Optical Mapping of Neural Responses in the Embryonic Rat Brainstem with Reference to the Early Functional Organization of Vagal Nuclei

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The Journal of Neuroscience, February 15, 1998, 18(4):1345-1362

Optical Mapping of Neural Responses in the Embryonic Rat Brainstem with Reference to the Early Functional Organization of Vagal Nuclei
Katsushige Sato, Yoko Momose-Sato, Akihiko Hirota, Tetsuro Sakai, and Kohtaro Kamino
Department of Physiology, Tokyo Medical and Dental University School of Medicine, Bunkyo-ku, Tokyo 113, Japan

  ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

We examined the functional organization of the vagal nuclei of the rat embryo during morphogenesis, using multiple-site opticalrecording with a voltage-sensitive dye. Slice preparations withvagus nerve fibers were dissected from 13- to 16-d-old embryonic(E13-E16) rat brainstems, and they were stained with the dye.Electrical activity in response to vagal stimulation was recordedoptically from many sites. In the E13-E14 preparations, two typesof spike-like optical signals were recorded: one was a narrowsignal (type I), and the other was a broader signal (type II).Comparison with the morphology revealed by DiI labeling suggeststhat the type I signal response area corresponds to the nucleusof the tractus solitarius, and the type II signal response areacorresponds to the dorsal motor nucleus of the vagus nerve. Inthe E15-E16 preparations, type I signals were followed by a slowsignal related to glutamate-mediated excitatory postsynaptic potentials,suggesting that synaptic function is organized in the nucleusof the tractus solitarius by the 15-d-old embryonic stage. Inthe E14 preparation, a small, slow signal was evoked only in Mg²⁺-free solution, implying that postsynaptic function related toNMDA receptors emerges, in latent form, at the 14-d-old embryonicstage. In the E15 and E16 preparations, although the nucleus ambiguusis identified morphologically, no neural response-related opticalsignal was observed there, indicating that the embryonic organizationof morphology and physiological function is not necessarily temporallycoincident. We have mapped the dynamic spatiotemporal patternsof the evoked optical signals and have outlined the early phaseof the functional organization of the cranial nuclei related tothe vagus.

Key words: optical mapping; brainstem; vagal nuclei; development; synaptic activity; voltage-sensitive dye

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Ontogenetic approaches to the emergence of spatiotemporal patterns of electrical activity in neural circuits could be a usefuland rational strategy to study the functional organization andarchitecture of the extremely complex CNSs of mammals. Electrophysiologicalexperiments on early embryonic CNSs of mammals, however, are oftendifficult or impossible because of the small size and fragilityof the young embryonic cells. Thus, little is known about theontogenesis and early embryonic development of the functionalorganization and architecture in the mammalian CNS.

Optical techniques using fast voltage-sensitive dyes have made it possible to monitor electrical activities in small cellsthat are difficult or impossible to access by traditional electrophysiologicalmeans and also to facilitate the simultaneous recording of electricalactivity from multiple sites in living systems such as CNSs (Salzberget al., 1977; Cohen and Salzberg, 1978; Grinvald et al., 1988;Salzberg, 1983, 1989; Kamino, 1990). A particularly importantapplication of this technique using photodiodes involves the analysisof the components of presynaptic and postsynaptic potentials basedon the analysis of the shapes of the signal wave (Grinvald etal., 1982; Komuro et al., 1991; Momose-Sato et al., 1994).

Our previous studies have established the feasibility of using optical techniques to record the electrical activity in brainstempreparations isolated from early developing embryos; using suchoptical techniques, we have investigated the onset and early developmentof action potential activity evoked by vagus, or glossopharyngealstimulation in young embryonic chick brainstems during early developmentalstages (Kamino et al., 1989b, 1990; Momose-Sato et al., 1991,1994; Sato et al., 1995), and we found that distinct glutamate-mediatedEPSPs are generated within the nucleus of the tractus solitariusin 7-d-old embryonic chick brainstems (Komuro et al., 1991; Momose-Satoet al., 1991, 1994). In addition, in experiments using two antagonists,DL-2-amino-5-phosphonovaleric acid (APV) and 6-cyano-7-nitroquinoxaline-2,3-dione(CNQX) for EPSP-related slow optical signals, we have identifiedNMDA and non-NMDA receptor-related phases (Komuro et al., 1991;Momose-Sato et al., 1994). Subsequently we reported the earlydevelopmental characteristics of the Mg²⁺-sensitive components of the slow signals (Momose-Sato et al.,1994). We have also found, recently, that the glutamatergic EPSP-relatedslow optical signal is reduced by GABA (Momose-Sato et al., 1995a)and by glycine at high concentration (Sato et al., 1996b).

