NMDA-Mediated Activation of the Medial Amygdala Initiates a Downstream Neuroendocrine Memory Responsible for Pseudopregnancy in the Female Rat

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The Journal of Neuroscience, June 1, 2001, 21(11):4104-4110

NMDA-Mediated Activation of the Medial Amygdala Initiates a Downstream Neuroendocrine Memory Responsible for Pseudopregnancy in the Female Rat
Eva K. Polston¹^,², Molly Heitz¹, William Barnes¹, Kristen Cardamone¹, and Mary S. Erskine¹
¹ Department of Biology, Boston University, Boston, Massachusetts 02215, and ² Division of Neuroscience, Oregon Regional Primate Research Center, Beaverton, Oregon 97006

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In female rats, genitosensory stimulation received during mating initiates twice-daily prolactin (PRL) surges, a neuroendocrineresponse that is the hallmark of early pregnancy or pseudopregnancy(P/PSP). Nocturnal and diurnal PRL surges are expressed repeatedlyfor up to 2 weeks after copulation, suggesting that a neuroendocrinememory for vaginocervical stimulation (VCS) is established atthe time of mating. These studies investigated whether the processingand retention of VCS involves acute glutamatergic activation orde novo protein synthesis within the medial nucleus of the amygdala(MEA), a VCS-responsive brain site that is implicated in P/PSPinitiation. Pharmacological activation of the MEA with the glutamateagonist, NMDA, initiated nocturnal PRL surges, causing a PSP statein females that had not received VCS. P/PSP initiation by matingwas prevented by intra-amygdalar infusion of the NMDA receptorantagonist, 2-amino-5-phosphonopentanoic acid (AP-5), providedthat it was administered before mating. AP-5 treatment also disruptedmating-induced c-fos expression in the principle bed nucleus ofthe stria terminalis and the ventrolateral division of the ventromedialhypothalamic nucleus, but not in the medial or anteroventral periventricularpreoptic nuclei. Neither P/PSP nor downstream cellular activationwas prevented when a protein synthesis inhibitor, anisomycin,was administered to the MEA. The results indicate that MEA cellsare critical to the early processing of VCS through NMDA channelactivation, rapidly conveying information to downstream hypothalamiccell groups that modulate neuroendocrinefunction.

Key words: glutamate; medial amygdala; NMDA; VCS; sensory transduction; memory

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Reproductive neuroendocrine systems are particularly amenable to investigation of the mechanisms through which sensory inputsinduce long-term changes in brain function. These circuitriesare markedly affected by experience, and persistent changes inneuroendocrine and behavioral function occur as a result of mating,parturition, and lactation (Keverne et al., 1993; Gies and Theodosis,1994; Bridges et al., 1997). In female rats, the receipt of thresholdamounts of vaginocervical stimulation (VCS) during mating triggerslong-term changes in neuroendocrine function that are essentialfor pregnancy success. Bicircadian pituitary prolactin (PRL) surgesare initiated in direct response to VCS, occurring repeatedlyfor 10-12 d and characterizing early pregnancy or pseudopregnancy(P/PSP) (Gunnet and Freeman, 1983; Erskine, 1995). Because PRLsurges are expressed for up to 2 weeks without further genitosensorystimulation, it is postulated that a neuroendocrine memory, ormnemonic, is formed centrally by VCS (Freeman et al., 1974; Terkelet al., 1990).

The transduction mechanisms and CNS pathways responsible for the establishment and expression of the VCS mnemonic are poorlyunderstood. However, there is substantial evidence that the posterodorsalmedial amygdala (MEApd) is involved in initiating P/PSP. By measuringexpression of the immediate-early gene, c-fos, we and others haveidentified an anatomically distinct group of MEApd cells thatis activated selectively by VCS (Pfaus et al., 1993; Rowe andErskine, 1993; Tetel et al., 1993; Polston and Erskine, 1995),and electrophysiological studies confirm that neuronal activityin the medial amygdala (MEA) is increased by VCS treatment (Kawakamiand Kubo, 1971). Moreover, pharmacological excitation of the MEAby NMDA results in cessation of ovarian cyclicity for 10-12 d,as is typical of PSP (Numan et al., 1993; Polston and Erskine,2001), and the incidence of P/PSP is reduced when the sodium channelantagonist, lidocaine, is infused into the MEA before mating (Coopersmithet al., 1996). Thus, although additional brain sites, includingthe medial preoptic area and the dorsomedial, ventromedial, andarcuate hypothalamic nuclei, may be involved in the expressionof PRL surges (Erskine, 1995), activation of the MEApd appearsto be particularly important to the initial transduction of VCSand to mnemonicacquisition.

The aim of the present experiments was to determine whether glutamate receptor activation or protein synthesis in the MEAis involved in the establishment of the mating mnemonic. We investigatedwhether daily PRL surges could be initiated through bilateralinfusions of the glutamate agonist, NMDA, into the MEA of unmatedanimals and whether treatment of the MEA with glutamate antagonistsor a protein synthesis inhibitor could block P/PSP in mated animals.Lastly, we examined the effects of NMDA receptor blockade or proteinsynthesis inhibition on mating-induced c-fos expression in theprinciple bed nucleus of the stria terminalis (BSTp), ventrolateraldivision of the ventromedial hypothalamus (VMHvl), medial divisionof the medial preoptic nucleus (MPNm), and anteroventral periventricularpreoptic nucleus (AVPV), areas that receive efferents from theMEApd and are involved in the regulation of PRL secretion (Krettekand Price, 1978; Canteras et al., 1995; Erskine, 1995).

