Circadian Phase Shifts to Neuropeptide Y In Vitro: Cellular Communication and Signal Transduction

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Volume 17, Number 21, Issue of November 1, 1997 pp. 8468-8475
Copyright ©1997 Society for Neuroscience

Circadian Phase Shifts to Neuropeptide Y In Vitro: Cellular Communication and Signal Transduction

Stephany M. Biello, Diego A. Golombek, Kathryn M. Schak, and Mary E. Harrington
Department of Psychology, Clark Science Center, Smith College, Northampton, MA 01063

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Mammalian circadian rhythms originate in the hypothalamic suprachiasmatic nuclei (SCN), from which rhythmic neural activitycan be recorded in vitro. Application of neurochemicals can resetthis rhythm. Here we determine cellular correlates of the phase-shiftingproperties of neuropeptide Y (NPY) on the hamster circadian clockin vitro. Drug or control treatments were applied to hypothalamicslices containing the SCN on the first day in vitro. The firingrates of individual cells were sampled on the second day in vitro.Control slices exhibited a peak in firing rate in the middle ofthe day. Microdrop application of NPY to the SCN phase advancedthe time of peak firing rate. This phase-shifting effect of NPYwas not altered by block of sodium channels with tetrodotoxinor block of calcium channels with cadmium and nickel, consistentwith a direct postsynaptic site of action. Pretreatment with theglutamate receptor antagonists (DL-2-amino-5-phosphonovalericacid and 6-cyano-7-nitroquinoxaline-2,3-dione disodium) also didnot alter phase shifts to NPY. Blocking GABA_A receptors with bicuculline(Bic) had effects only at very high (millimolar) doses of Bic,whereas blocking GABA_B receptors did not alter effects of NPY.Phase shifts to NPY were blocked by pretreatment with inhibitorsof protein kinase C (PKC), suggesting that PKC activation maybe necessary for these effects. Bathing the slice in low Ca²⁺/high Mg²⁺ can block phase shifts to NPY, possibly via a depolarizing action.A depolarizing high K⁺ bath can also block NPY phase shifts. The results are consistentwith direct action of NPY on pacemaker neurons, mediated througha signal transduction pathway that depends on activation of PKC.
Key words: neuropeptide Y; calcium; circadian; suprachiasmatic nucleus; PKC; hamster; GABA; TTX; phase shift; glutamate

INTRODUCTION

Mammalian circadian rhythms are generated and regulated by the hypothalamic suprachiasmatic nuclei (SCN) (Rusak and Zucker,1979; Ralph et al., 1990). SCN neurons exhibit a circadian rhythmin spontaneous activity that can be used as a marker of circadianclock output in vitro (Green and Gillette, 1982). The hypothalamicslice preparation allows recording of this rhythm for two to fourcycles (Gillette, 1991; Biello et al., 1997). Typically, treatmentsare applied on the first day in vitro, and firing rate is monitoredthroughout the second day. Phase shifts are measured by the differencebetween the time of the peak in firing rate in treated versuscontrol brain slice preparations.

The circadian clock can phase shift in response to photic stimuli. The phase-response curve for light shows characteristicphase delays early in the night followed by phase advances laterin the night (DeCoursey, 1964). In contrast, the circadian clockis sensitive to nonphotic stimuli during the subjective day andis less sensitive or insensitive during the subjective night (Smithet al., 1992; Mrosovsky, 1995). Nonphotic phase shifts can beinduced by behavioral events such as novel wheel-induced runningor social interactions (Reebs and Mrosovsky, 1989).

The SCN receive input from the intergeniculate leaflet, and the associated neurochemical neuropeptide Y (NPY) seems to mediatesome nonphotic phase shifts of the circadian clock. Lesions ofthe hamster geniculohypothalamic tract block nonphotic phase shifts(Johnson et al., 1988; Biello et al., 1991; Meyer et al., 1993;Janik and Mrosovsky, 1994). NPY can induce nonphotic-type phaseshifts in rats and hamsters in vivo (Albers and Ferris, 1984;Huhman and Albers, 1994; Biello and Mrosovsky, 1996) and in vitro(Shibata and Moore, 1993; Golombek et al., 1996; Biello et al.,1997; but see Medanic and Gillette, 1993). Infusion of antiserumto NPY into the area of the hamster SCN blocks phase shifts toinduced activity (Biello et al., 1994). Finally, nonphotic pulsesinduce the expression of c-Fos in NPY-immunoreactive neurons ofthe intergeniculate leaflet (Janik et al., 1995).

