Differential Regulation of Synaptic Vesicle Protein Genes by Target and Synaptic Activity

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The Journal of Neuroscience, August 1, 1998, 18(15):5832-5838

Differential Regulation of Synaptic Vesicle Protein Genes by Target and Synaptic Activity
Jeffery A. Plunkett¹, Stephen A. Baccus², and John L. Bixby¹^,²
¹ Department of Molecular and Cellular Pharmacology and ² Neuroscience Program, University of Miami School of Medicine, Miami, Florida 33136

  ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Differentiation of presynaptic nerve terminals involves changes in gene expression; these may be regulated by synaptic transmissionand/or by contact with the target muscle. To gain insight intothe control of presynaptic differentiation, we examined the regulationby target and synaptic activity of synaptic vesicle protein (SVP)genes in the chick ciliary ganglion (CG). In the CG, two SVP genes,synaptotagmin I (syt I) and synaptophysin II (syp II), are coordinatelyupregulated at the time of target contact. To test the hypothesisthat this upregulation is induced by target contact, we examinedmRNA levels of syt I and syp II in CGs from embryos in which oneeye had been removed before axon outgrowth. As expected, targetremoval prevented the normal upregulation of syt I mRNA in thedeprived ganglion. In contrast, and unexpectedly, syp II mRNAupregulation was not affected. The target dependence of syt Iupregulation was not attributable to nerve-muscle transmission,because blockade of this transmission had no effect on SVP mRNAlevels. Surprisingly, blockade of synapses onto CG neurons fromthe brain also did not affect syt I mRNA levels but increasedlevels of syp II mRNA. We conclude that contact with target inducesupregulation of syt I mRNA, which is the case for spinal motorneurons. However, the normal upregulation of syp II mRNA is notcontrolled by the same signal(s). Instead, our results suggestthat these two SVP genes are differentially regulated, both bytarget contact and by blockade of synaptic transmission.

Key words: synaptotagmin; synaptophysin; ciliary ganglion; synapse formation; atropine; hemicholinium-3

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Synaptogenesis at the neuromuscular junction requires coordinate differentiation of both the presynaptic and postsynapticelements. For the presynaptic nerve terminal, this differentiationinvolves the reorganization of specific synaptic proteins (e.g.,Bixby and Reichardt, 1985; Dai and Peng, 1996) as well as changesin the levels of expression of synapse-specific genes (e.g., Louand Bixby, 1993, 1995). Relatively little is known concerningthe mechanisms through which these changes in gene expressionare regulated.

The most well-studied group of nerve terminal-specific proteins consists of the synaptic vesicle proteins (SVPs). The SVPsgenerally comprise families of related isoforms with differentdevelopmental and tissue distributions (Bajjalieh et al., 1994);prominent examples include the synapsins, the synaptophysins,and the synaptotagmins (Bahler et al., 1990; Bixby, 1992; Jahnand Sudhof, 1994; Li et al., 1995). In previous studies, we haveused the expression of SVP genes as molecular markers of presynapticdifferentiation (Lou and Bixby, 1993, 1995; Campagna et al., 1997).In the chick ciliary ganglion (CG), mRNAs encoding two SVPs, synaptophysinII (syp II) and synaptotagmin I (syt I), are upregulated at thetime that these neurons contact their target muscle (Lou and Bixby,1993, 1995). These results suggest that contact with muscle inducesthe upregulation of SVP genes in the innervating motor neurons.This hypothesis has been partially tested in the case of spinalmotor neurons. It has been found that the increase in syt I mRNAwithin the lateral motor column, which normally occurs at thetime of muscle contact, is abrogated by removal of this targetbefore innervation (Campagna et al., 1997).

Our study with spinal motor neurons implies that at least one SVP gene depends on target contact for upregulation in thisneuronal population. However, several important questions remainunanswered. Is syt I upregulated by target contact in other motorneuron populations, and are other SVP genes upregulated by targetcontact? Is synaptic activity between neuron and muscle requiredfor upregulation of SVP genes? Are SVP genes regulated by synapticsignals impinging on the motor neuron itself?

