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The Journal of Neuroscience, January 1, 1999, 19(1):206-219
Pituitary Adenylate Cyclase-Activating Polypeptide and Melatonin
in the Suprachiasmatic Nucleus: Effects on the Calcium Signal
Transduction Cascade
Michael D. A.
Kopp1, 2,
Christof
Schomerus1,
Faramarz
Dehghani1,
Horst-Werner
Korf1, and
Hilmar
Meissl2
1 Dr. Senckenbergische Anatomie, Anatomisches
Institut II, Johann Wolfgang Goethe-Universität, D-60590
Frankfurt, Germany, and 2 Max-Planck-Institut für
Physiologische und Klinische Forschung, W. G. Kerckhoff-Institut, D-61231 Bad Nauheim, Germany
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ABSTRACT |
The suprachiasmatic nucleus (SCN) harbors an endogenous oscillator
generating circadian rhythms that are synchronized to the external
light/dark cycle by photic information transmitted via the
retinohypothalamic tract (RHT). The RHT has recently been shown to
contain pituitary adenylate cyclase-activating polypeptide (PACAP) as
neurotransmitter/neuromodulator. PACAPergic effects on
cAMP-mediated signaling events in the SCN are restricted to distinct
time windows and sensitive to melatonin. In neurons isolated from the
SCN of neonatal rats we investigated by means of the fura-2 technique
whether PACAP and melatonin also influence the intracellular calcium
concentration ([Ca2+]i). PACAP
elicited increases of [Ca2+]i in 27%
of the analyzed neurons, many of which were also responsive to the RHT
neurotransmitters glutamate and/or substance P. PACAP-induced changes
of [Ca2+]i were independent of cAMP,
because they were not mimicked by forskolin or 8-bromo-cAMP. PACAP
caused G-protein- and phospholipase C-mediated calcium release from
inositol-trisphosphate-sensitive stores and subsequent protein kinase
C-mediated calcium influx, demonstrated by treatment with GDP- -S,
neomycin, U-73122, calcium-free saline, thapsigargin,
bisindolylmaleimide, and chelerythrine. The calcium influx was
insensitive to antagonists of voltage-gated calcium channels of the L-,
N-, P-, Q- and T-type (diltiazem, nifedipine, verapamil,  -conotoxin,
-agatoxin, amiloride). Immunocytochemical characterization of the
analyzed cells revealed that >50% of the PACAP-sensitive neurons were
GABA-immunopositive. Our data demonstrate that in the SCN PACAP affects
the [Ca2+]i, suggesting that
different signaling pathways (calcium as well as cAMP) are involved in
PACAPergic neurotransmission or neuromodulation. Melatonin did not
interfere with calcium signaling, indicating that in SCN neurons the
hormone primarily affects the cAMP signaling pathway.
Key words:
PACAP; substance P; glutamate; retinohypothalamic tract; suprachiasmatic nucleus; melatonin; circadian rhythm; calcium; phospholipase C; protein kinase C; GABA
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INTRODUCTION |
The hypothalamic suprachiasmatic
nucleus (SCN) of mammals is the primary endogenous oscillator
generating circadian rhythms that are synchronized with the
environmental light/dark cycle by photic information directly
transmitted from the retina via the retinohypothalamic tract (RHT).
This photic input is the major natural phase-shifting stimulus
(zeitgeber) that regularly resets the clock. The amino acid glutamate
and the neuropeptide substance P (SP) are
neurotransmitters/neuromodulators of the RHT that convey light
information to the oscillator and thus produce phase-shifts of SCN
activity during the night (for review, see Inouye and Shibata, 1994 ).
In contrast, pituitary adenylate cyclase-activating polypeptide (PACAP), recently proposed as another neuromodulator of the RHT, induces phase-shifts during the daytime, probably mediated via PACAP-induced phosphorylation/activation of the transcription factor
calcium/cAMP response element binding protein (CREB), a putative
mediator between light (or darkness) information and phase-shifting of
SCN activity rhythms. Thus, PACAPergic neurotransmission to the SCN may
encode darkness information (Fukuhara et al., 1997; Hannibal et al.,
1997; Kopp et al., 1997).
PACAP binding sites have been divided into different types based on the
relative affinities for PACAP and vasoactive intestinal polypeptide
(VIP), which shows 68% amino acid identity with the (1-28)N-terminal
sequence of PACAP. PACAP type II receptors bind PACAP and VIP with
equal affinity and are coupled to adenylate cyclase (AC) activity
(Ishihara et al., 1992; Lutz et al., 1993), whereas type I receptors
specifically bind to PACAP and exist in at least seven splice variants.
These receptor isoforms are coupled to phospholipase C (PLC) and/or AC
activity, with the exception of one isoform that is coupled to
activation of voltage-gated calcium channels (Spengler et al., 1993;
Chatterjee et al., 1996; Pantaloni et al., 1996). Furthermore, a third
PACAP receptor subtype has been cloned that binds to both PACAP and VIP
with high affinity and is coupled to AC and (probably) PLC activation
(Inagaki et al., 1994).
The hormone melatonin, which is synthesized in and released from the
pineal organ during the night and thus serves as an endocrine signal of
darkness, is another time cue acting on the SCN. Melatonin elicits its
effects via binding to mt1 and MT2 receptors
that are coupled to inhibition of the AC (Reppert et al., 1994; Liu et
al., 1997). In addition, recent reports demonstrated that melatonin also activates the calcium signaling pathway and thus affects PLC and
protein kinase C (PKC) activity (Godson and Reppert, 1997; McArthur et
al., 1997). Furthermore, in hypophysial gonadotrophs, melatonin has
been shown to have a direct influence on the intracellular calcium
concentration ([Ca2+]i) by
inhibition of calcium influx through voltage-sensitive channels
(Vanecek and Klein, 1992, 1995).
In the SCN the PACAP-induced activation of CREB, solely inducible at
distinct time windows, is sensitive to melatonin (Kopp et al., 1997).
In the present study we investigated the effects of PACAP and melatonin
on the calcium signal transduction cascade in SCN cells isolated from
neonatal rats to give further insight into the signaling events
affected by these phase-entraining substances in the biological clock.