In the hamster, we have shown that the response to NPY is dose-dependent and is mediated through Y2 receptors (Golombek etal., 1996), a result similar to that found in vivo (Huhman etal., 1996a). Although the phase-shifting effects of NPY measuredin vivo in the hamster are blocked by co-infusion with tetrodotoxin(TTX) (Huhman et al., 1996b), similar phase shifts measured invitro in the rat are unaffected by sodium channel block, suggestinga direct postsynaptic effect on the pacemaker cell (Shibata andMoore, 1993). However, GABA transmission has also been implicatedin mediating phase shifts to NPY, because co-infusion of bicuculline(Bic) with NPY in vivo prevented the phase shift (Huhman et al.,1995).

One approach to understanding the mechanism of the clock is to follow the pathway of a phase-shifting stimulus and determinethe biochemical events associated with its action. Thus, the aimof the present study is to determine the signal transduction mechanismsresponsible for NPY-induced long-term modifications of the hamstercircadian clock in vitro.

MATERIALS AND METHODS
Animals and tissue preparation. Male golden hamsters (LVG, Charles River Laboratories, Wilmington, MA) (1-6 months of age)were housed in one of two rooms under opposite photoperiods, withboth rooms under a schedule of 14 hr light/10 hr dark. Lightsoff in the animal room was designated Zeitgeber time (ZT) 12 byconvention. Hamsters were administered an overdose of halothaneanesthesia and decapitated at times when this manipulation doesnot induce phase shifts, generally between ZT 2 and 5 (Gillette,1986). Hypothalamic slices (400-500 µm) containing the SCN wereplaced in a gas-fluid interface slice chamber (Medical SystemsBSC with Haas top) and bathed continuously (1 ml/min) in artificialcerebrospinal fluid (ACSF) containing 125.2 mM NaCl, 3.8 mM KCl,1.2 mM KH₂PO₄, 1.8 mM CaCl₂, 1 mM MgSO₄, 24.8 mM NaHCO₃, 10 mMglucose. ACSF, pH 7.4, was supplemented with an antibiotic (gentamicin,0.05 gm/l) and a fungicide (amphotericin, 2 mg/l), maintainedat 34.5°C with warm, humidified 95% oxygen/5% carbon dioxide.

Electrophysiological recording and data analysis. Extracellular single unit activity of SCN cells was detected with glassmicropipette electrodes filled with either 2 M NaCl or ACSF, advancedthrough the slice using a hydraulic microdrive. The signal wasamplified, filtered, and monitored with an oscilloscope and audiomonitor. The average spontaneous firing rate (measured for 1 min)and the ZT for each single unit encountered were recorded by anexperimenter blind to all treatments. Slices without significantdifferences across firing rate data grouped into 1 hr bins (p< 0.05; ANOVA) were not used for further analysis. If there weresignificant differences, data were smoothed by 1 hr running meanswith a 15 min lag. The time corresponding to the maximum of thesmoothed data was used as the time of the peak firing. Phase shiftswere measured relative to the average time of peak firing of controlslices. Some of the data for control, NPY, and glutamate-treated(ZT 14) slices have been published previously (Golombek et al.,1996; Biello et al., 1997).

Drugs and treatments. Unless noted otherwise, drugs were warmed to 34.5°C and applied as 200 nl microdrops to the SCN areaat ZT 6, at least 1 hr after slice preparation, using a Hamilton1 µl syringe. Recordings were performed for 6-12 hr during ZT0-12 of the second day in vitro. NPY was applied as a 200 ng/200nl (175 µM, in ACSF) drop, a dose similar to that used in in vivostudies of NPY-induced phase shifts (Biello et al., 1994). Whentwo agents were applied there was a 5 min interval between drops.

