5-HT Modulation of Multiple Inward Rectifiers in Motoneurons in Intact Preparations of the Neonatal Rat Spinal Cord

Ole Kjaerulff and Ole Kiehn

Division of Neurophysiology, Department of Medical Physiology, The Panum Institute, University of Copenhagen, DK-2200 Copenhagen, Denmark


    ABSTRACT
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Kjaerulff, Ole and Ole Kiehn. 5-HT Modulation of Multiple Inward Rectifiers in Motoneurons in Intact Preparations of the Neonatal Rat Spinal Cord. J. Neurophysiol. 85: 580-593, 2001. This study introduces novel aspects of inward rectification in neonatal rat spinal motoneurons (MNs) and its modulation by serotonin (5-HT). Whole cell tight-seal recordings were made from MNs in an isolated lumbar spinal cord preparation from rats 1-2 days of age. In voltage clamp, hyperpolarizing step commands were generated from holding potentials of -50 to -40 mV. Discordant with previous reports involving slice preparations, fast inward rectification was commonly expressed and in 44% of the MNs co-existed with a slow inward rectification related to activation of Ih. The fast inward rectification is likely caused by an IKir. Thus it appeared around EK and was sensitive to low concentrations (100-300 µM) of Ba2+ but not to ZD 7288, which blocked Ih. Both IKir and Ih were inhibited by Cs2+ (0.3-1.5 mM). Extracellular addition of 5-HT (10 µM) reduced the instantaneous conductance, most strongly at membrane potentials above EK. Low [Ba2+] prevented the 5-HT-induced instantaneous conductance reduction below, but not that above, EK. This suggests that 5-HT inhibits IKir, but also other instantaneous conductances. The biophysical parameters of Ih were evaluated before and under 5-HT. The maximal Ih conductance, Gmax, was 12 nS, much higher than observed in slice preparations. Gmax was unaffected by 5-HT. In contrast, 5-HT caused a 7-mV depolarizing shift in the activation curve of Ih. Double-exponential fits were generally needed to describe Ih activation. The fast and slow time constants obtained by these fits differed by an order of magnitude. Both time constants were accelerated by 5-HT, the slow time constant to the largest extent. We conclude that spinal neonatal MNs possess multiple forms of inward rectification. Ih may be carried by two spatially segregated channel populations, which differ in kinetics and sensitivity to 5-HT. 5-HT increases MN excitability in several ways, including inhibition of a barium-insensitive leak conductance, inhibition of IKir, and enhancement of Ih. The quantitative characterization of these effects should be useful for further studies seeking to understand how neuromodulation prepares vertebrate MNs for concerted behaviors such as locomotor activity.


    INTRODUCTION
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

The discharge pattern of motoneurons (MNs) in the spinal cord depends on the characteristic of each of a number of ionic currents selectively channeled through membrane proteins (Kiehn 1991b; Rekling et al. 2000; Schwindt and Crill 1984). A subset of currents preferably flow at hyperpolarized membrane potentials and are therefore known as inward rectifiers (Hille 1992). Dependent on the speed of current activation, inward rectification (IR) is seen as a downward bend in either the instantaneous or the steady-state current-voltage (I-V) relationship, or both. The presence of one particular type of inward rectifier causes a slow sag toward the original membrane potential when the cell is hyperpolarized from the resting membrane potential. In spinal cord MNs, Ito and Oshima (1965) originally described this slowly developing inward rectification in the cat. Later studies in a slice preparation of the neonatal rat spinal cord suggested that the underlying current is a slow, noninactivating inward cation current with a reversal potential more positive than rest (Takahashi 1990a). This current corresponds to the hyperpolarization-activated inward mixed cation current, or Ih, found in many vertebrate and invertebrate neurons (Pape 1996). The slow activation of Ih explains the time dependency of the sag. Moreover, since Ih also deactivates slowly when the hyperpolarization is released, this current contributes to the formation of a long-lasting rebound excitation. Another form of inward rectification is found in various types of excitable cells including neurons. This "instantaneous" current, IKir, is carried by potassium ions (Constanti and Galvan 1983; Katz 1949; Nichols and Lopatin 1997; Standen and Stanfield 1979; Travagli and Gillis 1994; Williams et al. 1997; Yamoah et al. 1998). IKir, as well as Ih, typically contribute to the resting membrane potential. This is one important reason why inward rectifiers play essential roles for the excitability and response properties of nerve cells. Moreover, the contribution of both IKir and Ih to the resting membrane potential makes these currents prime targets for neuromodulators. One such neuromodulator is serotonin (5-HT), which is often used to induce locomotion in the isolated spinal cord of the neonatal rat (Cazalets et al. 1992; Kiehn and Kjaerulff 1996; Kjaerulff and Kiehn 1996, 1997). 5-HT strongly excites spinal MNs in the rat (Berger and Takahashi 1990; Kiehn 1991a; Takahashi and Berger 1990; Wang and Dun 1990). A part of this excitation has been ascribed to an enhancement of Ih (Takahashi and Berger 1990). However, the exact mechanism behind the enhancement has not been determined.

We have started to investigate the contribution of inward rectification to the discharge pattern in neonatal rat lumbar MNs during transmitter-induced rhythmic locomotor activity (Kiehn et al. 2000). A complete understanding of how inward rectification contributes to the discharge patterns in neonatal rat lumbar MNs requires knowledge of the biophysical parameters of the underlying currents. Furthermore, earlier studies have generally been performed on MNs located superficially in thin slice preparations (e.g., Takahashi 1990a). Despite the importance of the information obtained under such circumstances, it has hardly been possible to avoid elimination of part of the dendritic arbor. This might lead to important qualitative and quantitative deviations from the membrane current characteristic in the more intact MNs located in whole spinal cords used for locomotor studies.

Our study shows that, in addition to the slowly developing inward rectification caused by activation of Ih, most neonatal rat MNs possess an instantaneous rectifier with kinetics and pharmacology similar to IKir. We show that 5-HT enhances Ih by causing a depolarizing shift in the activation curve. In contrast, the fast inward rectifier IKir is inhibited by 5-HT. In addition, 5-HT appears to inhibit other instantaneous currents, possibly "leak" currents, as well. These effects of 5-HT enhance resting MN excitability and cause a theoretical enhancement of rebound firing and phase-transition during rhythmic motor discharges. Preliminary results from these experiments have been presented in abstract form (Kjaerulff and Kiehn 1998).


    METHODS
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INTRODUCTION
METHODS
RESULTS
DISCUSSION
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Dissection

The procedure for isolating the spinal cord has been described in detail earlier (Kjaerulff and Kiehn 1996, 1997) and is only partially summarized here. Neonatal rat pups (1-2 days old) were anesthetized with ether and quickly decapitated. The spinal cord was isolated and a piece of cord comprising approximately the Th12-S1 segments was placed in a recording chamber perfused with standard Krebs solution containing (in mM) 128 NaCl, 4.69 KCl, 25 NaHCO3, 1.18 KH2PO4, 1.25 MgSO4, 2.52 CaCl2, and 22 glucose, aerated with 5% CO2 in O2. The composition of this extracellular solution is identical to that used in our previous locomotor studies (e.g., Kiehn and Kjaerulff 1996; Kjaerulff and Kiehn 1997) (see INTRODUCTION) and was selected also for the present study to be able to directly relate the findings on the inward rectifier currents to the results of the locomotor experiments.

