Differential modulation of voltage-gated sodium channels by nerve growth factor in three major subsets of TrkA-expressing nociceptors

Animals

CHRNA3-EGFP mice, official name Tg(Chrna3-EGFP)BZ135Gsat/Mmnc (RRID:MMRRC_000243-UNC) and Npy2r^Cre/+, official name Tg(Npy2r-cre)SM19Gsat/Mmucd (RRID:MMRRC_036630-UCD) and ChR2^loxP/+ animals (B6;129S-Gt(ROSA)26Sortm32(CAG-COP4* H134R/EYFP)Hze/J; RRID:IMSR_JAX:012569) were obtained from Jackson Laboratories. Mice were housed in the Interfacultary Biomedical Facility of Heidelberg University according to the institutional guidelines, and all animal experiments were carried out according to the German Animal Protection Law and with permission of the Regierungspraesidium Karlsruhe (T-57/16).

DRG cell culture

Twelve to eighteen weeks old female mice were killed by placing them in a CO₂-filled chamber for 2 to 4 min followed by cervical dislocation. L2–L5 DRGs were collected in Ca²⁺ and Mg²⁺-free phosphate-buffered saline (PBS) and incubated in a mixture of Collagenase type I (2.0 μg/ml, Sigma) and Trypsin (1.5 μg/ml, Sigma) for 60 min at 37°C. Digested DRG’s were washed twice with growth medium (Dulbecco’s modified Eagle’s medium-F12 (Invitrogen) supplemented with L-glutamine (2 µM, Sigma), glucose (8 mg/ml, Sigma), penicillin (200 U/ml)–streptomycin (200 µg/ml) (both Life Technologies) 5% fetal horse serum (Life Technologies)), triturated with a fire-polished Pasteur pipette and plated in a droplet of growth medium on glass coverslips precoated with poly-L-lysine (20 µg/cm², Sigma) and laminin (4 µg/cm², Life Technologies). To allow neurons to adhere, the coverslips were kept for 3 to 4 h at 37°C in a humidified 5% incubator before being flooded with fresh growth medium. Cultures were used for patch-clamp experiments on the next day.

Immnuohistochemistry

DRGs were dissected in ice-cooled PBS, fixed with 4% paraformaldehyde for 30 min at 4°C and incubated overnight in 30% sucrose at 4°C. DRGs were then embedded in Tissue-Tek O.C.T compound and cut into 16 µm cryo-sections. After drying, sections were incubated in 50 mM Glycine for 20 min, washed twice with PBS with Tween 20 (PBST) (0.2%), blocked with PBST (0.2%) + 10% donkey serum + 1% bovine serum albumin and then incubated with primary antibodies for 1 h at room temperature (RT). Primary antibodies were diluted in PBST (0.2%) + 10% donkey serum. Sections were then washed four times with PBST (0.2%), subsequently incubated with secondary antibodies for 1 h at RT, washed with PBST four times, dried and mounted with fluorogel (Fluoprobes).

Antibodies

The following primary antibodies were used: rat anti-GFP (Nacalai tesque, #04404–84, 1:3000; RRID:AB_10013361), mouse anti-neurofilament heavy polypeptide (NEFH) (Sigma-Aldrich, N0142, 1:600, RRID:AB_477257), goat anti-TrkA (R&D, AF1056, 1:200, RRID:AB_2283049) and Isolectin GS-IB4-Alexa Fluor® 568 Conjugate (Life technologies, 3 µg/ml). Secondary antibodies were AlexaFluor-488 donkey anti-rat (Life technologies, AF21208, 1:500, RRID:AB_2535794), AlexaFluor-594 donkey anti-mouse (Life technologies, AF21203 1:500, RRID:AB_2535789) and AlexaFluor-633 donkey anti-goat (Life technologies, A21082, 1:500, RRID:AB_10562400).

Electrophysiology

Whole-cell patch-clamp recordings were made at RT (20–24°C). Patch pipettes with a tip resistance of 0.8 to 1.5 MΩ were pulled (Flaming-Brown puller, Sutter Instruments, Novato, CA, USA) from borosilicate glass capillaries (BF150-86–10, Sutter Instrument), filled with a solution consisting of 120 mM CsCl, 10 mM NaCl, 20 mM TEA-Cl, 1 mM 4-aminopyridine, 1 mM EGTA, 10 mM HEPES, 2 mM guanosine 5′-triphosphate (GTP) and 2 mM adenosine 5′-triphosphate (ATP) adjusted to pH 7.3 with CsOH. The bathing solution contained 144 mM NaCl, 2 mM CaCl₂, 1 mM MgCl₂, 4 mM glucose, 10 mM HEPES and 100 µM CdCl₂ adjusted to pH 7.4 with NaOH. TTX and capsaicin were applied with a gravity-driven multi-barrel perfusion system (Valvelink8.2, Automate Scientific). All recordings were made using an EPC-10 amplifier (HEKA, Lambrecht, Germany) in combination with Patchmaster© and Fitmaster© software (HEKA). Pipette and membrane capacitance were compensated using the auto function of Patchmaster, and series resistance was compensated by >70% to minimize voltage errors. Using this approach, the maximal voltage errors shown in Table 1 for TTX-S and TTX-R currents were achieved.