NPY (porcine) was obtained from Bachem Bioscience (Philadelphia, PA). The cyclic nucleotide-dependent protein kinase inhibitorH-8, the cAMP-dependent protein kinase inhibitor H-89, the glutamatereceptor antagonists DL-2-amino-5-phosphonovaleric acid (AP-5)and 6-cyano-7-nitroquinoxaline-2,3-dione disodium (CNQX), andthe phorbol esters phorbol 12-myristate 13-acetate (PMA) and phorbol12,13-dibutyrate (PDBu; less hydrophobic than PMA), were all fromResearch Biochemicals International (Natick, MA). The proteinkinase C (PKC) inhibitor chelerythrine chloride (Chel) was fromLC Laboratories (Woburn, MA). The PKC inhibitors calphostin C(Cal) and bisindolylmalemide I (Bis) were from Calbiochem (LaJolla, CA). Because Cal is light-activated, the drug was not exposedto light until application to the tissue, when lights were kepton the preparation for at least 10 min. Bicuculline methiodide,glutamate, cadmium chloride, calcium chloride, magnesium chloride,and TTX were from Sigma (St. Louis, MO). Nickel chloride was obtainedfrom Fisher Scientific (Pittsburgh, PA). The GABA_B receptor blockerCGP-35348 (CGP) was a gift from Ciba-Geigy (Basel, Switzerland).Several drugs (PMA, PDBu, CGP, Cal, Chel, H-89) were initiallydissolved in DMSO and brought to final concentration with ACSF( $<=$ 0.1% DMSO in the final solution in all cases except 5 µM Cal,where the final concentration was 1% DMSO; controls showed noeffect of DMSO on rhythm phase).

RESULTS

NPY phase shifts
Control slices receiving either no application or application of one or two ACSF microdrops at ZT 6 showed peak firing ratebetween ZT 6.1 and 7.3 on the subsequent day in vitro (n = 10;mean ± SEM, 6.7 ± 0.1) (Fig. 1A, Table 1). An application ofNPY (200 ng/200 nl) at ZT 6 on the first day in vitro induceda long-term modification in the circadian clock so that the timeof peak firing occurred between ZT 2.0 and 3.7 on the second dayin vitro (n = 7; mean phase shift ± SEM, 3.6 ± 0.2) (Fig. 1B,Table 1) and at ZT 3.4 in a slice recorded on the third day invitro. Results were similar whether NPY was applied as a singlemicrodrop or whether the NPY application was preceded or followedby an ACSF application (Table 1).
Fig. 1. Average firing rate of individual SCN cells (dots) plotted against the Zeitgeber time (ZT) of recording. ZT 12 is definedas the time of lights off in the animal's previous light/darkcycle. Animals were killed between ZT 2 and ZT 10, and sliceswere kept in the chamber until recording the following day. Theline indicates results from the running mean smoother. A, Resultsfrom slices receiving no application; B, results from slices receivingNPY (175 µM; 200 nl) application at ZT 6 on day 1 in vitro.
[View Larger Version of this Image (17K GIF file)]

Table 1. Mean peak times of control slices and mean phase shifts to NPY (measured relative to the average time of peak firing of controlslices)

Treatment Number of slices Average peak times (hr ± SEM) Average phase shift (hr ± SEM)

No treatment 6 6.7 ± 0.1

ACSF + ACSF 3 6.8 ± 0.2

ACSF 1 6.1

NPY + ACSF 1 3.1

NPY alone 3 3.4 ± 0.3

ACSF + NPY 3 3.9 ± 0.4

Postsynaptic action of NPY
Initially we performed several experiments to determine whether phase shifts induced by NPY depended on release of transmitterwithin the SCN (summarized in Table 2). We used TTX, a blockerof sodium channels. First, we co-applied NPY with TTX at a concentration(1 µM, 200 nl) that has been shown to block NPY phase shifts invivo (Huhman et al., 1996b). This treatment in vitro did not blockphase shifts to NPY, nor did a higher dose (10 µM), although itsuppressed firing for ~3 hr (ANOVA F_(2,14) = 45.2; p < 0.0001;TTX 1 and 10 µM + NPY grouped and NPY not significantly differentfrom each other, but significantly different from TTX 1 and 10µM + ACSF grouped). There was no phase-shifting effect of TTXalone. To eliminate calcium spikes and calcium-mediated neurotransmitterrelease, we treated slices with cadmium and nickel to block allvoltage-dependent Ca²⁺ currents (Huang, 1993). Pretreatment with TTX (10 µM), cadmium(20 µM), and nickel (100 µM) in a 200 nl microdrop applied beforeNPY did not reduce the NPY phase shift (Table 2, TTX/Cd/Ni).Similarly, a 3 hr treatment with cadmium (20 µM) and nickel (100µM) in the bath (ZT 5.5-8.5), combined with a microdrop of TTX(10 µM, 200 nl; 5 min before the NPY; TTX+(Cd/Ni)) did not alterthe long-term effect of NPY on the circadian clock (Fig. 2, Table2) (ANOVA F_(2,17) = 83.8; p < 0.0001; TTX/Cd/Ni + NPY, TTX+(Cd/Ni)+ NPY grouped and NPY not significantly different from each other,but significantly different from TTX/Cd/Ni + ACSF and TTX+(Cd/Ni)+ ACSF grouped).