We have addressed these issues using the chick CG in vivo as our motor neuronal population. We examined levels of mRNA fortwo SVPs, syt I and syp II, in CG neurons in vivo after variousperturbations of normal development. These perturbations included(1) peripheral target (eye) removal before innervation and (2)application of drugs blocking either postganglionic (CG-target)activity or both postganglionic and preganglionic (brain-CG) activitybefore and during the early innervation period. Our results suggestthat levels of mRNA encoding syt I and syp II are not coordinatelyupregulated by contact between neurons and muscle targets as expected;instead, distinct mechanisms operate to regulate these two SVPgenes in developing CG neurons.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Materials. Fertilized White Leghorn eggs were purchased from SPAFAS (Norwich, CT) and incubated in a humidified forced-draftincubator until the desired stage of development. All RNase-freereagents and atropine sulfate were purchased from Sigma (St. Louis,MO). Hemicholinium-3 was obtained from Aldrich (Milwaukee, WI).

Surgical manipulations. Chick embryos from embryonic day 2 (E2) (stage 13) to E10 (stage 36) were used in this study. Allstaging was done by the staging methods of Hamburger and Hamilton(1951). Unilateral eye removals were performed at E2 (stages 10-13),following previously described methods (Dourado et al., 1994).Briefly, the egg was windowed, and the extraembryonic membraneswere opened just enough to expose the head of the developing embryo.Finely sharpened forceps were then used to remove the developingoptic vesicle unilaterally. The window was resealed with ScotchMagic tape (3M), and the embryos were placed back into the incubatoruntil E8. Embryos were analyzed only if no trace of eye tissuewas observed on the operated side at the time of harvest.

Drug treatments. All drugs were dissolved in sterile isotonic saline and were delivered in doses of 100 µl per dose eitheronce or twice daily from E6 to E8.5. Eggs were windowed at E5;after the shell and extraembryonic membranes were perforated,the egg was resealed with Scotch Magic tape (3M). A formula fromPilar et al. (1987) was used to determine the correct dosage ofatropine. Briefly, effective concentrations of drug were determinedassuming uniform diffusion with an estimated egg volume of 40ml. A dose of 0.15 mg/dose/d (Meriney et al., 1987) (estimatedfinal concentration, 5 µM) was applied to the chorioallantoicmembrane of the embryo. Hemicholinium-3 was applied to windowedembryos as described at a dose of 1 mg/dose (twice daily; estimatedfinal concentration, 40 µM) (Maderdrut et al., 1988). Controlsfor both drug experiments involved windowing the egg and removingthe shell membrane at E5, followed by application of 100 µl ofsaline (once or twice daily) from E6 to E8.5.

Assays of drug efficacy. The efficacy of atropine treatment was measured at E10, after application of atropine from E6 toE10 (stages 29-36), using an iris contraction assay originallydeveloped by Pilar et al. (1987). Briefly, eyes with intact, attachedCGs were isolated from both drug-treated and saline controls at6 hr after the final injection. Iris contraction was measured(with a red-filtered light) using a dissecting microscope withan eyepiece micrometer either after electrical stimulation (20sec at 50 Hz) through a suction electrode attached to the ganglionor after bathing the iris in 100 mM KCl for direct contraction.The preparation for stimulation has been described previously(Pilar et al., 1987).

The efficacy of hemicholinium-3 (HC-3) treatment was measured by use of a leg kick assay for neuromuscular synapses and bymeasurements of transmission through the CG. Leg kick measurementswere made at ~9 hr after the first E8 injection and before thesecond E8 dose. A window was opened over the embryo, and the frequencyof discrete spontaneous hindlimb kicks over a 5 min period wasmeasured. Synaptic transmission through the CG was measured usingmethods similar to those of Landmesser and Pilar (1974a), withganglia from E8 to E9 embryos.

RNase protection assay. RNA isolation and RNase protection assays were performed as described previously (Lou and Bixby, 1993,1995). Modifications to the original RNase protection assay proceduresinclude the following. A new syt I probe was generated from aBglII/NspI digest of clone p65.1 (Lou and Bixby, 1993) [nucleotides(nt) 1279-1590 of the published sequence]. This piece was clonedinto the pSP73 vector (Promega, Madison, WI) in the antisenseorientation relative to the SP6 promoter. This resulted in a probesize of 355 nt and a protected fragment of 312 nt. This methodof probe preparation allowed for individual preparations of totalRNA to be analyzed simultaneously for levels of syp IIa, syp IIb,syt I, $beta$ -actin, and neurofilament-M mRNAs (see Fig. 1). Signalswere quantified from autoradiographic film using SigmaScan Pro(Jandel Scientific, Corte Madera, CA). Multiple autoradiographicexposures were used to ensure that signals were in the linearrange.