Throughout those investigations, inevitably, we have noted the embryogenesis of the electrical activity and functional organizationin mammalian CNSs. Here we address some aspects of the electricalactivity that occurs in response to vagus stimulations in theearlier embryonic rat brainstem. Using a 1020-element photodiodearray recording system that has been developed recently (Hirotaet al., 1995), together with a 128-element photodiode array system,we first began to monitor electrical activity evoked by vagalstimulation in the brainstem preparation with the goal of exploringthe spatiotemporal patterning of the neural responses and thentraced the embryonic functional organization of the vagus relatednuclei.

Preliminary results have been presented previously in abstract form (Sato et al., 1996a).

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Preparations. In the present experiments, we used 13- to 16-d-old embryonic (E13-E16; n = 118) rat brainstem slice preparations(the date of mating was designated embryonic day 0). Wistar ratsof 13-16 d gestation were anesthetized deeply with ether, andfetuses were removed surgically. The brainstems with vagus nervefibers were dissected from the embryos. The isolated brainstempreparation was attached to the silicone (KE 106LTV; Shin-etsuChemical Co., Tokyo, Japan) bottom of a simple chamber by pinningit with tungsten wires. The preparation was kept in a bathingsolution with the following composition (in mM): NaCl, 149; KCl,5.4; CaCl₂, 1.8; MgCl₂, 0.5; glucose, 10; and Tris-HCl buffer,pH 7.4, 10. The solution was equilibrated with oxygen. The piamater attached to the brainstem was carefully removed in the bathingsolution under a dissecting microscope. Slices were then prepared,with the right and/or left vagus nerve fibers attached, by sectioningthe embryonic brainstem transversely at the level of the rootof the vagus nerve. The thickness of the slice was ~1000-1500µm.

Voltage-sensitive dye staining. The isolated slice preparation was stained by incubating it for 15-20 min in a Ringer's solutioncontaining 0.2 mg/ml voltage-sensitive merocyanine-rhodanine dyeNK2761 (Nippon Kankoh Shikiso Kenkyusho, Okayama, Japan) (Kaminoet al., 1981, 1989a; Salzberg et al., 1983; Kamino, 1991; Momose-Satoet al., 1995b), and the excess (unbound) dye was washed away withdye-free Ringer's solution before recording. This merocyanine-rhodaninedye has been established to be particularly useful in embryonicnervous and cardiac tissues (Kamino, 1990, 1991). Furthermore,it has been confirmed that the immature cellular-interstitialstructure of the early embryonic brainstem preparations allowsthe dye to diffuse readily from the surface to the interior regions(Sato et al., 1995).

Electrical stimulation. For preparations in which the vagus nerve was stimulated, the cut end of the nerve was drawn intoa microsuction electrode fabricated from TERUMO hematocrit tubing(VC-HO75P; TERUMO Co., Tokyo, Japan), which had been hand-pulledto a fine tip (~100 µm internal diameter) over a low-temperatureflame. Positive (depolarizing) square current pulses (8.0 µA/5.0msec), which evoked maximum responses, were applied to the rightor left vagus nerve.

