Electrophysiological Development of Central Neurons in the Drosophila Embryo

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The Journal of Neuroscience, June 15, 1998, 18(12):4673-4683

Electrophysiological Development of Central Neurons in the Drosophila Embryo
Richard A. Baines and Michael Bate
Department of Zoology, University of Cambridge, Cambridge, CB2 3EJ, United Kingdom

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

In this study, we describe the development of electrical properties of Drosophila embryonic central neurons in vivo. Usingwhole-cell voltage clamp, we describe the onset of expressionof specific voltage- and ligand-gated ionic currents and the firstappearance of endogenous and synaptic activity. The first currentsoccur during midembryogenesis [late stage 16, 13-14 hr after egglaying (AEL)] and consist of a delayed outward potassium current(I_K) and an acetylcholine-gated inward cation current (I_ACh).As development proceeds, other voltage-activated currents arisesequentially. An inward calcium current (I_Ca) is first observedat 15 hr AEL, an inward sodium current (I_Na) at 16 hr AEL, anda rapidly inactivating outward potassium current (I_A) at 17 hrAEL. The inward calcium current is composed of at least two individualand separable components that exhibit small temporal differencesin their development. Endogenous activity is first apparent at15 hr AEL and consists of small events (peak amplitude, 5 pA)that probably result from the random opening of relatively fewnumbers of ion channels. At 16 hr AEL, discrete (10-15 msec duration)currents that exhibit larger amplitude (25 pA maximum) and rapidactivation but slower inactivation first appear. We identify theselatter currents as EPSCs, an indication that functional synaptictransmission is occurring. In the neurons from which we record,action potentials first occur at 17 hr AEL. This study is thefirst to record from Drosophila embryonic central neurons in vivoand makes possible future work to define the factors that shapethe electrical properties of neurons during development.

Key words: CNS; connectivity; development; Drosophila; neurogenesis; neuron; synaptogenesis

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Neural development in Drosophila, as in vertebrates, involves an early, relatively activity-independent phase during whichneurons are born, extend axons, and contact targets, followedby a later phase when neurons acquire their electrical properties,refine their synaptic connections, and become the functional unitsof neural circuits (Goodman and Shatz, 1993). There has been arapid increase in our understanding of the early development ofthe nervous system, including the mechanisms of neural cell fatedetermination, axon growth and guidance, target recognition, andthe establishment of synaptic terminals (Goodman and Doe, 1993;Hall and Sanes, 1993; Tessier-Lavigne and Goodman, 1996). On theother hand, relatively little is known of the later stages ofneuronal development when nerve cells first become functionaland when neuronal activity may itself contribute to the maturationof neuronal characteristics and the refinement of connections.The difficulty in Drosophila is that although it is an ideal organismfor genetic and molecular analysis, there are technical problemsin gaining access to embryonic neurons and, in particular, inapplying advanced electrophysiological techniques to these cellsthat would allow their developing functional properties to beassayed.

Because of these difficulties our knowledge of the electrical properties of Drosophila neurons has been gained almost exclusivelyfrom neurons grown in culture. Studies with cultured neurons havenot only described the kinetics of activation and inactivation,ion specificity, and pharmacological blockade of particular voltage-and ligand-dependent ion channels, but more importantly, theirmolecular identities. Thus, for a majority of voltage-dependention channels expressed in Drosophila neurons, genes have beencloned, and mutations have been generated. In brief, at leastfour genes are known to encode voltage-dependent potassium channels;these are Shal and Shaker (both of which encode a fast I_A-typecurrent), Shab (I_K, slowly inactivating), and Shaw (I_K, noninactivating)(Solc and Aldrich, 1988; Baker and Salkoff, 1990; Tsunoda andSalkoff, 1995a,b). The para gene product carries the inward voltage-dependentsodium current (Germeraad et al., 1992), whereas the molecularidentities of voltage-dependent calcium channels are less wellestablished, but candidate genes (Dmca1A and Dmca1D) await characterization(Zheng et al., 1995; Smith et al., 1996).

The fact that Drosophila neurons can express the full array of voltage- and ligand-gated currents in culture could be takenas indicating that there is a significant degree of cell autonomyin the determination of the neuronal phenotype (O'Dowd et al.,1988; Ribera and Spitzer, 1990; Spitzer 1994). However, whetherthe characteristics of such cultured neurons accurately reflectproperties such as current densities, thresholds for excitability,and patterns of activity, which would be appropriate for suchcells in vivo, has yet to be determined. Intuitively, one mightexpect that the development of specific characteristics by individualneurons would require extrinsic cues that would be provided, forexample, by cell-cell interactions and an appropriate patternof synaptic connectivity. Cues of this kind would be primarilymissing from cell cultures, and it might be that under these conditionsneurons would develop generalized properties of excitability ratherthan the specific attributes that allow them to contribute tothe function of particular neural circuits.

To resolve questions of this kind and to begin an analysis of the mechanisms that regulate the functional development of nervecells, we have developed a preparation of the Drosophila embryothat allows the application of standard whole-cell recording techniquesto the CNS. Here we show that readily accessible neurons, thosesituated along the dorsal surface of the ventral nerve cord, expressspecific voltage- and ligand-gated ion channels sequentially accordingto a developmental timetable. We also describe the onset of appearanceof synaptic input and action potentials in these neurons. Thisinformation, which represents the first developmental descriptionof the electrical properties of Drosophila embryonic neurons,provides a framework for further studies aimed at investigatingthe genetic basis of later, potentially activity-dependent neuraldevelopment.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Fly stocks. The wild-type strain Oregon-R was used. UAS-Tetanus (G) toxin light chain was expressed throughout the CNS usinga Scabrous Gal4 driver (Brand and Perrimon, 1993; Sweeney et al.,1995; Thor and Thomas, 1997). A small deficiency in the para locus,Df(1)LD34, was used to remove I_Na (Broadie and Bate, 1993c). Flieswere kept at 25°C and fed on apple juice agar supplemented withyeast.