Normalization of mRNA signals. In a previous study, we outlined our rationale for the use of neurofilament-M (nfM) mRNA asa normalization standard rather than absolute mRNA amount, neuronnumber, ganglion number, or $beta$ -actin mRNA (Lou and Bixby, 1995).As a test of this justification, we have compared the relativelevels of syp II (IIa + IIb) mRNA at E7 and E9 using three differentmethods of normalization. Normalizing syp II mRNA to the numberof ganglia (equivalent to neuron number at this time) yieldeda sixfold apparent upregulation between E7 and E9, whereas normalizingto $beta$ -actin (2.5-fold) or nfM (threefold) gave results approximatelycomparable with each other (data not shown). We conclude thateither $beta$ -actin or nfM mRNA is a suitable normalization standard,with nfM providing the most specific test (Lou and Bixby, 1995),whereas normalization to ganglion or neuron number overestimatesthe magnitude of specific SVP mRNA upregulation. In this study,therefore, the relative amounts of syt I and syp II mRNAs werenormalized to nfM and/or to $beta$ -actin mRNA.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

SVP mRNA expression in the CG after unilateral eye removal

To test the hypothesis that increased levels of SVP mRNAs are induced by contact of CG neurons with their targets, we examinedthe levels of syt I and syp II mRNAs after unilateral eye removal.The developing optic vesicle was removed before CG formation (E2;stage 13-19), and the animals were allowed to develop until E8(stage 34), ~1 d after contact of CG neurons with their targets.Examination at this stage eliminates the interpretational difficultiescaused by cell death; morphological changes associated with celldeath are first observed in target-deprived CG neurons at E9 (stage35) (Landmesser and Pilar, 1974a, 1976). Before the period ofcell death, synaptic transmission and ultrastructure of the CGneurons are normal (Landmesser and Pilar, 1974b).

Our laboratory has shown previously that mRNA expression levels for syt I and for syp II are upregulated approximately threefold(2.5-fold for syt I) within 2 d (E7-E9; stages 31-35) of contactwith targets in the eye and that these are the only significantincreases in mRNA expression during embryonic development (Louand Bixby, 1993, 1995). In those studies, we did not measure mRNAlevels at E8. To test whether SVP mRNAs are upregulated as earlyas E8, we measured mRNAs for syt I and syp II (IIa + IIb), normalizedto that for nfM, in CG neurons at E7 and E8. In these experimentswe found that syp II mRNA was 2.4-fold higher and that syt I mRNAwas twofold higher at E8 compared with E7 (data not shown). Therefore,~80% of the mRNA upregulation seen during development has occurredby 1 d after target contact (E8; stage 34). We conclude that examinationof eye-deprived ganglia at E8 will allow us to test for the targetdependence of gene upregulation.

Because it was difficult to obtain sufficient material from eye-deprived ganglia to use nfM as the normalization standard,we used $beta$ -actin in most experiments. As expected, there was a1.9-fold decrease in the expression of syt I mRNA relative tothat in the contralateral controls, almost quantitatively accountingfor the normal developmental increase (Fig. 1B). This result impliesthat syt I gene upregulation in CG neurons completely dependson the presence of the synaptic target, as is the case for spinalmotor neurons (Campagna et al., 1997). Surprisingly, however,there were no significant differences in the levels of syp IIaor syp IIb between the controls and eye-deprived ganglia (Fig.1). Indeed, the data show a slight trend toward higher levelson the deprived side for syp IIa. To ensure that our results werenot biased by the use of $beta$ -actin normalization, we performed twoexperiments using nfM mRNA as the standard. In these experiments,syt I mRNA levels in the eye-deprived CG were decreased by thesame amount that was seen with the actin experiments (1.8-fold),whereas levels of syp IIa and syp IIb mRNA were not significantlychanged, when compared with the contralateral controls. Althoughthese data must be considered less reliable than are the datanormalized to actin, they confirm that the syt I mRNA upregulationin developing CG is target-dependent and that syp II mRNAs arenot upregulated by the same mechanism.

