Effects of Antisense to the {alpha}2A-Adrenoceptors Administered into the Region of the Locus Ceruleus on Behaviors in Plus-Maze and Sexual Behavior Tests in Sham-Operated and Castrated Male Rats

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 Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via Web of Science (14)

Citing Articles via Google Scholar

Google Scholar

Articles by Shishkina, G. T.

Articles by Dygalo, N. N.

Search for Related Content

PubMed

PubMed Citation

Articles by Shishkina, G. T.

Articles by Dygalo, N. N.

Previous Article  |  Next Article

The Journal of Neuroscience, January 15, 2001, 21(2):726-731

Effects of Antisense to the $alpha$ 2A-Adrenoceptors Administered into the Region of the Locus Ceruleus on Behaviors in Plus-Maze and Sexual Behavior Tests in Sham-Operated and Castrated Male Rats
Galina T. Shishkina, Tatjana S. Kalinina, Natalja Yu. Sournina, and Nikolai N. Dygalo
Institute of Cytology and Genetics, Russian Academy of Sciences, Novosibirsk 630090, Russia

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Clinical and experimental findings have implicated brain $alpha$ 2-adrenoceptors in the regulation of many physiological functions,including sexual activity and stress-related behavior. However,which subtypes of the three $alpha$ 2-adrenoceptors that have now beencloned ( $alpha$ 2A, $alpha$ 2B, and $alpha$ 2C) are involved in these controls haveyet to be established. Here, we investigated the contributionof $alpha$ 2A-adrenoceptors of the locus ceruleus, the principal sourceof brain noradrenaline, to exploratory and sexual behaviors. Usingadministration of antisense oligodeoxynucleotide to inhibit thereceptor expression, we found that reductions in brainstem $alpha$ 2A-adrenoceptormRNA levels and $alpha$ 2-adrenoceptor densities induced by antisensetreatment were not accompanied by any changes in the major characteristicsof male sexual activity, such as mount latencies and numbers ofmounts. However, in sexual behavior tests, antisense-treated malerats had decreased numbers of rearings and thus have higher percentagesof behaviors positively correlated with sexual activity. Besides,antisense-treated animals had decreased anxiety in plus-maze tests.The data demonstrate that inhibition of $alpha$ 2A-adrenoceptor expressionin the region of the locus ceruleus has an anxiolytic-like effectand facilitates male's attention to female in sexual behaviortest.

Key words: $alpha$ 2A-adrenoceptors; locus ceruleus; anxiety; male sexual behavior; antisense oligodeoxynucleotide; mRNA

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Pharmacological studies have implicated brain $alpha$ 2-adrenoceptors in the regulation of male sexual behavior (for review, seeBancroft, 1995; Rampin, 1999). Administration of the receptoragonists have been shown to inhibit copulatory activity in malerats (Clark et al., 1985a; Clark, 1991; Benelli et al., 1993),whereas the receptor antagonists enhance their sexual motivation(Clark and Smith, 1984; Clark et al., 1985a,b; Smith et al., 1987;Peters et al., 1988; Sala et al., 1990; Koskinen et al., 1991;Benelli et al., 1993; Tallentire et al., 1996; Spedding et al.,1998). $alpha$ 2-Adrenoceptors have been subdivided into three distinctsubtypes: $alpha$ 2A, $alpha$ 2B, and $alpha$ 2C (Bylund et al., 1994). However, whichsubtypes of the receptors are involved in the control of malesexual behavior have yet to beestablished.

It has been reported that systemic administration of $alpha$ 2-adrenoceptor antagonists that facilitate sexual behavior are accompaniedby an increased noradrenergic transmission in brain regions thatreceive noradrenergic innervation (Dennis et al., 1987; Szemerediet al., 1991; Gobert et al., 1997). A majority of noradrenergicneurons are located in the locus ceruleus that project to thecortex and to most subcortical areas. Autoreceptor control ofnoradrenaline release in the locus ceruleus is mediated by $alpha$ 2A-adrenoceptors(Callado and Stamford, 1999). In the present study, the involvementof the $alpha$ 2A-adrenoceptors of the locus ceruleus in the regulationof male sexual behavior was explored. For this, we examined possiblealterations in sexual behavior in sham-operated and castratedmale rats after injections of an antisense oligodeoxynucleotidecomplementary to the $alpha$ 2A-adrenoceptor mRNA into the region ofthe locus ceruleus. In addition to sexual behavior, anxiety ofthe animals in the elevated plus-maze test was evaluated afteradministration of this antisense because the changes in locusceruleus noradrenergic function appear to influence anxious behavior(Bremner et al., 1996a,b). We also measured the levels of $alpha$ 2A-adrenoceptormRNA, binding of $alpha$ 2- and $beta$ -adrenoceptors, and concentrations ofnoradrenaline and dopamine in the brain to estimate the specificityof antisense effect on the expression of $alpha$ 2A-adrenoceptors.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals and experimental procedures. Adult male Wistar rats (225-240 gm) were housed under conditions of natural illuminationwith food and water available ad libitum. All animal use proceduresconformed to international European ethical standards (86/609-EEC)and the Russian national instructions for the care and use oflaboratory animals. Animals were either bilaterally castratedor underwent a sham operation under etheranesthesia.