Staging and dissection. Eggs collected from overnight lays were dechorionated in commercial bleach. Early stage 16 embryos,from 12 hr 45 min to 12 hr 55 min after egg laying (AEL), wereidentified by the presence of three disk-like contractions ofthe gut. These embryos were further incubated at 25°C until theyhad reached the required developmental time. Embryos were removedfrom their vitelline membrane using a glass micropipette and fixedat both their anterior and posterior ends to a Sylgard (Dow Corning)-coatedcoverslip using cyanoacrylate glue (Histoacryl; Braun, Melsungen,Germany) under dissection saline (see below). Embryos were openeddorsally using sharp tungsten needles and then glued flat to theSylgard coverslip. Gut and fat body were removed to expose theventral nerve cord. The embryo was viewed using a 63× water immersionlens combined with Nomarski optics.

A small section of the neurilemma surrounding the nerve cord between abdominal segments A1-A4 was ruptured using protease(1% type XIV; Sigma, Dorset, UK) made up in whichever externalsaline was required (see below). The protease saline was containedin a large-diameter (10-20 µm) patch pipette that was broughtinto contact with a region of neurilemma covering the dorsal surfaceof the CNS. A small amount of the neurilemma was drawn into thepipette using gentle suction and held for 2 min. After this perioda small hole was made in the neurilemma by alternating pulsesof gentle suction and expulsion of the saline in the pipette.With care, it is possible to rupture the neurilemma to exposeneurons in at least the two adjacent segments. Any debris, includingthe transverse nerves, are removed by suction into the proteasepipette, and the pipette is then withdrawn. With a region of neurilemmaremoved, the underlying neurons are exposed. However, the characteristicposition of the exposed neurons is sometimes lost during thisprocedure; unequivocal neuronal identification based on positionin the nerve cord is, therefore, not always possible.

Electrophysiology. Whole-cell recordings were achieved with standard patch electrodes (thick-walled borosilicate glass), fire-polishedto final resistances of between 15 and 20 M $Omega$ . Amplification andvoltage control were achieved using an Axoclamp-1D patch clampamplifier and pCLAMP6 software running on an IBM-compatible personalcomputer (Axon Instruments, Foster City, CA). Tight seals (usually>5 G $Omega$ ) formed readily, but the success of going whole-cell waslower (~20-50%), a problem that is more severe with younger embryos,particularly <16 hr AEL (10-20% success rate). The reason forthis difference in younger embryos is unknown but possibly representsan age-related difference in the rigidity and/or composition ofthe neuronal membrane. Only cells with an input resistance >1G $Omega$ (average, 5.1 ± 0.4 G $Omega$ ; n = 100; mean ± SE) were accepted foranalysis. Typical cell capacitances (determined by integrationof the area under the capacitative transients for the averageof 50 steps from $-$ 60 to $-$ 90 mV) ranged between 0.7 and 4.6 pF(2.1 ± 0.15 pF; n = 37; mean ± SE) and were not compensated foron the patch amplifier. Series resistance (52 ± 3.3 M $Omega$ ; n = 10;mean ± SE) was not corrected; with maximum currents <200 pA (andusually <100 pA), series resistance error should not have exceeded10 mV. Current traces were sampled at 20 KHz and filtered usingpCLAMP6 at 2 KHz. For potassium and calcium currents, a linearlyscaled leak current obtained from hyperpolarizing conditioningsteps (from $-$ 60 to $-$ 90 mV) before any depolarizing voltage stepswas subtracted from each current trace before analysis using pCLAMP6.To resolve sodium currents better, an on-line leak substractionoption within pCLAMP6 was used: the protocol using the averageof 4 depolarizing pulses (P/4). All traces shown are the averageof at least five trials. All recordings were made at room temperature(21-25°C). Recordings in current clamp were unsatisfactory becauseof uncontrolled fluctuations in membrane voltage, attributableto the fact that only small holding currents (<10 pA) are requiredto maintain resting potentials of $-$ 60 to $-$ 40 mV.

Iontophoresis. A 60 M $Omega$ electrode containing 0.1 M aqueous ACh (HCl; Sigma) was brought to within 1-2 µm of the neuron underexamination. A retaining current of approximately $-$ 2 nA and anejection current of approximately +30 nA (although this was varied)was used to prevent leakage and expel ACh, respectively. Currentwas generated by pCLAMP6 and a homemade intracellular amplifier.Cells were allowed to recover for at least 30 sec between successiveapplications.

Solutions. External saline for dissection and normal whole-cell recording consisted of (in mM): 135 NaCl, 5 KCl, 2 MgCl₂,0.5 CaCl₂, 5 N-Tris[hydroxymethyl]methyl-2-aminoethanesulfonicacid (TES), and 36 sucrose. Potassium conductance saline consistedof (in mM): 6 KCl, 140 Tris-HCl, 10 MgCl₂, 10 HEPES, and 10 glucose.Calcium conductance saline consisted of (in mM): 50 Tris-HCl,50 BaCl₂, 50 tetraethylammonium chloride (TEA), 10 4-aminopyridine,10 MgCl₂, 10 HEPES, and 10 glucose. Sodium conductance salineconsisted of (in mM): 100 NaCl, 50 TEA, 10 4-aminopyridine, 10MgCl₂, 10 HEPES, and 10 glucose. All solutions were pH 7.4.

Internal saline consisted of (in mM): 140 KCl, 2 MgCl₂, 11 EGTA, and 10 HEPES, pH 7.4. In some instances, K-aspartate wassubstituted for KCl with identical results. It was noted, however,that cell survival increased when chloride was substituted. Whenrecording either calcium or sodium conductances, CsCl₂ was substitutedfor KCl. ATP and GTP were not routinely added, because the requiredduration of whole-cell access normally lasted <3 min, and theirinclusion was found unnecessary. All chemicals were obtained fromSigma.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Heterogeneity of neuronal properties

This study reports the development of electrical properties of neurons located dorsally in the nervous system and close tothe midline in abdominal segments A1-A4. These neurons were chosenbecause of their relative ease of access and their relativelylarge-diameter (3-4 µm) cell bodies. The majority of neurons examinedexpressed the same range of whole-cell currents, including atleast two voltage-activated outward potassium currents (I_A andI_K), a voltage-activated inward sodium current (I_Na), at leasttwo voltage-activated inward calcium currents (I_Ca), and an ACh-gatedinward current (I_ACh).

