Repression of the Calcitonin Gene-Related Peptide Promoter by 5-HT1 Receptor Activation

PeproTech - Your Source for Neuroscience Research Reagents

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (33)

Citing Articles via Google Scholar

Google Scholar

Articles by Durham, P. L.

Articles by Russo, A. F.

Search for Related Content

PubMed

PubMed Citation

Articles by Durham, P. L.

Articles by Russo, A. F.

Pubmed/NCBI databases
Compound via MeSH
Substance via MeSH
Hazardous Substances DB
CALCIUM COMPOUNDS
CALCIUM, ELEMENTAL

Previous Article  |  Next Article

Volume 17, Number 24, Issue of December 15, 1997

Repression of the Calcitonin Gene-Related Peptide Promoter by 5-HT₁ Receptor Activation

Paul L. Durham¹, Ram V. Sharma², and Andrew F. Russo¹
Departments of ¹ Physiology and Biophysics and ² Anatomy and Cell Biology, University of Iowa, Iowa City, Iowa 52242

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

We have investigated the control of calcitonin gene-related peptide (CGRP) expression by a serotonergic agonist that is relatedpharmacologically to currently used antimigraine drugs. Duringmigraines, CGRP levels are elevated but then returned to normalby a 5-HT₁ receptor agonist, sumatriptan. However, neither themolecular nor cellular targets of this drug are known. Trigeminalneurons are the major source of cerebrovascular CGRP, and thuswe have used trigeminal primary cultures and the neuronal-likeCA77 thyroid C-cell line as a model. We first demonstrate thatsumatriptan and another 5-HT₁ agonist, CGS 12066A (CGS), causea robust and prolonged increase with oscillations in intracellularcalcium in CA77 cells. CGS caused a similar increase in trigeminalcultures. We then show that CGS treatment leads to a decreasein CGRP mRNA levels in the CA77 cells. This decrease is attributableto the repression of promoter activity through two discrete elements:(1) the cAMP-responsive region, via a cAMP-independent mechanism;and (2) the cell-specific enhancer, which binds the upstream stimulatoryfactor helix-loop-helix protein and a cell-specific activator.These results demonstrate that activation of the endogenous 5-HT₁receptor is coupled to calcium signaling pathways and leads toinhibition of CGRP gene transcription.
Key words: CGRP; transcription; trigeminal; thyroid C-cells; serotonin; 5-HT₁ receptor; sumatriptan; calcium

INTRODUCTION

Calcitonin gene-related peptide (CGRP) has been well characterized as the most potent peptide vasodilator of peripheral andcerebral vessels (Brain et al., 1985; McCulloch et al., 1986).Alternative processing of the primary transcript yields the hormonecalcitonin (CT) in thyroid C-cells and CGRP in neurons (Rosenfeldet al., 1983). In the cerebrovasculature the major source of CGRPis perivascular nerve endings from the trigeminal ganglia (McCullochet al., 1986; O'Conner and Van der Kooy, 1988). High levels ofcirculating CGRP have been measured during migraine and clusterheadache (Goadsby and Edvinsson, 1993, 1994; Edvinsson and Goadsby,1994) and have been implicated in neurogenic inflammation (Goadsbyet al., 1988; Buzzi et al., 1991). Recently, sumatriptan, a serotonintype 1 (5-HT₁) receptor agonist commonly used in the treatmentof migraine, has been reported to selectively return CGRP to normalserum levels and alleviate the headache (Ferrari and Saxena, 1993;Edvinsson and Goadsby, 1994; Buzzi et al., 1995). Based on pharmacologicalevidence, this drug is known to interact preferentially with thehuman and rat 5-HT_1B, 5-HT_1D, and 5-HT_1F receptors (Boess andMartin, 1994). Although the mRNAs for these receptors have beendetected in trigeminal ganglia (Bruinvels et al., 1992; Rebecket al., 1994; Bouchelet et al., 1996), it is not known if theseneurons express functional receptors. Hence, the mechanisms bywhich 5-HT₁ antimigraine drugs may regulate CGRP levels have notbeen investigated.

The 5-HT₁ receptors generally have been viewed as coupled to the inhibition of adenylate cyclase via pertussis toxin-sensitiveG_i-proteins (see Boess and Martin, 1994). More recently, the receptorsalso have been reported to elevate intracellular calcium levelswhen stably expressed in fibroblast cell lines (Adham et al.,1993; Zgombick et al., 1993). CT/CGRP gene transcription and peptidesecretion are increased by cAMP (deBustros et al., 1986, 1992;Monia et al., 1995), and prolonged elevated calcium has been reportedto lower CT and CGRP mRNA levels in a C-cell line (Zeytin et al.,1987). However, there have been contradictory reports on calciumregulation in C-cells, possibly because of the experimental systems(Jacobs et al., 1983; Besnard et al., 1989). In either case, thecAMP-dependent and/or calcium-dependent regulation of CT/CGRPgene expression may be potential targets of 5-HT₁ agonists.

In this study we have demonstrated that 5-HT₁ receptors are coupled to calcium pathways in trigeminal neurons and the CA77rat medullary thyroid carcinoma C-cell line. The CA77 cells providea useful neuronal model system (Russo and Lanigan, 1996; Russoet al., 1996) that eliminates the complicating heterogeneity oftrigeminal ganglia. We primarily used CGS 12066A (CGS) (Nealeet al., 1987) as a 5-HT₁ receptor agonist, along with other agonistsand antagonists. We have shown that CGS decreases CGRP steady-statemRNA levels and CT/CGRP promoter activity in CA77 cells. The CGSresponsiveness is mediated via two distinct elements, a cAMP-responsiveregion and the cell-specific enhancer. These results raise thepossibility that at least one mechanism of action of serotonergicantimigraine drugs may be to inhibit CGRP transcription in trigeminalneurons.

MATERIALS AND METHODS
Cell culture. Trigeminal ganglia primary cultures were based on the protocol of Vedder and Otten (1991). Ganglia from 2-week-oldSprague Dawley rats were dissociated with Dispase II (Life Technologies,Gaithersburg, MD). The cells from four ganglia were plated onglass coverslips coated with mouse EHS laminin (Life Technologies)and incubated in L15 medium, 10% fetal bovine serum (FBS), and5 ng/ml mouse 2.5 S nerve growth factor (Sigma, St. Louis, MO)at 37°C in 5% CO₂. CA77 cells were maintained in Ham's F-12/DMEM(low glucose) (1:1) and 10% FBS at 37°C in 7% CO₂. Parental HeLacells and HeLa cells stably transfected with the human 5-HT_1Breceptor (Hamblin et al., 1992) (from M. Hamblin, Seattle VeteransAffairs Medical Center, Seattle, WA), were maintained in Ham'sF-12 and 10% FBS at 37°C in 5% CO₂. Penicillin and streptomycinwere added to all media. CA77 cells used for RNA isolation andtransfection were subcultured for 24 hr in serum-free medium (Clarket al., 1995b). Pertussis toxin (100 ng/ml; Sigma) treatmentsoccurred for 20 hr before the experiment. CGS-12066A monomaleate,N-(3-trifluoromethylphenyl) piperazine hydrochloride (TFMPP),1-(3-chlorophenyl)piperazine dihydrochloride (mCPP), methiothepinmesylate, and SB 206553 hydrochloride were obtained from ResearchBiochemicals International (RBI, Natick, MA). The original CGScompound was synthesized as a dimaleate (CGS 12066B maleate) (Nealeet al., 1987), but the two forms appear to have the same pharmacologicalproperties (RBI, R. P., personal communication). Sumatriptan succinatewas obtained from the University of Iowa Pharmacy. CGS was preparedat 10 mM in 0.1N HCl, with aliquots stored at $-$ 20°C; TFMPP andmCPP were prepared fresh at 10 mM in 0.1N HCl and water, respectively.In all studies the cells were treated with equivalent amountsof vehicle.