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Figure 1. Expression levels of SVP mRNAs in control and target-deprived CGs at E8. A, Autoradiogram of an RNase protection assay. On the right, the probes used in the assay are shown, and the corresponding signals from the protected fragments are shown on the left. EYE $-$ , CGs ipsilateral to the removed eye; CON, CGs contralateral to the removed eye. The positions of molecular weight markers (in nt) are shown with arrows. Note that the syt I signal is reduced in the EYE $-$ lane, even though the actin and nfM signals are greater. B, Relative levels of SVP mRNAs in contralateral control (shaded bars) and target-deprived (open bars) CGs, quantified from four experiments with 12-18 ganglia per condition per experiment (mean ± SEM). The levels of syt I, syp IIa, and syp IIb mRNA are shown normalized to that of actin. Note that syp II mRNA levels are not affected by the absence of target but that syt I mRNA levels are reduced 1.9-fold (p < 0.001). Qualitatively similar results were obtained in two experiments using nfM mRNA as a standard (see text).

SVP mRNA expression after blockade of peripheral synaptic activity

Given the target dependence of syt I mRNA upregulation, it is natural to wonder whether "target contact" in this context requiressynaptic activity. Maturation of the synaptic apparatus at neuromuscularjunctions seems to depend on neuromuscular activity (Lohof etal., 1993; Poo, 1994; Xie et al., 1997). Therefore, it is reasonableto suppose that the upregulation of SVP genes, a presumed requirementfor this maturation, could be linked to neuromuscular transmission.

The ciliary ganglion contains two types of cholinergic neurons: ciliary neurons and choroid neurons. Synaptic transmissionfrom choroid neurons to smooth muscle in the choroid layer ismuscarinic. Although transmission from ciliary neurons to matureiris muscle is nicotinic, only muscarinic ACh receptors are functionalon iris muscle before E11 (stage 37) (Pilar et al., 1987). Therefore,the muscarinic agonist atropine would be expected to block transmissionfrom both neuronal types between E6 and E10 (Fig. 2). To investigatethe role that neuromuscular activity plays in syt I mRNA upregulationin the CG, we delivered an atropine solution daily to the chorioallantoicmembrane of embryos beginning at E6 (stage 29) and harvested theCGs at E9 (stage 35), 15 hr after the final injection. These ageswere chosen because they span the time from first peripheral contactof CG axons (Meriney and Pilar, 1987) to the time of SVP geneupregulation. To test the efficacy of the atropine blockade, weexamined CG-evoked contraction of the iris in control and atropine-treatedembryos 6 hr after a final in ovo application. In these experiments,atropine-treated animals showed a 79% reduction in iris contractionwhen compared with saline controls (Table 1). This is likelyto be an underestimate of the in ovo effect, because the eyeswere bathed in normal saline during the experiments and atropinecould have begun to wash out. Our results confirm the resultsof Pilar et al. (1987), showing that transmission to the irisat early stages is muscarinic, and demonstrate that we establishedan atropine dose that is able to block substantially synaptictransmission to the iris from the CG.

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Figure 2. Schematic of the neural circuit involving the CG and the sites of drug action (arrows) for atropine and HC-3. Brainstem neurons from the accessory oculomotor nucleus (AON) make nicotinic cholinergic synapses onto both types of neurons (ciliary and choroid) in the CG. In turn, CG neurons send axons in the postganglionic nerve to make cholinergic synapses onto targets in the eye, which include the iris and ciliary body for the ciliary neurons and smooth muscle in the choroid for the choroid neurons. Before E10, when our experiments were performed, both ciliary and choroid postganglionic synapses are blocked by atropine. HC-3, by depleting neurons of acetylcholine, blocks both pre- and postganglionic synapses.


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Table 1. Effect of atropine treatment on iris contraction

Blockade of transmission from CG neurons to their muscle targets had no effect on the levels of either syt I or syp II mRNAs(Fig. 3). These data suggest that the target dependence of sytI mRNA upregulation is not attributable to functional synaptictransmission. Rather, the target-derived signal seems effectivein the absence of synaptic activity.