Figure 1 shows typical whole-cell recordings from three such neurons at the same late developmental stage (19-21 hr AEL).At least two outward K currents were present in all three: a fast,rapidly inactivating I_A-like current and a slower, inactivating(delayed-rectifier) I_K-like current. Additionally, two of thethree neurons express an initial fast inward current that representsI_Na. I_Ca was masked in these recordings by the outward K currents.The largest source of heterogeneity we observed between neuronswas in the characteristics and amplitude of their K currents.The majority of developmentally mature neurons expressed botha clear I_A-like and an I_K-like current at all voltages above threshold(approximately $-$ 30 to $-$ 20 mV; see below) (Fig. 1A). The remainderof neurons exhibited either a clear predominance of I_A-like (Fig.1B) or I_K-like (Fig. 1C) currents. The significance of this distinctionis unclear, but it could contribute to the characteristic spikingactivity of individual neurons.

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Figure 1. Current heterogeneity between neurons. Whole-cell voltage clamp shows the presence of at least two voltage-activated outward K currents and a voltage-activated inward Na current (I_Na) in developmentally mature neurons (19 hr AEL and older). K currents include a fast, inactivating A-type (I_A) current and a slower, inactivating, delayed rectifier (I_K)-like current. These neurons also express inward Ca currents, but these are masked by the outward K currents under the conditions used for these recordings (but see Fig. 4). A, The majority of neurons examined exhibit prominent I_A and I_K currents. The remainder of neurons predominantly express either I_A (B) or I_K (C). I_Na is present in most but not all neurons (e.g., absent in B; see Fig. 6). The presence or absence of I_Na appears unrelated to neuronal K current characteristics. D, Currents were evoked from voltage steps (15 mV increments; range, $-$ 60 to +45 mV; 50 msec) applied from a conditioning prepulse of $-$ 90 mV. Recordings were obtained in normal whole-cell saline (see Materials and Methods).

Voltage-activated potassium currents

Potassium currents were isolated by substitution of Na with Tris (an impermeant ion of Na channels) and by using a calcium-freesaline (see Materials and Methods). Under these conditions atleast two distinct voltage-activated outward currents were presentin late embryonic central neurons, I_A-like and I_K-like (althoughthe I_K-like current comprised more than one current; see Discussion)(Fig. 2A). The absence of extracellular Ca removes the contributionof any calcium-activated K currents that may be present. The firstK current to appear in development was the slow I_K-like current(hereafter termed I_K), and this was the first voltage-activatedwhole-cell current to be expressed, preceding the I_A-like current(hereafter termed I_A) by ~3-4 hr. Although I_K first appeared at~13 hr AEL (present in 2 of 10 neurons), the majority (8 of 10neurons) of whole-cell recordings from 13 hr neurons showed onlyleakage currents that were no greater than 10 pA at +40 mV (Fig.2). By 14 hr AEL, however, I_K was expressed by a majority of neurons(8 of 10 neurons) (Fig. 2), and by 16 hr AEL, I_K had developedto its mature state, which remains constant to hatching (Fig.2). I_A, on the other hand, first appeared at 17 hr AEL (6 of 9neurons) (Fig. 2). Significantly, the appearance of I_A coincidedprecisely with the first appearance of action potentials in thesoma (see below).

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Figure 2. Voltage-activated potassium currents appear sequentially during development. A, I_K is the first K current expressed during development and is first reliably observed at 14 hr AEL (ii). Before 14 hr AEL, most neurons exhibit only leakage currents (i, but see B). By 16 hr AEL, I_K has increased in amplitude and is at this stage representative of its mature form (iii). At 17-18 hr AEL, the second voltage-activated K current (I_A) is first seen (iv). Recordings were obtained in K conductance saline (see Materials and Methods), and voltage steps (15 mV increments; range, $-$ 60 to +45 mV; 50 msec) were applied from a conditioning prepulse of $-$ 90 mV (v). B, C, Beginning at 13 hr AEL, neuronal recordings were made to determine the presence or absence of each of the two K currents isolated using these conditions. Results shown are based on at least 10 (I_K) and 9 (I_A) neurons for each time point.

To be confident that the voltage-activated K current expressed before 17 hr AEL did not contain any inactivating components(such as I_A), currents were separated by exploiting differencesin their steady-state inactivation (Tsunoda and Salkoff, 1995a,Martínez-Padrón and Férrus, 1997). In Drosophila neurons, I_Ais inactivated by a conditioning holding potential (V_h) of $-$ 20mV, whereas I_K is primarily unaffected. Currents elicited fromV_h of $-$ 20 mV, therefore, isolate I_K by inactivation of I_A. Subtractionof I_K from combined I_K-I_A currents evoked from V_h $-$ 90 mV isolatesI_A. At 16 hr AEL, K currents evoked from V_h $-$ 90 or $-$ 20 mV wereessentially identical, and their subtraction yielded no inactivatingoutward K component (Fig. 3A). However, by 17 hr AEL when I_A waspresent, V_h $-$ 20 mV isolated I_K, and subtraction currents isolatedI_A (Fig. 3B). Thus, we are confident that I_A does not appear inthe neuronal cell body before 17 hr AEL.

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Figure 3. I_K and I_A can be separated by differences in voltage-dependent inactivation. A, Voltage-activated K currents evoked from different conditioning prepulses ( $-$ 90 and $-$ 20 mV) at 16 hr AEL are essentially identical such that their subtraction from one another shows no evidence for any inactivating K-currents (which are inactivated by a prepulse to $-$ 20 mV). B, At 17 hr AEL when both I_K and I_A are present, a prepulse of $-$ 20 mV inactivates only I_A-isolating I_K; subtraction yields I_A. C, Recordings were obtained in K conductance saline (see Materials and Methods), and voltage steps (15 mV increments; range, $-$ 60 to +45 mV; 50 msec) were applied from conditioning prepulses of either $-$ 90 or $-$ 20 mV. D, E, Current-voltage relationships for I_K and I_A isolated by differential voltage-dependent inactivation. To overcome heterogeneity in current amplitude between individual neurons, currents are normalized to the maximum current (I) evoked at 45 mV in each neuron. Each point is the average of 13 (I_K) or 14 (I_A) determinations ± SE (average peak amplitude: I_K, 64 ± 13 pA; I_A, 141 ± 29 pA) from neurons 19-21 hr AEL.

