Angiotensin II Induces Calcium-Dependent Rhythmic Activity in a Subpopulation of Rat Hypothalamic Median Preoptic Nucleus Neurons

doi:10.1152/jn.00769.2004

Angiotensin II Induces Calcium-Dependent Rhythmic Activity in a Subpopulation of Rat Hypothalamic Median Preoptic Nucleus Neurons

David Spanswick¹^,2 and Leo P. Renaud¹

¹Neurosciences Program, Ottawa Health Research Institute and University of Ottawa, Ottawa, Ontario, Canada; and ²Warwick Medical School, University of Warwick, Coventry, United Kingdom

Submitted 28 July 2004; accepted in final form 9 November 2004

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Whole cell patch-clamp recordings revealed a subpopulation (16%,n = 18/112) of rat median preoptic nucleus (MnPO) neurons respondedto bath-applied angiotensin II (Ang II; 100 nM to 5 µM;30–90 s) with a prolonged TTX-resistant membrane depolarizationand rhythmic bursting activity. At rest, cells characteristicallydisplayed relatively low input resistance and negative restingpotentials. Ang-II-induced responses featured increased inputresistance, a reversal potential of –95 ± 2 mV,an increase in action potential duration from 2.9 ± 0.5to 4.3 ± 0.8 ms, and the appearance of a rebound excitationat the offset of membrane responses to hyperpolarizing currentinjection. The latter was sensitive to Ni²⁺ (0.5–1 mM;n = 5), insensitive to extracellular Cs⁺ (1 mM, n = 7), andintracellular QX-314 (4 mM, n = 5), consistent with activationof a T-type Ca²⁺ conductance. Coincident with the Ang-II-induceddepolarization was the appearance of rhythmic depolarizing shiftsat a frequency of 0.14 ± 0.09 Hz with superimposed burstsof 4–22 action potentials interspersed with silent periodspersisting for >1 h after washout. These TTX-resistant depolarizingshifts increased in amplitude and decreased in frequency withmembrane hyperpolarization with activity ceasing beyond approximately–80mV, and were abolished in low-Ca²⁺/high-Mg²⁺ bathingmedium (n = 6), Co²⁺ (1 mM; n = 6), or Ni²⁺ (0.5–1 mM;n = 8). Thus in a subpopulation of MnPO neurons, Ang II induces"pacemaker-like" activity by reducing a K⁺-dependent leak conductancethat contributes to resting membrane potential and promotingof Ca²⁺-dependent regenerative auto-excitation mediated, inpart, by a T-type Ca²⁺ conductance.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

The lamina terminalis, the thin strip of neural tissue formingthe rostral wall of the third cerebral ventricle, contains threecollections of neurons that serve a critical role in maintainingbody fluid and cardiovascular homeostasis (reviewed in Johnsonet al. 1996; McKinley et al. 1999). Two of these are circumventricularorgans or CVOs the fenestrated capillaries of which permit blood-bornemolecules access to central neurons. Located dorsally is thesubfornical organ (SFO) the neurons of which are a target forcirculating angiotensin; at the ventral edge of the lamina terminalisis the organum vasculosum lamina terminalis (OVLT) the neuronsof which participate in osmoreception. Thus neurons in bothof these CVOs serve a sensory role to systemic challenges suchas a rise in plasma angiotensin (Ang II) or an increase in plasmaosmolality, respectively. The consequences of their participationto these challenges is the instigation of specific responses.In the case of Ang II, peripheral or central administrationresults in a clearly defined change in behavior (e.g., drinking)as well as autonomic (e.g., suppression of sweating to eliminateevaporative heat loss) and/or endocrine reflexes (e.g., vasopressinrelease) aimed at the conservation and restoration of fluidvolume (Lind and Johnson 1982; Owens et al. 1989).