Optical recording. Light from a 300 W tungsten-halogen lamp (type JC-24V/300W; Kondo Philips Ltd., Tokyo, Japan) was collimated,rendered quasimonochromatic with a heat filter (32.5B-76; OlympusOptical Co., Tokyo, Japan) and an interference filter having atransmission maximum at 703 ± 15 nm (Asahi Spectra Co., Tokyo,Japan), and focused on the preparation by means of a bright fieldcondenser with a numerical aperture (NA) matched to that of themicroscope objective (S plan Apo, 10×, 0.4 NA). The objectiveand photographic eyepiece (2.5×) projected a real image of thepreparation (magnification, 25×) onto a multielement silicon photodiodematrix array mounted on an Olympus Vanox microscope (type AHB-L-1).In the present experiments, we used two optical recording systems.One is a 1020-site optical recording system with a 34 × 34-elementsilicon photodiode array (Hamamatsu Photonics, Hamamatsu, Japan),which had been constructed recently in this laboratory (Hirotaet al., 1995). In Figure 1A, the schematic diagram of the systemis illustrated. In this system, each pixel (element) of the arraydetected light transmitted by a square region (54 × 54 µm²) of the preparation. An example of the relative position of thephotodiode array on the image of the preparation is shown in Figure1B. The outputs from 1020 elements were fed into amplifiers viacurrent-to-voltage converters and then passed to 32 sets of 32-channelanalog multiplexers. Each output from the 32-channel multiplexerswas fed into a subranging type analog-to-digital (AD) convertersystem with a resolution of 18 bits and was sent to a computer(LSI-11/73 system; Digital Equipment Co., Tewksbury, MA). TheAD converter was designed originally in this laboratory (Hirotaet al., 1995). Another recording system is a 128-channel multiple-siteoptical recording system using a 12 × 12-element silicon photodiodearray (MD-144-4PV; Centronic Ltd., Croydon, UK). This system hasbeen described in detail elsewhere (Komuro et al., 1991; Momose-Satoet al., 1991, 1994) (for review, see Kamino, 1990, 1991). In thissystem, each pixel of the array detected light from a square region(56 × 56 µm²) of the preparation. The output of each detector in the diodearray was passed to an amplifier (AC coupling = 3 sec) via a current-to-voltageconverter. The amplified outputs from 127 elements of the detectorwere first recorded simultaneously on a 128-channel recordingsystem (RP-890 series; NF Electronic Instruments, Yokohama, Japan)and then were passed to a computer (LSI-11/73 system, DigitalEquipment). The 128-channel data recording system is composedof a main processor (RP-891), eight input-output processors (RP-893),a 64,000 word wave memory (RP-892), and a videotape recorder.The time resolution of these systems was $sime$ 1 msec. The recordingswere made in a single sweep (for additional details, also seeFig. 1 legend). The optical measurement was performed in a stillchamber without continuous perfusion with Ringer's solution, atroom temperature, 26-28°C. The incident light was turned off exceptduring the measuring period. Under these conditions, the evokedoptical signals can often be detected continuously for >30 min.In some experiments, we performed measurements with continuousperfusion (~5 ml/min), and there was no difference between datawith and without perfusion.

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Figure 1. Schematic drawing of the simultaneous 1020-site optical recording system. A, The preparation chamber is mounted on the stageof an Olympus Vanox microscope (type AHB-L-1). Bright-field illuminationis provided by a 300 W tungsten-halogen lamp (type JC-24V/300W,Kondo-Philips) driven by a stable DC power supply. Incident lightis collimated, passed through a 703 ± 15 nm interference filter(Asahi Spectra), and focused on the preparation by means of abright-field condenser with an NA matched to that of the microscopeobjective (S plan Apo, 10×, 0.4 NA). The objective and photographiceyepieces project a magnified real image of the preparation ontoa 34 × 34-element silicon photodiode array. The outputs from 1020elements are fed into individual current-to-voltage convertersfollowed by individual amplifiers. The amplified outputs are thenfed into 32 sets of 32-channel analog multiplexers via individualRC low-pass filters. Each output of the 32 analog-to-digital conversionsystems is digitally multiplexed and is sent to a specially designedinterface in the computer system (LSI 11/73 system, Digital Equipment)using a fiber-optic transmission system. The time resolution ofthis system is 1024 samples/sec for each element. B, Example ofthe relative positions of the image of the brainstem slice preparationdissected from a 16-d-old rat embryo and the 1020-element photodiodearray grids. N.IX, Glossopharyngeal nerve; N.X, vagus nerve; IXGs,superior glossopharyngeal ganglion; IXGi, inferior glossopharyngealganglion; XGs, superior vagal ganglion; XGi, inferior vagal ganglion.

DiI labeling. The 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI) labeling method that we have usedwas essentially similar to that described by Godement et al. (1987).Embryos used for DiI labeling studies were fixed with 4% paraformaldehydein 0.1 M phosphate buffer, pH 7.4. A small crystal of the fluorescentneuronal tracer DiI (Molecular Probes, Eugene, OR) was placedin the region of the nodose ganglion. Brainstem slice preparationswith DiI placements were stored in 4% paraformaldehyde for 2-8weeks at room temperature. The brainstem dissected free from surroundingtissue was embedded in 3% gelatin and was sectioned in the transverseplane at a thickness of 50 µm on a vibratome (microslicer DTK-2000;Dosaka EM, Kyoto, Japan). Wet-mounted sections were examined withan epifluorescence microscope (Fluophot; Nikon Co. Tokyo, Japan)equipped with a rhodamine filter set (excitation, 520-550 nm;emission, >570 nm).