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals. Experimental animals were female Long-Evans rats (225-275 gm) obtained from Charles River Laboratories (Wilmington,MA). Mating stimulation was provided by sexually experienced malesof the same strain (300-400 gm). Animals were housed singly inwire mesh cages with food and water available ad libitum. Becauserats are a nocturnally active species, animals were housed ina room in which the light cycle was reversed from normal daylighthours (lights off from 8:00 A.M. to 8:00 P.M.), facilitating proceduresthat were conducted during the dark phase of the cycle. For presentationpurposes, these times have been adjusted to correspond to naturaldaylight hours. Ovarian cyclicity of all females was monitoredby daily vaginal lavage, and females exhibiting two consecutiveestrous cycles of 4-5 d were used. After treatments, P/PSP wasconsidered to have been induced if 8-13 d of consecutive diestrussmears, characterized by an absence of cornified epithelial cellsassociated with estrus and a preponderance of leukocytes, wereobserved (Cooper et al., 1993). All procedures were approved bythe Laboratory Animal Use and Care Committee at Boston University(Boston, MA) in accordance with National Institutes of Healthguidelines.

Administration of NMDA into the medial amygdala. To determine whether the sensory transduction mechanisms required for initiationof VCS-induced PRL surges may include activation of NMDA receptorswithin the MEA, cycling females were infused on proestrus withNMDA into the MEA, and repeated blood samples were obtained 6-7d later at the time of the diurnal PRL surge, the intersurge period,and the nocturnal PRL surge as detailed below. For infusion ofNMDA, females were anesthetized with sodium pentobarbital (Nembutal,50 mg/kg, i.p.; J. A. Webster, Sterling, MA) and placed in a stereotaxicapparatus (David Kopf Instruments, Tujunga, CA) with the toothbarset at $-$ 3.3 mm in accordance with the atlas of Paxinos and Watson(1986). Holes were drilled bilaterally in the skull, and a beveled1 µl Hamilton syringe (model 7001) filled with NMDA (0.14 M; Sigma,St. Louis, MO) or PBS vehicle (VEH) was attached to a Kopf microinjectorand lowered into the MEA [bregma $-$ 2.4 mm anteriorposterior (AP),±3.75 mm mediolateral, dura $-$ 7.3 mm dorsoventral (DV)] with thebevel pointing medially. This directed the infusate toward theMEApd from the site of penetration at the lateral edge of theoptic tract. NMDA or VEH was infused bilaterally into the MEAin a volume of 0.4 µl per side. Infusion occurred over 2 min,and syringes were left in place for an additional postinfusionperiod of 2 min to allow for drug diffusion away from the needletip. After removal of the infusate needle, the holes in the skullwere filled with bone wax, and the skin was suturedclosed.

Blood sampling and PRL radioimmunoassay. Immediately after NMDA or VEH infusion, animals were fitted with intra-atrial cathetersfor repeated blood sampling as described previously (Kornbergand Erskine, 1994). Postoperatively, females were treated withatropine sulfate (0.05 mg per rat, s.c.; J. A. Webster) and dailyinjections of gentomycin sulfate (1.5 mg/d per rat, s.c.; SterisLaboratories, Phoenix, AZ). Catheters were kept patent by dailyflushes with 100 U/ml sterile heparinized saline (Henry ScheinCo., Port Washington, NY). Using previously published methods(Polston et al., 1998), we collected blood samples (0.3 ml) 6-7d after drug treatment at 6:00 P.M., 12:00 A.M., and 6:00 A.M.,times of day that correspond, respectively, to the diurnal PRLsurge, the intersurge period, and the nocturnal PRL surge duringP/PSP. Samples were centrifuged at 4°C for 20 min, after whichplasma was collected and frozen at $-$ 20°C until radioimmunoassaywas performed. Methods for radioimmunoassay of PRL were as previouslyreported (Polston et al., 1998). Briefly, plasma was diluted in1% BSA (1:20) and incubated for 24 hr with anti-rat-PRL antibody[anti-r-PRL-S-9; National Institute of Diabetes and Digestiveand Kidney Diseases (NIDDK), Bethesda, MD] at a final tube concentrationof 1:10,000. Radiolabeled PRL (¹²⁵I-PRL; 20,000 cpm/100 µl; Covance Laboratories, Vienna, VA) wasadded to all assay tubes, and incubation continued for an additional24 hr. Antibody-bound isotope was precipitated by adding coldProtein A (IgGSorb; The Enzyme Center, Malden, MA), and pelletswere counted in a gamma counter. Raw data were analyzed usingBeckman EIARIA radioimmunoassay software. The within-assay coefficientof variation was 5.79%, and assay sensitivity was 30 pg ofPRL.

Administration of antagonist drugs. The NMDA receptor antagonist, 2-amino-5-phosphonopentanoic acid (AP-5), and the proteinsynthesis inhibitor, anisomycin (ANI), were administered intothe MEA at several times around the time of mating to determinethe efficacy of these drugs on the inhibition of mating-inducedP/PSP. To allow treatment of awake animals with AP-5 and ANI,steel guide cannulas were constructed from wide-bore 23 ga needles(Becton Dickinson, Franklin Lakes, NJ) and cut to a length of15 mm. Cannulas were implanted and affixed to the skull with dentalcement using standard stereotaxic techniques. They were lowereduntil the ventral tips resided 2.0 mm dorsal to the MEApd (DV $-$ 5.3 mm from dura). Cannulas were cleared daily with size 00 insectpins cut to the same length. After establishing that normal estrouscycles continued postoperatively, AP-5 (0.05 M, 1.0 µl per side;Sigma) or VEH (1.0 µl per side) was administered into the MEAon the evening of the proestrus vaginal smear (11:00 P.M.) usinga beveled 30 ga infusion needle that extended 2.0 mm beyond theventral tip of the guide cannula (Coopersmith et al., 1996). Theinfusion needle was connected by polyethylene tubing (PE20; ClayAdams, Parsippany, NJ) to a 1 µl syringe was placed in a Kopfmicroinjector. Animals were held gently by the investigator, andinfusates were delivered to unanesthetized females over the courseof 1-2 min per side. An additional 1-2 min was allowed beforewithdrawal of the infusionneedle.