Twenty-four days after the surgery, a steel cannula was implanted in the vicinity of the locus ceruleus (9.5 mm caudal tobregma and 5.9 mm below the skull) under Nembutal anesthesia (40mg/kg, i.p.). Both sham-operated and castrated groups were thensubdivided into three subgroups (each subgroup consisted of sixanimals). Four days after insertion of the cannula, rats of thefirst subgroups were injected three times continuously for 3 dwith 1 nmol with 5µl per day antisense phosphorotioate oligodeoxynucleotideto $alpha$ 2A-adrenoceptor mRNA. The antisense was targeted to the areathat bridges the initiation codon (from $-$ 11 to + 7, 5'-agcccatgggcgcaaagc-3').Animals of the two control subgroups received infusions of a phosphorotioate-modifiedoligodeoxynucleotide containing the same nucleotides as antisense,but in random sequence (5'-gacgacccagtgagcacg-3'), or saline.The sequences of antisense and random have relatively low homologywith any of the other known mammalian sequences found in the GenBankdatabase.

Behavioral tests were conducted on days 2 and 3 of the infusion. All animals were decapitated 24 hr after the last injection.Frontal cortex, hippocampus, and brainstem were rapidly dissectedout on a cooled plate and frozen in liquid nitrogen. Frontal cortexsample included tissue sections of 1.5-mm-thick cut from the uppersurface of the frontal half of the hemispheres. Brainstem sampleincluded pons and medulla oblongata. The levels of $alpha$ 2A-adrenoceptormRNA (reverse transcription-PCR), numbers of $alpha$ 2- and $beta$ -adrenoceptors(radioligand binding of ³H-clonidine and ³H-dihydroalprenolol), and contents of noradrenaline and dopaminewere determined in theseregions.

Elevated plus-maze tests. Animals were tested on the elevated plus-maze tests 6 hr after the second injections of drugs between3:00 P.M. and 4:00 P.M. At the start of the test, rats were placedindividually on the center square facing an open arm. During the5 min test period, the number of entries into both open and closedarms separately and number of rearings wererecorded.

Male sexual behavior tests. Sexual behavior tests were conducted 2 hr after the onset of darkness on day 3 of the injections.A receptive female was presented to the male for 20 min. The followingmeasurements were taken: (1) mount latency; (2) number of mounts;(3) number of rearings; (4) number of genital sniffings; (5) numberof groomings; and (6) percent of behaviors positively correlatedwith sexual activity, which was calculated by expressing suchbehaviors (i.e., number of mounts plus number of groomings) asa percent of the total of scored behaviors (number of mounts plusnumber of groomings plus number of rearings plus number of genitalsniffings).

Analysis of $alpha$ 2A-adrenoceptor mRNA. Total cellular mRNA (2 µm) from the brainstem was isolated by a single step acid guanidinium-phenol-chloroformextraction method (Chomczynski and Sacchi, 1987). Two microgramsof total mRNA were used as template for the first-strand cDNAsynthesis in 20 µl reaction volume containing 67 mM Tris-HCl,pH 8.8, 17 mM KCl, 1 mM MnCl₂, and 1 mM each of dNTP, 100 ng ofoligo-dT primer, 2.5% glycerol, and 5 U of TET-z DNA polymerase,which has reverse transcriptase activity in abundance of Mn²⁺. Reaction temperatures were 25°C for 10 min for annealing ofprimer, and 42°C for 1 hr for extension of primers. After that,5 µl of reaction mixture was increased to 50 µl with 45 µl ofPCR mix (67 mM Tris-HCl, pH 8.0, 2.5 mM MnCl₂, 0.01 M 2-mercaptoethanol,0.01% Tween 20, 0.2 mM of forward and reverse for $alpha$ 2A-adrenoceptoror $beta$ -actin PCR primers, and 2.5 U of Tag polymerase). Oligonucleotideprimers were designed from sequences of cytoplasmic $beta$ -actin and $alpha$ 2A-adrenoceptor, which are presented in the GenBank database.Oligonucleotides for $alpha$ 2A-adrenoceptor forward primer sequencewere 5'-tgcgagatcaacgaccagaag-3' and reverse-5'-cacgaacgtgaagcgcttctc-3'.The expected size of the amplified fragment was 564 bp. For $beta$ -actin,primers were 5'-tccctcatgccatcctgcgt-3' and 5'-ggaacctctcattgccgata-3'to produce a 255 bp fragment. Amplifications were performed ina programmable thermal cycler with an initial template denaturationat 95°C for 3 min, annealing at 52°C for 1.5 min, and extensionof primers for 2 min at 70°C. This first cycle was followed by40 amplification cycles of denaturation at 95°C for 0.8 min, annealingat 52°C for 0.8 min, and extension at 70°C for 1 min. The finalcycle lasted 10 min at 70°C. In all experiments, the presenceof possible contaminants was checked by control reaction in whichamplification was performed on samples in which reverse transcriptasewas omitted from the reverse transcription reaction mixture. Theamplification products were separated on ethidium bromide-stained1.5% agarose gel. Gene expression level of $alpha$ 2A-adrenoceptors wasquantified relatively to $beta$ -actin by scanning densitometer (BiodocII video documentation system; Biometra GmbH, Gottingen,Germany).