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Optical signals in response to vagal stimulus

Figure 2 illustrates a series of multiple-site optical recordings of neural activities in response to vagal stimulations inE13-E16 rat brainstem preparations. The electrical activitieswere evoked by a brief depolarizing square current (8 µA/5.0 msec),which gave the maximum response, applied to the right vagus nerve,and they were optically recorded simultaneously from many sitesof the preparation, using a 1020-element photodiode array in asingle sweep without averaging. We detected the optical signalswith a signal-to-noise ratio of >30. There was essentially nodeterioration of the optical signal, either from photobleachingor photodynamic damage, over a 30 min. On each recording, therelative position of the photodiode array on the image of thepreparation is drawn. Each photodiode element detected opticalsignals from a 54 × 54 µm² area in the preparation.

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Figure 2. Simultaneous multisite optical recordings of neural responses. The optical signals were evoked by vagal stimulation, and theywere recorded from E13 (A), E14 (B), E15 (C), and E16 (D) slicepreparations, using the 1020-element photodiode array. The insetsat the bottom left of each recording show the enlarged tracesof the evoked optical signals. These signals were obtained ina single sweep. The direction of the arrow to the right of therecordings indicates a decrease in transmitted light intensity(increase in absorption), and the length of the arrow representsthe stated value of the fractional change (the change in the lightintensity divided by DC background intensity).

E13 and E14 preparations
The present 1020-site optical recording system can detect the signals from a large area in the brainstem preparation. Therefore,we have been able to identify more easily the relative locationof the response area(s). First, in the recordings obtained fromE13 and E14 preparations (Fig. 2A,B), two response areas thatwere spatially separated were discriminated in the dorsal portionof the preparation: one (response area I, labeled area I) waslocated on the dorsolateral portion, and the other (response areaII, labeled area II) was located on the dorsomedial portion onthe stimulated side of the preparation. Similar results were obtainedin three preparations of E13 and in 24 preparations of E14. Althoughthe signals detected from the two areas were simple in shape,a definite difference was observed in the waveforms of the signalsfrom areas I and II. Area I exhibited shorter-duration signals(mean ± SD of half-width, 9.1 ± 0.9 msec; n = 10; labeled typeI), and area II displayed longer-duration signals (22.9 ± 5.0msec half-width; n = 10; labeled type II). This difference inthe waveform exhibited in the two response areas (areas I andII) may have significant physiological and anatomical implications(see Discussion).
When tetrodotoxin (TTX; 20 µM) was applied to the bathing solution, the signals (types I and II) were completely blocked.This result indicates that these signals were the results of actionpotentials and/or the terminal depolarization. In the part ofthe nodose ganglion and the root of the vagus nerve, electrotonicpotential-related signals, which were not blocked by TTX, weredetected.

E15 and E16 preparations
In E15 and E16 preparations (Fig. 2C,D), another type of signal (type III), composed of two components, a first, fast signalcomponent that appeared to correspond to a type I or II signaland a second, delayed slow component, was detected. Type I andtype II signals were detected from the right and left marginalzones of the response area, respectively. On the other hand, typeIII signals were detected from the boundary (overlapping) areaof areas I and II. Both the fast and slow signals in type IIIsignals were wavelength-dependent, in the same manner as the actionspectra of the used merocyanine-rhodanine dye (Momose-Sato etal., 1995b). This result indicates that they originate from evokedmembrane potential changes. Similar results were obtained from24 preparations of E15 and 34 preparations of E16.
For type III signal, two subtypes (types IIIa and IIIb) could be distinguished. Type IIIa signals appeared to be composedof a type I signal and a slow signal, and type IIIb signals werecomposed of a type II signal and a slow signal. In Figure 3, typesI, II, and III (a and b) signals are displayed on an expandedtime base. This issue will be taken up again in Discussion.

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Figure 3. Four types of the evoked signals. Type I and type II were selected from the 1020-element photodiode array optical recordingin an E14 preparation, and type IIIa and type IIIb were from anE16 preparation. See Results for additional details.

Slow signals

Electrophysiologically, four separate events related to synaptic transmission are identified: (1) the presynaptic action potential,(2) the Ca²⁺ current in the presynaptic nerve terminal, (3) the synaptic potentialin the postsynaptic cell, and (4) the spike in the postsynapticneuron.

