Experience Affects Recruitment of New Neurons But Not Adult Neuron Number

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The Journal of Neuroscience, February 1, 2002, 22(3):825-831

Experience Affects Recruitment of New Neurons But Not Adult Neuron Number
Linda Wilbrecht, Alex Crionas, and Fernando Nottebohm
Laboratory of Animal Behavior, The Rockefeller University, New York, New York 10021

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

It is not known whether the addition of new neurons to the high vocal center (HVC) of juvenile zebra finches permits vocallearning or is the consequence of it. To tease apart these two,we performed surgery on 26-d-old juveniles. The operations wereremoval of both cochleae and unilateral or bilateral denervationof the syrinx. Ability to imitate a tutor song was little affectedby unilateral syringeal denervation but was severely hinderedby bilateral denervation or deafening. Recruitment of new HVCneurons was studied by injecting BrdU, a cell birth marker, onpost-hatching days 61-65 and killing the animals 30 d later. Deafeningor bilateral denervation did not alter the number of BrdU-labeledneurons in HVC, but unilateral denervation nearly doubled thisnumber in the intact side. This doubling was transient, was blockedby deafening, and was not seen in birds that received BrdU injectionsearlier or later in vocal ontogeny. The adult number of HVC neuronswas not affected by any of our surgical procedures. Apparentlyexperience does not affect the total number of neurons in adultHVC, but some kinds of experience can, during narrowly definedtimes, influence the recruitment of new HVCneurons.

Key words: song learning; neurogenesis; BrdU; unilateral denervation; sensitive period; syrinx

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Many new neurons are added to the song system of birds during periods of song acquisition, both in juveniles (Alvarez-Buyllaet al., 1988, 1990; Nordeen and Nordeen, 1988; Nordeen et al.,1989) and in adults (Kirn et al., 1994), suggesting that new neuronsmight underlie the exceptional behavioral changes that take placethen. Changes in new neuron numbers in the hippocampus of birds(Barnea and Nottebohm, 1994) and mammals (Kempermann et al., 1997;Gould et al., 1999; Shors et al., 2001) have also been shown tobe related to changes in experience and behavior. It is not knownwhether the high rate of new neuron recruitment in the song systemduring the sensitive period for song learning is the result ofa developmental program permissive for learning or the consequenceof learning taking place at thetime.

We quantified new neuron recruitment in zebra finches in which we disrupted the ability to imitate song to determine whetherrecruitment was affected. To this end we deafened birds at post-hatchingday 26. These birds were not able to hear a tutor song that theywould later imitate, nor were they able to hear themselves toperfect this imitation. We also denervated the syrinx (vocal organof birds) (see Fig. 1) bilaterally and unilaterally by cuttingthe tracheosyringeal (ts) nerve that controls the syringeal muscles.Because the syrinx of songbirds consists of two functionally independenthalves, unilateral denervation blocked control of just one ofthe birds' two sound sources. In such birds, unilateral denervationis followed by full atrophy of the ipsilateral syringeal muscles(Nottebohm et al., 1979). The song system of the brain also consistsof two functional halves, each of which controls the ipsilateralsyringeal half. As a result, it is possible to peripherally disconnectone or both halves of the song system from their respective syringealmuscles by severing one or both ts nerves. When one syringealhalf is denervated, the opposite, intact side assumes responsibilityfor sound modulation, and when this is done early in life, thebird is still able to imitate sounds (Nottebohm et al., 1979).Thus unilateral denervation makes it possible to compare hemispheresthat are or are not involved with direct syringeal control inan animal in which social variables and blood-borne factors arethe same for bothsides.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Subjects and groups. All procedures affecting animals were approved by the Rockefeller Animal Care and Use Committee. We usedmale zebra finches (Taeniopygia guttata) of known age, hatchedin our aviaries in Millbrook, NY, for all of our experiments.We labeled new neurons with the cell birth marker bromodeoxyuridine(BrdU), a thymidine analog, using injections of 100 µl at a concentrationof 10 mg/ml (~0.08 mg/gm body weight); injections were given intramuscularlyat 11 A.M. for 5 consecutivedays.

