Vol. 276, Issue 4, R1078-R1086, April 1999
Interstrain differences in activity pattern, pineal function,
and SCN melatonin receptor density of rats
Gabriela
Klante1,
Karin
Secci2,
Mireille
Masson-Pévet3,
Paul
Pévet3,
Berthe
Vivien-Roels3,
Stephan
Steinlechner4, and
Franziska
Wollnik1
1 Biological Institute,
Department of Animal Physiology, University of Stuttgart, D-70550
Stuttgart; 2 Faculty of Biology,
University of Konstanz, D-78434 Konstanz;
4 Institute of Zoology, Hanover
School of Veterinary Medicine, D-30559 Hannover, Germany; and
3 Université Louis Pasteur,
F-67000 Strasbourg, France
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ABSTRACT |
We investigated the possibility that
strain-dependent differences in the diurnal pattern of wheel running
activity rhythms are also reflected in the melatonin profiles. The
inbred rat strains ACI/Ztm, BH/Ztm, and LEW/Ztm. LEW were
examined for diurnal [12:12-h light-dark (LD)] wheel
running activity, urinary 6-sulphatoxymelatonin (aMT6s) excretion,
melatonin concentrations of plasma and pineal glands, and melatonin
receptor density in the suprachiasmatic nuclei (SCN). ACI rats
displayed unimodal activity patterns with a high level of activity,
whereas BH and LEW rats showed multimodal activity patterns with
ultradian components and reduced activity levels. In contrast, the
individual daily profiles of aMT6s excretion and mean melatonin
synthesis followed a unimodal time pattern in all three strains,
suggesting that different output pathways of the SCN are responsible
for the temporal organization of locomotor activity and pineal
melatonin synthesis. In addition, melatonin synthesis at night and SCN
melatonin receptor density at day were significantly higher in BH and
LEW rats than in ACI rats. These results support the hypothesis of a
long-term stimulating effect of melatonin on its own receptor density
in the SCN.
6-sulphatoxymelatonin; pineal gland; suprachiasmatic nuclei; rat
strains; wheel running activity; ACI/Ztm; BH/Ztm; LEW/Ztm
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INTRODUCTION |
THE MAMMALIAN circadian pacemaker is located in the
suprachiasmatic nuclei (SCN) of the hypothalamus (27), generating
endogenous rhythms in a wide variety of physiological and behavioral
functions, including locomotor activity (48) and melatonin synthesis in the pineal gland (38). Under natural conditions, circadian rhythms are
entrained or adjusted to the 24-h period by so-called zeitgebers such
as the light-dark (LD) cycle. It has been suggested that circadian
rhythms of locomotor activity and pineal melatonin synthesis are driven
by the same pacemaker system, because they show characteristic similarities in their phase-shifting response to light pulses (15) and
in their entrainment to non-24-h lighting cycles (28). The SCN regulate
the rhythmic synthesis and release of melatonin in the pineal
gland by a multisynaptic pathway via the paraventricular nucleus of the hypothalamus, the intermediolateral cell columns of the
spinal cord, the superior cervical ganglion, and postganglionic adrenergic innervation (37). Although the efferent projection from the
SCN to the pineal gland is well characterized, the neural pathway
mediating circadian rhythms of locomotor activity has not yet been
identified. It may not even be a necessary precondition, because SCN
transplantation experiments in hamsters have demonstrated that a
diffusible signal is sufficient to restore circadian activity rhythms
in the SCN-ablated hosts (46), whereas reestablishment of melatonin
rhythms has never been observed (30).
The SCN not only drive the circadian rhythms of locomotor activity and
melatonin synthesis, but are also a target for feedback effects of both
activity (40) and melatonin (2, 5, 6, 8, 43). For example, it has been
demonstrated that spontaneous activity or some kind of arousal can
alter the period or induce phase shifts in the free-running rhythm in
hamsters (39, 40) and mice (14), whereas in rats only weak feedback
effects of a daily treadmill schedule on circadian activity rhythm were
described (36). Furthermore, changes in rhythmic melatonin synthesis or administration of exogenous melatonin lead to altered locomotor activity rhythms in rats and hamsters (2, 6, 8, 9, 25, 32), although
different circadian responses to exogenous melatonin occur depending on
species, strain, age, and method of administration (43). The mammalian
SCN contain melatonin receptors (12, 44), and melatonin given in vitro
can decrease the metabolic activity (7) and phase shift the neuronal
firing rate of the SCN (35). Melatonin injections in vivo accelerate the reentrainment of activity rhythms (2), synchronize disrupted components of a circadian rhythm under constant light (6), and affect
SCN melatonin receptor density (16). Therefore, locomotor activity and
melatonin synthesis may not only be controlled by the same pacemaker
system, but they may also affect each other by feedback effects
mediated through the SCN.