While the importance of these lamina terminalis CVOs in theseresponses to Ang II is well characterized, the neural mechanismsunderlying these actions rely on a third neuronal structure,the median preoptic nucleus (MnPO, also called MnPN or nucleusmedianus). Located around the anterior commissure at the midpointof the lamina terminalis, the MnPO has features suggestive ofan integrating center. Its neurons are reciprocally connectedwith SFO and OVLT neurons, receive input from medullary autonomicneurons, and project to hypothalamic and brain stem targetsthat are known to regulate fluid balance (e.g., supraoptic andparaventricular magnocellular neurons) and cardiovascular function(e.g., nucleus tractus solitarii, ventrolateral medulla) (reviewedin McKinley et al. 1999). Moreover, MnPO is essential for thedrinking response induced by central and peripheral administrationof Ang II, as lesions of this nucleus abolish these responses(Cunningham et al. 1991). A critical component of the responseto peripheral Ang II is the SFO the neurons of which are notonly sensitive to blood-borne Ang II but also give rise to anangiotensin-immunoreactive innervation to MnPO (Lind et al.1984). The presence within MnPO of a high-density of angiotensinbinding sites, as well as neurons expressing AT₁ type receptors(Lenkei et al. 1998) and responding with excitation and membranedepolarization to exogenous angiotensin (Bai and Renaud 1998;Travis and Johnson 1993), suggest that this nucleus has a pivotalrole in coordinating the central drive to drink induced by elevatedlevels of circulating Ang II. However, to date there is littleinformation on the cellular mechanisms whereby this peptidemodulates activity of MnPO neurons to bring about such behavioralchanges.

To address this issue, we have utilized whole cell patch-clamprecording techniques in an in vitro hypothalamic slice preparationto investigate the actions of Ang II on MnPO neurons. An earlierstudy (Bai and Renaud 1998) revealed that $~$ 50% of neurons respondedto exogenous Ang II with an AT₁ receptor-mediated prolongeddepolarization and associated reduction in membrane conductance.We now report that a subpopulation of MnPO neurons respondingto a brief exposure to Ang II displays a unique pacemaker-likeactivity that persists for hours postinduction, a feature thatis intrinsic to these neurons and conditional on exposure toAng II. We therefore propose these neurons to be Ang II-sensitive"conditional pacemakers" the participation of which may be akey element in a central mechanism underlying the behavioraldrinking response.

METHODS

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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Slice preparation

The methods employed in this study were in accordance with theprinciples and guidelines of the Canadian Council for AnimalCare. Briefly, male Long-Evans rats (200–350 g body wt,6–12 wk old) were anesthetized with halothane and decapitatedand the brain was removed and stripped of dura and pia mater.Coronal or saggital slices (300–450 µm) of hypothalamuscontaining the MnPO were cut on a vibratome under ice-cold,gassed (95% O₂-5% CO₂) artificial cerebrospinal fluid (ACSF)of the following composition (in mM) 127 NaCl, 1.9 KCl, 1.2KH₂PO₄, 2.4 CaCl₂, 1.3 MgCl₂, 26 NaHCO₃, and 10 D-glucose; pH7.4. Slices were maintained carbogenated at room temperaturefor 1–2 h prior to transfer to a submerged-type recordingchamber.

Recording

Whole cell recordings were obtained from MnPO neurons at roomtemperature and at 34 ± 0.5°C. Patch-pipettes withresistances of 3–12 M ${Omega}$ were filled with an intracellularsolution of the following composition (in mM) 130 Kgluconate,10 KCl, 0.2 MgCl₂, 0.1 CaCl₂, 0.5 EGTA-Na, 10 HEPES, and 2 Na₂ATP,pH 7.4 (with NaOH). Recordings were obtained with a patch-clampamplifier (Axopatch 1D, Axon Instruments). Correction of theliquid junction potential was applied to whole cell recordings.Access resistances ranged between 5 and 30 M ${Omega}$ . Recordings weremonitored on an oscilloscope (Gould 1602), displayed on a pressureink pen recorder (Gould RS3200), and stored on videotape forlater off-line analysis. Statistical analysis was performedusing Excel (Microsoft) with all values given as means ±SD. Statistical significance was determined using Student'stwo-tailed paired t-test. P < 0.05 was taken to indicatestatistical significance.