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MATERIALS AND METHODS |
Cell culture. Wistar rats (Charles River, Sulzfeld,
Germany) were maintained in our rat colony under a 12 hr light/dark
cycle with food and water ad libitum. Newborn male and
female rats (1-7 d old) were killed by decapitation during the light
period, and the area of the SCN was punched out of hypothalamic brain
slices. The SCN was identified macroscopically by its position at the ventral surface of the hypothalamus, extending laterally to the third
ventricle and directly dorsally to the optic chiasm. The tissue was
transferred immediately to ice-cold Earle's Balanced Salt Solution
(EBSS) containing 10 mM HEPES and 7 mg/ml glucose. The
cells were dissociated by incubation in a papain digestion solution
(EBSS containing 10 mM HEPES, 7 mg/ml glucose, 5 mM EDTA, 1 mM L-cysteine,
and 20 U/ml papain) and repetitive pipetting. After complete
dissociation the cells were pelleted by centrifugation, and the papain
solution was removed. The cells were resuspended in EBSS containing 10 mM HEPES, 7 mg/ml glucose, 0.01% trypsin inhibitor, and
0.1% bovine serum albumin (BSA) and overlaid on an EBSS gradient
solution (EBSS containing 10 mM HEPES, 7 mg/ml glucose,
0.1% trypsin inhibitor, and 1% BSA). After a second centrifugation the cells were washed in DMEM/Nutrient Mix F12 (DMEM/F12)
supplemented with 10 mM HEPES, 2 mM glutamine,
100 U/ml penicillin, 100 µg/ml streptomycin, 100 µg/ml ascorbic
acid, and 10% fetal calf serum and finally plated onto
poly-L-lysine-coated coverslips with an internal grid.
Cultures were maintained in supplemented DMEM/F12 in an incubator at
37°C in an atmosphere of 7% CO2 and 93% air and
cultured for at least 5 d before the experiments.
Fluorescence microscopy and calcium imaging. For dye
loading, cells were incubated for 30 min at 37°C in artificial
CSF (aCSF) containing (in mM): NaCl 140, KCl 5, CaCl2 2, MgCl2 1, HEPES 10, and glucose 5 that
contained 3 µM fura-2 AM, the fluorescent calcium indicator (Molecular Probes, Eugene, OR). Thereafter the coverslips were mounted in a specially constructed superfusion chamber on the
heatable stage of a microscope (Axiovert 100; Zeiss,
Jena-Göttingen, Germany) and superfused with aCSF for 10 min
before drug application at a constant temperature of 37°C and at a
flow rate of 500 µl/min. All experiments were performed between 10 A.M. and 10 P.M., except the measurements after long-time treatment
with PACAP, which were performed during a 24 hr period from 9 A.M. to 9 A.M. Application of the drugs was performed by stopping the
superfusion and adding the drugs with a Pasteur pipette directly into
the superfusion chamber.
PACAP exists in two isoforms, PACAP38 and PACAP27, which share the same
N-terminal 27 amino acids and arise from a 175 amino acid precursor
peptide by tissue-specific post-translational processing (Miyata et
al., 1989, 1990). Because PACAP38 appears as the predominant product of
this processing of the PACAP precursor in the hypothalamus (Arimura et
al., 1991; Hannibal et al., 1995), we focused on this isoform of the
peptide. In most of the experiments PACAP was used at a concentration
of 100 nM. The inhibitors of G-protein, PLC, PKC, and
voltage-gated calcium channels, respectively, were applied for 3-10
min before stimulation with PACAP; pretreatment with melatonin extended
over a period of 5-30 min before PACAP application. All drugs tested
were stored as stock solutions at  20°C and diluted with prewarmed
aCSF immediately before use. The drugs were washed out by starting the
perfusion again, and complete washout of the chamber was achieved
within 30 sec.
For the analysis of intracellular calcium concentrations, an Attofluor
Ratio Imaging system (Atto Instruments, Rockville, MD) was used.
Excitation light was provided by a mercury lamp (HBO 103 W/2; Osram,
Berlin-München, Germany); excitation wavelengths of 334 and 380 nm were selected by different interference filters mounted on a
computer-controlled filter changer. Exposure times were controlled by a
shutter between the filter changer and a neutral density filter that
was used in conjunction with manual gain setting to obtain
approximately equal fluorescence intensities at the two different
excitation wavelengths. Fluorescence light was collected by an
Achrostigmat 40× oil-immersion objective (Zeiss), passed through a
dichroic mirror (395 nm) and an emission filter (500-530 nm), and
finally transmitted to a CCD camera with a photomultiplier. A personal
computer with appropriate software (Attofluor Ratio Vision, Atto
Instruments) was used to control the optic equipment and to record,
analyze, and store the images and data.
In some experiments ratio data of the emission intensities at 334 and
380 nm were converted to approximate calcium concentrations as
described previously (Grynkiewicz et al., 1985; Schomerus et al.,
1995). However, this calibration procedure is an approximation, and the
methods for calibrating emission ratios make many assumptions that
cannot be readily tested experimentally (Leong, 1989; D'Souza and
Dryer, 1994). Thus, most of the data in this study are presented in a
semiquantitative manner as 334 nm/380 nm emission ratios instead of as
intracellular calcium concentrations. In SCN neurons, PACAP elicited
changes in [Ca2+]i with a broad
variety (enhancement of [Ca2+]i
from basal concentrations of ~100 nM to peak
concentrations ranging from 700 nM to 3.5 µM), and PACAP stimulation led to a long-lasting
refractory time. Therefore, we defined for the experiments with
G-protein or PLC inhibitors a threshold to identify the cells, which
were responding to PACAP after specific inhibition of signal transduction cascade components. An increase of basal ratio values by a
value of 0.15 was sufficient to declare this cell to be a responder.
Statistical analysis was performed using unpaired Student's t test. Values were considered significantly different with
p < 0.05.
