Actions of substance P on membrane potential and ionic currents in guinea pig stellate ganglion neurons

Robert Gilbert1, Jennifer S. Ryan1, Magda Horackova2, Frank M. Smith3, and Melanie E. M. Kelly1

Departments of 1 Pharmacology, 2 Physiology and Biophysics, and 3 Anatomy and Neurobiology, Faculty of Medicine, Dalhousie University, Halifax, Nova Scotia, Canada B3H 4H7

    ABSTRACT
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Neuropeptides are known to modulate the excitability of mammalian sympathetic neurons by their actions on various types of K+ and Ca2+ channels. We used whole cell patch-clamp recording methods to study the actions of substance P (SP) on dissociated adult guinea pig stellate ganglion (SG) neurons. Under current-clamp conditions, SG neurons exhibited overshooting action potentials followed by afterhyperpolarizations (AHP). The K+ channel blocker tetraethylammonium (1 mM), the Ca2+ channel blocker Cd2+ (0.1-0.2 mM), and SP (500 nM) depolarized SG neurons, decreased the AHP amplitude, and increased the action potential duration. In the presence of Cd2+, the effect of SP on membrane potential and AHP was reduced. Under voltage-clamp conditions, several different K+ currents were observed, including a transient outward K+ conductance and a delayed rectifier outward K+ current (IK) consisting of Ca2+-sensitive [IK(Ca)] and Ca2+-insensitive components. SP (500 nM) inhibited IK. Pretreatment with Cd2+ (20-200 µM) or the high-voltage-activated Ca2+ channel blocker omega -conotoxin (10 µM) blocked SP's inhibitory effects on IK. This suggests that SP reduces IK primarily through the inhibition of IK(Ca) and that this may occur, in part, via a reduction of Ca2+ influx through voltage-dependent Ca2+ channels. SP's actions on IK were mediated by a pertussis toxin-insensitive G protein(s) coupled to NK1 tachykinin receptors. Furthermore, we have confirmed that 500 nM SP reduced an inward Cd2+- and omega -conotoxin-sensitive Ba2+ current in SG neurons. Thus the actions of SP on IK(Ca) may be due in part to a reduction in Ca2+ influx occurring via N-type Ca2+ channels. This study presents the first description of ionic currents in mammalian SG neurons and demonstrates that SP may modulate excitability in SG neurons via inhibitory actions on K+ and Ca2+ currents.

G protein; patch clamp; tachykinin; omega -conotoxin

    INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

THE INVESTIGATION of sympathetic efferent projections in a number of different mammalian species has revealed that sympathetic postganglionic neurons innervating the heart arise primarily from the middle cervical-stellate ganglion (SG) complex (29). In contrast to autonomic neurons from other paravertebral ganglia, such as the superior cervical ganglion (SCG) (1, 34, 36) and enteric ganglion (1, 37, 41), information on the electrophysiological properties of SG neurons and their modulation by neuroactive agents is sparse. The SG is an important site for modulation of transmission of the sympathetic cardiomotor drive; therefore, information on the signal transduction pathways involved in the control of ganglionic transmission is essential for our understanding of autonomic regulation of the heart.

The purpose of the present study was to examine the effects of substance P (SP) on guinea pig SG neurons. SP is an undecapeptide that acts as a neurotransmitter and a neuromodulator in the central and peripheral nervous systems (27, 28). SP is found within the cell bodies and nerve fibers of a number of different mammalian autonomic ganglia, including the neurons of the enteric plexus (9, 27) and the neurons of the SG in situ (13, 20). Immunohistochemical studies have indicated that nerve terminals in the guinea pig SG may contain SP or other peptides, including calcitonin gene-related peptide (13, 17). These peptide-containing fibers are believed to originate from preganglionic sympathetic neurons of the spinal cord or from sensory neurons (13).

The actions of SP in the mammalian nervous system are typically associated with slow depolarization (26, 27, 37, 39, 41). In rat sympathetic SCG neurons, SP-coupled signaling pathways appear to be involved in the modulation of Ca2+ channels (35), whereas in guinea pig submucosal and celiac neurons a decreased K+ conductance (the M current) is primarily responsible for the slow excitatory postsynaptic potential and depolarization produced by SP (37, 41). This depolarization also included a component that was due to SP activation of a nonspecific cation current (37). Although the different ion channels underlying the modulation of action potential (AP) threshold and excitability in mammalian SG neurons have not been resolved, SP was found to depolarize ganglion neurons through a decreased conductance, possibly a K+ conductance (25). Our data provide evidence that SP depolarizes dissociated guinea pig SG neurons via a decrease in outwardly rectifying K+ current (IK), primarily the Ca2+-sensitive component [IK(Ca)]. We show that the peptide-signaling pathway involves a pertussis toxin (PTX)-insensitive G protein and that the inhibition of IK(Ca) may be mediated in part through SP inhibition of voltage-dependent Ca2+ influx. Furthermore, we also demonstrate the occurrence of a transient K+ current (IA) in guinea pig SG neurons that was not affected by SP. Although M current has been shown to be blocked by SP in other autonomic neurons (37), an M-type current was rarely observed in guinea pig SG neurons in this study and is therefore unlikely to contribute significantly to the observed reduction in K+ conductance.

