Adult Learning Deficits after Neonatal Exposure to D-Methamphetamine: Selective Effects on Spatial Navigation and Memory

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The Journal of Neuroscience, June 15, 2000, 20(12):4732-4739

Adult Learning Deficits after Neonatal Exposure to D-Methamphetamine: Selective Effects on Spatial Navigation and Memory
Charles V. Vorhees, Sandra L. Inman-Wood, LaRonda L. Morford, Harry W. Broening, Masao Fukumura, and Mary S. Moran
Division of Developmental Biology, Children's Hospital Research Foundation and Department of Pediatrics, University of Cincinnati, Cincinnati, Ohio 45229-3039

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The effects of neonatal D-methamphetamine (MA) treatment on cued and spatial learning and memory were investigated. MA wasadministered to neonatal rats on postnatal days 11-20. All groupsreceived four subcutaneous injections per day. Group MA40-4 received40 mg · kg¹ · d¹ of MA in four divided doses (10 mg/kg per injection). Group MA40-2received 40 mg · kg¹ · d¹ of MA in two divided (20 mg/kg/injection) and saline for theother two injections per day. Controls received saline for fourinjections per day. As adults, both MA groups showed no differencesin swimming ability in a straight swimming channel. The MA40-4group showed no differences in cued learning, but was impairedin hidden platform learning in the Morris water maze on acquisition.They also showed reduced memory performance on probe trials. Similartrends were seen on reversal learning and reversal probe trials.Reduced platform-size learning trials caused spatial learningimpairments to re-emerge in the MA40-4 group. The MA40-2 groupshowed no differences in straight channel swimming, but was slowerat finding the visible platform during cued learning. They werealso impaired during acquisition and memory trials in the Morrishidden platform maze. They showed a similar trend on reversallearning and memory trials, but were not different during reducedplatform-size learning trials. When the MA40-2 group's performanceon hidden platform learning and memory trials was adjusted forcued trial performance, the spatial learning deficits remained.Deficits of spatial learning and memory are a selective effectof neonatal methamphetamine treatment irrespective of other learningand performancevariables.

Key words: methamphetamine; development; spatial learning; Morris maze; rats; substituted amphetamines

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In some cities methamphetamine (MA) use exceeds that of cocaine, and nationally the prevalence of MA use is comparable tothat of crack cocaine (Johnston et al., 1998). Although thereis evidence that prenatal cocaine is associated with neurobehavioralimpairments (Richardson et al., 1996; Lester et al., 1998; Leechet al., 1999), there is no comparable information on MA. HumanMA studies have focused on perinatal complications (Oro and Dixon,1987; Little et al., 1988; Dixon and Bejar, 1989), with only onereport on possible neonatal neurobehavioral disturbances (Dixon,1989).

Earlier experimental investigations of developmental MA have found few effects, including no impairments of learning or memory(Martin, 1975; Martin et al., 1976, 1979, 1983; Sato and Fujiwara,1986; Weissman and Caldecott-Hazard, 1993). Recently, we reportedimpairments induced by developmental MA treatment on spatial learningand memory (Vorhees et al., 1994a, 1998, 1999), whereas sequentiallearning in a multiple-T water maze was spared. However, the selectivityof the effect for distal, as opposed to proximal, cue learningis not yetknown.

Spatial learning and memory in the Morris water maze (MWM) is linked to hippocampal function (Brandeis et al., 1989; Morris,1989, 1991; Morris et al., 1989, 1990a; McNamara and Skelton,1993). Disruption of hippocampal function by lesions, gene targeting,or pharmacological inhibition of glutamatergic NMDA receptorsimpairs MWM spatial learning and memory while sparing cued learning(Morris et al., 1982, 1986, 1990b; Silva et al., 1992; Morris,1993; Giese et al., 1998). Furthermore, it has recently been suggestedthat MWM-related stress may contribute to some of these impairments(Holscher, 1999). NMDA antagonist-induced spatial learning impairmentsin the MWM are reduced or eliminated by previous water maze experience(Bannerman et al., 1995; Saucler and Cain, 1995) as are thoseafter saturation of LTP (Otnaess et al., 1999). Whether theseeffects are the product of stress reduction or of transfer oftraining, in which animals learn general task characteristicsin the nonspatial MWM that facilitates later learning of the spatialversion, is notclear.

The present experiment sought to test the selectivity of the developmental effects of MA in three ways. (1) We compared learningin the MWM under cued versus spatial conditions to determine selectivity.(2) We conducted cued learning first so that positive transferof training or stress habituation effects in the cued versionwould reduce nonspecific group differences on the spatial versionof the task. (3) We added a component to the MWM that increasedthe spatial demands of the task by reducing platform size. Wereasoned that if the effect of MA is selective for distal cues,then cued learning using proximal cues should be unaffected. Furthermore,we reasoned that if stress or transfer of training effects contributeto MA-induced spatial learning impairments, then previous experiencein the cued MWM or a straight swimming channel should attenuatedifferences on spatial learning. Finally, we reasoned that ifMA-induced MWM effects are specific to spatial ability then increasingthe spatial demands of the task (by reducing platform size) shouldaffect MA-treated progeny selectively compared tocontrols.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Subjects
Nulliparous Sprague Dawley CD (Charles River, Raleigh, NC) rats were obtained and bred in house. The day a sperm plug wasobtained was considered embryonic day zero (E0). The day of parturition(P0) was considered E22. On the first day after birth (P1), offspringwere weighed and randomly culled to eight, balancing for gender.Litters with gender imbalances >5:3 or less than four progenywere excluded. Experimenters were blind to treatment group assignments.Litters were weaned on P28, and two males and two females wererandomly selected and retained from each litter. These offspringwere housed in same-gender pairs to P42 and individually thereafter.Offspring were weighed daily from P11-P21 and weeklythereafter.

