Development of Vasoactive Intestinal Peptide mRNA Rhythm in the Rat Suprachiasmatic Nucleus

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Volume 17, Number 10, Issue of May 15, 1997 pp. 3920-3931
Copyright ©1997 Society for Neuroscience

Development of Vasoactive Intestinal Peptide mRNA Rhythm in the Rat Suprachiasmatic Nucleus

Yuriko Ban¹, Yasufumi Shigeyoshi², and Hitoshi Okamura²
¹ Department of Ophthalmology, Kyoto Prefectural University of Medicine, Kyoto 602, Japan, and ² Department of Anatomy and Brain Science, Kobe University School of Medicine, Kobe 650, Japan

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Development of the daily rhythm of vasoactive intestinal peptide (VIP) mRNA in the rat suprachiasmatic nucleus (SCN), a mainlocus of circadian oscillation, was investigated by in situ hybridization.The phenotypic expression of VIP neurons occurred in two developmentalstages in the ventrolateral portion of the SCN (VLSCN): the firstwas found before birth in the rostral part, and the second occurredin the main part between postnatal day (P) 10 and P20. The latterperiod coincided with the time that the massive VIP-efferent fibersproject to the subparaventricular zone. In the adult and P20,the VIP mRNA signals of the SCN showed a clear diurnal rhythmwith a trough in the light phase and a peak in the dark phaseunder light/dark (LD) conditions, but under constant dark (DD)conditions, no VIP mRNA fluctuations were observed. At P10, however,it was found that SCN VIP mRNA showed a peak at the transitionfrom night to day and a trough at early dark period in LD conditions,in sharp contrast to the night peak in the adult rhythm. In DDconditions, a light-phase peak and a dark-phase trough were alsoobserved at P10, contrasting the arrhythmic feature at adult stage.The present findings suggest that daily VIP rhythm was first generatedin the early developed clock-controlled rostral SCN neurons, andlater regulated by light-dependent main VLSCN neurons.
Key words: suprachiasmatic nucleus; vasoactive intestinal peptide; in situ hybridization; development; circadian rhythm

INTRODUCTION

The hypothalamic suprachiasmatic nucleus (SCN) contains a circadian oscillator that is involved in behaviors and hormonalsecretion in mammals (Moore, 1983). The rat SCN contains manypeptidergic neurons, of which vasoactive intestinal peptide (VIP)neurons are restricted to the ventrolateral portion of the SCN(VLSCN) (Card et al., 1981). The VLSCN receives innumerable photicsignals from the retinal ganglion cells directly through the retinohypothalamictract (RHT) (Hendrickson et al., 1972; Moore and Lenn, 1972) orindirectly through the geniculohypothalamic tract (GHT) (Swansonet al., 1974). Photic information conveyed by these pathways entrainsthe circadian clock to an environmental light/dark time schedule(Meijer and Rietveld, 1989). VIP neurons in the VLSCN receivesynaptic contacts by both the direct (Ibata et al., 1989) andindirect (Hisano et al., 1988) pathways, and it is known thatVIP gene expression is negatively regulated by the photic stimuli(Takahashi et al., 1989; Albers et al., 1990; Okamoto et al.,1991). Because the light-evoked rhythms disappear under constantdark (DD) conditions and the VIP level decreased in proportionto the duration of light exposure (Shinohara et al., 1993), theexpression of VIP is driven not by an endogenous circadian clock,but rather by the photic information, when the adult SCN was examined.

However, there is much evidence that VIP expresses its own endogenous rhythm after surgical or pharmacological manipulationsof the SCN afferents. The serotonin depletion by intraperitonealinjection of parachlorophenylalanine, an inhibitor of the rate-limitingenzyme of serotonin synthesis, induced endogenous VIP rhythm independentof photic cues in DD-conditioned rats (Okamura et al., 1995).Serotonergic inputs from the midbrain raphe nuclei are anothermajor input to the VLSCN (Moore et al., 1978), and synapse withVIPergic neurons (Kiss et al., 1984; Bosler and Beaudet, 1985).Similar light-independent endogenous VIP rhythms were detectedin somatostatin-depleted cysteamine-treated rats (Fukuhara etal., 1994) and in slice cultures of the SCN in vitro (Shinoharaet al., 1994). To explain these phenomena, we hypothesized previouslythat synaptic inputs from various VLSCN afferents inhibit theendogenous rhythm of VIP under normal conditions, and that theelimination of these synaptic inputs liberates the endogenousrhythm. In the present study, we investigated the VIP mRNA rhythmat various developmental stages, during which the invasion ofnerve afferents and the formation of synaptic contacts are rapidlyoccurring. In the SCN, the first retinal terminals arrive at thelast embryonic stage (Bunt et al., 1983), prominent synaptogenesisoccurs between postnatal day (P) 4 and P10 (Moore and Bernstein,1989), and raphe-serotonergic and GHT-neuropeptide Y (NPY) afferentsincrease between P10 and P20 (Takatsuji et al., 1995). Takingthese developmental data into account, we analyzed the developmentof the daily rhythm of VIP mRNA level by semiquantitative in situhybridization, with special reference to the site of expressionof VIP phenotype in the VLSCN.