Currents were sampled at 20 kHz, filtered at 2.9 kHz and linear leak currents were subtracted using a P/4 pulse protocol. Whole-cell sodium currents were elicited by a series of 40 ms step depolarizations from a holding potential of −120 mV to test potentials ranging from −70 mV to +60 mV in increments of 5 mV at an interval of 1 s. The TTX-S currents were isolated by subtracting the current recorded in the presence of 300 nM TTX (TTX-R current) from the total current recorded in the absence of TTX. For conductance–voltage curves, Na⁺ conductance (G) was calculated was calculated using the following equation: G = I_Na/(V-E_Na), where I_Na is the peak current amplitude at the test potential V, and E_Na is the reversal potential of sodium (+62.9 mV), which was calculated with the Nernst equation. To determine the voltage at which half of the sodium channels are activated (V_1/2), G/G_max curves were fit with a Boltzmann equation: G/G_max = 1/[1+exp(V_1/2–V/k)], where G_max is the maximal conductance, V is the test potential and k is the slope factor.

Fura2-Ca²⁺ imaging

To identify peptidergic C-fibre nociceptors – i.e. IB4⁻ neurons that respond to the TRPV1 agonist capsaicin – for the collection of cell samples for qRT-PCR, FURA-2-Ca²⁺ imaging was used. To this end, cultured DRG neurons loaded with FURA-2 (25 µM) and labelled with 1.5 µg/ml Isolectin GS-IB4-Alexa Fluor 568 conjugate at 37°C for 25 min and then washed with PBS for 10 min. Neurons were placed in a chamber containing extracellular buffer consisting of 140 mM NaCl, 1 mM MgCl_2, 2 mM CaCl₂, 4 mM KCl, 4 mM glucose and 10 mM HEPES adjusted to pH 7.4. Cells were illuminated alternately at 340 nm and 380 nm (100 ms exposure time Polychrome V, Visitron Systems) at a sampling frequency of 2 Hz, and Fura-2 fluorescence images were acquired with a ProgRes MF^Cool charge-coupled device (CCD) camera (Jenoptik, Germany). The Polychrome V and the ProgRes MF^Cool CCD camera were controlled by the imaging extension of the PatchMaster software (HEKE Elektronik). Fura-2 ratio images were generated with the ImageJ software. Neurons with a cell soma diameter <25 µm that were not labelled by IB4 and exhibited an increase in the Fura-2 signal in response to capsaicin were considered as peptidergic polymodal C-fibre nociceptors. To ensure that we did not collect silent nociceptors, some of which are also small and respond to capsaicin, all IB4⁻/caps⁺ neurons were collected from cultures prepared from CHRNA3^EGFP mice and the lack of a GFP signal was used as an additional selection criterion.

Cell sample collection and qRT-PCR

mRNA expression levels of VGSCs and beta subunits were determined as follows. From each nociceptor subpopulation (CHRNA3⁺, NPY2R⁺ or IB⁻/caps⁺) and each treatment condition (control and NGF), four cell samples (20 cell per sample) were collected from DRG cultures by aspirating the cells into a patch-clamp pipette with a tip diameter of 25 µm, filled with 2 to 4 µl PBS containing 4 U/µl RNAseOUT (Thermofisher). cDNA synthesis was carried out directly on the sample using the Power SYBR® Green Cells-to-CT™ Kit (Life Technologies) according to the manufacturers’ instructions. qRT-PCR reactions were set up using FastStart Essential DNA Green Master (Roche) by adding 4 µL of the obtained cDNA as template, and the primer pairs mentioned in Table 2 were used at a concentration of 250 nM.qRT-PCR reactions were performed in a LightCycler 96 (Roche) with a thermal cycler profile as follows: 10 min preincubation step at 95°C followed by 40 cycles of PCR with a 10 s denaturing cycle at 95°C, followed by 10 s of annealing at 60°C and 10 s extension at 72°C.

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Table 1.

Summary of patch-clamp recording parameters.

Cell population	Access resistance (mean ± SEM)	Compensation (%)	Maximum voltage error TTX-S (mV)	Maximum voltage error TTX-R (mV)
CHRNA3+ (ctl)	3.1 ± 0.37	80.1 ± 2.4	6.7 ± 1.6	3.3 ± 0.8
CHRNA3+ (NGF)	2.9 ± 0.39	78.9 ± 2.1	9.6 ± 1.7	5.3 ± 1.6
NPY2R+ (ctl)	2.9 ± 0.22	87.8 ± 0.7	8.8 ± 1.4	2.6 ± 0.3
NPY2R+ (NGF)	2.5 ± 0.27	87.9 ± 0.5	7.1 ± 1.2	4.0 ± 0.7
IB4−/caps+ (ctl)	4.2 ± 1.21	76.2 ± 0.9	4.7 ± 1.3	2.2 ± 0.3
IB4−/caps+ (NGF)	3.9 ± 0.82	81.4 ± 3.1	4.1 ± 1.6	1.6 ± 0.4

NGF: nerve growth factor; IB4: Isolectin B4; NPY2R: neuropeptide Y receptor type 2; CTL: control.