Previously, we have reported that the signals that are composed of fast and slow components, which were similar to type IIIsignals, are observed in the early embryonic chick brainstem preparations,and that the slow optical signals correspond to glutamatergicexcitatory postsynaptic potentials (Komuro et al., 1991; Momose-Satoet al., 1994; Sato et al., 1995). In the present study, we alsoexamined some characteristics of the slow signal.

Figure 4 shows the effects of repetitive stimulation on type IIIa and IIIb signals detected from an E16 preparation. In bothtype IIIa and IIIb signals, the amplitudes of the slow opticalsignals were decreased exponentially with repetitive stimulation(0.1 Hz) applied to the vagus nerve. Although the plots were scattered,the fast spike-like signals appeared not to be affected. Thiseffect seems to reflect synaptic fatigue, and if so, it arguesthat the slow signal is related to the postsynaptic potential.As shown in Figure 5, the slow signals were also eliminated inCa²⁺-free Ringer's solution and were blocked by either Cd²⁺ or Mn²⁺ (data not shown), supporting the idea that the slow signal representsthe postsynaptic potential.

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Figure 4. The decrease in the slow optical signal amplitude with repetitive stimulation. The measurements were made on an E16 preparation.Square current pulses of 8 µA/5.0 msec and 0.1 Hz were appliedto the right vagus nerve. The relative amplitudes of the fastand slow signals in type IIIa and type IIIb are plotted againsttime in seconds. Closed circles, Fast signals in type IIIa; closedtriangles, slow signals in type IIIa; open circles, fast signalsin type IIIb; open triangles, slow signals in type IIIb.

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Figure 5. Optical signals detected in control and Ca²⁺-free bathing solution. In Ca²⁺-free Ringer's solution, CaCl₂ was replaced by MgCl₂. The recordingwas made 15 min after the replacement of Ca²⁺ with Mg²⁺. Similarly, the recovery experiment was made 15 min after replacementof the Ca²⁺-free Ringer's solution with normal Ringer's solution. Note thatthe slow signal was eliminated in the Ca²⁺-free Ringer's solution.

APV and CNQX sensitivity
It is well known that APV is an NMDA receptor antagonist (Nelson et al., 1986) and that CNQX is a non-NMDA receptor antagonist(Yamada et al., 1989). Accordingly, we tested the effects of APVand CNQX on the slow signal. The later phase of the slow signals(both in type IIIa and IIIb signals) was reduced by APV (200 µM),and the initial phase was reduced by CNQX (5 µM). Each exampleis shown in Figure 6, A (top traces) and B (middle traces). WhenAPV was added together with CNQX, the slow signals were eliminatedcompletely (Fig. 6C, bottom traces). These results suggest thatthe slow signal displays the glutamate-mediated excitatory postsynapticpotential, that the initial phase of the slow signal was mainlyattributable to non-NMDA receptors, and that the later phase wasattributable to NMDA receptors.

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Figure 6. The effects of APV and CNQX on the postsynaptic slow signals. The data were obtained from three different E16 preparations.A was obtained in the APV (200 µM)-containing bathing solution;B was in the CNQX (5 µM)-containing solution, and C was made inthe presence of APV (190 µM) together with CNQX (5 µM). The recordingswere made ~15 min after application of the drugs.

In the recordings shown in Figure 6, B and C, during the application of CNQX and the application of APV and CNQX, the fastoptical signals were also reduced. To clarify this event, we madeadditional experiments. The obtained results are illustrated inFigure 7. In type IIIa signal, of which the slow signal was relativelylarge (Fig. 7A), the fast signal was reduced during the applicationof APV together with CNQX, whereas in type IIIa signal, of whichthe slow signal was relatively small, the fast signal was notaffected, although the slow signal was reduced. Furthermore, onthe right traces, the expanded time base makes it clear that thefast signal associated with the larger slow signal contains thepresynaptic action potential (Fig. 7A, arrowhead) and the firingin the postsynaptic neurons (Fig. 7A, open circle), whereas thefast signal associated with the smaller slow signal contains thepresynaptic action potential alone. These results indicate thattype IIIa signal should be classified further into two subtypes,type IIIa(1) and type IIIa(2), and that in type IIIa(1) signals,the fast signal contains the presynaptic and postsynaptic actionpotential-related components (also see Fig. 16). Indeed, in typeIIIa(1) signals, it was often observed that the fast signals werepartly reduced by the repetitive stimuli and in a Ca²⁺-free Ringer's solution.