Immunocytochemistry. The cell culture was characterized by
immunocytochemical identification of glial as well as neuronal antigens
and the demonstration of neurotransmitters known to be present in the
SCN. Furthermore, in a subset of experiments, the cells, which were
initially analyzed with the fura-2 technique, were subsequently
characterized by immunocytochemical demonstration of GABA. Cells
were fixed with 4% paraformaldehyde or 4% paraformaldehyde plus 0.5%
glutaraldehyde in PBS, respectively, for 30 min. The cells were
then thoroughly washed with PBS and preincubated for 30 min with PBS
containing 0.3% Triton X-100 and 10% normal goat serum to reduce
nonspecific staining. Blocking solution was replaced with the primary
antibody solution [glial fibrillary acidic protein (GFAP) 1:1000
(Dako, Hamburg, Germany), microtubule-associated protein 2 (MAP2) 1:200
(ICN, Eschwege, Germany), GABA 1:250 (Sigma, Deisenhofen, Germany),
arginine vasopressin (AVP) 1:200 (gift from Dr. F. Nürnberger,
Dr. Senckenbergische Anatomie, Frankfurt, Germany), VIP 1:200 (Genosys,
Cambridge, UK), gastrin-releasing peptide (GRP) 1:200 (Affiniti,
Nottingham, UK), somatostatin (SOM) 1:200 (UCB, Brussels, Belgium) in
PBS containing 0.3% Triton X-100, 1% BSA], and the cells were
incubated overnight at room temperature (RT). Coverslips were then
washed with PBS, and the secondary antibody solution [Cy3-conjugated
goat anti-rabbit/mouse IgG 1:250-1:500 (Dianova,
Hamburg, Germany), dichlorotriazinyl
aminofluorescein-conjugated goat anti-rabbit IgG 1:50
(Dianova), FITC-conjugated goat anti-mouse IgG 1:30 (Sigma) in PBS
containing 0.3% Triton X-100, 1% BSA] was added for 90 min at RT.
The coverslips were finally mounted onto glass slides using
fluorescence mounting medium (Dako).
Confocal laser microscopy. To characterize
immunocytochemically the cells initially analyzed with the
fura-2 technique as GABA-immunopositive or -negative neurons, a
Zeiss LSM 510 confocal imaging system equipped with an argon laser and
an inverse Axiovert 100 Zeiss microscope were used. Immunocytochemistry
was performed with the fluorescent dye FITC-conjugated goat anti-mouse
IgG as the second antibody to avoid extensive nonspecific staining of the layer of glial cells, usually elicited by chromogenes such as
diaminobenzidine, and thus to allow re-identification of the coordinate
system etched onto the coverslip. Monochromatic light at 488 nm was
used to excite the FITC fluorophore using a dichroic beam splitter (FT
488) and an emission bandpass filter (BP 505-530), and also to
generate transmission images. The images were stored for further
analysis as digitized images with an eight-bit resolution (1024 × 1024 pixel).
Autoradiographic detection of
2-[125I]-iodomelatonin binding sites. Newborn
Wistar rats (1-7 d old) were killed by decapitation, and the brains
were frozen in 2-methylbutane (20°C). Serial coronal sections
including the SCN (16 µm thick) were cut using a cryostat and mounted
on gelatin-coated slides. In vitro autoradiography was
performed using one set of sections to determine total binding and a
second set to determine nonspecific binding. Slides were preincubated
in PBS containing 0.01% BSA for 1 hr at RT to remove endogenous
ligand. Thereafter they were incubated with 50 pM
2-[125I]-iodomelatonin (specific activity: 2200 Ci/mmol) in PBS/BSA without (total binding) or with (nonspecific
binding) 1 µM melatonin for 1 hr at RT. After washing in
ice-cold buffer (1 × 15 min in PBS/BSA + 1 × 15 min in
PBS), sections were air-dried and exposed to x-ray film (Kodak,
Stuttgart, Germany) for 3 weeks.
Materials. Drugs and chemicals were obtained from the
following sources: NaCl, KCl, CaCl2,
MgCl2, KH2PO4,
Na2HPO4, Triton X-100, glucose, EGTA
(Merck, Darmstadt, Germany); EBSS, DMEM/F12, fetal calf serum,
penicillin/streptomycin, glutamine, HEPES (Life Technologies,
Eggenstein, Germany); papain (Boehringer Mannheim, Mannheim,
Germany); PACAP38, ionomycin, tetrodotoxin (TTX), forskolin, thapsigargin, GDP--S, U-73122, U-73343, bisindolylmaleimide I, chelerythrine, -agatoxin IVA, -conotoxin GVIA, melatonin
(Calbiochem-Novabiochem, Bad Soden, Germany); 8-bromo-cAMP (8-Br-cAMP)
(BioLog, Bremen, Germany); PACAP38 (Bachem, Heidelberg, Germany); SP,
VIP (Peninsula, Belmont, CA);
2-[125I]-iodomelatonin (DuPont NEN, Boston, MA);
all other drugs and chemicals were obtained from Sigma. Coverslips with
a coordinate system that was etched onto the glass were obtained from
Eppendorf (Hamburg, Germany).
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RESULTS |
Characterization of the dissociated and cultured cells
After 4-10 d in culture, cells dissociated from the hypothalamus
of neonatal rats were characterized by immunocytochemical demonstration
of specific antigens to determine the amount of SCN cells in our
primary cell cultures. Neurons, identified by MAP2-immunoreactivity
(Fig. 1C), rested on a layer
of GFAP-immunopositive astrocytes (Fig. 1A,B).
Astrocytes were initially rare but multiplied and flattened during the
following days, achieving confluence after ~4 d in culture. Neurons
were further characterized by immunolabeling for GABA, AVP, VIP, GRP,
and SOM (Fig. 1D-H). GABA is the predominant neurotransmitter of SCN neurons, whereas the neuropeptides delineate distinct neuronal subpopulations within the SCN (van den Pol and Tsujimoto, 1985). Immunocytochemical demonstration of GABA revealed that the majority of neurons in the cell culture were GABAergic (~70%); AVP and VIP were detectable in ~5-10% and GRP and SOM were detectable in ~2% of the neurons. The number of the
immunocytochemically identified cells varied between the preparations
(n = 9), but the relative proportions of GABA, AVP,
VIP, GRP, and SOM cells were similar to those found in the SCN in
vivo, indicating that representative subsets of SCN neurons
remained viable in culture (also see Welsh et al., 1995).
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Figure 1.
Immunocytochemical characterization of dissociated
rat SCN cells after 4-10 d in culture. Neurons identified by the
expression of MAP2 (C) rested on a layer of
GFAP-immunopositive glial cells, which could be distinguished in flat
(type-1-like) (A) and process-bearing
(type-2-like) (B) astrocytes. Furthermore,
different neurotransmitters that are typical for SCN neurons were
immunodetected: GABA (D), AVP
(E), GRP (F), SOM
(G), and VIP (H).