Recordings

Recordings from MNs were made with patch electrodes pulled from thick-walled borosilicate glass (OD: 1.5 mm; ID: 1.0 mm, Clark Electromedical Instruments, Pangbourne, England) to a final resistance of 4-7 MOmega . Recordings were made in the whole cell configuration (Hamill et al. 1981) using an Axoclamp 2B amplifier (Axon Instruments, Foster City, CA) in the continuous single-electrode voltage-clamp (cSEVC) mode. With maximal phase-advance, it was usually possible to increase the clamp gain to 100 nA/mV (maximal gain). However, the gain was generally kept slightly lower (~90 nA/mV) to prevent fatal oscillations of the clamp circuit induced by changes in the access resistance. pCLAMP (Axon Instruments) was used for data acquisition and off-line current measurements. Current signals were low-pass filtered at 1-2 kHz and digitized at 2.667 kHz.

In most experiments the spinal cord was pinned down with the ventral side up and the electrode lowered blindly into the ventrolateral region of the L4 (occasionally L5) segment through a slit cut in the white matter. In a few cases the ventral part of the cord was isolated (Kjaerulff and Kiehn 1996), pinned down dorsal side up, and the electrode lowered into the motor column via the dorsal cut surface. The pipette electrode solution contained (in mM) 128 potassium gluconate, 4 NaCl, 1 glucose, 10 HEPES, 0.0001 CaCl2, 4 ATP-Mg, and 0.3 GTP-Li. The pH was adjusted to 7.3 with KOH. Recordings were made at room temperature.

Correction of the voltage

In general, the access resistance, Ra, was within 10-30 MOmega . Since the current could reach amplitudes of 1 nA or more, the predicted voltage drop over Ra was not negligible. To compensate for this error, we monitored Ra pertaining to individual voltage steps and corrected the membrane potential off-line using the relation
<IT>V</IT> = <IT>V</IT><SUB>cmd</SUB> − <IT>R</IT><SUB>a</SUB><IT>I</IT> (1)
where V is the corrected membrane potential, Vcmd is the command potential, and I is the current (Finkel and Redman 1984). Equation 1 implies that the changes in voltage-sensitive currents evoked by the step command will be mirrored by changes in V. This fluctuation in the effective command was generally below 10 mV, and hence it was ignored in the data analysis. In the relevant figures, however, rather than the ideal constant step command, we display the trajectories of the membrane potential calculated using Eq. 1, since this is expected to more accurately represent the effective command.

JUNCTION POTENTIAL. Voltages were not corrected for the liquid junction potential (Neher 1992), which was within the range 6-8 mV (pipette interior negative) with the intracellular and various extracellular solutions used in the present experiments. Correcting potentials would lead to more hyperpolarized values than those reported in the text.

Database

Recordings from 138 MNs were included in this study. Cells were identified as MNs when ventral root stimulation through a suction electrode evoked an antidromic action potential. For a MN to be included in the database, the holding current corresponding to a holding potential of -50 mV had to be more positive than 0 pA.

Pharmacological compounds

Serotonin creatine sulfate (5-HT, 10 µM), tetrodotoxin (TTX, 0.2-0.3 µM), tetraethylamminium-chloride (TEA 20-30 mM), and 4-aminopyridine (4-AP, 2-4 mM) were from Sigma (St. Louis, MO). The 5-HT concentration chosen is at the plateau of the dose-response curve for activation of the previously described 5-HT-induced inward current, I5-HT, in neonatal rat MNs (Takahashi and Berger 1990). D,L-2-amino-5-phosphonovaleric acid (APV, 20 µM) and 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 10 µM) were from RBI (Natick, MA) and 4-(N-ethyl-N-phenylamino)-1,2-dimethyl-6-(methylamino) pyrdinium chloride (ZD 7288, 100 µM) from Tocris Cookson (Bristol, UK). In experiments involving the extracellular use of BaCl2 (100-300 µM), KH2PO4 was omitted and MgSO4 replaced with an equimolar concentration of MgCl2.

Statistical analysis

Commercially available software (Statistica; StatSoft, Tulsa, OK) was used to test for differences between the amplitude of the difference current, Iss - Iin, before, during, and after application of 5-HT in the same MNs. Data were transformed by taking the square root of the absolute current amplitudes prior to significance testing (Altman 1991) to conform with the assumptions underlying the statistical model used, i.e., repeated measures ANOVA. This model was also used to evaluate changes in holding current induced by 5-HT in normal medium. Duncans multiple range test was employed for post hoc comparisons.

INSTANTANEOUS I-V RELATIONSHIP. We used a statistical criterion to help decide whether rectification was present in the instantaneous I-V relationship. If the I-V relationship was judged by eye to be linear, this was accepted without further analysis. However, if the I-V curve appeared to bend around a given voltage, Vbend, linear regression was used to determine Gdep and Ghyp, i.e., the average slope conductance in the voltage range more depolarized and hyperpolarized, respectively, than Vbend (see Figs. 3A and 5, A and B, for indications of Vbend, Gdep, and Ghyp). The 97.5% confidence interval for Gdep was then compared with the 97.5% confidence interval for Ghyp. Fast rectification was set to be present if the two confidence intervals did not overlap. The bend in the instantaneous I-V curve was generally sharp enough to permit the identification of Vbend with an uncertainty below ~10 mV.

Pharmacologically induced changes in Gdep, Ghyp, and in fast rectification were analyzed using paired t-tests. Since the distributions of the instantaneous conductance data were positively skewed, data were transformed by taking the logarithm before testing (Altman 1991). Reported summary statistics (mean ± SE) were, however, calculated from the raw data. The level of significance was set to 5%.


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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Generally, experiments were done in the presence of TTX to block the fast Na+ current, INa (Takahashi 1990b). TTX also blocks synaptically mediated indirect effects of 5-HT on MNs caused by spike activation of presynaptic interneurons (Wang and Dun 1990). In most experiments, the glutamate receptor antagonists APV and CNQX were also added to reduce spontaneous synaptic noise.

Current responses in normal medium

LINEAR. In some MNs, when hyperpolarizing voltage steps from a holding potential of -50 mV were generated, the size of the instantaneous current response, Iinst, was proportional to the size of the voltage step (Fig. 1, A and B). In normal medium (with or without TTX/APV/CNQX), such a linear instantaneous I-V relationship was observed in 30 of 72 MNs (41.7%).



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Fig. 1. Variability in fast and slowly developing inward rectification (IR) among spinal neonatal rat motoneurons (MNs). A: current responses (top) evoked by a family of hyperpolarizing voltage steps (bottom) from a holding potential of -50 mV. Capacitive transients related to changes in the voltage command have been blanked. Note instantaneous current () proportional to the voltage step amplitude and the pronounced slowly developing inward current relaxation caused by Ih. Ih approached steady state only after several seconds (open circle ). B: current-voltage (I-V) plots derived from A showing the absence of fast IR (linear, ) and the strong steady-state IR caused by Ih (open circle ). Measurements were taken from A at the time points indicated by the symbols identical to those used for plotting. C and D: different MN showing fast IR () and relatively weak Ih-dependent steady-state IR (open circle ). Holding current, 61 pA in A and B; 71 pA in C and D.