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Table 2.

List of primers used for qRT-PCR.

Nav1.6_ FWD	5′-CAGCAGGTCGAGAAATGTCTTTC-3′
Nav1.6_ REV	5′- CTCAAGCATTTCTGCCATTTCC-3′
Nav1.7_ FWD	5′-GTGGGCGAATTCACCTTCCT-3′
Nav1.7_ REV	5′-TCGAAGAGCTGAAACATTGCCTA-3′
Nav1.8_FWD	5′-ATAAGGGGCCAGGACATCTTC-3′
Nav1.8_REV	5′-AAACACGAAGCCCTGGTACT-3′
Nav1.9_FWD	5′-TGAGGCAACACTACTTCACCAATG-3′
Nav1.9_REV	5′-AGCCAGAAACCAAGGTACTAATGATG-3′
Beta1_ FWD	5′-TGCATGATGGGTGAAGCAAT-3′
Beta1_ REV	5′-GCCTATGTGCAAATCAGCAAAA-3′
Beta2_ FWD	5′-ATACCCGCCTGCCCTGTACC-3′
Beta2_ REV	5′-TCTCCAAACCGCTCCAGCTTC-3′
Beta3_ FWD	5′-TATAAATGAGAAAGCCCTGGTTCTG-3′
Beta3_ REV	5′-GCCTAACCTAGTGCTCGACACA-3′
Beta4_ FWD	5′-GGATGCCCAAATGAGGGATT-3′
Beta4_ REV	5′-CCAGAGGACTAAACCATGCATAAGA-3′
GAPDH- FWD	5′-GCATGGCCTTCCGTGTTC-3′
GAPDH-REV	5′-GTAGCCCAAGATGCCCTTCA-3′

GAPDH: Glyceraldehyde 3-phosphate dehydrogenase.

Statistics

All statistical analyses were made using GraphPad Prism 7. The statistical tests that were used are mentioned in the figure legends and in the main text. N-numbers for each experiment – i.e. numbers of biological replicates – are provided in the figure or in the figure legend. To select the appropriate test, all data sets were tested for Gaussian distribution using the Kolmogorov–Smirnov test.

The properties of VGSCs differ between the three major subpopulations of TrkA⁺ nociceptors

To identify silent nociceptors, we prepared DRG cultures from CHRNA3-EGFP mice in which EGFP is exclusively expressed in this subset of nociceptors, which are unmyelinated as indicated by the lack of NEFH expression, have small-to-medium cell soma diameters and express the NGF receptor TrkA (Figure 1(a)). ¹⁹ Aδ-fibre nociceptors were visualized using NPY2R^ChR2 mice in which EYFP-tagged channelrhodopsin 2 expression is confined to myelinated TrkA⁺ neurons with large cell bodies (Figure 1(b)), as previously described. ³¹ Finally, polymodal C-fibre nociceptors were identified in cultures from CHRNA3-EGFP mice as EGFP⁻/IB4⁻ small diameter neurons (< 25 µm) that were sensitive to capsaicin (Figure 1(c)).

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Figure 1.

Differences in TTX-S sodium currents in three major subsets of TrkA-expressing neurons. (a) Immunohistochemistry of a DRG section showing that CHRNA3⁺ neurons co-express the TrkA receptor but not NEFH. (b) Immunohistochemistry showing that NPY2R⁺ neurons express both TrkA and NEFH. (c) Representative example traces of TTX-S currents (bottom traces) elicited by the indicated pulse protocol (top trace). The rightmost trace shows a typical response of a small diameter IB4⁻ neuron to 500 nM capsaicin. (d) Current–voltage relationship of the TTX-S currents (mean current density ± SEM) in the indicated cell types. (e) Comparison of the current densities of the maximal TTX-S current in the indicated cell types using one-way ANOVA and Holm–Sidak’s multiple comparison test. Note that the current densities of the TTX-S current were significantly bigger in NPY2R+ neurons as compared to the other two nociceptor subtypes. (f) Boltzmann fits of the conductance–voltage plots showing that TTX-S currents in NPY2R⁺ and CHRNA⁺ activate at more negative potentials compared to TTX-S currents in IB4⁻ neurons. (g) Comparison of the V_1/2 ± SEM values obtained by the Boltzmann fits shown in (f). Boltzmann fits (V_1/2 values) were compared pairwise using the extra sum-of-squares F-test. ****P < 0.0001. TTX: tetrodotoxin; IB4: Isolectin B4; NPY2R: neuropeptide Y receptor type 2; NEFH: neurofilament heavy polypeptide; CHRNA3: nicotinic acetylcholine receptor alpha-3 subunit.