Pharmacology

Drugs made up as concentrated stocks, diluted in ACSF and appliedby superfusion at known concentrations in the bathing medium,included: Ang II, the voltage-dependent sodium channel blockertetrodotoxin (TTX; Sigma and/or Sigma/RBI, St Louis, MO), thecalcium channel blockers Co²⁺ and Ni²⁺, and the nonselectivepotassium channel blockers Cs⁺ and Ba²⁺. QX-314 (Sigma), anintracellular sodium channel blocker (also known to block hyperpolarization-activatednonselective cation channels) was included in the pipette solution.In experiments where low-Ca²⁺ and high-Mg²⁺ bathing medium wereused, CaCl₂ was omitted from the bathing medium, and the concentrationof MgCl₂ increased to 5.2 mM.

Cell identification and morphology

For unambiguous identification of MnPO neurons, the morphologyand anatomical localization was examined by including the intracellularmarker Lucifer yellow (dipotassium salt, 1 mg/ml, Sigma) inthe patch-pipette solution. Methods for visualizing neuronsafter whole cell recording with Lucifer yellow have been describedin detail previously (Pickering et al. 1991). Briefly, afterrecording, slices were fixed in 4% paraformaldehyde overnight,cleared in DMSO, and mounted between two coverslips for subsequentepifluorescent microscopy (Zeiss Axioskope).

RESULTS

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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Properties of MnPO neurons

Whole cell recordings from a total of 112 MnPO neurons situatedventral or dorsal to the anterior commissure revealed a collectivemean resting membrane potential and input resistance of –56.6± 8.0mV and 1,581 ± 668 M ${Omega}$ , respectively. We observedno obvious differences in the morphology, electrophysiologicalproperties, or sensitivity to Ang II of MnPO neurons in coronalversus saggital slices.

Ang II induction of a pacemaker-like activity

During this study we noted that a subpopulation (16%, n = 18/112)of MnPO neurons were characteristically silent and respondedto Ang II in a unique manner. These cells had a comparativelyhyperpolarized mean resting membrane potential (–68.5± 8.0 mV; range: –78 to –58 mV) and low inputresistance (1,068 ± 386 M ${Omega}$ ). Typically these cells respondedto bath application of Ang II (100 nM to 5 µM, 10–90s) with a slowly developing membrane depolarization (15.2 ±6.3 mV) and rhythmic bursts of action potential discharge (Figs.1, A and B). Rhythmic activity induced by Ang II was characterizedby bursts of 4–22 action potentials interspersed withsilent periods of inactivity. The mean frequency of these burstswas 0.14 ± 0.09 Hz at the final steady-state membranepotential induced by Ang II (data from 5 cells). Individualbursts displayed characteristic wave-forms comprising slow,progressive depolarizing shifts, with superimposed trains ofaction potentials toward the peak of the shift, followed bya relatively rapid termination and silent period before theonset of the subsequent burst (Fig. 1B). The mean peak amplitudeof these depolarizing shifts was 19.1 ± 1.4 mV (calculationfrom 5 neurons at a holding potential of –70 mV). Burstfiring induced by Ang II persisted even at membrane potentialsmore negative than the preresponse resting membrane potential.As illustrated in Fig. 1B, bursts of action potential firingdecreased in frequency with increasing membrane hyperpolarizationand ceased at membrane potentials more negative than around–80 mV. These features suggest that this Ang-II-inducedburst firing involves mechanisms that are intrinsic to theseneurons. Indeed rhythmic activity persisted in the presenceof TTX (0.5–1 µM; see Fig. 4, A2 and B2; n = 8).

