Remodeling of Membrane Properties and Dendritic Architecture Accompanies the Postembryonic Conversion of a Slow into a Fast Motoneuron

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The Journal of Neuroscience, September 15, 2000, 20(18):6950-6961

Remodeling of Membrane Properties and Dendritic Architecture Accompanies the Postembryonic Conversion of a Slow into a Fast Motoneuron
Carsten Duch and R. B. Levine
Division of Neurobiology, University of Arizona, Tucson, Arizona 85721

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The postembryonic acquisition of behavior requires alterations in neuronal circuitry, which ultimately must be understoodas specific changes in neuronal structure, membrane properties,and synaptic connectivity. This study addresses this goal by describingthe postembryonic remodeling of the excitability and dendriticmorphology of an identified motoneuron, MN5, which during themetamorphosis of Manduca sexta (L.) changes from a slow motoneuronthat is involved in larval-crawling behavior into a fast adultflight motoneuron. A fivefold lower input resistance, a higherfiring threshold, and an increase in voltage-activated K⁺ current contribute to a lower excitability of the adult MN5,which is a prerequisite for its newly acquired behavioral role.In addition, the adult MN5 displays larger Ca²⁺ currents. The dendrites of MN5 undergo extensive remodeling.Drastic regression of larval dendrites during early pupal stagesis followed by rapid growth of new dendrites. Critical changesin excitability take place during the onset of adult dendriteformation. Larval Ca²⁺ currents are absent when dendritic remodeling is most dramaticbut increase markedly during later development. Changes in Ca²⁺ and K⁺ currents follow different time courses, allowing the transientoccurrence of Ca²⁺ spikes during pupal stages when new dendritic branching ceases.The adult MN5 can produce prolonged Ca²⁺ spikes after K⁺ currents are reduced. We suggest that alterations in Ca²⁺ and K⁺ currents are necessary for the participation of MN5 in flightbehavior and that the transient production of Ca²⁺ spikes may influence postembryonic dendriticremodeling.

Key words: postembryonic development; calcium current; potassium current; neuronal differentiation; insect; Manduca sexta; CNS; flight behavior

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Changes in the excitability and dendritic architecture of central neurons accompany the development and plasticity of behavior(McCobb et al., 1989, 1990; Baines and Bate, 1998; Gao and Ziskind-Conhaim,1998; Reynolds et al., 1998; Sun and Dale, 1998; Martin-Caraballoand Greer, 1999). As neuronal structure, biophysical properties,and synaptic interactions differentiate or are modified postembryonically,the activity patterns of the mature CNS emerge (Casanovas andMeyrand, 1995). These emergent activity patterns, in turn, influenceneuronal differentiation (Spitzer, 1991; Ribiera and Spitzer,1992; Muller et al., 1998). Activity-dependent Ca²⁺ influx controls neuronal growth (Cohan et al., 1987; Mattsonet al., 1988; Fields et al., 1990; Haydon and Zoran, 1994), andtransient patterns of electrical activity regulate synaptic input(Shatz, 1990). A satisfactory understanding of these interdependentprocesses requires a detailed description of the temporal relationshipbetween the structural and functional remodeling of identifiedneurons in a behavioralcontext.

Although behavior changes postembryonically in all organisms, the particularly extreme example of metamorphosis offers a uniquemodel system for such studies. In holometabolous insects the participationof central neurons in larval behavior ceases as novel behavioris acquired during postembryonic life (Weeks and Levine, 1990).For example, in Manduca sexta (L.), five motoneurons that innervateslowly contracting muscles of the larval dorsal body wall persistthroughout metamorphosis to innervate the new, fast-contracting,dorsal longitudinal flight muscle (DLM) of the adult (Casadayand Camhi, 1976; Rheuben and Kammer, 1980; Duch et al., 2000).Identified flight motoneurons, such as MN5, mediate slow toniccontractions of larval target muscles during crawling but fasttwitch contractions of newly generated adult target muscles duringflight.

Many motoneurons that survive metamorphosis to participate in adult-specific behavior undergo dendritic remodeling (Levineand Truman, 1982, 1985; Truman and Reiss, 1988; Weeks and Ernst-Utzschneider,1989; Kent and Levine, 1993). Little is known, however, aboutelectrophysiological changes that may accompany structural remodelingand the development of new behavior. The isolated somata of culturedManduca leg motoneurons display differences in ionic currentsamong different developmental stages (Hayashi and Levine, 1992),some of which are mediated by the steroid hormone 20-hydroxyecdysone(Grünewald and Levine, 1998). The functional consequences ofsuch changes have yet to be determined, however, and it is notclear how accurately the characteristics of isolated motoneuroncell bodies reflect the properties of cells undergoing the normalremodeling of dendrites and synaptic interactions in vivo.

This study describes both the dendritic remodeling of MN5 and changes in its membrane properties that are appropriate forthe postembryonic conversion of a slow into a fast motoneuron.Moreover, specific changes in excitability and voltage-dependentionic currents are correlated temporally with critical phasesof dendriticremodeling.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals. Manduca sexta obtained from a laboratory culture were reared on an artificial diet (Bell and Joachim, 1976) undera long-day photoperiod regimen (17:7 hr light/dark cycle) at 26°Cand ~60% humidity. Both chronological and morphological criteriawere used for the staging of animals (Nijhout and Williams, 1974;Bell and Joachim, 1976; Tolbert et al., 1983; Consoulas et al.,1996). In summary, L5 represents the fifth larval instar, W0 signifiesthe first day of wandering, and W1 to W4 represent the remaining4 d of wandering. P0 indicates the day of the pupal molt, andP1 to P18 are the following 18 d of adultdevelopment.