In the first experiment, we labeled neurons born on post-hatching days 61-65 in five groups of birds (10 control, 7 unilaterallydenervated, 5 bilaterally denervated, 5 deafened, 5 unilaterallydenervated + deafened) and killed the animals 30 d after the firstinjection.

In a subsequent experiment, we labeled neurons during post-hatching days 61-65 (6 control, 10 unilaterally denervated birds)and killed these animals either 10 or 90 d after the firstinjection.

In a final experiment, we labeled new neurons at three other times during song ontogeny and harvested brains 30 d after thefirst injection. Series of five injections were made at post-hatchdays 21-25 (four control, five unilaterally denervated), post-hatchdays 35-39 (four control, six unilaterally denervated), and post-hatchdays 120-124 (four control, six unilaterallydenervated).

Surgery. All surgeries were performed on post-hatch day 26 using sodium pentobarbital diluted 1:5 (0.055 mg/gm) (controlswere given anesthetic alone). For denervation, the tracheosyringealbranch of the hypoglossal nerve, which innervates the ipsilateralsyringeal half (Paton and Manogue, 1982), the vocal organ of birds,was sectioned unilaterally or bilaterally (Fig. 1). In the unilaterallydenervated birds, a balance was kept between left and right nervecuts, to take into account that the extent of song control exertedby both these nerves can differ in zebra finches (Williams etal., 1992). Deafening was done by removing both cochleae, as describedin Konishi (1965).

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Figure 1. Schematized view of part of the male zebra finch showing the two high vocal centers (HVC), and the motor output pathway of one side to nucleus robustus of the archistriatum (RA), the tracheosyringeal portion of the hypoglossal nucleus (nXII ts), and the muscles of the syrinx. Denervation involved unilateral or bilateral removal of a long segment of the ts nerve from the length of the trachea.

Housing. All finches were kept in a standard cage (50 × 62 × 38 cm) with both of their parents and no more than one siblingafter day 30, under a photoperiod of 12 hr light/dark, with adlibitum access to food and water. For all groups, injections,surgery, and euthanasia were performed on the correspondinglysame post-hatching day. At day 65, all birds were placed singlyin a smaller cage (25 × 46 × 22 cm) and then given an unrelatedfemale companion 60-90 d old, to encourage singing and the normaloccurrence of social relations (Zann, 1996).

Sound recording and analysis. Songs were recorded on Marantz tape recorders using Maxell Cr02 cassette tapes and tie-clipbattery-powered microphones (Radio Shack) 3 d or less before perfusion.Comparisons were made with songs recorded from tutors to assessimitation using birds from all treatment groups killed at 91 dof age (seven control, eight unilaterally denervated, six deaf,five bilaterally denervated, five denervated and deaf). For thesemeasurements we relied on software developed for measuring zebrafinch song similarity (Tchernichovski et al., 2000). The advantageof this method is that it is quick and avoids subjective criteriathat might differ between human observers. We used the software'sdefault zebra finch settings. This setting evaluates the similaritybetween brief periods of sound, regardless of their temporal order,and thus is an inclusive way of screening for similarity. Becausethe syrinx of zebra finches can be induced to produce zebra finch-likesounds even in the absence of any innervation or learning, similaritycan be found in small intervals of sound regardless of an overallfailure to imitate a model. That is why two songs that, to oureye (sound-spectrographic evaluation), might look very differentcan still get a similarity score of 30 or 40% (Fig. 2). In evaluationsof song similarity and song stereotypy, we used the consistentlyrepeated part of a song [the "motif," e.g., see Lombardino andNottebohm (2000)] identified by eye from the visual transcriptionof songs.

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Figure 2. The songs of three tutors and their sons' imitations. For tutor A and B, the first son shown was an intact control; the second son was unilaterally denervated, and the third was deafened. For tutor C, the first son shown was unilaterally denervated, the second was bilaterally denervated, and the third was unilaterally denervated and deafened. Most sons were raised apart from each other in serial clutches.