Analysis of $alpha$ 2- and $beta$ -adrenoceptor binding sites. Brain tissues were homogenized in 20 vol of ice-cold 50 mM Tris-HCl buffer,pH 7.7, and centrifuged at 20,000 × g for 15 min. The pelletswere rehomogenized in another portion of the buffer and then centrifugedagain. The final pellets were resuspended in 140 vol of the samebuffer. ³H-Clonidine (3.2 nM; 23.2 Ci/mmol), imidazoline with $alpha$ 2-adrenoceptoragonist specificity, or 1.6 nM ³H-dihydroalprenolol (³H-DHA) (75 Ci/mmol), the $beta$ -adrenoceptor antagonist, were addedto 0.8 ml of membrane suspensions, and the samples in final volumesof 1 ml were incubated: for ³H-clonidine binding, 30 min at 25°C in the absence (total binding)or presence (nonspecific binding) of 100 µM noradrenaline (Koch-Light,Haverhill, UK); for ³H-DHA binding, 20 min at 23°C with or without 10 µM propranolol(Sigma, Poole, UK). The reactions were terminated by rapid filtrationunder a vacuum through glass fiber filters (GF/B; Whatman, Maidstone,UK). Filters were immediately washed three times with 5 ml ofice-cold buffer, and radioactivity was measured in a Delta-300liquid scintillation counter. Specific binding was determinedby subtracting nonspecific binding from total binding and expressedas femtomoles of radioligand bound per milligram of protein (Shishkinaand Naumenko, 1995). Determination of protein was performed bythe method of Lowry et al. (1951).

Neurochemical assays. The concentrations of noradrenaline and dopamine were determined fluorimetrically (Jacobowitz and Richardson,1978).

Statistics. Data were analyzed by using two-way ANOVA for effect of castration and treatment. One-way ANOVA was used for treatmenteffect within each sham-operated or castrated group. Significantdifferences were identified by Tukey's post hoc ttest.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Elevated plus maze

Castration of male rats significantly elevated the numbers of open-arm entries compared with that in sham-operated animals(F_(1,30) = 18.150; p < 0.001) (Fig. 1). Treatment of the ratswith antisense to $alpha$ 2A-adrenoceptors increased the numbers of open-armentries compared with random and saline controls (F_(2,30) = 12.008;p < 0.001). The effect of treatment was significant for both sham-operated(F_(2,15) = 8.903; p < 0.01) and castrated (F_(2,15) = 5.572; p< 0.05) rats.

View larger version (24K):
[in this window]
[in a new window]
Figure 1. Numbers of entries in the open arms of the plus maze (A), total arm entries (B), and rearings (C) made by sham-operated (SHAM) and castrated (CASTR) males after injections of antisense oligodeoxynucleotide to the $alpha$ 2A-adrenoceptors, oligodeoxynucleotide of a random sequence, or saline into the region of the locus ceruleus. *p < 0.05 versus saline and random.

There were no significant differences among groups in total number of arm entries (castration, F_(1,30) = 2.148, NS; treatment,F_(2,30) = 0.393, NS) (Fig. 1).

Numbers of rearings (Fig. 1) were significantly elevated with castration (F_(1,30) = 4.489; p < 0.05). Antisense treatmenthad no effect on the numbers of rearings in these tests (F_(2,30)= 1.608,NS).

Male sexual behavior tests

Castration of male rats produced a suppression of copulatory behavior as evidenced by drastic increases in mount latencies(F_(1,30) = 19.736; p < 0.001) and decreases in numbers of mounts(F_(1,30) = 21.357; p < 0.001) (Fig. 2). Antisense treatment didnot affect the mount latencies (F_(2,30) = 0.890, NS) or numbersof mounts (F_(2,30) = 0.154, NS). Although antisense-treated castratedmales had shorter mount latencies and greater numbers of mountsthan did the control castrated males, none of the differencesreached statistical significance.

View larger version (31K):
[in this window]
[in a new window]
Figure 2. Mount latencies (A), numbers of mounts (B), rearings (C), and percent of behaviors positively correlated with male sexual activity (number of mounts plus number of groomings) (D) shown by sham-operated (SHAM) and castrated (CASTR) males after injections of antisense oligodeoxynucleotide to the $alpha$ 2A-adrenoceptors, oligodeoxynucleotide of a random sequence, or saline into the region of the locus ceruleus. *p < 0.05 versus saline and random.