Dissection for intracellular recordings. The animals were anesthetized by chilling on ice for 15 min. Animals were dissectedalong the dorsal midline and superfused with saline. The thoracicand the first two abdominal ganglia were removed, transferredinto a Sylgard-coated Petri dish, and pinned down at the cut endsof their lateral nerves in saline. The ganglionic sheath was removedmechanically with a fine pair of forceps. Nerve 1 of the mesothoracicganglion was left intact toward its specific peripheral branchthat contains only the axons of the five DLM motoneurons (Duchet al., 2000). MN5 is the only motoneuron in the mesothoracicganglion that carries an axon in this particular nerve branch(Duch et al., 2000). Antidromic stimulation from this nerve branchwas used to identify MN5 during intracellularrecordings.

Intracellular staining techniques. Rhodamine Dextran 3000 (Molecular Probes, Eugene, OR) was used for all intracellular stainings.The tips of thin-walled borosilicate electrodes (resistances,20-25 M $Omega$ ) were filled with 5% dextran in 1 M potassium acetate.The electrode shafts were filled with 1 M potassium acetate, andan air bubble was left between the tip and the shaft to preventdye dilution. After intracellular penetration and antidromic identificationof MN5, dye was injected iontophoretically by applying depolarizingcurrent pulses of 3-4 nA amplitude and 200 msec duration witha frequency of 2.5 Hz for 30-60 min. After dye injection, gangliawere left in saline for an additional 30 min to allow dye diffusion.Subsequently, ganglia were fixed in 4% paraformaldehyde and washedthree times in 10 mM PBS, pH 7.4, for 15 min each. Then preparationswere dehydrated in ethanol, cleared in methyl salicylate, andmounted in Permount (Fisher Scientific, Fair Lawn,NJ).

Confocal microscopy. Digital images were captured on a Nikon PCM 2000 laser-scanning confocal microscope using Simple PCI(Compix, Tualatin, OR) image acquisition software. Images werefurther processed using Corel Draw 8 software (Corel, Ottawa,Ontario, Canada). Preparations were scanned with a helium-neonlaser line with an excitation maximum at 546 nm using a long-passfilter at 565 nm. All preparations were scanned with a 40× lensat optical planes of 1 µm. All images shown are the projectionsof all optical planes of a given stack into one focal plane, toshow the entire dendritic field in one two-dimensionalimage.

Electrophysiology. An Axoclamp 2B amplifier (Axon Instruments, Foster City, CA) was used for all recordings. Synaptic potentialsand spike shapes were recorded in bridge mode with the same electrodeshapes used for intracellular dye injections (see above), butelectrode tips were coated with silicon oil. Input resistancewas determined in discontinuous current-clamp mode (DCC) to avoidthe problem of an inadequate bridge balance, which can occur becauseof changes in electrode resistance while penetrating the ganglionictissue. Electrodes with resistances between 20 and 25 M $Omega$ werefilled either with 1 M potassium acetate or with 5% rhodaminedextran in 1 M potassium acetate. No differences between thesemethods were observed. Sampling rates between 3.5 and 5 kHz werereached without any signal cutoff. The slope input resistancewas calculated from the linear portion of the voltage/currentrelationship using 0.2 nA current steps between $-$ 2 and +0.2 nA.The firing threshold was measured as the minimum depolarizationfrom the resting potential necessary to trigger an actionpotential.

Voltage-activated Ca²⁺ and K⁺ currents were measured in discontinuous single-electrode voltage-clamp mode (dSEVC). Electrodesof 12-15 M $Omega$ resistance were filled with 2 M potassium acetate(for measuring K⁺ current) or with 1.5 M cesium chloride (for measuring Ca²⁺ currents). In dSEVC mode, sampling rates of 3.5-5 kHz could beused without any signal cutoff. The amplifier was controlled usingpClamp8 software (Axon Instruments) running on an IBM-compatiblepersonal computer. A linearly scaled leak current obtained fromhyperpolarizing steps from $-$ 60 to $-$ 90 mV was subtracted from eachcurrent trace before further analysis with Clampfit8 (Axon Instruments).All traces shown are averages of at least four trials. All recordingswere made at room temperature (22-25°C).

Solutions. External saline for dissection and recording consisted of (in mM): 140 NaCl, 5 KCl, 4 CaCl₂, 28 D-glucose, and5 HEPES; pH was adjusted to 7.4 with 1 M NaOH. K⁺ conductance saline contained (in mM): 140 NaCl, 5 KCl, 4 MgCl₂,28 D-glucose, 5 HEPES, and 0.5 CdCl₂. Ca²⁺ conductance saline contained (in mM): 110 NaCl, 5 KCl, 4 MgCl₂,28 D-glucose, 5 HEPES, and 30 tetraethylammonium chloride (TEA;Sigma, St. Louis, MO). After antidromic identification of MN5,a small volume of concentrated tetrodotoxin (TTX; 10² M in H₂O; Sigma) was added to achieve a final concentration of10⁸ M in thebath.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Differences in excitability between the larval and the adult MN5