To assess song stereotypy, a mark of maturation, in seven 91-d-old unilaterally denervated birds and seven intact controls,we compared nine motifs sung on the same day. We averaged thesimilarity scores obtained from the comparison of each of thesemotifs with the othereight.

Perfusion and histology. Birds were perfused intracardially after an overdose of diluted sodium pentobarbitol with 0.9% salinefollowed by 3% paraformaldehyde. Brains were removed and leftin 3% paraformaldehyde overnight. They were then washed for 24hr in phosphate buffer, dehydrated in alcohol over 3 d, clearedfor 1 hr in xylene, and embedded in paraffin. Parasagittal 6 µmsections were cut on a microtome and mounted on chromalum-coatedglassslides.

Brains were prepared for immunohistochemistry by deparaffinization in xylene, denaturation in citric acid/sodium citrate buffer,and a weak pepsin incubation. After incubation in 10% normal horseserum and 0.3% Triton X-100, a mouse monoclonal antibody againstBrdU (1:200, Dako, Carpinteria, CA) and a horse biotinylated secondaryantibody (1:200, Vector, Burlingame, CA) were used to first stainBrdU+ nuclei with diaminobenzidine (DAB) using an ABC Elite reactionkit (Vector). This staining was followed by a mouse Hu 16A11 primary(1:500, Molecular Probes, Eugene, OR) and a donkey Cy-3 (1:200,Jackson ImmunoResearch, West Grove, PA) fluorescent secondaryantibody to stain the Hu protein in the cytoplasm of neurons (Baramiet al., 1995). Previous DAB staining prevented any secondary crossreactivity (Valnes and Brandtzaeg, 1982). All brains were analyzedusing a 63× objective on a computer-yoked microscope (Alvarez-Buyllaand Vicario, 1988). The identity of each BrdU+ nucleus identifiedunder the light microscope was checked under fluorescence forthe neuronal marker Hu. BrdU+ DAB-stained nuclei with a Hu+ Cy-3halo were counted as new neurons (Fig. 3). A 1 mm² portion of the high vocal center (HVC) was mapped for each hemisphere;this typically involved mapping five or more sections of HVC throughoutthe fullest parts of the nucleus. The sections used were at least60 µm apart. In those cases in which birds received unilateraltreatment, we analyzed both hemispheres individually. In the restof the groups, after we determined that the right/left differenceswere not significant, we then used data from just the right hemispherefor comparisons.

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Figure 3. Left panel, BrdU+ nuclei stained with DAB viewed under the confocal microscope. Scale bar, 5 µm. Center panel, Merged images of BrdU and Hu showing one single labeled cell (1), not counted, and two double-labeled cells (2, 3) counted as new neurons (N). Right panel, Hu+ cells under the confocal microscope counted to determine total neuron number in HVC.

Quantification of results. Comparisons of more than two groups were first performed using a nonparametric Kruskal Wallis one-wayANOVA. Comparisons of two groups were made using a Mann-WhitneyU test or Wilcoxon matched pairs signed rank test when comparingtwo hemispheres from the same birds. All p values reported aretwo-tailed; p < 0.05 was treated as the threshold for significance.SEM is indicated in Tables andFigures.

Estimates of the total number of Hu+ cells (i.e., neurons) and of the total number of cells that were Hu+ and BrdU+ (i.e.,new neurons) were made for the entire nucleus using volume estimatesand the Abercrombie correction equation [number of cells per volume= number of cells per area × (T/(T + D)] to accurately count sectionedobjects by accounting for section thickness (T) and average nucleardiameter (D) (Guillery and Herrup, 1997). Estimates of HVC volumewere made by measuring its area every 180 µm throughout the brain.Where nucleus robustus of the archistriatum (RA) volume was assessed,it was measured every 120 µm. We measured the diameter of 20 nucleithat were BrdU+ and Hu+, and 50 nuclei of Hu+ cells in the ipsilateraland contralateral HVC of five unilateral ts cut birds, and theright hemisphere of five control birds and five deaf birds, all91 d old. For calculations of percentage of neurons labeled inthe 1 mm² area covered in mapping, neuron density was assessed by averagingthe number of Hu+ cells counted in three 0.012 mm² fields of each HVC section mapped for each bird in all groups.Each field was counted, taking care to exclude cells touchingtwo sides of the rectangular visual field, and counts were correctedwhen converted to volumes. Density of neurons in RA was also assessedin this manner in unilaterally denervated and control groups at91d.