    MATERIALS AND METHODS
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Ganglion dissection and cell culture. SG were isolated from adult guinea pigs (250-300 g) according to Horackova et al. (18). All procedures conformed to guidelines of the Canadian Council on Animal Care. Briefly, animals were anesthetized with halothane (Fluothane) and decapitated. The right and left SG were exposed rostral to the first rib, removed, and placed in bubbled PBS solution. After removal of excess connective tissue, ganglia were dissociated by incubation at 37°C in 5 mg/ml collagenase and 1 mg/ml trypsin. The trypsin action was terminated after 50 min by the addition of 1 ml of newborn calf serum. Cells were then centrifuged (1,000 g) and resuspended in 2 ml of DMEM (GIBCO BRL, Burlington, ON, Canada) and gently triturated with a fire-polished Pasteur pipette. Suspensions of isolated SG somata were seeded in growth medium on collagen-coated (Boehringer Mannheim, Laval, PQ, Canada) glass coverslips and placed in a 37°C incubator with an atmosphere of 5% CO2-95% air. Growth medium consisted of DMEM containing 10% newborn calf serum, 1% penicillin-streptomycin, 10 ng/ml nerve growth factor, and 5 µg/ml cytosine 1-beta -D-arabinofuranoside, used to inhibit the growth of nonneuronal cells (17). Neurons were maintained in primary culture for 24-72 h and identified by morphological and electrophysiological criteria (see RESULTS). For experiments examining G protein subtypes, pretreatment with PTX was accomplished by the addition of PTX (500 ng/ml) to the culture medium at the time of cell plating. SG neurons were exposed to PTX for at least 24 h before electrophysiological recording. Control SG neurons were plated from the same ganglion culture as the PTX-treated cells, and recordings of control and PTX-treated neurons were obtained on the same experimental day to ensure consistent experimental conditions.

Superfusion and solutions. Cultured SG neurons grown on glass coverslips were placed in a shallow recording chamber (2 ml) and superfused at 1-2 ml/min with standard recording solution containing (in mM) 140 NaCl, 5 KCl, 20 Na+-HEPES, 1 MgCl2, 2 CaCl2, and 10 glucose. In experiments examining Ca2+ currents, the external solution was (in mM) 150 tetraethylammonium chloride (TEA), 5 BaCl2, 10 HEPES, 0.8 MgCl2, and 10 glucose. In experiments examining K+ and Ca2+ currents, 1 µM TTX was present in the external solution, unless otherwise stated. Standard internal pipette solutions used in whole cell recordings contained (in mM) 140 KCl, 0.4 CaCl2, 1 MgCl2, 20 HEPES, 1 EGTA, 5 MgATP, and 0.3 NaGTP. For recording Ca2+ currents the internal pipette solution was composed of (in mM) 125 CsCl2, 4.5 MgCl2, 10 HEPES, 9 EGTA, 5 MgATP, and 0.3 Tris · GTP. All solutions were maintained at pH 7.3-7.4, and osmolarity of solutions was 324-329 mosM. Ca2+ concentration was calculated using a software program based on the algorithm of Goldstein (11). Free Ca2+ in the standard pipette solution was estimated at 100 nM, and in the 125 mM CsCl pipette solution it was <20 nM.

Chemicals. All drugs and chemicals were obtained from Sigma Chemical (Mississauga, ON, Canada), except PTX, neurokinin A (NKA), and neurokinin B (NKB), which were obtained from Rose Scientific (Edmonton, AB, Canada) and Calbiochem (San Diego, CA).

Electrophysiological recording techniques. Membrane potential (Vm) and currents were recorded using standard whole cell patch-clamp recording procedures (12). Currents were recorded with an Axopatch 1-D amplifier (Axon Instruments, Foster City, CA), filtered with a four-pole low-pass Bessel filter (3 dB at 1 kHz), and digitized at a sampling frequency of 5 kHz. Micropipettes were prepared from borosilicate glass (Sutter Instruments, Novato, CA) using a two-stage vertical electrode puller (model PP83, Narishige, Tokyo, Japan). Pipette resistances were 2-3 MOmega when filled with standard electrophysiological recording solutions. The tips of the electrodes were coated with beeswax to reduce capacitance. Voltage commands and acquisition of membrane current were accomplished using pCLAMP software (Axon Instruments). Except where indicated, leak and capacitance subtraction were routinely employed. Series resistance compensation (90%) was used in all recordings. Liquid junction potentials (LJP) between the bath and patch-clamp electrode were measured experimentally and determined as the potential of the bath solution with respect to the pipette solution (2). For whole cell recording, the Vm of the cell was then calculated as Vm = Vp - LJP, where Vm is corrected membrane potential and Vp is pipette potential. The LJP was 3 mV for the standard internal and external solutions used to record K+ currents and was not corrected for in the data shown. For solutions used to record Ca2+ currents, the LJP was 11 mV and Vm was corrected in the current-voltage (I-V) plots shown. Values for cell capacitance and series resistance were obtained from the amplifier. Series resistance was always <10 MOmega . Current and voltage signals were stored on computer disk as well as on videotape with the aid of a digital data converter (Medical Systems, Greenvale, NY).

All experiments were conducted at room temperature (20-22°C). Values are means ± SE. Student's unpaired t-test was used to compare differences between data groups unless otherwise noted. Differences between groups were considered significant when P < 0.05.

    RESULTS
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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Membrane properties of SG neurons. Details of cell morphology, survival, and the neuropeptide content of adult guinea pig SG neurons grown in culture for up to 3 mo have been described previously (18). The average resting Vm of cultured (1-3 days) SG neurons determined under current-clamp conditions was -49 ± 2 mV (n = 40). Cell capacitance averaged 42 ± 2 pF (n = 114). Input resistance was 577 ± 212 MOmega (n = 5, range 52-1,350 MOmega ). These values are similar to mean values described for dissociated rat SCG neurons and rabbit celiac ganglion neurons (1).

Injection of depolarizing current under current-clamp conditions elicited a fast overshooting AP in SG neurons that showed adaptation (a slow decrease in frequency of AP elicited by maintained depolarization; Fig. 1A). Previous investigations of neurons from isolated intact rat and guinea pig SG and from cultured SG neurons have demonstrated that, in response to sustained depolarization, the majority of neurons fire phasically (show adaptation), whereas a smaller proportion show little or no adaptation and fire tonically (18, 25). Although we did not investigate firing properties in detail in isolated cultured guinea pig SG neurons, we found that ~80% of neurons (32 of 40) from which APs were recorded could best be described as phasic (Fig. 1A); the remaining 20% (8 of 40) exhibited tonic properties (data not shown).


