Comparing memory-forming capabilities between laboratory-reared and wild Lymnaea: learning in the wild, a heritable component of snail memory

doi:10.1242/jeb.020172

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First published online August 22, 2008
Journal of Experimental Biology 211, 2807-2816 (2008)
Published by The Company of Biologists 2008
doi: 10.1242/jeb.020172

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Comparing memory-forming capabilities between laboratory-reared and wild Lymnaea: learning in the wild, a heritable component of snail memory

Michael V. Orr, Karla Hittel and Ken Lukowiak^*

Hotchkiss Brain Institute, Faculty of Medicine, University of Calgary, Calgary, Alberta, Canada, T2N 4N1

^* Author for correspondence (e-mail: lukowiak{at}ucalgary.ca)

Accepted 19 June 2008

Summary

TOP
Summary
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
References

We set out to determine whether the ability to form long-termmemory (LTM) is influenced by laboratory rearing. We investigatedthe ability of four populations of Lymnaea stagnalis to formLTM following operant conditioning both in the freely behavinganimal and at the electrophysiological level in a neuron, RPeD1,which is a necessary site for LTM. We hypothesized that laboratoryrearing results in a decreased ability to form LTM because rearingdoes not occur in an `enriched environment'. Of the four populationsexamined, two were collected in the wild and two were reared inthe laboratory – specifically, (1) wild Dutch snails;(2) their laboratory-reared offspring; (3) wild Southern Albertasnails (Belly); and (4) their laboratory-reared offspring. Wefound that Belly snails had an enhanced capability of formingLTM compared with Dutch laboratory-reared snails. That is, theBelly snails, which are much darker in colour than laboratory-reared snails(i.e. blonds), were `smarter'. However, when we tested the offspringof Belly snails reared in the laboratory we found that thesesnails still had the enhanced ability to form LTM, even thoughthey were now just as `blond' as their laboratory-reared Dutchcousins. Finally, we collected wild Dutch snails, which arealso dark, and found that their ability to form LTM was not differentto that of their laboratory-reared offspring. Thus, our hypothesis wasnot proved. Rather, we now hypothesize that there are straindifferences between the Belly and Dutch snails, irrespectiveof whether they are reared in the wild or in the laboratory.

Key words: Lymnaea, long-term memory, wild, electrophysiology, operant conditioning, environmental enrichment

INTRODUCTION

TOP
Summary
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
References

Despite a rich history of exploration, investigating how genetic predispositionversus environmental experience affects the ability to learn andform memory remains poorly understood. The positive effectsof `environmental enrichment' on brain function (van Praag etal., 2000), including improved memory formation (Berardi etal., 2007; Fischer et al., 2007; Harburger et al., 2007; Rosenzweiget al., 1993) as well as neuroanatomical, neurochemical andbehavioral consequences (Renner and Rosenzweig, 1987; Rosenzweig,1979), have been described for a wide range of species and sensorysystems. Evidence exists in vertebrates and invertebrates demonstratingan innate `hardwired' component to cognitive processing as wellas a parallel network that is adaptable for associative learningprocesses (Kobayakawa et al., 2007; Suh et al., 2004; Tobinet al., 2002). The interaction between `hardwired' behaviorsand how they are modified by experience is unclear.

Few model systems exist where the: (1) essential neural circuitmediating a behavior is known; (2) behavior is easily observable,interesting and tractable; and (3) opportunity exists to investigateboth laboratory-reared and naturally occurring wild populations.One system that meets these criteria is aerial respiratory behaviorin the pond snail Lymnaea stagnalis. In Lymnaea, the aerialrespiratory behavior is driven by a three-neuron central patterngenerator (CPG) whose sufficiency and necessity has been documented(Syed et al., 1990; Syed et al., 1992). The behavior exhibitsassociative learning and long-term memory (LTM) (Lukowiak etal., 1998; Lukowiak et al., 1996; Lukowiak et al., 2003b; Martenset al., 2007a; Martens et al., 2007b; Parvez et al., 2006b).Moreover, not only have electrophysiological correlates of memoryformation been demonstrated in a single neuron, RPeD1, thatis a member of the three-neuron CPG (McComb et al., 2005; Spenceret al., 2002; Spencer et al., 1999) but it has also been shownthat this neuron is a necessary site for formation of LTM, reconsolidation,extinction and forgetting (Sangha et al., 2003a; Sangha et al.,2005; Sangha et al., 2003b; Scheibenstock et al., 2002). Finally,Lymnaea is a cosmopolitan species that can be easily collectedin the wild and whose progeny can then be maintained in the laboratoryfor many generations. The snails collected in the wild (eitherin The Netherlands or Southern Alberta, Canada) are much darkerin colour than snails reared in the laboratory (Fig. 1). Wetherefore referred to the laboratory-reared snails as `blonds'.

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Fig. 1. (A) Laboratory-reared snail performing aerial-respiratory behavior at the air–water interface. Note that the markings on the dorsal shell are utilized in the laboratory for identifications purposes. (B) A wild Lymnaea stagnalis aerial-respiring in its native habitat. The bars indicate that the wild snail is approximately twice the size of the laboratory snail.