Castration of animals significantly increase the number of rearings (F_(1,30) = 10.968; p < 0.01) (Fig. 2) and genital sniffings(F_(1,30) = 7.134; p < 0.001) (data not shown) in sexual behaviortests. Administration of antisense significantly reduced bothrearing (F_(2,30) = 10. 416; p < 0.001) and sniffing (F_(2,30) =3.43; p < 0.05) numbers. Numbers of groomings that were significantlyreduced after castration (F_(1,30) = 19.833; p < 0.001) were notinfluenced by antisense treatment (F_(2,30) = 0.062, NS) (datanotshown).

The percent of the behaviors positively correlated with sexual activity (number of mounts plus number of groomings) were higherin sham-operated animals than in castrated males (F_(1,30) = 28.100;p < 0.001) (Fig. 2). There were marginal elevations in the percentagesof these behaviors after antisense treatment (F_(2,30) = 3.208;p < 0.06). The elevation reached significance in castrated rats(F_(2,15) = 3.770; p < 0.05).

Expression of $alpha$ 2A-adrenoceptors in the brainstem

The levels of $alpha$ 2A-adrenoceptor mRNA in the brainstem (Fig. 3) were increased by castration (F_(1,12) = 8.001; p < 0.05) anddecreased by administration of antisense into the region of locusceruleus (F_(2,12) = 17.301; p < 0.001).

View larger version (40K):
[in this window]
[in a new window]
Figure 3. Levels of $alpha$ 2A-adrenoceptor mRNA (A) and ³H-clonidine binding (B) in the brainstem of sham-operated (SHAM) and castrated (CASTR) males after injections of antisense oligodeoxynucleotide to the $alpha$ 2A-adrenoceptors, oligodeoxynucleotide of a random sequence, or saline into the region of the locus ceruleus. *p < 0.01 versus saline and random.

The densities of brainstem $alpha$ 2-adrenoceptors (Fig. 3), assessed by ³H-clonidine binding, were not changed in castrated males (F_(1,30)= 0.036, NS). Marginally significant decreases in ³H-clonidine binding were found in this brain region after antisensetreatment (F_(2,30) = 3.075; p < 0.07).

³H-clonidine binding in the frontal cortex and hippocampus

The densities of ³H-clonidine binding sites in the frontal cortex were significantly increased after castration (F_(1,30) =5.471; p < 0.05) (Fig. 4). Administration of antisense into theregion of the locus ceruleus did not affect the densities of bindingsites in the frontal cortex (F_(2,30) = 0.760, NS).

View larger version (42K):
[in this window]
[in a new window]
Figure 4. Binding of ³H-clonidine in the frontal cortex (A) and hippocampus (B) of sham-operated (SHAM) and castrated (CASTR) males after injections of antisense oligodeoxynucleotide to the $alpha$ 2A-adrenoceptors, oligodeoxynucleotide of a random sequence, or saline into the region of the locus ceruleus. *p < 0.05 versus saline and random.

In the hippocampus (Fig. 4), castration did not modify specific ³H-clonidine binding (F_(1,30) = 0.042, NS). Treatment with antisenseinduced a significant reduction in the binding site densitiesin this brain region (F_(2,30) = 6.575; p < 0.01).

Concentrations of noradrenaline and dopamine, and ³H-DHA binding in the frontal cortex

No significant changes were found in the concentrations of noradrenaline in the frontal cortex of rats after castration (F_(1,30)= 1.519, NS). Antisense treatment caused a significant decreasein cortical noradrenaline concentrations (F_(2,30) = 5.679; p <0.01) (Fig. 5).

View larger version (42K):
[in this window]
[in a new window]
Figure 5. Cortical noradrenaline (A) and ³H-DHA binding (B) in sham-operated (SHAM) and castrated (CASTR) males after injections of antisense oligodeoxynucleotide to the $alpha$ 2A-adrenoceptors, oligodeoxynucleotide of a random sequence, or saline into the region of the locus ceruleus. *p < 0.05 versus random.

There was no effect of castration (F_(1,30) = 0.018, NS) or antisense treatment (F_(2,30) = 0.028, NS) on the concentrationsof dopamine in the frontal cortex (data notshown).

A marginally significant elevation in the binding of ³H-DHA to cortical $beta$ -adrenoceptors (Fig. 5) was seen for the castratedanimals (F_(1,30) = 3.293; p < 0.08). Antisense treatment led toa marginally significant reduction in ³H-DHA binding in the frontal cortex (F_(2,30) = 3.225; p < 0.06).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The present results showed that administration of antisense to $alpha$ 2A-adrenoceptors into the region of locus ceruleus decreasedthe level of $alpha$ 2A-adrenoceptor mRNA and the number of $alpha$ 2-adrenoceptorsin the brainstem. However, the reduction of the receptor densitywas only marginal, whereas that of mRNA level was highly significant.One possible reason for this difference is the ability of ³H-clonidine to label nonadrenoceptor imidazoline binding sites,in addition to $alpha$ 2-adrenoceptors (Ernsberger et al., 1987). A similar20-30% decrement in binding site densities in brain regions closeto the side of the intracerebroventricular infusion of antisenseto $alpha$ 2D-adrenoceptors has been reported by Robinson et al. (1999)with the other non-subtype selective radioligand ³H-RX821002.