The above methods were used to generate three estimates: number of new neurons per square millimeter (uncorrected), totalnumber of new HVC neurons (corrected), and percentage of HVC neuronsthat were BrdU labeled (uncorrected). Our comparisons betweengroups yielded very similar results using any of these three methods.For the sake of simplicity, we present our data as number of newneurons per square millimeter. This is justified because therewere no differences between groups in neuronal density or nucleardiameter of newneurons.

Terminology. We counted numbers of BrdU+ and Hu+ cells, and therefore presumed "new" neurons, 5-90 d after injection of thebirth date marker (BrdU). The numbers seen at the shorter survivalare likely to be underestimates because neurons born elsewheremay not yet have migrated to their final destination. At longersurvivals, the number of neurons is likely to be influenced byselective attrition (Kirn et al., 1999). In short, we chose theterm "recruitment" to refer to the number of new neurons presentat any one time, without attempting to tease apart the contributionsof production, migration, andsurvival.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Unilateral denervation affected the recruitment of new neurons, but deafening and bilateral denervation did not

Thirty days after BrdU injections on post-hatching day 61-65, significantly more BrdU+ neurons were recruited into the HVCcontralateral (contra-) to nerve section than in the ipsilateral(ipsi-) one or that of controls (1.6 times more in contra- thanipsi-, p = 0.03, and 1.9 times more in contra- than in intactcontrol birds, p = 0.007) (Table 1, Fig. 4).


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Table 1. BrdU injection days 61-65 $right-arrow$ killed at day 91

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Figure 4. Bar graph comparing the number of BrdU+/Hu+ cells per square millimeter in HVC 30 d after injection at days 61-65. Unilaterally denervated birds have values for counts in HVC ipsilateral (white) and contralateral (black) to the ts nerve section. Asterisks above the bar for the contralateral HVC of the unilaterally denervated birds indicate a significant difference from its ipsilateral partner and control birds. When unilateral denervation is combined with deafening, the difference in new neuron number between the two HVCs is no longer seen. Error bars indicate SEM.

When birds were only deafened but not denervated, the number of labeled HVC neurons was not significantly different from thatin age-matched intact controls (p = 0.96). Likewise, bilateraldenervation did not change the number of BrdU+ neurons recruitedto HVC when compared with intact controls (p = 0.43).

No significant left/right differences were detected in the number of Brdu+/Hu+ cells in the HVCs of the two hemispheres incontrol, bilaterally denervated, or deafened birds (p > 0.2; datanot shown). The volume of RA and the density of neurons withinit did not differ significantly between controls (n = 7) and theipsilateral or contralateral sides of unilaterally denervatedbirds (n = 7) (volume: controls 0.134 ± 0.021 mm³, contra- 0.122 ± 0.012 mm³, ipsi- 0.115 ± 0.014 mm³, control vs contra- p = 0.62, control vs ipsi- p = 0.36, contra-vs ipsi- p = 0.21; density: controls 52 ± 2 neurons in three 63×fields, contra- 54 ± 2, ipsi- 48 ± 2, control vs contra- p = 0.58,control vs ipsi- p = 0.39, contra- vs ipsi- p = 0.15).

Deafening cancelled the effect of unilateral denervation on new neuron numbers

When unilateral denervation was combined with bilateral deafening, the increased recruitment of BrdU+ neurons born betweendays 61 and 65 was no longer observed (Table 1, Fig. 4). In thisset of birds the number of new neurons per square millimeter didnot differ between the contralateral and ipsilateral sides (p= 0.43) and was not significantly different from that in intactcontrols (p = 0.35).