FAST INWARD RECTIFICATION. In a larger fraction of the MNs, however, the Iinst elicited by large hyperpolarizing voltage steps was disproportionally larger than Iinst evoked by smaller hyperpolarizing steps. Thus these MNs showed fast IR (Fig. 1, C and D). Typically, the membrane potential at which the increase in conductance occurred was rather sharply defined, producing an inflection point on the instantaneous I-V relationship at 79.8 ± 1.1 mV (mean ± SE; Vbend, see METHODS). A comparison of the 97.5% confidence interval of the average instantaneous slope conductance at voltages above Vbend, termed Gdep, with that of the conductance, Ghyp, below Vbend confirmed the presence of fast IR in a high number of MNs (35 of 72 MNs, 48.6%).

OUTWARD RECTIFICATION. In relatively few MNs, the Iinst elicited by large hyperpolarizing voltage steps was disproportionally smaller than the Iinst evoked by smaller hyperpolarizing steps (7 of 72 MNs, 9.7%; not shown). Thus fast outward rectification (OR) was also observed, but only in a minority of the MNs. The average Vbend for fast OR was -83.3 ± 2.8 mV.

SLOWLY DEVELOPING INWARD RECTIFICATION, Ih. An inwardly increasing current usually followed the instantaneous current jump. The rate of inward increase was fast initially but leveled off with time (inward relaxation). The steady-state current, Iss, was reached only after several seconds (e.g., Fig. 1, A and C). The activation rate and the amplitude of this slowly developing inward relaxation increased with increasing hyperpolarization. The amplitude increase lead to inward rectification in the steady-state I-V relationship (steady-state IR; Fig. 1, B and D).

The slowly developing inward rectification shares voltage and time dependency with the hyperpolarization-activated cation current, Ih, previously described by Takahashi (1990a), who named it IIR. Here we will use the term Ih. In normal medium, an Ih was observed unambiguously in 65 of the 72 MNs mentioned above (90%). However, the distinctness of Ih and consequently of the steady-state IR could vary considerably (compare in Fig. 1, A with C, and B with D). In current clamp, Ih was seen as a slowly developing, depolarizing sag in the membrane potential in the face of a constant hyperpolarizing current injection (data not shown).

Multiple forms of inward rectification caused by distinct conductances co-exist in MNs

PERSISTENCE OF FAST INWARD RECTIFICATION IN ZD 7288. In roughly half of the MNs, Ih appeared to be the only form of inward rectifying current present, since these cells showed no fast IR (33 of 72 MNs, 45.8%; Fig. 1B). However, fast IR co-existed with the steady-state IR indicative of Ih in a substantial number of MNs (32 of 72 MNs, 44.4%; Fig. 1, C and D). In contrast to Ih, fast IR has not previously been reported to be present in spinal rat MNs. It therefore became important to determine whether the two forms of inward rectification are mediated by different conductances, or whether they are different expressions of the same conductance, e.g., Ih. For this purpose, we employed ZD 7288, an established blocker of Ih (BoSmith et al. 1993; Harris and Constanti 1995; Hughes et al. 1998; Khakh and Henderson 1998; Williams et al. 1997). Figure 2A shows a MN, in which both fast IR and the slowly developing IR indicative of Ih was present in control conditions. ZD 7288 reduced both the instantaneous and the steady-state conductance (Fig. 2B). Moreover, ZD 7288 abolished the slow inward relaxation. In contrast, fast IR persisted (Fig. 2B; Fig. 2C, compare open circle  and ). In current clamp (not shown; see Kiehn et al. 2000) ZD 7288 removed the sag response, again indicating an efficient blockade of Ih. As in voltage clamp, however, fast IR persisted. Similar results were obtained in a total of five MNs (2 in voltage clamp, 3 in current clamp). The fact that ZD 7288 blocked Ih but not fast IR suggests that the fast IR is caused by a different inward rectifier than Ih.



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Fig. 2. The Ih antagonist ZD 7288 blocks slowly developing IR but not fast IR. A and B: current responses (top) to hyperpolarizing voltage steps from -50 mV (bottom) before (A) and during (B) application of ZD 7288 (100 µM). Note that in ZD 7288 Ih was abolished while the fast IR remained, as in control. Holding current, -120 pA in A; -4 pA in B. C: instantaneous I-V plots based on measurements from A and B at the time points indicated by the symbols also used for plotting. Note persistence of fast IR in ZD 7288. Dashed lines were added for better appreciation of the curve bending related to fast IR.

In accordance with the known sensitivity of Ih to Cs2+ (Pape 1996; Takahashi 1990a), the slow inward relaxation under voltage clamp, or the sag under current clamp, were blocked in a concentration-dependent manner by adding CsCl2 to the superfusate (0.3-1.5 mM, n = 7 MNs; data not shown). The fast IR was also strongly affected by Cs2+ (see the following section).

Identity of the fast inward rectifying current

Several of our observations suggest that at least part of the fast IR in spinal neonatal rat MNs is caused by an IKir, i.e., an inward ("anomalous") rectifying current carried by potassium ions (Constanti and Galvan 1983; Hagiwara et al. 1976; Katz 1949; Nichols and Lopatin 1997; Standen and Stanfield 1979; Travagli and Gillis 1994). First, IKir is generally associated with fast or "instantaneous" IR. Second, fast IR in the rat MNs occurred around a Vbend of -80 mV on average; this voltage is close to the K+ equilibrium potential (EK, predicted to be -79 mV with the intra- and extracellular solutions used). This similarity suggests that fast IR, like IKir, is largely K+ dependent. Third, we sometimes observed an apparent inactivation during strong hyperpolarizing steps (Fig. 4). This behavior of IKir has been reported previously in a number of cell types (Biermans et al. 1987; Constanti and Galvan 1983; Hagiwara et al. 1976; Silver and DeCoursey 1990; Yamoah et al. 1998) and has generally been attributed to an external voltage- and time-dependent block by Na+ ions rather than true inactivation of the IKir channels themselves.

EFFECTS OF DIVALENT CATIONS ON FAST IR. If the fast IR in spinal neonatal rat MNs is caused by IKir, it should be sensitive to Cs2+ concentrations in the millimolar range (Benson and Levitan 1983; Constanti and Galvan 1983; Hagiwara et al. 1976; Standen and Stanfield 1979; Travagli and Gillis 1994). Indeed, we found that fast IR was reduced or blocked by CsCl2 (0.3-1.5 mM, n = 6 MNs; not shown).

IKir is known to be reduced by low concentrations (few hundred micromolar) of Ba2+, in contrast to Ih (e.g., Hagiwara et al. 1978). We therefore investigated the effect of Ba2+ on the instantaneous I-V relationship in those MNs that showed fast IR. The difference Delta Ginst triple-bond  Ghyp - Gdep was determined in control and after addition of Ba2+. From its definition, Delta Ginst is positive when fast IR is present, and negative in the face of instantaneous OR. In all MNs, Ba2+ reversed Delta Ginst from positive (fast IR) to negative (fast OR), the difference being highly significant (4.5 ± 1.5 nS, control; -1.5 ± 0.5 nS, Ba2+; n = 5, P < 0.0001). This conversion of fast IR to fast OR is illustrated for selected MNs in Figs. 3 and 4. Delta Ginst changed back from negative (fast OR) to positive (fast IR) on washout of Ba2+ (-1.4 ± 0.4 nS, Ba2+; 9.5 ± 4.9 nS, wash; n = 3, P < 0.05; Fig. 3). The reduction in Delta Ginst caused by Ba2+ was due to a dominant reduction of Ghyp (19.6 ± 6.7 nS, control; 11.8 ± 3.6 nS, Ba2+, n = 5, P < 0.05). Gdep also showed a reduction, which, however, was smaller and not statistically significant (15.1 ± 5.4 nS, control; 13.3 ± 3.9 nS, Ba2+, P > 0.5).