We performed a series of pilot experiments using locally obtained Lymnaea(i.e. Lymnaea from the Belly river drainage in Southern Alberta;see Materials and methods) and found to our amazement that thesesnails had a significantly enhanced ability to form LTM comparedwith our laboratory-reared `blond' snails. Our `blond' snailsare descended from snails that were originally collected inUtrecht Province in The Netherlands in the 1950s. Thus, we hypothesizedthat rearing snails in the laboratory not only resulted in theircolour lightening but also resulted in snails that had a diminishedcapacity to form LTM. Possibly, this cognitive disability arose becausethey were reared in an `unenriched environment' compared withsnails reared in the wild. We first tested this hypothesis by`enriching' the laboratory environment by introducing the presenceof a sympatric predator, crayfish to the laboratory-reared snails.We demonstrated that our laboratory-reared Lymnaea maintainedthe ability to detect and respond to the scent of a crayfishwith multiple predator-avoidance behaviors and changes in theelectrophysiological properties of RPeD1 (Orr et al., 2007

).Thus, this instinctual behavior was maintained in these laboratory-rearedsnails. We further demonstrated that this predator-detectionenhanced formation of LTM both behaviorally and electrophysiologicallyin RPeD1 (Orr and Lukowiak, 2008

Here, we test the hypothesis that laboratory rearing reducesthe capability of snails to form LTM following operant conditioningof aerial respiratory behavior. However, the data presentedhere are inconsistent with this hypothesis and caused us toformulate another set of hypotheses: first, laboratory rearingdoes not alter the ability of snails to form memory and, second,there are significant strain differences in memory capabilitybetween Dutch and Belly snails, which are stable regardlessof rearing conditions. That is, there is a heritable componentto this memory ability.

MATERIALS AND METHODS

TOP
Summary
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
References

Snails
The great pond snail Lymnaea stagnalis L. is a cosmopolitan speciesfound in temperate regions worldwide. In this investigation,we utilized four different populations of snails, two wild andtwo laboratory reared. We examined two geographically distinctwild populations of snails: first, wild snails collected frompolders near Utrecht in Amsterdam (wild Dutch; latitude: 52°16'N; longitude: 5°17' E; elevation: –1 m) and, second,wild snails collected from six seasonally isolated ponds inthe Belly river drainage in Southern Alberta, Canada (termedBelly snails; latitude: 49°31' N; longitude: 113°16'W; elevation: 961 m). Lymnaea stagnalis in Alberta were identifiedby using previously established criteria (Clarke, 1981; Clifford,1991) as well as descriptions from other published works ofsnails in a similar locality (Boag and Pearlstone, 1979; Boaget al., 1984). In order to ensure further that both the Albertanand Dutch snails were in fact the same species, cross-breedingexperiments between wild Albertan and Dutch snails were conductedto ensure that the progeny themselves produced viable offspring.As this was the case, we concluded that these were in fact thesame species. A representative specimen of each population isshown in Fig. 1.

We also collected egg sacs from Belly snails and reared themin separate aquaria in the snail facility at the Universityof Calgary until adulthood (referred to as Belly F1s). Finallywe also used laboratory-reared snails, which have been maintainedin Calgary since 1988 (a gift of Vrije Universeit, Amsterdam,The Netherlands). The original Amsterdam colony was establishedin the mid-1950s from snails collected in a polder near Utrecht.Cohorts of 10–14 adult snails with a shell length of 30–55mm for wild snails and 21–26 mm for F1 snails were labeledand maintained within home eumoxic aquaria (P_O2>9975 Pa)at room temperature ( ${approx}$ 20°C) until training.

Breathing observations
To ensure that aerial respiratory behavior between these populationswas directly comparable, we measured several aerial respiratoryparameters of naive snails from each population, which is alsothe same hypoxic challenge the snails experience during operantconditioning (see below). Briefly, snails were placed in 500ml of room temperature hypoxic pond water (P_O2<931 Pa) andthe time, duration and number of pneumostome (the respiratoryorifice) openings were noted during a 0.5 h period. From thesemeasurements, the number of openings, total breathing time andaverage breathing time for the different populations of snailswere calculated.

Operant conditioning
Snails were removed from their home aquaria and placed intoa 1-liter beaker containing 500 ml of hypoxic pondwater (PW).PW is made hypoxic by bubbling N₂ gas through the water for20 min before introducing the snails. The animals are givena 10 min acclimatization period before the 30 min training session.By subjecting snails to a hypoxic challenge, the animals increasetheir rate of aerial respiration (Lukowiak et al., 1998; Lukowiaket al., 1996). The animals are operantly conditioned by applyinga gentle tactile stimulus with a sharpened wooden applicatorto their pneumostome as the pneumostome begins to open. Thestimulus is strong enough to cause the snails to close the pneumostomeyet gentle enough that the snails do not perform the full body-withdrawalresponse. The contingent stimulation is given during both the trainingsession (TS) and during the test for memory (TM). This pneumostome-closureresponse is a graded part of the whole-snail escape response(Inoue et al., 1996). Every time the snail opens its pneumostomeand receives the stimulus during the training period, the timeis recorded for future use in yoked control experiments. Yokedcontrols (see below) were performed for all behavioral and electrophysiologicalexperiments. All behavioral experiments were run concurrentlyand were performed `blind', where the person performing the trainingparadigm was unaware of the status of the cohort being tested. Becausethere is an obvious difference in the size of wild and laboratory-rearedsnails, the `blind' testers were able to discriminate betweenwild and laboratory-reared snails; however, the testers wereunable to discriminate between the origin of either the wildAlberta or Dutch snails as well as either of the laboratory-rearedcohorts during training.