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Figure 7. Illustrations that might account for the case in which the fast signal in type IIIa contains the presynaptic and postsynapticaction potential components. In A, both the fast and slow signalswere reduced in the presence of APV together with CNQX. The enlargementsof the signals are shown on the right. This expanded time basereveals that the presynaptic and postsynaptic action potentialsare overlapped. In such a case, the slow signals were often relativelylarge. In B, the fast signal is not altered in the presence ofAPV and CNQX. In this case, the slow signal was often small. Thintraces are control in normal Ringer's solution; thick traces arerecordings made in APV (190 µM)- and CNQX (5 µM)-containing solution.

Mg²⁺ sensitivity
According to the idea that Mg²⁺ block is a key characteristic of NMDA receptors, we also examined the effects of Mg²⁺ on the slow signal. Figure 8 shows an example of optical recordingobtained from an E14 preparation in Mg²⁺-free Ringer's solution. In normal Ringer's solution containing0.5 mM Mg²⁺, explicitly, only type I signals were detected in area I. Whereas,when Mg²⁺ was removed from the Ringer's solution, in area I, small slowsignals accompanied by type I signal were evoked (Fig. 8, solidcircles). Such slow signals were not elicited in area II in Mg²⁺-free Ringer's solution. Figure 9 shows the enhancement of theamplitude of the slow signals observed in an E16 preparation inMg²⁺-free Ringer's solution.

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Figure 8. Appearance of the slow signal in Mg²⁺-free bathing solution. The signals were obtained from an E14 preparation; in normal Ringer'ssolution, no slow optical signal was observed (in the top recording),and in the Mg²⁺-free solution, small slow signals were detected (solid circlesin the bottom recording). These recordings were made by usingthe 128-element photodiode array.

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Figure 9. Enhancement of the slow signal in Mg²⁺-free bathing solution. The signals were recorded from an E16 preparation in normal Ringer'ssolution (thick traces) and in Mg²⁺-free solution (thin traces). The signals from two sites (G7,E8) were selected from the 128-element photodiode array recording.Note that the fast signals were not altered.

In the Mg²⁺-free experiment, one may provide a comment that magnesium not only affects NMDA receptors but also the transmitterrelease in being competitive to calcium. Thus we examined theeffect of APV and CNQX on the Mg²⁺ sensitivity. The slow signals that were induced in the E14 preparationsin the Mg²⁺-free solution were blocked in the presence of APV. Furthermore,in the E15 and E16 preparations, the slow signals were not enhancedin the Mg²⁺-free solution in the presence of APV, but the slow signal wasenhanced in the presence of CNQX (Fig. 10). Therefore, we concludedthat most of the Mg²⁺-sensitive component of the slow signal is attributable to NMDAreceptors.

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Figure 10. Evoked slow optical signals typical of those that appeared in APV-containing Ringer's solution and APV-containing Mg²⁺-free Ringer's solution (A) and in CNQX-containing Ringer's solutionand CNQX-containing Mg²⁺-free Ringer's solution (B). The optical recordings were madein two different E16 preparations.

Contour line mapping of optical signals

As may be seen in the original recordings shown in Figure 2, there were regional differences in the amplitudes of the evokedoptical signals. Thus, we measured the amplitudes of all of thedetected spike-like signals (type I and type II) and slow signalsshown in Figure 2, and we constructed contour line maps of thesignal amplitudes in normal Ringer's solution using an interpolationmethod.

In Figure 11A, the maps that were constructed with the data obtained from the E13-E16 preparations are illustrated. In themaps for the E13 and E14 preparations, two circular (or nearlycircular) response areas (areas I and II) were observed. The twoareas are spatially disjointed. The amplitudes of type I and typeII signals were distributed in a quasiconcentric circular patternwithin areas I and II, respectively. In the preparations of theE15 and E16, both areas I and II expanded together with an increasein the amplitudes of the signals. Furthermore, in E15 and E16preparations, the contour lines of the amplitude of the slow signalspartly overlapped areas I and II. This profile in E15 and E16confused us in the specification of areas I and II. This problemwill be considered further in Discussion.

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Figure 11. Contour line maps of the amplitude of the optical signals. The data were obtained from E13-E16 preparations, correspondingto the recordings shown in Figure 2 (A-D). Solid lines are usedfor type I and type II fast signals; dotted lines are for theslow signals. In B, the map constructed from the signals obtainedin APV and CNQX containing solution is shown. The control forthis map is E16 map shown in A.