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FIG. 1. Angiotensin II (Ang II) induced burst firing in 16% (n = 18 of 112) of median preoptic (MnPO) neurons. A: current-clamp trace revealed that bath application of Ang II (5 µM; horizontal bar) initiates a prolonged membrane depolarization and action potential discharge. A concomitant increase in neuronal input resistance was indicated by the increase in the amplitude of electrotonic potentials (downward deflections of the record) evoked in response to hyperpolarizing current pulse injection (0.03 Hz, 500 ms, –20 pA). Towards the end of the trace, manual membrane hyperpolarization to preresponse resting levels revealed a burst-firing pattern of activity. B: samples of a continuous record from the same neuron shown in A to illustrate that membrane hyperpolarization progressively reduced the frequency of burst firing and eventually abolished all activity at a membrane potential of –85 mV. Note, action potentials in this and subsequent records are truncated due to the limited frequency response of the chart recorder.

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FIG. 4. Ang-II-induced burst firing is mediated by an underlying Ca²⁺-dependent regenerative mechanism. Samples of continuous records from 2 MnPO neurons are shown. A1: spontaneous burst firing induced by Ang II. A2: subsequent application of TTX abolished bursts of action potentials giving rise to regular, single action potential discharge. A3: in low-Ca²⁺/high-Mg²⁺ bathing medium, the frequency of firing initially increased and ultimately activity was abolished, effects fully reversible on returning to normal calcium and magnesium levels (A, 4 and 5). A6: addition of a nonselective calcium channel blocker Co²⁺ completely abolished all activity, again effects reversible on washout of the cation (A7). B1: recordings from another neuron showing burst firing induced by Ang II. B2: in the presence of TTX, large amplitude "plateau-like" potentials persisted. This activity was partly reduced by addition of Ni²⁺ at a concentration of 0.5 mM (B3) and completely abolished in 1 mM Ni²⁺ (B4), effects reversible on washout of this cation (B5).

Ang-II-induced responses were associated with a concomitant34.9 ± 19.8% increase in neuronal input resistance to1,377 ± 275 M ${Omega}$ (P < 0.001, see Figs. 1A and 2A), assessedfrom measurements taken after manual repolarization of the membraneto preresponse resting levels by injection of constant negativecurrent (Fig. 2A). Voltage-current relations of MnPO neuronsbefore and during exposure to Ang II indicated a reversal potentialof –95 ± 2 mV (see Fig. 2, B and C; n = 5), closeto the reversal potential for K⁺ ions under our recording conditions(E_K–98 mV). Ang-II-induced rhythmic activity was sustainedover the time course of the experiment, $≤$ 4.5 h in some cases(n = 7), and partly recoverable in the remaining neurons. Quantitativelyand qualitatively similar data were obtained in experimentsperformed at 34 ± 0.5°C in a further five MnPO neurons.This response was selectively induced by Ang II. By contrast,responses to L-glutamate (500 µM, n = 3) induced membranedepolarization associated with a reduction in input resistance,recovering rapidly on washout of the drug. Both GABA (1 mM,n = 6) and muscimol (15 µM, n = 4) induced rapidly reversiblemembrane hyperpolarization with an associated decrease in inputresistance.

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FIG. 2. Ang-II-induced changes in passive membrane properties. A: current-clamp trace illustrates Ang-II-induced membrane depolarization associated with an increase in neuronal input resistance, the latter indicated by the increase in the amplitude of electrotonic potentials (downward deflections of the record) evoked in response to hyperpolarizing current pulse injection (0.03 Hz, 500 ms, –20 pA). At the peak of the response, manual membrane hyperpolarization to preresponse resting levels revealed the increase in neuronal input resistance to be due to exposure to Ang II rather than an indirect effect of activation of voltage-dependent conductances. Bottom: electrotonic potentials sampled from the points in the record above indicated by the arrows and shown here on a faster time base. Note the increase in peak amplitude of the potential elicited after exposure to Ang II compared with control, indicating an increase in neuronal input resistance. B: samples of a continuous record showing superimposed membrane responses to injection of current pulses in the absence (control) and after exposure to Ang II. C: plot of data shown in B. Note the increased slope in the presence of Ang II and point of intersection of the plots indicating the reversal potential of the Ang-II-induced depolarization around –95 mV. This is close to the reversal potential for potassium ions under our recording conditions.