The operant conditioning procedure we utilized consists of asingle 30 min TS, after which the snails are returned to theirhome aquaria. The snails are then tested for memory (TM; i.e.a `savings-test') using a test similar to that of the trainingsession, or the group is then subject to electrophysiologicaltesting in lieu of the TM. The time of the TM or recording isindicated as time after the TS.

Yoked control experiments
During the training period, yoked control snails received exactlythe same number and sequence of stimuli as those of the operantconditioning group; however, the stimuli were not contingentupon their pneumostome opening. However, these yoked controlsnails did receive a contingent stimulus to the pneumostomeduring the savings test session (TM). Snails that received yoked trainingwere treated in an identical manner as that outlined in the`yoked operant conditioning procedure' used previously (Lukowiaket al., 2000; Lukowiak et al., 1998; Lukowiak et al., 1996; Lukowiaket al., 2003c).

Semi-intact preparation and electrophysiological recordings
The Lymnaea semi-intact preparation used here is similar tothose used previously (Inoue et al., 2001; McComb et al., 2003;McComb et al., 2005; Spencer et al., 2002; Spencer et al., 1999)except that only the penis was removed, the head–foot complexand buccal mass being left fully intact (Orr et al., 2007). Preparationswere pinned down in individual recording dishes with their dorsal sidesuppermost. The central ring ganglia (CNS) were pinned to thedish directly through the foot musculature, with the dorsal-sideup. The outer sheath surrounding the CNS was removed using fineforceps. Enzymatic softening of the sheath was not used in anyof our recordings. Standard electrophysiological techniqueswere used, as described in the above-referenced reports. Intracellularrecordings were obtained using sharp glass microelectrodes filledwith saturated K₂SO₄ solution. The tip resistances of the microelectrodesused for recordings ranged from 20 to 30 M ${Omega}$ . Intracellular signalswere amplified by means of a NeuroData amplifier and displayedsimultaneously on a Macintosh PowerLab/-4SP (AD instruments,Colorado Springs, CO, USA) and a Hitachi oscilloscope. Recordingswere analyzed and stored using the PowerLab software. Completedetails have been published elsewhere (McComb et al., 2003; McCombet al., 2005). Once RPeD1 was successfully impaled, the cellswere given a minimum stabilization period of 10 min after whicha 600 s trace was used for analysis. Nine electrophysiologicalcharacteristics were measured for each recording and are asfollows: (1) total number of action potentials (APs) per 600s, (2) total frequency, (3) resting membrane potential, (4)number of APs per burst, (5) burst frequency, (6) after hyperpolarizationof the first AP in each burst, (7) average AP peak of each burst,(8) burst duration and (9) the number of bursts per 600 s.

Operational definition of learning and memory
As described previously (Lukowiak et al., 2000; Lukowiak etal., 1998; Lukowiak et al., 1996) for the single 0.5 h trainingsession, memory is defined as a significant reduction in thenumber of attempted pneumostome openings in the memory testsession (TM) compared with the training session (TS). That is,TM must be significantly less than TS, and the TM of the correspondingyoked cohort must not be significantly different from the TS.

Snail grades
Another measure of memory that we have previously used is toassign a `mark' to each snail whether they performed extremelywell or very poor in TM. That is, individual snails were givengrades based upon their performance (Lukowiak et al., 2003c; Roseneggeret al., 2004). Briefly, an `A' grade was given if there wasgreater than a 50% reduction in the number of attempted pneumostomeopenings in the TM compared with the TS, whereas a `B' gradewas given for a 35–49% reduction; a `C' grade for a 20–34%reduction and an `F' grade was given if the decrease was less than20%.

Statistics
We analyzed operant conditioning effects on snail behavioraldata with repeated-measures ANOVA, where the within-subjectfactors of populations were used and the between-subject factorof Interval (time in days) was used. All repeated-measures datawere tested for equal variance using Mauchly's test for sphericity.In cases where sphericity could not be assumed, we used the conservativeadjusted Greenhouse–Geisser P-values. For cases in whichwe identified a significant interaction between the repeatedfactor and the population, we used repeated contrasts to identifywhich treatment pairs differed significantly. Electrophysiologicaldata were analyzed using ANOVA with a Tukey's post hoc testto detect cases in which we identified a significant interaction.Nonhomogenous data (number of spikes per 600 s interval, spikesper burst, burst duration and number of bursts) were log transformedto homogenize between treatment data before ANOVA. Grade distributions(i.e. `marks') were compared using a chi-squared ( ${chi}$ ²) comparisonof proportions test. In cases where the number of samples, N,between populations was uneven (grades comparison), a randomselection of animals was used from each population to matchthe N value of the smallest sample in the analysis. In all analyses reportedhere, a type I error rate of 0.05 was used. All statistics wererun on SPSS Macintosh OSX version 11.0.4 (SPSS Inc., Chicago,IL, USA).