MATERIALS AND METHODS
Animals. Pregnant female Wistar rats (Nihon Animal Care, Osaka, Japan) were obtained at 7-10 d of gestation (timed pregnancy).They were maintained in individual cages under the standard laboratoryconditions with diurnal lighting (light on at 7:00 A.M., lightoff at 7:00 P.M.) and free access to food and water. These ratstypically gave birth on the 22nd day after mating. The day aftermating was designated embryonic day (E) 1. To study the fetuses,pregnant females were anesthetized with pentobarbital (Nembutal,70 mg/kg), and the fetuses were removed and perfused. The fetuseswere anesthetized by deep low-temperature anesthesia. The timeof birth was carefully noted, and the day after birth was designatedP1. All postnatal animals were anesthetized with ether beforebeing killed. We used fetuses of both sexes, but only male postnatalrats.

For the developmental immunocytochemical study, E17 animals were used (n = 3), as well as E18 (n = 3), E19 (n = 2), E20 (n= 3), E22 (n = 2), P1 (n = 5), P5 (n = 5), P10 (n = 5), P20 (n= 5), and P50 (adult; n = 5) animals. For the developmental insitu hybridization histochemistry experiments, animals were usedat E17 (n = 3), E18 (n = 3), E19 (n = 2), E20 (n = 2), E22 (n= 2), P1 (n = 5), P5 (n = 5), P10 (n = 5), P20 (n = 5), and P50(adult; n = 5).

For the quantitative developmental analysis of the in situ hybridization signals, animals at P1, P5, P10, P20, and P50 (5rats per group) were killed at Zeitgeber time (ZT) 4 (4 hr afterthe onset of the light phase; ZT0 was defined as the transitiontime from the dark to light phase) under the standard LD conditions.

The daily rhythm of the VIP mRNA signals was also analyzed in P10, P20, and P50 rats. After 2 weeks of adaptation to the standardlight/dark cycles, half of the rats (n = 30 at each developmentalstage) were transferred to DD conditions before being subjectedto experiments on the third day in constant darkness. The restof the animals were kept under LD cycles. In these experiments,circadian time (CT) 0 and CT12 are referred to as 7:00 A.M. and7:00 P.M., respectively, because locomotor activity measurementsindicated that 2 d of free running in darkness did not shift thephase of the animals' rhythm by >0.5 hr (data not shown). Theanimals were killed for in situ hybridization at ZT0, ZT4, ZT8,ZT12, ZT16, and ZT20 for the LD entrained rats, and at CT0, CT4(4 hr after the onset of the third subjective day), CT8, CT12,CT16 (4 hr after the onset of the third subjective night), andCT 20 for the DD free-running rats. The dams were purchased beforepartum, four to five male pups were chosen, and these litterswere nursed for 10-20 d. The dams were also associated with theirlitters until they were killed.

The experimental protocol of the current research was approved by the Committee for Animal Research at Kobe University Schoolof Medicine and the Kyoto Prefectural University of Medicine.

Immunocytochemistry. Under deep ether anesthesia, animals at E17, E18, E19, E20, E22, P1, P5, P10, P20, and P50 were perfusedvia the left cardiac ventricle with 200 ml of 0.1 M phosphatebuffer (PB) containing 4% paraformaldehyde and 0.2% picric acid.The brains were then removed and post-fixed in the same fixativesolution for 2 d. Serial frontal sections (thickness: 60 µm forembryonic animals, 40 µm for postnatal animals) from the rostralend of the SCN to the retrochiasmatic area were made on a cryostat.The sections were incubated with an anti-VIP serum (code no. R5302;courtesy of Dr. N. Yanaihara, Yanaihara Institute; diluted 1:5000with 1% PB containing 0.3% Triton X-100) at 4°C for 3 d. Theywere then incubated with biotinylated anti-rabbit IgG (1:1000,Vecta) at 4°C overnight and an avidin-biotin-peroxidase conjugate(1:1000, Vecta) at 4°C overnight. The immunoreactions were visualizedin 0.05 M Tris-HCl buffer, pH 7.5, containing 0.02% 3,3 $'$ -diaminobenzidinetetrahydrochloride and 0.003% H₂O₂. The reaction was stopped bythe transfer of the sections into 0.05 M Tris-HCl buffer. Thespecificity of the antisera used has been described elsewhere(Yanaihara et al., 1977; Okamura et al., 1986, 1987). The sectionswere mounted onto chrome-alum-coated slides, air-dried, clearedin a graded series of ethanol, cleared in xylene, and then mountedin Entellan (Merck, Darmstadt, Germany).

