H12O6, molecular weight = 180.16
L-Ascorbic AcidSigma-AldrichA5960C6H8O6, molecular weight =176.12
Sodium ChlorideAcros Organics327300025NaCl, molecular weight =  58.44
Potassium GluconateSigma-AldrichG4500C6H11KO7, molecular weight =  234.25
Phosphocreatine di(tris) saltSigma-AldrichP1937C4H10N3O5P · 2C4H11NO3, molecular weight =  453.38
HEPESSigma-AldrichH3375C8H18N2O4S, molecular weight = 238.30
EGTASigma-AldrichE0396[-CH2OCH2CH2N(CH2CO2H)2]2, molecular weight = 380.40
Adenosine 5'-triphosphate magnesium saltSigma-AldrichA9187 C10H16N5O13P3 · xMg2+, molecular weight = 507.18
Guanosine 5'-triphosphate sodium salt hydrateSigma-AldrichG8877C10H16N5O14P3 · xNa+, molecular weight = 523.18
Tetrodotoxin citrateAlomone LabsT-550C11H17N3O8, molecular weight = 319.27
 DL-2-Amino-5-Phosphonovaleric AcidSigma-AldrichA5282 C5H12NO5P, molecular weight = 197.13
CNQX disodium salt hydrate Sigma-AldrichC239C9H2N4Na2O4 · xH2O, molecular weight = 276.12
StrychnineSigma-AldrichS0532C21H22N2O2, molecular weight = 334.41
Mecamylamine hydrochlorideSigma-AldrichM9020 C11H21N · HCl, molecular weight = 203.75
Gabazine (SR-95531)Sigma-AldrichS106C15H18BrN3O3, molecular weight = 368.23
Ketamine hydrochlorideMylan67457-001-00
MicroscopeNikonEclipse E600FN
MicromanipulatorSutter InstrumentsROE-200
MicromanipulatorSutter InstrumentsMPC-200
AmplifierMolecular DevicesMulticlamp 700B
A/D converterMolecular DevicesDigidata 1440A
HeaterWarner InstrumentsTC-324B
PumpCole-ParmerMasterflex L/S 7519-20
Pump cartridgeCole-ParmerMasterflex 7519-85
Pipette pullerSutter InstrumentsP-97
CameraQ-ImagingRET-200R-F-M-12-C
VibratomeLeica Biosystems Leica VT1200 S
Refrigeration systemVibratome Instruments900R
Equipment
microscopeNikonEclipse E600FN
micromanipulatorSutter InstrumentsROE-200
micromanipulatorSutter InstrumentsMPC-200
amplifierMolecular DevicesMulticlamp 700B
A/D converterMolecular DevicesDigidata 1440A
heaterWarner InstrumentsTC-324B
pumpCole-ParmerMasterflex L/S 7519-20
pump cartridgeCole-ParmerMasterflex 7519-85
pipette pullerSutter InstrumentsP-97
cameraQ-ImagingRET-200R-F-M-12-C

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