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Fig. 1.   Action potential (AP) generation and firing properties of stellate ganglion (SG) neurons. APs were recorded in control recording solution and after addition of 1 µM TTX (A), 1 mM tetraethylammonium chloride (TEA, B), or 0.2 mM Cd2+ (C). AP traces have been superimposed for comparison. Resting membrane potential is indicated at left of each trace and by dashed line. Presence of drug.

The minimum current required to generate an AP in 22 neurons examined was 20 ± 2 pA. The average AP amplitude, measured from the resting Vm to the peak of the AP, was 79 ± 6 mV (n = 38); the peak afterhyperpolarization (AHP) amplitude was -14 ± 1 mV (n = 34); the AHP duration (measured at half-maximal AHP amplitude) was 42 ± 8 ms (n = 27), and the AP duration measured at resting Vm and at 0 mV was 20 ± 3 (n = 24) and 5 ± 0.3 ms (n = 36), respectively. These values are comparable to those reported for neurons in in vitro rat SG and SCG preparations (1, 25). The amplitude of the APs generated by depolarizing current injection was diminished by exposure to 1 µM TTX (Fig. 1A, n = 4). For the cell shown in Fig. 1B, when 1 mM TEA was added to the superfusate the resting Vm depolarized by 2 mV, the AP duration increased by 13%, and the AHP amplitude was reduced by 41%. Similar effects were observed in two other cells exposed to TEA and are consistent with block of voltage-dependent K+ current. Exposure to the Ca2+ channel blocker Cd2+ (0.2 mM) depolarized the Vm (11 ± 5 mV) in four of seven neurons sampled, whereas in the remaining three neurons, Cd2+ produced no effect or a slight hyperpolarization (1-5 mV). However, in all neurons examined, Cd2+ consistently decreased the AHP amplitude and duration by 43 ± 13 and 25 ± 2% (n = 7), respectively (Fig. 1C), suggesting the contribution of a Ca2+-activated K+ current to AP repolarization.

Actions of SP on Vm and AHP in SG neurons. SP (500 nM) was applied to individual SG neurons by a single pressure ejection from a glass pipette with its tip positioned ~50 µm from the cell. Application of 500 nM SP produced a small depolarization (7 ± 3 mV) of the Vm in seven of seven neurons tested, in which the mean resting Vm was -50 ± 2 mV (Fig. 2Aa). Pressure application of standard external solution alone did not evoke a response in SG neurons. However, when neurons were current clamped to more depolarized potentials of -30 mV, a second SP application produced a repeatable depolarization of 16 ± 5 mV (n = 7; Fig. 2, Ab and Ac), which was associated with a 27 ± 8% (n = 7) decrease in membrane conductance. In four neurons current clamped at potentials of -30 mV, an initial pressure application of SP evoked a 25 ± 5 mV depolarization associated with a 42 ± 8% decrease in membrane conductance. When these same four neurons were superfused with 0.2 mM Cd2+, the SP-evoked depolarization and conductance decrease were significantly less than values observed with SP alone (P < 0.01, Student's paired t-test), with SP now producing a mean depolarization of only 18 ± 5 mV accompanied by a 19 ± 9% decrease in conductance (Fig. 2Ad).


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Fig. 2.   Effects of substance P (SP) and Cd2+ on membrane properties of cultured SG neurons. A: membrane depolarization measured at -50 mV (a) and -30 mV (b and c) in same neuron in response to sequential 10-s pressure applications of 500 nM SP; in presence of 0.2 mM Cd2+, depolarizing effects of 500 nM SP are reduced (d). B and C: decrease in AP afterhyperolarization (AHP) induced by 500 nM SP in another neuron in which membrane potential was continuously clamped at resting membrane potential (B); in presence of 0.2 mM Cd2+, effects of 500 nM SP on AHP are attenuated (C). Resting membrane potential is indicated at left of each trace and by dashed line.

The effect of SP application on depolarization-elicited APs was examined in Fig. 2B. Pressure application of 500 nM SP decreased the AHP amplitude from -14.5 to -9 mV and decreased the AHP duration from 35 to 28 ms, with an increase in the AP duration (measured at the resting Vm) from 11 to 14 ms. In six other neurons, SP produced a mean decrease in AHP amplitude of 54 ± 15% and reduced the time to one-half AHP inactivation by 59 ± 13% (n = 6). Subsequent application of 500 nM SP in the presence of Cd2+ in the neuron shown in Fig. 2C and three other neurons failed to significantly affect the AHP.

Thus the depolarizing actions of SP on Vm, which are associated with a decrease in the total membrane conductance and the inhibition of AHP in SG neurons, are consistent with inhibition of K+ current. Because the actions of SP on Vm and AHP were reduced in the presence of Cd2+, which blocks voltage-dependent Ca2+ influx, this further suggests that the actions of SP on SG neurons may include inhibition of IK(Ca).

Actions of SP on whole cell K+ currents in SG neurons. Figure 3 illustrates representative whole cell currents recorded in guinea pig SG neurons using standard recording solutions. The protocol shown in Fig. 3 consisted of 500-ms depolarizations from holding potentials (Vh) of -100 or -35 mV followed by test potential steps from -40 to +60 mV in 20-mV increments. In SG neurons, step depolarizations from a Vh of -100 mV evoked a transient outward current followed by a sustained component (Fig. 3Aa). Depolarization of Vh to -35 mV inactivated the transient outward current component, leaving the sustained component intact (Fig. 3Ab). Figure 3B shows the I-V relationship for the peak outward currents recorded at Vh of -100 and -35 mV.


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Fig. 3.   Whole cell K+ currents in a cultured SG neuron. A: representative currents elicited by a series of step depolarizations from -40 to +60 mV from a holding potential (Vh) of -100 mV (a) or -35 mV (b). B: current-voltage (I-V) relationships for peak outward currents measured in neuron shown in A over a full range of voltage potentials from -100 to +60 mV from Vh = -100 mV (black-square) or -35 mV (bullet ). C: conductance (g)-voltage curve for transient outward current. Conductance was obtained by subtracting currents measured from Vh = -35 mV from currents measured from Vh = -100 mV and calculated according to Eq. 1, with conductance expressed as a percentage of maximum conductance (gmax) measured at 0 mV. Inset: representative subtracted currents measured at -20, 0, and +20 mV.