Anisomycin (Sigma) was administered in crystalline form. Insert cannulas were constructed of 28 ga stainless steel hypodermictubing. They were filled to a depth of 2 mm with ANI by tampingthe end of the insert cannula into the powdered drug and measuringthe depth by means of a thin wire inserted from the top. The outsideof each insert was cleaned with ethanol; the inserts were loweredthrough the guide cannulas such that they extended 2 mm beyondthe tip of the guide cannula. Inserts were held in place by apiece of polyvinyl tubing attaching them to the guide cannulas.ANI-filled implants were lowered into the MEApd either 1.5 hrbefore mating or 1, 2, or 4 hr after mating and left in placefor a total of 3 hr. Control groups were given empty implants1.5 hr before mating or ANI implants for 3 hr without mating.At the conclusion of the treatment period, insert cannulas wereremoved, and animals were returned to their home cages. Examinationof the insert cannulas showed that ANI had not diffused to thepoint of depletion after the 3 hr treatmentperiod.

Verification of drug efficacy and implant-infusion sites. To verify that AP-5 blocked neuronal activation and that ANI preventedprotein synthesis within the MEA, separate groups of animals weretreated with AP-5 or ANI as above, and the ability of mating stimulationto induce c-fos expression within the MEApd was measuredas indicated below. Table 1 shows the efficacy of AP-5 and ANItreatments within the MEApd as measured by the number of FOS-immunoreactive(FOS-IR) cells induced by mating. Animals were treated with eithera single infusion of AP-5 15 min before mating (n = 4) or an implantof ANI 1.5 hr before mating (n = 6); these times correspondedto the premating treatment times in the experimental groups. Mated(n = 6) and unmated (n = 5) control females received blank implants.Local treatment with AP-5 and ANI prevented the mating-inducedFOS response seen in the mated controls (F_(3,17) = 26.64; p $<=$ 0.001). Both AP-5 and ANI treatments eliminated the predominantstreak of FOS-IR cells that are observed normally after mating(Polston and Erskine, 1995), significantly reducing the numberof FOS-IR cells within the treated area compared with that ofuntreated, mated animals (p $<=$ 0.002). The suppressive effectsof both treatments were comparable, and the numbers of FOS-IRcells in the treated groups were not significantly higher thanthose that were observed in the unmated females. Thus, AP-5 treatmentsuccessfully inhibited activation of cells known to be responsiveto VCS, and ANI treatment effectively suppressed protein synthesiswithin the same site.


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Table 1. Effect of intra-amygdalar administration of AP-5 and ANI on FOS-IR labeling in the MEApd after mating

For histological analysis of placement sites, animals were deeply anesthetized with sodium pentobarbital 12-16 d after NMDA,receptor antagonist, or ANI treatment and perfused transcardiallyusing 10% formalin as previously described (Coopersmith et al.,1996). Brains were removed and stored in cryoprotectant (25% sucrosein 10% formalin). Coronal 40 µm sections through the amygdalawere cut on a cryostat (model 1800; Leica, Holliston, MA), mountedonto gelatin-coated slides, stained with cresyl violet acetate,and coverslipped using Permount mounting medium (Sigma). Sitesof NMDA, AP-5, and control infusions and ANI implantation weretraced onto coronal diagrams from the atlas of Paxinos and Watson(1986) by an investigator blind to the condition of the animals.Only data from animals with bilateral infusion-implant sites thatwere within the posterior portion of the MEA from the AP plane $-$ 3.14 to $-$ 3.80 were included in the analyses. Because NMDA infusionscaused eventual cytotoxic damage to the area (Dusart et al., 1991),the presence of gliosis was used as an additional verificationof needle placement in thatgroup.

Administration of mating stimulation. Behavioral treatments were administered in a dimly illuminated room between 10:00 P.M.and 2:00 A.M. on the night of the proestrus vaginal smear. Femalesshowing a positive lordosis response to at least two of threemanual palpations were placed alone into glass testing chambers(30 × 26 × 50 cm) for a 10 min habituation period, and then stimulusmales were introduced into the chambers. Behavioral tests continueduntil males had achieved 15 intromissions, including ejaculationswhen they occurred. This number of intromissions has induced P/PSPin 91% of females in this laboratory (Kornberg and Erskine, 1994;Coopersmith et al., 1996; Polston and Erskine, 2001). Behavioralrecords of the mating stimulation received by each female includedthe number of mounts, intromissions, and ejaculations receivedand the proportion of mounts that included intromission and ejaculation(mating efficacy). Measures obtained of the level of sexual receptivityshown by each female were the percentage occurrence of lordosisin response to male mounts [lordosis quotient (LQ)] and the meanintensity of lordosis responses based on a four-point rating scale[lordosis rating (LR)] (Hardy and DeBold, 1971). At the end ofthe behavioral treatments, females were returned to their homecages for the remainder of theexperiment.