Birds that sustain unilateral denervation of their vocal organ can imitate a tutor's song

Song similarity was assessed using sound analysis software (Tchernichovski et al., 2000). Songs of intact (control) birdshad a similarity score of 75.9 ± 6.6% SEM. The imitations of unilaterallydenervated birds were not significantly different when comparedwith controls (similarity score of 62.6 ± 5.7% SEM; p = 0.12).In contrast, the other manipulations produced scores significantlylower than those of unilaterally denervated birds. Songs of birdsthat had been bilaterally denervated (similarity score 43.2 ±5.1% SEM; p = 0.03), songs of birds that were deaf (34.9 ± 6.91%SEM; p = 0.01), and songs of birds that were deaf and unilaterallydenervated (33.8 ± 8.8% SEM; p = 0.01) were grossly abnormal,bearing little resemblance to the complex features of the tutor'ssong (Fig. 2).

To assess whether unilateral denervation arrested song development, we compared the songs of these birds at day 91 with thoseof intact controls. Comparisons of motifs sung on the same dayshowed comparable song stereotypy in intact (82.4 ± 2.74% SEM)and unilaterally denervated birds (88.1 ± 1.66% SEM), suggestingthat elevated levels of neuronal incorporation during late stagesof song development do not reflect behavioralimmaturity.

Altered levels of neuronal recruitment were transient

After finding that new neuron numbers roughly doubled in the HVC contralateral to ts nerve section in birds injected withBrdU during days 61-65, we wondered whether the difference betweenthe two HVC sides was present soon after the cells were born (5-10d survival) and whether the difference lasted for as long as 90d. This might be expected if the excess of new neurons in theintact side embodied part of a permanent repository of long-termmotormemory.

There was no significant difference between the number of 5- to 10-d-old neurons in HVC on either side (p = 0.81). Moreover,there was no difference between these animals and their intactcontrols (p = 0.39). Interestingly, the difference between thetwo sides seen at 30 d survivals (above) was no longer presentat 90 d survivals (p = 0.63), and the values for the two sidesseen at 90 d survivals did not differ significantly from thoseof controls (p = 0.68) (Table 2).


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Table 2. BrdU injection days 61-65 $right-arrow$ killed 10, 30, or 90 d later

Unilateral differences in neuronal recruitment did not occur at other times in development

To determine whether unilateral denervation affected HVC neuronal recruitment earlier in song development or after song crystallization,we also counted BrdU-labeled neurons in birds that had been unilaterallydenervated at day 26 and then received BrdU at different timesin development. We injected BrdU on days 21-25, when birds arelikely to imitate songs they hear but are only starting to producesub-song; on days 35-39, when birds are still likely to imitatesongs they hear and are singing advanced sub-song; and on days120-124, when the adult learned song is sung in a stereotypedmanner (Immelmann 1969; Price 1979; Eales, 1985; Boehner, 1990;Lombardino and Nottebohm, 2000; Tchernichovski et al., 2000) (Fig.5). As in the first experiment, recruitment of new neurons wasmeasured by the number of Hu+/BrdU+ neurons per square millimeterin HVC 30 d after the first BrdU injection.

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Figure 5. Decline in BrdU+/Hu+ cells per square millimeter in HVC during the period for song learning. Injections were made at four different times during song learning, and birds were killed 30 d after the first injection. Intact controls are represented by open squares, and unilaterally denervated birds are represented by open and closed circles. Open circles correspond to counts from the HVC ipsilateral to the ts nerve cut, and closed circles indicate values from the intact side contralateral to the nerve cut. For groups injected at days 61-65 and killed at day 91, the HVC contralateral to denervation is significantly higher than the ipsilateral side and controls. For groups injected at days 120-124 and killed at day 150, the asterisk indicates that the ipsilateral side of unilaterally denervated birds is significantly higher than controls. Error bars indicate SEM.