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Fig. 3. Ba2+ blocks fast IR in a manner compatible with an involvement of IKir. A: instantaneous I-V relationships obtained in normal medium (), during addition of Ba2+ (300 µM, open circle ), and following Ba2+ washout (black-triangle). Note reversible conversion of fast IR to fast outward rectification (OR). The potential at which the I-V curves bend maximally is indicated (Vbend, approximately -80 mV); this potential defines the voltage zones relating to the "hyperpolarized" (Ghyp) and "depolarized" (Gdep) instantaneous conductances (see text). B: the barium-sensitive current (IBa2+) calculated by subtracting in A either the control curve or the wash curve from the curve obtained in Ba2+ (symbol equations). The approximate reversal potential for IBa2+ is indicated [E(IBa2+), -82 mV]. Note the similarity of this value with Vbend in A.



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Fig. 4. Unmasking of Ih by blocking the IKir with Ba2+. A and B, control; C and D, Ba2+; E and F, following Ba2+ wash-off. A, C, and E: current responses (top traces) evoked by a family of voltage steps (bottom traces) from a holding potential of -50 mV. In the corresponding I-V relationships (B, D, and F), the instantaneous () and steady-state (open circle ) I-V curves are taken at the time points indicated by the same symbols in A, C, and E. In B, D, and F, the difference current (see text; black-triangle) results from subtracting the instantaneous current () from the steady-state current (open circle ). Note that fast IR appears in control and wash but is absent in Ba2+ (compare  in B and F with those in D). On the other hand, Ih seems to be absent in control and wash but is unmasked by Ba2+ (compare black-triangle in B and F with those in D). Holding current (pA), 94 in A; 59 in C; 179 in E. Scale bars in E apply for A, C, and E.

REVERSAL POTENTIAL FOR IBa2+. The reversal potential for the current blocked by Ba2+, IBa2+, was determined as the intersection between the instantaneous I-V curves obtained in the same cells in control and during Ba2+ application (Fig. 3). The reversal potential for IBa2+ was -75.0 ± 3.4 mV (n = 5); this is close to the potassium equilibrium potential (i.e., -79 mV). IBa2+ was generally of small, albeit not negligible, amplitude at membrane potentials depolarized to its reversal potential.

These data suggest that Ba2+ blocks a fast inward rectifying potassium current (IKir) in neonatal rat spinal MNs. Furthermore, compared with blockade of other potassium currents, the blockade of IKir appears to be the dominant action of Ba2+ in the low concentration used here. This notion is based on the observed selective conductance reduction in the hyperpolarized voltage range, in which IKir is strong. For example, a more equal reduction in Ghyp and Gdep would have been expected if barium had mainly acted on leak currents. Some effect of Ba2+ on leak currents cannot, however, be excluded.

OUTWARD CURRENT RELAXATION BLOCKED BY Ba2+. An outward current relaxation was sometimes observed in response to large hyperpolarizing voltage steps (i.e., beyond approximately -80 mV; Fig. 4A). This outward relaxation, generally preceded by a brief inward relaxation, was slow, and typically did not reach steady state before the voltage step was terminated, typically after 3 s. Since Ih or its related currents do not inactivate (DiFrancesco 1985; Pape 1996), the outward relaxation in response to extreme hyperpolarizing steps cannot be caused by Ih inactivation. However, it may be caused by the "inactivation" of IKir (Biermans et al. 1987; Yamoah et al. 1998). In accordance with this notion, addition of the IKir antagonist Ba2+ (300 µM, Fig. 4B) profoundly altered the response by abolishing the outward relaxation. This effect was reversible on washout of Ba2+ (Fig. 4C).

BLOCKING IKir ENHANCES Ih. The inactivation of IKir can efficiently mask Ih. This important point is illustrated in Fig. 4. Before Ba2+, the inward relaxation characteristic of Ih was inconspicuous during voltage steps of small/medium amplitude (Fig. 4A). Furthermore, during stronger hyperpolarizations, it was largely obscured by the persistent outward relaxation that we ascribe to the inactivation of IKir. These observations provide the false impression that Ih was largely absent in this MN. However, this was not the case, since an inward relaxation with a voltage dependency of amplitude and activation rate characteristic of Ih was observed after the Ba2+ block of IKir (Fig. 4B). This and similar findings in other MNs points out that to study the behavior of Ih in detail, it is necessary to first eliminate IKir.

We conclude that in neonatal rat spinal motor neurons a fast inward rectifier very likely to be a potassium-dependent IKir often co-exists with the slow mixed cation-dependent inward rectifier Ih.

5-HT influences the instantaneous I-V relation

The discovery of IKir in neonatal rat spinal MN prompted an investigation of the possible influence of 5-HT on IKir and other instantaneous currents. By separately analyzing the effect of 5-HT on the "depolarized" and the "hyperpolarized" instantaneous conductances (Gdep and Ghyp, respectively; see METHODS), we found that 5-HT reduces the instantaneous conductance in a voltage-dependent manner. 5-HT reduced Gdep from 21.4 ± 3.0 nS (control) to 15.8 ± 2.1 nS (5-HT). This reduction was significant (P < 0.00001, n = 24 MNs, paired t-test; Fig. 5A) and partially reversible, since Gdep rose again on washout of 5-HT (16.7 ± 4.4 nS, 5-HT; 19.8 ± 5.1 nS, wash, n = 9, P < 0.05). In the same MNs, 5-HT also significantly reduced Ghyp, from 28.2 ± 4.6 nS in control to 24.4 ± 3.9 nS in 5-HT (P < 0.005, Fig. 5A). This effect is probably normally reversible, although we were not able to demonstrate this in the present experiments (Ghyp = 24.8 ± 8.6 nS, 5-HT; 23.5 ± 7.3 nS, P > 0.5). Thus 5-HT reduced the instantaneous conductance over the entire voltage range tested. Interestingly, this reduction was significantly stronger in the depolarized voltage range than in the hyperpolarized range (reduction in Gdep = -5.7 ± 1.3 nS vs. reduction in Ghyp = -3.9 ± 2.0 nS; n = 24; P < 0.05). Stated equivalently, 5-HT enhanced the inward bend in the instantaneous I-V relationship. These data suggest that the fast IR is under neuromodulatory control in spinal MNs.



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Fig. 5. Effects of serotonin (5-HT) on fast IR. A: instantaneous I-V relationship derived from current responses evoked by a family of voltage steps from -50 mV before (normal medium, ) and after (open circle ) application of 10 µM 5-HT. Note pronounced reduction of the depolarized conductance (Gdep) and weaker reduction in the hyperpolarized conductance (Ghyp). In combination, these conductance changes enhanced bend already present in control. B: same as in A but experiment carried out in the constant presence of 300 µM Ba2+. Note that 5-HT again reduced Gdep while there was no change in Ghyp. The fast OR induced by Ba2+ (see text) was reduced. The approximate Vbend is indicated in A and B, which represent different MNs.