Hypothalamic and preoptic areas responsive to VCS-induced activity within the MEA. To determine whether the effects of AP-5infusion in the MEA on P/PSP induction could be demonstrated toinclude disruption of mating-induced activity within downstreambrain sites involved in PRL regulation, we examined mating-inducedc-fos expression in separate groups of animals in four preopticand hypothalamic target areas, the BSTp, the VMHvl, the MPNm,and the AVPV, after unilateral infusion-implantation of AP-5 orANI into the MEA. AP-5 was infused 15 min before mating, ANI wasimplanted 1.5 hr before mating as above, and saline infusionsor blank implants were administered to the contralateral sideof the brain. A group of unmated control females received blankimplants on both sides. For determination of neuronal activation,brain areas were labeled immunocytochemically for nuclear FOSprotein, and the number of FOS-IR cells within the ipsilateraland contralateral sides were compared to determine the effectsof treatment within individualanimals.

Females were anesthetized 1.0-1.5 hr after mating and perfused transcardially with 0.9% saline followed by 4% paraformaldehyde.Brains were notched unilaterally on the cortical surface to identifythe sides ipsilateral and contralateral to treatment and weresectioned at 60 µm on a vibratome in the coronal plane (Paxinosand Watson, 1986). Free-floating sections through the AVPV, MPNm,BSTp, and VMHvl were labeled for FOS as previously reported (Polstonand Erskine, 1995). Briefly, sections were preincubated in 1%normal goat serum/1% H₂O₂ in PBS for 20 min, and, after two 10min rinses in PBS, sections were incubated for 24 hr at room temperaturein primary anti-FOS antibody (1:2000 in 0.4% Triton X-100 in PBSsolution; sc52; Santa Cruz Biotechnology, Santa Cruz, CA). Visualizationwas performed using biotinylated anti-rabbit IgG antibody generatedin goat (1:200 in 0.4% Triton X-100 in PBS) followed by VectastainElite avidin-biotin complex and nickel-enhanced DAB peroxidasesubstrate (Vector Laboratories, Burlingame, CA). Stained sectionswere mounted onto gelatin-coated slides, dehydrated in ethanol,cleared in xylenes and coverslipped as above. Verification ofspecificity of the primary antibody has been demonstrated previously(Erskine and Hanrahan, 1997). FOS-IR cells were identified bytheir brown-black nuclear staining and were counted if they haddistinct nuclear boundaries. Cell counts were taken on both sidesof the brain within each area of interest using a CCD camera andthe NIH Image analysis program or a camera lucida (Polston andErskine, 1995). Standard templates delineating an area 410 × 420µm for the MPNm and BSTp, 460 × 210 µm for the MEApd, 300 × 310µm for the VMHvl, and 305 × 140 µm for the AVPV were superimposedover the nuclei at a magnification of 200×, as depicted in Figure1, and labeled cells within these templates were quantified byan investigator blind to the treatment groups of the animals.

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Figure 1. Schematic representation of the five brain areas in which FOS-immunoreactivity was quantified. Outlined boxes represent the region of interest templates within which the numbers of FOS-IR cells were counted. Numbers represent the distance from bregma in the AP plane. 3v, Third ventricle; ac, anterior commissure; AVPV, anteroventral periventricular preoptic nucleus; BSTp, principle bed nucleus of the stria terminalis; f, fornix; MEApd, posterodorsal division of the medial amygdala; MPNm, medial division of the medial preoptic nucleus; oc, optic chiasm; ot, optic tract; sm, stria medularis; st, stria terminalis; VMHvl, ventrolateral division of the ventromedial hypothalamic nucleus.

Statistical analyses. Effects of drug treatments on the number of subsequent days of diestrous smears, prolactin levels measured6-7 d after NMDA or VEH infusion, and the number of FOS-IR cellswithin the MEApd after local treatment with AP-5 or ANI were comparedby ANOVA followed by Scheffé's post hoc tests. Numbers of FOS-IRcells in ipsilateral and contralateral sides downstream to theunilateral MEA treatments were analyzed using paired t tests withineach brain area. All effects were considered to be statisticallysignificant when p $<=$ 0.05.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Effect of NMDA infusion into the MEA on induction of PRL surges and P/PSP

Intra-amygdalar infusion of NMDA resulted in prolonged ovarian acyclicity characteristic of PSP in 100% of the animals, comparedwith 28% in the VEH-infused group (F_(2,14) = 9.87; p $<=$ 0.002).To determine whether this effect reflected the induction of PRLsurges by NMDA treatment, plasma PRL concentrations at the timesof the diurnal surge (6:00 P.M.), intersurge period (12:00 A.M.),and nocturnal surge (6:00 A.M.) were compared between NMDA-infusedPSP females (n = 7) and VEH-infused cycling females (n = 5). Asshown in Figure 2, there were significant effects of drug treatment(F_(1,10) = 5.46; p $<=$ 0.05) and sample time (F_(2,20) = 4.01; p $<=$ 0.05) and a drug × sample time interaction (F_(2,20) = 6.85;p $<=$ 0.005). A statistically significant elevation of PRL levelsoccurred in the NMDA-infused animals compared with the VEH-infusedanimals at 6:00 A.M., indicating the induction of nocturnal PRLsurge release by this glutamate agonist. Diurnal surges were notobserved, as is consistent with the reported inhibition of thissurge in animals bearing intra-atrial catheters (Freeman et al.,1974; Polston and Erskine, 2001). Because the nocturnal PRL surgehas been demonstrated to be primarily responsible for maintenanceof P/PSP (Gala and Haisenleder, 1984) and is observed physiologicallyonly in females that have received pelvic nerve stimulation throughVCS (Spies and Niswender, 1971; Kornberg and Erskine, 1994), thepresence of the nocturnal surge 6-7 d subsequent to NMDA infusionconfirms that pharmacological stimulation of the MEA initiatedcentral events that are associated specifically with the processingof the VCS stimulus.