Experimental procedures
There were three treatment groups with 15-18 litters in each group. There were two MA-treated groups because, in adult rats,MA administration in four doses, spaced every 2 hr, has been suggestedto be more neurotoxic than other patterns (Sonsalla and Heikkila,1988; Sonsalla et al., 1989, 1991; Bowyer et al., 1992, 1994).Because our previous developmental MA experiments had used twodoses per day, we compared equal daily doses given as either twoor four doses. Entire litters were treated with MA on P11-P20with four subcutaneous injections spaced every 2 hr (time 0, 2,4, and 6). This exposure period was based on previous experimentsin which these days were found to be sensitive to the inductionof MWM impairments compared to days P1-P10 (Vorhees et al., 1994a)or compared to prenatal exposure (Acuff-Smith et al., 1995). BothMA-treated groups received a total dose of 40 mg · kg¹ · d¹ (MA40). Group MA40-2 received 40 mg/kg each day in two divideddoses, such that they received doses of 20 mg/kg at time 0 and6 hr and saline at time 2 and 4 hr. The MA40-4 group receivedtheir 40 mg/kg each day in four divided doses, such that theyreceived doses of 10 mg/kg at time 0, 2, 4, and 6 hr; and salinecontrols received saline at time 0, 2, 4, and 6 hr. Drug treatmentconsisted of D-methamphetamine HCl (expressed as the free base;Sigma, St. Louis, MO) dissolved in saline in a dosing volume of3 ml/kg. During treatment, dams were removed from the litter andplaced in a separate cage. Offspring were then removed one ata time from the nest, weighed, injected, and returned to the cage.After all offspring were treated, the dam was returned to thehomecage.

Behavioral methods
Straight channel. Beginning between P50 and P56, each animal was administered four timed trials in a 15 × 150 cm straightwater channel with a wire ladder at one end. On each trial, therat was placed in the channel at the opposite end from the goal(facing away from it) and allowed to find the ladder and escape.These trials were used to determine swimming proficiency and motivationto escape before maze trials. Water temperature was 22 ± 1°C.
Morris maze. The Morris water maze was as described by Morris (Morris, 1981, 1984). Our tank diameter was 183 cm. The platformwas camouflaged by being constructed of transparent acrylic andset against the black background of the interior of the tank.We have demonstrated that this arrangement is effective; whenthe platform is shifted randomly between trials, rats performat chance levels (Vorhees and Minck, 1989). The platform was 10× 10 cm and was submerged 2 cm beneath thesurface.
Cued learning. The platform had a visible marker mounted above it constructed of Styrofoam (7 cm diameter, 5 cm in height)and covered with black paper sealed in transparent cellophane.The cue was affixed to the platform on a 20 cm rod held in positionby being fitted in a small hole in the center of the platform.The distance between the surface of the water and the bottom edgeof the cue was 12 cm. Black curtains were drawn closed aroundthe maze to minimize extramaze cues. Rats were administered fourconsecutive trials per day for 6 d. Trial time limit was 2 min,and the intertrial interval (ITI) was 30 sec spent on the platformplus an additional 15-20 sec in its home cage while the platformwas relocated. Start and platform positions were varied randomlyon everytrial.
Spatial learning $---$ acquisition. The goal was positioned in the middle of one quadrant and start positions were randomly distributedamong the four cardinal positions around the perimeter. Rats receivedfive trials per day for six consecutive days with the curtainsopen. Daily sessions consisted of four acquisition trials andone probe trial (the probe trial was the last of the day). Foracquisition trials, the time limit per trial was 2 min, and theITI was 30 sec. Animals not finding the platform within 2 minwere placed on the platform at the end of the trial. Probe trialslasted 1 min. Swim paths were recorded using a video-trackingsystem (San Diego Instruments, San Diego, CA). Data recorded onlearning trials included latency, path length, cumulative distancefrom the platform (Gallagher et al., 1993), and first bearingand for probe trials were time in the target quadrant, targetsite crossings, cumulative distance from the platform site, andfirst bearing. First bearing was determined based on animal'saverage vector for the first 13 cm traveled at the start of eachtrial.
Spatial learning $---$ reversal. On the next 6 d, the platform was moved to the opposite quadrant. Rats were administered trialsidentical to those for acquisition (four platform trials per dayand one probe trial). All procedures were identical toacquisition.
Spatial learning $---$ reduced platform. After reversal, 6 d of additional trials were administered with the platform remainingin the reversal position. As before, rats were given five trialsper day consisting of four platform trials and one probe trial.The only difference was that the platform was 25% (5 × 5 cm) ofthe size of the one used previously (i.e., 25 cm² rather than 100 cm²). All other procedures were identical to acquisition and reversal.For all MWM procedures, water temperature was ~22°C.