The excitability of MN5 changed during postembryonic life. In the isolated ganglion preparation, the larval MN5 received manysynaptic inputs and fired spontaneously (n = 8), whereas the adultMN5 received fewer synaptic inputs, and no spontaneous actionpotentials were observed in any of 12 preparations (Fig. 1A).In addition the resting membrane potential of the adult MN5 wasmore hyperpolarized than was that of the larval MN5 (Fig. 1A,F).The larval MN5 displayed tonic firing in response to current injectioninto the soma (Fig. 1C). In contrast, the adult MN5 required currentinjection of higher amplitudes and responded only occasionallywith a single spike (Fig. 1D). The larval MN5 had a linear current/firingfrequency relationship between 0.5 and 2.5 nA current injection,before reaching a maximal firing frequency of ~60 Hz (Fig. 1E).In contrast, in the adult MN5 only two spikes per second occurredon average at 3 nA of current injection (Fig. 1E). The lower excitabilityof the adult MN5 was caused in part by its lower resting membranepotential and its higher firing threshold. The membrane voltagedifference between the resting potential and firing thresholdwas 33 mV for the adult but only 11 mV for the larval MN5 (Fig.1F).

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Figure 1. Excitability of the "slow" larval and the "fast" adult MN5. A, Representative intracellular recordings of spontaneous activity recorded from the cell body in the larval (top trace) and the adult (bottom trace) MN5 in the isolated ganglion preparation. B, Larval (dotted lines) and adult (solid lines) orthodromically and antidromically evoked spikes. Each trace represents a signal average of eight spikes taken from a representative recording. C, D, Representative responses of the larval (C) and the adult (D) MN5 to current injection into the soma. E, Injected current plotted against evoked firing frequency (I/F relationship). Top, I/F relationships for the larval and the adult MN5 created from five recordings each. Bottom, The adult I/F relationship shown again at an expanded scale. F, Average resting potential and average firing threshold for the larval and the adult MN5. Error bars represent SDs. The average voltage difference between the resting potential (RP) and the firing threshold (FTR) is defined as $Delta$ V_m and indicated by gray bars. G, Average spike amplitude (millivolts) and average spike duration at half amplitude (milliseconds) for the antidromically and for the orthodromically evoked spike of the larval (white bars) and the adult (gray bars) MN5. Statistically significant differences between the larval and the adult stages are indicated by asterisks (p < 0.001). Error bars represent SDs.

Spike shape differed significantly between the larval and the adult stage (Fig. 1B,G). Antidromically evoked spikes displayeda threefold longer duration at half amplitude in the adult. Spikesevoked by current injection into the soma had a twofold longerduration in the adult. Spike amplitude did not differ significantlybetween stages. Neither the orthodromic nor the antidromic spikeswere Ca²⁺ dependent, because replacing Ca²⁺ with Mg²⁺ had no effect on spike shape in either developmental stage. TTXblocked the spikes at bothstages.

Remodeling of the dendrites of MN5

The adult MN5 was significantly larger than the larval MN5 (Fig. 2B). In both stages the cell body was located on the contralateralside of the mesothoracic ganglion in relation to the target muscle.The elaborate dendritic field was located ipsilateral to the targetmuscle. All compartments, including dendrites, axon, and cellbody, of the adult MN5 were larger than those of the larval MN5[quantitative morphometric analysis (F. Libersat and C. Duch,unpublished results)]. This was correlated with an increase inganglionic size between the larval and the adult stage. To understandwhether the changes in the excitability of MN5 were caused bythe increase in cell size during metamorphosis or by changes inmembrane properties, we studied the active and passive membraneproperties and the morphology of MN5 throughout postembryonicdevelopment.

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Figure 2. A, Schematic drawing of the arrangement of the five motoneurons that innervate the mesothoracic DLM. MN5 is the only DLM motoneuron that is located in the mesothoracic ganglion and that can, therefore, be individually identified by antidromic stimulation throughout all developmental stages. B, Confocal images of the adult and the larval MN5. Inset, High-order branches of the adult MN5 depicted in a selective enlargement (region enclosed in the dotted line in the adult image; see asterisk).

Although the larval and the adult MN5 exhibited similarities in their central projections, the dendritic field underwent drasticremodeling during metamorphosis. The end of larval life was accompaniedby a regression of most larval dendrites (Fig. 3). No changesin the dendritic architecture were observed until stage W2 (Fig.3). Dendritic regression started on the third day of the wanderingphase (Fig. 3, W3). All secondary and higher order dendrites becamethicker and more compact as compared with earlier larval stages(Fig. 3, larva, W2). Two days later in development, on the firstday of pupal life (Fig. 3, P0), most secondary and higher orderlarval dendrites were lost, although the length of the primarydendrite remained relatively constant. During the following 2d of pupal life (Fig. 3, P1, P2) dendritic regression continued,and the primary dendrite became shorter. The third day of pupallife (Fig. 3, P2) was the stage of maximal dendritic regression.The following 6 d of pupal life were accompanied by dramatic dendriticbranching and growth (Fig. 4). At early stage P3 the dendritesformed growth cone-like structures at their tips and began togrow. These growth cone-like structures (see Fig. 4, inset) wereobserved between pupal stages P3 and P5 (Fig. 4), although dendriticgrowth and the sprouting of higher order dendrites continued atleast until pupal stage P8 (Fig. 4). Dendritic branching ceasedbetween pupal stages P8 and P10 (Fig. 4). Therefore, most adultdendrites were formed by 40-50% of pupal life, although the dendrites,the neurite, and the cell body grew in overall size until pupalstage P16.