In situ hybridization. Under deep ether anesthesia, animals at E17, E18, E19, E20, E22, P1, P5, P10, P20, and P50 were perfusedvia the left cardiac ventricle with PB containing 4% paraformaldehyde.The brains were removed, post-fixed in the same fixative for 12hr at 4°C, and transferred into 20% sucrose in PB for 24 hr. Frontalsections (40 µm in thickness) were made using a cryostat, collectedinto 4× SSC, and then processed for in situ hybridization as describedpreviously (Okamura et al., 1995). Briefly, the sections weretreated with 0.1 mg/ml proteinase K (Sigma), 10 mM Tris buffer,pH 7.4, and 10 mM EDTA for 5 min at 37°C, 4% paraformaldehydein 0.1 M PB for 5 min, and 0.25% acetic anhydride in 0.1 M triethanolaminefor 10 min. The sections were then incubated in hybridizationbuffer [50% formamide, 0.025% yeast tRNA, 0.025% herring spermDNA, 1× Denhardt's solution (0.02% Ficoll/0.02% polyvinyl pyrolidone/0.02%bovine serum albumin), 1% Saccosyl, 100 mM dithiothreitol, 600mM NaCl, and 60 mM sodium citrate] containing the ³⁵S-dATP-labeled oligonucleotide probe complementary to the ratVIP mRNA for 12 hr at 42°C. The nucleotide sequence of the probecomplementary to the rat VIP mRNA (Nishizawa et al., 1985) was5 $'$ -GTCGCTGGTGAAAACTCCATCAGCATGCCT GGCATTTCTGGA-3 $'$ (42-mer) (agift from Dr. S-I.T. Inouye, Yamaguchi University). The probewas 3 $'$ end-labeled using [³⁵S]dATP (6000 Ci/mM; New England Nuclear) and terminal deoxynucleotidyltransferase (Takara Shuzo, Kyoto, Japan), and was used at a finalconcentration of 3.2 × 10⁶ dpm/ml. To elucidate the time difference in the VIP mRNA signalsof the SCN, we hybridized sections from six different time pointsin the same chamber. After hybridization, these sections wererinsed in 2× SSC/50% formamide for 15 min four times, and in 1×SSC for 30 min twice at 42°C. The sections were mounted onto gelatin-coatedmicroscope slides, air-dried, and dehydrated through a gradedalcohol series. The slides were exposed to an imaging plate (radiosensitiveplates coated with BaFBr:Eu²⁺; Fuji Film) for 24 hr, after which the slides were apposed to $beta$ -max film (Amersham International) at 4°C for 4 d. The $beta$ -maxfilms were developed by a Kodak D19 developer for 5 min at 20°C.The section-mounted slides were dipped in Kodak NTB2 nuclear trackemulsion (dilution 1:1 distilled water), developed after 12 weeks,and counterstained by Nissl staining (cresyl violet).

VIP mRNA-positive cells were counted in each rostrocaudally arranged SCN section (40 µm in thickness) in a representativerat at each stage (P10, P20, and adult). By Nissl staining, SCNwas recognized as the small, compactly packed cell mass locatedbilaterally just dorsal to the optic chiasma. Most rostral SCNsections judged by the Nissl were designated as No. 1, and thefollowing sections were sequentially numbered at the rostrocaudaldirection.

Quantification of the signals and statistical analysis. To quantify the VIP mRNA signals, the radioactivity of each SCN onthe imaging plate was measured as photo-stimulated luminescence(PSL) emitted from the imaging plate when scanned with a laserbeam, and was analyzed using a microcomputer interfaced to animage analyzing system (BAS2000; Fuji Film). In this system, awide range of linearity was established between the isotope radioactivityand the PSL signals (Amemiya and Miyahara, 1988). The total radioactivitycount of the sections is considered proportional to the amountof VIP mRNA present. The number of PSL signals in the preopticarea of each section was zero. The PSL values of the SCN in eachrat were summed from the most rostral to the caudal end. In thestudy of the VIP mRNA signals in the SCN at each developmentalstage, signals at each developmental point were expressed as mean± SEM (n = 5). Statistical analyses of the data were made by usingone-way ANOVA followed by Scheffe's multiple comparisons test.In the study of the daily rhythm of VIP mRNA signals at P10, P20,and P50, the average of the VIP signals was estimated at eachdevelopmental stage (n = 5). At each time point, the value wasexpressed as a percentage of the average VIP mRNA level and asmean ± SEM (n = 5), which was also statistically analyzed by one-wayANOVA followed by Scheffe's multiple comparisons test.