In addition, Figure 11B illustrates the contour line map for the optical signals recorded from the E16 preparation in a Ringer'ssolution containing APV and CNQX. In this map, areas I and IIare outlined clearly and are similar to areas I and II tracedin the E13 and E14 preparations. Nonetheless, in comparison withE13 and E14, areas I and II in the E15 and E16 preparations wereclosely apposed, and their boundary was somewhat ambiguous.

Figure 12 summarizes preparation-to-preparation variation in the relative location and size of areas I and II in E13 (n = 3),E14 (n = 4), E15 (n = 4), and E16 (n = 4) preparations. The variationof the areas of the slow signals is also drawn for E15 and E16preparations. In Figure 12, the spacing between the centers ofareas I and II appeared to decrease with embryonic age.

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Figure 12. Interpreparation variation of the relative location and size of the areas in which optical signals were evoked. These illustrationswere drawn by superimposing traces from several preparations observedat each stated stage. The relative size of the areas was evaluatedapproximately from the signals of which the amplitudes (fractionalchange) were larger than 2 × 10⁴. Solid lines are used for type I and type II signals; dottedlines are for slow signals. The shapes of the preparations arerepresented by the averaged anatomical outlines of the preparationsat each stage.

To see the developmental change of the slow signal quantitatively, we measured the peak amplitudes of the slow signal in E13-E16brainstem preparations (n = 89). Table 1 gives the amplitudeof the largest slow signal detected in each preparation. In thistable, although there is some variation between the preparations,it is indicated obviously that the size of the slow signal increasedgradually, as development proceeded. This profile is shown moreclearly in Figure 13, where the mean and SD calculated for eachdevelopmental stage are given.


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Table 1. Maximum amplitude of the EPSPs evoked by the vagus nerve stimulation

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Figure 13. Developmental changes in the amplitude of the slow signals. Based on the data shown in Table 1, mean + SD of the maximumamplitude of the slow signal were calculated for each developmentalstage.

Comparison with morphology

Figure 14 shows the pathways of the vagus nerve into the embryonic rat brainstem. These photographic views were obtained fromE14 and E15 preparations in which the vagus nerves were labeledwith a carbocyanine dye, DiI. In the photograph obtained fromthe E15 preparation (Fig. 14B), three neural populations linkedto the vagus nerve were identified, and it is likely that theyindicate the relative positions of three cranial nerve nucleirelated to the vagus nerve, viz, the nucleus of the tractus solitarius,the dorsal motor nucleus of the vagus nerve, and the nucleus ambiguus.In contrast, in the E14 preparation (Fig. 14A), two neural populations,corresponding to the nucleus of the tractus solitarius and thedorsal motor nucleus of the vagus nerve, were observed, but thepopulation corresponding to the nucleus ambiguus was missing.

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Figure 14. Morphological views of the vagus nerve pathways into the brainstem. The photographs were obtained using a carbocyanine dye(DiI) fluorescence labeling method. A was made with an E14 preparation,and B was made with an E15 preparation. In B, the nucleus of thetractus solitarius (NTS), the dorsal motor nucleus of the vagusnerve (DMNV), and the nucleus ambiguus (NA) can be identified.However, in A, the nucleus ambiguus is missing. Right, Drawingstraced from the photographs.

Although the morphological views and the optical recordings are not superimposed tightly because of the difference in thethickness of the preparations, in comparison with the opticalresponse areas with the photographic profile, it is likely thatareas I and II are correlated to the nucleus of the tractus solitariusand the dorsal motor nucleus of the vagus nerve, respectively.However, in E15-E16 brainstem preparations, although the nucleusambiguus was observed morphologically, no optical responses havebeen detected from the area corresponding to the nucleus ambiguus,suggesting that the nucleus ambiguus is not yet functionally organizedat these embryonic stages.

Spatiotemporal activity mapping

To examine more closely the dynamic pattern of the neural responses, we made spatiotemporal activity maps. Figure 15, A andB, illustrates the images of the time sequences of the opticalresponses recorded from E14 and E15 preparations in normal Ringer'ssolution. In such a pseudocolor imaging display, it is difficultand often impossible to identify the presynaptic and postsynapticactivity components. So, in these figures, the imaging maps arecompared with the corresponding optical waveforms obtained simultaneouslyfrom three sites of the preparations.

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Figure 15. Spatiotemporal activity mappings. The time lapse imaging representations of the neural response in E14 (A) and E15 (B) preparationsare shown. The images are compared with the signals obtained fromthree sites of the preparations. I and II were recorded from areasI and II, respectively. III was recorded from the midarea betweenareas I and II. Color imagings were constructed from the opticalrecording signals using an interpolation method of Transform (FortnerResearch LLC, Sterling, VA).