EFFECTS OF 5-HT ON INSTANTANEOUS CURRENTS IN BARIUM. It has been argued above that low concentrations of barium provide a relatively selective blockade of the putative IKir. In an attempt to extract the effect of 5-HT on IKir from effects on other instantaneous currents, we repeated the experiments described in the previous paragraph, but this time with barium present both before and during the addition of 5-HT, to permanently block IKir. In Ba2+ (100-300 µM), 5-HT still reduced Gdep (28.3 ± 0.8 nS, Ba2+ alone; 24.3 ± 0.9 nS, Ba2+ plus 5-HT, n = 17, P < 0.001, Fig. 5B). In contrast, the 5-HT-induced reduction of Ghyp observed in normal medium was not seen in Ba2+ (21.9 ± 0.6 nS, Ba2+ alone; 23.5 ± 0.7 nS, Ba2+ and 5-HT, P > 0.10, Fig. 5B).

DEDUCED EFFECTS OF 5-HT ON IKir AND OTHER INSTANTANEOUS CURRENTS. Comparing the results of 5-HT application on the instantaneous currents in normal medium and in barium leads to the following conclusions. Since barium, in concentrations favoring the antagonism of IKir, prevented the 5-HT-dependent reduction in Ghyp, we suggest that the Ghyp reduction stems from 5-HT diminishing IKir. In contrast, the 5-HT-dependent reduction of Gdep observed in normal medium is unlikely to strongly involve IKir, since this effect was not prevented by the IKir antagonist barium. Rather, 5-HT appears to reduce other instantaneous conductances in addition to IKir (see DISCUSSION).

Reversal potential of Ih

In the following we discuss the effects of 5-HT on Ih. To permit the evaluation of these effects in terms of conductance rather than current alone (see below), we determined Eh, the reversal potential of Ih. We used the method previously employed by others (Bayliss et al. 1994; Mayer and Westbrook 1983; Takahashi 1990a), where the intercept of two instantaneous I-V curves evoked from two different holding potentials is used to estimate Ih (not shown) (see Fig. 6 in Takahashi 1990a for an illustration of a similar protocol). The holding potentials were kept below the threshold for depolarization-induced currents. Eh was determined in 125 experiments (50 MNs) under various pharmacological conditions. Due to the presence of some clear outliers, the median rather than the mean was chosen for calculations (see below) of the Ih conductance. The median Eh was -33 mV, well in agreement with previous measurements in the same MNs (Takahashi 1990a).



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Fig. 6. 5-HT enhancement of Ih in Ba2+. A: superimposition of corresponding current traces in response to voltage steps from -40 mV in the constant presence of 300 µM Ba2, before (bold traces) and after (light traces) adding 10 µM 5-HT. The holding current was 817 and 497 pA before and after adding 5-HT, respectively. Numbers to the right indicate the level of the voltage step in mV. B: plots of Ih against the step potential before () and after 5-HT (open circle ). Ih was calculated as the difference between the steady state and the instantaneous currents. Note 5-HT-induced depolarizing shift in current activation. C: box-and-whisker plots summarizing Ih measurements at -80 mV in 16 MNs. Note 5-HT enhancement of Ih. The P value refers to testing the difference in the means of square root transformed data (control vs. 5-HT; see METHODS).

5-HT effects on Ih in barium

ENHANCEMENT OF THE Ih AMPLITUDE. The fact that Ba2+ blocks IKir (Figs. 3 and 4) allowed us to isolate the effect of 5-HT on Ih. Ih was elicited by hyperpolarizing voltage steps before and after the addition of 5-HT, in the constant presence of 200-300 µM Ba2+ to eliminate IKir. Measurements in 5-HT were taken as soon as possible after control measurements, to minimize the impact of time-dependent rundown (see later). In the example MN in Fig. 6, the access resistance, Ra, associated with the recording was low, so that voltage steps of the same nominal amplitude were similar even after correcting the membrane potential for the voltage drop over Ra (see METHODS). In this MN, therefore, the current responses to voltage steps of the same order, elicited before and during 5-HT, could be compared directly (Fig. 6A). Responses were identical down to -66 mV. Beginning at -72 mV, however, the Ih amplitude was larger in 5-HT than in control. This difference (in steady state) increased with further hyperpolarization, peaked at -90 mV, and then gradually declined again to reach zero at -107 mV. The I-V curve in Fig. 6B summarizes the 5-HT enhancement of the steady-state Ih, calculated as the difference between the steady-state current, Iss, and the instantaneous current, Iin. The average amplitude measured at -80 mV was 144 ± 36 pA in barium alone, and 252 ± 62 pA in barium plus 5-HT (P < 0.001, n = 16 MNs, Fig. 6C). Thus the enhancement of the Ih amplitude in the intermediate voltage range was a general finding in the barium-containing solution.

5-HT ENHANCEMENT OF V1/2. The estimated Eh permitted us to convert steady-state Ih-V curves (Fig. 6B) to Gh activation curves (Fig. 7A), using the equation
<IT>G</IT><SUB>h</SUB> = <IT>I</IT><SUB>h</SUB>&cjs0823;  (<IT>V</IT> − <IT>E</IT><SUB>h</SUB>) (2)
The data were fitted to a Boltzmann function of the form
<IT>G</IT> = <IT>G</IT><SUB>max</SUB>&cjs0823;  {1 + exp[(<IT>V</IT> − <IT>V</IT><SUB>1&cjs0823;  2</SUB>)&cjs0823;  <IT>k</IT>]} (3)
where Gmax is the maximal conductance, k is a slope factor, and V1/2 is the potential at which the conductance is half-maximally activated (Fig. 7A).



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Fig. 7. Effects of 5-HT on Gh in Ba2+. A: Gh activation curves calculated from the steady-state Ih currents in Fig. 6B using the equation Gh = Ih/(V - Eh), with Eh = -33 mV (see text). Boltzmann functions were fitted to the data. Note that compared with control () 5-HT (open circle ) did not markedly change the maximal conductance (Gmax) but caused a depolarizing shift in the activation curve. B and C: box-and-whisker plots summarizing the 5-HT effects on Gmax (B) and V1/2 (C) in the constant presence of Ba2+. n.s., not significant.

The maximal conductance in Ba2+ before and after adding 5-HT was 11.8 ± 1.5 nS and 12.2 ± 1.7 nS, respectively. These values were not significantly different (P > 0.5, n = 16 MNs, paired t-test, Fig. 7B). We therefore pooled the data obtained without 5-HT with those obtained in the presence of the drug, thereby obtaining a Gmax of 12.0 ± 1.5 nS. This Gmax value for Ih is substantially higher than previously reported in neonatal spinal MNs (Takahashi 1990a). The lack of effect of 5-HT on Gmax agrees with the findings in adult rat facial MNs (Larkman and Kelly 1992) but is in contrast to the situation in guinea pig trigeminal MNs where 5-HT increases Gmax (Hsiao et al. 1997).

The slope factor was also unaffected by 5-HT. It was 8.5 ± 0.8 mV-1 in Ba2+ alone, and 7.9 ± 0.4 mV-1 in Ba2+ plus 5-HT (P > 0.3, n = 16 MNs, paired t-test). The pooled value was 8.2 ± 0.5 mV-1.

The potential at which the Gh conductance is half-maximally activated, V1/2, was depolarized 7 mV by 5-HT (-93.0 ± 3.0 mV, Ba2+ alone; -85.6 ± 2.5 mV, Ba2+ + 5-HT; P < 0.005, n = 16 MNs, paired t-test, Fig. 7C). A similar, albeit less pronounced, depolarizing shift in V1/2 has been observed in adult rat facial MNs (3.4 mV depolarization) (Larkman and Kelly 1992). These data show that 5-HT enhances Ih by selectively imposing a depolarizing shift in the activation curve.