Most of the neurons in our cell culture were GABAergic (~70%);
~5-10% of the neurons expressed AVP or VIP, respectively, and
~2% of the neurons showed GRP- or SOM-immunoreactivity. Scale bars,
10 µm.
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PACAP induces changes in [Ca2+]i
in a very complex pattern in GABAergic and non-GABAergic neurons
Fura-2 loading of cells resulted in a strong uptake of the
fluorescent dye by neurons identified by their size and cell
morphology, whereas only very few fibrillary astrocytes were labeled.
Analysis of [Ca2+]i was restricted to
neurons only, and up to 60 individual cells could be monitored
simultaneously within one measurement.
After stimulation with  10 nM PACAP, 1169 (27%) of 4285 neurons analyzed with the fura-2 technique showed an increase of
[Ca2+]i (Fig.
2a). The percentage of cells
that were responding to PACAP varied between different preparations
(10-60%; n = 38). Conversion of the semiquantitative
ratio values into approximate intracellular calcium concentrations
showed that the PACAP-induced increases in
[Ca2+]i varied considerably among
single cells. During stimulation, [Ca2+]i rose from a basal
concentration of ~100 nM to peak concentrations ranging
from 700 nM to 3.5 µM (Fig.
2b-d). These differences were not dependent on the
preparation or the culturing period.
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Figure 2.
PACAP-induced increases of
[Ca2+]i in SCN neurons and conversion
of the 334 nm/380 nm emission ratio data to approximate calcium
concentrations. PACAP at concentrations of 10 nM caused
an increase of [Ca2+]i in SCN neurons
(a). The ratio data of a single PACAP-responsive
neuron (b) were converted to approximate calcium
concentrations (d) by means of the Grynkiewicz
equation (Grynkiewicz et al., 1985). c,
d, PACAP-induced changes of
[Ca2+]i in two neurons from the same
experiment that display a striking variation in the amplitude of the
response. PACAP elicited [Ca2+]i
increases from basal levels of ~100 nM to peak
concentrations ranging from 700 nM to 3.5 µM.
The duration of PACAP application is indicated by
bars.
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The PACAP-induced changes of [Ca2+]i
could be distinguished into three major response patterns: (1)
monophasic responses (20%) (Fig.
3a), (2) biphasic responses
with an initial increase of [Ca2+]i
followed by a plateau phase (65%) (Fig. 3b), which extended in many neurons over several minutes and was not dependent on the
duration of PACAP stimulation (Fig. 3c,d), and (3) calcium oscillations with varying amplitude (15%) (Fig.
3e,f).
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Figure 3.
PACAP-induced changes of
[Ca2+]i in SCN cells. Stimulation with
PACAP (100 nM) elicited a broad spectrum of different
changes of [Ca2+]i in 27% of the
analyzed SCN neurons (n = 4285): 20% of these
cells showed a monophasic response (a), 65%
showed a biphasic pattern with an initial increase of
[Ca2+]i followed by a plateau phase
(b), which in many cells extended over several
minutes and was not dependent on the duration of PACAP application
(c, d), and 15% of the responding cells showed calcium
oscillations with varying amplitude (e, f).
Application of a short PACAP pulse (~30 sec) resulted in a long-lasting
refractory time, because even after 30 min >90% of the neurons (27 of
29 analyzed PACAP-responsive cells) did not respond to a second PACAP
pulse with increases in [Ca2+]i
(g). Prolonged pretreatment of SCN neurons with
PACAP (16 hr) resulted in a dramatic desensitization of PACAP-induced
calcium signaling. During the following 24 hr period after removal of
the neuropeptide, <1% of the analyzed cells (8 of 1838) showed
PACAP-induced increases in [Ca2+]i. A
great number of neurons that responded to PACAP were also sensitive to
glutamate (60%), SP (55%), or both glutamate and SP (40%)
(h). The data are presented as 334 nm/380 nm emission
ratios. The duration of the application of the
neurotransmitters/neuromodulators is indicated by
bars.
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Application of a short PACAP pulse (~30 sec) resulted in a
long-lasting refractory time, because even 30 min after this first pulse most of the neurons (>90%) did not react to a second PACAP pulse with changes in [Ca2+]i (Fig.
3g). Prolonged incubation of the neurons with PACAP (16 hr)
caused a dramatic desensitization of PACAP-induced calcium signaling.
During the following 24 hr period after removal of the neuropeptide,
virtually all cells were unresponsive to further treatment with PACAP
(>99%). In contrast, glutamate (10 µM) elicited changes
of [Ca2+]i in these experiments that
were not distinguishable from the responses of cells that were not
pretreated with PACAP.
To demonstrate that the observed changes of
[Ca2+]i were directly elicited by
PACAP acting on SCN neurons and not caused by activation of neighboring
cells that convey the signals via synaptic transmission or gap
junctions, cells were preincubated with TTX or treated with PACAP after
1 d in culture. TTX (300-500 nM; n = 157), a reversible blocker of Na+ channels that are
essential for propagation of impulses in excitable membranes, neither
inhibited PACAP-induced increases of
[Ca2+]i nor influenced the pattern of
PACAP-induced changes in [Ca2+]i. Even
in the presence of TTX, PACAP elicited increases of
[Ca2+]i that were indistinguishable
from those caused in the absence of TTX (Fig.
4a). Furthermore,
PACAP-induced increases of [Ca2+]i
were detectable as soon as 20 hr after cell dissociation, when the
layer of astrocytes had not yet been developed and the cells were
situated separately on the coverslip (Fig. 4b). These data indicate that the PACAP-induced changes in
[Ca2+]i in SCN neurons were not
mediated through intercellular communication.
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Figure 4.
Influence of intercellular communication on the
PACAP-induced changes in [Ca2+]i.
Pretreatment with TTX (300-500 nM; n = 157) did not interfere with PACAP-induced calcium signaling
(a). Furthermore, PACAP elicited changes in
[Ca2+]i even 20 hr after dissociation
of the cells, when the layer of astrocytes had not yet been developed
and the neurons were situated separately on the coverslip
(b). These data indicate that PACAP-induced
changes of [Ca2+]i are not the result
of synaptic transmission or coupling via gap junctions but a direct
effect of the peptide on the calcium signaling pathway in SCN neurons.
The duration of TTX and PACAP application is indicated by
bars.