RESULTS

TOP
Summary
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
References

Considering that all of our previous work on Lymnaea has utilized astrain that was originally derived from canals in a polder locatednear Utrecht in the early 1950s and has been reared in the laboratoryever since, we thought it would be interesting to sample snails(e.g. test their ability to learn and remember) from: (1) alocal wild population (Belly snails), (2) their laboratory-rearedoffspring (Belly F1s) and (3) a wild population (wild Dutch)from the area where the founding Amsterdam colony was originally collectedin order to see how they compared with the established laboratory population(referred to as `laboratory snails') reared in our laboratory.

Aerial respiratory behavior of wild and laboratory-reared snails
To ensure that aerial respiratory behavior between the fourdifferent snail populations was similar and therefore directlycomparable, we measured aerial respiratory behavior betweenboth wild (Belly and Dutch) and both laboratory-reared (BellyF1s and `laboratory snail') populations. We found no significantdifference between the wild and the laboratory-reared populations inthe number of pneumostome openings, total breathing time oraverage breathing time (Table 1). We concluded that the aerialrespiratory behavior is similar between the Belly and Dutchpopulations of snails we sampled regardless of whether theywere reared in a natural or laboratory setting.

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Table 1. The mean (±s.e.m.) number of pneumostome openings, total breathing time and mean breathing time of snails from each of the four populations

Behavioral memory profile of the wild and laboratory-reared populations
After confirming that the aerial respiratory behavior of allfour populations of snails was similar, we could begin to testthe hypothesis that laboratory rearing results in a diminishedcapacity to form LTM following operant conditioning of aerialrespiration. We first compared the memory-forming abilitiesof the Belly snails and the Dutch derived laboratory-rearedsnails. When the Belly snails were subjected to the single 0.5h training session (TS), we found that these snails formed LTM (Fig. 2A,black bars). In distinct contrast, laboratory-reared snails (Fig. 2B)receiving the same training procedure did not exhibit LTM. Thatis, Belly snails formed LTM following a single 0.5 h TS, whereaslaboratory-reared (i.e. Blond snails) did not.

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Fig. 2. Behavioral response of wild Belly (left black bars) and laboratory snails (descendents of wild Dutch snails; right white bars) after a single 0.5 h training session (TS). (A) Operant conditioning of wild Belly snails results in an LTM that persists for 24 and 72 h (24 h TM, N=53, P<0.05; 72 h TM, N=23, P<0.05). Yoked control snails do not demonstrate memory at these same time periods (faded bars; 24 h yoke, N=26, P=0.36; 72 h yoke, N=25, P=0.45). Snails did not demonstrate memory after 1 week (1 week TM, N=32, P=0.24). (B) Laboratory snails do not demonstrate LTM after a single 0.5 h training session (TS; 24 h TM, N=30, P=0.55; 24 h yoke, N=15, P=0.42). All results shown as means + s.e.m. ^**P<0.001.

We next sought to determine the how long the LTM persisted inthe Belly snails following the single 0.5 h TS. We found thatLTM persisted for at least 72 h. That is, there was a significantreduction in the number of attempted pneumostome openings atthe 72 h TM compared with the TS. Yoked control Belly snailsdid not demonstrate a significant reduction in the number ofattempted openings at the 72 h TM (Fig. 2, black faded bars).Belly snails, however, tested one week after the single 0.5hTSdid not show LTM. A between-groups comparison of the 24 h and72 h TM sessions demonstrated that the numbers of attemptedpneumostome openings were also significantly reduced comparedwith the yoked controls at the same time point and the one-weekTM. These data are consistent with our hypothesis that snailsreared in the laboratory experience an unenriched environmentthat results in a diminished ability to form LTM.

Considering that we found such a dramatic increase in LTM durationin the Belly snails compared with that which we have reportedpreviously (e.g. Parvez et al., 2005) using laboratory-rearedsnails (i.e. no LTM with the single 0.5h TS), we hypothesizedthat one of two possibilities could account for these observed differences.The first is that the Belly snails had developed in an enriched environmentcompared with that of the laboratory population and that itwas the enriched environment during ontogeny that accountedfor the difference in LTM formation. The second possibilitywas that there could be differences between the original wildpopulations in their inherent memory-forming capabilities. Thatis, strain differences between the wild Dutch and Belly snailsexist, and this phenotype persisted regardless of rearing conditions. Todifferentiate between the two hypotheses, we needed to performtwo experiments: first, rear the offspring of Belly snails inour laboratory under conditions identical to those of our laboratory-rearedDutch snails and, second, resample wild Dutch snails from thesame locations that our laboratory populations were derivedfrom over 50 years ago.

We therefore collected `wild Dutch' snails from polders nearUtrecht from which our laboratory population was originallyderived. We also collected egg sacks from Belly snails in thewild and reared them to adulthood in separate aquaria in ourlaboratory. After successfully crossbreeding these two populationsof snails to ensure compatibility, we then proceeded to measure theability of these different snail populations (i.e. wild Dutchand Belly F1s) to form LTM following the single 0.5 h trainingsession.