RESULTS

Macroautoradiographic analysis of the development of VIP mRNA in the SCN
At E17, no VIP mRNA was detected in the forebrain, including the SCN. VIP mRNA signals first appeared in the SCN at E18 (Fig.1). At this stage, the signals were very weak, but the signalintensity increased until E21, at which point distinct signalswere detected in the SCN.
Fig. 1. In situ hybridization of VIP mRNA in the prenatal period. Photomicrographs were taken from $beta$ -max film. Scale bar, 1 mm.
[View Larger Version of this Image (67K GIF file)]

After birth, VIP mRNA signals increased progressively in density and intensity. We semiquantified the VIP mRNA increase bysumming the SCN sections in each rat at different developmentalstages using an image analyzing system (Fig. 2). Until P5, thePSL value was less than one-tenth of the adult value. The increasebecame pronounced from P5 to P10, and the sharpest increase inVIP mRNA was observed between P10 and P20. By P20, the signalintensity had reached the adult level.
Fig. 2. Postnatal development of VIP mRNA levels shown as the total amount of PSL on imaging plates. The data are shown as the mean± SEM, and examples of the images are shown under the time schedule.
[View Larger Version of this Image (33K GIF file)]

VIP rhythm in the SCN in late neonatal (P10), weaning (P20), and adult stages (P50)
The image analyzing system (BAS2000; Fuji Film) for quantifying VIP mRNA signals in the present study has a wide range oflinearity between isotope radioactivity and PSL signals, but theresolution sensitivity is not very high. Thus, daily variationsin the weak signals (e.g., at P5; one-tenth of the adult value)could not be examined by this system. Therefore, we analyzed ratsonly at P10 (late neonatal period) and P20 (weaning stage), comparingthose at P50 (adult).

In the adult SCN under LD conditions, the VIP mRNA signals showed a clear diurnal rhythm: a trough during the early lightphase (ZT4) and a gradual increase until the early night phase(ZT16), followed by a gradual decrease (Fig. 3). The VIP mRNAlevels showed diurnal variations in adult stage (ANOVA, F_(5,24)= 5.486, p < 0.01). In the adult SCN under DD conditions, no VIPmRNA fluctuations were observed (ANOVA, F_(5,18) = 0.53, p > 0.5).
Fig. 3. Diurnal and circadian profiles of VIP mRNA levels in the SCN at P10, P20, and adult (P50).
[View Larger Version of this Image (22K GIF file)]

VIP mRNA signals in P20 rats also showed a diurnal rhythm under LD conditions: a peak at ZT20 and a trough at ZT4 (ANOVA,F_(5,24) = 3.607, p < 0.05) (Fig. 3). However, the amplitude wassmaller than in the adult. In P20 rats under DD conditions, themean values at each time point varied widely, but they do notrepresent a statistically significant difference (ANOVA, F_(5,24)= 1.565, p > 0.2).

P10 rats also showed the diurnal rhythm under LD conditions (ANOVA, F_(5,12) = 9.570, p < 0.01). Surprisingly, the phase ofthe rhythm was completely different from the adult and P20 rats.P10 rats showed a peak at the onset of the light phase (ZT0) anda trough 4 hr after the onset of the dark phase (ZT16) (Fig. 3).Moreover, we found that under DD conditions, the VIP mRNA showeda rhythm; the VIP mRNA levels showed a peak at the early subjectiveday (CT4) and a trough at the early subjective night (CT16) (ANOVA,F_(5,18) = 3.783, p < 0.05).

Cellular analysis of the VIP neurons in the developing SCN
One day later (E19) or on the same day (E18) of the first appearance of the VIP mRNA signals, VIP-immunoreactive neurons appearedin the VLSCN (data not shown). At this stage, weakly immunoreactivecell bodies with faintly immunopositive fibers were restrictedto the ventral border of the VLSCN, and no immunoreactive materialswere found in the dorsomedial part or outside of the SCN. FromE21 to P1, the number of immunoreactive cell bodies and proximalprocesses increased, and a few processes had reached the dorsomedialpart of the SCN (Fig. 4B). Rarely, solitary fibers were detectedin the paraventricular thalamic nucleus and the retrochiasmaticarea (data not shown). At P5, the VIP immunoreactivity and mRNAsignals had increased, but their pattern of distribution in theVLSCN was basically similar. However, a moderate number of VIP-immunoreactivefibers were found in the dorsomedial part of the SCN, and sparseSCN-efferent VIP fibers to the anterior hypothalamic area weredetected at this stage (data not shown).
Fig. 4. Immunocytochemistry (A, B) and emulsion images of in situ hybridization (C-E) of VIP at P1. A, Rostrocaudal arrangement ofVIP immunoreactivity in the SCN. Note that immunoreactivitieswere distributed not in the whole part, but only in limited areasof the VLSCN in most sections. B, Higher magnification photomicrographof A3. Boundaries of SCN at P1 are encircled with dotted lines.C, D, Dark-field photomicrographs of VIP mRNA at the most rostral(C) and the middle (D) level of the SCN. At the middle level ofthe VLSCN, the signal mass was detected in the main medial (MM)part (thick short arrow), extending ventral thin wings to thelateral part (thin long arrows). E, Bright-field higher magnificationphotomicrograph of D counterstained with cresyl violet. oc, Opticchiasma; v, third ventricle. Scale bars, 100 µm.
[View Larger Version of this Image (124K GIF file)]