Intrinsic mechanisms contributing to Ang-II-induced rhythmic activity

We further investigated mechanisms initiated by Ang II thatcould contribute to rhythmogenesis in these particular neurons.In addition to an increase in neuronal input resistance, Fig. 3illustrates that Ang-II-induced responses also revealed arebound excitation at the offset of the membrane response toinjection of rectangular-wave hyperpolarizing current pulses(–0.05–80 pA, 0.2–1 s, 0.2–0.3 Hz).This rebound excitation was characterized by a large-amplitude,rapidly rising depolarizing shift with superimposed action potentials(Fig. 3A2). Prior to exposure to Ang II, this conductance wasnot observed in response to hyperpolarizing current pulses thatgenerated equivalent membrane responses from membrane potentialsclose to threshold (Fig. 3A1). This rebound excitation was partlyreduced by Ni²⁺ at a concentration of 500 µM (n = 3) andcompletely blocked at a concentration of 1 mM (n = 5; Fig. 3A4).Extracellular Cs⁺ (1 mM; n = 7; Fig. 3A3) and intracellularQX-314 (4 mM; n = 5; Fig. 3B) were without effect on the Ang-II-inducedmembrane rebound depolarization.

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FIG. 3. Effects of Ang II on intrinsic active conductances contributing to autorhythmicity. A: samples of a continuous current-clamp record showing superimposed electrotonic potentials evoked in response to hyperpolarizing rectangular-wave current pulses (0.10–0.35 pA; 500 ms; 0.03 Hz). A1: electrotonic potentials evoked prior to exposure to Ang II. A2: electrotonic potentials evoked in the presence of Ang II. Note the rebound depolarizations evoked at the offset of the response to current injection. A3: subsequent exposure to Cs⁺ was without significant effect. A4: however, Ni²⁺ (1 mM) completely blocked the rebound excitation. B: superimposed electrotonic potentials evoked in response to hyperpolarizing rectangular-wave current pulses (0.4p A; 500 ms; 0.03 Hz) in a QX-314-loaded neuron prior to and during exposure to Ang II. Note the rebound excitation evoked at the offset of the membrane response to hyperpolarization in the presence of Ang II. Each record in this figure is the average of 8 consecutive electrotonic potentials. C: samples of a continuous record showing Ang-II-induced modulation of the action potential waveform. The action potential was prolonged in the presence of Ang II (2) compared with control (1) and a distinct shoulder on the repolarization phase exposed in the presence of Ang II. Each record here is the average of 8 consecutive action potentials evoked in response to depolarizing current injection.

Ang II also significantly modulated the action potential waveform.When evoked in response to suprathreshold depolarizing currentpulses (0.05–20 pA), action potential repolarization inthe presence of Ang II (100 nM to 5 µM), was slowed andthe duration increased from 2.9 ± 0.5 ms in control to4.3 ± 0.8 ms with a significant "shoulder" appearingon the repolarizing aspect (Fig. 3C).

Ionic mechanism underlying Ang-II-induced rhythmic activity

To determine the mechanisms underlying the generation of Ang-II-inducedrhythmic activity, we tested the effects of a range of ion channelblockers. Whereas the voltage-dependent sodium channel blockerTTX (1 µM, n = 3) blocked fast action potential discharge,rhythmic activity persisted in the form of slow-rising depolarizingshifts that gave rise to a single action potential (calciumspike) at the peak of the shift (Fig. 4A2). The frequency ofthe depolarizing shifts and associated spike was little affectedby TTX, being similar to that of bursts seen prior to TTX (1.2± 0.3 Hz in TTX vs. 1.2 ± 0.4 Hz before TTX).Similar activity was induced in response to Ang II in each ofthree neurons preexposed to TTX.