First, we determined whether the freshly collected wild Dutchsnails formed LTM following the single 0.5h TS. That is, arethe wild Dutch snails as capable as the Belly snails in formingLTM following the single 0.5h TS? Or, put another way, are wildDutch snails better able to form LTM than the laboratory snails,which are descendants of snails collected from the same Utrechtpolder? We also tested yoked-control wild Dutch snails. We were surprisedto find that wild Dutch snails did not demonstrate memory 24hafter the single TS session (Fig. 3). That is, there was nosignificant reduction in the number of attempted pneumostomeopenings in the 24h TM session compared with the TS. Yoked-control wildDutch snails also did not demonstrate LTM. These data are similarto our previous findings demonstrating that `laboratory snails'do not exhibit LTM at 24h following a single 0.5 h TS (Lukowiak etal., 2000; Lukowiak et al., 2003a; Lukowiak et al., 2003b; Parvezet al., 2006a; Parvez et al., 2006b; Taylor and Lukowiak, 2000).These data are not consistent with our original hypothesis regardinglaboratory rearing. That is, wild Dutch snails, presumably developingin an enriched environment compared with the laboratory-reared snails(originally derived from wild Dutch snails), do not exhibitsuperior memory-forming capabilities compared with laboratory-rearedsnails. These data, however, are consistent with the hypothesisthat there are strain differences between Dutch and Belly snailsin their capability to form LTM. However, we still had to demonstratethat the offspring from Belly snails reared in the laboratoryhave a superior capacity to form LTM compared with that of wildDutch and laboratory-reared snails that were derived from an originalDutch population.

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Fig. 3. Behavioral response of wild Dutch snails after a single 0.5 h training session (TS). Wild Dutch snails do not demonstrate LTM when tested 24 h after operant conditioning (left light-gray bars, 24 h TM, N=22, P=0.60). Yoked controls do not demonstrate altered behavior after conditioning (right faded-black bar, 24 h yoked, N=16, P=0.57). Results are shown as means + s.e.m.

We thus subjected Belly F1s (i.e. snails reared from eggs collectedin the Belly river drainage), when they reached a length of2–2.5cm and had begun laying eggs of their own, signifyingmaturity (McComb et al., 2003; McComb et al., 2005), to a single0.5 h TS and determined whether they had the capability to formLTM. We found that these laboratory-bred Belly snails (BellyF1s) had a similar memory profile to that of the wild parentalpopulation. That is, the Belly F1s demonstrated memory at 72hbut not at 1 week (Fig. 4). The yoke control Belly F1 snailsdid not demonstrate memory at either 24 or 72h. A between-groupscomparison of the 72h TM session demonstrated that the number ofattempted pneumostome openings was also significantly reducedcompared with that of the yoked controls at the same time pointand the one-week TM. Thus, laboratory rearing of Belly snailsdid not result in a diminished capacity to form LTM. These dataare also in agreement with our data regarding Dutch snails,which also showed that laboratory rearing did not alter theirinherent ability to form LTM.

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Fig. 4. Behavioral response of Belly F1 snails after a single 0.5 h training session (TS). Operant conditioning of Belly F1 snails results in an LTM that persists for 24 and 72 h (24 h TM, N=26, P<0.05; 72 h TM, N=26, P<0.05). Yoked control snails do not demonstrate memory at these same time periods (faded-black bars, 24 h yoke, N=24, P=0.55; 72 h yoke, N=25, P=0.73). Snails did not demonstrate memory after 1 week (1 week TM, N=25, P=0.82). Results are shown as means + s.e.m. ^**P<0.001.

Another method used to determine how `good' a memory is makesuse of individual marks given to each snail (Lukowiak et al.,2003c

; Rosenegger et al., 2004

). We therefore determined thegrade distribution for each wild Dutch snail and each `laboratorysnail' based on their performance following the single 0.5 hTS. We found no difference in the grade distribution betweenthe wild Dutch and the laboratory snails 24 h after TS. Thatis, the percentage of snails given `A' grades in the wild Dutchcohort (27%) was not significantly different from the numberthat the laboratory snails earned (16%). The number of `F' grades givenwas also similar between these populations, with 44% of thewild Dutch snails failing the test and 57% of laboratory snailsreceiving `F' grades ( ${chi}$ ², N=89, P=0.335). Thus, we conclude that thebehavioral memory profiles of wild Dutch snails and their laboratory-rearedcousins are similar. Thus, it appears that laboratory rearinghas not altered the ability (or inability) of the populationsto form LTM.

We also compared the individual grade distributions betweenthe wild Belly snails and their laboratory-reared offspring.We found no difference in the grade distribution between thesetwo populations. That is, the percentage of snails given `A'grades in the wild Belly snails (40%) was not significantly differentfrom the number that the Belly F1 snails earned (50%). The numberof `F' grades given was also similar between these populations,with 36% of the wild Belly snails failing the test and 35% ofBelly F1 snails receiving `F' grades ( ${chi}$ ², N=51, P=0.712). Thus,we conclude that being reared in the `simple' environment ofthe laboratory does not affect the behavioral memory profileof the Belly snails.

To dissect further the differences between the wild Dutch, laboratory snails,wild Belly snails and Belly F1 snails, we compared the individual gradedistributions in each separate population. We found that thewild Belly snails and Belly F1 snails received significantlymore `A' grades and significantly fewer `F' grades than thewild Dutch or laboratory snails ( ${chi}$ ², N=104, P=0.022). Together,all of the data we collected regarding the ability to form LTMbetween the different populations of snails are consistent withthe hypothesis that there are strain-specific differences betweenDutch and Belly snails, with the Belly snails having superiormemory-forming capabilities regardless of their rearing conditions.