Table 2. Mean phase shifts to NPY or ACSF combined with tetrodotoxin (TTX) (1 µM and 10 µM) and TTX (10 µM) microdrop + cadmium (20µM) + nickel (100 µM) (microdrop TTX/Cd/Ni and bath TTX + (Cd/Ni)applications)

Treatment Number of slices Average phase shift (hr ± SEM)

TTX 1 µM + NPY 2 3.3 ± 0.3

TTX 10 µM + NPY 3 3.2 ± 0.4

TTX 10 µM + ACSF 3 0.2 ± 0.1

TTX/Cd/Ni + NPY 3 3.3 ± 0.1

TTX/Cd/Ni + ACSF 3 0.4 ± 0.1

TTX + (Cd/Ni) + NPY 2 3.5 ± 0.5

TTX + (Cd/Ni) + ACSF 3 0.5 ± 0.1

Shifts are measured relative to the average time of peak firing of control slices.

Fig. 2. Histogram showing phase shifts to NPY or ACSF combined with tetrodotoxin (TTX) (1 and 10 µM grouped) and TTX (10 µM) + cadmium(20 µM) + nickel (100 µM) (TTX + Cd + Ni) (bath and microdropapplications combined), or low Ca²⁺ (0.02 mM)/high Mg²⁺ (10 mM) bath. Mean phase shifts ± SEM.
[View Larger Version of this Image (14K GIF file)]

Previous studies in vivo suggested a role for GABA in mediating NPY phase shifts, so we investigated effects of blocking GABAreceptors on NPY shifts in vitro. At high concentrations, Bic(1.2 mM, 200 nl) blocked the phase-shifting action of NPY (Table3). This dose of Bic was similar to that shown to block NPY phaseshifts in vivo (Huhman et al., 1995). However, such a high doseof Bic is associated with nonspecific effects (Olsen et al., 1978;Lester and Peck, 1979). When we reduced the dose to 100 µM, Bicgiven as a microdrop or administered for 1 hr (ZT 5.5-6.5) inthe bath did not block phase shifts to NPY. The GABA_B receptorblocker CPG-35348 (CPG; 100 µM; 200 nl) did not block phase shiftsto NPY either (Fig. 3, Table 3). At this concentration, thisdrug should act as an antagonist at both GABA_B R1a and -b subtypes(Kaupmann et al., 1997) [ANOVA F_(4,18) = 17; p < 0.0001; NPY +CGP and NPY + Bic (100 µM; bath and microdrop grouped) significantlydifferent from Bic (100 µM; bath) + ACSF and CGP + ACSF, but notfrom each other; NPY + CGP and NPY + Bic (100 µM; bath and microdropgrouped) not significantly different from NPY].

Table 3. Mean phase shifts to NPY or ACSF combined with treatments that interfere with GABA transmission

Treatment Number of slices Average phase shift (hr ± SEM)

Bic (1.2 mM, 200 nl) + ACSF 3 0.3 ± 0.2

Bic (1.2 mM; 200 nl) + NPY 3 0.5 ± 0.2

Bic (100 µM; 200 nl) + NPY 3 2.6 ± 0.3

Bic (100 µM; 1 hr bath) + NPY 3 3.0 ± 0.1

Bic (100 µM; 1 hr bath) + ACSF 3 1.1 ± 0.5

CGP (100 µM; 200 nl) + ACSF 3 0.6 ± 0.1

CGP (100 µM; 200 nl) + NPY 3 2.8 ± 0.3

Shifts are measured relative to the average time of peak firing of control slices. Bic, Bicuculline; CPG, CPG 35348.

Fig. 3. Histogram showing phase shifts to NPY or ACSF combined with treatments that interfere with GABA transmission, bicuculline(100 µM), and CPG-35348 (CPG) (100 µM). Mean phase shifts ± SEM.
[View Larger Version of this Image (16K GIF file)]

Previous studies suggested that NPY alters intracellular calcium levels through effects on glutamate transmission (van denPol et al., 1996). To test for a similar mode of action, we appliedthe glutamate receptor antagonists AP-5 (100 µM) and CNQX (10µM) in the bath for 1 hr (ZT 5.5-6.5) and then applied NPY atZT 6. These antagonists did not alter phase shifts to NPY andhad no phase-shifting effect by themselves (Table 4) (ANOVA F_(2,13)= 51.3; p < 0.0001; AP-5/CNQX + NPY and NPY not significantlydifferent from each other, but significantly different from AP-5/CNQX+ ACSF). To check that the bath application of AP-5 and CNQX didindeed block glutamate receptors, we applied AP-5 and CNQX inthe bath (ZT 13.5-14.5) before an application of glutamate atZT 14. Application of glutamate (1 mM; 200 nl) at ZT 14 inducesan average phase delay in the time of peak firing of 4.5 hr (Bielloet al., 1997) (n = 5; SEM = 0.5). Bath application of glutamateantagonists for 1 hr was able to block glutamate phase shifts(Table 4) (df = 5; t = $-$ 14; p < 0.0001).