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Figure 2. Plasma PRL (in nanograms per milliliter) concentrations at the times of the diurnal surge (6:00 P.M.), the intersurge period (12:00 A.M.), and the nocturnal surge (6:00 A.M.) in animals receiving bilateral infusions of NMDA (filled bars; n = 7) or VEH (hatched bars; n = 5) into the MEA 6-7 d previously. Values are mean ± SEM. * indicates significantly higher levels compared with VEH controls (p $<=$ 0.03).

Effect of NMDA receptor blockade and protein synthesis inhibition within the MEA on initiation of P/PSP by mating

The effects of local treatment with AP-5 and ANI on the induction of P/PSP are presented in Figure 3. Bilateral infusion ofAP-5 15 min before mating and 75 min after mating [early group(AP-5_E); n = 8] completely blocked the induction of P/PSP by matingin all animals, whereas AP-5 given at +0 and +90 min after matingonset [late group (AP-5_L); n = 4] failed to prevent P/PSP induction.All mated control females infused with VEH and none of the unmatedanimals treated with AP-5 (AP-5_U) became P/PSP. As shown in Figure3A, significant group differences were observed in the numberof days of vaginal diestrus observed after treatment (F_(4,24)= 182.51; p $<=$ 0.001). The mean number of consecutive daily diestroussmears was significantly higher among the AP-5_L and VEH animalsthan among the AP-5_E and AP-5_U animals (p $<=$ 0.001).

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Figure 3. Number of diestrus days (mean ± SEM) observed after mating in groups receiving bilateral infusions of AP-5 (A) beginning either before (AP-5_E; n = 8) or after (AP-5_L; n = 4) mating, or bilateral implants of ANI (B) beginning before (ANI_E; n = 9) or after (ANI_L; n = 7) mating. Control groups received either VEH infusions (n = 6) or blank implants (n = 7) before mating or received AP-5 (n = 7) or ANI (n = 5) without mating. Animals that were pregnant rather than PSP were assigned a diestrus duration of 12 d. * indicates significant difference from VEH or blank controls (p $<=$ 0.001).

A high proportion (88.9%) of animals treated with ANI bilaterally for 3 hr beginning 1.5 hr before mating [early group (ANI_E);n = 9] and 100% of animals given ANI beginning 1-4 hr after mating[late group (ANI_L); n = 7] became P/PSP. Control animals given3 hr exposure to ANI without mating (ANI_U; n = 5) did not becomeP/PSP. As shown in Figure 3B, significantly lengthened periodsof acyclicity were observed after mating in the ANI_E and ANI_Lgroups but not in the ANI_U group (F_(3,24) = 26.46; p $<=$ 0.001).

Analysis of the behavioral measures obtained showed that there were no significant differences between drug-treated and controlgroups in the quantity of VCS received or in the level of sexualreceptivity (LQ and LR) exhibited (data not shown). The matingefficacy was equally unaffected as a function of treatment, suggestingthat there were no drug-related behavioral effects that mighthave prevented the female from receiving normal intromissivestimulation.

Effect of NMDA receptor blockade and protein synthesis inhibition on mating-induced cellular activation in sites downstream to the MEApd

Unilateral infusion of AP-5 into the MEA 15 min before mating resulted in significantly lower numbers of FOS-IR cells in theipsilateral than in the contralateral BSTp (t = 5.52; df = 5;p $<=$ 0.003) and VMHvl (t = 7.79; df = 4; p $<=$ 0.001) 1.0-1.5 hrafter mating (Fig. 4A). There was no effect of this treatmenton c-fos expression within the ipsilateral compared with contralateralMPNm or AVPV. In contrast, local unilateral treatment of the MEAwith ANI 1.5 hr before mating did not influence mating-inducedFOS expression in any of the four downstream sites examined (Fig.4B), and numbers of FOS-IR cells were comparable on the ipsilateraland contralateral sides in these areas.

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Figure 4. Number of FOS-immunoreactive cells 1.0-1.5 hr after mating in sites downstream to the MEApd in groups of animals receiving unilateral treatment of the MEA with AP-5 (A, filled bars) or ANI (B, filled bars). Contralateral areas were counted for each animal as a control. Values are mean ± SEM. * indicates significantly lower (p $<=$ 0.05) numbers compared with the untreated side (hatched bars). There were three to six animals per group.

  DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The present experiments indicate that a specific viscerosensory stimulus, VCS, can cause long-term alterations in brain functionthrough a temporally limited action of glutamate within the MEA.Direct application of NMDA into the MEA mimicked the sensory stimulationreceived by an estrous female during natural mating, initiatingPRL secretory patterns that are seen normally only after receiptof VCS. Moreover, application of the selective NMDA receptor antagonist,AP-5, to this same area before mating prevented PRL surges andP/PSP. Previous studies support the hypothesis that activationof the MEA contributes to P/PSP initiation. The MEApd exhibitssubstantial immediate-early gene responses to both natural andartificial mechanical VCS, and is the single area out of severalmating-responsive brain sites in which FOS responses reflect sensitivityto subtle changes in the quantity (Polston and Erskine, 1995)and quality (Erskine and Hanrahan, 1997) of VCS received. Infusionof lidocaine into this area significantly reduced the incidenceof P/PSP in mated females (Coopersmith et al., 1996), furtherverifying that neuronal excitation within the MEA is necessaryfor P/PSPinduction.