Whole-cell sodium currents elicited by a series of 40 ms step depolarizations from −120 mV to test potentials ranging from −70 mV to +60 mV in increments of 5 mV were recorded before and after application of 300 nM TTX. The TTX-S currents were isolated by subtracting the TTX-R current from the total current recorded in the absence of TTX. The current–voltage relationship showed that TTX-S currents in CHRNA3⁺ neurons and NPY2R⁺ neurons activated at more hyperpolarized potentials than TTX-S currents in IB4⁻/caps⁺ nociceptors (Figure 1(a)) and revealed differences in current densities between the three nociceptor subpopulations (Figure 1(e)). Thus, the maximum current densities of the TTX-S currents in NPY2R⁺ neurons were significantly bigger than the TTX-S current densities in the other two populations (NPY2R⁺ I_max-TTX-S = −1052 ± 123.8 pA/pF; CHRNA3⁺: I_max-TTX-S = 450.2 ± 112.4 pA/pF; IB4⁻/caps+: I_max-TTX-S = −609.2 ± 71.1 pA/pF; Figure 1(e)). Boltzmann fits of the conductance–voltage relations shown in Figure 1(f) revealed that the voltage for half-maximal activation (V_1/2) of TTX-S currents was significantly more negative in CHRNA3⁺ (V_1/2 = −26.74 ± 0.51 mV) and NPY2R⁺ (V_1/2 = −30.29 ± 0.37 mV) neurons as compared to IB4⁻/caps⁺ nociceptors (V_1/2 = −14.22 ± 0.82 mV) (Figure 1(g)). The TTX-R currents in the three nociceptor subpopulations (Figure 2(a)) also differed from one another in several aspects. Thus, the current densities of TTX-R currents were significantly bigger in NPY2R⁺ nociceptors (−272.7 ± 30.4 pA/pF) as compared to CHRNA3⁺ neurons (−188.4 ± 21.7 pA/pF) and IB4⁻/caps⁺ nociceptors (−140.0 ± 24.3 pA/pF) (Figure 2(b) and (c)). Moreover, TTX-R currents in CHRNA3⁺ neurons were activated at significantly more negative potentials (V_1/2 = −16.8 ± 0.5 mV) as compared to TTX-R currents in NPY2R⁺ neurons, which had a V_1/2 of −7.7 ± 1.0 mV, and IB4⁻/caps⁺ nociceptor with a V_1/2 of −4.3 ± 0.6 mV (Figure 2(d) and (e)).

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Figure 2.

Differences in TTX-R sodium currents in three major subsets of TrkA-expressing neurons. (a) Representative example traces of TTX-R currents (bottom traces) elicited by the indicated pulse protocol (top trace). (b) Current–voltage relationship of the TTX-R currents (mean current densities ± SEM) in the indicated cell types. (c) Comparison of the current densities of the maximal TTX-R current in the indicated cell types using one-way ANOVA and Holm-Sidak’s multiple comparison test. Note that the current densities of the TTX-R current in NPY2R⁺ neurons are significantly bigger than in the other two subtypes. (d) Boltzmann fits of the conductance–voltage plots showing that TTX-R currents in NPY2R⁺ and CHRNA⁺ activate at more negative potentials compared to TTX-R currents in IB4⁻ neurons. (g) Comparison of the V_1/2 ± SEM values obtained by the Boltzmann fits shown in (f). Boltzmann fits (V_1/2 values) were compared pairwise using the extra sum-of-squares F-test. ****P < 0.0001. TTX: tetrodotoxin; IB4: Isolectin B4; NPY2R: neuropeptide Y receptor type 2; CHRNA3: nicotinic acetylcholine receptor alpha-3 subunit.

To test if the observed differences in current densities and in half-activation voltages of TTX-S and TTX-R currents (Figures 1 and 2) result from differences in the expression levels of certain VGSC α- and β-subunits, we next quantified the mRNA levels of Na_v1.6, Na_v1.7, Na_v1.8 and Na_v1.9, which are the most abundant α-subunit isoforms in DRG neurons, as well as the mRNA levels of the β1, β2, β3 and β4 subunits using qRT-PCR. This analysis revealed that NPY2R⁺ neurons express Na_v1.6 and the β-subunits β1 and β4 at significantly higher levels than IB4⁻/caps⁺ neurons (Figure 3(a)). Moreover, we observed a trend towards higher expression levels of Na_v1.7, Na_v1.8 and β2 in NPY2R⁺ neurons as compared to IB4⁻/caps⁺ neurons, but these differences were not statistically significant (Figure 3(a)). CHRNA3⁺ neurons exhibited a similar sodium channel expression profile as NPY2R⁺ neurons, with higher levels of Na_v1.6, Na_v1.7, Na_v1.8, β2 and β4 than IB4⁻/caps⁺ neurons, but none of the differences was statistically significant.

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Figure 3.

Comparison of the expression patterns of sodium channel α and β subunits. (a) Bars show the mean ± SEM mRNA expression levels of the indicated sodium channel α- and β-subunits normalized to the expression levels of the housekeeping gene GAPDH in the same samples. The expression levels of the individual samples are indicated by the symbols. The mean expression levels were compared using one-way ANOVA and Holm–Sidak’s multiple comparison test and where significant differences were observed, the exact P values are provided in the graph. TTX: tetrodotoxin; GAPDH: Glyceraldehyde 3-phosphate dehydrogenase; IB4: Isolectin B4; NPY2R: neuropeptide Y receptor type 2; CHRNA3: nicotinic acetylcholine receptor alpha-3 subunit.