In the youngest of these groups (days 21-25), finches added BrdU+ HVC neurons at a relatively high rate of 58.9 ± 11.7 neuronsper square millimeter. Then progressively fewer labeled neuronswere incorporated into HVC, so that in our oldest group of birds,which had settled on their stable adult song, only 10.2 ± 1.8labeled neurons per square millimeter were found in HVC (Table3, Fig. 5). The time course of decline in the number of labeledHVC neurons ipsilateral to the nerve section closely followedthat of intact control animals. On the intact contralateral side,the number of BrdU-labeled neurons was similar to that seen inthe ipsilateral side, except for the group injected with BrdUat days 61-65, which yielded a higher count, as described earlier.A significant difference in neuronal recruitment between ipsilateraland contralateral HVC sides was not evident at any other timepoint (p > 0.31). Interestingly, in unilaterally denervated adultsinjected with BrdU on days 121-124 and killed at day 150, thenumber of BrdU-labeled neurons added to HVC of both operated andunoperated sides was higher than in controls, although only theipsilateral side was significantly different (contra- vs control,p = 0.06; ipsi- vs control, p = 0.02).


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Table 3. Five days of BrdU injections throughout development $right-arrow$ killed 30 d later

Unilateral differences in neuronal recruitment are not accompanied by differences in nuclear diameter, neuronal density, or total neuron number

The treatment groups did not vary with respect to nuclear diameter of new neurons (BrdU+/Hu+) (p = 0.62) or neurons of unknownage (Hu+) at day 91 (p = 0.40; data not shown). We noted, in allgroups, that BrdU+ neurons were significantly larger than therest of the neurons, which has been observed before (p = 0.004)(Kirn et al., 1999). This was accounted for in corrections toestimate total neuron counts, using the mean attained for eachtreatment group (see Materials and Methods). The density of Hu+cells in HVC did not vary between groups at any age (p > 0.21;data not shown). These results allowed us to calculate total neuronnumbers from measures of density and HVCvolume.

The total neuron numbers of the contralateral and ipsilateral side of unilaterally denervated finches were similar at allages sampled, even when recruitment numbers differed (p > 0.31).The total number of HVC neurons of birds that had been unilaterallydenervated was larger at post-hatch day 51 (contra-, p = 0.03;ipsi-, p = 0.015) and post-hatch day 65 (contra-, p = 0.03; ipsi-,p = 0.11) than in age-matched intact controls (Table 3, and Fig.6). There was no difference in the total number of HVC neuronsin controls and in any of the experimental groups at any latersurvival date (from day 71, p > 0.10) (Tables 1-3, Fig. 6).

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Figure 6. The total number of Hu+ cells in HVC increases during the period for song learning. Shown are measurements from four different times during song learning. Intact controls are represented by open squares, and open circles correspond to counts from the HVC ipsilateral to the ts nerve cut; closed circles indicate values from the intact side contralateral to the nerve cut. At post-hatch day 51, the asterisk indicates that the HVC of both sides of denervated birds is significantly larger than that of controls. At day 65, the asterisk indicates that only the HVC contralateral to ts nerve cut is significantly larger than that of controls. After this period there is no significant difference between groups. Error bars indicate SEM.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Several lines of work suggest that HVC adult neuron number is remarkably independent of experience. Burek et al. (1991) showedthat the total number of HVC neurons in zebra finches deafenedearly in ontogeny was no different from that seen in intact controls.In line with this, Brenowitz et al. (1995) showed that marsh wrens(Cistothorus palustris) induced to learn large song repertoireshad no more HVC neurons than those that, because of limited tutoring,had small repertoires. Our observations indicate that the numberof HVC neurons present in adulthood is much the same in intactzebra finches that mastered a model as in those that, becauseof early deafness or syringeal denervation, were unable to imitatea model. Taken together, these observations would seem to closethe door for a possible role of experience in recruitment of newHVC neurons. Yet, a subset of our observations suggests that experienceplays a role in this recruitment, even if this role does not affecteventual neuronnumber.