Calcium measurements. Intracellular calcium levels in cultured trigeminal neurons and CA77 cells were measured by a videomicroscope digital image analysis system (Photon Technology, SouthBrunswick, NJ), as described previously (Sharma et al., 1995).Briefly, dissociated trigeminal ganglia and CA77 cells grown onlaminin-coated 25 mm glass coverslips were maintained in phenol-and serum-free medium 24 hr before the start of the calcium imagingprocedure. Cells were incubated in DMEM (high glucose) containing0.2% bovine serum albumin and 1-4 µM fura-2/AM for 30-45 min at37°C in 5% CO₂. Higher basal calcium levels were seen with thelonger loading time (compare Tables 1 and 2). After washingthe cells twice with DMEM/bovine serum albumin, we incubated thecells for 30 min before measurement, using a Nikon Diaphot microscope.Basal calcium levels were measured for a minimum of 60 sec inuntreated cells or for 300 sec in cells treated with antagonistsbefore the addition of CGS. For the pertussis toxin study, cellswere kept in the presence of toxin. An equal volume of mediumcontaining agonist or vehicle (at two times the final concentration)was added directly to the cells, and measurements were recordedevery 10 sec, generally for 6-10 min (up to 30 min in some experiments),on a heated stage at 37°C. Calcium levels in individual cellswere determined by using a 50 × 50 pixel area in the center ofeach cell.

Table 1. Effect of CGS on intracellular calcium levels in CA77 cells

[CGS] n Basal (nM) Peak (nM) Fold increase Peak time (sec)

1 µM 45 142 ± 6.1 179 ± 5.7 1.26 ± 0.10 242 ± 10

10 µM 71 160 ± 3.9 381 ± 27 2.38 ± 0.16 225 ± 7.3

50 µM 49 148 ± 7.2 684 ± 20 4.62 ± 0.12 204 ± 7.6

The values are the mean and SE (n = number of cells). Basal values were measured in untreated cells 30 sec after the startof the experiment. Peak values correspond to the maximum [Ca²⁺]_i measured during the 6 min sampling period. The fold increaseindicates the change from basal to peak calcium levels for eachindividual cell. The peak times are the time of maximal recorded[Ca²⁺]_i after the addition of CGS. Cells were loaded for 45 min withfura-2.

Table 2. Effect of serotonergic agents on intracellular calcium levels in CA77 cells

Agent n Basal (nM) Peak (nM) Fold increase Peak time (sec)

CGS (1 µM) 29 64 ± 3.0 139 ± 4.5 2.17 ± 0.08 355 ± 17

CGS (1 µM) + 0.1 µM MET 25 61 ± 1.8 85 ± 3.1 1.41 ± 0.04 352 ± 13

CGS (1 µM) + 1.0 µM MET 42 52 ± 2.2 61 ± 3.3 1.18 ± 0.05 368 ± 10

CGS (10 µM) 40 66 ± 2.9 265 ± 18 4.02 ± 0.30 319 ± 16

CGS (10 µM) + 10 µM MET 19 64 ± 4.4 142 ± 2.7 2.22 ± 0.04 325 ± 23

CGS (10 µM) + 50 µM MET 32 70 ± 3.1 117 ± 3.8 1.67 ± 0.05 291 ± 13

CGS (10 µM) + 100 µM MET 36 58 ± 1.9 69 ± 2.6 1.20 ± 0.04 305 ± 9

CGS (10 µM) + 2 µM SB 26 51 ± 1.9 197 ± 9.8 3.89 ± 0.19 308 ± 19

CGS (10 µM) + 50 µM SB 31 64 ± 2.8 274 ± 15 4.28 ± 0.27 341 ± 19

mCPP (50 µM) 15 73 ± 5.4 263 ± 5.5 3.60 ± 0.08 293 ± 24

Sumatriptan (20 µM) 26 60 ± 3.2 198 ± 6.8 3.30 ± 0.11 218 ± 18

CGS (10 µM) + PTX 85 69 ± 3.0 280 ± 8.3 4.06 ± 0.11 328 ± 17

Sumatriptan (20 µM) + PTX 27 55 ± 2.8 187 ± 7.3 3.40 ± 0.09 222 ± 19

The values are the mean and SE (n = number of cells). Basal values were measured in untreated cells 60 sec after the startof the experiment. Peak values are the maximum [Ca²⁺]_i measured during the 10 min sampling period. The fold increaseindicates the change from basal to peak calcium levels calculatedfor each individual cell. The peak times are the time of maximalrecorded [Ca²⁺]_i after the addition of the agent. Cells were preincubated withmethiothepin (MET) or SB 206553 (SB) for 5 min before the additionof CGS or treated overnight with pertussis toxin (PTX, 100 ng/ml).Cells were loaded for 30 min with fura-2.

cAMP and adenylate cyclase assays. CA77 cells were incubated with 10 µM forskolin (Sigma) in the presence or absence of 10µM CGS for 30 min at 37°C, and total cAMP was measured by a cAMP-specificradioimmunoassay (Jaquette and Segaloff, 1997). Adenylate cyclaseassays and membrane preparations were performed as described (Salomon,1979). Reactions were initiated by the addition of membranes (10µg) to the assay and then incubated for 20 min at 30°C. Membraneswere treated with vehicle or 100 µM forskolin ±10 µM CGS or 5-HTcreatine sulfate complex (freshly prepared in dilute acid; RBI).

RNA isolation, RT-PCR, and Northern blots. Total RNA was isolated and analyzed by Northern blots as described (Clark et al.,1995b). After the removal of CGRP probe from the filter, the membraneswere hybridized with a ³²P-labeled rabbit mitochondrial cytochrome oxidase subunit II (COII) cDNA (Durham et al., 1992). The signals were quantitated withNational Institutes of Health Imagescan software. RT-PCR conditionsand 5-HT_1B oligonucleotide sequences have been described (Clarket al., 1995a). Total RNA (2 µg) was used to generate first-strandcDNA with Moloney murine leukemia virus reverse transcriptase,and the products were resolved on 2% agarose gels.

Plasmids and transfection assays. Many of the rat CT/CGRP and thymidine kinase (TK) luciferase reporter plasmids and the cytomegalovirus(CMV) $beta$ -galactosidase reporter plasmid have been described (Tverbergand Russo, 1992, 1993; Lanigan et al., 1993; Lanigan and Russo,1997). The 1250 bp CT/CGRP luciferase reporter contains sequencesfrom the KpnI site ( $-$ 1250) to the Sau3A site (+21) in exon 1.The 280 bp cAMP response element (CRE)-CT-luciferase reportercontains a PCR fragment from $-$ 280 bp to +21 bp. The 1160-920+BamTK reporter contains a BamHI linker (CGGATCCG) inserted at thePvuII site ( $-$ 1038 bp) of the 1160 to 920 bp TK-luciferase gene(Tverberg and Russo, 1993). Complementary oligonucleotides withBamHI ends were annealed and ligated into the BamHI site of theTK-luciferase plasmid. The H/O and H/O+A reporters used in ourstudies contained four tandem repeats in the sense orientation.The H/O+A mutant sequence (5 $'$ -ggatccGGCAGCTGTGCAAATCCTggatcc-3 $'$ )(BamHI ends in lower case) contains an adenosine nucleotide (underlined)inserted between the HLH and octamer motifs to create a consensusoctamer binding site within the H/O enhancer. All plasmids weresequenced to confirm the insertions.