Statistical methods
Data were analyzed using ANOVAs (general linear model). For data that had repeated measure components, split-plot ANOVAs wereused with day and trial as within-factors. Gender was also treatedas a within-factor to control for litter effects (Holson and Pearce,1992). Because more than one subject of each gender was tested,data were averaged within gender. For split-plot analyses, sphericitytests for compound symmetry were used. Where significantly nonspherical,Greenhouse-Geisser adjusted F-ratios were used. Significant interactionswere further analyzed using simple-effect ANOVAs. A posteriorigroup comparisons were performed by the method of Duncan. Frequencydata (mortality) were analyzed by Fisher's test for uncorrelatedproportions.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Mortality and growth

Litter characteristics are shown in Table 1. The MA40-2 group had three nonsurviving litters, and the MA40-4 group had one.This trend was not significant. Both MA groups had significantlyincreased mortality compare to saline controls. Although the MA40-2group's mortality was higher than that of the MA40-4 group, thisdifference was not significant. A formal survival analysis couldnot be performed because mortality was too low, therefore, weanalyzed the mean age of death by ANOVA. As can be seen in Table1, there were no significant group differences for age at thetime of death.


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Table 1. Litter characteristics

Analyses of body weight during treatment showed significant treatment group, F_(2,42) = 16.0, p < 0.0001, treatment × day,F_(18,378) = 47.8, p < 0.0001, treatment × interval (i.e., timeof injection within a given day), F_(2,42) = 4.9, p < 0.05, andtreatment × day × interval effects, F_(18,378) = 5.6, p < 0.0001.Both MA treatment groups gained weight slower than saline controls.Simple-effect ANOVAs and a posteriori group comparisons showedthat both MA-treated groups weighed less than the saline groupbeginning on P13 and extending throughout the remainder of treatmenton P20. These effects are illustrated in males in Table 2. Femalesshowed a similar pattern.


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Table 2. Effects of neonatal methamphetamine on male offspring body weight expressed in grams ± SEM

Post-treatment body weight analyses showed no significant treatment group or treatment-related interactions when analyzedfrom P21 to P91. However, an inspection of the data showed thatthere was a catch-up phase to the recovery of body weight amongthe MA-treated groups, therefore, the data were reanalyzed intwo separate ANOVAs. The first of these was for the period fromthe end of treatment to the day before behavioral testing began(P21-P49). In this analysis, treatment group was significant,F_(2,42) = 6.4, p < 0.01. Simple effect ANOVAs on each day showedthat treatment group differences were present on days P21, 28,35, and 42, but not on P49 (Table 2). No treatment-related interactionswere significant. A posteriori group comparisons showed that bothMA groups weighed less than controls on days P21-P42, but thedifferences progressively diminished over successive weeks untilthey were no longer significant by P49. The second analysis wasfor body weights during behavioral testing (P56-P91). No treatmentgroup or treatment-related interactions were found (Table 2,males). Females showed a similar pattern (data notshown).

Straight channel swimming

A treatment group by sex by trial split-plot ANOVA on latencies in straight swimming trials showed no significant treatmentgroup or treatment-related interactions (Fig. 1A).

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Figure 1. A, Straight channel swimming times averaged (± SEM) across test trials and gender. The straight channel was 15 × 150 cm. B, Morris cued-platform maze latencies (means ± SEM) averaged across trials (4 trials per day for 6 d) and gender in MA-treated and control offspring. For these trials curtains were drawn around and over the maze, a flag was mounted above the platform, and the position of the platform was moved on every trial. Start positions also varied on every trial. *p < 0.05 compared to controls by a posteriori comparisons.

Morris maze

Cued learning
A treatment group by sex by day by trial split-plot ANOVA on latencies to find the platform on cued trials showed a significanttreatment group main effect, F_(2,42) = 3.8, p < 0.05. No significanttreatment-related interactions were found. A posteriori groupcomparisons showed that the MA40-2 group had significantly longerlatencies to reach the platform than the saline group (Fig. 1B).The MA40-4 group was not different from salinecontrols.

Spatial learning and memory $---$ acquisition
Treatment group by sex by day by trial split-plot ANOVAs on latency, path length, and cumulative distance from the platformall showed significant treatment group main effects, latency,F_(2,42) = 13.3, p < 0.0001, path length, F_(2,42) = 8.4, p < 0.001,and cumulative distance, F_(2,42) = 8.1, p < 0.01. A posterioricomparisons all showed the same pattern, i.e., that both MA groupswere impaired in reaching the hidden platform compared to salinecontrols (all comparisons p < 0.01; Fig. 2A-C). In addition, latencyand path length showed small but significant treatment × day ×trial interactions, latency F_(30,630) = 1.8, p < 0.05, and pathlength, F_(30,630) = 1.6, p < 0.05.

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Figure 2. Morris hidden-platform maze acquisition performance in MA-treated and control offspring. For hidden platform trials, curtains were opened revealing surrounding room cues, the platform was submerged, and it was placed in a fixed position on each trial. Start positions were varied on each trial. Panels are for latency (A), path length (B), cumulative distance (C), and latency adjusted for cued platform performance (D) to find the platform (means ± SEM) averaged across trials (4 trials per day for 6 d) and gender. *p < 0.05; **p < 0.01 compared with their respective controls by a posteriori comparisons.