Unilateral denervation of the syrinx was conceived as a way to reduce variables while still addressing issues related to learning.We reasoned that in the unilaterally denervated birds we wouldbe able to compare neuronal recruitment in a hemisphere directlyinvolved in syringeal control and in one that was not. We reporthere that unilateral denervation affects neuronal recruitmentto HVC during the sensitive period for song learning and thereafter,although it does not appear to affect the total neuron numberin HVC at maturity. We report, too, that this effect occurs onlyif the birds are able to hear themselvessing.

To review, at 51 d of age the total number of HVC neurons was significantly smaller in the intact controls than in eitherside of the unilaterally denervated birds, in which this numberwas already close to that seen in adults (Fig. 6). Yet, at 51d the number of new neurons observed was the same in both groups(Fig. 5). Clearly, the dynamics of addition and replacement musthave differed in the control and experimental birds before day51, although this was not caught by our BrdU injections. Furthermore,although the number of new neurons counted was the same in birdskilled at days 51 and 65 (Fig. 5), the total neuron number wasincreasing in younger controls but not in the denervated birds(Fig. 6). This means new neurons were likely to be added to anolder population of neurons in young controls, whereas they werelikely to be replacing neurons in young denervated birds withmature HVC volume. Differences in total neuron number disappearedafter day 65, and by day 91 the HVC of the intact controls aswell as the HVC ipsilateral and contralateral to the nerve sectionhad the same total neuron number, although recruitment of newneurons during this 30 d period differed. During this time, theHVC still directly involved in syringeal muscle modulation inthe single nerve cut birds recruited 1.9 times more neurons thanthat of controls and 1.6 times more than its disconnected contralateralpartner. By day 150, total HVC neuron numbers stabilized (Fig.6), and yet both HVCs of the unilaterally denervated birds recruitedtwice as many new neurons as that of intact controls, althoughthe absolute numbers of new neurons had decreased in all threecases (Fig. 5).

We only analyzed behavioral performance of our birds at 90 d of age, but birds trained with a tutor usually produce recognizableimitations of the model by days 50-60 and a very close approximationby days 80-90 (Immelmann, 1969; Zann, 1996). Arguably, the fastestoccurring changes take place soon after first exposure to a tutor(Tchernichovski et al., 2001). In our case, by day 90 the unilaterallydenervated birds produced copies of the song of their tutor (father)that, by our measure, were about as accurate as those of intactcontrols and with comparablestereotypy.

Given these observations, three questions come to mind. (1) Why was the effect of experience on neuronal recruitment obviousonly in the unilaterally denervated animals? (2) Why is the effecton recruitment present only late in song acquisition and intoadulthood? (3) Do our observations suggest a role of new neuronsinlearning?

Starting with the first question, three very different kinds of answers come to mind. (1) Increased recruitment on the intactside could result from the additional complexity of imitatinga whole song with only half a syrinx. (2) Denervation of one sidemay provide abnormal feedback to the other one, forcing a deviationfrom the normal modus operandi, and this may affect the recruitmentand replacement of HVC neurons. (3) The single nerve cut may alsoresult in an attentional asymmetry, in that only the intact sidecan guide imitation. Because the asymmetric effect of denervationon new neurons disappeared if the bird was also deafened, someaspect of song imitation, perhaps the guidance of motor outputby auditory feedback, is involved in the differences in recruitmentbetweensides.

In terms of actual mechanisms, differences between the denervated and intact sides could result from differences in electricalactivity, modulatory transmitters, or growth factors that couldaffect new neuron recruitment (Li et al., 2000). Because RA volumeand neuron density did not differ between the intact and denervatedsides, it seems unlikely that asymmetries in neuronal recruitmentresulted from differences in the innervation target space of theHVC.