Electrophysiological profile of RPeD1
In RPeD1, the neuron that both initiates aerial respiratorybehavior and is a necessary site of LTM formation, we have recentlydemonstrated electrophysiological changes associated with enhancedLTM formation that parallel the duration of the behavioral phenotypefollowing predator detection (Orr and Lukowiak, 2008). We thereforehypothesized that, given the differing memory capabilities between theDutch and Belly snail populations, there would be predictable electrophysiologicaldifferences in RPeD1 activity following the single 0.5 h TSbetween these two snail populations.

We have also recently shown that, 24 h after the single 0.5h TS, laboratory snails do not demonstrate memory, and the electrophysiological characteristicsof RPeD1 are not different from the naive state (Orr and Lukowiak,2008). We therefore first sought to determine whether the electrophysiological propertiesof RPeD1 in wild Dutch snails were altered when sampled 24 hafter the single 0.5h TS. However, before we could make thiscomparison, we needed to determine whether the activity recordedin RPeD1 from semi-intact preparations prepared from naive wildDutch and laboratory snails was similar. We found that therewere no significant differences in any of the nine electrophysiologicalmeasurements made from `naive' RPeD1s in these two groups ofsnails (data not shown, but see Materials and methods for descriptionsof the electrophysiological properties measured).

Next, we trained both wild Dutch and laboratory snails withthe single 0.5 h TS and then 24 h later recorded from RPeD1in semi-intact preparations. We found, as in the behavioralexperiments, that there was no difference in any of the measuredelectrophysiological parameters in RPeD1 24 h after TS comparedwith the naive state (Fig. 5). That is, 24 h after TS1, RPeD1activity is indistinguishable from that seen before training.

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Fig. 5. Representative electrophysiological recordings from RPeD1 in semi-intact preparations taken from wild Dutch and laboratory snails before (naive) and 24 h after operant conditioning. No significant differences were found between any of the measured electrophysiological characteristics (wild Dutch naive, N=8; wild Dutch 24 h, N=8; laboratory-reared Dutch naive, N=9; laboratory-reared Dutch 24 h, N=8).

Considering that we observed a dramatic difference in the abilityof wild Belly snails and Belly F1s to form LTM compared withwild Dutch and laboratory snails, we sought to determine whetherchanges in RPeD1 activity would parallel the behavioral changesin these wild Belly snails. We therefore trained naive cohortsof wild Belly and Belly F1 snails with the single 0.5 h TS and3 days later prepared semi-intact preparations from these snails.We found in both the wild Belly (Fig. 6) and the Belly F1s (Fig. 7)significant changes in the measured electrophysiological parametersof RPeD1 72 h after TS. Specifically, the number of spikes per600 s, the number of spikes per burst, frequency of spikes perburst, burst duration and total numbers of bursts per 600 swere all reduced in the trained groups at 72 h compared withthe naive state. Yoked control groups did not demonstrate significantchanges at 72 h compared with the naive state (Figs 6 and 7for each population respectively). Thus, we conclude that single0.5 h TS has similar effects on the electrophysiological characteristicsof both wild Belly and Belly F1 snails and that these changesparallel the observed behavioral phenotype. Thus, unlike thecase with wild Dutch and laboratory snails, significant electrophysiologicaldifferences are seen in RPeD1 from wild Belly snails and BellyF1 snails for 72 h after the TS, which parallel the behavioral memory.

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Fig. 6. RPeD1 activity in wild Belly snails following the single 0.5 h training session. (A) Representative recordings from RPeD1 in wild Belly snails starting at top with a naive snail (naive wild Belly), 24 h after the operant conditioning procedure, 72 h after conditioning, 72 h yoked control and 1 week after conditioning. (B) Summary data for mean (+s.e.m.) spiking activity per 600 s. (C) Number of spikes per burst. (D) Burst duration. (E) Number of bursts per 600 s. In all measured characters presented here, both the 24 h and 72 h operantly conditioned groups demonstrated significantly lower activity than the naive state and are significantly lower than the 72 h yoke and 1 week groups. 72 h yoke and 1 week groups are not significantly different from the naive state. All data represent log-transformed values. ^*P<0.05; ^**P<0.001. Naive N=9; 24 h N=9; 72 h N=7; 72 h yoke N=7; and 1 week N=8. No significant differences were detected between treatments in other electrophysiological parameters measured (see Materials and methods).

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Fig. 7. RPeD1 activity in Belly F1 snails following the single 0.5 h training session (A) Representative recordings from RPeD1 in Belly F1 snails starting at top with a naive snail (naive Belly F1), 24 h after the operant conditioning procedure, 72 h after conditioning, 72 h yoked control and 1 week after conditioning. (B) Summary data for mean (+s.e.m.) spiking activity per 600 s. (C) Number of spikes per burst. (D) Burst duration. (E) Number of bursts per 600 s. In all measured characters presented here, the 24 h and 72 h operantly conditioned groups both demonstrated significantly lower activity than the naive state (except burst duration at 72 h) and are significantly lower than the 72 h yoke and 1 week groups. 72 h yoke and 1 week groups are not significantly different from the naive state. All data represent log-transformed values. ^*P<0.05; ^**P<0.001. Naive N=8; 24 h N=7; 72 h N=7; 72 h yoke N=8; and 1 week N=7. No significant differences were detected between treatments in other electrophysiological parameters measured (see Materials and methods).