The distinctive feature of the distribution pattern of VIP neurons in the SCN at these perinatal stages is that the area ofVIP distribution was very narrow; the positive immunoreactivityand mRNA signals were restricted in the medial part of the VLSCN(Fig. 4A3,A4,D,E), extending ventral thin wings in a lateral direction(Fig. 4D, double thin arrows). Thus, most of the VLSCN neuronsdid not show VIP phenotype. The adult-type distribution showingthe positive signals throughout the whole VLSCN was found onlyin the most rostral section.

To examine the anatomical correlation with the age-dependent changes in the VIP mRNA rhythm, we performed a more detailedmorphological analysis of VIP gene-expressing cells in the SCNat P10 (late neonatal period) and P20 (weaning stage), and comparedthose at P50 (adult) in serial in situ hybridization sections(40 µm thickness). In Nissl staining, SCN was distinguished easilyby the surrounding anterior hypothalamic area by a landmark ofthe dense accumulation of small, packed cells. In rostrocaudallyordered Nissl-stained sections, VIP mRNA-positive cells were firstfound in the second or third section from the rostral head ofthe SCN at all stages examined (see Fig. 6).
Fig. 6. Counts of VIP mRNA-positive cells in each rostrocaudally arranged section in one representative rat at each stage (P10, P20,and adult). Section 1 was designated as the most rostral SCN sectionrecognized by Nissl staining, and the section number was sequentiallyordered at the rostrocaudal direction. Section thickness was 40µm at all stages.
[View Larger Version of this Image (16K GIF file)]

At P10, in the rostral level of the nucleus (Fig. 5, P10, numbers 1 and 2), strong VIP mRNA signals were evenly found in thewhole region of VLSCN. This whole VLSCN distribution pattern wasfound in the only two serial sections (i.e., 80 µm thickness),but after those (Fig. 5, P10, number 3), there was a tendencyfor the medial VIP signal intensity to be higher than the lateralhalf of the VLSCN. In the middle sections (Fig. 5, P10, numbers4 and 5), the signal level decreased suddenly, and a signal wasconfined to the medial part (Fig. 5, MM) with no labeling in thelateral part (Fig. 5, ML). In the caudal sections (Fig. 5, P10,numbers 6 and 7), the signal was also sparse.
Fig. 5. Emulsion images of VIP mRNA in the SCN at P10, P20, and adult (P50). All serial sections (40 µm thickness) from one rat ateach stage are presented in order of rostrocaudal direction. Atmiddle-level sections (P10, number 4; P20, number 5) of P10 andP20, VLSCN was subdivided further into lateral (middle-lateral;ML) and medial (middle-medial; MM) parts, and the borders of MMand ML are presented as arrowheads. (R) and (C) are representativesections of rostral and caudal SCN, respectively. Scale bars,100µm.
[View Larger Version of this Image (76K GIF file)]

The VIP mRNA distribution changed dramatically between P10 and P20. At P20, the sections showing the whole VLSCN distributionpattern increased in number (rostral four sections, i.e., 160µm thickness; Fig. 5, P20, numbers 1, 2, 3, and 4). A slight mediolateraldistribution tendency was observed at the next section (Fig. 5,P20, number 5), and this tendency is more pronounced in the twosubsequent sections (Fig. 5, P20, numbers 6 and 7). However, incontrast to P10 rats, it should be noted that the level of signalsin these middle-level sections did not decrease. In the caudalsections (Fig. 5, P20, numbers 8 and 9), the signal level clearlydecreased.