Current-voltage relationships for I_K and I_A, separated by differential inactivation, show that each current is activated atdifferent membrane potentials (Fig. 3C,D). To overcome problemsassociated with heterogeneity, current amplitude (I) was normalizedto I_max (current evoked at 45 mV) for each neuron. I_K activatesbetween $-$ 30 and $-$ 15 mV and is 50% activated at approximately +20mV. I_A activates between $-$ 45 and $-$ 30 mV and is 50% activated at0 mV.

Voltage-activated calcium currents

Calcium channel activity was isolated by substitution of extracellular Na with Tris, and K currents were blocked by the inclusionof TEA and 4-AP in the saline and by substitution of K by cesiumin the patch pipette (see Materials and Methods). Ca current wasmeasured using barium (Ba; 50 mM) to prevent activation of Ca-activatedK currents. This also allowed the extracellular concentrationof the permeant ion to be increased without exacerbating the problemsthat increased muscle contractility has on the stability of thepreparation. Ba has been previously demonstrated to be suitablein measuring I_Ca in isolated Drosophila neurons (Leung and Byerly,1991).

I_Ca(Ba) is adequately resolved in most neurons, although its voltage control is not always good. This indicates that unlikeK currents in which voltage control is excellent, a significantportion of the I_Ca(Ba) we observed was generated outside the membraneof the cell body (i.e., in the membrane of the distal neuronalprocesses). Under the conditions used, I_Ca(Ba) was first apparentin neurons at 15 hr AEL (4 of 10 neurons), which was ~1-2 hr afterI_K first appeared and 2 hr before I_A was expressed (Fig. 4A,B).However, given the caveat that a significant portion of the I_Ca(Ba)we recorded may be generated outside of the cell body, it is conceivablethat the first appearance of I_Ca(Ba) may occur somewhat earlierthan this. How much earlier is hard to estimate, but because wesaw clear differences between the magnitude of I_Ca(Ba) recordedat 15 and 16 hr AEL, respectively, we speculate that its firstappearance (in the distal regions of neurons) would occur no morethan 1 hr earlier (i.e., at 14 hr AEL). Later in development,between 19 and 21 hr AEL, almost all neurons examined expressedI_Ca(Ba) (Fig. 4B).

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Figure 4. Development of voltage-activated calcium current. A, Representative whole-cell currents showing the development of I_Ca during embryonic development. At 14 hr AEL, neurons do not express Ca currents (i). I_Ca is first observed at 15-16 hr AEL and thereafter increases in magnitude such that by late development (e.g., 19-21 hr AEL, iii) I_Ca is clearly visible in the majority of neurons examined (ii). Recordings were obtained in Ca conductance saline (see Materials and Methods), and voltage steps (15 mV increments; range, $-$ 60 to +45 mV; 50 msec) were applied from a conditioning prepulse of $-$ 90 mV (iv). All recordings use Ba as the permeant ion. Note that the small amount of outward current present in Aii is almost certainly attributable to an incomplete blockade of the voltage-activated I_K current. This outward current begins to become apparent because of the small size of I_Ca observed at this stage. At later stages of development, I_Ca is large enough to mask it completely. B, The presence or absence of I_Ca was determined during the second half of embryogenesis beginning at 13 hr AEL. Results shown are based on at least 10 neurons for each time point. C, Current-voltage relationship in mature embryos (19-21 hr AEL) shows I_Ca activates above $-$ 30 mV, peaks at 0-15 mV, and reverses at ~45 mV. Currents are normalized to I_max. Each point is the average of 11 determinations ± SE (average peak amplitude, $-$ 34 ± 5 pA). Only recordings that showed a clear and graded voltage dependency of I_Ca were used.

Normalizing individual neuronal conductances to I_max, I_Ca(Ba) activated above $-$ 30 mV, reached its peak near 0 mV, and reversedat ~45 mV (Fig. 4C). Over the 50 msec voltage step duration used,I_Ca(Ba) inactivated only slowly, reducing in amplitude by ~10%by the end of the voltage step. In an analysis of I_Ca in culturedDrosophila neurons, both slow and fast inactivating Ca currentswere observed. Replacement of Ca by Ba in these studies resultedin the appearance of only the slowly inactivating current. Itwas concluded that in some neurons, Ca-induced inactivation ofI_Ca was occurring (Byerly and Leung, 1988; Leung and Byerly, 1991).

In Drosophila larval muscles it is possible to separate two voltage-activated Ca channels using either pharmacology or differentialinactivation (Gielow et al., 1995). One channel, similar to thevertebrate T-type Ca channel, is blocked by amiloride and is virtuallyinactivated by V_h $-$ 30 mV. Removal of this T-type channel revealsan underlying L-type Ca channel. We used both these approachesto determine whether the neuronal Ca conductance we recorded wascomposed of similar Ca channel types. Figure 5A shows the effectof V_h $-$ 30 mV on the evoked voltage-dependent Ca conductance inneurons of mature embryos (19-21 hr AEL). The peak current evokedfrom V_h $-$ 30 mV was significantly less than that from V_h $-$ 90 mVin the same neurons (33 ± 4 vs 51 ± 6 pA for V_h $-$ 30 and $-$ 90 mV,respectively; n = 8; mean ± SE). To determine whether the currentinactivated by V_h $-$ 30 mV corresponded totally or partially toa T-type amiloride-sensitive current, the recordings were repeatedin the presence of amiloride (1 mM). If amiloride and depolarizationaffect two different components, then amiloride would be expectedto reduce the current recorded at V_h $-$ 30 mV further. This is clearlynot the case; the peak Ca current recorded at $-$ 90 mV was not significantlydifferent from that at V_h $-$ 30 mV in the presence of amiloride(18 ± 4 vs 16 ± 4 pA for V_h $-$ 90 and $-$ 30 mV, respectively; n =5; mean ± SE) (Fig. 5B). Thus, it would seem that amiloride removesthe portion of Ca current that is sensitive to inactivation byV_h $-$ 30 mV (i.e., a T-type Ca channel) (Gielow et al., 1995).