Taken together, our electrophysiological characterization together with the results of the qRT-PCR indicate that each of the three major subsets of TrkA⁺ nociceptors expresses a different combination of sodium channel α- and β-subunits, which results in the generation of functionally different sodium currents in each of the three subpopulations.

NGF differentially modulates VGSC in different subsets of TrkA⁺ nociceptors

We next asked if the TTX-S and TTX-R currents are differentially modulated by NGF in the three nociceptor subpopulations. To this end, 100 ng/ml NGF was added to the growth medium at the time of cell plating, and sodium currents were recorded on the next day – i.e. usually between 20 and 28 h after the addition of NGF. NGF treatment did not alter any of the examined properties of TTX-S currents in CHRNA3⁺ neurons (Figure 4(a) to (d)). However, NGF did induce a significant increase in the TTX-R current density in these neurons, from −188.4 ± 21.7 pA/pF under control conditions to −291.3 ± 22.2 pA/pF after NGF treatment (Figure 4(e) to (f)). The half-activation voltage of TTX-R currents was only minimally affected (Figure 4(g) to (h)). Surprisingly, the effects of NGF on NPY2R⁺ neurons were completely different. Thus, NGF treatment caused a small but significant reduction in the TTX-S current densities (CTL: −1052 ± 123.8 pA/pF vs. NGF: −694.3 ± 73.2 pA/pF; Figure 5(a) and (b)); the voltage dependence of activation of TTX-S current was not altered (TTX-S-CTL-V_1/2 = −30.3 ± 0.4 mV vs. TTX-S-NGF-V_1/2 = −29.4 ± 0.7 mV; Figure 5(c) and (d)). Unlike in CHRNA3⁺ neurons, NGF treatment did not alter the TTX-R current densities in NPY2R⁺ (Figure 5(e) and (f)) but instead shifted the half-activation voltage by ∼7 mV to more negative potentials (TTX-R-CTL-V_1/2 = −8.7 ± 0.7 mV vs. TTX-R-NGF-V_1/2 = −15.1 ± 1.0 mV; Figure 5(g) and (h)). The sodium currents in IB4⁻/caps⁺ neurons were modulated in a similar manner as those in NPY2R⁺ neurons. Thus, the TTX-S current densities in IB4⁻/caps⁺ neurons were slightly, though not significantly, reduced by NGF treatment (Figure 6(a) and (b)). Interestingly, in contrast to NPY2R⁺ and CHRNA3⁺ neurons, NGF treatment significantly shifted the voltage dependence of activation to more negative potentials in IB4⁻/caps⁺ neurons (TTX-S-CTL-V_1/2 = −13.9 ± 0.7 mV vs. TTX-S-NGF-V_1/2 = −19.6 ± 1.3 mV; Figure 6(c) and (d)). TTX-R current densities were also slightly, but not significantly, increased (Figure 6(e) and (f)) and, as in NPY2R⁺ neurons, NGF shifted the V_1/2 of the TTX-R currents in IB4⁻/caps⁺ neurons by ∼12 mV to more negative potentials (TTX-R-CTL-V_1/2 = −3.9 ± 0.5 mV vs. TTX-R-NGF-V_1/2 = −16.4 ± 1.3 mV; Figure 6(g) and (h)). We next asked if the effects of NGF on sodium current properties could, at least partially, be attributed to changes in the expression levels of sodium channel α- and β-subunits. To this end, we compared the mRNA levels of Na_v1.6–1.9 and β_1–4 in cells that were cultured for 24 h in normal growth medium with cells that were cultured in the presence of 100 ng/ml NGF for the same period of time. Surprisingly, the only noteworthy change that we could observe was a more than two-fold down-regulation of the mRNA levels of Na_v1.8 in IB4⁻/caps⁺ neurons, which, however, was not statistically significant (Figure 7(a) to (c)). All other sodium channel α- and β-subunits appeared to be expressed at the same level in the absence and presence of NGF.

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Figure 4.

Modulation of TTX-S and TTX-R currents by NGF in silent nociceptors. (a) Current–voltage relationship of the TTX-S currents (mean current densities ± SEM) in CHRNA3⁺ neurons cultured for 24 h in normal growth medium (CTL; green circles) and 24 h in the presence of 100 ng/ml NGF (NGF, half-filled circles). (b) Comparison of the current densities of the maximal TTX-S current in control conditions (CTL, green bars) and in the presence of NGF (hatched bars) using Student’s t-test. (c) Boltzmann fits of the conductance–voltage plots showing that NGF does not alter the voltage dependence of activation of TTX-S currents in CHRNA⁺ neurons. (d) Comparison of the V_1/2 ± SEM values obtained by the Boltzmann fits shown in (c). Boltzmann fits (V_1/2 values) were compared using the extra sum-of-squares F-test. (e) Current–voltage relationship of the TTX-R currents (mean current densities ± SEM) in CHRNA3⁺ neurons. (f) Comparison of the current densities of the maximal TTX-R current using Student’s t-test showing that NGF significantly increases the TTX-R current in CHRNA3⁺ neurons (g) Boltzmann fits of the conductance–voltage plots showing that NGF does not alter the voltage dependence of activation of TTX-R currents in CHRNA⁺ neurons. (h) Comparison of the V_1/2 ± SEM values in the absence and presence of NGF obtained by the Boltzmann fits shown in (g). Boltzmann fits (V_1/2 values) were compared using the extra sum-of-squares F-test. N-numbers were same in (a) to (h) and are provided below the bars in (b), (d), (f), and (h). The exact P values of the statistical comparisons are also indicated below the bar graphs. TTX: tetrodotoxin; CTL: control; NGF: nerve growth factor; CHRNA3: nicotinic acetylcholine receptor alpha-3 subunit.