VIP mRNA signals in adults were found in the whole VLSCN in most of the SCN sections (Fig. 5, ADULT, numbers 1, 2, 3, 4, 5,6, and 7), and the mediolateral gradient was only found in caudaltwo sections (Fig. 5, ADULT, numbers 8 and 9). The level of signalintensity was high throughout the SCN. The development of theVIP mRNA is schematically summarized in horizontal plane as Figure8A.
Fig. 8. A, Schematic representation of the development of VIP mRNA at P1, P10, P20, and adult in the SCN in the horizontal plane.Gray area represents the VIP cell body distribution, and the dottedline shows the border of SCN outlined by Nissl staining. B, Schemaof the phenotypic expression time (underlined) in each compartmentof the SCN, and the invasion time of SCN afferents [serotonin(5-HT), GHT-NPY, and RHT]. Invasion time of the SCN afferentswas adapted from Takatsuji et al. (1995). C, Schema of the developmentalchange of VIP mRNA rhythms. See Discussion for details.
[View Larger Version of this Image (35K GIF file)]

The above tendency was confirmed by the count of VIP mRNA-positive cell number in each rostrocaudally ordered section (Fig.6). In Nissl staining, SCN was detected from number 1 to number14 at P10, number 1 to number 16 at P20, and number 1 to number17 at adult. From the most rostral section (number 1) to the number5 sections, VIP cell number was similar at each stage, but afterthe number 6 sections, the P10 stage shows a completely differentpattern compared with other stages; VIP cell number concomitantlydecreased after number 6 at P10, but the high levels of cell numberwere observed until number 11 and number 12 sections at P20 andadult. The total cell number of the SCN in each developmentalstage was 352 (P10), 682 (P20), and 835 (adult).

Immunocytochemical analyses were also performed in P10, P20, and adult rats. Compared with P1 rats, the innervation of VIP-stainedfibers to the dorsomedial part of the SCN had greatly increasedby P10 (Fig. 7A), and the immunoreactive density was about thesame as the P20 and adult rats (Fig. 7C,E). However, at P10, theextra-SCN dorsal projections were weak, and very few projectionswere observed in the subparaventricular zone (Watts and Swanson,1987) just ventral to the paraventricular nucleus (Fig. 7B). AtP20, the VIP-efferent projections to the subparaventricular zonehad increased dramatically and reached the adult level (Fig. 7D,F).
Fig. 7. Immunocytochemistry of VIP at P10 (A, B), P20 (C, D), and adult (P50) (E, F) in SCN (A, C, E) and the subparaventricular zone(B, D, F). A long thin arrow indicates the main portion of theVLSCN, and a thick hollow arrow indicates the dorsomedial partof the SCN. PVN, Hypothalamic paraventricular nucleus; v, thirdventricle. Scale bars, 100 µm.
[View Larger Version of this Image (145K GIF file)]

DISCUSSION
In the present study, we demonstrated that VIP mRNA showed an endogenous (light-independent) circadian rhythm in the earlypostnatal period (P10), and the conversion to the adult-type light-dependentrhythm took place between P10 and P20. The finding seems to beconsistent with the presence of the two ontogenetically differentVIP neuronal cell groups in the SCN; the first starts to be expressedbefore birth, and the second between P10 and P20.

Rhythm of VIP expression in the SCN
In the adult stage, we found that VIP mRNA signals in the SCN showed a night-peak and day-trough type of diurnal rhythm inLD conditions, whereas no VIP mRNA fluctuations were observedunder DD conditions. The result is consistent with previous reportsat the peptide (Albers et al., 1987; Takahashi et al., 1987, 1989;Morin et al., 1991; Shinohara et al., 1993) and mRNA levels (Gozeset al., 1989; Albers et al., 1990; Okamoto et al., 1991; Yanget al., 1993). In the present study, we also found that VIP geneexpression was regulated by light at the weaning stage (on P20)as it was in adults; the VIP mRNA signals under LD conditionsshowed a peak at dark phase and a trough at light phase, but norhythm was found in DD conditions.

P10 rats also showed a diurnal rhythm under LD conditions. However, in contrast to the adult and P20 rhythms, the result ofanalysis on P10 animals showed a peak at the onset time of thelight phase, and a trough in early dark phase. Moreover, on P10even under DD conditions, the VIP mRNA level in the SCN demonstrateda clear circadian rhythm with a peak on the early subjective dayand a trough on the early subjective night. The peaks in the subjectiveday and troughs in the subjective night resemble the reporteddeoxyglucose uptake rhythm (Schwartz et al., 1980), electricalactivity rhythm (Inouye and Kawamura, 1979, 1982), and vasopressinrhythm at both the peptide (Tominaga et al., 1992) and mRNA (Cagampangand Inouye, 1994) levels in the SCN. The current observation suggeststhat VIP mRNA level at P10 is under the influence of the circadianclock.