The question of whether NMDA acted by agonistic stimulation of excitatory responses or by inducing excitotoxic effects thatled to eventual cell death in the MEA is particularly germaneto interpretation of these results. Necrotic responses to excitatoryamino acid injections are well described, comprising an earlyphase lasting 1-14 d after infusion and a later stage that ischaracterized by an infiltration of astrocytic glia cells (Dusartet al., 1991; Marty et al., 1991). In the present experiment,glial coverage was observed in brains taken 16 d after NMDA infusion,and nocturnal PRL surges observed 6-7 d after NMDA infusion werediminished in magnitude, as is characteristic for MEA-lesionedfemales (Clark and Gala, 1985; Polston and Erskine, 2001). Nevertheless,several lines of evidence suggest that it is the initial excitatoryeffect of NMDA on MEA neurons that is responsible for the presenteffects. First, loss of function of glutamate-sensitive cellswould be predicted to cause effects similar to those of glutamateantagonists. Contrary to this, NMDA channel agonist and antagonisttreatments resulted in opposite neuroendocrine profiles in thesestudies, with agonist treatments inducing PSP and antagonistspreventing P/PSP induction. Second, because AP-5_L treatment wasineffective in preventing P/PSP, critical NMDA-mediated eventsin the MEA must be extremely rapid, occurring within the courseof the mating session, and thus are unlikely to reflect the signalingtransduction processes by which neuronal overstimulation leadsto cell death. Lastly, the influences of NMDA on neuroendocrineprofile are temporary, lasting approximately as long as a naturallyinduced PSP (Numan et al., 1993; Polston and Erskine, 2001). Althoughrecent results have demonstrated that the ability of mating toinduce P/PSP is regained after long-term MEA lesion (Polston andErskine 2001), the cessation of estrous cyclicity seen in thepresent study is unlikely to reflect a temporary loss of function.Rather, the extremely specific nature of nocturnal PRL surge secretionsuggests that the observed effects are caused by a temporallyisolated, excitatory response to NMDAtreatment.

The present experiments required infusion volumes that would influence the entire MEA. However, the selective effects of AP-5administration to the MEA on FOS expression within the BSTp andVMHvl support the hypothesis that cells within the MEApd, specifically,are responsible for the reported observations. Neuroanatomicalstudies demonstrate that MEApd efferents alone project directlyto the neuroendocrine hypothalamus, innervating the BSTp and theVMHvl as well as the MPNm and AVPV (Krettek and Price, 1978; Canteraset al., 1995; Coolen and Wood, 1998; Wang and Swann, 2000). Althoughthe MEApd is typically associated with pheromonal modulation ofreproductive function, a subpopulation of MEApd cells has beendescribed that is sensitive to VCS but not vomeronasal cues (Roweand Erskine, 1993). On the basis of the ability of AP-5 infusionsin the MEA to block the mating-induced FOS responses seen normallywithin the BSTp and VMHvl, we propose that excitation of theseMEApd cells by glutamate initiates a series of events within alarger neuroendocrine circuit (Simerly, 1995). The BSTp appearsto play an important role in the amygdalar-hypothalamic communicationof VCS, and BSTp neurons that are stimulated by VCS-responsivecells in the MEApd may act as a site of convergence for pheromonaland VCS inputs. In turn, both the MEApd and the BSTp send projectionsto the MPNm and AVPV (Simerly, 1995). However, MEA treatmentsthat suppressed FOS expression in the BSTp did not influence mating-inducedFOS expression in the MPNm or AVPV, areas thought to be involvedin regulating PRL secretory responses (Erskine, 1995; Gu and Simerly,1997). The role of the VMHvl in the processing of VCS-derivedinformation is less clear, but results from early studies usinglesions of the dorsomedial and ventromedial hypothalamic nucleisuggest that the VMH may be involved in the expression of PRLsurges and PSP (Gunnet et al., 1981).

The expression of daily PRL surges after mating requires that long-term changes occur in brain, retaining the imprint of VCSfor many days. Therefore, it is possible that cellular mechanismssimilar to those involved in the retention of explicit memorymay play a role in this model. NMDA channel function has beenimplicated consistently in amygdalar long-term potentiation (LTP),as well as in amygdala-mediated learning paradigms (Yamamoto etal., 1998; Maren, 1999), and NMDA-dependent LTP has been demonstratedelectrophysiologically within medial amygdalar circuits (Geanet al., 1993; Shindou et al., 1993). In the MEA, these processesof potentiation may be facilitated further by high levels of circulatingestrogens, such as are seen at the time of mating (Schiess etal., 1988). However, the failure of crystalline ANI implants toprevent PRL surges in the present study suggests that the establishmentof LTP in the amygdala is not required for the expression of thelong-term VCS mnemonic, because LTP has been shown consistentlyto require de novo protein synthesis (Huang et al., 2000). Rather,the data suggest that the amygdala is involved in the initialtransduction of VCS, rapidly processing sensory information duringthe course of the mating session. Because protein synthesis inthe MEA does not influence P/PSP induction, other downstream brainsites, such as the BSTp, are likely to be involved in the long-termstorage and subsequent expression of the mating mnemonic. However,whether the amygdala acts solely to relay VCS to the neuroendocrinehypothalamus or is directly involved in initial stages of mnemonicacquisition remainsundetermined.