	DISCUSSION

TOP Summary INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION References

The original purpose of this study was to test the hypothesisthat laboratory rearing of Lymnaea results in `blond' snailsthat are challenged with respect to formation of LTM. Our initialpilot experiment on locally obtained wild Lymnaea (i.e. Bellysnails, which are darker in color; Fig. 1) found that these snailshad superior memory-forming capabilities compared with our `blond' laboratory-bredsnails. Consistent with this hypothesis were the data obtained froma series of experiments on exposing these blond snails to asympatric predator (crayfish) in an attempt to `enrich' thelaboratory-rearing environment. We found (Orr et al., 2007

;Orr and Lukowiak, 2008

) that these `blond' snails instinctuallyresponded to the presence of the predator with specific predator-avoidancebehaviors, including an enhanced ability to form LTM. This enhancedability to form LTM, as a result of predator detection, wasstrikingly similar to the pilot data from the Belly snails.Thus, we were encouraged to perform a series of experiments totest our hypothesis directly that an enriched environment, suchas that provided in the snails' natural habitat, results insnails with superior memory-forming capabilities. The data presentedhere, however, did not support this hypothesis; rather, thedata support an alternative hypothesis that there are heritabledifferences in memory-forming ability between two geographically distinctpopulations of Lymnaea.

From this study, we have drawn three important conclusions:first, we have identified two naturally occurring, geographicallyseparate, wild populations of Lymnaea stagnalis that have differentcapacities for forming LTM following operant conditioning ofaerial respiratory behavior; second, rearing of the progenyof wild snails under laboratory conditions does not significantlyalter their memory-forming abilities – that is, thereis an inherent and heritable capacity for memory formation withineach population that is maintained regardless of rearing ineither natural or artificial conditions; and, third, this `hardwired'memory capability, which differs between stains of Lymnaea stagnalis,is encoded within a neural network that is itself malleable– that is, significant physiological changes occur withinthis neural network during memory formation that are directlycorrelated with behavioral modification. Support for these conclusionswas obtained at both the behavioral level and in the electrophysiologicalproperties of the neuron RPeD1. This is a neuron that is bothnecessary and sufficient for driving the respiratory network (Syedet al., 1990; Syed et al., 1992) and is a necessary site ofLTM formation (Scheibenstock et al., 2002).

We have demonstrated previously that laboratory snails havemaintained instinctual defensive responses to a natural predatorfor over 250 generations of predator-free existence and thatoperant conditioning in the presence of this predator resultsin dramatically enhanced LTM (Orr et al., 2007; Orr and Lukowiak,2008). This instinctual behavioral response is also reflectedin RPeD1 activity. Together, these results lend strong supportto the idea that there is both an innate `hardwired' component(i.e. that heritable predator defense and memory-capabilityresponses are maintained in both the behavioral phenotype andin the CPG circuit that drives the behavior), whereas the networkitself remains adaptable for associative learning and formationof LTM. Thus, behavioral and electrophysiological differencesbetween strains are present in an identified tractable neuralnetwork that is inherently malleable and maintained regardlessof environmental conditions during ontogeny.

Despite a rich history of exploration, investigating the neuralcorrelates of cognition has led behavioral ethologists to followgenerally one of two hypotheses. The first suggests that cognitionhas been, and continues to be, acted upon by natural selection(Healy and Hurly, 2004). Evidence supporting this theory comesfrom investigations into optimal foraging theory, where theability of an animal to choose optimal foraging grounds, rememberfood caches and incorporate risk assessment results in increasedsurvivorship and reproductive output (Healy and Hurly, 2004; Orret al., 2007; Shettleworth et al., 1985). However, some researchershave criticized this view (Bolhuis and Macphail, 2001; Macphailand Bolhuis, 2001) and suggest that natural selection has actedonly on the `peripheral nervous system' (by which they meanthe neural regions involved in the perception of stimuli) andnot on higher learning areas (Healy and Hurly, 2004). Instead,investigators supporting this alternative view have focusedon other mechanisms, such as exposure to stress (Healy and Hurly,2004; Herberholz et al., 2004; Kim and Diamond, 2002; Martenset al., 2007b; Rundle and Bronmark, 2001; Shors, 2004; Shors,2006) or environmental enrichment (Berardi et al., 2007; Fischeret al., 2007; Frick et al., 2003; Harburger et al., 2007; Irvineand Abraham, 2005; Martens et al., 2007b) to explain the cognitivevariation within and between species. This second hypothesissuggests that the cognitive ability of an organism is dependenton what it experiences during its ontogeny, and it is this ontogeneticadaptation that determines the behavioral fitness of an organism.