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Figure 3. The larval dendrites of MN5 are retracted during late larval and early pupal life. Confocal images of the dendritic region of MN5 taken from representative preparations of sequential stages between the fifth larval instar and the third day of pupal life (P2). All images are projections of all optical planes of each preparation (see Materials and Methods). The cell body is located to the right, and the axon is leaving the field of view to the left.

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Figure 4. Sprouting and subsequent growth of new adult dendrites during pupal life. Confocal images of the dendritic region of MN5 taken from representative preparations of sequential stages between the third day of pupal life (P2) and adulthood. All images are projections of all optical planes of each preparation (see Materials and Methods). Inset (bottom left), The region enclosed in the dotted line in the stage P3 early preparation. Note the growth cone-like structure at the tip of the growing dendrite. Filopodia-like processes are marked by arrows.

Changes in electrical properties of MN5

The adult MN5 had a fourfold to fivefold lower input resistance as compared with the larval MN5 (Fig. 5A), perhaps contributingto its lower excitability (Fig. 1C-E). To test whether this wassimply a consequence of the larger size of the adult motoneuron,the input resistance of MN5 was followed throughout development.Input resistance did not decrease gradually while MN5 was growingbut instead decreased dramatically between pupal stages P2 andP3 (Fig. 5C), although the cell body size increased graduallythroughout all stages of metamorphosis (Fig. 5B) and the dendritesgrew between pupal stages P2 and P16 (Fig. 4). Therefore, theabrupt decrease in input resistance within 1 d of pupal life wasnot caused simply by a sudden increase in cell size. By comparison,variations of input resistance that occurred during other developmentalstages were minor (Fig. 5C).

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Figure 5. Changes in input resistance during postembryonic development. The input resistance of MN5 was recorded in DCC mode at different developmental stages. A, Representative voltage responses of MN5 at the larval stage, pupal stage P3, and the adult stage to 12 steps of current injection between $-$ 2 and 0.2 nA. B, Confocal images of the cell bodies of MN5 at different developmental stages. C, Average input resistances for different developmental stages. The number of recordings for each group is presented above each bar. Error bars represent SDs.

The active properties of MN5 were also modified during postembryonic life. Spike shape differed not only between the larvaland the adult stage (Fig. 1) but changed more drastically duringspecific pupal stages (Fig. 6). Before pupal stage P2, the spikeshape, the tonic firing response of MN5, and the spontaneous patternsof postsynaptic potentials (PSPs) remained larval-like (Fig. 6A,B).In fact, MN5 received many PSPs at all stages of dendritic regression(Fig. 6B, P1). At pupal stage P3, which also marked the onsetof dendritic growth, both the amplitude and duration of the spikesincreased (Fig. 6C). Furthermore, MN5 responded phasically ratherthan tonically to current injection (Fig. 6C,D). This change inresponsiveness to current injection was correlated in time withthe large decrease in input resistance (Fig. 5).

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Figure 6. Developmental changes in firing responses of MN5. Representative intracellular recordings of firing responses of MN5 to somatic current injections at different developmental stages (A, larval stage; B, P1; C, P3; D, P4; E, P8; F, P16). In all preparations, MN5 was stimulated by square-pulse current injections into the soma at ~0.5 nA above the firing threshold, as indicated below each voltage trace. The horizontal dotted lines indicate the resting membrane potentials. The vertical bars in D and E indicate where the action potential amplitude was measured. At pupal stage P3 (C), action potential amplitude and width increase, and MN5 responds phasically rather than tonically as compared with earlier stages (A, B). A longer current pulse was injected in C and D to illustrate this fact. At pupal stage P8 (E), large-amplitude action potentials were evoked (arrows). At pupal stage 16 (F), MN5 fired only occasionally after current injections into the soma.

A dramatic change in spike shape occurred during pupal stages P7 to P9, when dendritic sprouting ceased. At pupal stage P8,action potential amplitude was eightfold larger than that at pupalstage P4, measured as the distance from firing threshold to peak(see Fig. 6D,E, vertical bars). This prominent action potential,which was always followed by an afterhyperpolarization, occurredonly during pupal stages P7 to P9 and was not affected by bathapplication of TTX. In contrast, at all other stages the actionpotentials could be blocked by bath application of TTX (10⁸ M). In 3 out of 12 recordings of MN5 at pupal stages P7, P8,and P9, fast events were clearly visible on top of the prominentTTX-independent action potential (see Fig. 6E, arrows). Thesefast events could be blocked by bath application of TTX. Frompupal stage P10 onward, the action potential was of the adultshape and amplitude (Fig. 6F). Furthermore, the low excitabilityof the adult MN5 (Fig. 1) was established by pupal stages P10toP11.