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Figure 5.

Modulation of TTX-S and TTX-R currents by NGF in NPY2R⁺ Aδ-nociceptors. (a) Current–voltage relationship of the TTX-S currents (mean current densities ± SEM) in NPY2R⁺ neurons cultured for 24 h in normal growth medium (CTL; orange circles) and 24 h in the presence of 100 ng/ml NGF (NGF, half-filled circles). (b) Comparison of the current densities of the maximal TTX-S currents in control conditions (CTL, orange bars) and in the presence of NGF (hatched bars) using Student’s t-test showing that NGF causes a small but significant reduction in TTX-S current density. (c) Boltzmann fits of the conductance–voltage plots showing that NGF does not alter the voltage dependence of activation of TTX-S currents in NPY2R⁺ neurons. (d) Comparison of the V_1/2 ± SEM values in the absence and presence of NGF obtained by the Boltzmann fits shown in (c) using the extra sum-of-squares F-test. (e) Current–voltage relationship of the TTX-R currents (mean current densities ± SEM) in NPY2R⁺ neurons. (f) Comparison of the current densities of the maximal TTX-R current using Student’s t-test. (g) Boltzmann fits of the conductance–voltage plots showing that NGF shifts the voltage dependence of activation of TTX-R currents in NPY2R⁺ neurons to more hyperpolarized potentials. (h) Comparison of the V_1/2 ± SEM values obtained by the Boltzmann fits shown in (g) using the extra sum-of-squares F-test showing that NGF treatment shifts the half-activation voltage by ∼7 mV from −8.7 ± 0.7 mV to −15.1 ± 1.0 mV. N-numbers were same in (a) to (h) and are provided below the bars in (b), (d), (f), and (h). The P values of the statistical comparisons are also indicated below the bar graphs. TTX: tetrodotoxin; CTL: control; NGF: nerve growth factor; NPY2R: neuropeptide Y receptor type 2.

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Figure 6.

Modulation of TTX-S and TTX-R currents by NGF in polymodal C-fibre nociceptors. (a) Current–voltage relationship of the TTX-S currents (mean current densities ± SEM) in small diameter IB4⁻ capsaicin-sensitive (caps⁺) neurons cultured for 24 h in normal growth medium (CTL; red circles) and 24 h in the presence of 100 ng/ml NGF (NGF, half-filled circles). (b) Comparison of the current densities of the maximal TTX-S current using Student’s t-test showing that NGF does not alter TTX-S current density in IB4⁻/caps⁺ neurons. (c) Boltzmann fits of the conductance–voltage plots showing that NGF shifts the voltage dependence of activation of TTX-S currents in IB4⁻/caps⁺ neurons to more hyperpolarized potentials. (d) Comparison of the V_1/2 ± SEM values obtained by the Boltzmann fits shown in (c) using the extra sum-of-squares F-test. Note that NGF treatment shifts the half-activation voltage by ∼6 mV from −13.9 ± 0.7 mV to −19.6 ± 1.3 mV. (e) Current–voltage relationship of the TTX-R currents (mean current densities ± SEM) in the same cells shown in (a) to (d). (f) Comparison of the current densities of the maximal TTX-R current using Student’s t-test. (g) Boltzmann fits of the conductance–voltage plots showing that NGF shifts the voltage dependence of activation of TTX-R currents in IB4⁻/caps⁺ neurons to more hyperpolarized potentials. (h) Comparison of the V_1/2 ± SEM values obtained by the Boltzmann fits shown in (g) using the extra sum-of-squares F-test showing that NGF treatment shifts the half-activation voltage by ∼12 mV from −3.9 ± 0.5 mV to −16.4 ± 1.3 mV. N-numbers were same in (a) to (h) and are provided below the bars in (b), (d), (f), and (h). The P values of the statistical comparisons are also indicated below the bar graphs. TTX: tetrodotoxin; CTL: control; NGF: nerve growth factor; IB4: Isolectin B4.

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Figure 7.

NGF does not alter the expression levels of sodium channel α- and β-subunits. Comparisons of the mean ± SEM mRNA expression levels of the indicated sodium channel α- and β-subunits normalized to the expression levels of the housekeeping gene GAPDH in CHRNA3⁺ (a), NPY2R⁺ (b) and IB4⁻/caps⁺ (c) neurons cultured for 24 h in the absence (CTL) and neurons cultured for 24 h in the presence of 100 ng/ml NGF (NGF). The expression levels of the individual samples are indicated by the symbols. The expression levels were compared using Student’s t-test, but no significant changes in mRNA expression were detected. GAPDH: Glyceraldehyde 3-phosphate dehydrogenase; CTL: control; NGF: nerve growth factor.