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Application of the structurally related peptide VIP (100 nM) did not increase calcium in neurons of the SCN
(n = 53), indicating that the PACAP-induced changes of
[Ca2+]i are mediated via specific
PACAP receptors. Furthermore, pretreatment with VIP did not lead to
desensitization of the PACAP-sensitive receptors, nor did it influence
the pattern of PACAP-induced calcium signaling (Fig.
5a,b).
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Figure 5.
Influence of VIP and cAMP on the PACAP-induced
changes in [Ca2+]i. VIP (100 nM; n = 53) neither increased
[Ca2+]i nor interacted with the
pattern of changes of [Ca2+]i elicited
by PACAP used at the same concentration, i.e., even after pretreatment
with VIP, PACAP elicited monophasic and biphasic calcium responses as
well as calcium oscillations. These data indicate that the
PACAP-induced increases of [Ca2+]i are
mediated via PACAP type I receptors (a, b). The
PACAP-induced increases of [Ca2+]i are
independent of the cAMP level, because activation of the AC by
forskolin (10 µM; n = 162)
(c) or direct enhancement of the intracellular
cAMP concentration by treatment with 8-Br-cAMP (1 mM;
n = 141) (d) did not increase
basal calcium levels or interfere with PACAP-induced calcium signaling.
The duration of drug application is indicated by
bars.
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Activation of the AC by forskolin (10 µM;
n = 162) or application of the cell-permeable cAMP
analog 8-Br-cAMP (1 mM; n = 141) did not
change the basal [Ca2+]i or affect the
PACAP-induced increases of
[Ca2+]i, demonstrating that the
intracellular cAMP level is obviously not involved in PACAP-induced
calcium signaling in SCN neurons (Fig.
5c,d).
Combined analysis of the PACAP-induced calcium responses and
immunocytochemical demonstration of GABA showed that PACAP elicited increases in [Ca2+]i in both
GABA-immunopositive (53%; 28 of 53 cells) and
GABA-immunonegative neurons (47%) (Fig.
6). Nevertheless, the pattern of
PACAP-induced changes of [Ca2+]i did
not vary between these PACAP-sensitive cells, i.e., PACAP induced
monophasic and biphasic responses as well as calcium oscillations in
GABAergic and non-GABAergic neurons.
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Figure 6.
Correlation of the PACAP-sensitive cells with
immunocytochemically identified GABA-immunopositive neurons. Cells
initially analyzed with the fura-2 technique were subsequently fixed
with a mixture of paraformaldehyde/glutaraldehyde. GABA was
immunodetected by labeling with a specific primary antibody and a
FITC-coupled secondary antibody. The transmission image shows the cells
on a coverslip with an internal grid, allowing the re-identification of
the analyzed neurons (a); the corresponding
fluorescence image shows the GABA-immunoreactive neurons
(b). Arrowheads indicate
GABA-immunopositive cells, which responded to PACAP with increases of
[Ca2+]i. More than 50% of the
PACAP-sensitive neurons were GABA-immunopositive. The pattern of
PACAP-induced changes of [Ca2+]i
(monophasic or biphasic responses or calcium oscillations) did not vary
between GABAergic and non-GABAergic neurons. Scale bar, 10 µm.
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In addition to PACAP, many of the neurons were also sensitive to
glutamate and SP, two other neurotransmitters of the RHT. Application
of SP (100 nM) resulted in an increase of
[Ca2+]i in 30% of all cells tested
(134 of 447); application of glutamate (10 µM) enhanced
[Ca2+]i in 45% of the analyzed cells
(1678 of 3794). A great number of neurons that responded to PACAP with
increased [Ca2+]i were also sensitive
to glutamate (60%; 216 of 361 cells), to SP (55%; 86 of 155 cells),
and to glutamate and SP (40%; 24 of 62 cells) (Fig. 3h).
This indicates that individual SCN neurons obtain photic information by
different neurotransmitters/neuromodulators of the RHT.
PACAP mobilizes calcium from intracellular and
extracellular origin
PACAP application to SCN neurons kept in calcium-free saline plus
EGTA (1 mM) resulted in a uniform response pattern in all responding cells. A rapid increase in
[Ca2+]i was followed by an immediate
drop to basal levels, but a plateau phase or calcium oscillations, as
detected in 80% of the responding cells after PACAP treatment in
calcium-containing saline, were abolished (n = 393)
(Fig. 7a). This indicates that
intracellular calcium stores are involved in PACAP-induced calcium
signaling in the SCN. Application of caffeine (10 µM-1
mM), which mobilizes calcium from ryanodine-sensitive
intracellular calcium stores, did not interfere with PACAP-induced
calcium responses (n = 345) (Fig. 7b). In
contrast, treatment with thapsigargin (2 µM), which releases calcium from intracellular stores by inhibiting the microsomal (endoplasmic reticular) Ca2+-ATPase, caused an
increase in [Ca2+]i, and no
PACAP-induced changes in [Ca2+]i were
detectable after thapsigargin-sensitive calcium stores were depleted
(n = 174) (Fig. 7c).
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Figure 7.
Effects of removal of extracellular calcium and
depletion of intracellular calcium stores on PACAP-induced calcium
signaling. Application of PACAP to cells kept in calcium-free saline
plus EGTA (1 mM) resulted in a rapid increase of
[Ca2+]i followed by an immediate drop
to basal levels in all PACAP-responsive cells. The plateau phase and
calcium oscillations were abolished under these conditions, indicating
that intracellular and extracellular calcium is involved in
PACAP-induced calcium signaling (n = 393)
(a). Treatment with caffeine (10 µM-1 mM; n = 345) did
not interfere with PACAP-induced calcium responses
(b). In contrast, incubation of thapsigargin (2 µM; n = 174) caused an increase of
[Ca2+]i, and no PACAP-induced
changes of [Ca2+]i were detectable
after thapsigargin-sensitive calcium stores were depleted
(c); however, these cells were able to react to
glutamate. These data indicate that in SCN neurons PACAP induces
calcium release from (thapsigargin-sensitive) intracellular stores and
also calcium influx. The duration of drug application is indicated by
bars.