Inspection of the learning curves revealed that on day 1, trial 1, all groups performed identically, i.e., they all had equivalentlatencies, path lengths, and distances from the platform and showedno preference for any one quadrant over another. On successivetrials, controls improved rapidly, whereas both MA groups improvedby only half as much as controls. By the end of the first fourtrials (day 1), controls were performing significantly betterthan either MA-treated group. On day 2, the groups showed a similarpattern, with the same relative differences prevailing. By day3, controls reached asymptotic performance and showed no significantfurther improvement through day 6 of acquisition. The MA-treatedgroups, by contrast, lagged behind controls on all measures ondays 3-6, but continued to improve slowly, thereby narrowing thegroup differences caused by the ceiling effect operating in controls.Despite narrowing the gap, however, the MA-treated groups neverperformed as well as controls on acquisition. This was most evidenton trial 1 of each day in that controls showed near optimum performance,whereas MA-treated animals showed overnight loss of accuracy andhad renewed difficulty finding the platform at the start of eachday.
Analyses of probe trial performance (Fig. 3) showed significant main effects of treatment group for both percentage of timein the target quadrant, F_(2,42) = 4.5, p < 0.02, and cumulativedistance from target, F_(2,42) = 3.8, p < 0.05. No significantinteractions between treatment group and other factors were found.A posteriori group comparisons of the main effect showed thatthe MA groups on both measures performed below saline controlsin that they spent less time in the target quadrant (Fig. 3A)and were further away from the target site than were saline controls(Fig. 3B).

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Figure 3. Morris hidden-platform maze probe trial performance (acquisition) in MA-treated and control offspring. Panels are for percent time in the target quadrant (A), cumulative distance from target (B), and first bearing to the target (C) (means ± SEM) averaged across probe trials and gender. *p < 0.05; **p < 0.01 compared to controls by a posteriori comparisons.

Although the treatment by trial interaction for percentage of time in the target quadrant was not significant, there was asignificant main effect of trial (p < 0.0001). This effect reflectedthe fact that all groups spent an increasing percentage of timein the target quadrant on probe trials across successive days.Controls spent 41% of their time in the target quadrant on thefirst probe trial (chance performance = 25%) given after the firstfour learning trials on day 1. This increased to 50% of theirtime in the target quadrant after their final probe trial givenafter the last learning trial on day 6 (24^th trial). By comparison, the MA40-4 group spent 34% of their timein the target quadrant on the first probe trial and 48% in thetarget quadrant on the last probe trial of acquisition. The MA40-2group performed similarly to the MA40-4 group. Hence, the magnitudeof the MA-induced effect on probe trials was ~17% on day 1 and4% on day 6, reflecting the fact that MA-treated animals continuedto learn after controls reached asymptotic performance (ceilingeffect), thereby narrowing the difference by the end of day6.
An analysis of platform site crossings was not significant, although a trend was observed in the treatment group × day interaction(p = 0.07). This interaction showed that the MA groups had fewerplatform site crossings on later probe trials than saline controls(data not shown). Probe trial performance was further analyzedfor first bearing shortly after the beginning of each trial. Thisis the animal's initial heading after it turns away from the walland begins to swim. The bearing is the angle of deviation betweena direct lay-line to the target and the animal's heading. Analysisof first bearing showed a significant main effect of treatmentgroup, F_(2,42) = 5.3, p < 0.01; no interactions with treatmentgroup were found. A posteriori group comparisons showed that bothMA groups' first bearing was significantly further away from adirect line to the target than was that of the saline controlgroup (Fig. 3C).

Spatial learning and memory $---$ reversal
Analyses of reversal learning for latency, path length, and cumulative distance from the platform were uniform in findingno significant treatment group or treatment-related interactions(Fig. 4A-C). For two of these analyses, however, an interactiontrend was observed. This was the treatment × trial trend for latency(p < 0.08), and cumulative distance (p < 0.06). For both of thesemeasures, the trend was that the MA groups, and especially theMA40-4 group, to have longer latencies and cumulative distancesfrom the target on later trials than did saline controls. Analysisof first bearing showed a significant treatment group main effect,F_(2,41) = 3.6, p < 0.05 and a significant treatment group by sexby trial interaction, F_(6,123) = 2.8, p < 0.02. A posteriori groupcomparisons for the main effect showed that both MA groups weremore off course in their initial headings than were saline controls(Fig. 4D). Further analyses of the interaction revealed that mostof the group differences were among the males. The average firstbearing change among male controls from trial 1 to trial 4 (averagedacross days) was 9.1°, whereas for the MA40-4 males it was 7.0°,and for the MA40-2 group it was $-$ 3.3°. This indicates that onreversal the MA40-2 males had the greatest difficulty learningthe new position of the platform. Females showed a similar butslightly smaller treatment effect.

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Figure 4. Morris hidden-platform maze reversal performance in MA-treated and control offspring. For reversal, the platform was moved to the opposite quadrant from that used during acquisition. Values are means ± SEM averaged across trials and gender. Panels are latency (A), path length (B), cumulative distance from the target (C), and first bearing to the target (D). *p < 0.05 compared to control by a posteriori group comparisons.

On reversal probe trials, no treatment group main effects were significant. However, several interactions with treatment wereobtained. Analysis of the percentage of time in the target quadrantshowed significant treatment × sex, F_(2,41) = 3.3, p < 0.05, andtreatment × day × sex effects, F_(10,205) = 1.9, p < 0.05; cumulativedistance from the target showed a significant treatment × sexeffect, F_(2,41) = 4.5, p < 0.02; and platform site crossings showeda significant treatment × sex × day effect, F_(10,205) = 1.9, p< 0.05. All of these interactions showed the same pattern, i.e.,that the MA groups had greater difficulty in giving up searchingwhere the platform used to be on acquisition and finding it inits new location (data not shown). The interactions with day andsex were the result of the male MA40-4 animals having more difficultyon days 1-3 than the MA40-2 males or the MA40-2 females or thanmale or femalecontrols.