CA77 cells were transiently transfected by electroporation with 10-20 µg of plasmid DNA at 200 V, 960 µF (Tverberg and Russo,1992). HeLa cells were transfected with 20 µg of DNA at 240 V,960 µF. Transfected cells were equally divided among 60 mm dishescontaining serum-free medium, treated with CGS or other agentsfor the times indicated, and harvested 14-20 hr later. This protocolinsured that the control and drug-treated cells had equal transfectionefficiencies. For the time course, 10 µM CGS was added immediatelyafter transfection and then removed from the cells at the indicatedtimes by washing in PBS, followed by the addition of medium withoutCGS for the remainder of the time. In the forskolin and cAMP experiments,cells were pretreated for 1 hr in 10 µM CGS or vehicle and thentreated for an additional 4 hr with vehicle, CGS, 10 µM forskolin,or 500 µM dibutyrl cAMP (Sigma). Luciferase was measured withreagents from Promega (Madison, WI). In some experiments the transfectionefficiencies were normalized to $beta$ -galactosidase measured withgalacto-light reagents (Tropix, Bedford, MA). The $beta$ -galactosidasenormalization did not significantly alter the relative activities.Each experimental condition was repeated in at least three independentexperiments done in duplicate.

RESULTS

Elevation of calcium levels in CA77 cells by CGS
To study the mechanisms controlling trigeminal CGRP gene expression, we used the CA77 thyroid C-cell line as a model system.This was necessitated because trigeminal ganglia are a heterogeneouspopulation of neuronal and non-neuronal cells. It is estimatedthat <23% of the neurons express CGRP (O'Conner and van der Kooy,1988). The CA77 cell line was established from a rat medullarythyroid carcinoma, yet it has a neuronal phenotype that is characterizedby high levels of CGRP and expression of 5-HT_1B receptor mRNA(Clark et al., 1995a; Russo and Lanigan, 1996; Russo et al., 1996).In addition, both trigeminal neurons and C-cells share a neuralcrest origin. The pyrroloquinoxaline CGS was used in our studiesas a 5-HT₁ agonist. CGS was characterized initially as a 5-HT_1Bspecific agonist; however, it has not been tested against manyof the more recently discovered 5-HT receptors, such as 5-HT_1F.A major advantage of CGS is that it is not likely to be metabolizedby monoamine oxidases (MAO), because the chemical structure ofCGS does not contain an amine group. These properties were importantbecause a drawback of the CA77 cells is that they express theserotonin reuptake transporter and MAO, and the full spectrumof 5-HT receptors is not known (Clark et al., 1995a; Russo etal., 1996). Hence, the use of CGS allowed us to circumvent thesecomplications pharmacologically.

We determined whether CA77 cells express functional 5-HT₁ receptors, using CGS in conjunction with other agonists and antagonists.The approach was to measure intracellular calcium levels, becausethe cloned 5-HT_1B receptor has been reported to elevate calciumlevels transiently (Zgombick et al., 1993). Calcium levels weremeasured with the calcium-sensitive fluorescent dye fura-2. Theaddition of 10 µM CGS caused a marked increase in intracellularcalcium levels when compared with basal levels in the same cellsbefore CGS treatment (Fig. 1). After the addition of CGS, elevatedlevels of calcium were maintained in each cell for at least 30min, the longest time point measured in this study. CGS also causedoscillations in calcium levels that were superimposed on the overallincrease. As a control, calcium levels did not change appreciablyafter the addition of vehicle for at least 10 min (data not shown).The dosage required for detecting increased calcium levels was~1 µM (Table 1). At 10 µM, CGS caused a several-fold increasein calcium levels (Tables 1 and 2) and was used for subsequentexperiments.
Fig. 1. CGS increases the concentration of intracellular calcium in CA77 cells. Intracellular calcium concentrations, [Ca²⁺]_i, were measured by using fura-2 and a microscopic digital imagingsystem. A, Basal levels in cells loaded for 30 min. B, Levels5 min after the addition of 10 µM CGS. CGS elevated [Ca²⁺]_i in all cells. The pseudocolor scale indicates the 340/380 nmexcitation wavelength ratio and corresponding [Ca²⁺]_i.
Fig. 3. CGS increases the concentration of intracellular calcium in primary trigeminal neuron cultures. Intracellular calcium concentrations,[Ca²⁺]_i, were measured, using fura-2 in trigeminal neurons after 3d in culture. A, Basal levels in cells loaded for 45 min. B, Levels4 min after the addition of 10 µM CGS. Marked increases in [Ca²⁺]_i are observed in the soma of trigeminal neurons. The pseudocolorscale indicates the 340/380 nm excitation wavelength ratio and[Ca²⁺]_i.

[View Larger Version of this Image (75K GIF file)]

The specificity of CGS was demonstrated by using methiothepin as a 5-HT type 1 receptor antagonist. The addition of methiothepinat concentrations previously used to block 5-HT₁ receptors (Adhamet al., 1993; Zgombick et al., 1993) essentially blocked the actionof 10 µM CGS (Table 2). Concentrations of methiothepin as lowas 0.1 µM could effectively inhibit calcium increases caused bysubsaturating concentrations (1 µM) of CGS. In contrast, the additionof a different antagonist, SB 206553, at concentrations that blockthe 5-HT_2C and 5-HT_2B receptors (Kennet et al., 1996), did notaffect CGS activity (Table 2). This particular antagonist waschosen because the efficacy of CGS on 5-HT_2C receptors had notbeen tested, and this receptor is coupled to calcium.

We then demonstrated that two other 5-HT type 1 receptor agonists, sumatriptan and mCPP (Boess and Martin, 1994), also increasedcalcium levels to a comparable extent (Table 2). Sumatriptanshould activate multiple 5-HT₁ receptors at the concentrationthat was used. This dosage was chosen on the basis of the relativebinding affinities of sumatriptan and CGS to the 5-HT_1B receptor(Boess and Martin, 1994). Although mCPP is not completely selectivefor type 1 receptors (it can also activate the type 2C receptors),its activity is consistent with the action of CGS. As anothertest for specificity, we showed that 10 µM CGS increased calciumlevels in HeLa cells stably transfected with the human 5-HT_1Breceptor (Hamblin et al., 1992), but not in parental HeLa cellsthat lack 5-HT_1B receptors (data not shown).

As an initial characterization of the type of G-protein coupled to the 5-HT_1B receptor in CA77 cells, we tested the effectof pertussis toxin on CGS and sumatriptan activity. Preincubationwith pertussis toxin overnight had no detectable effect on CGS-or sumatriptan-induced elevation in intracellular calcium (Table2). These data are in contrast to the inhibitory effect of pertussistoxin on 5-HT-stimulated calcium levels in cells stably transfectedwith 5-HT_1B receptors (Zgombick et al., 1993). This differencein coupling is consistent with differences in the type of calciumresponse in the two studies. Although we observed a delayed, sustainedincrease in calcium, Zgombick et al. (1993) reported a rapid,transient elevation in calcium. Our results argue that CGS andsumatriptan are activating 5-HT₁ receptors that are coupled bya pertussis toxin-insensitive G-protein to a calcium signalingpathway in CA77 cells.