Treatment with antisense caused reduction in expression of brainstem $alpha$ 2-adrenoceptors in both sham-operated and castratedrats. However, castration itself affected the receptor expressionin brain regions. The levels of $alpha$ 2-adrenoceptor mRNA in the brainstemand the densities of $alpha$ 2-adrenoceptors in the frontal cortex wereincreased in castrated animals 4 weeks after the operation comparedwith sham-operated males. This is consistent with the previouslypublished report that demonstrated increases in ³H-clonidine binding in the cortex 2 and 3 weeks after castration(Shishkina et al., 1997). Although the castrated group startedout with a higher level of $alpha$ 2A-adrenoceptor mRNA, antisense treatmentlowered it to the same level as the sham-operated antisense-treatedanimals. Effects of antisense on behavioral assessments in sexualbehavioral tests were also more pronounced in castratedrats.

Male sexual behavior depends on testicular hormones (Damassa et al., 1977; Clark et al., 1988; Shishkina et al., 1993). Resultsfrom the present and previous studies indicate that $alpha$ 2-adrenoceptorsappear to be sensitive to their regulatory influences (Shishkinaand Naumenko, 1995; Shishkina et al., 1997). These observationssuggest that the stimulatory effects of testosterone on sexualbehavior may be attributable to alterations in brain $alpha$ 2-adrenoceptordensity. Moreover, ability of the $alpha$ 2-adrenoceptor antagonist yohimbineto facilitate sexual activity in long-term castrated male ratsindicate that the $alpha$ 2-adrenergic regulation of sexual behavioris downstream from the effect of testosterone (Clark et al., 1985b).

The locus ceruleus noradrenergic cell group is involved in the formation of the arousal system (Marrocco et al., 1994). However, $alpha$ 2A-adrenoceptors of the locus ceruleus are not important in thecontrol of sexual arousal. Reduction of the $alpha$ 2A-adrenoceptor expressioninduced by antisense treatment was not accompanied by changesin major characteristics of male sexual activity, such as mountlatency and number of mounts. Thus, it seems likely that stimulatoryeffects of systemic injection of $alpha$ 2-adrenoceptor antagonists onmale sexual behavior (Clark et al., 1984, 1985a,b; Smith et al.,1987; Peters et al., 1988; Sala et al., 1990; Koskinen et al.,1991; Benelli et al., 1993; Tallentire et al., 1996; Speddinget al., 1998) occur via other brain regions. For example, Clark(1991) has reported that administration of yohimbine into themedial preoptic area attenuated the inhibitory effect of systemicallyadministered clonidine on sexual activity. At the same time, becausein sexual behavior tests genital sniffing in castrated males andrearing in rats of both sham-operated and castrated groups weredeclined after antisense treatment, percent of behaviors positivelycorrelated with sexual activity (number of mounts plus numberof groomings) was increased in these animals. It is importantto note that the inhibitory effect of antisense on rearing isspecific for the sexual behavior test because, in the other behavioraltest, the plus maze, number of rearings did not differ betweencontrol and antisense-treated rats. Together, these findings suggestthat antisense treatment resulted in a facilitatory effect onmale's attention to female but, in general, did not affect copulatorybehavior inmales.

Antisense administration also modified the function of the noradrenergic system in the target brain regions of the locus ceruleus,such as the frontal cortex and hippocampus. Thus, a significantfall in $alpha$ 2-adrenoceptor densities in the hippocampus was observedafter the treatment. This is consistent with the finding thatthe majority of hippocampal $alpha$ 2A-adrenoceptors appear to be associatedwith fine axons and presynaptically located (Milner et al., 1998).In contrast to the hippocampus, we did not observe any effectof antisense on the $alpha$ 2-adrenoceptor densities in the frontal cortex.The presence of relatively large number of $alpha$ 2-adrenoceptors locatedpostsynaptically and on noncatecholaminergic terminals (Heal etal., 1993; Aoki et al., 1994; Venkatesan et al., 1996) could maskthe possible effect of antisense on cortical receptors, whichare imported into this region from the brainstem. In the frontalcortex, concentrations of noradrenaline were decreased in antisense-treatedanimals. This effect can be explained by an enhancement in neuronalfiring and release of neurotransmitter. Such a possibility issupported by the finding that infusion of preferential $alpha$ 2A-adrenoceptorantagonist into the locus ceruleus enhanced release of noradrenalinein the cortex (Mateo and Meana, 1999). Because long-term exposureto agonist can change the expression of different adrenoceptors,the tendency for the decrease in cortical $beta$ -adrenoceptor densityafter antisense treatment may reflect downregulation of this receptorpopulation by continued noradrenaline stimulation (Hosoda et al.,1994, 1995).