Table 4. Mean phase shifts to NPY or ACSF combined with substances that interfere with glutamate transmission

Treatment Number of slices Average phase shift (hr ± SEM)

AP-5/CNQX + ACSF(CT6) 3 0.4 ± 0.2

AP-5/CNQX + NPY(CT6) 4 3.9 ± 0.2

Glutamate (CT14) 5 $-$ 4.5 ± 0.5

AP-5/CNQX + glutamate (CT14) 3 1.2 ± 0.1

AP-5/CNQX + ACSF (CT14) 1 0.4

Shifts are measured relative to the average time of peak firing of control slices. Glutamate receptor blockers AP-5 (100 µM)and CNQX (10 µM) were applied in the bath for 1 hr.

NPY signal transduction
After finding that the phase-shifting effect of NPY was consistent with a direct postsynaptic effect, we began to investigatethe signal transduction events that followed application of NPY.We investigated the role of protein kinases in phase shifts toNPY. Pretreatment with a cyclic nucleotide-dependent protein kinaseinhibitor (H-8; 200 nl, 50 µM) did not alter the phase-shiftingaction of NPY (n = 3), nor did it induce phase shifts when administeredalone (n = 3) (Table 5) (ANOVA F_(3,22) = 104; p < 0.0001; NPYand H-8+NPY different from control; H-8+ACSF not significantlydifferent from control). Additionally, H-89 (either 200 nl of50 µM or 1 hr bath of 10 µM), a specific cAMP-dependent proteinkinase inhibitor, did not affect NPY-induced phase shifts (n =4) and in combination with ACSF (n = 1) did not have any effecton the time of peak firing (Table 5) (ANOVA F_(2,18) = 153; p< 0.001; NPY and H-89 + NPY different from H-89 + ACSF but notsignificantly different from each other).

Table 5. Mean phase shifts to NPY or ACSF combined with substances related to protein kinases

Treatment Number of slices Average phase shift (hr ± SEM)

H-8 (50 µM; 200 nl) + ACSF 3 0.7 ± 0.1

H-8 (50 µM; 200 nl) + NPY 3 3.1 ± 0.2

H-89 (50 µM; 200 nl) + ACSF and H-89 (10 µM; 1 hr) + ACSF 2 0 ± 0.8

H-89 (50 µM; 200 nl) + NPY and H-89 (10 µM; 1 hr) + NPY 4 3.3 ± 0.6

Chel (10 µM; 200 nl) + ACSF 3 0.4 ± 0.3

Chel (10 µM; 200 nl) + NPY 3 0.9 ± 0.5

Cal (0.5 µM; 200 nl) 2 0.3 ± 0.1

Cal (0.5 µM, 200 nl) + NPY 3 3.6 ± 1.5

Cal (5 µM; 200 nl) + ACSF 2 0.8 ± 0.2

Cal (5 µM; 200 nl) + NPY 3 0.0 ± 0.2

Bis (0.1 µM, 200 nl) and Bis (0.1 µM; 200 nl) + ACSF 3 $-$ 0.3 ± 0.2

Bis (0.1 µM; 200 nl) + NPY 3 0.6 ± 0.3

PDBu (10 nM; 200 nl) and PDBu (10 nM; 200 nl) + ACSF 4 2.6 ± 0.6

PMA (1 nM; 200 nl) 3 2.3 ± 0.4

Chel (10 µM; 200 nl) + PMA (1 nM; 200 nl) and PMA (1 nM; 200 nl) + Chel (10 µM; 200 nl) 3 0.7 ± 0.3

PMA (10 nM; 200 nl) 3 3.8 ± 0.2

Chel (10 µM; 200 nl) + PMA (10 nM; 200 nl) 3 2.6 ± 0.7

low Ca²⁺/high Mg²⁺ (2 hr) + NPY 3 0.5 ± 0.4

low Ca²⁺/high Mg²⁺ (2 hr) + ACSF 4 0.7 ± 0.6

low Ca²⁺/high Mg²⁺ (15 min) + NPY 3 0.7 ± 0.1

high K⁺ ACSF (50 mM, 1 hr) + NPY 2 $-$ 0.3 ± 0.8

Shifts are measured relative to the average time of peak firing of control slices. Chel, Chelerythrine chloride; Cal, calphostinC; Bis, bisindolylmalemide.