CGS increases calcium levels in cultured trigeminal neurons
Although 5-HT_1B receptor mRNA had been found in adult rat trigeminal ganglia by in situ hybridization, there was no informationon the signaling mechanism in these cells. To address this issue,we established primary cultures from day 14 neonatal rat trigeminalganglia. We first confirmed that 5-HT_1B receptor mRNA was expressedin these ganglia by using RT-PCR (Fig. 2). Only a single productwas detected. It was the predicted size and comigrated with RT-PCRamplification products from CA77 cells and rat brain. The identityof the CA77 amplified product was established by sequence analysis(Clark et al., 1995a). As a control for contaminating DNA, noproduct was detected in the absence of reverse transcriptase.
Fig. 2. 5-HT_1B receptor mRNA in trigeminal ganglia. Total RNA isolated from day 14 neonatal rat trigeminal ganglia and brain and fromCA77 cells was reverse-transcribed and PCR-amplified, using 5-HT_1Bspecific primers. A 303 bp 5-HT_1B cDNA product was detected inCA77 cells (lane 3), trigeminal ganglia (lane 5), and rat brain(lane 7). As controls, RT-PCR was performed with H₂O as a substitutionfor an RNA template (lane 2) or in the absence of reverse transcriptase(lanes 4, 6, 8). A 100 bp DNA standard is shown in lane 1. Aninverse image of an ethidium bromide-stained gel is shown.
[View Larger Version of this Image (51K GIF file)]

We then asked whether CGS also would activate a calcium pathway in cultured trigeminal neurons. We observed a robust, sustained(>15 min) increase in intracellular calcium levels after 10 µMCGS treatment when compared with basal levels in the same cells(Fig. 3). In addition to the sustained overall increase in calcium,there was also a series of calcium oscillations after CGS treatment.Elevated calcium levels were observed initially in the soma andshortly thereafter in the neurites. These data demonstrate thatCGS activation of 5-HT₁ receptors is coupled to increases in intracellularcalcium in both trigeminal neurons and CA77 cells.

CGS does not decrease cAMP levels
The effect of CGS on cAMP levels in CA77 cells was measured to determine if CGS also might be coupled to the more classical5-HT₁ signaling pathway. However, 10 µM CGS had no significanteffect on the 20-fold increase in cAMP levels caused by 1 hr offorskolin treatment (Table 3). We also observed no effect ofCGS on cAMP levels in cells plated at twice the normal cell density(n = 2) or in cells treated for 20 min (n = 2). To confirm thatCGS did not affect cAMP levels significantly, we directly measuredadenylate cyclase activity in CA77 membrane preparations. CGS(10 µM) had little or no effect on the approximately fourfoldforskolin stimulation of adenylate cyclase activity. The greatestrepression by CGS was ~14%, and no decrease was detected in mostexperiments. A similar lack of an effect was seen after treatmentwith 10 µM 5-HT, with at most a 10% inhibition. These resultsindicate that 5-HT₁ receptors are not coupled to a cAMP-dependentpathway in CA77 cells.

Table 3. Effect of CGS on forskolin-stimulated cAMP levels in CA77 cells

Sample [cAMP] Fold increase

Control 0.77 ± 0.09 1

FSK 16.1 ± 3.8 20.9

FSK + CGS 19.1 ± 4.2 24.8

Total cAMP levels (pmol/ml) were measured from untreated CA77 cells (control) or cells treated with 10 µM forskolin (FSK)or 10 µM forskolin and 10 µM CGS for 60 min. The mean and SE fromtwo independent experiments with triplicate samples are reported.The fold increase in cAMP relative to control cells is shown.

CGS decreases CGRP mRNA levels
Because increases in calcium levels have been shown to regulate neuropeptide transcription in neuronal cells (MacArthur andEiden, 1996), we asked whether CGS would decrease CGRP steady-statemRNA levels. CA77 cells were treated with CGS for 14-16 hr, becauseit was reasoned that this amount of time would be needed to detecta change in the relatively stable CGRP mRNA (Cote and Gagel, 1986).Treatment of CA77 cells with 10 µM CGS resulted in a decreasein the level of both the nuclear precursor CT/CGRP RNA (~4 kB)and mature 1.2 kB CGRP mRNA (Fig. 4A). As a control, the membraneswere stripped and reprobed for CO II mRNA. The effect of CGS treatmenton CGRP mRNA levels normalized to CO II levels is shown in Figure4B. CGS treatment caused a threefold decrease in CGRP steady-statemRNA levels. These results demonstrate that a 5-HT₁ agonist candownregulate directly the CGRP transcripts in CA77 cells.
Fig. 4. CGS treatment downregulates CGRP steady-state mRNA levels. A, Northern blot analysis of total RNA (3 µg) from vehicle-treated(CON) or CGS-treated (CGS; 10 µM for 16 hr) CA77 cells. The filterwas hybridized with cDNA probes for CGRP (top) or CO II (bottom).B, Levels of CGRP mRNA from CGS-treated cells relative to controlcells. The CGRP signals were normalized to the density of theCO II band in the vehicle- and CGS-treated cells. The means andSE from four independent experiments are shown.
[View Larger Version of this Image (26K GIF file)]

Dose- and time-dependent inhibition of promoter activity by CGS
To determine whether the decrease in steady-state CGRP mRNA levels was the result of decreased gene transcription, we evaluatedthe effect of CGS on promoter activity by using the same treatmentparadigm. A luciferase reporter gene containing 1250 bp of the5 $'$ flanking sequences of the rat CT/CGRP promoter was transientlytransfected into CA77 cells. The 1250 bp fragment contains theregulatory sequences responsible for the cell-specific and cAMP-responsiveactivities of the rat CT/CGRP gene. CT/CGRP promoter activitywas decreased to ~10% of control levels after 16 hr of treatmentwith 10 µM CGS (Fig. 5A). In contrast, CGS had little or no effecton the activity of a cotransfected $beta$ -galactosidase reporter geneunder the control of the CMV promoter (Fig. 5A). CGS caused adose-dependent decrease in CT/CGRP promoter activity with half-maximalinhibition at ~2.5 µM (Fig. 5B). A similar value has been reportedfor CGS inhibition of forskolin-stimulated cAMP accumulation incells expressing the 5-HT_1B receptor (Unsworth and Molinoff, 1992).
Fig. 5. CGS repression of CT/CGRP promoter activity. A, CA77 cells were cotransfected with the CT/CGRP luciferase and CMV- $beta$ -galactosidasereporter genes. The CT/CGRP sequences contain a proximal cAMPresponse region (dotted box) and a distal enhancer that containsboth cell-specific (black box) and noncell-specific (striped box)elements. The cells were pooled and divided into parallel dishesthat were treated with the vehicle or 10 µM CGS for 16 hr. Themean reporter activity per 20 µg of protein with the SE is shownfrom four independent experiments. B, The effect of CGS dosageon CT/CGRP promoter activity. CA77 cells were treated with CGSor the maximum volume of vehicle for 16 hr. The activities werenormalized to the vehicle activities, which were generally 32,000light units per 20 µg of protein. The means and the SE from fourindependent experiments are shown, except the 0.1 µM CGS point,which is from a single experiment. C, The effect of CGS treatmenttime on CT/CGRP promoter activity. CA77 cells were treated with10 µM CGS or vehicle for the indicated times, washed to removeCGS, and incubated in medium without CGS until 20 hr after transfection.The activities were normalized to the vehicle activities at eachtime point. The means and the SE from two independent experimentsare shown.
[View Larger Version of this Image (21K GIF file)]

We then addressed whether shorter treatment times also could repress promoter activity. CA77 cells were treated with 10 µMCGS for 2, 4, or 8 hr, and then the drug was removed from theculture medium until the cells were harvested at 20 hr. A treatmenttime as short as 2 hr, followed by 18 hr without CGS, was sufficientto reduce activity by 50% (Fig. 5C). This indicates that CGS initiatesa reduction in CGRP promoter activity within a few hours thatis maintained even after removal of the drug.