Of the brain regions that have been investigated, noradrenergic neurotransmission or $alpha$ 2A-autoreceptors in the frontal cortexmay be involved in regulating behaviors in sexual tests by alteringthe male's reactivity to female stimuli. Thus, adrenergic pathwaysinnervating the cortex play a role in cognito-attentional processes(Marrocco et al., 1994), and it has been shown that male ratswith lesions of the cerebral cortex near the midline in the frontalregion had very long mount latencies (Agmo and Villalpando, 1995).The involvement of cortical $alpha$ 2-adrenoceptors in sexual behavioris also supported by changes in their expression after castrationand copulation (Rago et al., 1992).

The results obtained with the plus maze showed anxiolytic-like effects of long-term castration and antisense administration.Effect of castration may be attributable to the decreased levelof testosterone. Thus, it was shown that adult male rats madea lower percentage of entries in the open arms than females. Besides,newborn castration led to an adult male behavioral pattern thatresembles that of the female (Lucion et al., 1996). A hypothesisto explain the anxiolytic effect of antisense may be an increaseof noradrenergic neurons firing and elevation of synaptic noradrenalinerelease. This hypothesis is supported by studies showing a decreasein anxiety-related behavior after direct stimulation of the locusceruleus (Weiss et al., 1994). This is also consistent with thefinding that noradrenergic neuronal integrity is required forthe anxiolytic-like effects of chronic antidepressant treatment(Fontana et al., 1999). However, we have no comparable data pointingto the $alpha$ 2A-adrenoceptor mechanism whereby novelty leads to anxiety.Pharmacological results reported with $alpha$ 2-adrenoceptor antagonistsare quite inconsistent. They span the full range of effects fromanxiogenesis (Handley and Mithani, 1984) to anxiolysis (La Marcaand Dunn, 1994; Cole et al., 1995). This is discussed in relationto the well known action of the used antagonists on monoaminergicreceptors other than $alpha$ 2-adrenoceptors. Nevertheless, our resultsare consistent with the view that agents with selective antagonismat the $alpha$ 2-adrenoceptor may be anxiolytic, whereas agents withless specificity at this adrenoceptors are not anxiolytic (LaMarca and Dunn, 1994; Cole et al., 1995). The divergence in theantagonist effects may be also attributable to the multiplicityof $alpha$ 2-adrenoceptor subtypes and the lack of subtype-specific ligands.The present study provides evidence that specific reduction ofthe $alpha$ 2A-adrenoceptors in the brainstem exerts anxiolytic-likeeffects in sham-operated and castrated malerats.

Together, the results of the present study could be also interpreted as that administration of antisense against $alpha$ 2A-adrenoceptorsinto the region of the locus ceruleus caused anxiolytic-like effect,resulting in an increase in male's attention to the female inthe sexual behavior test. This interpretation is supported bythe finding that the anxiogenic agent RS-30199 has been shownto fully inhibit the facilitation of male sexual behavior in ratscaused by the $alpha$ 2-adrenoceptor antagonist delequamine (Speddinget al., 1998). Moreover, Rowland et al. (1997) found no effectof yohimbine on most aspects of sexual response in sexually functionalmen. Facilitation of sexual activity under yohimbine in men witherectile problems has been suggested to relate with yohimbic effectson psychological factors that modulate overall sexual responserather than a more selective activation of erectileresponse.

In conclusion, we have shown that inhibition of $alpha$ 2A-adrenoceptor expression in the region of the locus ceruleus has an anxiolytic-likeeffect and facilitates male's attention to female in sexual behaviortest.

  FOOTNOTES

Received July 28, 2000; revised Oct. 31, 2000; accepted Nov. 1, 2000.