Comparisons of selected lines or inbred strains of rats have already
been used as a suitable experimental approach for further elucidation
of the interaction of components of the circadian system (4, 10, 11,
13, 55) and the pineal gland (24, 53). For example, rats of the inbred
strains ACI/Ztm, BH/Ztm, and LEW/Ztm exhibit genetically determined
differences in circadian rhythm of wheel running activity, with
characteristic differences in rhythm amplitude and in the absence (ACI)
and presence (BH, LEW) of significant ultradian components (55).
Fragmentation of the activity phase into discrete bouts suggests
control by individual circadian pacemakers that are part of a coupled
multioscillator system (45). The aim of the present study was to
investigate the characteristics of diurnal melatonin synthesis in these
inbred strains of rats as well as the relationship between melatonin patterns and differences in wheel running activity rhythms. Individual melatonin rhythms in activity-registered rats were determined by
measurement of 6-sulphatoxymelatonin (aMT6s), the main catabolic product that is excreted into urine (1) and is known to reflect the
pattern of the pineal melatonin rhythm both qualitatively and
quantitatively but is time delayed by 1-2 h as a result of catabolism (3, 42, 49). The aMT6s data of these three inbred rat
strains were validated by direct measurements of plasma and pineal
melatonin concentrations in an additional experiment. Furthermore, melatonin receptor density in the SCN was analyzed to look for possible
strain-dependent differences in the feedback effect of melatonin on the
circadian pacemaker.
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MATERIALS AND METHODS |
Animals and Housing
Rats of the inbred strains ACI/Ztm, BH/Ztm, and LEW/Ztm were bred and
raised in our laboratory under controlled environmental conditions (22 ± 1°C room temperature, 55 ± 5% relative humidity, 12:12-h
LD cycle, lights on at 0700, 500 lx at cage level). Food (Altromin
1320) and tap water were available ad libitum.
Experiment I
Monitoring of wheel running activity.
Six male rats of each strain, 15 wk old, were used for this study. The
animals were individually housed in Macrolon cages (type IV; Becker,
Castrop-Rauxel, Germany) equipped with a running wheel (diameter 35 cm,
width 10 cm). Activity recordings started 4 wk after transfer to a
reversed LD cycle (12:12 h, lights on at 2200) and continued for 4 wk, except on days
14 and
21, when the animals were transferred
for 48 h to metabolic cages. Wheel rotations were detected by a
magnetic reed switch (Hamlin) mounted on the wheel axle, so that one
complete wheel rotation resulted in one impulse. The number of impulses per 5-min interval was recorded continuously and registered by a
personal computer. Subsequent calculations of mean daily activity and
24-h profiles were based on days
1-13,
17-20, and
24-28 of the registration period,
omitting only the two 48-h periods of urine sampling and the first day
immediately after the transfer from the metabolic cages back to the
wheel running cages. Calculations of
2 periodogram analysis (47)
were performed only for the first 13-day segment preceding the transfer
to the metabolic cages.
Urine collection. For urine
collection, the animals were singly housed in metabolic cages (diameter
19.5 cm) for an adaptation period of 24 h and a sampling interval of 24 h. Urine was sampled from each animal twice within 21 days. During
sampling the animals were deprived of food but provided with water ad
libitum. Each metabolic chamber was equipped with a special funnel
system, which separated urine from feces. In an automated setup, the
funnel and connecting tubes (silicone, inner diameter 1 mm) were washed every hour with 1 ml distilled water from a perfusion pump (pump 22;
Harvard Apparatus, South Natick, MA). Urine samples, including water,
were transported by a peristaltic pump (type XV; Alitea, Sweden) and
collected automatically in fractions of 1 h (Collector MM 10; Neolab,
Heidelberg, Germany). The volume of the urine samples was determined to
an accuracy of 0.1 ml, and all samples were frozen at 
20°C
for later analysis.