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Figure 5. At least two voltage-activated Ca currents are present in neurons. A, The voltage-activated Ca current can be visualized using a ramp protocol (shown in C). Depolarization inactivates a significant portion of this Ca current, indicating the presence of more than one current. B, In the presence of amiloride (1 mM), depolarization does not significantly reduce the whole-cell Ca current, showing that amiloride blocks that portion of current that can be inactivated by depolarization. C, Voltage ramps of $-$ 60 to +45 mV over 500 msec were applied from holding potentials of either $-$ 90 mV (normal) or $-$ 30 mV (depolarized). Currents shown in A and B are from different neurons (19-21 hr AEL) and are representative of at least five separate experiments.

We used differential inactivation to determine the developmental profile of the two Ca currents isolated by this manipulation.At 16 hr AEL, 70% of neurons (7 of 10) expressed a Ca conductancethat was reduced by V_h $-$ 30 mV. I_Ca(Ba) in the remaining 30% ofneurons at this stage was not affected, suggesting that theseneurons lacked a depolarization-sensitive T-type channel. At 17hr 90% (9 of 10) of neurons and at 18 hr AEL 100% (6 of 6) ofneurons expressed a current that was reduced by V_h $-$ 30 mV (i.e.,all neurons of this stage expressed more than one Ca current).We could not extend our analysis to 15 hr AEL, which was the timewe first observed an inward voltage-activated Ca current (seeabove), because at this early stage the magnitude of current wastoo small, and its voltage control was too poor to allow reliablemeasurements. Thus, it appears that although both Ca currentsseparable by this manipulation are expressed at or approximatelythe same time, a minority of neurons first express the currentthat is unaffected by V_h $-$ 30 mV (i.e., probably an L-type Ca current)at least 1 hr before the V_h $-$ 30 mV-sensitive T-type channel.

Voltage-activated sodium current

Na conductance was isolated by omission of extracellular Ca and by blockade of K currents with TEA-4-AP and cesium in thepatch pipette (see Materials and Methods). Depolarizing voltagesteps under these conditions elicited rapidly inactivating inwardcurrents characteristic of I_Na previously characterized in Drosophilaneurons maintained in culture (Byerly and Leung, 1988; O'Dowdand Aldrich, 1988). Further evidence that these were Na currentswas provided by the fact that they are eliminated by null mutationsin para (O'Dowd and Aldrich, 1988). Of all the whole-cell currentsmeasured in this study, I_Na was the most difficult to visualizeand often escaped from voltage control. An on-line leak subtraction(P/4) protocol provided optimal separation of I_Na and was, therefore,routinely used. As with I_Ca(Ba) it would seem that I_Na is alsogenerated primarily outside the neuronal cell body. I_Na was firstexpressed in dorsal neurons at 16 hr AEL (5 of 10 neurons) andin all neurons examined by 17 hr AEL (10 of 10 neurons) (Fig.6A,B). Again, because we suspect that I_Na is generated mainlyoutside the cell body, its first appearance may precede our timings(see above). I_Na activated between $-$ 60 and $-$ 45 mV, peaked near $-$ 15 mV, and reversed thereafter (Fig. 6C).

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Figure 6. Development of voltage-activated sodium current. A, Representative whole-cell currents showing the development of I_Na during embryogenesis. At 15 hr AEL, I_Na is not present in neuronal recordings (i). I_Na is first observed at 16 hr AEL, although at this stage its amplitude is small (ii). As development continues, I_Na increases in size such that by late development (18-21 hr AEL,) it is clearly visible in the majority of neurons examined (iii). Recordings were made in Na conductance saline (see Materials and Methods), and voltage steps (15 mV increments; range, $-$ 60 to +45 mV; 50 msec) were applied from a conditioning prepulse of $-$ 90 mV (iv). Currents were leak-subtracted on-line using a P/4 protocol. B, The presence or absence of I_Na was determined throughout mid to late embryogenesis. Results shown are based on at least 10 neurons for each time point. C, Current-voltage relationship in mature embryos (19-21 hr AEL) shows that I_Na activates between $-$ 60 and $-$ 45 mV and reaches its maximum amplitude at approximately $-$ 15 mV. Currents are normalized to I_max. Each point is the average of 11 determinations ± SE (average peak amplitude, $-$ 47 ± 7 pA). Only recordings that showed a clear and graded voltage dependency of I_Na were used.

Development of acetylcholine receptor expression

The major excitatory neurotransmitter of the insect CNS is ACh; it is also the principle neurotransmitter of sensory neuronsthat send their axons into the CNS (Burrows, 1996). We were interested,therefore, in determining when in their development Drosophilacentral neurons begin to express functional receptors for ACh.We applied ACh to neurons under whole-cell voltage clamp (V_h $-$ 60mV) by iontophoresis from a high-resistance microelectrode positioned1-2 µm away from the neuronal cell body. The current used to expelACh from the iontophoretic pipette was sufficient to cause a saturatingresponse in late embryonic neurons (+30 nA, 100 msec) (Fig. 7B).Neurons were first responsive to applied ACh relatively earlyin their development, at 13 hr AEL (2 of 7 neurons) (Fig. 7A,i, ii). Before this, no response to ACh was observed (12 hr AEL,0 of 6 neurons; data not shown) (Fig. 7C), even if an ejectioncurrent of significantly increased amplitude and/or duration wasused (up to +80 nA, 500 msec). By 16 hr AEL and older, all neuronstested were responsive to ACh (Fig. 7A,C).