The K+ selectivity of the transient outward current component was confirmed by examination of current tails, obtained by stepping the Vm to potentials negative and positive to the Vh after 10-ms step depolarizations to +10 mV (data not shown). Outward current tails reversed at a Vm of -71.0 ± 5.0 mV [n = 14, calculated equilibrium potential for outward K+ current (EK) = -84 mV] in standard recording solutions. The reversal potential of the tails shifted positively to -48.0 ± 7.0 mV (n = 3, calculated EK = -41.0 mV) and -24.0 ± 1.0 mV (n = 4, calculated EK = -26.0 mV) when the external K+ concentration was increased to 20 and 50 mM, respectively. This shift of 47 mV per 10-fold change in extracellular K+ concentration approaches the theoretical value of 58 mV predicted by the Nernst equation.

Figure 3C shows the conductance-voltage plot for the peak transient outward current, obtained by subtracting the whole cell currents activated by step potentials of -100 to +60 mV in 20-mV increments from Vh of -35 mV from currents activated from Vh of -100 mV. Figure 3C (inset) shows representative subtracted current traces elicited with step depolarizations to -20, 0, and +20 mV. Conductance was calculated as follows
<IT>g</IT> = [<IT> I</IT><SUB>p(−100)</SUB> − <IT>I</IT><SUB>p(−35)</SUB> ] / (<IT>V</IT> − <IT>E</IT><SUB>K</SUB>) (1)
where g is the transient outward K+ conductance, Ip(-100) is the peak outward current measured from a Vh of -100 mV, and Ip(-35) is the peak outward current measured from a Vh of -35 mV. V is the membrane potential, and EK is the equilibrium potential for outward K+ currents measured in SG neurons (see above). The transient K+ conductance activated at a Vm of -50 mV, and the conductance increased with incremental depolarization to 0 mV and then decreased. The decrease in conductance at potentials positive to 0 mV primarily reflects inactivation of the transient current (Fig. 3C, inset) but may also reflect a small reduction in IK(ca), resulting from Ca2+ channel inactivation at the depolarized Vh of -35 mV (7, 30, 31).

In mammalian sympathetic neurons, the voltage-gated K+ channels that mediate IA exhibit greater sensitivity to 4-aminopyridine (4-AP) than do other K+ currents (3). Figure 4A shows representative current recordings in an SG neuron. The neuron was held at a Vh of -60 mV, and 500-ms duration steps from potentials of -100 to +20 mV were applied in 20-mV increments. The outward current evoked by depolarization from a Vh of -60 mV consisted of an initial transient component and a sustained current component. Both components of the outward current were reduced by 4-AP. However, 4-AP was more selective for the transient current in guinea pig SG neurons, and 2 mM 4-AP essentially eliminated the transient outward current component over the Vm range of -50 to -20 mV (those Vm where the transient current activates in isolation from the sustained current). The I-V relationship shown in Fig. 4B was constructed from the peak current traces shown in Fig. 4A and demonstrates the reduction in transient K+ current in the presence of 2 mM 4-AP.


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Fig. 4.   Pharmacological block of outward K+ currents in SG neurons. A: currents elicited by a series of step depolarizations to +20 mV from Vh = -100 mV recorded in absence (control) and presence of 2 mM 4-aminopyridine (4-AP). B: I-V relationships for peak component of outward K+ current measured from current traces shown in A () in absence (control, black-square) and presence of 4-AP (bullet ). C: whole cell currents elicited by a series of step depolarizations to +140 mV from Vh = -100 mV in absence (control) and presence of 0.2 mM Cd2+. D: I-V relationships for sustained outward current component measured from traces shown in C () in absence (control, black-square) and presence of 0.2 mM Cd2+ (black-triangle). Cd2+-sensitive current (bullet ) was obtained by subtracting current records measured in presence of Cd2+ from control currents.

Figure 4C shows current recordings obtained from a representative SG neuron in the presence and absence of the Ca2+ channel blocker Cd2+. The neuron was stepped for 500 ms from a Vh of -100 mV to potentials of +140 mV in 20-mV increments. Depolarization of Vm in SG neurons elicited sustained outward K+ current, the amplitude of which showed some decline at potentials positive to +80 mV. The I-V relationship (Fig. 4D) obtained for the current traces in Fig. 4C demonstrates that in the presence of 0.2 mM Cd2+ the sustained outward current was reduced at all Vm positive to -30 mV. The Cd2+ difference current was obtained by subtracting currents recorded in the presence of Cd2+ from control currents. The Cd2+-sensitive current activated around -30 mV and increased with depolarization to +75 mV, which approaches the calculated equilibrium potential for Ca2+ current (+125 mV) for these neurons under the recording conditions used, then the current declined. In 21 neurons tested, 0.2 mM Cd2+ reduced the outward current by 35 ± 6 and 46 ± 5% at 0 and +60 mV, respectively. In four other neurons exposed to nominally Ca2+-free extracellular solution, the outward K+ current was reduced by 41 ± 11% at +60 mV, thus indicating that ~30-50% of IK activated at depolarized potentials in SG neurons may be due to IK(Ca).