Unlike the small Na⁺-dependent action potentials that ordinarily invade the somata of insect motoneurons passively, the prominentTTX-independent action potentials that occurred between pupalstages P7 and P9 were dependent on external Ca²⁺ (Fig. 7). Replacing Ca²⁺ with Mg²⁺ in the bath led to a reduction in spike amplitude (Fig. 7A).Figure 7B shows selective time points of the continuous recordingshown in Figure 7A. In regular saline, four large-amplitude actionpotentials were evoked by somatic current injection. Thirty secondsafter Ca²⁺ was replaced with Mg²⁺ only the first two of the four spikes were of full amplitude,and by 90 sec none of the four spikes was of full amplitude (Fig.7B). The small action potentials that remained could be blockedfully by bath application of TTX (10⁸ M; data not shown). Replacing Mg²⁺ with Ca²⁺ in the bath led to a full recovery of the action potential amplitude(Fig. 7A,B). Addition of the nonspecific Ca²⁺ current blocker Cd²⁺ [0.5 mM (Hayashi and Levine, 1992)] to the bath solution reducedthe spike amplitude irreversibly (Fig. 7C). Between pupal stage10 and the adult, the action potentials were not dependent onexternal Ca²⁺, and Cd²⁺ did not affect their shape, but they could be blocked by TTX.Therefore, we use the term "Ca²⁺ spike" for the Ca²⁺-dependent action potential that occurs only at the pupal stagesP7, P8, and P9, and the term "Na⁺ spike" for the TTX-sensitive action potentials.

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Figure 7. MN5 exhibits Ca²⁺ action potentials at pupal stages P7-P9. A, Representative continuous intracellular recording of MN5 at pupal stage P8. Somatic current injection (bottom trace) of 400 msec duration at 0.6 Hz led to bursts of four large action potentials (top trace). Replacing external Ca²⁺ with Mg²⁺ (see left arrow) reduced the action potential amplitude significantly. This effect was reversed when Mg² was replaced with Ca²⁺ (see right arrow). B, Single bursts taken at selected time points from the continuous recording shown in A. C, Cd²⁺ (0.5 mM) shown blocking the Ca²⁺-dependent component of the action potential in a recording of MN5 at pupal stage P7. D, A spontaneous action potential from a representative recording of MN5 at pupal stage P8 (left) and responses to electrical stimulation of a sensory nerve (right). Both subthreshold postsynaptic responses and Ca²⁺-dependent action potentials occurred in response to sensory stimulation.

The transient Ca²⁺ spike could not only be evoked by current injection into the soma of MN5 but also occurred spontaneouslyand could be elicited by stimulation of sensory nerves (Fig. 7D).Between pupal stages P7 and P9, the action potential thresholdwas $-$ 41 ± 4 mV (n = 8), and the average resting potential was54 ± 3 mV (n =12).

The size of the Ca²⁺ spike increased continually from late pupal stage P6 to pupal stage P8 (Fig. 8A). Replacing Ca²⁺ with Mg²⁺ in the bath did not affect the spike shape at early pupal stageP6 (Fig. 8A). Approximately 12 hr later in development ~30% ofthe action potential amplitude was Ca²⁺ dependent (Fig. 8A). At pupal stage P7, 60% and, at pupal stageP8, 80% of the spike amplitude was Ca²⁺ dependent. The Ca²⁺ component was absent in the small action potentials recordedfrom MN5 later than pupal stage P10. However, in these later pupalstages and in the adult, it could be unmasked by bath applicationof TEA (Fig. 8B). This suggests that an increase in K⁺ current at approximately pupal stage 10 ordinarily masked theCa²⁺ spike. In vivo voltage-clamp experiments were performed to revealthe ionic currents underlying the transient Ca²⁺ spike during postembryonic dendritic remodeling of MN5.

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Figure 8. The amplitude of the Ca²⁺ spike increases between P6 and P8. A, Ca²⁺ was replaced with Mg²⁺ in recordings of MN5 at the pupal stages P6 early, P6 late, P7, and P8. Removal of external Ca²⁺ reduced the action potential amplitude at P6 late, P7, and P8. The action potential amplitude increased between P6 and P8 (top row; indicated by horizontal dotted lines). Similarly, the Ca²⁺ dependence of the action potential amplitude increased continuously between P6 and P8 (middle row) as indicated by the gray-shaded area. At all stages between P6 early and P8, the reduction in action potential amplitude in the absence of external Ca²⁺ was fully reversible (bottom row). B, Left, The representative response of the adult MN5 to current injections into the soma is shown. Right, Five minutes after bath application of TEA (30 mM), the same MN5 responded with Ca²⁺-dependent action potentials to current injections.

Changes in calcium and potassium currents during adult development

For the analysis of Ca²⁺ currents, TTX (10⁸ M) was added to the bath to block fast Na⁺ currents, electrodes were filled with 1.5 M CsCl, and TEA wasapplied to the bath (30 mM). Nevertheless, outward currents werenot blocked completely (Fig. 9A). After obtaining these records,therefore, Ca²⁺ currents were blocked with Cd²⁺ (0.5 mM), and the residual outward current was subtracted (Fig.9A) to allow calculation of the total Ca²⁺ current. Because there are some limitations to current analysisusing single-electrode voltage-clamp recordings in situ, the actualmembrane voltage was monitored (Fig. 9A, top traces) to detectdeviations from the command potential. The actual membrane voltagesfor commands between $-$ 10 and 10 mV revealed slight depolarizingdeflections during the maximum Ca²⁺ currents, but these were always <5 mV (Fig. 9A, top traces, arrow).Therefore, the voltage-clamp control was adequate for comparinglarge differences in Ca²⁺ currents among developmental stages. The differences betweenthe command and actual holding potential were consistent withina developmental stage, but the actual voltages reached for depolarizingcommands above $-$ 20 mV differed among different developmental stages.Therefore, the instantaneous actual membrane voltage was usedfor the analysis of current/voltage relationships (see Fig. 9C).