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Figure 7. Development of an ACh-gated current. A, At 13 hr AEL, the majority of neurons do not respond to applied ACh (i); the minority respond to applied ACh by exhibiting a weak and slow inward current (ii). By 16 hr AEL, all neurons tested responded to ACh (iii). The inward current evoked at this stage displays markedly increased amplitude and kinetics. As development continues, the ACh-evoked current increases further in amplitude and in rate of onset (iv). Recordings were obtained in normal whole-cell saline (see Materials and Methods) and neurons were held under voltage clamp at $-$ 60 mV. ACh was applied to the neurons by iontophoresis using an ejection current of +30 nA (a saturating level; see B). B, Application of ACh by iontophoresis shows a clear dose-dependent response relative to the amplitude of ejection current. The responses shown are evoked by an increasing series of ejection currents (1, 2.5, 5, 10, 20, 30, and 40 nA) applied at 30 sec intervals to a neuron 21 hr AEL that responded particularly strongly. The response saturates at an ejection current amplitude of $>=$ 20 nA, and no response is evoked by 1 nA. Ejection current of opposite sign (i.e., hyperpolarizing) evoked no response (data not shown). C, The effect of ACh was determined during embryogenesis beginning at 13 hr AEL. Determinations were made at each successive hour in development, and the results shown are based on at least six neurons for each time point.

I_ACh activated rapidly, decayed quickly, and exhibited a reversal potential of $-$ 0.68 ± 12.7 mV (n = 3; mean ± SE), characteristicof a nonselective cation channel (Benson, 1992; Baines and Bacon,1994). Controls consisted of using water only, negative ejectioncurrent and placing the pipette at least 10 µm from the cell;all failed to elicit any response. Furthermore, successive applicationsof ACh applied within 5-10 sec of each other induced a rapidlydiminishing response, indicative of receptor desensitization (datanot shown).

Synaptogenesis and the development of active properties

Arguably the most important developmental phase in a nervous system occurs during synaptogenesis and the completion of neuronalnetworks. The time at which this critical phase occurs cannotreadily be deduced by extrapolation from the developmental profileof individual neuronal ion channels. In an attempt to establishthe developmental window during which synaptogenesis is initiatedin the CNS, we recorded endogenous neuronal activity in the hopeof observing the first appearance of postsynaptic events.

Under voltage clamp, the earliest reliable activity we recorded in neurons occured at ~15 hr AEL and was primarily composedof multiple random openings of single channels (Fig. 8A). Thesecurrents (amplitude, <5 pA) usually came in bursts that occasionallylasted for as long as 1-2 sec (data not shown). Because of thecomplexity of the inward currents expressed by neurons at thisstage in development, including I_ACh and I_Ca (and possibly I_Nain the neuronal processes), we did not attempt to identify theionic nature of these currents. Currents that have the characteristicsassociated with synaptic input (i.e., those resembling EPSCs)were first seen at 16 hr AEL (5 of 18 neurons). These currents,the largest of which were 25 pA in amplitude, displayed rapidactivation, slower inactivation, and a duration of ~10-15 msec(Fig. 8B). However, it should be pointed out that because theevents reflected in these currents are likely to be occurringat some distance away from the recording site on the cell body,it is difficult to assess their true amplitude and duration. Giventhat currents associated with miniature postsynaptic potentialsare notoriously difficult to record in neuronal cell bodies andare unlikely to spread far from their site of generation, we concludethat these currents are EPSCs and indicate that active synapticrelease of neurotransmitter is occurring. We discount the possibilitythat these events are attenuated action potentials (arising inareas of the neurons that are only weakly voltage-clamped), becausein older embryos such events are seen together with larger-currentwave forms that we identify unequivocally as being associatedwith action potentials (see below).

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Figure 8. Development of endogenous neuronal activity. A, At 15 hr AEL whole-cell recordings reveal small inward currents that exhibit characteristics of single channel activity. B, Inward currents that resemble EPSCs are first observed in neurons at 16 hr AEL. These currents, which can reach 25pA in amplitude, have a rapid onset but slower decay and persist for ~10-15 msec. C, Endogenous currents that are attributable to the generation and spread of action potentials in neurons are first observed at 17 hr AEL. These currents are relatively large (some exceeding 50 pA), are brief (3-5 msec), and overshoot. For B and C, three representative examples from three individual neurons are shown. Neurons are voltage-clamped at $-$ 60 mV (A, B) and $-$ 40 mV (C) in normal whole-cell saline. Calibration: A, 2.5 pA, 40 msec; B, C, 10 pA, 20 msec.

To substantiate the view that the events we identified as EPSCs are evoked synaptic currents, we recorded neuronal activityunder conditions in which synaptic activity should be either absentor severely reduced. First, we used a 0 Ca²⁺-high-Mg²⁺ saline (normal whole-cell saline containing no CaCl₂ and 20 mMMgCl₂) that does not support synaptic release of neurotransmitter(Getting, 1981). Second, we recorded from neurons that are expressingtetanus toxin light chain (UAS-TNT with expression driven by ScabrousGal4; Brand and Perrimon, 1993; Thor and Thomas, 1997). Tetanustoxin light chain cleaves synaptobrevin in synaptic terminals,severely reducing evoked, but not spontaneous (e.g., minis), releaseof neurotransmitter (Sweeney et al., 1995). Third, we recordedfrom neurons deficient for para, which eliminates I_Na and, therefore,presumably prevents sodium-based action potentials (O'Dowd andAldrich, 1988; Broadie and Bate, 1993c). Synaptic events thatwe classified as EPSCs in wild-type neurons (Fig. 9A) are absentin 0 Ca²⁺-high-Mg²⁺ saline (Fig. 9B) and are severely reduced in both amplitude andfrequency in neurons that express tetanus toxin light-chain (Fig.9C) or are para deficient (Fig. 9D). Event frequency is shownin Figure 9E and represents the average number of events thatwe identified as EPSCs from five separate recordings from variousmotoneurons (visualized by inclusion of 0.25% carboxyfluorosceinin the pipette saline and identified by the fact that their axonleaves the CNS). Motoneurons, rather than interneurons, whereselected because they show the highest incidence of EPSC-likeevents in wild-type embryos. Thus, based on these further observations,we conclude that the events that we first observed from 16 hrAEL are indeed EPSCs.