We also demonstrated that two other 5-HT₁ receptor agonists, TFMPP and mCPP (Boess and Martin, 1994), were able to decreaseCT/CGRP promoter activity. At 10 µM TFMPP and 10 µM mCPP, promoteractivity was decreased to 28% ± 4% and 33% ± 6% of control, respectively(mean ± SEM; n = 3 independent experiments). The mCPP result isespecially relevant because this compound increased intracellularcalcium levels analogous to CGS. Although, as noted before, mCPPas well as TFMPP is not completely selective, when taken togetherwith the CGS data, these results indicate that 5-HT₁ receptoractivation leads to an inhibition of CT/CGRP promoter activity.

CGS can inhibit cAMP stimulation of CT/CGRP promoter activity
We then asked whether CGS inhibition of the cAMP-responsive element of the CT/CGRP gene could contribute to repression ofpromoter activity. Although we had shown that the effect of CGSwas not coupled to decreased cAMP levels (Table 3), increasedintracellular calcium can inhibit cAMP-responsive elements (Ginty,1997). We have localized the cAMP-responsive region of the ratCT/CGRP gene between $-$ 280 and $-$ 100 bp (P. L. Durham, unpublisheddata). This region shares a high degree of homology with the humanCT/CGRP gene, which contains two cAMP-responsive motifs locatedbetween $-$ 250 and $-$ 150 bp (deBustros et al., 1992; Monia et al.,1995).

The effect of CGS on forskolin stimulation of the CT/CGRP reporter genes was tested after treatment of the cells with forskolinfor 4 hr. The transcriptional activities of the 1250, 920, and280 bp CT/CGRP luciferase reporter genes were increased by forskolin2.7-, 4.6-, and 5.6-fold, respectively (Fig. 6). This stimulatoryeffect of forskolin was inhibited 50% or greater by cotreatmentwith CGS (Fig. 6). Comparable inhibition was seen with cells thathad been treated with CGS for 16 hr or only 1 hr before forskolintreatment. Importantly, similar results also were seen when dibutyrlcAMP was substituted for forskolin. Dibutyrl cAMP induced the280 bp CT/CGRP promoter activity fourfold, and cotreatment with10 µM CGS decreased this stimulation by 51% (±4%; n = 2 independentexperiments). As a control, TK-luciferase reporter activity wasrelatively unaffected by forskolin, dibutyrl cAMP, or CGS duringthe 4 hr treatment times. These results demonstrate that CGS specificallycan inhibit cAMP-stimulated transcription of the CT/CGRP gene.
Fig. 6. CGS inhibition of cAMP stimulation of CT/CGRP promoter activity. Luciferase reporter genes containing 1250, 920, or 280 bpof the 5 $'$ -flanking sequence of the CT/CGRP gene or the non-cAMP-responsive105 bp TK promoter were transfected into CA77 cells. The cAMP-responsiveregion is indicated by a dotted box, whereas the striped and solidboxes identify the noncell-specific and cell-specific enhancer,respectively. Cells were cotreated with 10 µM forskolin in thepresence (+) or absence ( $-$ ) of 10 µM CGS for 4 hr and assayedfor luciferase activity. The activities of the forskolin-treatedcells with or without CGS were normalized to vehicle (control)cells. The average activity for the TK control cells was ~1700light units per 20 µg of protein. The fold stimulations in responseto forskolin and SEM from at least four independent experiments,each in duplicate, are shown.
[View Larger Version of this Image (15K GIF file)]

Repression of cell-specific enhancer activity by CGS
Because CGS can repress CT/CGRP mRNA levels and promoter activity even in the absence of cAMP stimulation, we reasoned thatadditional sequences might be involved. To test this prediction,we used a series of luciferase reporter genes containing variousregions of 5 $'$ flanking DNA. We first compared the degree of repressionof the 1250 bp promoter fragment, which contains the distal cell-specificenhancer and proximal cAMP-responsive region, with a 920 bp promoter-reporter,which lacks the distal enhancer. CGS decreased the activity ofthe 1250 bp promoter to a much greater extent than the 920 bppromoter (Fig. 7). To allow comparisons between multiple experiments,we normalized the data to the TK-luciferase reporter and a cotransfectedCMV- $beta$ -galactosidase reporter for which the activity remained unchangedafter CGS treatment (see Fig. 5A). Because the TK reporter generallywas inhibited 1.5- to 2.5-fold by overnight CGS treatment, thisnormalization also facilitated the comparison between reporterscontaining different elements linked to the TK promoter. The relativelack of an effect on the 920 bp reporter illustrates that theCGS effect on basal promoter activity is separate from its effecton forskolin-induced promoter activity.
Fig. 7. CGS-mediated repression of CT/CGRP enhancer activity. CT/CGRP or TK reporter genes containing the cAMP-responsive region (dottedbox), distal cell-specific enhancer HLH-octamer binding motifs(H/O; solid box), and/or noncell-specific elements (striped box)were transfected into CA77 cells treated with 10 µM CGS for 16hr and then assayed for luciferase activity. CGS responsivenessalso was tested by using reporter genes that contain site-directedmutations in the cell-specific enhancer. Insertion of a BamHIlinker (1160-920+Bam) or a single adenosine residue (H/O+A) eliminatedboth cell-specific enhancer activity and repression by CGS. Thedata in each experiment were normalized to the TK-luciferase reporteractivity in the presence (+) or absence ( $-$ ) of CGS and expressedas the fold change relative to TK-luciferase, the mean for whichwas set at one. The average activities for CGS-treated and untreatedTK-luciferase-transfected cells were 1000 and 2000 light unitsper 20 µg of protein, respectively. The means and SE from at leastthree independent experiments with duplicate samples are shown.
[View Larger Version of this Image (17K GIF file)]

We then mapped the sequences in the region between $-$ 920 and $-$ 1250 bp that were responsible for the CGS repression of basalactivity. The distal enhancer within this region is composed ofboth the cell-specific enhancer and flanking noncell-specificenhancer sequences (Lanigan and Russo, 1997). Reporter plasmidscontaining all of the enhancer sites (from $-$ 1160 to $-$ 960 bp) andcontaining only the cell-specific sites (H/O) were repressed byCGS (Fig. 7). The degree of repression of the distal enhanceris similar to that seen with the 1250 bp reporter, which containsthe enhancer and cAMP-responsive regions. Combined with the relativelack of an effect on the 920 bp reporter, these results demonstratethat the cAMP-responsive region does not contribute to the inhibitionof basal activity. In agreement with this conclusion, reportergenes containing the distal enhancer (from $-$ 1160 to $-$ 920 bp) juxtaposedwith the cAMP-responsive region (from $-$ 280 to +21 bp) showed noadditional repression by CGS, as compared with the 1160 to 920bp TK-luciferase reporter (data not shown). This is in contrastto vitamin D inhibition of CT/CGRP transcription, which requiredboth regions (Peleg et al., 1993). Furthermore, neither the $-$ 1160to $-$ 920 bp nor 18 bp H/O sequences are cAMP-responsive (data notshown). These studies demonstrate that the effectiveness of CGSis mediated via the cell-specific enhancer.