This work was supported by Russian Fund for Basic Research Grants N 98-04-49651 and N 99-04-50022.
Correspondence should be addressed to N. N. Dygalo, Institute of Cytology and Genetics, Novosibirsk 630090, Russia. E-mail:dygalo{at}bionet.nsc.ru.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Agmo A, Villalpando A (1995) Central nervous stimulants facilitate sexual behavior in male rats with medial prefrontal cortex lesions. Brain Res 696:187-193[Medline].
Aoki C, Go CG, Venkatesan C, Kurose H (1994) Perikaryal and synaptic localization of alpha2A-adrenergic receptor-like immunoreactivity. Brain Res 650:181-204[Web of Science][Medline].
Bancroft J (1995) Are the effects of androgens on male sexuality noradrenergically mediated? Some considerations of the human Neurosci Biobehav Rev 19:325-330[Medline].
Benelli A, Arletti R, Basaglia R, Bertolini A (1993) Male sexual behaviour: further studies on the role of alpha2-adrenoceptors. Pharmacol Res 28:35-45[Medline].
Bremner JD, Krystal JH, Southwick SM, Charney DS (1996a) Noradrenergic mechanisms in stress and anxiety. I. Preclinical studies. Synapse 23:28-38[Web of Science][Medline].
Bremner JD, Krystal JH, Southwick SM, Charney DS (1996b) Noradrenergic mechanisms in stress and anxiety. II. Clinical studies. Synapse 23:39-51[Medline].
Bylund DB, Eikenberg DC, Hieble JP, Langer SZ, Lefkowitz RJ, Minneman KP, Molinoff PB, Ruffolo Jr RR, Trendelenburg AU (1994) International Union of Pharmacology Nomenclature of Adrenoceptors. Pharmacol Rev 46:121-136[Web of Science][Medline].
Callado LF, Stamford JA (1999) Alpha2A- but not alpha2B/C-adrenoceptors modulate noradrenaline release in rat locus coeruleus: voltammetric data. Eur J Pharmacol 366:35-39[Web of Science][Medline].
Chomczynski P, Sacchi N (1987) Single step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal Biochem 162:156-159[Web of Science][Medline].
Clark JT (1991) Suppression of copulatory behavior in male rats following central administration of clonidine. Neuropharmacology 30:373-382[Medline].
Clark JT, Smith ER (1984) Enhancement of sexual motivation in male rats by yohimbine. Science 225:847-849[Abstract/Free Full Text].
Clark JT, Smith ER, Davidson JM (1985a) Evidence for the modulation of sexual behavior by alpha-adrenoceptors in male rats. Neuroendocrinology 41:36-43[Medline].
Clark JT, Smith ER, Davidson JM (1985b) Testosterone is not required for the enhancement of sexual motivation by yohimbine. Physiol Behav 35:517-521[Medline].
Clark JT, Gabriel SM, Simpkins JW, Kalra SP, Kalra PS (1988) Chronic morphine and testosterone treatment. Effects on sexual behavior and dopamine metabolism in male rats. Neuroendocrinology 48:97-104[Medline].
Cole JC, Burroughs GJ, Laverty CR, Sheriff NC, Sparham EA, Rodgers RJ (1995) Anxiolytic-like effects of yohimbine in the murine plus-maze: strain independence and evidence against alpha2-adrenoceptor mediation. Psychopharmacology 118:425-436[Medline].
Damassa DA, Smith EB, Tennent B, Davidson JM (1977) The relationship between circulating testosterone levels and male sexual behavior in rats. Horm Behav 8:275-287[Medline].
Dennis T, L'Heureux R, Carter C, Scatton B (1987) Presynaptic alpha-2 adrenoceptors play a major role in the effects of idazoxan on cortical noradrenaline release (as measured by in vivo dialysis) in the rat. J Pharmacol Exp Ther 241:642-649[Abstract/Free Full Text].
Ernsberger P, Meeley MP, Mann JJ, Reis DJ (1987) Clonidine binds to imidazoline binding sites as well as $alpha$ ₂-adrenoceptors in the ventrolateral medulla. Eur J Pharmacol 134:1-13[Web of Science][Medline].
Fontana DJ, McMiller Jr LV, Commissaris RL (1999) Depletion of brain norepinephrine: differential influence on anxiolytic treatment effects. Psychopharmacology 143:197-208[Medline].
Gobert A, Rivet JM, Cistarelli L, Melon C, Millan MJ (1997) Alpha2-adrenergic receptor blockade markedly potentiates duloxetine- and fluoxetine-induced increases in noradrenaline, dopamine, and serotonin levels in the frontal cortex of freely moving rats. J Neurochem 69:2616-2619[Web of Science][Medline].
Handley SL, Mithani S (1984) Effects of alpha-adrenoceptor agonists and antagonists in a maze-exploration model of "fear"-motivated behaviour. Naunyn Schmiedebergs Arch Pharmacol 327:1-5[Web of Science][Medline].
Heal DJ, Butler SA, Prow MR, Bucket WR (1993) Quantification of presynaptic alpha-2 adrenoceptors in rat brain after short term DSP-4 lesioning. Eur J Pharmacol 249:37-41[Medline].
Hosoda K, Feussner GK, Fitzgerald LR, Fishman PH, Duman RS (1994) Agonist and cyclic AMP-mediated regulation of alpha1-adrenergic receptor mRNA and gene transcription in rat C6 glioma cells. J Neurochem 63:1635-1645[Medline].
Hosoda K, Fitzgerald LR, Vaidya VA, Feussner GK, Fishman PH, Duman RS (1995) Regulation of beta 2-adrenergic receptor mRNA and gene transcription in rat C6 glioma cells: effects of agonist, forskolin, and protein synthesis inhibition. Mol Pharmacol 48:206-211[Abstract].