We set out to determine whether rearing conditions during ontogeny influencedthe ability to form LTM in Lymnaea in the hope of using ourtractable model to study the interface between environment andmemory. Exposure to enriched environments has been shown toresult in use-induced cortical plasticity (Hebb, 1950; Hebb,1951) leading to improved learning and memory (Berardi et al.,2007; Fischer et al., 2007; Harburger et al., 2007; Irvine andAbraham, 2005; Rosenzweig et al., 1993). These studies supporta central dogma of neural development – that formationof neural circuits is guided by experience (Feller and Scanziani,2005). However, we found that our laboratory rearing practicesalter neither aerial respiratory behavior nor associative learningand the subsequent formation of LTM. Rather, we found significantbehavioral and neurophysiological differences between two distinctgeographical populations of Lymnaea. The differences were manifestat both the behavioral and neurophysiological level in how muchbetter one population of snails (Belly snails) formed LTM afteroperant conditioning compared with the other (Dutch snails).Strain differences in memory capability, including neuroanatomicaland electrophysiological properties, have been demonstratedbetween strains of mammalian (Ammassari-Teule et al., 1993;Brooks et al., 2005; Gozzo and Ammassari-Teule, 1983; Ledoux etal., 1983; Reynierse, 1968; Ritzmann et al., 1993; Waddell etal., 2004) and invertebrate models (Hay, 1975; Meller and Davis,1996). However, here we present the first demonstration we knowof where strain differences have been examined from the behaviorof natural wild populations to an individual neuron necessaryfor the behaviors under investigation.

Our finding that LTM formation is not affected by natural orartificial rearing environments is consistent with the findingsof others studying the affects of rearing conditions on wildand F1 cohorts. These investigations have found that rearingthe offspring of wild animals in artificial conditions has littleeffect on their behavioral and physiological responses to stress (Kunzlet al., 2003) as well as associative learning or memory formation (Stuermerand Wetzel, 2006). In fact, there is evidence to the contrarydemonstrating increased learning by laboratory-reared animalscompared with wild animals (Millar, 1975; van der Staay andBlokland, 1996). This finding has been attributed to the effectsof domestication in selecting for behaviors that are compatiblefor laboratory use (Stuermer and Wetzel, 2006), which can occurwithin a short period of time. It should also be noted thatstudies examining environmental enrichment are necessarily performedon a single strain to isolate the effects of the enrichmentalone, as assessing the relative amount on `enrichment' of wildstrains would be difficult. Our inability to elucidate differencesbetween snails reared in the wild and those in the laboratorydoes not exclude the possibility that Lymnaea respond to theeffects of environmental enrichment. It might be that our rearingconditions are simply not `impoverished' enough or we are examininga behavior that is unaltered by environment challenges during ontogeny.Perhaps, if we reared individual snails in isolated environments,a difference in cognitive ability might be detected. These investigationsare ongoing in our laboratory.

Our data demonstrate that Belly snails have the capability offorming LTM with a training procedure that does not usuallyresult in LTM in the wild Dutch and laboratory snails. However,a single 0.5 h TS will in the laboratory-reared blond snailsresult in LTM if the training is performed in crayfish effluent(Orr and Lukowiak, 2008) or if the TS is immediately precededwith or followed by a sufficiently stressful event [e.g. immersionin 25 mmol l^–1 KCl for 30 s (Martens et al., 2007a)].In addition, when individual snails are examined, we found thatthe `quality' of LTM in the Belly snails was significantly better thanin the Dutch snails. The biological reasons for this differencein memory capability between the Alberta and Dutch populationsare unknown to us at this time; however, we can rule out laboratoryrearing as a cause.

The two populations are clearly subject to differing predatoryregimes as crayfish are not endemic to the Belly River, whereasthey are sympatric with Dutch snails in the Utrecht polders.It might be that these populations have undergone differentialselection resulting in this altered cognitive phenotype. Certainly,the traits under study in this experiment have at least twoof the three required characteristics that would be acted uponby natural selection: a heritable component of the traits measuredand variation among the traits (Endler, 1986; Lande and Arnold,1983). Whether this trait variation results in fitness differencesin an individual or between populations remains to be demonstrated.

Now that our model system includes naturally occurring straindifferences (i.e. Belly snails versus Dutch), we can begin toinvestigate the biological reasons why these differences exist.We can also now explore how a neural network, which is governedby an instinctual response, maintains the ability to be adaptableto operant conditioning. For example, in the future, we can beginto determine what differences in neural connectivity or in the constituentmolecular processes within this network underlie these strain differences.It is possible that, in Belly snails, the ratio of suppressive andactivator isoforms of the cyclic AMP response-element-bindingprotein CREB (Silva et al., 1998) in CPG neurons (Sadamoto etal., 2003) favors activation, such that LTM formation is triggeredmore easily. The identification of these two strains of Lymnaeapresents an exciting new opportunity to investigate the malleabilityof hardwired networks in a system where a defined behavior isdriven by identified neural circuitry, yet separate naturalpopulations within the model demonstrate dramatic variationin the behavior.

Here, we have strong evidence demonstrating that hardwired instinctual behaviorsare encoded within a network that is itself inherently malleable.As the molecular events in a single neuron (RPeD1) in Lymnaeahave been shown to be necessary for formation of LTM, reconsolidation,extinction and forgetting (Lattal et al., 2006; Parvez et al., 2006b;Sadamoto et al., 2003), it is now possible to investigate howa hardwired network can be modified to alter behavior at thelevel of the single neuron and how this neuronal adaptationaffects these animals at the level of populations.

Acknowledgments

We thank the Orr ranch and the Nelson ranch for allowing thisfield work and Hyojung Orr, David Rosenegger, Kara Martens,Kashif Parvez and Kim Browning for all their help and comments.This research was supported by NSERC.

References

TOP
Summary
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
References

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