5-HT effects in normal medium

To test whether the 5-HT enhancement of Ih is a robust phenomenon present under standard conditions and not only under circumstances aimed at pharmacologically isolating Ih, experiments similar to those described in the previous section were performed in standard Krebs solution, i.e., without barium. These data include measurements taken during wash-off of 5-HT. As in barium, 5-HT also enhanced the difference current, IssIin under standard conditions. The effect of 5-HT was transient, such that after prolonged exposure (10-15 min) to 5-HT the difference current IssIin again began to decline, despite the continuous presence of the drug (not shown). Furthermore, the difference current was typically smaller in wash than in control. We attribute these effects to rundown of Ih (Takahashi and Berger 1990), a current known in these and other cells to be modulated by diffusible second messengers (Hille 1992; Larkman et al. 1995; Pape 1996). IssIin at -80 mV was determined 1) before 5-HT (Fig. 8A, Control), 2) between 5 and 10 min following the application of 5-HT (Early 5-HT), and 3) either more than 15 min after adding 5-HT, or in washout of 5-HT (Late 5-HT/wash). The pooling of data obtained late in 5-HT with those obtained in wash was justified by the observation that there was no substantial differences between measurements in these two conditions, presumably as a result of rundown. The mean of (IssIin) showed a 19.0% average increase in 5-HT compared with control. This is close to significance at the 5% level (P = 0.07, n = 14). A 31.4% reduction in IssIin compared with control was seen in the wash/late 5-HT group (P < 0.001), reflecting the rundown effect.



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Fig. 8. Effects of 5-HT on the steady-state Ih in normal medium (A) and in a poly-channel antagonist solution aimed at pharmacologically isolating Ih from other currents (B). A: 5-HT enhanced the difference current IssIin in normal medium, in the face of some rundown. Under these conditions Ih generally dominates the difference current, although other currents may also contribute (see text). B: Ih was subject to severe rundown in the poly-channel antagonist solution and showed a monotonous decrease despite the application of 5-HT. See text for results and statistical analysis of the data in A and B.

Results obtained in normal medium should be interpreted with caution due to the presence of IKir (Fig. 4). However, even in normal medium Ih often appeared to form the main component of the difference current, IssIin, despite the contribution from IKir. Therefore these results confirm that the 5-HT enhancement of Ih also takes place in standard conditions. Furthermore, in view of the observed rundown, it seems likely that our results may well underestimate the degree of the 5-HT enhancement occurring under physiological circumstances.

Enhanced rundown of Ih in a poly-channel antagonist solution

In some experiments, the standard Krebs solution was replaced with a zero- or low (10%) Ca2+ solution with an elevated [Mg2+] to which was added TEA (20 mM) and 4-AP (2 mM). Such a "poly-channel antagonist" solution is conventionally used to pharmacologically isolate Ih from voltage-gated Ca2+ currents, the delayed rectifier (IK), and the A current (IA) (Takahashi 1990b). Ih was measured at -80 mV in 13 MNs (Fig. 8B), under the same conditions as in the experiments made in standard Krebs solution. Despite the application of 5-HT, a progressive decline of the Ih amplitude was typically observed in the poly-channel antagonist solution. On average, the Ih amplitude in 5-HT was reduced to 56% compared with control (P < 0.05, Fig. 8B) and after wash only 40% of the control Ih remained (P < 0.001). This observation is in sharp contrast to the findings in Ba2+ (Fig. 6C) and in normal medium (Fig. 8A), where 5-HT enhanced Ih. These data suggest that the poly-channel antagonist solution enhances Ih rundown. The underlying mechanism is currently unknown.

5-HT accelerates Ih activation

The results presented in this section all originate from the experiments done in the Ba2+-containing Krebs solution. Current activation in response to a family of hyperpolarizing voltage steps was fitted to a single-exponential function of the form
<IT>I</IT><SUB>t</SUB> = <IT>I</IT><SUB>ss</SUB> + <IT>I</IT><SUB>h</SUB> exp(−<IT>t</IT>&cjs0823;  &tgr;) (4)
where It is the current at time t, Iss is the steady-state current reached at t = infinity , Ih is the difference between Iss and the instantaneous current, and tau  is a time constant. We also used a double-exponential function of the form
<IT>I</IT><SUB>t</SUB> = <IT>I</IT><SUB>ss</SUB> + <IT>I</IT><SUB>fast</SUB> exp(−<IT>t</IT>&cjs0823;  &tgr;<SUB>fast</SUB>) + <IT>I</IT><SUB>slow</SUB> exp(−<IT>t</IT>&cjs0823;  &tgr;<SUB>slow</SUB>) (5)
This function defines two amplitude components of Ih, decaying exponentially from the initial constants Ifast and Islow with the time constants tau fast and tau slow, respectively.

The goodness-of-fit of single- and double-exponential functions did not differ substantially for voltage steps of low amplitude. However, when the membrane potential was stepped to more hyperpolarized levels than approximately -80 mV, double exponentials clearly fitted the current responses better than single exponentials. The fast and slow time constants, tau fast and tau slow, were extracted from the double-exponential fits (Fig. 9, A and B) and plotted against the membrane potential, V (Fig. 9, C and D). V was taken as the average between Vin and Vss (see METHODS).



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Fig. 9. 5-HT speeds up the activation of Ih. A and B: current responses (thick black lines) to a family of hyperpolarizing voltage steps from a holding potential of -40 mV, evoked in Ba2+ without (A) and with 5-HT (B). Only traces well fitted to double exponential functions (white lines) are shown. The number to the right of each trace represents the level of the corresponding voltage step (in mV). C and D: voltage dependency of the fast and slow time constants, respectively, extracted from the double exponential curve fitting in A and B. The curves were drawn according to the hyperbolic function tau  = 1/(aV + b), where tau represents tau fast (C) or tau slow (D), V is the step potential and a and b are constants. In D, the tau slow value in Ba2+ at -82 mV was treated as an outlier and omitted from the plot. E and F: summary of similar experiments in 10 MNs. Solid curves were drawn according to the same hyperbolic function as in C and D, but using the means of a and b obtained in individual experiments. The distance to the dashed curves indicates SE.

In 6 of 16 MNs (37.5%), there was no obvious relationship between V and tau fast. This was also the case for small-amplitude steps in the remaining 10 MNs (62.5%, not shown). However, for larger steps, tau fast systematically decreased with increasing hyperpolarization (Fig. 9C). The relationship between V and tau fast was well described by the hyperbolic function
&tgr;<SUB>fast</SUB> = 1&cjs0823;  (<IT>aV</IT> + <IT>b</IT>) (6)
where a and b are constants (Fig. 9, C-F). Analysis of the impact of 5-HT on Ih kinetics relied on reciprocal transformation of tau fast. Thus plots of kfast triple-bond  1/tau fast against V were fitted to the linear function
<IT>k</IT><SUB>fast</SUB> = <IT>aV</IT> + <IT>b</IT> (7)
to estimate a and b (not shown). While the addition of 5-HT did not change a significantly (-0.18 ± 0.03 s-1 mV-1, Ba2+; -0.20 ± 0.02 s-1 mV-1, Ba2+ and 5-HT; n = 10, P > 0.1, paired t-test), b was increased by 5-HT (-13.1 ± 1.8 s-1, Ba2+; -14.4 ± 2.1 s-1, Ba2+ and 5-HT, n = 10, P < 0.01). This increase in b implies (Eq. 7) that 5-HT reduced tau fast.