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Figure 3. Expression levels of SVP mRNAs in control and atropine-treated CGs at E9. A, Autoradiogram of an RNase protection assay. Signals are approximately equal in the control (Con) and atropine-treated (Atr) lanes. nf, Neurofilament-M. B, Relative levels of SVP mRNAs in control (shaded bars) and atropine-treated (open bars) CGs, quantified from two experiments with 20-30 ganglia per condition per experiment (mean ± range). The levels of syt I, syp IIa, and syp IIb mRNAs are shown normalized to that of nf mRNA. Note that RNA levels for all three SVPs are unaffected by the block of peripheral synaptic activity.

Syt I and syp II mRNA expression in the presence of ganglionic and peripheral activity-blocking drugs

The normal developmental increase in syp II mRNA does not depend on contact with muscle targets or synaptic activity. Onepossibility is that the increase in syp II mRNA is induced bysynaptic activity from preganglionic neurons in the accessoryoculomotor nucleus. There are numerous examples of genes in postsynapticneurons being upregulated by activity from innervating neurons(e.g., Black et al., 1985). To elucidate the role that preganglionicactivity may play in the upregulation of syp II and syt I mRNAs,we applied HC-3 to embryos in ovo. HC-3 prevents the reuptakeof choline from the synaptic cleft into the presynaptic terminaland thereby prevents cholinergic nerve terminals from synthesizingand secreting acetylcholine. Because CG neurons are both cholinoceptiveand cholinergic, HC-3 should effectively block both pre- and postganglionictransmission (Fig. 2).

We applied HC-3 in ovo, beginning at E6 (stage 29; the time at which CG neurons begin to receive synapses) (Landmesser andPilar, 1972) and continuing to E8.5 (stage 34), and examined theCGs at E9 (stage 35), 0.5 d after the final HC-3 injection. BecauseHC-3 affects cholinergic transmission in general, we could testits efficacy by examining peripheral neuromuscular activity, asmeasured by the frequency of spontaneous hindlimb kicks. Whenwe examined embryos 9 hr after injection (at E8), we found thatHC-3 reduced hindlimb kicks from a control value of 9.9 ± 1.5kicks/min (mean ± SEM; n = 4 embryos) to 2.6 ± 0.5 kicks/min (n= 5), a reduction of 76%. It was also clear that overall movementof the embryos was considerably reduced by the drug treatment,although this was not quantified. Thus, our HC-3 dose largelyinhibited neuromuscular activity during this period.

We examined SVP mRNA levels from HC-3-treated CGs using nfM as the normalization standard. As was the case for blockade ofpostganglionic activity alone, there was no effect of the HC-3treatment on levels of syt I mRNA (Fig. 4). Therefore, the target-dependentelevation of syt I mRNA does not require pre- or postganglionicsynaptic activity. Surprisingly, however, HC-3 treatment not onlydid not reduce syp II levels but actually resulted in increasesin syp II mRNAs (Fig. 4). Syp IIa mRNA levels were elevated 1.8-foldin drug-treated CGs (p < 0.05), whereas syp IIb levels increased~1.7-fold (p < 0.01). Therefore, syp II mRNAs are upregulatedby cholinergic blockade, whereas levels of syt I mRNA are unchanged.

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Figure 4. Expression levels of SVP mRNAs in control and HC-3-treated CGs at E9. Relative levels of SVP mRNAs are shown for control (shaded bars) and HC-3-treated (open bars) CGs, normalized to nfM, quantified from four experiments with 20-30 ganglia per condition per experiment (mean ± SEM). Both syp IIa (p < 0.05) and syp IIb (p < 0.01) are significantly elevated by the HC-3 treatment. There is no significant change in syt I mRNA. Similar results were seen in two experiments in which the data were normalized to $beta$ -actin, although syp II mRNA increases were not as great in the case with $beta$ -actin (data not shown).