RIA for aMT6s measurements. All urine
fractions were centrifuged at 2,500 g
for 10 min (Megafuge 1.0 R; Heraeus Sepatech, Osterode, Germany) to
remove solid material and contamination. We analyzed 0.1-20 µl
of the supernatant, depending on binding (B), so that 20-80%
B/B0 was guaranteed in the RIA.
All urine samples were assayed in duplicate, using
125I-labeled aMT6s tracer and
antibody from Stockgrand (Guildford, UK), according to the procedure of
Aldous and Arendt (1). The standard curve (triplicate) was
performed in buffer solution. A prior test revealed that adding 20 µl
daytime urine to the standard solutions did not interfere with binding
behavior. All samples were counted in a gamma counter (Compugamma CS
1282; LKB Wallac, Turku, Finland) for 2 min, and aMT6s amounts were
calculated by the counter's built-in software (RIA Calc; Pharmacia,
Wallac Oy, Turku, Finland). The intra-assay coefficient of variation
was 11.7%, calculated from 10 samples of 10 pg aMT6s. The interassay coefficient of variation was 14.6%, calculated from 10 RIAs. In each
urine sample the concentration of aMT6s was related to the concentration of creatinine (26) using Jaffé's test (Merck, Darmstadt, Germany). The 24-h profiles of urinary aMT6s excretion were
determined twice for each rat and averaged afterward. Total daily aMT6s
excretion was calculated by using the mean daily creatinine excretion
rate of each strain as a reference.
Experiment II
Collection of plasma and pineal
glands. Forty-eight male rats of each strain, 8-20
wk of age, were used for this study. Six animals of each strain were
killed by decapitation at various times throughout a 24-h cycle (times
indicated in Figs. 3 and 4), during which times a dim red light source
(<1 lx) was used during the dark period. Blood was
collected and treated with 10 µl/ml blood of 10% Titriplex III
(Merck) to obtain plasma after centrifugation at 1,500 g for 10 min (Megafuge). The pineal
glands were quickly removed and immediately frozen on dry ice. All
samples were stored at 80°C until further processing.
RIA for melatonin measurements. Pineal
glands were homogenized in 500 µl tricine buffer (Sigma) containing
0.9% sodium chloride and 0.1% gelatin. After centrifugation at 1,500 g for 5 min, aliquots of 100 µl of
the supernatant were assayed in duplicate. Plasma samples were
extracted using dichloromethane. The dichloromethane phase was
evaporated in a speed-vaporizer at 4°C under nitrogen, and the
residue was reconstituted in tricine buffer solution. From the plasma
extract aliquots of 200 µl were assayed in duplicate. The average
efficiency of extraction was 87±2%. Standards (Sigma) were
extracted in triplicate using the same procedure as for the plasma
samples. The RIA was performed using a rabbit antiserum (R19540) at a
final dilution of 1/200,000, provided by INRA (Nouzilly, France), and
the radioligand 125I-labeled
2-melatonin prepared in the laboratory with 10,000 cpm/tube. Cross
reactivity of the antiserum has been reported earlier (51). The assay
was validated by controlling the parallelism between serial dilutions
of pineal supernatant or dichloromethane plasma extracts and the
standard curve. The limit of sensitivity of the assay was 1.0 pg/tube.
The intra-assay coefficient of variation was 3%, and the interassay
coefficient of variation was 8% at the level of 100 pg/ml.
In vitro autoradiography of
125I-labeled 2-melatonin in the
SCN. The brains of five rats of each strain killed at
1300 (mid-light phase) were rapidly removed, frozen in isopentane
maintained at 30°C, and stored at 30°C until
processing. Serial coronal sections (20 µm) of the regions containing
the SCN were cut on a cryostat, thaw-mounted onto gelatin-coated
slides, and kept at 30°C until use. Sections were
preincubated at 4°C for 15 min in a 100-mM Tris buffer containing 4 mM CaCl2 (pH 7.4) and subsequently
incubated at room temperature for 1 h in the same buffer containing
various concentrations of
125I-labeled 2-melatonin
[synthesized according to the method of Vakkuri et al.