To investigate the role of calcium in Ang-II-induced rhythmicactivity, we tested the effects of reducing extracellular Ca²⁺concentration, the nonselective Ca²⁺ channel blocker Co²⁺, andthe relatively selective T-type Ca²⁺ channel blocker Ni²⁺. Superfusionof nominally 0 mM Ca²⁺ and high Mg²⁺ (5.2 mM) bathing mediumin TTX (n = 6) had several effects. At the onset of exposureto these conditions the frequency of spontaneous rhythmic activityincreased, action potential amplitude decreased and the interburstintervals were progressively reduced. At the peak of the response,irregular shifts in membrane potential persisted, and the membranepotential remained 10–15 mV more depolarized than thepeak of the membrane hyperpolarization observed during rhythmicactivity. Rhythmic activity was therefore disrupted under theseconditions (Fig. 4A, 2–4). On returning Ca²⁺ and Mg²⁺to normal, activity was progressively restored, the frequencyof activity decreasing with progressive restoration of normalCa²⁺ and Mg²⁺ levels. Again, the frequency and timing of therhythmic activity were re-established within 15 min of returningcalcium to the bathing medium (Fig. 4A, 4 and 5).

Bath application of Co²⁺ (1 mM) completely and reversibly abolishedAng-II-induced rhythmic activity (Fig. 4A6; n = 6). In the presenceof TTX, the T-type Ca²⁺ channel blocker Ni²⁺ partly reducedrhythmic activity and underlying depolarizing shifts at a concentrationof 0.5 mM (n = 4; Fig. 4B1–3) and completely blocked regenerativerhythmic activity induced by Ang II at a concentration of 1mM (Fig. 4B4; n = 8), a concentration that blocked the T-typecalcium conductance in these neurons (see Fig. 3A). The effectsof these divalent cations were completely reversible, the frequencyand timing of the rhythmic activity being re-established within15 min of wash (Fig. 4, A7 and B5).

DISCUSSION

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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

This study reports that a subpopulation of MnPO neurons characterizedby a relatively hyperpolarized resting membrane potential andlow input resistance responds to exogenous Ang II with membranedepolarization and a prolonged, bursting, "pacemaker-like" activity.The latter appears to be unique to these cells and involvesa calcium-dependent regenerative activity and conductances thatare intrinsic to the neurons, endowing them with a capabilityfor autorhythmic activity, conditional on exposure to Ang II.

Mechanism of Ang-II-induced excitation

Ang-II-induced membrane depolarization and burst firing activitywas associated with a decrease in neuronal input conductancethat could persist for >1 h after presumed washout of theagent. Because of the prolonged nature of the Ang-II-inducedresponse, maintaining stable recording conditions until theestablishment of a full recovery in combination with a tendencyfor desensitization, precluded a detailed pharmacological investigationof the concentration dependence and receptor specificity ofthe response. However, some of these aspects were featured earlier(see Bai and Renaud 1998). In the present investigation, current-voltagerelations indicated a reversal potential of –95 ±2 mV, close to the reversal potential for K⁺ ions under ourrecording conditions. These data imply that Ang-II-induced rhythmicactivity, in part, involves block of one or more K⁺ leak conductancesthat contribute to resting membrane potentials in these neurons.Ang-II-induced reductions in potassium conductances have alsobeen noted in other neurons (Li and Ferguson 1996; Li and Guyenet1996; Nagamoto et al. 1995).