Taken together, our results show that NGF differentially modulates voltage-gated sodium currents in different subpopulations of TrkA⁺ neurons and suggest that none of these effects is mediated by changes in the expression levels sodium channel α- or β-subunits.

Differences in the expression levels of sodium channel α- and β-subunits account for the functional differences in sodium current in the three nociceptor subpopulation

One of the key findings of this study was that TTX-S currents in CHRNA3⁺ and NPY2R⁺ nociceptors are activated at more negative potentials than TTX-S currents in IB4⁻/caps⁺ nociceptors (Figure 1(c) to (g)). One possible explanation for these differences is that the former two subpopulations express significant amounts of Na_v1.6 and the β4-subunit (Figure 3). Na_v1.6 has been shown to be activated at rather negative potentials, though it should be noted that the reported V_1/2 values of Na_v1.6 in DRG neurons vary between −35.9 mV and −18.7 mV in different studies,^34,35 and the β4-subunit was previously shown to shift the half-activation voltage of Na_v1.6 by ∼8 mV to hyperpolarized potentials in heterologous systems. ³⁶ Hence, the co-expression of these two proteins is most likely the reason for the extremely hyperpolarized half-activation voltages of TTX-S current in NPY2R⁺ and CHRNA3⁺ neurons. Our observation that NPY2R⁺ neurons, which are Aδ-fibre nociceptors, express high levels of Na_v1.6 is consistent with previous reports showing that myelinated Aδ- and Aβ-fibres but not C-fibre nociceptors express Na_v1.6.^37,38 We are not aware of any study that has examined the expression of Na_v1.6 in silent nociceptors, but recently Feng et al. ³⁹ demonstrated Nav1.6 expression in a significant proportion of Nav1.8-expressing colorectal afferents. Considering that CHRNA3⁺ afferents account for approximately one half of all nociceptive peptidergic colorectal afferents, ¹⁹ it is tempting to speculate that these fibres were also included in the population labelled by Feng et al. ³⁹ For Na_v1.7, V_1/2 values around −25 mV have previously been reported^35,40 and there is no evidence suggesting that β-subunits alter the voltage dependence of Na_v1.7 activation.^40–42 However, phosphorylation by ERK1/2 was shown to shift the V_1/2 of Na_v1.7 to more negative potentials. ³⁰ Hence, another possible explanation for the hyperpolarized half-activation voltages is that the basal activity of ERK1/2 is higher in NPY2R⁺ and CHRNA3⁺ neurons.

Another important observation of our study was that the TTX-R currents in NPY2R⁺ neurons had significantly higher current densities than CHRNA3⁺ neurons and IB4⁻/caps⁺ neurons (Figure 2(c)). Since NPY2R⁺ neurons only express small amounts of Na_v1.9 (Figure 3), most of the TTX-R current is probably carried by Na_v1.8. The expression levels of Na_v1.8 did not significantly differ between the three populations (Figure 3) and thus we propose that the high TTX-R current densities in NPY2R⁺ neurons result from the significantly higher levels of the β1-subunit (Figure 3), which has indeed been shown to increase Na_v1.8 mediated currents in heterologous systems. ³⁶ We further observed that TTX-R currents in CHRNA3⁺ neurons had more hyperpolarized half-activation voltages than TTX-R currents in both NPY2R⁺ and IB4⁻/caps⁺ nociceptors (Figure 2). The hyperpolarized half-activation voltage of TTX-R currents in CHRNA3⁺ is consistent with the high expression levels of the β4-subunit, which was shown to shift the V_1/2 of Na_v1.8 to hyperpolarized potentials by more than 15 mV, ³⁶ which is comparable to the difference between CHRNA3⁺ and IB4⁻/caps⁺ positive observed here (Figure 2(d) and (e)). Cell-to-cell variability in the properties of TTX-R sodium currents has previously been reported, ⁴³ and, moreover, it was shown that modulation of Na_v channel function by β-subunits can depend on the cellular background. The β1-subunit, for example, was shown to increase the rate of open-channel inactivation and to shift steady-state inactivation of Nav1.3 in Xenopus oocytes but not in HE293 cells. ⁴⁴ Sodium channel function is also altered by posttranslational modifications, e.g. by protein kinases, glycosylation and ubiquitylation.^20,21 Hence, one possible explanation for the cell type-specific effects of β-subunits is that different posttranslational modifications occur in different cell types, which could also explain why TTX-R currents in NPY2R⁺ neurons have half-activation voltages similar to TTX-R currents in IB4⁻/caps⁺ neurons (Figure 2(d) and (e)), despite expressing significantly higher levels of the β4 subunit (Figure 3). However, considering the variety of possible post-translational modification of VGSCs that had previously been described in other cells types,^20,21 we did not address this question here, as this would have been beyond the scope of this study.