Spatial learning and memory $---$ reduced target
Analyses of latency, path length, and cumulative distance from target showed significant treatment group main effects on allthree measures: latency, F_(2,42) = 8.2, p < 0.001, path length,F_(2,42) = 7.4, p < 0.01, and cumulative distance from platform,F_(2,42) = 6.8, p < 0.01. There were no treatment-related interactionsfound. A posteriori group comparisons showed that on all threemeasures, the MA40-4 group had greater difficulty finding thehidden platform than controls (p values < 0.01). However, theMA40-2 group's performance was not significantly different fromthat of saline controls (Fig. 5A-C).

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Figure 5. Morris hidden-platform maze reduced target size performance in MA-treated and control offspring. Panels are for latency (A), path length (B), and cumulative distance from the target (C). During reduced target trials the platform was in the same position as during reversal, but the platform size was reduced from 10 × 10 cm to 5 × 5 cm. Values are group means ± SEM averaged across trials and gender. *p < 0.05; **p < 0.01 compared to control by a posteriori group comparisons.

Analyses of probe trial performance on reduced target size trials showed no significant treatment group or treatment-relatedinteractions on percent time in the target quadrant (Fig. 6A),cumulative distance from platform (Fig. 6B), platform site crossings(data not shown), or first bearing (Fig. 6C). A trend was presentin the MA groups on first bearing performance, suggesting thatthe MA groups' initial heading was not as accurate as was thatof the control group.

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Figure 6. Morris hidden-platform reduced target size probe trial performance in MA-treated and control offspring. Values are group means ± SEM averaged across trials and gender. Panels are percentage of time in the target quadrant (A), cumulative distance from target (B), and first bearing (C). Note trend in first bearing in which both MA groups were further off course than controls.

Spatial learning in relation to cued learning

As noted above, the MA40-2 group was found to have longer latencies on cued platform learning than saline controls or thanthe MA40-4 group. This raised the possibility that the deficitsseen in the MA40-2 group on spatial navigation could be the resultof performance effects that caused this group to have longer latencieson cued platform trials. To investigate this possibility, we reanalyzedthe spatial learning data for acquisition, reversal, and reducedplatform phases by analyses of covariance (ANCOVA), using meanlatency on cued trials as the covariate. If cued trial performanceaccounted for the deficits in spatial learning, then the treatmenteffects of MA should disappear or be greatly diminished by sucha covariate analysis. On the other hand, if the cued trial performancedeficit was unrelated to performance on spatial learning, thenthe effects of MA on spatial measures should remain unchanged.All of the effects found on acquisition, reversal, and reducedplatform remained essentially unchanged using ANCOVA. The effectsof MA on spatial acquisition using adjusted means are illustratedin Figure 2D. As before, both the MA40-4 and MA40-2 groups tooksignificantly longer to reach the platform than controls, andthe effect in the MA40-2 group was only slightly altered by thecovariate adjustment for cued platform performance (compare Fig.2, A and D)

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We hypothesized that rats exposed to MA on P11-P20 and tested as adults would show spatial navigation deficits in the Morrismaze hidden platform procedure that would be selective for spatiallearning and memory compared to cued learning. This predictionwas confirmed in that the MA40-4 group showed no impairment incued learning but was impaired on acquisition, reversal, and reducedtarget in spatial learning. This group also showed impaired memoryon probe trials conducted during acquisition and reversal, however,not during reduced target trials. The MA40-2 group, on the otherhand, showed a deficit in cued and spatial learning. However,when the latter was analyzed with cued performance as a covariateon spatial MWM performance, the cued MWM differences did not accountfor the MA-induced spatial learning difference. This indicatesthat the effect of the MA40-2 treatment regimen on spatial learningis not caused by the proximal cue learning difference seen inthisgroup.

We further hypothesized that if MA-induced spatial learning impairment were the result of stress or transfer of training effects,then previous testing and handling should eliminate or reducethese differences. However, the spatial learning and memory impairmentsseen here were similar to those we have reported previously withoutprevious cued learning trials in the MWM (Vorhees et al., 1998).They were also similar to those seen (Vorhees et al., 1999) withprevious experience in a multiple-T swimming maze with very differenttask requirements (Vorhees et al., 1994a). In addition, both MA-treatedand saline-treated groups in the present study were extensivelyhandled during the neonatal period (weighing and injection fourtimes per day). Early handling is known to reduce later responsesto a stressful situation (Meaney et al., 1988). This fact, whentaken together with the straight channel and cued MWM experience,indicates that it is unlikely that the effects of developmentalMA treatment are accounted for by stress-related changes in physiologicalresponses or effects derived from positive transfer oftraining.

Reversal trials, in which the hidden platform was moved to the opposite quadrant, revealed no significant group differenceson learning trials except on first bearing. It may be that transferof training was beneficial in this context, allowing all groupsto learn the new location easier than they did during acquisition.Regardless of the basis for this change, the latency and pathlength measures indicate that reversal was not as difficult forthe animals to learn as was acquisition, and this may explainwhy these measures showed no group differences on reversal. Nonetheless,the first bearing findings revealed that the MA groups did notknow the location of the platform as well as controls becausetheir bearing was significantly further from the lay-line to thetarget site than was that of controls. This effect was not aslarge as that seen on first bearing during acquisition, againsuggesting that reversal was not as difficult as acquisition.It is also noteworthy that inspection of reversal first bearingpatterns showed that the animals never fully corrected their firstbearing to the new platform location, but rather started eachtrial heading for the position of the platform on acquisitionand then abruptly changed course to the new position of the platform.Despite the apparent inefficiency of this pattern, it persistedthrough both the reversal and reduced-platform trials, and itdid not prevent animals from improving their performance on eachof these successive phases oftesting.