Intrinsic active conductances contributing to Ang-II-induced rhythmic activity

In addition to its effects on resting membrane conductances,Ang II also either revealed or modulated active conductancesexpressed by these neurons. In the presence of Ang II, a reboundexcitation was observed at the offset of the response to membranehyperpolarization, giving rise to bursts of action potentialsthat were similar to those observed spontaneously after exposureto Ang II. This conductance was blocked by a low-voltage-activated(LVA) T-type Ca²⁺ channel blocker Ni²⁺, and unaffected by Cs⁺and intracellular QX-314, the latter two being blockers of thetime-dependent hyperpolarization-activated inward rectifierI_h (Pape 1996; Robinson and Siegelbaum 2003). Thus in the presenceof Ang II a T-type Ca²⁺ conductance was revealed or unmaskedin MnPO neurons. Although the concentrations of Ni²⁺ requiredto block the rebound excitation were relatively high (>500µM), other studies show variation in the sensitivity ofT-type Ca²⁺ conductances to Ni²⁺, (Lee et al. 1999; Wilson etal. 2002). This partly reflects the subunit composition of thechannels. At present, the T-type Ca²⁺ channel family consistsof three members, Ca_V3.1, Ca_V3.2, and Ca_V3.3 (see Perez-Reyes1999). Differential expression of these subunits and associatedsubunits can yield channels and conductances with distinct propertiesproposed to reflect specific neuronal functions. T-type channelsare activated at potentials negative to threshold for Na⁺-dependentaction potential firing and activation of high-threshold Ca²⁺conductances and act to amplify subthreshold stimuli leadingto suprathreshold activity by providing a depolarizing drive(see Huguenard 1996). These features are thought to be fundamentalto the initiation of firing and in generating pacemaker-likeactivity in certain neuronal types and in synchronization ofnetwork activity (Huguenard and McCormick 1992; Llinas 1988).

Ang II also slowed the repolarization phase of the action potential,extending its duration and forming a distinct "shoulder" onthe repolarizing aspect. This is consistent with a componentof the spike being mediated via high-threshold calcium conductances.Ca²⁺ components of the action potential in MnPO neurons weresubsequently revealed by their sensitivity to compromised trans-membraneCa²⁺ flux in the presence of TTX. The most-likely explanationfor the broadening of the action potential and unmasking ofthe shoulder is block of K⁺ conductances. Similar modulatoryroles for neurotransmitters have been reported in other neurons,e.g., sympathetic neurons (Spanswick et al. 1995; Yoshimuraet al. 1986). Functionally, in these MnPO neurons, the broadeningof the action potential may enhance Ca²⁺ influx and thus contributeto the calcium-dependent regenerative mechanism underpinningthe pacemaker-like activity. Further experiments are requiredto clarify this issue.

Ang-II-induced calcium-dependent regenerative pacemaker activity

Ang-II-induced rhythmic activity persisted in the presence ofTTX, suggesting a direct effect on the cell. Furthermore, Ang-II-inducedburst firing was sensitive to changes in membrane potential,being progressively reduced with membrane hyperpolarizationto around –80 mV, beyond which activity ceased. Takentogether, these data suggest burst firing induced by Ang IIin MnPO neurons is generated by mechanisms intrinsic to thecell rather than through activation of local extrinsic synapticcircuits.

A role for calcium was clearly demonstrated by the fact thatAng-II-induced rhythmic activity was selectively blocked orabolished by maneuvers to inhibit calcium entry into the celleither by exposure to low-calcium/high-magnesium bathing mediumor to the nonselective Ca²⁺ channel blocker Co²⁺. These dataare consistent with Ang II inducing or unmasking a Ca²⁺-dependentregenerative mechanism that underlies the generation of rhythmicburst firing in these neurons. Furthermore, the appearance oflow-threshold T-type conductances in the presence of Ang IIsupports the notion that the peptide can induce or unmask aregenerative calcium-dependent mechanism that in part involvesactivation of a T-type Ca²⁺ conductance. This in turn providesthe driving force for activation of Na⁺ and high-threshold Ca²⁺conductance activation. These data therefore suggest that asubpopulation of MnPO neurons express ionic conductances thatpredispose them to electrical autorhythmicity, conditional onexposure to Ang II. The role of Ang II appears to be as "a trigger"because once activated rhythmic activity may persist for severaltens of minutes to hours after washout.

While it remains to be clarified as to how Ang II brings aboutthis shift to autorhythmic electrical activity, blockade ofa resting membrane leak conductance appears to be pivotal. Wesuggest that resting membrane K⁺ conductances act as a "shunt"to suppress intrinsic oscillatory conductances. Ang II effectivelyremoves this shunt and modulates spike repolarization leadingto increased Ca²⁺ influx and Ca²⁺-dependent autorhythmicity.However, we cannot discount the possibility that other mechanisms,including direct modulation of calcium conductances, may beinvolved.