NGF differentially modulates sodium currents in different subsets of TrkA⁺ nociceptors

The second major goal of our study was to test if NGF, which has previously been shown to modulate sodium currents in small diameter IB4⁻ capsaicin-sensitive nociceptors, also modulates sodium currents in silent nociceptors (CHRNA3⁺) and Aδ-fibre nociceptors (NPY2R⁺). Specifically, we focused on two parameters – i.e. current density and voltage dependence of activation. Regarding current densities, our data show that NGF induces a significant increase in TTX-R currents in CHRNA3⁺ neurons (Figure 4(f)) but not in NPY2R⁺ neurons (Figure 5(f)), while it causes a small but significant decrease in TTX-S current density in NPY2R⁺ neurons (Figure 5(b)) without affecting TTX-S currents in CHRNA3⁺ nociceptors (Figure 4(b)). As mentioned earlier, changes in the current densities might result from changes in the expression levels of α-subunits and/or β-subunits, some of which are well known to enhance membrane trafficking of sodium channels.^20,41 However, unlike previously reported for small diameter neuron in long-term DRG cultures (7 div), ⁴⁵ we did not observe an up-regulation of Na_v1.8 in CHRNA3⁺ neurons (Figure 7(a)) after 24 h NGF treatment. Moreover, we neither detected a down-regulation of Na_v1.7 in NPY2R⁺ neurons (Figure 7(b)) nor any significant changes in β-subunit expression in these two nociceptor subpopulations, suggesting that the changes in current densities are probably induced by post-translational modifications rather than transcriptional changes. In fact, downstream effectors of NGF-TrkA signalling, including p38 MAP kinase and ceramide, have previously been shown to increase Na_v1.8 currents in small diameter IB4⁻/caps⁺ neurons, in case of p38 by facilitating membrane trafficking.^22,23,46 We also observed the previously described NGF-induced increase in Nav1.8 amplitudes in small diameter IB4⁻/caps⁺ neurons, though in our hands, this effect was not statistically significant, which may be attributed to the rather small samples size of these cells in our study (Figure 6(e) and (f)). The reduction in TTX-S current density in NPY2R⁺ neurons was significant, but rather small (Figure 5(b)), and was not reflected in a downregulation of TTX-S sodium channel α- or β-subunits (Figure 7(b)). However, the cell capacitance of NPY2R⁺ neurons increased from 30.5 ± 1.7 pF to 46.2 ± 5.3 pF after NGF treatment, which provides an alternative explanation for this effect.

The most robust effects of NGF on sodium currents that we observed were the hyperpolarizing shifts of the half-activation voltages of TTX-R currents in NPY2R⁺ (Figure 5(g) and (h)) and IB4⁻/caps⁺ neurons (Figure 6(g) and (h)) and the hyperpolarizing shift in V_1/2 of TTX-S currents in IB4⁻/caps⁺ neurons (Figure 6(c) and (d)). It is difficult to unequivocally attribute changes in TTX-S and TTX-R currents to changes in the functional properties of a single sodium channel, because these are composite currents generated from multiple channels. ⁴⁷ This is particularly true for the TTX-S currents in CHRNA3⁺ and NPY2R⁺ neurons, which express both Na_v1.6 and Na_v1.7 at considerable levels (Figure 3). The TTX-R currents are, however, most likely predominantly generated by Nav1.8, which is expressed at much higher levels than Nav1.9 in all three studied nociceptor populations (Figure 3). An NGF-induced hyperpolarizing shift in the voltage dependence of TTX-R sodium current, which is thought to be mediated by second messenger ceramide-induced activation of PKCζ, has previously been reported for small diameter IB4⁻/caps⁺ neurons,^23,24 but it has never been tested if this effect also occurs in other TrkA⁺ nociceptors. We did not detect any significant changes in the expression of sodium channel α-subunits and β-subunits (Figure 7(b)), which can also change the voltage dependence of activation.^20,41 Hence, it is tempting to speculate that the NGF-induced hyperpolarizing shift in the V_1/2 of TTX-R currents in NPY2R⁺ Aδ-nociceptors may be mediated by the same mechanisms that was previously described for IB4⁻/caps⁺ neurons.^23,24 Since NGF is known to activate ERK1/2 MAP kinases^1,48 and phosphorylation of Na_v1.7 by ERK1/2 was shown to cause a hyperpolarizing shift of channel activation, ³⁰ it has been hypothesized that NGF shifts the V_1/2 of TTX-S currents to more negative potentials, but actually this hypothesis has never been directly tested. Here, we demonstrate that NGF indeed shifts the voltage dependence of the TTX-S current in small diameter IB4⁻/caps⁺ neurons as previously proposed but not in myelinated NPY2R⁺ Aδ-fibre nociceptors or CHRNA3⁺ silent nociceptors. The observation that NGF did not alter the voltage dependence of activation of TTX-S currents in NPY2R⁺ and CHRNA3⁺ neurons was quite unexpected considering that ERK1/2, which supposedly mediates this effect in IB4⁻/caps⁺ neurons, is also activated by NGF in CHRNA3⁺ neurons, as we have recently shown, ¹⁹ and probably also in NPY2R⁺ neurons. While we can only speculate about the possible reasons for the lack of TTX-S sodium current modulation in CHRNA3⁺ neurons, our results clearly demonstrate that NGF exerts different effects on different nociceptor subpopulations, even though these subpopulations appear to express the same downstream effector proteins.