The importance of both sites within the cell-specific enhancer was shown by the loss of CGS-mediated repression on mutationof the H/O enhancer (Fig. 7). CGS did not have an inhibitory effecton the reporter gene containing the $-$ 1160 to $-$ 920 bp fragmentwith an 8 bp BamHI linker inserted into the HLH site (+Bam mutation).Likewise, there was no CGS repression of the 18 bp H/O enhancercontaining a single additional adenosine residue inserted betweenthe HLH and octamer motifs (+A mutation). The +Bam and +A mutationsreduce activity by disrupting the binding of upstream stimulatoryfactor (USF) and OB2, respectively (Lanigan and Russo, 1997).These studies demonstrate that CGS downregulation of the H/O enhancerrequires both the HLH and OB2 factors.

To confirm the cell specificity of CGS repression, we tested the effect of CGS on CGRP enhancer activity in heterologous cells.The H/O enhancer of the CT/CGRP gene previously has been shownto be inactive in HeLa cells, presumably because of the lack ofOB2 protein (Tverberg and Russo, 1993). Because HeLa cells havebeen reported to not express 5-HT₁ receptors, we took advantageof a HeLa line expressing 5-HT_1B receptors (Hamblin et al., 1992).Serotonin treatment of these cells has been reported to inhibitforskolin-stimulated cAMP accumulation in the 5-HT_1B-expressingcells, but not the parental HeLa cells (Hamblin et al., 1992).As mentioned above, we also saw a CGS-induced increase in calciumlevels in the HeLa 5-HT_1B cells. We observed a small (twofold)increase in each of the reporter gene activities after treatmentwith CGS. Hence, when normalized to the TK reporter, CGS had littleor no effect on the H/O enhancer in HeLa cells (Fig. 8). As acontrol, the mutant H/O+A enhancer yielded similar results. Theseresults confirm that CGS repression of the basal enhancer is cell-specific.
Fig. 8. Cell specificity of CGS inhibition of CT/CGRP enhancer activity. TK reporter genes containing the H/O enhancer (solid box)or the H/O+A mutant enhancer were transfected into HeLa cellsexpressing the 5-HT_1B receptor, treated with 10 µM CGS or vehiclefor 16 hr, and then assayed for luciferase activity. The datain each experiment were normalized to the TK-luciferase reporteractivity in the presence (+) or absence ( $-$ ) of CGS and expressedas the fold change relative to TK, the mean for which was setat one. The average activities for CGS-treated and untreated TK-transfectedcells were 3200 and 1600 light units per 20 µg of protein, respectively.The means and SE from three independent experiments with duplicatesamples are shown.
[View Larger Version of this Image (15K GIF file)]

DISCUSSION
To begin to understand the molecular mechanism by which serotonergic antimigraine drugs regulate CGRP levels, we have studiedthe effect of a 5-HT₁ receptor agonist, CGS, on CGRP transcription.We first demonstrated that CGS and sumatriptan markedly increasedintracellular calcium levels in CA77 cells in a manner that issimilar to CGS effects on trigeminal neurons. The pattern andduration of the calcium increase we observed in CA77 cells differfrom those reported for the 5-HT_1B receptor stably expressed ina fibroblast cell line (Zgombick et al., 1993). Furthermore, incontrast to the the coupling in fibroblasts, the coupling we observedin CA77 cells was cAMP-independent and pertussis toxin-insensitive.To our knowledge, this is the first demonstration of 5-HT₁ receptorscoupled to a calcium pathway via pertussis toxin-insensitive G-proteins.Our findings support the possibility of a cell-specific differencefrom the classical role ascribed to this class of receptors (Boessand Martin, 1994). Indeed, cell type-dependent recruitment ofcAMP and calcium pathways has been reported for transfected 5-HT_1Freceptors (Adham et al., 1993). This potential cell specificityemphasizes the importance of CA77 cells and trigeminal neuronshaving similar CGS calcium coupling and CGRP enhancer activityin transgenic mice (Stolarsky-Fredman et al., 1990). Althoughit is certainly possible that additional pathways and/or enhancermechanisms may be recruited in trigeminal neurons that differfrom CA77 cells or other models, these similarities support judicioususe of CA77 cells for CGRP gene expression studies.

Using the CA77 cells as a model, we found that CGS decreased CGRP mRNA levels and promoter activity. The concentration ofCGS required to inhibit promoter activity correlated with theconcentration required for a significant increase in calcium levels.Thus, activation of calcium-dependent pathway(s) is likely tobe involved in inhibition of CGRP transcription. How might thisbe mediated? Elevated calcium levels potentially could activateseveral signaling pathways and target genes (Ghosh and Greenberg,1995). For example, calcium is known to activate CAM-kinases andimmediate early genes, which then can, in turn, regulate neuropeptidegene transcription (MacArthur and Eiden, 1996). Interestingly,tonic neuronal activity, characterized by elevated calcium levels,either can activate or can suppress neuropeptide expression inperipheral neurons, dependent on the neuropeptide, the stimulus,and type of neuron (MacArthur and Eiden, 1996). Recently, Dolmetschet al. (1997) reported that both the duration and amplitude ofthe increase in calcium are critical determinants of gene regulation.Hence, it seems that the prolonged duration of elevated calciummay be an important component of CGS action.

We identified two distinct regulatory regions that are responsible for the inhibitory effect of CGS on CGRP gene transcription,the cAMP-responsive region and the cell-specific enhancer. Becausewe have shown that CGS had little or no inhibitory effect on cyclaseactivity and cAMP levels in CA77 cells, this indicates that CGSmust inhibit the cAMP-responsive region via a cAMP-independentmechanism, presumably involving calcium. Such inhibitory cross-talkbetween calcium and cAMP pathways can occur. Elevated calciumcan inhibit CRE binding protein (CREB) activity by stimulatinga CREB phosphatase (Mulkey et al., 1994; Ginty, 1997) and by causingan inhibitory phosphorylation of CREB (Sun et al., 1994). Theprediction that CGS inhibits a downstream target such as CREBis supported further by our observation that CGS also inhibitedthe stimulatory effect of exogenously added cAMP. Candidate targetproteins for repression by CGS include CREB, ATF-1 (Monia et al.,1995), and a novel factor responsive to activated Ras (Thiagalingamet al., 1996), all of which have been shown to bind the homologouscAMP-responsive region of the human CGRP gene.

The most marked inhibition of CGRP promoter activity was mediated via the 18 bp cell-specific H/O enhancer. This enhanceris controlled by a synergistic interaction between a ubiquitousUSF HLH heterodimer and the cell-specific OB2 protein (Tverbergand Russo, 1993; Lanigan and Russo, 1997). Both of these factorsare required for the inhibitory effect of CGS. In preliminarystudies we have not detected a change in binding activity in electrophoreticmobility shift assays after CGS treatment. This suggests thatCGS is not affecting the levels or binding activity of USF orOB2. Because CGS action appears to be fairly rapid, we predictthat a calcium-activated kinase cascade initiates repression ofthe activity of USF and/or OB2 proteins. Interestingly, the H/Oenhancer also is repressed by dexamethasone and retinoic acid(Tverberg and Russo, 1992; Lanigan et al., 1993). Thus the cell-specificenhancer appears to be a common focal point of several regulatoryagents.