We also predicted that increasing the spatial demands of the MWM would differentially affect the MA-treated progeny. Thisprediction was supported in that the MA40-4 group showed impairedlearning when the platform size was reduced, however, the MA40-2group did not. This suggests that the MA40-4 treatment regimenis more deleterious than the MA40-2 regimen. However, becausethis difference was only revealed under the more demanding requirementsof locating a platform only 25% of the size of the original goal,this difference between the two dosing schedules appears to besubtle.

The MA40-4 group failed to show a significant impairment on the reduced platform probe trials. The lack of probe trial differencescould be attributable to a lack of effect of MA on memory, butthis seems unlikely given the probe trial deficits seen in thisgroup on acquisition and to a lesser extent on reversal. It seemsmore likely that this was the result of the fact that the platformwas in the same position on reduced platform trials as on reversaltrials. Because of this sequence, the animals had 10 consecutivedays of learning to the same quadrant position. Reduced targetlearning would be expected to affect platform localization, i.e.,finding the platform on learning trials, but would not be expectedto affect the less precise measure of time in the target quadrantgiven that the animals had already learned its general locationfrom the preceding reversal trials. This is what was seen, demonstratingthat with extensive training to the same target position, probetrials become less revealing of memoryimpairments.

It is unlikely that the effects observed in MA-treated animals can be accounted for in terms of undernutrition. First, theundernutrition caused by early MA treatment is transient and showscomplete recovery. There are no residual weight reductions inthe MA progeny by the time of testing. Second, MWM has been evaluatedextensively in rats given severe protein-calorie malnutritionduring the neonatal period (Goodlett et al., 1986; Campbell andBedi, 1989; Bedi, 1992; Levitsky and Strupp, 1995; Strupp andLevitsky, 1995). Treatments causing more prolonged and more severeweight changes than those induced herein have consistently shownthat postnatal undernutrition (and growth retardation) have noeffect on spatial learning and memory in the MWM. Third, the effectsof MA treatment were selective for spatial learning and memorywithout affecting a variety of other behaviors (Vorhees et al.,1994a,b). Such selectivity is in contrast to the kind of generalizedimpairment caused by malnutrition. In addition, the impairmentin the MA40-4 group was more severe than that seen in the MA40-2group, even though both groups received the same number of dailyinjections, had the same total daily MA dose, and showed the samebody weight changes during treatment. This demonstrates that thecognitive effects of MA are dissociated from nonspecific nutritionaleffects. Overall, the data in this experiment reveal that differencesin learning and memory are both specific to early MA treatmentand selective for impairing spatialnavigation.

Offspring were separated from their dams four times per day on days P11-P20, and this produces some disruption of maternal-pupinteractions. Whereas the exact effect of this on later spatiallearning is not known, the preponderance of existing evidencesuggests that this manipulation is most similar to that seen afterearly handling. Early handling, which also involves maternal-pupdisruption, has been shown to improve later spatial learning andmemory in the Morris maze (Meaney et al., 1988; Holscher, 1999).Although the effect of early handling and injecting was not measuredin this experiment per se, all groups were matched on this variable,therefore, this factor would not be expected to contribute togroup differences. All groups were individually housed for 8 dbefore to the start of testing, and individual housing has beenshown to impair Morris maze performance (Wade and Maier, 1986).However, housing conditions were identical for all groups, therefore,housing would not be expected to affect the present findings unlesshousing were hypothesized to differentially affect MA-treated,but not control, animals. Moreover, the pretraining experienceof the animals in straight channel and the cued platform mazetrials would be expected to diminish group differences, yet MA-inducedspatial learning and memory impairments not only remained evident,they were as large as in other experiments without these previousexperiences.

Recently, it has been shown that pretraining eliminates Morris maze learning and memory impairments induced by saturationof hippocampal LTP (Otnaess et al., 1999) or by administrationof NMDA antagonists that block LTP (Bannerman et al., 1995; Sauclerand Cain, 1995). For example, acute treatment with the NMDA antagonistAP-5 in water maze-naïve rats results in significant (20-33%)deficits on probe trial performance (probe trials 2 and 3, respectively).However, this same treatment to water maze pretrained rats resultsin no significant deficits in spatial memory (10 and 13% differenceson probe trials 2 and 3, respectively) (Bannerman et al., 1995).Rats treated neonatally with MA showed probe trial deficits ofup to 17% after pretraining in a similar maze. Hence, the developmentalMA-induced memory deficits are larger than those induced by acuteAP-5 treatment after water maze pretraining or after LTP saturationby high-frequency stimulation (Otnaess et al., 1999).

The spatial learning effects caused by developmental MA treatment (postnatal days 11-20) have now been shown to occur in threedifferent strains of rats, in both males and females, in Morrismazes of different dimensions and differing procedures, with andwithout previous experience in other tasks, with previous experiencein related and unrelated tasks, and in the absence of impairmentsin swimming ability. This convergence suggests that the developmentaleffects of methamphetamine treatment on spatial learning are reliable.This may be a cause of concern for humans exposed to this drugduring stages of early braindevelopment.

  FOOTNOTES

Received Oct. 8, 1999; revised March 29, 2000; accepted April 4, 2000.