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The effects of PACAP on [Ca2+]i
are mediated via G-protein, PLC, and PKC
Because the number of PACAP-sensitive cells varied considerably
between different cell preparations, parallel measurements were
performed in the experiments with G-protein or PLC inhibitors, and the
average number of PACAP-responsive cells was normalized (control
measurements without inhibition = 100%). Preincubation of the
cells with GDP--S (1 mM; n = 240), a
nonhydrolyzable GDP analog that competitively inhibits G-protein
activation, resulted in an inhibition of PACAP-induced increases of
[Ca2+]i in >60% of the
PACAP-sensitive neurons (p < 0.0001 vs
controls) (Fig. 8). Application of two
different PLC inhibitors, neomycin (500 µM;
n = 443) or U-73122 (10 µM;
n = 249), led to a similar result. After pretreatment
with neomycin or U-73122, only 30 or 5% of the PACAP-sensitive cells,
respectively, responded to PACAP with a rise in
[Ca2+]i (p < 0.0001 vs controls for both inhibitors) (Fig. 8). In contrast, preincubation with U-73343 (10 µM; n = 175), an analog of U-73122 that acts as a very weak inhibitor of the
PLC and thus serves as a suitable negative control, did not result in
an inhibition of PACAP-induced increases of
[Ca2+]i (p = 0.51 vs controls) (Fig. 8). Inhibition of the PKC with bisindolylmaleimide I (GF 109203X; 2 µM)
(n = 126) elicited merely monophasic PACAP-induced
changes in [Ca2+]i in 70% of the
PACAP-responsive neurons and thus suppressed the plateau phase and
calcium oscillations in most cells (Fig. 9a). A similar result was
obtained by inhibition of the PKC with chelerythrine (10 µM; n = 156), which caused monophasic
responses in 90% of the PACAP-sensitive neurons. In contrast, PACAP
stimulation of cells from the same preparations, but without PKC
inhibition, showed monophasic increases of
[Ca2+]i in only 15% of the
PACAP-responsive neurons.
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Figure 8.
Effects of G-protein and PLC inhibitors on
PACAP-induced increases of [Ca2+]i.
The data of this subset of experiments are expressed as percentage of
control (measurements of cells from the same preparations without
specific inhibition) because the number of PACAP-sensitive cells varied
between the preparations (10-60%; n = 38), and
PACAP elicited changes of [Ca2+]i with
a striking variation in the amplitude (see Fig. 2 and Material and
Methods). Preincubation with the G-protein antagonist GDP--S (1 mM; n = 240) led to an inhibition of
PACAP-induced increases of [Ca2+]i in
60% of the PACAP-sensitive neurons. Application of the PLC inhibitors
neomycin (500 µM; n = 443) or U-73122
(10 µM; n = 249) resulted in
PACAP-induced calcium signaling in 30 or 5% of the analyzed
PACAP-sensitive cells, respectively, demonstrating an inhibition of
PACAP-induced calcium signaling in 70% or even 95% of these neurons.
In contrast, preincubation with the U-73122 analog U-73343 (10 µM; n = 175), which acts as a very
weak inhibitor of the PLC and thus serves as a negative control, did
not inhibit PACAP-induced changes of
[Ca2+]i. All inhibitors were
preincubated for 10 min. Asterisks indicate significant
differences from the corresponding control values (unpaired Student's
t test). ***p < 0.0001.
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Figure 9.
Effects of PKC inhibitors and antagonists of VGCCs
on PACAP-induced changes in [Ca2+]i.
Inhibition of the PKC with bisindolylmaleimide I (GF 109203X; 2 µM; n = 126) resulted in merely
monophasic PACAP-induced increases of
[Ca2+]i in 70% of the
PACAP-responsive cells and thus suppressed the plateau phase and
calcium oscillations in most cells (a). A similar
result was obtained by inhibition of the PKC with chelerythrine (10 µM; n = 156), which showed monophasic
responses in 90% of the PACAP-sensitive cells (data not shown). In
contrast, PACAP stimulation of cells from the same preparations, but
without PKC inhibition, elicited monophasic increases of
[Ca2+]i in only 15% of the
PACAP-responsive neurons. Specific blockade of VGCCs of the L-type with
diltiazem (10-100 µM; n = 149)
(b), nifedipine (10-100 µM;
n = 139) (c), or verapamil (10-100
µM; n = 100) (d),
respectively, did not inhibit the calcium-induced calcium influx
responsible for the plateau phase (c, d) and the calcium
oscillations (b) after PACAP stimulation. Similar
results were obtained by blockade of VGCCs of the T-type with amiloride
(100 nM-100 µM; n = 459)
(e), of the N-type with -conotoxin GVIA (1-10
µM; n = 290)
(f), and of the P-type and also
Q-type with -agatoxin IVA (1-500 nM;
n = 238) (g). Even
combined blockade of these VGCCs with a mixture of diltiazem (50-100
µM), amiloride (50-100 µM), -conotoxin
GVIA (1-2 µM), and -agatoxin IVA (50-100
nM) did not inhibit the calcium influx elicited by PACAP
application (n = 174) (h).
The duration of drug application is indicated by
bars.
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|
Voltage-gated calcium channels are not involved in PACAP-induced
changes in [Ca2+]i
The previous results demonstrate that calcium channels in the
plasma membrane are responsible for the plateau phase of the biphasic
calcium signals and for the calcium oscillations, because both depend
on calcium influx. To examine the role of voltage-gated calcium
channels (VGCCs) in PACAP-induced calcium signaling in SCN neurons, we
blocked VGCCs with subtype-specific antagonists and analyzed the
changes of [Ca2+]i after PACAP
stimulation. Blockade of L-type calcium channels with nifedipine
(10-100 µM; n = 139), verapamil (10-100
µM; n = 100), or diltiazem (10-100
µM; n = 149) did not influence the PACAP-induced changes of
[Ca2+]i, and it did not inhibit
the plateau phase or PACAP-induced calcium oscillations (Fig.
9b-d). Blockade of T-type channels with amiloride (100 nM-100 µM; n = 459) (Tang et
al., 1988), N-type channels with -conotoxin GVIA (1-10
µM; n = 290), and P-type and also Q-type
channels with -agatoxin IVA (1-500 nM;
n = 238) (Randall and Tsien, 1995) led to the same
results: none of these treatments interfered with PACAP-induced calcium
signaling (Fig. 9e-g). Furthermore, combined
blockade of these VGCCs with a cocktail of diltiazem (50-100
µM), amiloride (50-100 µM), -conotoxin
GVIA (1-2 µM), and -agatoxin IVA (50-100
nM) did not inhibit the PACAP-induced influx of calcium
that is responsible for the plateau phase and calcium oscillations
(n = 174) (Fig. 9h).