The second question is about the timing of the effect on new neuron recruitment. The increase in new recruitment found inunilaterally denervated birds occurred late in song learning,when song becomes increasingly stereotyped. We expected that ifunilateral denervation affected neuronal recruitment, its consequenceswould also be evident in our youngest groups of animals, in whomthe highest availability of new neurons coincided with the bird'searliest attempts to match a model and the corresponding markedchanges in vocal output. Yet, this was not so. It is possiblethat the achievement of stereotypy makes different demands onHVC circuitry than the process that occurs when song motor skillsare first developed (Pytte and Suthers, 1999). The neural eventsleading to song crystallization may be more sensitive to informationquantity and sensory feedback than is the case when circuits arebeing built, when perhaps an intrinsic ontogenetic program hasprecedence over experience. In adult canaries, peaks in new neuronrecruitment occur slightly later than peaks in new syllable recruitmentand probably correspond more to the time when syllables becomemore stable, rather than when they first appear (Kirn et al.,1994). To achieve stereotypy, HVC may have to shed "incorrect"neurons and replace them by others that fortify the "correct"circuitry that survives. The idea is that a greater number ofneurons doing the same thing brings stability (stereotypy) toa program's performance. If so, then the story starts with culling,and we get a readout of differences in culling activity by lookingat the survival of replacement neurons; in other words, the deadexplain theliving.

The third question is related to the previous two: do our observations suggest a role of new neurons in learning? Our dataand those from others strongly suggest that there is a programfor producing an adult HVC that occurs even in the absence ofvocal learning. This would explain why we see no difference inneuronal recruitment after deafening, bilateral denervation, oron the operated side after unilateral denervation. The total numberof neurons in HVC might be determined by a ratio of new neuronsto a fixed population of older neurons (Scharff et al., 2000).This fixed population could be, in HVC, the Area X-projectingneurons, which are formed mostly before the bird hatches (Alvarez-Buyllaet al., 1988) and are found in clusters with other HVC neurons(Kirn et al., 1999). We suggest that in the absence of learning(e.g., in the deaf or bilaterally denervated birds), neurons areculled and replaced in a stochastic manner. In contrast, as normalbirds learn their song, the neuron culling and replacement maybe more selective, based on use by the circuitry that producesthe learnedsounds.

To see the effect we describe, we had to create an asymmetry. Does the outcome reveal something about the forces that normallygovern the recruitment of neurons during ontogeny and in adulthood,or have we created a phenomenon more akin to a pathology thanto the normal workings of the brain? After section of one tracheosyringealnerve, the syringeal muscles on that side atrophied. Yet, asymmetryin neuronal recruitment occurred only if the animal could hear.This suggests that differences in neuronal recruitment reflectthe active process of song imitation and not simple pathologycaused by muscle atrophy on one side. If precedent serves, pathologiesresult from the basic properties of systems, rather than beinginduced by these properties de novo. Our observations suggestthat a degree of flexibility in the culling and replacement ofneurons in an intact part of the brain can be brought about bya lesion elsewhere in the brain. In time, this kind of responsecould be instructive as a vehicle to reinstate lost functionsafter braininjury.

It is clear that an experience-independent adult neuron number can emerge from an experience-dependent recruitment process.We suggest that in future studies much more attention will haveto be paid to the mechanisms that determine which of the manyneurons produced during ontogeny and in adulthood survive andfor how long. This more detailed approach will be necessary todetermine how the culling and incorporation of new neurons arerelated to the acquisition and maintenance of learned skills.It is clear that data on total numbers alone miss much of thestory.

  FOOTNOTES

Received July 6, 2001; revised Nov. 2, 2001; accepted Nov. 6, 2001.

This work was supported by a National Science Foundation Graduate Research Fellowship to L.W., by Public Health Service GrantMH18343, and by generous support from Howard Phipps and the MaryFlagler Cary Charitable Trust. We thank Constance Scharff, DavidVicario, and Phil Pierre for insightful discussion and comments.Special thanks for management of injections and attentive birdcare to Daun Jackson, Sharon Sepe, Helen Ecklund, and Chris Mooreand the staff of the Rockefeller University Field ResearchCenter.
Correspondence should be addressed to Linda Wilbrecht, The Rockefeller University, 1230 York Avenue, Box 153, New York, NY10021. E-mail: wilbrel{at}mail.rockefeller.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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Copyright © 2002 Society for Neuroscience 0270-6474/02/223825-07$05.00/0

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