Actions of SP on IK in SG neurons. Figure 5 shows current recordings from an SG neuron before and during a 30-s pressure application of SP measured at two different Vh. The current records in Fig. 5Aa demonstrate the lack of sensitivity of IK to SP. Current records were obtained from a neuron at a Vh of -100 mV, and the Vm was stepped in 20-mV increments from -100 to +60 mV. Control recordings indicate that transient and sustained IK are activated by depolarization in this neuron (Fig. 5Aa, top traces). Application of 500 nM SP reduced the sustained component of IK but did not appear to affect the transient component of outward conductance (Fig. 5Aa, bottom traces). The I-V relationship for the peak IK recorded in the presence and absence of 500 nM SP is shown in Fig. 5B. At Vm where the transient component of IK was activated in relative isolation from the sustained component (-50 to -30 mV), SP had little effect. Depolarizing Vh to -30 mV in the same neuron produced a voltage-dependent inactivation of the transient component of IK yet left the sustained IK relatively unaffected (Fig. 5Ab, top traces). Application of 500 nM SP reduced IK (Fig. 5Ab, bottom traces). The I-V relationship shown in Fig. 5C for current measured at the end of the voltage pulse demonstrates that SP now reduced IK over the range of potentials (-30 to +60 mV) at which sustained IK would be activated. For the cell shown in Fig. 5, the inhibition of IK, measured at +60 mV, by SP was greater at Vh of -100 mV (31%) than at Vh of -30 mV (20%) and may reflect some inactivation of Ca2+ and K+ channels at depolarized potentials (1, 30, 42).


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Fig. 5.   Inhibition of outward K+ current (IK) by SP. A: IK elicited by a series of step depolarizations to +60 mV from Vh = -100 mV (a) or -30 mV (b) recorded in absence (control) and presence of 500 nM SP. B and C: I-V relationships for current records shown in A measured for peak (B; ) and sustained (C; #) components of IK in absence (squares) and presence (circles) of 500 nM SP.

Figure 6A shows a dose-response curve for inhibition of IK at +60 mV by SP. IK was measured at the end of a 500-ms voltage pulse to +60 mV in cells held at Vh of -60 mV. SP at 5 nM had little effect on IK, with maximal inhibition obtained at 500 nM SP. IK was reduced 29 ± 5 and 33 ± 4% (n = 31) by 500 nM SP at 0 and +60 mV, respectively.


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Fig. 6.   SP inhibits IK through interaction with NK1 tachykinin receptors. A: concentration-response curves for inhibition of IK by SP. [SP], SP concentration. Each point is mean; error bars, SE; numbers in parentheses, number of cells tested. B: SP-induced inhibition of IK is attenuated in presence of NK1- selective antagonist CGP-49823 (1 µM). Bars represent mean inhibition of IK by SP in neurons incubated in absence and presence of 1.0 and 0.25 µM CGP-49823; error bars, SE. C: mean inhibition of IK by 500 nM SP, neurokinin A (NKA), and neurokinin B (NKB); error bars, SE. NKA and NKB produced significantly less inhibition of IK than SP: * P < 0.05, ** P < 0.01 compared with SP. Currents in B and C were measured at end of 500-ms step depolarization to +60 mV from Vh = -60 mV.

SP inhibits IK through an NK1 tachykinin receptor. The receptors for SP belong to the tachykinin receptor family and include receptors classified as NK1, NK2, and NK3. The preferred endogenous ligands for these receptor types are SP, NKA (substance K), and NKB, respectively (22). We investigated which receptor type might be involved in SP's inhibition of IK in SG neurons by using the nonpeptide NK1 selective antagonist CGP-49823 (33). Figure 6B summarizes the effects of CGP-49823 (0.25 and 1 µM) on the response to 500 nM SP. In the absence of the antagonist, SP reduced IK by 44 ± 8% (n = 11, see also Fig. 6A). However, when neurons were exposed to 1 µM CGP-49823, the inhibition of IK by SP was reduced to 3 ± 1.5% (n = 5). At 0.25 µM, CGP-49823 did not significantly affect SP's ability to inhibit IK (24 ± 12%, n = 3, P > 0.05).

We also compared the effects of the agonists SP, NKA, and NKB on the inhibition of IK in guinea pig SG neurons. The potency order has been reported to be SP >>  NKA > NKB for the NK1 receptor, NKA > NKB >>  SP for the NK2 receptor, and NKB > NKA > SP for the NK3 receptor (22, 35). Figure 6C shows the mean inhibition of IK produced by 500 nM SP, NKA, or NKB in 27 separate cells stepped to +60 mV for 500 ms from a Vh of -60 mV. Whereas inhibition by SP was 44 ± 8.0% (n = 11), NKA and NKB reduced IK by only 6.0 ± 1.0% (n = 8) and 16.0 ± 4.0% (n = 8), respectively (P < 0.1 and P < 0.05 vs. control). These data indicate that SP effects on IK are mediated via NK1 receptors, since the potency order for the inhibition of IK was SP >>  NKA >=  NKB.

Actions of SP on IK(Ca) in SG neurons. The inhibition of IK by SP was significantly diminished in neurons exposed to Cd2+. Figure 7A shows current traces recorded before and after SP application in a neuron superfused with standard extracellular recording solution and subsequently with solution containing 0.2 mM Cd2+. Depolarizing voltage steps to +60 mV were applied from a Vh of -100 mV for 500 ms. In the presence of Cd2+, the inhibitory actions of SP on IK were reduced.


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Fig. 7.   Effects of SP on Ca2+-activated K+ current [IK(Ca)]. A: outward current traces elicited by a 500-ms depolarizing pulse to +60 mV from Vh = -100 mV in an SG neuron before (control) and after a 30-s pressure application of 500 nM SP (a); in same neuron superfused with 0.2 mM Cd2+, SP has no effect (b). B: mean inhibition of IK by SP (500 nM) in absence and presence of 0.2 mM Cd+2 and 10 µM omega -conotoxin (CgTx) in external recording solution; error bars, SE. IK was measured at end of 500-ms voltage step to 0 (open bars) or +60 mV (hatched bars) from Vh = -60 mV. * P < 0.05, ** P < 0.01 compared with inhibition with SP in absence of Cd2+ or omega -conotoxin.