To test whether NPY phase shifts are mediated through activation of PKC, we blocked PKC with the specific inhibitors Chel(10 µM, 200 nl; n = 3), Cal (both 0.5 and 5 µM, 200 nl; n = 6),or Bis (0.1 µM, 200 nl; n = 3). These inhibitors blocked NPY-inducedphase advances, without showing any effects when administeredalone (Fig. 4, Table 5) [ANOVA; no significant differences betweenChel + NPY, Cal (5 µM) + NPY, Bis + NPY, Chel + ACSF, Cal (5 µM)+ ACSF, Bis + ACSF]. Effects of Cal seemed to be dose-dependentin that the NPY effect was blocked in only one of three slicesat the lower dose tested (0.5 µM) but in all three slices exposedto the higher dose (5 µM). We also activated PKC through applicationof the phorbol esters PDBu (10 nM) and PMA (1 nM, 10 nM). Thesephorbol esters induced long-term shifts in circadian clock phasesimilar to those induced by NPY (Table 5) (ANOVA; no significantdifference between PMA 10 nM, PDBu, and NPY). Effects of PMA weredose-dependent and reduced by pretreatment with the PKC inhibitorChel (10 µM, PMA 10 nM; df = 7; t = 4.1; p < 0.005).
Fig. 4. Histogram showing phase shifts to NPY (175 µM) alone, or combined with inhibitors of PKC [chelerythrine chloride (Chel; 10µM), calphostin C (Cal; 5 µM), bisindolylmalemide I (Bis; 0.1µM), and phase shifts to phorbol esters (PDBu, 10 nM; PMA, 10nM)] at ZT 6. Mean ± SEM.
[View Larger Version of this Image (15K GIF file)]

By bathing the slice in ACSF with lowered Ca²⁺ (to 0.05 mM) and increased Mg²⁺ (to 10 mM) (Pan et al., 1992), ZT 5-7 blocked the phase advanceinduced by NPY at ZT 6, suggesting a role for calcium in phaseshifts to NPY. The change in ACSF Ca²⁺ and Mg²⁺ levels did not affect the timing of the firing rate rhythm byitself (Fig. 2, Table 5) (ANOVA F_(2,13) = 22.5; p < 0.0001; lowCa²⁺/high Mg²⁺ + NPY and low Ca²⁺/high Mg²⁺ + ACSF not significantly different from each other, but significantlydifferent from NPY). Because this treatment would also be expectedto depolarize neurons (Pan et al., 1992), we tested the effectsof high K⁺ ACSF on NPY phase shifts. Bathing of the slice in ACSF with 50mM KCl (and 75.2 mM NaCl) for 1 hr (ZT 5.5-6.5) blocked the NPYphase shift (Table 5). A 15 min bath of low Ca²⁺ and high Mg²⁺ ACSF centered on the time of NPY application also blocked theNPY phase shift (Table 5).

DISCUSSION
Our data are consistent with the hypothesis that NPY resets the circadian clock in vitro via a direct postsynaptic effect.Although one study reports that TTX does not block NPY-inducedphase shifts in rat SCN in vitro (Shibata and Moore, 1993), otherwork indicates that TTX blocks in vivo NPY-induced phase shiftsin hamsters (Huhman et al., 1996b). Our results support and extendthe previous in vitro results, indicating that the discrepancymay arise from a difference between the in vivo and in vitro experimentsand is not attributable to a species difference. We attemptedto mimic the conditions of the previous in vivo experiments butobtained different results. Our studies indicate that the NPY-responsiveSCN cells are capable of generating a permanent phase shift ofthe entire circadian clock, even in the absence of sodium-dependentaction potentials.

Cells in the SCN show calcium spikes that are not blocked by TTX (Llinás and Hess, 1976; Huang, 1993; van den Pol and Dudek,1993), and it was possible that these might mediate the effectsof NPY. We used cadmium and nickel to block voltage-gated Ca²⁺ currents and Ca²⁺ spikes as well as calcium-mediated neurotransmitter release anddid not observe a change in the NPY effect. These experimentsfurther indicate that the action of NPY does not require extracellularcalcium influx via voltage-gated channels, because block of thesechannels by cadmium and nickel did not reduce the shift. Furthermore,decreased calcium influx at ZT 5.5-8.5 does not phase shift thecircadian clock, because block of these channels did not producephase shifts when given in the absence of NPY.