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Figure 9. Developmental modifications of calcium currents in MN5. A, Representative membrane current (I_m) recordings in dSEVC mode of MN5 at pupal stage P7 to demonstrate the method used for isolating Ca²⁺ currents (see Results). The actual membrane potential was monitored in all experiments. Slight voltage fluctuations were sometimes observed at the membrane potentials at which the maximum Ca²⁺ currents occurred, but these were always <5 mV (see arrow). B, Representative traces of inward currents for different developmental stages after subtraction (see A). The time points where peak and sustained Ca²⁺ currents were measured are indicated with arrows. C, I-V relationships for the peak Ca²⁺ current created from four recordings each in the larval stage, pupal stages P4 and P8, and the adult. D, Average peak and sustained Ca²⁺ currents for different developmental stages. The number of recordings for each group is presented below each set of bars. Error bars represent SDs.

The larval MN5 displayed a sustained Ca²⁺ current that was activated at approximately $-$ 35 mV and peaked at ~5 mV (Fig. 9B,C).This corresponds to the description of Ca²⁺ currents in cultured leg motoneurons of Manduca sexta larvae,as measured from isolated somata with patch pipettes (Hayashiand Levine, 1992; Grünewald and Levine, 1998). No Ca²⁺ current was detected at pupal stages P3 and P4 (Fig. 9B-D). Twodays later, at late pupal stage P6, Ca²⁺ currents were again expressed (Fig. 9B). The activation and thepeak voltage were similar to the larval Ca²⁺ current, but the peak amplitude was twice as large (Fig. 9B).Furthermore, a transient component appeared in addition to thesustained Ca²⁺ current (Fig. 9B, arrows), although the components have not beenseparated pharmacologically or electrically. The amplitude ofthe transient Ca²⁺ current increased until pupal stage P8 (Fig. 9B-D). The occurrenceof the maximum peak Ca²⁺ current correlated with the prominent Ca²⁺ spike at pupal stage P8. Neither the transient nor the sustainedcomponent of the Ca²⁺ current changed significantly during further development (Fig.9B-D), even though action potentials did not have a Ca²⁺ component from pupal stage P11 onward. Because a large Ca²⁺-dependent action potential could be unmasked by bath applicationof TEA at all developmental stages beyond P11, there may be anincrease in voltage-activated K⁺ currents between pupal stages P10 andP11.

To test this hypothesis, we compared the K⁺ currents of MN5 at pupal stage P4 (no Ca²⁺ current present), pupal stage P8 (Ca²⁺ currents fully developed and Ca²⁺ spike present), and pupal stage P12 (Ca²⁺ currents fully developed but no Ca²⁺ spike present). K⁺ currents were measured with TTX (10⁸ M) and Cd²⁺ (0.5 mM) in the bath solution. In contrast to the absence ofvoltage-activated Ca²⁺ currents at pupal stage P4, two different components of voltage-activatedoutward currents, a fast transient and a slower sustained component,were present at this developmental stage (Fig. 10A). Bath applicationof TEA (30 mM) blocked most of the sustained component, but thetransient component was also reduced (Fig. 10A). Subtraction ofthe TEA-insensitive outward current from the total outward currentrevealed the TEA-sensitive sustained component (Fig. 10A). Althoughthe transient and the sustained components were not isolated completely,they probably correspond to the "A-current" and the "delayed rectifier"K⁺ current revealed by patch-clamp analysis of isolated Manducaleg motoneurons (Hayashi and Levine, 1992; Grünewald and Levine,1998).

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Figure 10. Developmental modifications of potassium currents in MN5. A, Panel 1, Total potassium current was recorded in dSEVC mode from MN5 at pupal stage P4 with TTX (10⁸ M) and cadmium (0.5 M) in the bath. Panel 2, Bath application of TEA (30 mM) affected the sustained component of the outward current significantly, although the transient component was also reduced. Panel 3, Subtraction of the residual transient component from the total outward current revealed the sustained component. B, I-V relationships for the total potassium current (see traces in A) at pupal stages P4, P8, and P12 are shown. Total current was measured at 350 msec of each voltage step (see arrow in A) and plotted against the actual instantaneous membrane potential (see Results). Five recordings were plotted for each stage, and curves were fitted using the simplex method. The I-V relationships for pupal stages P4 and P8 showed no significant difference, but the fitted curve for pupal stage P12 was significantly steeper. C, Typical current responses of MN5 at the stages P4, P8, and P12 are shown after bath application of TTX and cadmium to voltage steps from a holding potential of $-$ 50 mV to an actual membrane potential of $-$ 25 mV. The bottom traces show the voltages recorded at the three different stages, and the top traces show the current responses.