This work was supported by National Institutes of Health research Grant DA06733 (C.V.V.), training Grant ES07051 (H.W.B. andS.L.I-W.), and individual National Research Service Award GrantDA05740 (H.W.B.).
Correspondence should be addressed to Dr. Charles V. Vorhees, Division of Developmental Biology, Children's Hospital ResearchFoundation, 3333 Burnet Avenue, Cincinnati, OH 45229-3039. E-mail:charles.vorhees{at}chmcc.org.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Acuff-Smith KD, Schilling MA, Fisher JE, Vorhees CV (1995) Stage-specific effects of prenatal D-methamphetamine exposure on behavioral and eye development in rats. Neurotoxicol Teratol 18:199-215.
Bannerman DM, Good MA, Butcher SP, Ramsay M, Morris RGM (1995) Distinct components of spatial learning revealed by prior training and NMDA receptor blockade. Nature 378:182-186[Medline].
Bedi KS (1992) Spatial learning ability of rats undernourished during early postnatal life. Physiol Behav 51:1001-1007[Medline].
Bowyer JF, Tank AW, Newport GD, Slikker Jr W, Ali SF, Holson RR (1992) The influence of environmental temperature on the transient effects of methamphetamine on dopamine levels and dopamine release in rat striatum. J Pharmacol Exp Ther 260:817-824[Abstract/Free Full Text].
Bowyer JF, Davies DL, Schmued L, Broening HW, Newport GD, Slikker Jr W, Holson RR (1994) Further studies of the role of hyperthermia in methamphetamine neurotoxicity. J Pharmacol Exp Ther 268:1571-1580[Abstract/Free Full Text].
Brandeis R, Brandys Y, Yehuda S (1989) The use of the Morris water maze in the study of memory and learning. Int J Neurosci 48:29-69[Web of Science][Medline].
Campbell LF, Bedi KS (1989) The effects of undernutrition during early life on spatial learning. Physiol Behav 45:883-890[Medline].
Dixon SD (1989) Effects of transplacental exposure to cocaine and methamphetamine on the neonate. West J Med 150:436-442[Web of Science][Medline].
Dixon SD, Bejar R (1989) Echoencephalographic findings in neonates associated with maternal cocaine and methamphetamine use: incidence and clinical correlates. J Pediatr 115:770-778[Web of Science][Medline].
Gallagher M, Burwell R, Burchinal M (1993) Severity of spatial learning impairment in aging: development of a learning index for performance in the Morris water maze. Behav Neurosci 107:618-626[Web of Science][Medline].
Giese KP, Fedorov NB, Filipkowski RK, Silva AJ (1998) Autophosphorylation at Thr²⁸⁶ of the $alpha$ calcium-calmodulin kinase II in LTP and learning. Science 279:870-873[Abstract/Free Full Text].
Goodlett CR, Valentineo ML, Morgane PJ, Resnick O (1986) Spatial cue utilization in chronically malnourished rats: task specific learning deficits. Dev Psychobiol 19:1-15[Web of Science][Medline].
Holscher C (1999) Stress impairs performance in spatial watermaze learning tasks. Behav Brain Res 100:225-235[Web of Science][Medline].
Holson RR, Pearce B (1992) Principles and pitfalls in the analysis of prenatal treatment effects in multiparous species. Neurotoxicol Teratol 14:221-228[Web of Science][Medline].
Johnston LD, O'Malley PM, Bachman JG (1998) National survey results on drug use. In: The monitoring the future study, 1975-1997, pp 1-433 Rockville, MD: National Institute on Drug Abuse.
Leech SL, Richardson GA, Goldschmidt L, Day NL (1999) Prenatal substance exposure: Effects on attention and impulsivity of 6 year olds. Neurotoxicol Teratol 21:109-118[Web of Science][Medline].
Lester BM, LaGasse LL, Seifer R (1998) Cocaine exposure and children: the meaning of subtle effects. Science 282:633-634[Free Full Text].
Levitsky DA, Strupp BJ (1995) Malnutrition and the brain: changing concepts and changing concerns. J Nutr 125:2212S-2220S.
Little BB, Snell LM, Gilstrap LC (1988) Methamphetamine abuse during pregnancy: outcome and fetal effects. Obstet Gynecol 72:541-544[Web of Science][Medline].
Martin JC (1975) Effects on offspring of chronic maternal methamphetamine exposure. Dev Psychobiol 8:397-404[Web of Science][Medline].
Martin JC, Martin DC, Radow B, Sigman G (1976) Growth, development and activity in rat offspring following maternal drug exposure. Exp Aging Res 2:235-251[Medline].
Martin JC, Martin DC, Radow B, Day HE (1979) Life span and pathology in offspring following nicotine and methamphetamine exposure. Exp Aging Res 5:509-522[Web of Science][Medline].
Martin JC, Martin DC, Sigman G, Day-Pfeiffer H (1983) Saccharin preferences in food deprived aging rats are altered as a function of perinatal drug exposure. Physiol Behav 30:853-858[Medline].
McNamara RK, Skelton RW (1993) The neuropharmacological and neurochemical basis of place learning in the Morris water maze. Brain Res Rev 18:33-49[Medline].
Meaney MJ, Aitken DH, van Berkel C, Bhatnager S, Sapolsky RM (1988) Effect of neonatal handling on age-related impairments associated with the hippocampus. Science 239:766-768[Abstract/Free Full Text].
Morris R (1984) Developments of a water-maze procedure for studying spatial learning in the rat. J Neurosci Methods 11:47-60[Web of Science][Medline].
Morris RGM (1981) Spatial localization does not require the presence of local cues. Learn Motiv 12:239-260[Web of Science].