Melatonin and PACAP in the SCN: no evidence for an interaction on
the calcium signal transduction cascade
In the SCN of newborn Wistar rats (day 1-7), melatonin binding
sites were detected by in vitro autoradiography (Fig.
10). Calcium imaging by means of the
fura-2 technique revealed that application of melatonin in a
physiological concentration (10 nM) did not change
[Ca2+]i in primary cell cultures of
rat SCN neurons (Fig. 11a).
Furthermore, melatonin did not inhibit PACAP-induced increases of
[Ca2+]i when applied for 5-10 min
before PACAP treatment (n = 92) (Fig. 11a).
Even after a prolonged time of preincubation (30 min), a period
sufficient to completely inhibit PACAP-induced phosphorylation of the
transcription factor CREB in slice cultures of the rat SCN (Kopp et
al., 1997), melatonin did not influence the PACAP-induced pattern of
changes in [Ca2+]i (n = 143) (Fig. 11b,c).
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Figure 10.
Autoradiographic demonstration of melatonin
binding sites in the SCN of a newborn Wistar rat. Coronal hypothalamic
sections (16 µm) of a 3-d-old rat were incubated with
2-[125I]-iodomelatonin. Melatonin binding sites
were detected in the suprachiasmatic nucleus
(SCN) and also in the paraventricular nucleus of
the thalamus (PVN). Scale bar, 1 mm.
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Figure 11.
Effects of melatonin on
[Ca2+]i and PACAP-induced calcium
signaling. Application of melatonin in a physiological concentration
(10 nM) neither changed the basal concentration of
intracellular calcium nor inhibited PACAP-induced increases of
[Ca2+]i in SCN neurons
(n = 92) (a). Even after a
prolonged time of preincubation (30 min), a period sufficient to
completely block the PACAP-induced phosphorylation of the transcription
factor CREB in the rat SCN (Kopp et al., 1997), melatonin did not
interfere with the complex pattern of PACAP-induced changes in
[Ca2+]i (n = 143)
(b, c). The duration of melatonin and PACAP application
is indicated by bars.
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DISCUSSION |
During the last few years, increasing evidence has been provided
that PACAP acts as a neuromodulator of the RHT, conveying information
about the ambient light/dark cycle to the circadian pacemaker in the
hypothalamus (Hashimoto et al., 1996; Hannibal et al., 1997; Shioda et
al., 1997). The cAMP signal transduction cascade is apparently one
pathway through which PACAP affects SCN functions, because
PACAP-induced phase-shifts were blocked by a specific cAMP antagonist
(Hannibal et al., 1997) and the PACAP-induced phosphorylation of CREB
was inhibited by melatonin (Kopp et al., 1997). In the present report
we demonstrate that PACAP also elicits changes in
[Ca2+]i in SCN neurons, demonstrating
a substantially enhanced signaling potential of this neuropeptide in
the circadian clock.
PACAP was first isolated in 1989 from ovine hypothalamus and named
because of its AC-activating potency (Miyata et al., 1989). More
recently, the peptide has also been shown to activate the calcium
signaling pathway via a broad spectrum of signal transduction mechanisms. These signaling cascades are activated in parallel in many
systems and include (1) activation of the AC with subsequent cAMP/protein kinase A-dependent opening of calcium channels, (2) release of calcium from inositol (1,4,5)-trisphosphate
(IP3)-sensitive stores without subsequent calcium
influx, (3) calcium release from ryanodine-sensitive stores independent
of both IP3 and cAMP, and (4) PKC-dependent activation of
calcium channels without IP3 formation. Different types of
VGCCs and voltage-gated (TTX-sensitive) Na+ channels
are often involved in these PACAP-induced calcium signaling events
(Isobe et al., 1993; Rawlings et al., 1993, 1994; Leech et al., 1995;
Hezareh et al., 1996, 1997; K. Tanaka et al., 1996, 1997, 1998;
O'Farrell and Marley, 1997).
Our results demonstrate that in SCN neurons PACAP induces changes in
[Ca2+]i that are independent of cAMP
but require G-protein-mediated activation of PLC. This leads to an
initial release of calcium from IP3-sensitive intracellular
stores, which in turn causes PKC-mediated opening of calcium channels
in the plasma membrane and subsequent calcium influx in 80% of the
analyzed cells, resulting in a plateau phase or calcium oscillations. A
similar mechanism has been described in a rat pancreatic cell line
(Barnhart et al., 1997), in gonadotrophs of the rat anterior pituitary
gland, and in the gonadotroph-derived  T3-1 cell line (Rawlings et
al., 1993; Schomerus et al., 1994). However, in T3-1 cells, the
plateau phase could be blocked by L-type VGCC antagonists (Hezareh et al., 1997). In contrast, in SCN neurons, blockade of VGCCs of the
L-type or of the N-, P-, Q-, and T-type as well as simultaneous blockade of all of these channels had no effect, suggesting that other
(non-voltage-gated?) channels are involved in PACAP-induced changes in
[Ca2+]i. In addition, voltage-gated
Na+ channels are not involved in this
calcium-induced calcium influx, because application of TTX did not
interfere with PACAP-induced calcium signaling.
In SCN neurons, PACAP elicits a broad spectrum of different changes in
[Ca2+]i. Because individual neurons of
the SCN express an endogenous circadian rhythmicity (Welsh et al.,
1995), SCN neurons may also display circadian rhythms in PACAP-
sensitivity or in the pattern of PACAP-induced changes in
[Ca2+]i. The different PACAP-induced
changes in [Ca2+]i may therefore
depend on the circadian phase of single neurons. Treatment with VIP did
not elicit any changes in [Ca2+]i when
applied in the same concentration as PACAP (100 nM),
indicating that PACAP-induced changes in
[Ca2+]i in the SCN are mediated via
PACAP type I receptors. These receptors have recently been shown to
mediate PACAP-induced phase-shifting of circadian rhythms in the SCN
via activation of the cAMP signaling pathway (Hannibal et al., 1997).