The dependence of tau slow on V also largely (10 of 16 MNs) obeyed Eq. 6, although the datapoints were more scattered than those related to tau fast. Again, 5-HT did not change a (-0.022 ± 0.004 s-1 mV-1, Ba2+; -0.026 ± 0.003 s-1 mV-1, Ba2+ and 5-HT; n = 10, P > 0.2, paired t-test) but increased b significantly (-1.5 ± 0.3 s-1, Ba2+; -1.7 ± 0.3 s-1, Ba2+ and 5-HT, P < 0.00001, n = 10). Thus like tau fast, tau slow was decreased by 5-HT. These data show that activation of Ih is accelerated by 5-HT, which also appears from direct inspection of the raw data (Fig. 9A, see also Fig. 6A). Figure 9, E and F, shows the overall effect of 5-HT on tau fast and tau slow, respectively. When comparing the two time constants, 5-HT exerted its strongest effect on tau slow. This was most obvious in the hyperpolarized region.

We were not able to determine with certainty the time constants in the voltage region more depolarized than approximately -70 mV. This was partly due to weak activation of Ih but was also related to the fact that the fitted parameters were contaminated by the decay of the capacitive currents related to generation of the voltage steps.

5-HT effect on the holding current

At a holding potential of -50 mV, the holding current in normal medium (including TTX/CNQX/APV) was 80 ± 23 pA (n = 12 MNs). Five minutes after adding 5-HT, the holding current measured in the same MNs displayed a strong inward shift, reaching -51 ± 27 pA (P < 0.0005, data not shown). This level did not change significantly during the next 5 min (5 min vs. 10 min in 5-HT, P > 0.3). We made the qualitative observation, however, that the holding current began to shift back in the outward direction after ~15-20 min in 5-HT. The transient effect of 5-HT on the holding current matches the clear but fleeting 5-HT enhancement of the Ih amplitude described in a previous section.

An inward shift in holding current was also induced by 5-HT in the experiments done in the constant presence of Ba2+ (see above). The holding potential was -40 mV, while the holding current was 440 ± 47 pA in Ba2+ and 239 ± 46 pA in Ba2+ plus 5-HT (P < 0.00005, n = 14 MNs, paired t-test). An inward shift in holding current was observed in a total of 26 MNs.

Both enhancing Ih (which has a reversal potential more positive than the holding potential used in the present experiments) and inhibiting IKir and potassium-dependent leak currents (with a reversal potential more negative than the holding potential) leads to an increase in inward current. Therefore our consistent observation of an inward shift in the holding current is in accordance with our conclusions earlier in the paper that 5-HT enhances Ih and inhibits potassium-dependent currents including IKir. The frequent occurrence of the 5-HT-induced inward current suggests that this feature is important for normal motor function in the neonatal rat.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Takahashi (1990a) reported the presence of a slowly activating, mixed Na+/K+-dependent inward current in neonatal rat spinal MNs. While he preferred to denote this current IIR, we have used the term Ih, which is now a more common name for this class of currents in neurons (Pape 1996). The Ih in MNs of the neonatal rat is enhanced by 5-HT (Larkman and Kelly 1997; Takahashi and Berger 1990). Some aspects of this neuromodulatory effect, especially the pharmacology, have been closely studied (Larkman and Kelly 1997; Larkman et al. 1995; Takahashi and Berger 1990). However, a detailed quantitative investigation of how 5-HT affects the biophysical parameters of Ih has been missing in mammalian MNs. Furthermore, previous studies on neonatal rat MNs have often involved recordings from MNs in thin slices. The MNs recorded from were situated superficially in the slices and were mechanically cleared to allow visual inspection of the cells (Larkman and Kelly 1998; Takahashi and Berger 1990). It seems likely that this procedure may have lead to a partial pruning of the dendritic tree, which could alter the quantitative features of whole cell currents. In contrast, here we present the results of whole cell tight-seal voltage-clamp recordings from MNs in the intact spinal cord. Too strong emphasis on the quantitative aspects of our data should be avoided due to the imperfections of the whole cell voltage-clamp technique, including the absence of ideal space clamp and the rundown of the second-messenger-dependent currents such as Ih. Nevertheless, our results provide a necessary framework for future investigations, e.g., of 5-HT-mediated control of MN behavior during integrated motor tasks in intact preparations, including locomotor activity (Kiehn et al. 2000).

INSTANTANEOUS INWARD RECTIFICATION. During experiments aimed at quantifying the effects of 5-HT on the time-dependent inward rectifier, Ih, we discovered that fast inward rectification in neonatal rat spinal MNs is quite common and often coexists with Ih. We treat this finding first, partly because it is novel and of independent interest, and partly because fast inward rectification complicated the analysis of neuromodulation of Ih, as discussed below.

We found that half (49%) of the spinal MNs in the neonatal rat display fast IR. Several observations support the idea that this property is due to a potassium-dependent current belonging to the IKir class (Constanti and Galvan 1983; Hille 1992; Katz 1949; Nichols and Lopatin 1997; Standen and Stanfield 1979). First, the general swift activation of IKir fits well with our observation that the inward rectification not related to Ih was "instantaneous," occurring immediately after settling of the capacitive transient associated with the change in voltage command. Second, since IKir is carried by potassium ions, the voltage area in which inward rectification appears would be expected to be close to the potassium equilibrium potential, EK. This is in accordance with our finding that the inflection point in the instantaneous I-V relationships occurred at an average of -80 mV; this value is essentially identical to the predicted EK of -79 mV. Third, the fast IR in neonatal rat MNs was abolished by Ba2+ in concentrations of a few hundred micromolar, in agreement with the known Ba2+ sensitivity of IKir (Constanti and Galvan 1983; Hagiwara et al. 1978; Yamoah et al. 1998). A voltage dependency of the block imposed by Ba2+ on IKir has been suggested for supra-spinal MNs, with the potency of the ion block increasing with increasing hyperpolarization (Larkman and Kelly 1998). This conforms to our analysis of the effect of Ba2+ on the instantaneous conductance, which showed a significant reduction in Ghyp but no change in Gdep. However, it cannot be excluded that the apparent voltage-dependent effect of Ba2+ was simply due to the voltage dependency of IKir itself. Depending on the strength of inward rectification, the outward IKir flowing in the depolarized voltage range may be weak, in which case blocking it might have produced a conductance change too small to be detected. To summarize, we consider the evidence presented here strong enough to conclude that spinal neonatal rat MNs are endowed with an IKir.

In view of our finding that half of the spinal neonatal MNs show fast IR, it is surprising that fast IR has not already been demonstrated directly in these cells despite several previous studies of their active membrane properties. In rat facial MNs (Larkman and Kelly 1997, 1998), the presence of an IKir subject to modulation by 5-HT has been inferred mainly from pharmacological evidence (see also below). However, fast IR in the I-V relationships was not reported in these studies. Indeed, these authors found that the K+-dependent component of the 5-HT-sensitive current displayed a linear, i.e., nonrectifying, I-V relationship. One explanation for the absent demonstration of fast IR in previous studies may be that the extracellular potassium concentration was commonly raised (e.g., to 12 mM) (Larkman et al. 1995; Takahashi 1990a) to depolarize EK and thereby enhance the driving force of Ih. For IKir, the voltage associated with the most pronounced fast IR is identical to EK. This potential may have been depolarized beyond the range covered by the voltage-clamp commands, so that fast IR eluded observation in the previous work. Also, antagonists used to pharmacologically isolate Ih may have obscured the fast IR in previous studies. Specifically, we obtained some evidence suggesting that TEA occludes a Ba2+-induced positive shift in the holding current (unpublished observations). This may indicate that the IKir in the neonatal rat, besides being sensitive to barium, is also TEA sensitive, as described for other cells (Bobker and Williams 1995; Hille 1992; Travagli and Gillis 1994). The clear presence of fast IR in neonatal rat MNs in our experiments as opposed to those of others could also be related to differences in the recording circumstances (see above), especially if one assumes a dendritic predominance of IKir, relative to linear leak or outward rectifying currents. Finally, the different experimental approaches in this study compared with that of others might have led to a biased selection of MNs with a pronounced fast IR.