Previously, we hypothesized that VIP gene expression in the SCN may be regulated by synaptic inputs from outside the SCN,and that the elimination of these extrinsic factors might revealthe endogenous VIP rhythm, from the in vivo evidence of the overtendogenous rhythm in DD-conditioned serotonergic afferent-omittedrats (Okamura et al., 1995) and in vitro data of rhythmic VIPrelease in long incubated SCN slice culture (Shinohara et al.,1994). Our present results seem to fit this speculation. For synaptogenesisin the SCN, Moore and Bernstein (1989) reported that synapticcontacts were rare in the E21 to P2 stages, but that they increasedstrikingly from P4 to P10, and by P10, the number of synapseswas approximately 70% of the total synaptic number in adults.At P10, many of the synaptic types found in adults were found(Moore and Bernstein, 1989), but it should be noted that sometypes of synapses were rare at this point (i.e., small pleomorphicsynapses with densely stained presynaptic terminals containinglarge dense-core vesicles, perhaps including the peptidergic ones,and axosomatic synapses, indicating inhibitory synapses). Synapticdiversity and the complexity of the neuropile continued for upto 5 weeks (Lenn et al., 1977). For the development of optic nerveinnervation in the SCN, Güldner (1978) reported that optic nerveterminals containing characteristic tubular mitochondria madesynapses first at P9, and these optic synapses increased and maturedfrom P17 to P27. Thus, it is evident that synaptic contacts arenot complete at P10, and our results can be interpreted to suggestthat late-forming synapses may be important for the suppressionof the endogenous VIP rhythm. If this is the case, then it couldbe speculated that VIP shows an endogenous rhythm in younger animals.VIP mRNA first appeared at E18 in the SCN and increased progressivelythereafter, which was consistent with the previous developmentalstudies using in situ hybridization and peptide immunocytochemistry(Ishikawa and Frohman, 1987; Hares and Foster, 1988; Laemle, 1988).However, the levels at E18 to P5 were less than one-tenth of theadult rat mRNA levels. Unfortunately, our present quantitativeanalysis using the macroautoradiographic imaging plates failsto adequately detect such low-level expression of VIP mRNA inthese perinatal animals. More sensitive and quantitative methodsmight reveal the VIP rhythm at an earlier neonatal stage.

Two VIP neuronal hypotheses and the conversion of the endogenous rhythm to the light-dependent rhythm
In the present study, we found that VIP phenotype expression occurs in the SCN in two steps: the first appeared in the fetalperiod in the rostral VLSCN, and the second occurs later, mainlybetween P10 and P20 in the main portion of the VLSCN (Fig. 8A).The delayed appearance of VIP mRNA phenotypes in the main portionof the nucleus may have several explanations based on neurogenesis,neuronal migration, and phenotypic expression. [³H]Thymidine autoradiography suggested that the neurogenesis ofrat SCN neurons started at E14 and ended at E17 (Ifft, 1972; Altmanand Bayer, 1978). Thus, the later appearance of VIP mRNA expressionis not attributable to neurogenesis. The possibility of the migrationof VIP neurons from the rostral VLSCN to the main part of VLSCNcannot be excluded at present. However, even if it could occur,the migration alone cannot explain the increase in the total cellnumber at P20, which was two times as much as that at P10, andthis difference cannot be explained without assuming the appearanceof newly differentiated VIP mRNA-positive cells in the SCN (particularlyin the VLSCN).

What factors then trigger the phenotypic expression of neurons in the main VLSCN? One possibility is that the innervationfrom other brain structures trigger the phenotypic expressionof VIP neurons (Fig. 8B). It is generally accepted that the neuronsproduced from the final mitotic division of progenitor cells needenvironmental factors to express its phenotype (Anderson, 1989).Genetic expression of specific genes is known to be regulatedby a number of neurotrophic factors, and it is known that neurotransmitters,in addition to their mediation of transsynaptic information coding,can induce a spectrum of effects on neuronal outgrowth, plasticity,and survival (Lauder, 1993). In this context, it is interestingthat the first timing of NPY and serotonergic innervation to theSCN (Takatsuji et al., 1995) coincides with the period of latephenotypic expression of VIP in the main part of VLSCN (Fig. 8B).Retinal fibers may not have a direct effect on this conversion,because the first retinal innervation was already detected beforebirth and concomitantly increased until P20 (Bunt et al., 1983;Takatsuji et al., 1995). However, it is possible that the opticsynaptic formation influences the maturation, because the mostprominent time of the increase of optic synapses was between P12and P17 (Güldner, 1978).

The demonstration of two developmentally different VIP neuronal groups in the VLSCN may explain the conversion of VIP rhythmsoccurring from P10 to P20. The endogenous rhythm generated bythe early developed rostral VLSCN VIP neurons is later taken overby the light-dependent rhythm generated by the late-developedmain VLSCN VIP neurons controlled by the inputs conveying externaltime cues. Do the rostral VIP VLSCN neurons still keep the endogenousrhythmic expression at the adult stage? The answer is not yetknown, because we failed to remove and analyze the rostral VLSCNgroup, since in the adult rat, rostral VLSCN and main VLSCN VIPneurons are tightly packed and distributed in continuity. It alsois not known whether undifferentiated main VLSCN neurons beforeP10 have the ability to produce an endogenous rhythm, becausein our experiments they were analyzed only after the expressionof VIP mRNA.