Previous reports have indicated a possible role for GABA in phase shifts during the subjective day. Bic, a GABA_A antagonist,blocks NPY-induced phase shifts in vivo (Huhman et al., 1995),suggesting that GABAergic neurons may be targets of NPY-responsivecells or may be directly NPY-responsive, or that simultaneousactivation of NPY and GABA_A receptors is necessary for a phaseshift. Our data suggest that this role may be minimal, becauseboth GABA_A and GABA_B receptor antagonists generally do not blockphase shifts to NPY. Bic is specific for GABA_A receptors in themicromolar concentration range (Olsen et al., 1978; Lester andPeck, 1979), and at 10-50 µM in the bath, Bic blocks all IPSCsin rat and guinea pig SCN slices (Kim and Dudek, 1993). This wouldsuggest that effects reported in earlier in vivo studies (Huhmanet al., 1995) may be the result of a nonspecific action by millimolarconcentrations of Bic. For instance, at high concentrations Biccan inhibit acetylcholinesterase activity (Frigo et al., 1987),may depolarize neurons by blocking a potassium conductance (Heyeret al., 1982), and can have other nonspecific effects (Bartoliniet al., 1990).

TTX (1 µM) blocks most IPSCs but does not block spontaneous EPSCs in SCN brain slices (Jiang et al., 1995a). Excitatory eventsin the SCN are blocked by the glutamate receptor blockers AP5and CNQX (Kim and Dudek, 1991; van den Pol et al., 1996). However,application of these glutamate receptor blockers did not alterphase shifts to NPY, lending support to the possibility that NPYacts on a postsynaptic site.

Our results suggest that NPY resets the hamster circadian clock via activation of PKC. PKC has been identified in the SCN(Van der Zee and Bult, 1995), and NPY-induced phase shifts weremimicked by two PKC activators, the phorbol esters PMA and PDBu.Another phorbol ester that activates PKC, 12-O-tetradecanoylphorbol13-acetate, has been shown to induce phase shifts in rat SCN invitro. At CT6, however, these shifts were minimal, possibly attributableto a species difference (McArthur et al., 1997). NPY-induced phaseshifts were blocked by pretreatment with three different inhibitorsof PKC, which work by inhibiting this kinase through differentspecific mechanisms. Chel acts on the catalytic domain of PKCand is a noncompetitive inhibitor with respect to ATP and a competitiveinhibitor with respect to the phosphate acceptor (Jarvis et al.,1994). Cal interacts with the regulatory domain of PKC by competingat the binding site of diacylglycerol and phorbol esters (Tamaokiand Nakano, 1990). Bis acts as a competitive inhibitor for theATP binding site on the catalytic domain of PKC (Toullec et al.,1991).

NPY did not have long-term effects on circadian rhythm phase if the slice was bathed in low Ca²⁺/high Mg²⁺ ACSF during the time of NPY application. One explanation of thisresult might be that the reduction of extracellular calcium induceddepletion of intracellular calcium stores (Llano et al., 1994),thus reducing the NPY activation of PKC. One concern is that thelow Ca²⁺ conditions might affect the integrity of the NPY receptors (Parkeret al., 1996), alter general cell functioning, or depolarize cellseither by reducing positive surface charges on the extracellularmembrane or by potentiating glutamatergic currents (Alberi etal., 1997). Low Ca²⁺/high Mg²⁺ ACSF has been reported to depolarize SCN cells (Pan et al., 1992),and depolarization might block NPY phase shifts (Biello et al.,1997). The hypothesis that low Ca²⁺/high Mg²⁺ ACSF may act via depolarization is supported by our results showingthat even a 15 min bath of low Ca²⁺/high Mg²⁺ ACSF can block NPY phase shifts, and that a depolarizing highK⁺ bath has a similar effect.