In MN5 both components were present at all developmental stages between P4 and adult (data not shown). Earlier stages werenot examined in this study. Because of contamination of the transientcurrent by the rising phase of the sustained component and nonspecificpharmacological blocking of both components by TEA and 4-AP, thedevelopmental fate of the individual components could not be investigatedseparately. Therefore, the net outward current at 350 msec wasmeasured (see Fig. 10A, arrow). Currents were plotted against theactual voltage because of variable differences between the commandpotential and the actual membrane potential among different recordings.The I-V relationships revealed no significant differences betweenpupal stages P4 and P8. In contrast, the net K⁺ current was increased at pupal stage P12 because the slope ofthe fitted curve became significantly steeper (Fig. 10B). Becauseof this increase in K⁺ current, the membrane voltage could not be held at values depolarizedmore than $-$ 22 mV using the single-electrode voltage-clamp technique,which allowed a maximum current of ~20 nA to pass. At pupal stageP12, the K⁺ currents reached a peak amplitude of 20 nA at $-$ 22 mV. In contrast,at pupal stages P4 and P8, maximum currents of ~20 nA were reachedat approximately $-$ 10 mV. It is not clear whether the increasein K⁺ current measured after 350 msec of each voltage step was causedby an increase in the sustained component or by a decrease inthe inactivation of the transient component. However, total K⁺ current was clearly larger at pupal stage P12 than at pupal stagesP4 and P8 (Fig. 10B,C). This agrees with the finding that the Ca²⁺ spike disappeared at stages later than pupal stage P10 but couldbe unmasked by bath application of TEA (Fig. 8B).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

MN5 develops from a slow to a fast motoneuron

The dendritic morphology and electrophysiological properties of MN5 change during postembryonic life. MN5 is more readilyexcitable in the larva than in the adult. Insect and crustaceanmotoneurons that innervate slowly contracting muscles are typicallymore excitable than those innervating rapidly contracting muscles.Slow or "tonic" motoneurons spike continuously during locomotion,whereas "phasic" motoneurons fire single spikes or brief burststo induce rapid muscle contractions (Kennedy and Takeda, 1965a,b;Meyer and Walcott, 1979; Atwood and Wojtowicz, 1986; Burrows,1996). In crustaceans, slow neuromuscular junctions can be convertedinto fast ones in an activity-dependent manner during postembryoniclife (Lnenicka and Murphey, 1989). Here, we show that the excitabilityof an identified motoneuron can be modified according to changesin its behavioral function during postembryonic development. Itslarval target muscle is involved in slow crawling movements (Kammerand Rheuben, 1976; Rheuben and Kammer, 1980), in which it mustmaintain tonic tension. In contrast, flight motoneurons ordinarilyfire once to twice per wing-beat cycle to mediate fast twitchcontractions but no muscle tonus (Zarnack and Möhl, 1977; Burrows,1996).

The lower excitability of the adult MN5 is caused by a more hyperpolarized resting potential, a more depolarized firing threshold,and a fivefold lower input resistance. Major decreases in inputresistance and tonic firing occur during the onset of dendriticgrowth, but input resistance remains relatively constant throughoutall later stages despite significant cell growth. Therefore, changesin excitability are not simply reflective of changes in cell size.The excitability of MN5 is adult-like at pupal stage P11. Thiscorrelates with an increase in the net K⁺ current between pupal stages P8 and P12. Similarly, in Xenopusembryonic development, modifications in K⁺ currents in spinal neurons are correlated with the maturationof motor patterns (Sun and Dale, 1998). For MN5, the low excitabilityduring late pupal stages is important because contractions ofthe pupal DLM muscle, which is striated and functionally innervatedby pupal stage P8 (Duch et al., 2000), would tear the soft newlyformed adultcuticle.

Ca²⁺ conductances that are independent of the spike-initiating zone play a major role in the generation of plateau potentials(Hartline and Russel, 1984; Schwindt and Crill, 1984; Hancox andPitman, 1991, 1993; Kiehn, 1991). Although the adult MN5 displayedno plateau potentials in the isolated ganglion preparation, prolongedCa²⁺ action potentials could be evoked after applying TEA. In manysystems, plateau potentials can be induced by neuromodulatorsor any intervention that sufficiently reduces opposing outwardcurrents (Ramirez and Pearson, 1991; Hultborn and Kiehn, 1992;Kiehn and Harris-Warrick, 1992; Bal et al., 1994). Flight is stronglyinfluenced by neuromodulators, such as octopamine, which evokesplateau potentials in locust flight interneurons (Orchard et al.,1993). Moths display a prolonged warm-up phase during which neuromodulatorsmay prepare the CNS for flight behavior (Claassen and Kammer,1986). Thus, the Ca²⁺current detected in the adult MN5 might be important in shapingits motor output, particularly if neuromodulators reduce K⁺ currents duringflight.

In contrast to the adult, Ca²⁺ spikes are readily produced during pupal stages P7 to P9. At later stages the Ca²⁺ spike is masked by the increased K⁺ currents. The large amplitude of the Ca²⁺ spike in somatic recordings suggests that these spikes are generatedin the cell body, although it is unclear where they are initiated.In contrast, the small amplitude of the Na⁺ spike as recorded from the soma at most stages, and evident atstages P7 to P9 after removal of external Ca²⁺, indicates that these spikes are not actively generated in thecell body, similar to the usual case for insect motoneurons (Gwilliamand Burrows, 1980).

MN5 undergoes sequential changes in ionic currents during postembryonic life

Embryonic and postnatal maturation of central neurons is accompanied by a sequential expression of different voltage-activatedionic currents (for review, see Spitzer, 1991). We report sequentialmodifications in Ca²⁺ and K⁺ currents during the postembryonic acquisition of a newbehavior.