Because the upregulation of syp II mRNA was unexpected, we examined directly whether synaptic transmission in the CG was blockedby our drug-treatment protocol. This was accomplished by in vitrostimulation of the preganglionic nerve while recording from thepostganglionic nerve. In control ganglia, preganglionic stimulationproduced action potential activity that could be recorded postsynaptically(n = 2/2 ganglia), and this was abolished by incubation in a lowCa²⁺ and high Mg²⁺ solution (Fig. 5). In ganglia treated with HC-3 for 3 d and examinedat E9, this synaptically evoked activity was absent (n = 3/3 ganglia;Fig. 5). This result was not attributable to nerve damage, becausedistal stimulation of the postganglionic nerve produced a largecompound action potential (Fig. 5). Therefore, our HC-3 treatmenteffectively blocked synaptic activity in the CG.

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Figure 5. Blockade of transmission through the CG by treatment with HC-3. Suction electrodes were used for stimulation and recording from isolated CG examined in vitro. A, B, In untreated embryos, preganglionic stimulation (blank area in trace) produced action potential activity (A). This evoked activity was abolished after incubation in saline containing 0.1 mM Ca²⁺ and 6 mM Mg²⁺ (B). C-E, Similar preganglionic stimulation of CG from HC-3-treated embryos evoked no activity, either in normal saline (C) or in low Ca²⁺ and high Mg²⁺ (D), despite the fact that spontaneous action potentials could sometimes be seen in these nerves (data not shown) and that distal stimulation of the postganglionic nerve produced a robust compound action potential (E). Calibration: A-D, 20 µV, 5 msec; E, 120 µV, 5 msec.

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

In the chick CG, at least two different SVPs, syt I and syp II, are upregulated at the time of contact with peripheral targets(Lou and Bixby, 1993, 1995), and results with spinal motor neuronssuggested that these upregulations were likely target-dependent,at least in the case of syt I (Campagna et al., 1997). Our presentresults demonstrate that, as expected, upregulation of syt I mRNAin the CG depends on the presence of the synaptic target. In addition,we have extended these results to show that neither pre- nor postganglionicsynaptic activity is required for this target-dependent gene upregulation.Contrary to our expectations, however, syp II mRNA is not regulatedin the same way. Not only is the developmental increase in sypII mRNA independent of target contact, but these mRNAs, unlikethat for syt I, are upregulated after blockade of pre- and postganglionictransmission with HC-3. The surprising conclusion is that sytI and syp II mRNAs are not coordinately regulated, either by synapticactivity or by contact with peripheral targets.

Several key strengths of this work deserve mention. First, because we found that upregulation of CG SVP genes is substantialby E8, we were able to work within a developmental time framethat avoided complications caused by neuronal cell death. Second,our normalization to nfM (and to $beta$ -actin) ensured that our measuredchanges in SVP mRNAs were selective and not attributable to generalizedneuronal growth or neuronal differentiation. Third, our peripheralblockade was achieved via the use of atropine, which blocks bothciliary and choroid transmission at these early time points, incontrast to nicotinic blocking agents such as $alpha$ -bungarotoxin.Finally, we applied activity-blocking drugs during a short, relevantdevelopmental window, minimizing the risk of irrelevant side effectsof the drugs.

Combined with the earlier study of Campagna et al. (1997), our data demonstrate the existence of target-dependent developmentalincreases in syt I mRNA in two separate populations of motor neurons.This confirms (for one SVP) our original hypothesis (Lou and Bixby,1993) that contact of motor neurons with peripheral targets wouldresult in upregulation of synapse-specific genes. Clearly, itwould be of interest to know whether this kind of target-mediatedupregulation occurs at neuron-neuron synapses as well.

A number of studies have examined the developmental regulation of neuronal genes in the CG (e.g., Dourado et al., 1994; Bruseset al., 1995; Levey et al., 1995; Thomas et al., 1995). In particular,our data add to existing evidence from the Jacob and Dryer laboratoriesthat contact with peripheral targets is required for normal expressionof neuron-specific genes in the CG. Levey et al. (1995) have shownthat loss of peripheral targets reduces levels of mRNA encoding $alpha$ 3 and $beta$ 4 ACh receptor (AChR) subunits in the CG, without changinglevels of $alpha$ 5 mRNA. Similarly, Dourado et al. (1994) showed thatloss of target prevented the normal expression of the Ca²⁺-dependent K⁺ current in CG neurons and significantly reduced a component ofslow inactivation of the A-type K⁺ current. Therefore, contact with muscle targets is required forthe normal upregulation of at least three distinct types of neuronalgenes, two of which are clearly related to synapse formation.Interestingly, in both of the above cases, as in the present study,target-dependent upregulation was found for some, but not all,of the genes encoding proteins with similar functions (SVPs, AChRsubunits, and K⁺ channels).