Central to the question of how VCS is processed in the brain are the substantial data which demonstrate that a threshold amountof VCS is required for P/PSP induction. Approximately 10-15 intromissionsfrom males are required to initiate PRL surges (Terkel and Sawyer,1978; Polston and Erskine, 2001). The inability of lower numbersof intromissions to induce P/PSP suggests that multiple VCS mustbe processed additively in the CNS, and we have hypothesized thata second, short-term mnemonic process is responsible for accumulatinginformation from a series of VCS toward the threshold for PSPinduction. The MEApd may be involved in this summation process,because FOS-IR in the MEApd increases in a graded fashion withincreasing amounts of VCS (Polston and Erskine, 1995) and, whenfemales self-regulate the rate at which VCS is received, a treatmentfacilitatory to PSP induction (Erskine et al., 1989), c-fos expressionis enhanced only in this area (Erskine and Hanrahan, 1997). Althoughthe single, bolus NMDA infusion used in the present study waslikely to be sufficiently strong and/or persistent to excite MEAneurons to a threshold comparable with that of multiple intromissivestimuli, the effects of AP-5_E treatments are consistent with thepossibility that summation of multiple VCS occurs within the MEA.This hypothesis is strengthened further by our recent findingsthat three temporally spaced intra-amygdalar infusions of NMDAat a subthreshold dose can initiate P/PSP (Lehmann and Erskine,2000).

The central mechanisms by which somatosensory stimuli modulate the formation of memories are not well understood. Typically,these questions are investigated using classical associative andbehavioral methodologies, which are confounded by multimodal sensoryinputs and complex cognitive responses. The mating-induced neuroendocrinemnemonic in the rat offers a novel model in which a defined sensoryinput leads to long-term, measurable changes in brain function.Using this model, these studies demonstrate that activation ofNMDA channels within the MEA is both necessary and sufficientfor the establishment of long-term, VCS-mediated neuroendocrineresponses, and moreover, that the MEA is involved specificallyin the early sensory transduction processes that contribute tomnemonic acquisition. Furthermore, we demonstrate that mnemonicformation may be dependent selectively on activation of the BSTpand/or VMHvl after glutamatergic excitation of the MEApd. BecausePSP induction requires only pelvic nerve stimulation and is expressedas a unique neuroendocrine profile, the multiple-intromissionmating paradigm in the rat provides a simple, neuroethologicalapproach to the study of memory in mammalianbrain.

  FOOTNOTES

Received Jan. 2, 2001; revised March 19, 2001; accepted March 21, 2001.