Nonphotic stimuli do not seem to be using a single signal transduction pathway to reach the circadian clock. Although NPYand serotonin are similar in that both shift the clock even whencells are bathed in TTX (Prosser et al., 1992; this paper), NPYand serotonin induce nonphotic phase shifts via different signaltransduction pathways. NPY seems to activate PKC, whereas serotonin-mediatedphase shifting in the rat is dependent on activity of cAMP-dependentprotein kinase (Prosser et al., 1994). Because these two neurotransmittersinduce phase shifts in similar patterns, it is plausible thattheir signal transduction pathways converge at some point. Interestingly,both NPY and serotonin phase shifts seem to depend on K⁺ channel activation (Prosser et al., 1994; Hall and Harrington,1996; our unpublished results). Melatonin also phase shifts thecircadian clock in the subjective day and seems to use PKC (McArthuret al., 1997); effects of melatonin on K⁺ channels, however, are observed only at concentrations well abovethose necessary for phase shifting (Jiang et al., 1995b).

Various NPY receptor types function in the SCN. Although Y2 receptors mediate phase shifts to NPY both in vivo (Huhman etal., 1996a) and in vitro (Golombek et al., 1996), NPY blocks pituitaryadenylate cyclase-activating peptide phase shifts via a receptorother than the Y2 receptor (Harrington and Hoque, 1997).

NPY induces long-term depression in both electrical activity and glutamate-evoked increases in intracellular calcium levelsin mature rat SCN cultures and slices (van den Pol et al., 1996)or GABA-evoked increases in less mature cultures (Obrietan andvan den Pol, 1996). These effects are largely mediated presynaptically,by both Y1 and Y2 NPY receptor subtypes (Chen and van den Pol,1996; Obrietan and van den Pol, 1996; van den Pol et al., 1996).All of these long-term effects of NPY in the rat SCN are abolishedin the presence of AP5 and CNQX (van den Pol et al., 1996). BecauseNPY can phase shift the hamster SCN in the presence of AP5 andCNQX, the long-term effects of NPY on intracellular free calcium(van den Pol et al., 1996) may not be related to phase shifting.Furthermore, although SCN neurons dramatically increase firingrate around ZT 6, our experiments demonstrate that block of calciumchannels and ionotropic glutamate receptors has no effect on thetime of peak firing on the subsequent cycle. Thus, the intracellularcalcium level may not be an integral clock component at ZT 6.Interestingly, the only response to NPY that persisted when AP5/CNQXwas included in van den Pol's studies was a brief hyperpolarizationof the postsynaptic membrane.

These data suggest a general model for the mechanism of nonphotic phase shifting of the circadian clock. Because both NPYand serotonin seem to activate protein kinases, one might hypothesizethat either PKA or PKC can phosphorylate a putative clock protein.Phosphorylation might act to induce nuclear translocation of aprotein, similar to circadian systems studied in Drosophila andNeurospora (Edery et al., 1994; Garceau et al., 1997). In bothsystems, it is thought that nuclear translocation of clock protein(s)allows initiation of a negative feedback loop, by which theseproteins negatively regulate their own gene's transcription (Hardinet al., 1990; Aronson et al., 1994). If a similar system wereunderlying the mammalian clock, one might predict that the clockprotein is normally phosphorylated late in the subjective day,thus reducing the ability of NPY and serotonin to phase shift.From this, a further prediction would be that PKA or PKC inhibitorswould delay the clock if applied during this time; preliminarydata supporting this has been reported (Prosser et al., 1994).

Although there is some understanding of the intracellular mechanisms leading to photic entrainment of circadian rhythms, littleis known about the events leading to nonphotic stimulation ofthe clock. The present study is the first to present data on thesignal transduction pathways required for NPY-induced phase shiftsin the Syrian hamster. Our data are consistent with the hypothesisthat the effects of NPY are postsynaptic and depend on PKC. Althoughthis is unusual for an NPY receptor, which is more commonly linkedwith inhibition of adenylate cyclase, it is similar to reportedeffects of melatonin on circadian clock tissue. These resultsshould stimulate further work examining links between NPY andPKC in other systems, as well as possible links between the actionsof NPY and melatonin.

FOOTNOTES

Received June 9, 1997; revised Aug. 4, 1997; accepted Aug. 11, 1997.

This study was supported by National Institutes of Health Grant NS26496 (M.E.H.), National Research Service Award NS09804(S.M.B.), and a Howard Hughes Medical Institute stipend (K.M.S).The technical assistance of Edra Stern, Roselle Hoffmaster, andGina Rendon is gratefully acknowledged. We are grateful to Dr.Adam Hall for helpful discussions.

Reprint requests should be addressed to Dr. Stephany Biello, Psychology Department, Adam Smith Building, Bute Gardens, Universityof Glasgow, Glasgow, Scotland G12 R8T.

Dr. Golombek's present address: Departamento de Fisiologia, Facultad de Medicina, Universidad de Buenos Aires, Buenos Aires1121, Argentina.

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