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Figure 9. Characterization of EPSC-like currents. A, Neuronal recordings from wild-type (WT) embryos show currents that we classify as EPSCs (see Fig. 8). B, In conditions of 0 Ca²⁺-high Mg²⁺ (20 mM) known to prevent evoked release of neurotransmitter, no such currents are observed, supporting our identification of these events as resulting from the evoked release of synaptic neurotransmitter. C, Disruption of synaptic release by the expression of tetanus toxin light chain (TNT) in all neurons of the CNS (see Results) markedly reduces both frequency and amplitude of these currents. D, In embryos that carry a deficiency for para and cannot therefore support sodium-based action potentials, these events are also, as expected for evoked synaptic currents, severely reduced in both frequency and amplitude. E, Average frequency ± SE of EPSC-like currents per minute, determined from 3 min recordings from five separate motoneurons for each category. All three treatments are significantly different from WT at p < 0.05 (Mann-Whitney U test). Neurons are voltage-clamped at $-$ 60 mV in normal whole-cell saline.

Because we can record apparent EPSCs in neurons 16 hr AEL, we would expect that other neurons, presynaptic to them, wouldbe able to fire action potentials. By 16 hr AEL, many neuronshave acquired both I_Ca and I_Na and, thus, have the necessary ionchannels to support the initiation of action potentials. However,in the neurons we examined, we never observed currents attributableto endogenous action potentials before 17 hr AEL (Fig. 8C). Thesecurrents, which are relatively large (some exceeding 50 pA inamplitude), are brief (lasting between 3 and 5 msec), and overshoot,display all the characteristics expected of the currents thatunderlie an action potential. Furthermore, these currents wererarely seen in neurons voltage-clamped at $-$ 60 mV but were commonin neurons clamped at potentials more positive than $-$ 40 mV. Thefact that these currents were present at all, however, is indicativethat distal parts of the neurons recorded from are poorly voltage-clamped,because the currents arise from action potentials generated inthese regions. However, although undesirable, this lack of spaceclamp has allowed us to estimate the time in development whenthe neurons we sampled were first able to generate propagatingaction potentials.

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Based on general properties such as excitation threshold, inactivation, and reversal potential, the currents we recorded fromneurons in vivo are essentially identical to those obtained fromDrosophila neurons maintained in culture. This similarity validatesour preparation as a suitable model for analyzing the electrogenesisof neurons and indicates that the development of individual neuronalcurrents is, to a significant degree, cell autonomous. However,by recording from neurons in vivo, we gain the additional advantageof potentially being able to determine the extent to which externalsignals also influence neural development.

Development of voltage-activated ion channels

As far as we can judge from studying a population of neurons rather than individual cells, voltage-gated currents appear insequence in the developing central neurons of the Drosophila embryo.The first current to appear, I_K, occurs between 13 and 14 hr AEL(62-67% of development) and is followed by I_Ca (15 hr AEL, 71%of development), I_Na (16 hr AEL, 76% of development), and finallyI_A (17 hr AEL, 81% of development). The sequence, which is summarizedin Figure 10, has some similarity to that seen in Drosophila photoreceptorsas they develop in the pupa. Photoreceptors are also neural inorigin, and the first whole-cell current they express is I_K (60hr after pupariation, ~60% of pupal development), followed byI_A at 76 hr (76% pupal development) (Hardie, 1991). The sequenceof current expression in neurons is, however, different from thatseen in both Drosophila embryonic and pupal muscle (Broadie andBate 1993b; Salkoff, 1985). Vertebrate neural development alsoinvolves a stereotyped sequence in which specific voltage- andligand-gated currents appear in an order that varies between differenttypes of neurons (O'Dowd et al., 1988; Ribera and Spitzer, 1990;Spitzer 1994). Thus, the progressive appearance of currents isa typical feature of the development of excitable cells. The sequencethat we observed suggests that at least the neurons from whichwe have recorded (those situated dorsally in the abdominal ventralnerve cord) share a common developmental program and that individualcharacteristics will be superimposed on this general sequenceof maturation.

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Figure 10. Summary of the electrophysiological development of Drosophila embryonic neurons. The development of electrical properties of embryonic central neurons are shown with published data summarizing the development of the electrical properties of an identified body wall muscle (muscle 6) (Broadie and Bate, 1993). Bars show the onset of each current, and arrowheads show that the currents continue throughout the rest of development in the direction shown. The first appearance of both a voltage- and a ligand-gated current (I_K and I_ACh) in central neurons coincides with the onset of currents in muscle. However, the ionic nature of the currents first observed in neurons differs from those in muscle 6.

We have not isolated all the voltage-activated currents known to be present in Drosophila neurons. To do that we will haveto be able to recognize and record reliably from individual identifiedneurons. The neuronal I_K current in Drosophila is composed ofat least two currents; one inactivates slowly and is encoded byShab, whereas the other, encoded by Shaw, is smaller and noninactivating(Solc and Aldrich, 1988; Tsunoda and Salkoff, 1995b). Northernanalysis shows that transcripts for the relevant channels areexpressed simultaneously in the developing embryo from 9 hr AEL(Tsunoda and Salkoff, 1995a). These two genes are also responsiblefor the I_K current present in muscle (Tsunoda and Salkoff, 1995a).By contrast, the molecular identity of the principal I_A appearsto differ between neuron and muscle. In muscle, I_A is encodedby Shaker (Singh and Wu, 1990; Broadie and Bate, 1993b), althoughin central neurons, Shaker I_A is only detectable in a subpopulationof neurons and even then does not constitute the major I_A (Bakerand Salkoff, 1990; Tsunoda and Salkoff, 1995a,b). The principalneuronal I_A is encoded by Shal and exhibits different kineticsto Shaker (Tsunoda and Salkoff, 1995a). Because Shaker I_A appearsto be either absent or relatively insignificant in the majorityof recordings from the neuronal cell body, it has been suggestedthat its expression in the CNS is restricted to the terminalsof neurons (Tsunoda and Salkoff, 1995a). However, an analysisof type III (peptidergic) motoneuron terminals by whole-cell voltageclamp has failed to find any evidence for Shaker I_A, the presentI_A being removed by null mutations of Shal (Martínez-Padrónand Férrus, 1997). Recordings from neurons in embryos carryingnull mutations in Shaker also show no obvious contribution ofShaker to I_A (R. A. Baines, unpublished observations).