The validity of the in situ single-electrode voltage-clamp measurements is supported by findings obtained from a populationof cultured motoneurons recorded in the whole-cell patch configuration.Leg motoneuron somata that were isolated acutely from early pupalManduca had smaller Ca²⁺ current densities than did those isolated from larvae or adultsbut retained some K⁺ currents (Hayashi and Levine, 1992). Although these measurementsfrom isolated somata avoided space-clamp problems, the extentto which they represented normal physiology and their functionalconsequences were unclear. Thus, the in situ measurements reportedhere were indispensable for defining the normal sequence of ioniccurrent expression during development. The absence of Ca²⁺ currents in MN5 at early pupal stages in vivo was not an artifactattributable to space-clamp problems, because MN5 was much smallerat these stages than at other stages in which Ca²⁺ currents were detected. By contrast, the net K⁺ current did not change between P4 and P8 but increased afterstage P12. These findings allow a correlation of physiologicalchanges that are evident during normal development with the timecourse of dendriticremodeling.

Putative signals for changes in ionic currents during postembryonic development

The steroid hormone 20-hydroxyecdysone (20E) may regulate the modification of Ca²⁺ currents. Manduca leg motoneurons cultured during early pupalstages show a 20E-dependent increase in Ca²⁺ current (Grünewald and Levine, 1998). Systemic ecdysteroid levelsrise continuously between stages P4 and P8 (Bollenbacher et al.,1981), while Ca²⁺ currents in MN5 increase. Ecdysteroids regulate the excitabilityof neurosecretory neurons in Manduca (Hewes and Truman, 1994),perhaps by altering ionic currents, and steroid hormones are potentmodulators of ionic currents in the vertebrate CNS (Kerr et al.,1992; Rendt et al., 1992; Dunlap et al., 1997). Alternatively,activity-dependent mechanisms could be involved, because electricalactivity influences the postnatal shaping of neuronal connections(Shatz, 1990; Fields and Nelson, 1992; Gu and Spitzer, 1995) andthe expression of ion currents (Garcia et al., 1994; Lnenickaet al., 1998). Finally, interactions with the degenerating larvaltarget muscle during late larval and early pupal stages (Duchet al., 2000) might play a role. The trigger for the increasein net K⁺ current between pupal stages P8 and P12 also remains to be investigated.Systemic ecdysteroid levels decline during these stages (Bollenbacheret al., 1981), but 20E had no effect on the K⁺ currents of cultured pupal leg motoneurons (Grünewald and Levine,1998). Alternatively, the large Ca²⁺ current at stage P8 might play a role, similar to the role ofa Ca²⁺ influx-dependent increase in K⁺ channel expression during the postnatal maturation of Purkinjecells (Muller et al., 1998).

Possible role of transient calcium signals in dendritic differentiation

Similar to other central neurons in Manduca (Levine and Truman, 1985; Weeks and Ernst-Utzschneider, 1989; Kent and Levine,1993), MN5 undergoes dramatic dendritic remodeling during metamorphosis.Some aspects of the dendritic plasticity are controlled directlyby 20E (for review, see Weeks and Levine, 1990, 1995), but interactionswith the periphery are also involved (Kent and Levine, 1993).This is the first study in which dendritic remodeling can be correlatedtemporally with changes in active and passive membrane propertiesduring normal postembryonic development. This correlation is consistentwith a role for Ca²⁺ influx in dendritic remodeling. Prominent growth cone-like structuresform at the tips of the growing adult dendrites between pupalstages P2 and P6. This corresponds in time with a low level ofCa²⁺ currents. In culture systems, low levels of Ca²⁺ influx promote growth cone extension and branching, but highlevels of influx and prolonged internal elevation inhibit theseprocesses (for review, see Kater et al., 1988; Kater and Mills,1991). The cessation of the formation of high-order branches ofMN5 is correlated with the transient occurrence of Ca²⁺ spikes during pupal stages P7 to P9, because of the differentialtiming of Ca²⁺ versus K⁺ current modifications. Because these spikes occurred spontaneouslyand could be evoked by sensory stimulation in the isolated ganglionpreparation, it is likely that they also occur during normal development.During embryonic spinal cord development, the frequency of growthcone Ca²⁺ transients is inversely proportional to the rate of axon outgrowth,with large elevations in internal Ca²⁺ at pausing sites (Gomez and Spitzer, 1999), causing an increasein the activity of calcineurin (Lautermilch and Spitzer, 2000).Furthermore, the Ca²⁺-sensitive enzyme calmodulin kinase II is required to limit theelaboration of neuronal arbors in the developing Xenopus opticaltectum (Zou and Cline, 1999). The effects of postembryonic Ca²⁺ current modifications on cytosolic Ca²⁺ levels of MN5 remain to be investigated. However, the abilityto correlate structural and functional events in their normalcontext in this system provides distinct advantages for examiningwhether Ca²⁺ signals mediate the initiation and cessation of dendritic growthduring postembryoniclife.

  FOOTNOTES

Received April 19, 2000; accepted June 28, 2000.

We gratefully acknowledge the support by National Institutes of Health Grant NS 28495 and by the Deutsche ForschungsgemeinschaftFellowship DU 331/2-1 (C.D.). We thank Dr. C. Consoulas for manyhelpful comments on thismanuscript.
Correspondence should be addressed to Dr. Carsten Duch, University of Arizona, Division of Neurobiology, 611 Gould-SimpsonBuilding, Tucson, AZ 85721. E-mail: duch{at}neurobio.arizona.edu.

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DISCUSSION
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