(52)] and purified by HPLC, with specific activity of
1,431-1,888 Ci/mmol. Sections were washed twice for
30 s in assay buffer and again in distilled water at 4°C with
agitation. Hyperfilm (3H,
Amersham) was placed on the air-dried sections for 10 days in the
presence of 20-µm thick
125I-labeled microscales standards
(Amersham). Quantitative analysis of the autoradiograms was performed
using the computerized analysis system Biocom-program RAG 200. The data
obtained in femtomoles per milligram of polymer were converted to
femtomoles per milligram of protein according to the method of Nazarali
et al. (41). The saturation curve was described by the equation
Y = Ax/B x, where A = Bmax and B = dissociation constant
(Kd)
(Graph Pad; Graph Pad, San Diego, CA).
Statistics
Daily profiles of wheel running activity, aMT6s excretion, and plasma
and pineal melatonin levels were analyzed by two-way ANOVA (Statistica,
Statsoft) using the Fisher's least significant difference test or
Tukey's honest significant difference test. For unequal sample sizes,
Spjotvoll/Stoline's test was used. Pearson's r was calculated for correlation
analysis. Furthermore, estimates of broad-sense heritability and
genetic correlation were calculated according to the procedure
described by Hegmann and Possidente (20).
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RESULTS |
Experiment I: Individual Actograms and aMT6s Profiles
The rats used in this study exhibited strain-specific locomotor
activity patterns that were in good agreement with previous findings in
these three strains (55, 56). ACI rats had a unimodal activity pattern
characterized by a gradual increase of wheel running activity after
onset of darkness, reaching maximal values in the second half of the
dark phase (Fig. 1). Periodogram analysis revealed only one strong rhythmic component with a period of exactly 24 h (a representative actogram together with the respective periodogram of one ACI rat is shown in Fig. 2). On the
other hand, BH rats showed a rather weak activity rhythm with blurred
onsets and offsets of activity and an expanded duration of activity in
relation to the dark phase (Fig. 1). Periodogram analyses detected
significant ultradian components of 3, 4, and 6 h in addition to the
most significant 24-h period (Fig. 2). LEW rats also displayed a
multimodal activity pattern with ultradian components of 4 and 6 h and
an extended activity phase similar to the BH rats. All three strains showed an additional short activity peak at the onset of light. The
maximum activity levels of LEW rats were as high as those of ACI rats,
but were interrupted by short periods of rest. Thus two thirds of the
nighttime points were significantly different between ACI and LEW rats,
and half of them were significantly different between BH and LEW (Fig.
1; P < 0.05). ANOVA
revealed significant strain differences
[F(2,14) = 4.85, P < 0.025] with respect to the number of wheel rotations per day. The mean number of
rotations per day was highest in ACI rats and lowest in BH rats. This
resulted in a moderate estimate of broad-sense heritability, indicating
that this parameter is genetically determined (Table 1).
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Fig. 1.
Twenty-four-hour profiles of wheel running activity of ACI/Ztm, BH/Ztm,
and LEW/Ztm rats kept in 12:12-h light-dark (LD) cycle. Values are 1-h
means ± SE of 6 rats of each strain, averaged over a total of 22 days. Black bar indicates dark period.
*,+ P < 0.05 vs. ACI and BH,
respectively.
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Fig. 2.
Left: representative records of wheel
running activity (1 rat/strain). Bin height represents number of
rotations within a 5-min interval (0-20 rotations/bin). Vertical
dashed lines at 1000 and 2200 indicate beginning and end of dark
period. Black bar indicates dark period.
Right: corresponding
2 periodogram analyses of same
13-day segments of wheel running activity. Slanted lines indicate level
of significance (P = 0.001) according
to Sokolove and Bushell (47).
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Table 1.