Jacobowitz DM, Richardson JS (1978) Method for the rapid determination of norepinephrine, dopamine and serotonin in the same brain region. Pharmacol Biochem Behav 5:515-519.
Koskinen I, Hendricks S, Yells D, Fitzpatrick D, Graber B (1991) Yohimbine and naloxone: effects on male rat sexual behavior. Physiol Behav 50:589-593[Medline].
La Marca S, Dunn RW (1994) The alpha-2 antagonists idazoxan and rauwolscine but not yohimbine or piperoxan are anxiolytic in the Vogel lick-shock conflict paradigm following intravenous administration. Life Sci 54:PL179-PL184[Medline].
Lowry OH, Rosenbrough NJ, Farr AL, Randall RJ (1951) Protein measurement with the Folin phenol reagent. J Biol Chem 193:265-275[Free Full Text].
Lucion AB, Charchat H, Pereira GA, Rasia-Filho AA (1996) Influence of early postnatal gonadal hormones on anxiety in adult male rats. Physiol Behav 60:1419-1423[Medline].
Marrocco RT, Witte EA, Davidson MC (1994) Arousal systems. Curr Opin Neurobiol 4:166-170[Web of Science][Medline].
Mateo Y, Meana JJ (1999) Determination of the somatodendritic alpha2-adrenoceptor subtype located in rat locus coeruleus that modulates cortical noradrenaline release in vivo. Eur J Pharmacol 379:53-57[Medline].
Milner TA, Lee A, Aicher SA, Rosin DL (1998) Hippocampal alpha2a-adrenergic receptors are located predominantly presynaptically but are also found postsynaptically and in selective astrocytes. J Comp Neurol 395:310-327[Web of Science][Medline].
Peters RH, Koch PC, Blythe BL (1988) Differential effects of yohimbine and naloxone on copulatory behaviors of male rats. Behav Neurosci 102:559-564[Medline].
Rago L, Saano V, Tupala E, Nieminen SA, Airaksinen MM (1992) ³H-Atipamezole binding sites in mouse cerebral cortex: possible involvement of alpha2-adrenoceptors in sexual behavior. Methods Find Exp Clin Pharmacol 14:23-27[Medline].
Rampin O (1999) Pharmacology of alpha-adrenoceptors in male sexual function. Eur Urol 36:103-106.
Robinson ESJ, Nutt DJ, Hall L, Jackson HC, Hudson AL (1999) Autoradiographical and behavioural effects of a chronic infusion of antisense to the $alpha$ _2D-adrenoceptor in the rat. Br J Pharmacol 128:515-522[Web of Science][Medline].
Rowland DL, Kallan K, Slob AK (1997) Yohimbine, erectile capacity, and sexual response in men. Arch Sex Behav 26:49-62[Medline].
Sala M, Braida D, Leone MP, Calcaterra P, Monti S, Gori E (1990) Central effect of yohimbine on sexual behavior in the rat. Physiol Behav 47:165-173[Medline].
Shishkina GT, Naumenko EV (1995) Correlations between the hypothalamic density of ³H-clonidine-binding sites and plasma testosterone levels in mice. Neuroendocrinology 61:663-668[Medline].
Shishkina GT, Borodin PM, Naumenko EV (1993) Sexual maturation and seasonal changes in plasma levels of sex steroids and fecundity of wild Norway rats selected for reduced aggressiveness towards man. Physiol Behav 53:389-393[Medline].
Shishkina GT, Sournina N Yu, Dygalo NN (1997) Sexual behavior and alpha-2 adrenoceptors in the neocortex of male rats after castration and testosterone administration (in Russian). Zh Vyssh Nerv Dejat Im IP Pavlov 47:592-596.
Smith ER, Lee RL, Schnur SL, Davidson JM (1987) Alpha2-adrenoceptor antagonists and male sexual behavior. I. Mating behavior. Physiol Behav 41:7-14[Medline].
Spedding M, Newman-Tancredi A, Millan MJ, Dacquet C, Michel AN, Jacoby E, Vickery B, Tallentire D (1998) Interaction of the anxiogenic agent, RS-30199, with 5-HT1A receptors: modulation of sexual activity in the male rat. Neuropharmacology 37:769-780[Medline].
Szemeredi K, Komoly S, Kopin IJ, Bagdy G, Keiser HR, Goldstein DS (1991) Simultaneous measurement of plasma and extracellular fluid concentrations of catechols after yohimbine administration in rats. Brain Res 542:8-14[Web of Science][Medline].
Tallentire D, McRae G, Spedding M, Clark R, Vickery B (1996) Modulation of sexual behaviour in the rat by a potent and selective alpha2-adrenoceptor antagonist, delequamine (RS-15385-197). Br J Pharmacol 118:63-72[Web of Science][Medline].
Venkatesan C, Song XZ, Go CG, Kurose H, Aoki C (1996) Cellular and subcellular distribution of alpha2A-adrenergic receptors in the visual cortex of neonatal and adult rats. J Comp Neurol 365:79-95[Web of Science][Medline].
Weiss JM, Stout JC, Aaron MF, Quan N, Owens MJ, Butler PD, Nemeroff CB (1994) Experimental studies of depression and anxiety: role of the locus coeruleus and corticotropin-releasing factor. Brain Res Bull 35:561-572[Medline].

Copyright © 2001 Society for Neuroscience 0270-6474/01/212726-06$05.00/0

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 Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via Web of Science (14)

Citing Articles via Google Scholar

Google Scholar

Articles by Shishkina, G. T.

Articles by Dygalo, N. N.

Search for Related Content

PubMed

PubMed Citation

Articles by Shishkina, G. T.

Articles by Dygalo, N. N.