Ang-II-induced burst firing described here is the product ofintrinsic membrane conductances that create a slow depolarizingwave that triggers multiple spikes. Mechanisms for generatingslow depolarizing shifts vary among cell types and can involvecalcium spikes (White et al. 1989), noninactivating sodium conductances(Azouz et al. 1996; Jensen et al. 1996), low-threshold calciumconductances (Llinas and Yarom 1981; van Den Top et al. 2004),and the hyperpolarization-activated nonselected cation conductanceI_h (Pape 1996; Robinson and Siegelbaum 2003). The ability togenerate burst firing is also not a fixed feature of neuronsas changes in resting membrane potential required for low-thresholdcalcium and I_h activation (Steriade and Llinas 1988), changesin extracellular potassium concentration (Jensen et al. 1994)and neurotransmitters (Azouz et al. 1994; Wang and McCormick1993) affect the ability of a neuron to generate bursts. Thesituation described in these MnPO neurons is reminiscent ofthat previously described in the inferior olive (Jahnsen andLlinas 1984; Llinas and Yarom 1986) and arcuate nucleus of thehypothalamus (van Den Top et al. 2004).

Functional implications

Increases in plasma and cerebrospinal fluid osmolality, andcirculating Ang II levels can instigate a series of responsesaimed at the conservation and restoration of fluid volume. Theseinclude drinking, elevations in vasopressin release, and a suppressionof sweating to eliminate evaporative heat loss. The outcomeof earlier lesion studies reveal that the MnPO is essentialfor the drinking response induced by central and peripheraladministration of Ang II and has a pivotal role in coordinatingthe central drive to drink induced by elevated levels of AngII (Cunningham et al. 1991). Neurons with autorhythmic electricaloscillatory properties are thought to be important in many functionalroles and behaviors including sleep-wakefulness, attention,motor co-ordination, development of neural connections, andlearning and memory (see Llinas 1988). Recent experiments suggest"bursts" may be a more efficient and reliable means of neuronalcommunication of information (see Lisman 1997). Data presentedhere suggest that activation of neurons in MnPO by Ang II inducesprolonged autorhythmic electrical activity that may underliethe central cellular mechanism resulting in behavioral changesappropriate to the restoration and conservation of body fluidhomeostasis. The fact that these neurons represent a subpopulationof MnPO neurons suggests functional specialization. This mayreflect a specific chemical phenotype of MnPO neuron or neuronswith a target and function-specific organization. In relationto this point, recent studies in the arcuate nucleus revealedorexigen-sensitive NPY/AgRP pacemaker-like cells similar tothose described here (van Den Top et al. 2004) that may playa pivotal role in the central drive to feed. It is interestingto speculate that conditional pacemakers such as these may formcomponent parts of conserved central pattern generators underpinningthe central drive to drink in the case of the MnPO and to feedin the case of the arcuate nucleus. Further studies are requiredto fully appreciate the functional significance of these conditionalpacemaker neurons.

GRANTS

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METHODS
RESULTS
DISCUSSION
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ACKNOWLEDGMENTS
REFERENCES

This research was supported by the Canadian Institutes of HealthResearch and the Heart and Stroke Foundation of Canada.

ACKNOWLEDGMENTS

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INTRODUCTION
METHODS
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We thank E. Coderre for excellent technical assistance.

FOOTNOTES

The costs of publication of this article were defrayed in partby the payment of page charges. The article must therefore behereby marked "advertisement" in accordance with 18 U.S.C. Section1734 solely to indicate this fact.

Address for reprint requests and other correspondence: L. P Renaud, Neurosciences, Ottawa Health Research Institute, 725 Parkdale Ave., Ottawa, Ontario, Canada K1Y 4E9 (E-mail: lprenaud{at}ohri.ca)

REFERENCES

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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

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