Strain differences in wheel running activity and urinary aMT6s
excretion and estimates of broad-sense heritability
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Individual 24-h profiles of urinary aMT6s excretion were determined
twice for each animal. They were highly consistent
(r = 0.922, P < 0.001) and were therefore pooled
for further analysis. All three strains showed pronounced unimodal
diurnal rhythms of mean urinary aMT6s excretion (Fig.
3), which could also be observed in the
individual 24-h profiles (not shown). aMT6s levels of all rat strains
began to rise 2-3 h after onset of darkness, reached highest
values 2-3 h later, and remained elevated until the end of the
dark phase. At the end of the dark period, aMT6s levels declined
steadily, reaching daytime values below 10 ng/mg creatinine 2-5 h
after lights on. Amplitudes of the mean aMT6s rhythms in BH and LEW
rats were about twice as high as in ACI rats. Thus most nighttime aMT6s
values of ACI rats were significantly different from those of the BH
and LEW strains, but no differences were found between BH and LEW rats
(P < 0.05). Linear regression
analysis of daily amount of activity versus daily aMT6s excretion of
all strains detected a significant negative correlation
(r = 0.628, P = 0.007). However, this relationship
did not prove significant within each strain
(rACI = 0.017, P = 0.974;
rBH = 0.455, P = 0.441;
rLEW = 0.376, P = 0.463).
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Fig. 3.
Twenty-four-hour profiles of 6-sulphatoxymelatonin (aMT6s) excretion in
ACI, BH, and LEW rats. Values are 1-h means ± SE
(n = 6, 6, and 5 rats for ACI, LEW,
and BH, respectively). Black bar indicates dark period.
*,+ P < 0.05 vs. ACI and BH,
respectively.
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The 24-h integrals of total aMT6s excretion showed significant
differences [F(2,14) = 12.21, P < 0.0009] between the
strains (Table 1). Estimates of broad-sense heritability for total
daily aMT6s excretion were rather high (Table 1).
Experiment II: Daily Profiles of Melatonin and SCN Melatonin
Receptor Density
Pineal and plasma melatonin concentrations revealed clear 24-h rhythms
in all three strains (Figs. 4 and
5). Melatonin concentrations began to rise
with onset of darkness and reached their highest values within the
following 4 h. Nighttime values remained stable over the dark phase and
started to decline at the beginning of the light phase. Thus melatonin
levels displayed a unimodal pattern rather similar to the daily rhythm
of aMT6s excretion. The temporal patterns of plasma melatonin content
resembled those of pineal melatonin but showed higher variations in
their nighttime values (Figs. 4 and 5). The 24-h profiles of plasma
melatonin and pineal melatonin differed from each other at various time
points. For example, the plasma concentrations in LEW rats were highest
when their pineal melatonin contents showed a slight depletion phase. Furthermore, ACI rats showed a decline in plasma melatonin in the
second half of the dark phase, which was not obvious in the pattern of
pineal melatonin. Therefore, linear correlation between those two
parameters was strong in BH rats (r = 0.578, P < 0.0001) but rather weak
in ACI (r = 0.411, P < 0.005) and LEW rats
(r = 0.377, P < 0.011). Compared with ACI rats,
BH and LEW rats exhibited pineal melatonin rhythms with three- and
fivefold amplitudes and plasma melatonin rhythms with two- and
threefold amplitudes, respectively. Thus most nighttime values of BH
and LEW rats were significantly different from the corresponding values
of ACI rats (P < 0.05).
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Fig. 4.
Twenty-four-hour profiles of melatonin concentration in pineal gland in
ACI, BH, and LEW rats (means ± SE,
n = 6). Black bar indicates dark
period. *,+ P < 0.05 vs. ACI
and BH, respectively.
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Fig. 5.
Twenty-four-hour profiles of plasma melatonin concentration in ACI, BH,
and LEW rats (means ± SE, n = 6).
Black bar indicates dark period.
*,+ P < 0.05 vs. ACI and BH,
respectively.
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Strain differences in the amount of melatonin synthesis were more
obvious at the level of daily production rates or 24-h integrals (Table
2). Daily melatonin synthesis was four and
six times higher in BH and LEW rats, respectively, than in ACI rats,
resulting in highly significant strain differences
[F(2,15) = 198.8, P < 0.0001]. In
contrast, ANOVA of the 24-h integrals of plasma melatonin revealed only
a barely significant strain difference
[F(2,15) = 5.34, P < 0.018], with LEW
rats showing only ~30% higher plasma melatonin concentration than
ACI and BH rats. Estimates of broad-sense heritability were rather high
for daily pineal melatonin synthesis, but moderate for daily plasma
melatonin levels (Table 2).