The demonstration of endogenous rhythms in the neonatal period suggests that VIP neurons play a role as a circadian oscillator,at least in early developmental life. It should be noted thatthe existence of VIP neurons in grafts correlates with the restorationof circadian locomotor activity in a transplantation experienceusing fetal SCN cells (Silver et al., 1990; Lehman et al., 1991).A slice culture study showing the endogenous VIP release alsoused SCN tissues from neonatal animals (Shinohara et al., 1994).It is interesting to note that those studies use SCN tissue atthe early developmental stage, when SCN contains only the earlydeveloped endogenous rhythmic VIP cells, without having late-forminglight-dependent VIP cells. The endogenous rhythm of VIP in ratsdeveloped in total darkness from birth (Glazer and Gozes, 1994)also might be attributable to the undifferentiation of the mainVLSCN VIP neurons.

Immunocytochemical analysis showed that the fiber density of the dorsomedial part of the SCN was low at P1 and reached theadult level at P10. Because the formation of intra-SCN VIP fiberplexus appeared complete by P10, it is possible that the earlyformed rostral VLSCN neurons are involved mostly in the intra-SCNcommunication. However, the projection of VIP efferents to otherbrain areas was not established until P10. SCN has efferent projectionsto the various parts of the brain, but according to Watts et al.(1987), the most intensive projection was to the subparaventricularzone, a part of the anterior hypothalamic and medial preopticareas. By immunocytochemistry, many authors have shown that themajority of efferents of SCN VIP neurons terminate to this area(Watts, 1991; Okamura and Ibata, 1994). Because the increasingperiod of VIP innervation to the subparaventricular zone coincideswith the appearance of VIP neurons in the main VLSCN, it is possiblethat the majority of VIP efferents occurs from main VLSCN neurons,unlike the rostral VLSCN neurons which are intrinsic.

The efferent projection of late-forming VIP neurons can be related to the development of behavioral and hormonal rhythms.It is known that the entrainment of circadian locomotor activityto the environmental light/dark cycle was first observed betweenP10 and P14 (Honma and Hiroshige, 1977). Circadian fluctuationof plasma corticosterone was observed in the third to fourth weekof postnatal days (Takahashi et al., 1979; Hiroshige et al., 1982).These findings suggest that the circadian oscillating signalsremained disconnected from the locomotor center or the hormoneregulating center until P10. In support of these findings, thepresent study demonstrates that the primary VIP efferents fromSCN to the subparaventricular zone, from which many outputs transmittedto most brain areas (Watts, 1991), were weak at P10. The completionof these VIP efferents may start transmission of SCN oscillation,and the multiple synaptic relay will convey these rhythms to thebehavioral and hormonal centers. However, contrary to these rhythms,a pineal sympathetic rhythm was present by P4 (Moore, 1991), anda pineal enzyme N-acetyltransferase rhythm occurred from P4 toP7 (Duncan et al., 1986). This suggests that the SCN output pathwaycontrolling the melatonin rhythm is different from those of otherbehavioral and corticosterone controlling systems.

In conclusion, we demonstrated that the phenotypic expression of main VIP neurons in the SCN appears at a late stage of development,although some rostral VIP traits were produced before birth. Moreover,in the study of the development of daily VIP mRNA rhythm, we found,unexpectedly, that the VIP mRNA rhythm was driven by an endogenousclock in the early developmental period. The endogenous rhythmgenerated by the earlier rostral group is gradually taken overby the light-dependent VIP rhythm generated later by the maingroup. These findings suggest that the mammalian circadian systemoccurs early in the fetal period and develops and performs environmentaladaptation by differentiating a new cell group in the circadianpacemaking center, which integrates the information from environmentalcues.

FOOTNOTES

Received Nov. 25, 1996; revised Jan. 24, 1997; accepted Feb. 27, 1997.

This work was supported in part by grants from the Kanehara-Ichiro Memorial Foundation, the Ciba-Geigy Foundation, and theMinistry of Education, Science, Sports, and Culture of Japan.We thank Dr. Y. Ibata (Kyoto Prefectural University of Medicine)for his support and encouragement throughout the experiment. Wealso thank Dr. S-I.T. Inouye (Yamaguchi University) for criticalreading of this manuscript, Dr. T. Inatomi for the preliminaryexperiment, and Dr. N. Yanaihara for donating anti-VIP serum.

Correspondence should be addressed to Dr. Hitoshi Okamura, Department of Anatomy and Brain Science, Kobe University Schoolof Medicine, 7-5-1 Kusunoki-cho, Chuo-ku, Kobe 650, Japan.

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