Figure 7B represents the mean inhibition of IK by 500 nM SP in the presence of 0.2 mM Cd2+ and 10 µM omega -conotoxin. SG neurons were held at a Vh of -60 or -100 mV and stepped to 0 and +60 mV for 500 ms. IK was measured at the end of the voltage pulse. Under control conditions, SP reduced IK by 34 ± 6 and 37 ± 5.0% at 0 and +60 mV, respectively (n = 15); however, when the neurons were superfused with 0.2 mM Cd2+, IK was reduced by only 8 ± 2 and 1.4 ± 0.9% (n = 8), respectively (P < 0.01 and P < 0.05 vs. control). Similarly, in the presence of omega -conotoxin, inhibition of IK by SP at 0 and +60 mV was only 12 ± 6 and 3.0 ± 3.0% (n = 4).

Actions of SP on IK are mediated by a PTX-insensitive G protein. The involvement of G proteins in the signaling pathway of SP is well established (14). To confirm that SP modulation of IK is mediated through a G protein-coupled pathway in SG neurons, we compared cells dialyzed with a GTP-free pipette solution containing 2 mM guanosine 5'-O-(2-thiodiphosphate) (GDPbeta S), which is an antagonist of G protein activation, with results obtained using standard pipette solution (0.3 mM GTP) (16, 35). Neurons were dialyzed for at least 10 min before pressure application of 500 nM SP. Figure 8A summarizes the effects of GDPbeta S dialysis on the responsiveness of SG neurons to SP. SP inhibited IK (measured at the end of a 500-ms voltage step to +60 mV from Vh of -60 mV) by only 9.0 ± 4.0% (n = 5) in neurons dialyzed with 2 mM GDPbeta S compared with 33 ± 4.0% (n = 31) in control cells dialyzed with GTP (Fig. 8A). These data confirm that the SP-mediated inhibition of IK is via a G protein-coupled pathway. To identify the type of G protein involved in SP-mediated inhibition of IK, we incubated SG neurons with PTX. PTX inactivates G proteins of the Gi, Gz, or Go class by catalyzing NAD-dependent ADP ribosylation of the alpha -subunit (24). Overnight (24-h) treatment with PTX (500 ng/ml) was ineffective in blocking SP inhibition of IK (40 ± 8.0%, n = 5; Fig. 8B) compared with control untreated cells (43 ± 9%, n = 6). Thus we conclude that the G protein(s) involved in SP modulation of IK in SG neurons is not of the Gi, Gz, or Go class.


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Fig. 8.   Inhibition of IK by SP is mediated by a pertussis toxin (PTX)-insensitive G protein. A: inclusion of guanosine 5'-O-(2-thiodiphosphate) (GDPbeta S) in pipette attenuates SP response. Bars represent mean inhibition of IK by 500 nM SP with standard pipette solution (0.3 mM GTP) or with 2 mM GDPbeta S (0 GTP); error bars, SE. In all experiments, 10 min were allowed after break in and before recording to allow for sufficient guanine nucleotide dialysis. B: inhibition of IK by SP is PTX insensitive. Bars represent mean inhibition of steady-state IK at +60 mV by SP; error bars, SE. Cells were cultured overnight with 500 ng/ml PTX. Current inhibition in control neurons was recorded with standard recording solutions. * P < 0.05.

Actions of SP on Ca2+ channel currents in SG neurons. The reduction of the inhibitory effect of SP on IK in SG neurons pretreated with Cd2+ or the high-voltage-activated (HVA) N-type Ca2+ channel blocker omega -conotoxin (40) suggests that SP may act to inhibit IK(Ca) in SG neurons via the reduction of voltage-dependent Ca2+ influx. SP has been reported to act on NK1 receptors inhibiting N-type Ca2+ channels in dissociated rat SCG neurons (35). Therefore, we investigated the effects of SP on Ca2+ channel currents in SG neurons. Ion substitutions used to isolate Ca2+ channel currents are described in MATERIALS AND METHODS. In K+- and Na+-free solutions with external 5 mM Ba2+ as the current carrier, all K+ and Na+ currents were blocked and on membrane depolarization an inward current (IBa) was observed. Figure 9A shows inward IBa recorded after step depolarization to +10 mV from a Vh of -70 mV. The inward current in this neuron was reduced by >88% by 0.2 mM Cd2+. Similar results were observed in all cells examined, with a mean reduction in IBa amplitude measured at 0 mV by Cd2+ of 96.0 ± 6.0% (n = 5). Figure 9B shows IBa recorded after a step depolarization to 0 mV in the absence and presence of 10 µM omega -conotoxin. In the presence of omega -conotoxin, >95% (97 ± 1.5, n = 9) of the inward current at 0 mV was inhibited and showed no recovery during a 15-min postdrug recovery period. In five other cells, IBa at 0 mV was inhibited 96 ± 3.0% after a 15-min exposure to omega -conotoxin. Subsequent application of 0.2 mM Cd2+ to these cells resulted in no further reduction in IBa in four cells and an 11% reduction in one cell, suggesting that current through omega -conotoxin-sensitive Ca2+ channels accounts for most of the Ca2+ channel current in SG neurons under the conditions used in this study. Figure 9D shows the I-V plot for the omega -conotoxin-sensitive current. Inward current, from a Vh of -90 mV, activates at around -30 mV, with peak inward current occurring around a potential of -10 mV. However, voltage steps from -90 mV to Vm positive to +30 mV elicited outward omega -conotoxin-sensitive currents, which may represent Cs+ moving out of the cell via omega -conotoxin-sensitive Ca2+ channels (7, 8).


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Fig. 9.   Pharmacological block of voltage-dependent Ba2+ currents (IBa) in cultured SG neurons. A: IBa elicited with a step depolarization to +10 mV from Vh = -70 mV in absence (control) and presence of 0.2 mM Cd2+. B and C: superimposed IBa elicited with a step depolarization to 0 mV from Vh = -90 mV in absence (control) and presence of 10 µM omega -conotoxin (B) and 500 nM SP (C). D: I-V relationship for omega -conotoxin-sensitive current obtained by subtracting currents recorded in presence of omega -conotoxin from control currents (neuron in B). E: I-V relationship for SP-sensitive currents obtained by subtracting currents recorded in presence of SP from control currents (neuron in C).