In vitro autoradiography revealed marked strain differences of specific
125I-labeled 2-melatonin binding
in the SCN of animals that were killed in the middle of the light
period (Fig. 6). A statistically higher
density of melatonin binding sites was observed in the SCN of the LEW
rats (P < 0.05) compared with the
two other strains. Indeed, the maximal melatonin binding was similar in
the ACI and BH rats (Bmax = 7.4 ± 0.6 and 7.8 ± 0.5 fmol/mg protein, respectively) but higher in the LEW rats (Bmax = 10.6 ± 0.3 fmol/mg protein). The SCN receptor affinity to
125I-labeled 2-melatonin, as
revealed by the
Kd, was highest
in the BH rats
(Kd = 106 ± 15 pM) followed by LEW and ACI rats
(Kd = 116 ± 9 and 125 ± 23 pM, respectively). Saturation data indicated the
presence of a single high-affinity receptor site for melatonin in all
three strains
(rACI = 0.994, rBH = 0.996, rLEW = 0.999).
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Fig. 6.
Saturation curves and Scatchard regression plots
(inset) of specific
125I-labeled 2-melatonin binding
in suprachiasmatic nuclei region of rats killed in middle of light
phase (12:12-h LD cycle). Values are means ± SE
(n = 5 rats). B/F, bound/free.
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DISCUSSION |
Inbred strains of small rodents with genetically determined differences
in their activity rhythms provide a powerful tool for investigating the
temporal organization of the circadian system (10, 11, 13, 55, 56). In
the present study, rats of the inbred strains ACI, BH, and LEW, with
characteristic differences in amplitude and temporal organization of
diurnal wheel running activity rhythms (55), were analyzed for
comparable strain differences in another output parameter of the
circadian system: the qualitative and quantitative pattern of melatonin secretion.
The results of the present study confirmed previous findings that aMT6s
is a suitable parameter for monitoring melatonin rhythms of individual
animals (3, 49). The aMT6s excretion rates of all rat strains nicely
reflected the temporal pattern of pineal and plasma melatonin
concentrations both quantitatively and qualitatively, with, however, a
time lag of about 2 h in all three strains as a result of melatonin
catabolism. Therefore, strain-dependent differences in catabolic
capacity for the conversion of melatonin to its metabolite can be
excluded. The two aMT6s 24-h cycles analyzed for each rat proved to be
highly consistent; i.e., aMT6s excretion patterns were very stable
within individuals. A similar low cycle-to-cycle variability of aMT6s
has also been reported in humans (31).
In Syrian hamsters, a close relationship between temporal patterns and
phase shift responses of pineal melatonin and wheel running activity
rhythms has been demonstrated (15, 28), which suggests that both
parameters are controlled by the same rhythm-generating system.
We therefore expected to find strain-dependent differences in the
melatonin rhythm as well. However, the diurnal patterns of aMT6s
excretion and melatonin concentration were similar in all three
strains, and they all displayed a unimodal pattern. This suggests a
considerable divergence in the temporal organization of the two output
parameters of the circadian system. However, the finding of separate
temporal patterns in locomotor activity and melatonin synthesis does
not come as a complete surprise for the following reasons. First, none
of the numerous studies on melatonin secretion has ever reported the
occurrence of several discrete melatonin peaks during an undisturbed
dark phase. Second, uncoupling or divergence of different circadian
rhythms or components is quite common. For example, in continuous
bright light rats become arrhythmic with respect to locomotor activity
and melatonin production, whereas neural oscillations within the SCN
persist (21). When mammals are maintained in moderate
constant light, the activity rhythm exhibits an endogenous period
dependent on light intensity, whereas the melatonin rhythm is
completely suppressed (2). Third, SCN transplantation experiments
indicate that different output pathways control locomotor activity
rhythms and melatonin synthesis. Although SCN transplants can restore
the circadian rhythm of locomotor activity most probably by diffusible
signals (46), no reestablishment of pineal function has ever been
observed (30). The present findings, therefore, support the hypothesis that the circadian rhythms of locomotor activity and melatonin synthesis are controlled by different output pathways from the SCN.