On the basis of these findings, we speculate that antimigraine drugs that bind 5-HT₁ receptors potentially may decrease CGRPsynthesis in trigeminal ganglion neurons. This action is mostlikely occurring in tandem with a rapid inhibition of CGRP secretion,which would account for the fast action of these drugs (~30 min)(Ferrari and Saxena, 1993). Future studies using both trigeminaland CA77 cell cultures should help to uncover the signaling mechanismsand efficacies of serotonergic drugs on CGRP gene expression andpeptide secretion.

FOOTNOTES

Received June 10, 1997; revised Sept. 15, 1997; accepted Sept. 25, 1997.

This work was supported by Grants from the National Institutes of Health (HD25969) and American Heart Association (96013860)to A.R., with tissue culture support provided by the Diabetesand Endocrinology Center (DK25295) and an Iowa CardiovascularInterdisciplinary Research Fellowship (HL07121) to P.D. We thankT. Lanigan and M. Clark for discussions, and D. Segaloff, A. Abel,A. K. Johnson, M. Hamblin, and S. Barcellos for generously providingadvice and reagents.

Correspondence should be addressed to Dr. Andrew F. Russo, Department of Physiology and Biophysics, University of Iowa, IowaCity, IA 52242.

REFERENCES

Adham N, Borden LA, Schechter LE, Gustafson EL, Cochran TL, Vaysse PJ, Weinshank RL, Branchek TA (1993) Cell-specific coupling of the cloned human 5-HT_1F receptor to multiple signal transduction pathways. Naunyn Schmiedebergs Arch Pharmacol 348:566-575[ISI][Medline].
Besnard P, Jousset V, Garel J (1989) Additive effects of dexamethasone and calcium on the calcitonin mRNA level in adrenalectomized rats. FEBS Lett 258:293-296[ISI][Medline].
Boess FG, Martin IL (1994) Molecular biology of 5-HT receptors. Neuropharmacology 33:275-317[ISI][Medline].
Bouchelet I, Cohen Z, Case B, Seguela P, Hamel E (1996) Differential expression of sumatriptan-sensitive 5-hydroxytryptamine receptors in human trigeminal ganglia and cerebral blood vessels. Mol Pharmacol 502:219-223.
Brain SD, Williams TJ, Tippins JR, Morris HR, MacIntyre I (1985) Calcitonin gene-related peptide is a potent vasodilator. Nature 313:54-56[Medline].
Bruinvels AT, Landwehrmeyer B, Moskowitz MA, Hoyer D (1992) Evidence for the presence of 5-HT_1B receptor messenger RNA in neurons of the rat trigeminal ganglia. Eur J Pharmacol 227:357-359[ISI][Medline].
Buzzi MG, Carter WB, Shimizu T, Heath III H, Moskowitz MA (1991) Dihydroergotamine and sumatriptan attenuate levels of CGRP in plasma in rat superior sagittal sinus during electrical stimulation of the trigeminal ganglia. Neuropharmacology 30:1193-1200[ISI][Medline].
Buzzi MG, Bonamini M, Moskowitz MA (1995) Neurogenic model of migraine. Cephalalgia 15:277-280[ISI][Medline].
Clark MS, Lanigan TM, Page NM, Russo AF (1995a) Induction of a serotonergic and neuronal phenotype in thyroid C-cells. J Neurosci 15:6167-6178[Abstract].
Clark MS, Lanigan TM, Russo AF (1995b) Serotonergic neuronal properties in C-cell lines. Methods 7:253-261.
Cote GJ, Gagel RF (1986) Dexamethasone differentially affects the levels of calcitonin and calcitonin gene-related peptide mRNAs as expressed in a human medullary thyroid carcinoma cell line. J Biol Chem 261:15524-15528[Abstract/Free Full Text].
deBustros A, Baylin SB, Levine MA, Nelkin BD (1986) Cyclic AMP and phorbol esters separately induce growth inhibition, calcitonin secretion, and calcitonin gene transcription in cultured human medullary thyroid carcinoma. J Biol Chem 261:8036-8041[Abstract/Free Full Text].
deBustros A, Ball DW, Peters R, Compton D, Nelkin BD (1992) Regulation of human calcitonin gene transcription by cyclic AMP. Biochem Biophys Res Commun 198:1157-1164.
Dolmetsch RE, Lewis RS, Goodnow CC, Healy JI (1997) Differential activation of transcription factors induced by Ca²⁺ response amplitude and duration. Nature 386:855-858[Medline].
Durham PL, Nanthakumar EJ, Snyder JM (1992) Developmental regulation of surfactant-associated proteins in rabbit fetal lung in vivo. Exp Lung Res 18:775-793[ISI][Medline].
Edvinsson L, Goadsby PJ (1994) Neuropeptides in migraine and cluster headache. Cephalalgia 14:320-327[ISI][Medline].
Ferrari MD, Saxena PR (1993) On serotonin and migraine: a clinical and pharmacological review. Cephalalgia 13:151-165[ISI][Medline].
Ghosh A, Greenberg MA (1995) Calcium signaling in neurons: molecular mechanisms and cellular consequences. Science 268:239-247[Abstract/Free Full Text].
Ginty DD (1997) Calcium regulation of gene expression: isn't that spatial? Neuron 18:183-186[ISI][Medline].
Goadsby PJ, Edvinsson L (1993) The trigeminovascular system and migraine: studies characterizing cerebrovascular and neuropeptide changes seen in humans and cats. Ann Neurol 33:48-56[ISI][Medline].
Goadsby PJ, Edvinsson L (1994) Human in vivo evidence for trigeminovascular activation in cluster headache. Neuropeptide changes and effects of acute attacks therapies. Brain 117:427-434[Abstract/Free Full Text].
Goadsby PJ, Edvinsson L, Ekman R (1988) Release of vasoactive peptides in the extracerebral circulation of humans and the cat during activation of the trigeminovascular system. Ann Neurol 23:193-196[ISI][Medline].
Hamblin MW, Metcalf MA, McGuffin RW, Karpells S (1992) Molecular cloning and functional characterization of a human 5-HT_1B serotonin receptor: a homologue of the rat 5-HT_1B receptor with 5-HT_1D-like pharmacological specificity. Biochem Biophys Res Commun 184:752-759[ISI][Medline].
Jacobs J, Simpson WE, Penschow J, Hudson P, Coghlan J, Niall H (1983) Characterization and localization of calcitonin messenger ribonucleic acid in rat thyroid. Endocrinology 113:1616-1622[Abstract].
Jaquette J, Segaloff DL (1997) Temperature sensitivity of some mutants of the lutropin/choriogonadotropin receptor. Endocrinology 138:85-91[Abstract/Free Full Text].
Kennet GA, Wood MD, Bright F, Cilia J, Piper DC, Gager T, Thomas D, Baxter GS, Forbes IT, Ham P, Blackburn TP (1996) In vitro and in vivo profile of SB 206553, a potent 5-HT_2C/5-HT_2B receptor antagonist with anxiolytic-like properties. Br J Pharmacol 117:427-434[ISI][Medline].
Lanigan T, Russo AF (1997) Binding of upstream stimulatory factor and a cell-specific activator to the calcitonin/calcitonin gene-related peptide enhancer. J Biol Chem 272:18316-18324[Abstract/Free Full Text].
Lanigan TM, Tverberg LA, Russo AF (1993) Retinoic acid repression of cell-specific helix-loop-helix-octamer activation of the calcitonin/calcitonin gene-related peptide enhancer. Mol Cell Biol 13:6079-6088[Abstract/Free Full Text].
MacArthur L, Eiden L (1996) Neuropeptide genes: targets of activity-dependent signal transduction. Peptides 17:721-728[ISI][Medline].
McCulloch J, Uddman R, Kingman TA, Edvinsson L (1986) Calcitonin gene-related peptide: functional role in cerebrovascular regulation. Proc Natl Acad Sci USA 83:5731-5735[Abstract/Free Full Text].
Monia YT, Peleg S, Gagel RF (1995) Cell type-specific regulation of transcription by cyclic adenosine 3 $'$ ,5 $'$ -monophosphate-responsive elements within the calcitonin promoter. Mol Endocrinol 9:784-793[Abstract].
Mulkey RM, Endo S, Shenolikar S, Malenka RC (1994) Involvement of a calcineurin/inhibitor-1 phosphatase cascade in hippocampal long-term depression. Nature 369:486-489[Medline].
Neale RF, Fallon SL, Boyar WC, Wasley JWF, Martin LL, Stone GA, Glaeser BS, Sinton CM, Williams M (1987) Biochemical and pharmacological characterization of CGS 12066B, a selective serotonin-1B agonist. Eur J Pharmacol 136:1-9[ISI][Medline].
O'Conner TP, Van der Kooy D (1988) Enrichment of vasoactive neuropeptide calcitonin gene-related peptide in the trigeminal sensory projections to the intracranial arteries. J Neurosci 8:2468-2476[Abstract].
Peleg S, Abruzzese RV, Cooper CW, Gagel RF (1993) Down-regulation of calcitonin gene transcription by vitamin D requires two widely separated enhancer sequences. Mol Endocrinol 7:999-1008[Abstract].
Rebeck GW, Maynard KI, Hyman BT, Moskowitz MA (1994) Selective 5-HT_1D serotonin receptor gene expression in trigeminal ganglia: implications for antimigraine drug development. Proc Natl Acad Sci USA 91:3666-3669[Abstract/Free Full Text].
Rosenfeld MG, Mermod JJ, Amara SG, Swanson LW, Sawchenko PE, Rivier J, Vale WW, Evans RM (1983) Production of a novel neuropeptide encoded by the calcitonin gene via tissue-specific RNA processing. Nature 304:129-135[Medline].
Russo AF, Lanigan TM (1996) Neuronal properties of thyroid C-cell tumor lines. In: Genetic mechanisms in multiple endocrine neoplasia type 2 (Nelkin BD, ed), pp 137-162. New York: Chapman and Hall.
Russo AF, Clark MS, Durham PL (1996) Thyroid parafollicular cells: an accessible model for the study of serotonergic neurons. Mol Neurobiol 13:257-276[ISI][Medline].
Salomon Y (1979) Adenylate cyclase assay. In: Advances in cyclic nucleotide research (Brooker G, Greengard P, Robinson GA, eds), pp 35-55. New York: Raven.
Sharma RV, Chapleau MW, Hajduczok G, Wachtel RE, Waite LJ, Bhalla RC, Abboud FM (1995) Mechanical stimulation increases intracellular calcium concentration in nodose sensory neurons. Neuroscience 66:433-441[ISI][Medline].
Stolarsky-Fredman L, Leff SE, Klein ES, Crenshaw III EB, Yeakley J, Rosenfeld MG (1990) A tissue-specific enhancer in the rat-calcitonin/CGRP gene is active in both neuronal and endocrine cell types. Mol Endocrinol 4:497-504[Abstract].
Sun P, Enslen H, Myung PS, Maurer RA (1994) Differential activation of CREB by Ca²⁺/calmodulin-dependent protein kinases type II and type IV involves phosphorylation of a site that negatively regulates activity. Genes Dev 8:2527-2539[Abstract/Free Full Text].
Thiagalingam A, deBustros A, Borges M, Jasti R, Compton D, Diamond L, Mabry M, Ball DW, Baylin SB, Nelkin BD (1996) RREB-1, a novel zinc finger protein, is involved in the differentiation response to ras in human medullary thyroid carcinomas. Mol Cell Biol 16:5335-5345[Abstract].
Tverberg LA, Russo AF (1992) Cell-specific glucocorticoid repression of calcitonin/calcitonin gene-related peptide transcription. J Biol Chem 267:17567-17573[Abstract/Free Full Text].
Tverberg LA, Russo AF (1993) Regulation of the calcitonin/calcitonin gene-related peptide gene by cell-specific synergy between helix-loop-helix and octamer-binding transcription factors. J Biol Chem 268:15965-15973[Abstract/Free Full Text].
Unsworth D, Molinoff PB (1992) Regulation of the 5-hydroxytryptamine_1B receptor in opossum kidney cells after exposure to agonists. Mol Pharmacol 42:464-470[Abstract].
Vedder H, Otten U (1991) Biosynthesis and release of tachykinins from rat sensory neurons in culture. J Neurosci Res 30:288-299[ISI][Medline].
Zeytin FN, Rusk S, Leff SE (1987) Calcium, dexamethasone, and the antiglucocorticoid RU-486 differentially regulate neuropeptide synthesis in a rat C-cell line. Endocrinology 121:361-370[Abstract].
Zgombick JM, Borden LA, Cochran TL, Kucharewicz SA, Weinshank RL, Branchek TA (1993) Dual coupling of cloned human 5-hydroxytryptamine_1D and 5-hydroxytryptamine_1D receptors stably expressed in murine fibroblasts: inhibition of adenylate cyclase and elevation of intracellular calcium concentrations via pertussis toxin-sensitive G-proteins. Mol Pharmacol 44:575-582[Abstract].