Figure 9C shows IBa recorded at 0 mV in an SG neuron before and during application of 500 nM SP. In this cell, SP decreased the amplitude of IBa by 33%. Similar results were observed in eight cells examined with an average inhibition of IBa by SP of 49 ± 7.7%. The I-V plot in Fig. 9E represents the SP-sensitive inward current measured from peak inward currents recorded in the presence of 500 nM SP. As shown for the omega -conotoxin-sensitive current in Fig. 9B, the inward SP-sensitive current activates at -30 mV, with peak current around 0 mV. These data indicate that IBa in SG neurons is carried primarily via omega -conotoxin-sensitive Ca2+ channels and that SP inhibition of Ca2+ current may account for the observed SP-induced decrease in IK(Ca).

    DISCUSSION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

These results describe the cellular mechanisms by which the neuropeptide SP modulates ionic conductances in adult mammalian sympathetic neurons. We have used patch-clamp recording to investigate the membrane properties and whole cell K+ and Ca2+ currents in guinea pig SG neurons. We have not investigated the voltage-dependent characteristics of the TTX-dependent Na+ current that was observed in these SG neurons. Details of K+ and Ca2+ currents recorded in SG neurons are discussed below and compared with ionic conductances described for sympathetic neurons of other vertebrate ganglia and species.

We also report that SP depolarized guinea pig SG neurons, decreased membrane conductance at potentials positive to resting Vm, and inhibited the AP AHP. These actions of SP were reduced by the Ca2+ channel blocker Cd2+ and are consistent with inhibition of a Ca2+-activated K+ conductance. Voltage-clamp analysis of currents in SG neurons revealed that SP inhibited at least two ionic conductances: a Ca2+-sensitive K+ conductance and an inward Ca2+ conductance. Evidence for the modulation of these currents by SP and the results of an investigation of the molecular signaling pathways underlying the action of SP on IK(Ca) are discussed.

Voltage-dependent K+ and Ca2+ currents in guinea pig SG neurons: comparison with other autonomic neurons. The outward current in guinea pig SG neurons was selective for K+ and consisted of several distinct voltage-dependent K+ conductances. These conductances were identified on the basis of voltage dependence and pharmacological blockade and consisted of a transient outward K+ conductance, which resembled the A-type conductance described in mammalian autonomic neurons (3), and a delayed rectifier outward K+ current consisting of Ca2+-activated and Ca2+-insensitive components.

In guinea pig SG neurons the transient outward K+ current (IA) demonstrated voltage-dependent activation and was significantly inactivated at potentials near the measured resting Vm. This current typically activated within 1 ms of step depolarizations to Vm positive to -50 mV and reached a maximum amplitude within 10 ms. Peak conductance was followed by a rapid phase of current decay. The transient outward conductance was maximal after hyperpolarization and decreased sharply as the membrane voltage, before the depolarizing steps, became less negative. The voltage dependence and kinetics of the IA in guinea pig SG neurons resembled the IA described in other mammalian sympathetic neurons (1, 3, 6). Consistent with the pharmacological properties observed for IA in neurons of other mammalian sympathetic ganglia, IA in guinea pig SG neurons was also sensitive to 4-AP.

The predominant current expressed in all guinea pig SG neurons studied was a sustained outward K+ current. This sustained outward current activated with a brief delay after the onset of membrane depolarization to potentials positive to -30 mV and persisted while the depolarization was maintained. The voltage dependence and kinetics of the sustained K+ current in guinea pig SG neurons closely resembled delayed rectifier K+ currents described in neurons from several different sympathetic ganglia, including the rat SCG (1, 3, 34) and guinea pig enteric ganglia (41). The delayed rectifier outward current in guinea pig SG neurons was reversibly decreased by the external application of 4-AP and abolished by internal dialysis with Cs+. This is consistent with the pharmacological properties described for delayed rectifier K+ currents in neurons of other mammalian autonomic ganglia (1, 41, 42). Recent voltage-clamp studies of mammalian sympathetic neurons (1, 19), together with data from other neuronal types (21, 42), have provided support for the existence of several classes of Ca2+-dependent K+ currents contributing to AP repolarization and spike AHP. In the present study we observed a reduction of a portion of the sustained outward K+ current after superfusion with Ca2+ channel blockers or nominally Ca2+-free solution. Our data indicate that ~35-50% of the delayed rectifier K+ current in guinea pig SG neurons can be attributed to the activation of Ca2+-activated K+ channels.

In addition to the IK(Ca), we occasionally recorded a small noninactivating outward current in guinea pig SG neurons that exhibited voltage- and time-dependent properties similar to the M current described in several other sympathetic neurons, including the SCG neuron (5, 23), and guinea pig inferior mesenteric ganglia (10). Because of the infrequent occurrence (<15% of neurons) and the small amplitude of current relaxations (10 ± 5.6 pA, n = 15 with voltage steps from Vh = -30 to -70 mV) of M-like current in cultured guinea pig SG neurons, it is unlikely to make a significant contribution to the actions of SP described in this study. In support of this, the difficulty in studying the M current in sympathetic neurons has been reported previously in neurons where the M current is evident using intracellular recording techniques (41) but was not observed in the same cell type under whole cell patch-clamp recording techniques. This may reflect washout of the cytosolic constituents that are required for the regulation of the M current, a common unavoidable problem in the use of the whole cell patch-clamp configuration (12).