The efferent projection from the SCN to the pineal gland is well
characterized and ends in a sympathetic innervation of the pineal gland
regulating the melatonin synthesis (37). On the other hand, the neural
pathway mediating circadian rhythms of locomotor activity has not yet
been identified, and there is no reason to exclude the possibility that
ultradian modulations of the activity patterns are a result of
physiological or neuronal modifications of the output pathways.
The rat strains clearly differed in the amplitudes of aMT6s and
melatonin rhythms. ACI rats, which showed the highest level of
activity, had the lowest amounts of melatonin. In contrast, BH and LEW
rats, which had low levels of activity, displayed two- to fourfold
higher melatonin rhythm amplitudes. In studies on Wistar rats (12:12-h
LD cycle), maximal aMT6s rhythm amplitudes of ~60 and 25 ng/h were
found by Brown et al. (3) and Kennaway and Rowe (23), respectively. Our
findings in BH and LEW rats are consistent with Brown's data, whereas
the aMT6s measurements of the ACI rats are similar to Kennaway's
measurements. Therefore, we cannot identify one strain that shows
"normal" melatonin values. In general, the amount of melatonin
produced during the night correlates positively with the light
intensity present during the photophase (22, 33). This raises the
possibility that the highest levels of pineal melatonin were found in
LEW rats, because the albinotic LEW strain perceives light more
intensively than the pigmented ACI and BH strains. This hypothesis is
partly supported by a direct comparison of eight different rat strains demonstrating that most pigmented strains show smaller-sized pineal glands with lower melatonin concentration than albino strains (24, 54).
However, maximal melatonin content measured in the albinotic LEW/Han
rats was only 700 ± 29 pg/pineal, which corresponds to the
melatonin concentration found in the present study for the pigmented
ACI/Ztm rats (751 ± 124 pg/pineal), whereas our albinotic breeding
stock LEW/Ztm showed far higher melatonin levels of 3,691 ± 358 pg/pineal. The assumption of a pigmentation-dependent melatonin
production is also in conflict with a recent study on Wistar rats,
which demonstrated that pigmented or hooded Wistar rats had similar
aMT6s rhythm amplitudes but started aMT6s excretion ~2 h earlier than
albino Wistar rats (23). The pigmented Wistar rats produced even more
melatonin during the night. Thus it seems unlikely that the observed
strain differences in pineal function were simply a result of the
different eye pigmentation of the rats.
In the present study, regression analyses of melatonin synthesis and
aMT6s excretion versus wheel running activity revealed a strong
negative correlation between strains but not within strains. This
suggests that the levels of melatonin synthesis and locomotor activity
are not causally related but are strain dependent and most probably
genetically coupled characteristics of the circadian system. It is now
well accepted that exogenous melatonin has an entraining and
phase-shifting effect on the circadian system (2, 5, 8, 25, 32, 43),
but there is only limited evidence for a physiological effect of
melatonin on the level of activity. For example, systemic
administration of melatonin at pharmacological doses reduces locomotor
activity via a decrease of brain serotonin release (9). Such an
inhibitory effect of melatonin on locomotor activity would at least
partly explain the low level of overall activity accompanied by high
melatonin concentrations in BH and LEW rats. However, this hypothesis
needs to be verified by additional studies comparing the effects of
pinealectomy and/or constantly high melatonin administration on
activity levels among the strains.
A recent study of the three inbred rat strains ACI, BH, and LEW
demonstrated strain-dependent differences in the density of arginine
vasopressin (AVP) neurons of the SCN (56). The number of AVP neurons
was significantly higher in ACI rats, which have a strong unimodal
activity pattern, than in BH and LEW rats, which have dissociated
multimodal activity patterns. Such a positive correlation between the
number of AVP neurons and the strength of circadian activity rhythms
has also been demonstrated in selected lines of mice (4). These data
suggest that AVP neurons may be part of the SCN output pathways
controlling circadian rhythms of locomotor activity. Furthermore, they
raise the question of a causal relationship between the number or
density of AVP neurons, melatonin secretion from the pineal gland, and
dissociation of circadian activity patterns.