Syt I mRNA, but not syp II mRNAs, requires the presence of target for its developmental upregulation. In addition, syp IImRNAs, but not syt I mRNA, are upregulated after an HC-3-mediatedderangement of acetylcholine metabolism. These results indicatethat the control mechanisms regulating mRNA expression are differentfor different SVP genes. Our initial assumption, therefore, thatgenes encoding membrane proteins of synaptic vesicles would becoregulated is evidently incorrect. It seems reasonable to supposethat this differential regulation of SVP genes could be relatedto different nonsynaptic functions of the corresponding proteins.For example, other proteins involved in vesicle exocytosis seemto regulate axon growth as well (Osen-Sand et al., 1993; Igarashiet al., 1996).

Our experiments lead to two important questions concerning the regulation of syp II mRNA. First, if neither contact with peripheraltargets nor synaptic activity are required for developmental upregulation,how is this upregulation achieved? Second, how does synaptic blockadewith HC-3 lead to upregulation of syp II mRNAs? Although we cannotanswer the first question, some clues may be found in considerationof the second question. We can think of two broad categories ofmechanism for the HC-3 effect on syp II mRNAs. First, synapticdrive from preganglionic inputs may be inhibitory to syp II mRNAexpression (or the loss of such drive could signal mRNA upregulation).In either case, the effect of HC-3 would be to promote upregulationby blocking preganglionic synapses. Second, there could be somekind of negative coupling between synthesis and/or release ofacetylcholine by CG neurons and the expression in these neuronsof syp II mRNAs. In this case, the effect of HC-3 would be toupregulate syp II mRNA via the inhibition of acetylcholine synthesisand/or release by the CG neurons themselves. We cannot distinguishamong these and other possibilities at present.

Our experiments on regulation of SVP genes in motor neurons (Lou and Bixby, 1993, 1995; Campagna et al., 1997; this study)have been driven by the hypothesis that, during development, contactwith synaptic targets should lead to the upregulation of SVP genes.Where does this hypothesis stand? In the case of syt I, our evidencesuggests that the hypothesis is correct for two different populationsof motor neurons. However, it is now clear that not all SVP genesare regulated by target contact at the level of mRNA expression.Given that mature synapses require relatively large amounts ofSVPs, how might these levels be achieved during synapse formationand maturation for proteins like syp II? One recent study suggeststhat, at least in vitro, developmental upregulation of synaptophysin(a close relative of syp II) occurs mainly at the level of initiationof protein translation (Daly and Ziff, 1997). If this is truein vivo, it may be that target regulation of SVP expression isindeed a general phenomenon but that different mechanisms areused in different situations to achieve this general goal.

  FOOTNOTES

Received Oct. 27, 1997; revised April 24, 1998; accepted May 12, 1998.

This work was supported by the National Science Foundation Grant IBN 9603928 and by the National Institutes of Health GrantNS 34412 to J.L.B. J.A.P. was supported by a Cardiovascular PharmacologyTraining Grant from the National Institute of Heart, Lung, andBlood (HL 01788). S.A.B. was supported by a Howard Hughes MedicalInstitute Predoctoral Fellowship. We thank Jason Campagna andthe Jacob lab for invaluable advice on the techniques of opticvesicle extirpation, Ken Muller for generously allowing us touse physiology apparatus, and Chuck Luetje for his helpful commentson this manuscript.
Correspondence should be addressed to Dr. John L. Bixby, Department of Molecular and Cellular Pharmacology and NeuroscienceProgram, University of Miami School of Medicine, 1600 Northwest10th Avenue, Miami, FL 33136.

Dr. Plunkett's present address: Miami Project to Cure Paralysis, University of Miami School of Medicine, 1600 Northwest 10thAvenue, Miami, FL 33136.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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