We have also identified an inward Ca2+ current in cultured SG neurons. Guinea pig SG neurons exhibited a voltage-dependent Ca2+ current that activated on step depolarization to voltages more positive than -30 mV and was abolished by 0.2 mM Cd2+ or 10 µM omega -conotoxin. This current resembles the descriptions of HVA, omega -conotoxin-sensitive Ca2+ currents reported in a number of mammalian autonomic neurons, including the rat SCG neurons (30, 31, 34, 40) and the rat myenteric and guinea pig submucosal neurons (15, 37). In mammalian sympathetic neurons the major component (85-90%) of whole cell inward Ca2+ current has been shown to be carried by dihydropyridine-insensitive, high-threshold N-type Ca2+ channels (30, 31, 34). The remainder of the conductance has been attributed to current carried through dihydropyridine-sensitive L-type Ca2+ channels. The block of >95% of the Ca2+ current by omega -conotoxin in guinea pig SG neurons and the voltage dependence of the omega -conotoxin-sensitive current indicate that the whole cell Ca2+ current observed in these neurons is due primarily to the activation of a high-threshold N-type Ca2+ conductance.

Actions of SP on voltage-dependent K+ and Ca2+ currents in guinea pig SG neurons. A variety of peptides including SP, somatostatin, luteinizing hormone-releasing hormone, angiotensin II, atrial natriuretic factor, and neuropeptide Y have been demonstrated to modulate neuronal ionic conductances (4, 15, 18, 26, 33, 35-37, 41). In light of the potential importance of such modulation to neuronal excitability, much attention has been placed on understanding the underlying mechanisms of the actions of these neuropeptides.

Under our recording conditions, SP reversibly depolarized Vm and decreased membrane conductance. These actions are consistent with inhibition of an outward K+ conductance by SP in SG neurons. In the presence of the Ca2+ channel blocker Cd2+, a reduction in SP's ability to elicit membrane depolarization and a conductance decrease were observed, suggesting that SP may exert its effects, in part, via inhibition of IK(Ca). Our current-clamp studies also revealed a residual depolarization and small conductance decrease still elicited by SP in the presence of 0.2 mM Cd2+, which may reflect an incomplete block of IK(Ca) by Cd2+ in those neurons tested and/or actions on K+ currents distinct from the IK(Ca). For example, SP inhibition of a background (leak) K+ conductance has been described in other autonomic neurons, including guinea pig celiac and submucosal neurons (37, 39, 41).

Our subsequent voltage-clamp studies focused on IK(Ca) and confirmed that the actions of SP on outward K+ current were primarily mediated via inhibition of IK(Ca), since SP's inhibitory actions measured at 0 and +60 mV were reduced in the presence of 0.2 mM Cd2+ or the N-type Ca2+ channel blocker omega -conotoxin (10 µM). There was a slightly greater reduction in SP's inhibitory action on IK(Ca) at more positive potentials in the presence of Ca2+ channel inhibition, which may reflect alterations in the driving force for Ca2+ and decreased Ca2+ availability at these potentials (32). The Ca2+-insensitive component of the sustained outward K+ current, evident in the presence of Cd2+, was not significantly affected by SP application.

The identity of the receptor believed to mediate SP-induced modulation of IK(Ca) in guinea pig SG neurons was investigated. Three tachykinins, SP, NKA, and NKB, each possess a defined order of potency for the three known mammalian tachykinin receptors: NK1, NK2, and NK3 (22, 35). The rank order of potency for inhibition of IK in this study was SP > NKA >=  NKB, which demonstrates an NK1 subtype profile for tachykinin inhibition of IK(Ca) by SP.

We have also examined the effects of SP on the Ca2+ channel current (ICa) in guinea pig SG neurons. Bath application of SP produced an inhibition of ICa similar to that described in frog and rat sympathetic neurons (4, 35). Because <5% of the whole cell ICa in SG neurons is likely to be carried via L-type Ca2+ channels, we did not attempt to determine the effectiveness of SP on L-type currents in isolation. Our data indicate that SP inhibits ~50% of ICa in SG neurons, in which the majority of inward ICa represents activation of omega -conotoxin-sensitive HVA Ca2+ channels. Although these findings suggest that the effects of SP on IK(Ca) may represent a secondary consequence of the inhibition of Ca2+ influx, this does not exclude any additional direct effects of SP on K+ currents.

Transduction mechanisms underlying IK(Ca) inhibition. A series of experiments were designed to further examine the potential signaling pathway underlying SP's actions on IK in guinea pig SG neurons. We expected that the modulation of IK by SP was mediated by G protein(s), and therefore we used GDPbeta S and PTX to test this hypothesis. In the presence of GDPbeta S, a G protein blocker, SP's ability to inhibit IK was significantly diminished, thereby indicating G protein involvement. We found no effect of PTX pretreatment on the ability of SP to inhibit IK in SG neurons, indicating that the receptors responding to SP are not coupled to G proteins of the Gi, Go, and Gz family. These findings are consistent with other reports of receptor-mediated SP actions that are PTX insensitive. These include the inhibition of N-type Ca2+ channels in rat SCG neurons and frog sympathetic neurons (4, 35) and the inhibition of inwardly rectifying K+ channels in the nucleus basalis of the rat forebrain (26), both of which occur through interaction with an NK1 tachykinin receptor.

In summary, this study presents the first description of ionic currents in mammalian SG neurons and demonstrates that SP, acting via NK1 receptors coupled to a PTX-insensitive G protein pathway, may increase excitability in mammalian SG neurons via inhibitory actions on K+ and Ca2+ currents.

    ACKNOWLEDGEMENTS

We thank Dr. P. S. Pennefather for valuable discussions and suggestions, Z. Byczko for excellent technical assistance, and C. Jollimore for editing the manuscript.

    FOOTNOTES

This study was funded by Medical Research Council of Canada Grants MT-13484 to M. E. M. Kelly, MT-4128 to M. Horackova, and MT-11622 to F. M. Smith. F. M. Smith was a Heart and Stroke Foundation of Canada Research Scholar.

Address for reprint requests: M. E. M. Kelly, Dept. of Pharmacology, Sir Charles Tupper Medical Bldg., Dalhousie University, Halifax, NS, Canada B3H 4H7.

Received 31 March 1997; accepted in final form 16 December 1997.

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