Morris RGM (1989) Synaptic plasticity and learning: selective impairment of learning in rats and blockade of long-term potentiation in vivo by the N-methyl-D-aspartate receptor antagonist AP5. J Neurosci 9:3040-3057[Abstract].
Morris RGM (1991) Distinctive computations and relevant associative processes: Hippocampal role in processing, retrieval, but not storage of allocentric spatial memory. Hippocampus 1:287-290[Medline].
Morris RGM (1993) An attempt to dissociate "spatial-mapping" and "working-memory" theories of hippocampal function. In: Neurobiology of the hippocampus (Seifert W, ed), pp 405-432. New York: Academic.
Morris RGM, Garrud P, Rawlins JNP, O'Keefe J (1982) Place navigation impaired in rats with hippocampal lesions. Nature 297:681-683[Medline].
Morris RGM, Hagan JJ, Rawlins JNP (1986) Allocentric spatial learning by hippocampectomized rats: a further test of the "spatial mapping" and "working memory" theories of hippocampal function. Q J Exp Psychol 38B:365-395.
Morris RGM, Halliwell RF, Bowery N (1989) Synaptic plasticity and learning II: do different kinds of plasticity underlie different kinds of learning? Neuropsychologia 27:41-59[Web of Science][Medline].
Morris RGM, Davis S, Butcher SP (1990a) Hippocampal synaptic plasticity and NMDA receptors: a role in information storage? Philos Trans R Soc Lond B Biol Sci 329:187-204[Web of Science][Medline].
Morris RGM, Schenk F, Tweedie F, Jarrard LE (1990b) Ibotenate lesions of hippocampus and/or subiculum: dissociating components of allocentral spatial learning. Eur J Neurosci 2:1016-1028[Web of Science][Medline].
Oro AS, Dixon SD (1987) Perinatal cocaine and methamphetamine exposure: maternal and neonatal correlates. J Pediatr 111:571-578[Web of Science][Medline].
Otnaess MK, Brun VH, Moser M-B, Moser EI (1999) Pretraining prevents spatial learning impairment after saturation of hippocampal long-term potentiation. J Neurosci 19(RC49):1-5[Abstract/Free Full Text].
Richardson GA, Conroy ML, Day NL (1996) Prenatal cocaine exposure: effects on the development of school-age children. Neurotoxicol Teratol 18:627-634[Web of Science][Medline].
Sato M, Fujiwara Y (1986) Behavioral and neurochemical changes in pups prenatally exposed to methamphetamine. Brain Dev 8:390-396[Web of Science][Medline].
Saucler D, Cain DP (1995) Spatial learning without NMDA receptor-dependent long-term potentiation. Nature 378:186-189[Medline].
Silva AJ, Paylor R, Wehner JM, Tonegawa S (1992) Impaired spatial learning in $alpha$ -calcium-calmodulin kinase II mutant mice. Science 257:206-211[Abstract/Free Full Text].
Sonsalla PK, Heikkila RE (1988) Neurotoxic effects of 1-methyl-4-phenyl-1,2,3,6-tetrahydropryidine (MPTP) and methamphetamine in several strains of mice. Prog Neuropsychopharmacol Biol Psychiatr 12:345-354[Medline].
Sonsalla PK, Nicklas WJ, Heikkila RE (1989) Role for excitatory amino acids in methamphetamine-induced nigrostriatal dopaminergic toxicity. Science 243:398-400[Abstract/Free Full Text].
Sonsalla PK, Riordan DE, Heikkila RE (1991) Competitive and noncompetitive antagonists at N-methyl-D-aspartate receptors protect against methamphetamine-induced dopaminergic damage in mice. J Pharmacol Exp Ther 256:506-512[Abstract/Free Full Text].
Strupp BJ, Levitsky DA (1995) Enduring cognitive effects of early malnutrition: a theoretical reappraisal. J Nutr 125:2221S-2232S.
Vorhees CV, Minck DR (1989) Long-term effects of prenatal phenytoin exposure on offspring behavior in rats. Neurotoxicol Teratol 11:295-305[Web of Science][Medline].
Vorhees CV, Ahrens KG, Acuff-Smith KD, Schilling MA, Fisher JE (1994a) Methamphetamine exposure during early postnatal development in rats: I. Acoustic startle augmentation and spatial learning deficits. Psychopharmacology 114:392-401[Medline].
Vorhees CV, Ahrens KG, Acuff-Smith KD, Schilling MA, Fisher JE (1994b) Methamphetamine exposure during early postnatal development in rats: II. Hypoactivity and altered responses to pharmacological challenge. Psychopharmacology 114:402-408[Medline].
Vorhees CV, Reed TM, Schilling MA, Fisher JE, Moran MS, Cappon GD, Nebert DW (1998) CYP2D1 polymorphism in methamphetamine-treated rats: genetic differences in neonatal mortality and a comparison of spatial learning and acoustic startle. Neurotoxicol Teratol 20:265-273[Web of Science][Medline].
Vorhees CV, Morford LL, Inman SL, Reed TM, Schilling MA, Cappon GD, Moran MS, Nebert DW (1999) Genetic differences in spatial learning between Dark Agouti and Sprague-Dawley strains: possible correlation with CYP2D2 polymorphism in rats treated neonatally with methamphetamine. Pharmacogenetics 9:171-181[Web of Science][Medline].
Wade SE, Maier SF (1986) Effects of individual housing and stressor exposure upon the acquisition of watermaze escape. Learn Motiv 17:287-310[Web of Science].
Weissman AD, Caldecott-Hazard S (1993) In utero methamphetamine effects: I. Behavior and monoamine uptake sites in adult offspring. Synapse 13:241-250[Web of Science][Medline].

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