Copyright ©1997 Society for Neuroscience   0270-6474/1997/179545-09$05.00/0

This article has been cited by other articles:

J. L. Steiger, S. Bandyopadhyay, D. H. Farb, and S. J. Russek
cAMP Response Element-Binding Protein, Activating Transcription Factor-4, and Upstream Stimulatory Factor Differentially Control Hippocampal GABABR1a and GABABR1b Subunit Gene Expression through Alternative Promoters
J. Neurosci., July 7, 2004; 24(27): 6115 - 6126.
[Abstract] [Full Text] [PDF]

W. G. Chen, A. E. West, X. Tao, G. Corfas, M. N. Szentirmay, M. Sawadogo, C. Vinson, and M. E. Greenberg
Upstream Stimulatory Factors Are Mediators of Ca2+-Responsive Transcription in Neurons
J. Neurosci., April 1, 2003; 23(7): 2572 - 2581.
[Abstract] [Full Text] [PDF]

P. L. Durham and A. F. Russo
Stimulation of the Calcitonin Gene-Related Peptide Enhancer by Mitogen-Activated Protein Kinases and Repression by an Antimigraine Drug in Trigeminal Ganglia Neurons
J. Neurosci., February 1, 2003; 23(3): 807 - 815.
[Abstract] [Full Text] [PDF]

P. L. Durham and A. F. Russo
Differential Regulation of Mitogen-Activated Protein Kinase-Responsive Genes by the Duration of a Calcium Signal
Mol. Endocrinol., October 1, 2000; 14(10): 1570 - 1582.
[Abstract] [Full Text]