Activation of PACAP type I receptors in pheochromocytoma cells induces
gene transcription as well as neurotransmitter release by activation of
the cAMP or the calcium signaling pathway, respectively (Taupenot et
al., 1998). Continuous activation of these receptors in
catecholaminergic neuron-like cells attenuated the PACAP-induced cAMP
accumulation, whereas the phosphoinositide turnover and
phospho-CREB-mediated transcriptional activity has been overstimulated
(Muller et al., 1998). In contrast, chronic exposure of SCN cells to
PACAP resulted in a dramatic desensitization of the calcium signaling
pathway. Possibly, in the SCN, PACAPergic modulation of afferent inputs
and induction of phase-shifts, manifested by de novo protein
biosynthesis, may be restricted to one or the other signaling pathway,
a mechanism recently discussed for signaling events in the SCN induced
by neuropeptide Y, a neuromodulator of the geniculohypothalamic tract (Harrington and Hoque, 1997). Glutamatergic neurotransmission to the
SCN, suggested to be modulated by both neuropeptide Y and SP (Shirakawa
and Moore, 1994; Abe et al., 1996; van den Pol et al., 1996), may be
one target for PACAPergic neuromodulation. The effects of glutamate on
SCN neuronal firing rate are not dependent on the circadian time, but
glutamate induces the phosphorylation of CREB and phase-shifts
(phase-delays as well as phase-advances) that are restricted to
distinct time windows, indicating that glutamatergic neurotransmission
requires modulation by the circadian clock (Ding et al., 1994, 1997;
Gannon and Rea, 1994; Inouye and Shibata, 1994; Shirakawa and Moore,
1994). A great number of PACAP-sensitive neurons responds to glutamate
and/or SP. Thus, single SCN neurons are target cells for retinal
projections and display an individual (time-dependent?) sensitivity to
different neurotransmitters/neuromodulators. In addition to zeitgeber
information that is conveyed to the oscillator via the RHT, the SCN
receives neuronal inputs from the raphe nuclei and the thalamic
intergeniculate leaflet as well as endocrine information. Thus, various
information from different sources reaches the clock and has to be
integrated into rhythm generation, entrainment, and consolidation.
Immunocytochemical characterization revealed that >50% of the
PACAP-sensitive neurons are GABAergic. GABA is the major
neurotransmitter of the circadian timing system and has been shown in
~80% of all SCN neurons and ~50% of all SCN synaptic boutons (van
den Pol and Tsujimoto, 1985; Okamura et al., 1989; Decavel and van den Pol, 1990; Moore and Speh, 1993; Buijs et al., 1994; M. Tanaka et al.,
1997). GABAergic signaling events are involved in receiving, processing, and transmitting (light) information (Ralph and Menaker, 1989; O'Hara et al., 1995; Hermes et al., 1996; Isobe and Nishino, 1997; Strecker et al., 1997; Wagner et al., 1997). Thus, PACAP directly
affects one of the most important neurotransmitter systems of the
endogenous clock. The GABA-immunonegative population of PACAP-sensitive
neurons requires further characterization. These neurons may represent
GABAergic cells whose neurotransmitter content at the moment of
fixation was too low to be detected immunocytochemically. This
suggestion is based on findings that in the SCN GABA and glutamic acid
decarboxylase, the enzyme that catalyzes GABA biosynthesis, exhibit a
circadian rhythmicity of their content or activity (Aguilar-Roblero et
al., 1993; Cagampang et al., 1996) and that dissociated SCN cells in
culture express independently phased circadian rhythms with period
lengths of 24.35 ± 1.20 hr (Welsh et al., 1995). On the
other hand these neurons may be truly non-GABAergic. This would suggest
that two populations of PACAP-sensitive neurons exist in the SCN.
The hormone melatonin is synthesized and released in the mammalian
pineal organ in a diurnal rhythm, driven by the endogenous clock, with
high levels during the dark period. In the SCN, melatonin binding sites
have been demonstrated (Vanecek et al., 1987), indicating that the
hormone forms a feedback loop. Like many other substances conveying
time information to the SCN, melatonin elicits physiological responses
in the oscillator at distinct time windows (for review, see Klein et
al., 1991). These effects are thought to be mediated via inhibition of
the AC (Reppert et al., 1994; Liu et al., 1997), but in principle
melatonin can also affect the calcium signaling pathway (Vanecek and
Klein, 1992, 1995; Godson and Reppert, 1997; McArthur et al., 1997). In
the present report we show that melatonin does not affect
[Ca2+]i in SCN neurons on its own.
Moreover, melatonin does not affect PACAP-induced changes of
[Ca2+]i. The missing effects of
melatonin on [Ca2+]i may not be caused
by a lack of melatonin receptors, because newborn rats express
melatonin binding sites in the SCN and physiological effects of
melatonin have been demonstrated in primary cell cultures of the rat
SCN that were comparable to our cell cultures in preparation and
cultivation (Vanecek and Watanabe, 1998; Watanabe et al., 1998). Our
data indicate that the antagonistic effects of melatonin and PACAP on
CREB phosphorylation in rat SCN slice cultures seem to be mediated via
activation/inhibition of the cAMP signaling pathway (Kopp et al.,
1997). This is consistent with a recent report that in primary cell
cultures of the hamster SCN, melatonin inhibits the (cAMP-mediated)
forskolin- and dopamine-induced but not the
(Ca2+-mediated) glutamate-induced phosphorylation of
CREB (McNulty et al., 1998).
In conclusion, these data in combination with previous findings
demonstrate that in the SCN PACAP affects the cAMP as well as the
calcium signaling pathway, eliciting a complex pattern in second
messenger responses. Intrinsic GABAergic neurons of the SCN appear
as the prime target cells for PACAPergic neurotransmission, whereas
glutamatergic neurotransmission to the oscillator may be one target for
PACAPergic neuromodulation. The antagonistic potency of melatonin on
PACAP-induced signaling events seems to be restricted to the cAMP
signaling pathway.
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FOOTNOTES |
Received Aug. 25, 1998; revised Oct. 13, 1998; accepted Oct. 19, 1998.
This research was supported by grants from the Deutsche
Forschungsgemeinschaft. We thank E. Laedtke for expert technical
assistance, Drs. E. Gebke, E. Maronde, S. Kroeber, and C. von Gall for
helpful advice, and P. Schmidt, E. Cortés, K. Steinhauer, and M. Zimmer, who are responsible for our rat colony, for excellent collaboration.
Correspondence should be addressed to Dr. Michael D. A. Kopp,
Max-Planck-Institut für Physiologische und Klinische Forschung, W. G. Kerckhoff-Institut, Parkstrasse 1, D-61231 Bad Nauheim, Germany.
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Top
Abstract
Introduction