Development of acetylcholine-gated currents

In insects, acetylcholine is the principal sensory neurotransmitter and is also the major neurotransmitter of the CNS (Burrows,1996). Interestingly, our data show that Drosophila embryonicneurons respond to ACh early in their development (13-14 hr AEL)at a stage when they are only expressing one of their normal rangeof voltage-dependent whole-cell current types (I_K). The responseof such neurons to ACh is, therefore, unlikely to resemble thatof fully developed cells, and it seems likely that if ACh hasa function at this early developmental stage, it is not as a conventionalneurotransmitter. The dorsal unpaired median (DUM) neurons ofgrasshopper embryos are sensitive to ACh (and GABA) even earlierin embryogenesis (40%), sensitivity in this instance coincidingwith the initiation of axon outgrowth (Goodman and Spitzer, 1979).Such observations are circumstantial evidence for the view thatACh may have an early developmental function, in addition to itslater role as a neurotransmitter. More convincing evidence forsuch a developmental role for ACh comes from observations of someof the early expressed nicotinic acetylcholine receptor subunitsin the vertebrate CNS. These receptors are unusually permeableto Ca, and when they are expressed in PC12 cells, calcium influxmediates the initiation of early gene expression (Greenberg etal., 1996). Thus, extrinsic factors such as neurotransmittersmay influence, through Ca influx and/or second messenger activation,gene expression and, hence, the determination of final neuronalphenotypes.

Synaptogenesis

Our recordings suggest that functional synapses formed by neurons that are presynaptic to the cells from which we record firstappear between 15 and 16 hr AEL (71-76% embryonic development).Synaptic input is first apparent in recordings from DUM neuronsin grasshoppers at 75% embryogenesis and between cercal afferentsand central giant interneurons in cockroaches at 55% embryogenesis(Goodman and Spitzer, 1979; Blagburn et al., 1996). The embryonicDrosophila neuromuscular junction, a peripheral synapse that hasbeen investigated in some detail, is established at 13 hr AEL,becomes functional at 14 hr AEL (67%), and reaches maturity by17 hr AEL (Broadie and Bate, 1993a), the time at which our observationsshow that embryonic neurons display their full complement of voltage-activatedion channels. Synaptic activity underlies the mechanism of synapseelimination in vertebrate muscle, whereby multiply innervatedembryonic muscle fibers gradually remove inappropriate inputsto become individually innervated (Colman et al., 1997). Similaractivity-dependent mechanisms refine axonal projections in thevertebrate lateral geniculate nucleus and visual cortex (Goodmanand Shatz, 1993). Whether synaptic activity promotes the refinementof neuron-neuron connectedness in Drosophila is not known, butit may now be possible to resolve this issue during the laterphases of embryogenesis that we describe in this study.

Regulation of electrogenesis

An important goal of our work is to identify and understand the mechanisms of action of factors that regulate the functionaldevelopment of neurons and lead to the acquisition of specificcharacteristics by individual cells or cell classes. In this studywe have begun to focus on the differentiation of excitable propertiesduring late stages of neuronal development. There are severalquestions that we need to address before we begin to understandthe development of excitable properties by central neurons. Thefirst and most important of these is the extent to which thereis diversification in the excitable properties of different neuronsand classes of neurons. We can only resolve this by dealing withthe development of different identified cells. The work we reporthere sets the stage for this by showing that recording from centralneurons in vivo is feasible. The use of markers such as greenfluorescent protein (Brand 1995) and the means to target theseto individual cells or cell populations in the nervous system(Brand and Perrimon, 1993) means that we may now be able to addressthe question of diversity by recording from individual cells identifiedby such markers. If diversification is a fact, we turn to themechanism of its control, which is likely to have larger implicationsfor our understanding of functional plasticity, as well as functionaldevelopment. In general, as with any other developmental sequence,we can divide the factors that might influence this process intothose that are extrinsic and those that are intrinsic to the cellsthemselves. For example, the phenotype of individual neurons islikely to be dictated in part by their lineage within a particularneuroblast clone and in part by interactions with neighboringcells (Kuwada and Goodman, 1985; Spana et al., 1995; Doe et al.,1996). It will be important in this context to establish whetherthe expression of a particular transcription factor or constellationof transcription factors can be decisive in dictating the developmentof excitable properties just as, for example, the expression ofislet is required for the development of appropriate neurotransmittersynthesis and for axon pathfinding by a subset of Drosophila centralneurons (Thor and Thomas, 1997). Interestingly, recent work withthe leech shows that injection of transcripts of the homeoboxgene, Lox1, into neurons can lead to a change of electrical propertiesthat is manifested as a threefold increase in action potentialamplitude (Aisemberg et al., 1997). At the same time it will beimportant to establish the extent to which cell contact triggersor modifies the acquisition of electrical properties during development.Candidates for such a role might include glial cells, or targetssuch as muscles that are specific to a particular class of cells,the motoneurons. Finally, and perhaps most interesting and challenging,is the prospect that activity and activity-mediated signalingmay influence the development of specific excitable properties.In this sense, connectivity may be an essential component of theprocess by which the excitable properties of individual neuronsare set. If this is true, then a proper analysis of the functionalcharacteristics of individual neurons will only be possible iftheir correct connectivity within the CNS is maintained. The prospectnow is that it may be possible to show the extent to which thisexpectation is fulfilled and to dissect the pathways by whichthe functional characteristics of nerve cells are actually setduring development.

  FOOTNOTES

Received Jan. 30, 1998; revised March 18, 1998; accepted March 31, 1998.

This work is supported by The Wellcome Trust. We thank Roger Hardie, Simon Laughlin, Laurent Seugnet, Maximiliano Suster,and Matthias Landgraf for their help and comments on this manuscript.We thank Sean Sweeney for the gift of UAS-TNTG flies.
Correspondence should be addressed to Dr. R.A. Baines, Department of Zoology, University of Cambridge, Cambridge, CB2 3EJ,UK.

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Materials & Methods
Results
Discussion
References

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