It is assumed that melatonin can affect the coupling of oscillatory
units within the SCN (8), inasmuch as melatonin can accelerate the
reentrainment of activity rhythms and synchronize disrupted components
of the circadian system in constant light (6). In accordance with our
working hypothesis, the bimodal and multimodal activity patterns of BH
and LEW rats, respectively, could be the result of a desynchronization
of multiple circadian oscillators caused by the reduction or complete
loss of melatonin feedback on the SCN. However, the present findings of
rather high melatonin secretion levels in BH and LEW rats do not
support this hypothesis, because one would expect the two strains with
the ultradian activity patterns to have a rather low level of
melatonin. A possible explanation for this obvious contradiction would
be the partial or complete insensitivity of the SCN to the feedback effect of melatonin. Therefore, we also measured the density of melatonin receptors in the SCN of all three strains in the middle of
the photophase, when receptor density should be elevated (18, 19, 29,
34). However, melatonin receptor density was higher in LEW rats, which
showed higher melatonin content, than in ACI rats with low levels of
melatonin. Thus the present results of high melatonin levels and
receptor density do not support our previous assumption that the
bimodal and multimodal activity patterns of BH and LEW rats are caused
by a reduction or loss of melatonin feedback on the SCN.
An additional noteworthy result of the present study is that the strain
difference in SCN melatonin receptor density supports previous findings
that melatonin seems to affect the density of its own receptors in the
SCN (16-18). However, other studies have reported conflicting
results. On one hand, there is evidence for an inverse relationship
between melatonin levels and receptor density. For example, elevated
melatonin concentrations at night were accompanied by a decreased
amount of melatonin receptors in the SCN, whereas low melatonin
concentrations during the photophase were accompanied by increased
melatonin receptor density (18). Furthermore, enhanced melatonin
concentrations induced by stress reduced specific melatonin binding in
the SCN of the rats (50). These short-term effects of melatonin are
most likely regulated by a mechanism of downregulation. On the other
hand, there is evidence that long-term effects of melatonin can
stimulate the density of its receptors in the SCN. For example,
long-term pinealectomy decreased melatonin binding sites (17).
Furthermore, maternal melatonin seems to stimulate the synthesis of
melatonin receptors in the SCN of newborn rats, because receptor
density was ~20% lower in pups born to pinealectomized dams (57).
This stimulating effect of melatonin on its own receptor density in the
SCN is in accordance with our results in the LEW rats, where high
levels of melatonin were accompanied by a high melatonin receptor density.
The present study demonstrated pronounced strain differences in
activity rhythms, pineal function, and melatonin receptor density in
the SCN. ACI rats displayed unimodal locomotor activity patterns with a
high amplitude of activity, but low levels of melatonin secretion and
melatonin receptor density in the SCN. In contrast, LEW rats showed
dissociated activity patterns with a reduced amplitude of overall
activity but rather high levels of melatonin and melatonin receptor
density in the SCN. The inbred rat strains ACI, BH, and LEW may
therefore prove to be useful models to further investigate the complex
interaction between the circadian control of pineal function and
feedback effects of melatonin on the SCN as well as on other circadian
output parameters, such as locomotor activity.
| |
ACKNOWLEDGEMENTS |
The authors thank Tanja Brinschwitz, Yvonne Friedrich, Denise
George, Siegried Hilken, Andreas Kalkowski, Markus Kohler, Susanne Matuschek, and Doris Weissbach for technical assistance and Andreas Herrmann for reviewing the manuscript.
| |
FOOTNOTES |
This work was supported by a grant from the Deutsche
Forschungsgemeinschaft (Wo 354/8-2).
The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement"
in accordance with 18 U.S.C. §1734 solely to indicate this fact.
Address for reprint requests and other correspondence: G. Klante,
Biological Institute, Dept. of Animal Physiology, Univ. of Stuttgart,
Pfaffenwaldring 57, D-70550 Stuttgart, Germany.
Received 28 May 1998; accepted in final form 11 January 1999.
| |
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