This work was supported by National Institute of Child Health and Human Development Grant HD21802, a National Institute ofMental Health Independent Scientist Award (MH01435), and a ClareBoothe Luce Professorship from the Henry R. Luce Foundation toM.S.E. We thank Dr. A. Parlow and the National Institute of Diabetesand Digestive and Kidney Diseases for supplying the reagents forthe rat PRL assay. We also thank Greeshma Rai for her technicalassistance.
Correspondence should be addressed to Dr. Mary S. Erskine, Department of Biology, Boston University, 5 Cummington Street,Boston, MA 02215. E-mail: erskine{at}bio.bu.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Bridges RS, Henriquez BM, Sturgis JD, Mann PE (1997) Reproductive experience reduces haloperidol-induced prolactin secretion in female rats. Neuroendocrinology 66:321-326[Medline].
Canteras NS, Simerly RB, Swanson LW (1995) Organization of projections from the medial nucleus of the amygdala: a PHAL study in the rat. J Comp Neurol 360:213-245[ISI][Medline].
Clark WP, Gala RR (1985) Effect of lesions of the corticomedial amygdala on the nocturnal prolactin surge. Neuroendocrinology 41:297-305[Medline].
Coolen LM, Wood RI (1998) Bidirectional connections of the medial amygdaloid nucleus in the Syrian hamster brain: simultaneous anterograde and retrograde tract tracing. J Comp Neurol 399:189-209[ISI][Medline].
Cooper RL, Goldman JM, Vandenbergh JG (1993) Monitoring of the estrous cycle in the laboratory rodent by vaginal lavage. In: Methods in toxicology, pp 45-56 New York: Academic.
Coopersmith C, Gans SE, Rowe DW, Erskine MS (1996) Infusions of lidocaine into the amygdala, but not the preoptic area, block pseudopregnancy in the rat. J Neuroendocrinol 8:259-266[ISI][Medline].
Dusart I, Marty S, Peschanski M (1991) Glial changes following an excitotoxic lesion in the CNS-II. Astrocytes. Neuroscience 45:541-549[ISI][Medline].
Erskine MS (1995) Prolactin release after mating and genitosensory stimulation in females. Endocr Rev 16:508-528[ISI][Medline].
Erskine MS, Hanrahan SB (1997) Effects of paced mating on c-fos gene expression in the female rat brain. J Neuroendocrinol 9:903-912[ISI][Medline].
Erskine MS, Kornberg E, Cherry JA (1989) Paced copulation in rats: effects of intromission frequency and duration on luteal activation and estrus length. Physiol Behav 45:33-39[Medline].
Freeman ME, Smith MS, Nazian SJ, Neill JD (1974) Ovarian and hypothalamic control of the daily surges of prolactin secretion during pseudopregnancy in the rat. Endocrinology 94:875-882[ISI][Medline].
Gala RR, Haisenleder DJ (1984) Are both the nocturnal and diurnal prolactin surges necessary to maintain pseudopregnancy in the rat? Life Sci 34:179-185[Medline].
Gean P-W, Chang F-C, Huang C-C, Lin J-H, Way L-J (1993) Long-term enhancement of EPSP and NMDA receptor-mediated synaptic transmission in the amygdala. Brain Res Bull 31:7-11[ISI][Medline].
Gies U, Theodosis DT (1994) Synaptic plasticity in the rat supraoptic nucleus during lactation involves GABA innervation and oxytocin neurons: a quantitative immunocytochemical analysis. J Neurosci 14:2861-2869[Abstract].
Gu GB, Simerly RB (1997) Projections of the sexually dimorphic anteroventral periventricular nucleus in the female rat. J Comp Neurol 384:142-164[ISI][Medline].
Gunnet JW, Freeman ME (1983) The mating-induced release of prolactin: a unique neuroendocrine response. Endocr Rev 4:44-61[ISI][Medline].
Gunnet JW, Mick C, Freeman ME (1981) The role of the dorsomedial-ventromedial area of the hypothalamus in the control of prolactin secretion induced by cervical stimulation. Endocrinology 109:1846-1850[Abstract].
Hardy DF, DeBold JF (1971) The relationship between levels of exogenous hormones and the display of lordosis by the female rat. Horm Behav 2:287-297.
Huang Y-Y, Martin KC, Kandel ER (2000) Both protein kinase A and mitogen-activated protein kinase are required in the amygdala for the macromolecular synthesis-dependent late phase of long-term potentiation. J Neurosci 20:6317-6325[Abstract/Free Full Text].
Kawakami M, Kubo K (1971) Neuro-correlate of limbic-hypothalamic-pituitary-gonadal axis in the rat: change in limbic-hypothalamic unit activity induced by vaginal and electrical stimulation. Neuroendocrinology 7:65-89[ISI][Medline].
Keverne EB, Levy F, Guevara-Guzman R, Kendrick KM (1993) Influence of birth and maternal experience on olfactory bulb neurotransmitter release. Neuroscience 56:557-565[ISI][Medline].
Kornberg E, Erskine MS (1994) Effects of differential mating stimulation on the onset of prolactin surges in pseudopregnant rats. Psychoneuroendocrinology 19:357-371[Medline].
Krettek JE, Price JL (1978) Amygdaloid projections to subcortical structures within the basal forebrain and brainstem in the rat and cat. J Comp Neurol 178:225-254[ISI][Medline].
Lehmann ML, Erskine MS (2000) Unilateral NMDA infusions into the medial amygdala stimulate acute prolactin secretion. Soc Neurosci Abstr 26:213.
Maren S (1999) Long-term potentiation in the amygdala: a mechanism for emotional learning and memory. Trends Neurosci 22:561-567[ISI][Medline].
Marty S, Dusart I, Peschanski M (1991) Glial changes following an excitotoxic lesion in the CNS-I. Microglia/macrophages. Neuroscience 45:529-539[ISI][Medline].
Numan M, Numan MJ, English JB (1993) Excitotoxic amino acid injections into the medial amygdala facilitate maternal behavior in virgin female rats. Horm Behav 27:56-81[Medline].
Paxinos G, Watson C (1986) In: The rat brain in stereotaxic coordinates. San Diego: Academic.
Pfaus JM, Kleopoulos SP, Mobbs CV, Gibbs RB, Pfaff DW (1993) Sexual stimulation activates c-fos within estrogen-concentrating regions of the female rat forebrain. Brain Res 624:253-267[ISI][Medline].
Polston EK, Erskine MS (1995) Patterns of induction of the immediate-early genes c-fos and egr-1 in the female rat brain following differential amounts of mating stimulation. Neuroendocrinology 62:370-384[ISI][Medline].
Polston EK, Erskine MS (2001) Excitotoxic lesions of the medial amygdala differentially disrupt prolactin secretory responses in cycling and mated female rats. J Neuroendocrinol 13:13-21[Medline].
Polston EK, Centorino KM, Erskine MS (1998) Diurnal fluctuations in mating-induced oxytocinergic activity within the paraventricular and supraoptic nuclei do not influence prolactin secretion. Endocrinology 139:4849-4859[Abstract/Free Full Text].
Rowe DW, Erskine MS (1993) c-fos proto-oncogene activity induced by mating in the preoptic area, hypothalamus and amygdala in the female rat: role of afferent input via the pelvic nerve. Brain Res 621:25-34[ISI][Medline].
Schiess MC, Joels M, Shinnick-Gallagher P (1988) Estrogen priming affects active membrane properties of medial amygdala neurons. Brain Res 440:380-385[ISI][Medline].
Shindou T, Watanabe S, Yamamoto K, Nakanishi H (1993) NMDA receptor-dependent formation of long-term potentiation in the rat medial amygdala neuron in an in vitro slice preparation. Brain Res Bull 31:667-672[ISI][Medline].
Simerly RB (1995) Anatomical substrates of hypothalamic integration. In: The rat nervous system, Ed 2 (Paxinos G, ed), pp 353-376. San Diego: Academic.
Spies H, Niswender G (1971) Levels of prolactin, LH and FSH in the serum of intact and pelvic-neurectomized rats. Endocrinology 88:937-943[Medline].
Terkel J, Sawyer CH (1978) Male copulatory behavior triggers nightly prolactin surges resulting in successful pregnancy in rats. Horm Behav 11:304-309[Medline].
Terkel J, Witcher JA, Adler NT (1990) Evidence for "memory" of cervical stimulation for the promotion of pregnancy in rats. Horm Behav 24:40-49[Medline].
Tetel MJ, Getzinger MJ, Blaustein JD (1993) Fos expression in the rat brain following vaginal-cervical stimulation by mating and manual probing. J Neuroendocrinol 5:397-404[ISI][Medline].
Wang J, Swann JM (2000) Projections of the medial nucleus of the amygdala in female hamsters. Soc Neurosci Abstr 26:213.
Yamamoto T, Nagai T, Shimura T, Yasoshima Y (1998) Roles of chemical mediators in the taste system. Jpn J Pharmacol 76:325-348[Medline].

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