5-HT modulation of the instantaneous conductance

We found that 5-HT reduced the instantaneous conductance of spinal MNs in conjunction with a negative (depolarizing) shift in the holding current at -50 mV. This effect may be decomposed into suppression of at least two currents, which dominate at different voltage ranges. Low concentrations of Ba2+, which were sufficient to block IKir, specifically prevented the 5-HT-dependent conductance reduction at hyperpolarized potentials (below approximately -80 mV; Fig. 5); this 5-HT effect may therefore be explained at least partly by blockade of IKir. A previous demonstration of such a mechanism was made in nucelus accumbens neurons, where an instantaneous inward rectifying K+ conductance is reduced by 5-HT (North and Uchimura 1989). Also, 5-HT reduces K+ currents both in adult (Larkman and Kelly 1992) and neonatal (Larkman and Kelly 1998) rat facial MNs; one of these currents has been suggested to be an IKir mainly on pharmacological grounds.

In the depolarized voltage range (above approximately -80 mV), Ba2+ did not prevent the 5-HT-induced reduction in the instantaneous conductance in our recordings. Therefore a different current than IKir must be involved in this phenomenon. An interesting possibility is a background K+ current present in the neonatal rat spinal MNs (Fisher and Nistri 1993). This current is pharmacologically clearly different from IKir, since it is insensitive to Cs2+ (2 mM), and, although reduced in high (1.5 mM) [Ba2+], it is not affected by Ba2+ in low concentration (200 µM). The background current is inhibited by the neuropeptides TRH and substance P. Co-existence of these transmitters with 5-HT in fibers innervating spinal motor nuclei has been described (Arvidsson et al. 1992). Other currents may also be involved, however. In neonatal rat facial MNs, 5-HT reduces a potassium current, which is insensitive to antagonists of IKir, but sensitive to 4-AP (Larkman and Kelly 1998). It appears likely that a similar current exists in the spinal MNs. This current could contribute to the 5-HT effect provided it is not fully inactivated at the resting membrane potential.

The reduction of the instantaneous conductance and the outward shift in holding current caused by ZD 7288 suggest that Ih also contributes to the resting conductance at potentials around -50 mV. We found that 5-HT enhances this depolarizing contribution of Ih to the membrane potential (see also Kiehn et al. 2000).

Provided that IKir allows current flow at potentials more positive that EK, it will generate an outward current that decreases MN excitability. Inhibition of IKir by 5-HT in the depolarizing voltage range will therefore increase MN excitability. From the present series of experiments, it appears that there is little steady activation of IKir at potentials more positive than EK (see previous paragraph), suggesting that the 5-HT modulation of IKir in the depolarizing voltage range plays a minor role for MN firing.

Ih characteristics

We have established the biophysical parameters of Ih in MNs in the intact cord in detail, and in this section compare them with the parameters previously determined in acute slices (Takahashi 1990a). Since the co-existence of IKir with Ih in many MNs could obscure Ih (Fig. 4), we blocked the IKir with low concentrations of Ba2+. The maximal conductance, Gmax, was determined from Boltzmann fits to Gh/V plots and found to be 12.0 ± 1.5 nS. Takahashi (1990a) reported a half-maximally activated chord conductance of about 0.8 nS. Hence his Gmax value (~1.6 nS) would be about an order of magnitude smaller than ours. A likely explanation for this difference is that we have recorded from presumably more intact MNs. This technical aspect would be of particular relevance if the Ih channels in neonatal rat MNs are abundant in the distal membrane, as has been reported for hippocampal CA1 pyramidal neurons, where the density of Ih in the most distal regions is roughly sevenfold higher than in the somatic region (Magee 1998). It is also possible that our experimental approach for an as yet undetermined reason has lead to a selection of large MNs compared with those of previous experimenters.

We observed that for hyperpolarizing steps to approximately -80 mV or beyond, the sum of two exponentials was necessary to obtain good fits to Ih activation, with tau fast being measured in hundreds of milliseconds and tau slow in seconds. Double-exponential activation of Ih in the neonatal rat MNs may indicate that two kinetically distinct Ih channel populations are present in these neurons (cf., Solomon and Nerbonne 1993). Interestingly, Takahashi (1990a) reported that a single, slow time constant was sufficient to describe the activation of Ih. This apparent discrepancy can be resolved if it is assumed that the two kinetically distinct Ih channel populations are spatially segregated, so that the slow channels are concentrated proximally while the fast channels mainly localize to the distal dendrites that were presumably better conserved in our experiments (see above).

5-HT modulation of Ih

It has been reported previously that 5-HT increases a conductance very similar to Gh in spinal MNs (Takahashi and Berger 1990), but the biophysical nature of this effect was not determined. We found that this enhancement consists of a depolarizing shift in the activation curve for Ih, amounting to 7 mV on average. In contrast, 5-HT caused no systematic change in Gmax. Results from other MN types have been mixed. In adult rat facial MNs, 5-HT depolarizes V without changing the maximum tail current amplitude of Ih, i.e., similar to our findings (Larkman and Kelly 1992). On the other hand, 5-HT increases Ih in guinea pig trigeminal MNs without shifting the (normalized) activation curve, suggesting that this enhancement is related to an increase in Gmax (Hsiao et al. 1997). Apparently, the biophysical mechanism underlying the 5-HT enhancement of Ih in mammalian MNs is heterogeneous.

In our experiments, 5-HT shortened both the fast and the slow time constant. However, tau slow was clearly stronger affected that tau fast (Fig. 9, compare E with F). In combination with the considerations in the previous section, this observation leads us to suggest that neonatal rat spinal rat MNs may be endowed with two kinetically, spatially and pharmacologically distinct Ih channel populations. One of these populations predominates in the soma and proximal dendrites, activates slowly on hyperpolarization, and is strongly enhanced by 5-HT. The second population, although also represented proximally, predominates in the distal dendrites, activates quickly, and is more moderately enhanced by 5-HT. More experiments are necessary to further substantiate this idea.


    ACKNOWLEDGMENTS

We thank M. E. Denton and B. Johnson for participating in initial experiments in this study.

This work was supported by the NOVO Foundation and the Danish Medical Research Council.

Present address of O. Kjaerulff: The Nobel Institute for Neurophysiology, Dept. of Neuroscience, The Karolinska Institute, S-171 77 Stockholm, Sweden (E-mail: OleKjaerulff{at}neuro.ki.se).


    FOOTNOTES

Address for reprint requests: O. Kiehn, Section of Neurophysiology, Dept. of Medical Physiology, The Panum Institute, Blegdamsvej 3, DK-2200 Copenhagen, Denmark (E-mail: O.Kiehn{at}mfi.ku.dk).

Received 19 June 2000; accepted in final form 3 October 2000.


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ABSTRACT
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0022-3077/01 $5.00 Copyright © 2001 The American Physiological Society