In Figure 15A, the time courses of the appearance of two response areas (areas I and II) in an E14 preparation are depictedclearly. The neural response in area I was first visible in theframe at 15 msec (strictly speaking, during 10-15 msec); it reachedits maximum spatial extent by the frame at 20 msec and then disappearedin the frame at 35 msec. On the other hand, the neural activityin area II appeared in the frame at 20 msec; it reached its maximumspatial extent by the frame at 35 msec and then disappeared inthe frame at 90 msec. In these imaging maps, it is shown thatthere are differences between the time sequences in areas I andII; the neural activity invades first into area I, and ~5 mseclater it appears to reach area II. The activity duration in areaII was longer than that in area I, suggesting differences in conductionbetween type I and type II signals. However, because it is difficultto measure the effective distance from the stimulated site tothe response areas exactly, it was a formidable task to calculatethe conduction velocity unequivocally.

In Figure 15B, in addition to the fast responses in areas I and II, the slow optical signals related to the postsynaptic potentialsare imaged. Again in this map, the response appeared first inarea I and then, somewhat later, in area II. The activity durationin area I was shorter than that in area II, and in the framesat 70, 80, and 90 msec, only the slow signals were visible inthe overlapped area of areas I and II.

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The present work attempts to trace the initial emergence of systemic functional organization of the vagus-related nuclei inthe embryonic rat brainstem. This investigation has been madepossible, for the first time, by using multiple-site optical recordingsof neural response activities.

In the present experiments, electrical stimuli were applied to the vagus nerve with a microsuction electrode. For this experimentalprotocol, first we are reminded of the following basic features.

(1) The vagus nerve bundle contains both motor and sensory nerve fibers. Thus, the stimulation applied to the vagus nervewas simultaneously orthodromic for the sensory nerve fibers andantidromic for the motor nerve fibers. Unfortunately, at presentat least, it is a formidable task to separate the motor and sensorynerve fibers surgically, because the earlier embryonic nerve fibersare very thin and fragile.

(2) In the optical recording system that we have been using, each element of the photodiode array detects coherent opticalsignals from many neurons and processes from an area tens of micrometerson a side. Thus, signal size is proportional to the magnitudeof the membrane potential changes in each cell and process andto the number and membrane area of these elements within the fieldviewed by one photodiode (Obaid et al., 1985; Orbach et al., 1985;Kamino et al., 1989a).

As shown in Figure 2, A and B, in the E13 and E14 preparations, the two types of the fast spike-like signals, type I and typeII signals, were identified, and type I and type II signals weredetected from areas I and II, respectively. By comparison withanatomical information (e.g., for an atlas, see Altman and Bayer,1995) and the DiI labeling of the vagus nerve fibers (Fig. 14),area I was likely identified as the nucleus of the tractus solitarius,and area II was likely identified as the dorsal motor nucleusof the vagus nerve. It is, thus, reasonable to interpret typeI signals as corresponding to the orthodromic action potentialsevoked in the terminals of the sensory nerves and type II signalsas reflecting the antidromic action potentials evoked in the somataof the motoneurons.

Type I and type II signals were characterized as shorter- and longer-duration signals, respectively. Although we do not haveany experimental results, because it has not been possible touse voltage- and/or patch-clamp techniques in young embryonicpreparations, this difference in the shapes of the two type signalsmay be attributable to a difference in ion channel mechanisms.Furthermore, the longer duration of type II signals may be attributableto the dispersion of conduction velocities in the population ofmotoneuron fibers.

As can be seen in the time sequence shown in Figure 15, there was a difference in latency between type I and type II signals.Although it is difficult to estimate this result unequivocally,the conduction velocity of the orthodromic action potential inthe sensory nerve fibers appears to be larger than that of theantidromic action potential in the motor nerve fibers. It is suggestedthat there are differences in the factors determining conductionvelocity, such as nerve fiber diameter, membrane resistance, membranecapacitance, and myelination between the sensory and motor nervefibers contained in the vagus nerve bundle, in the 13-16 d embryonicstages.

Slow signals

The slow optical signals were first detected in the E15 preparations. Similarly in the case of the embryonic chick brainstem,the slow signal showed a decrease in amplitude with repetitivestimulation (Fig. 4); the result shows that embryonic synapsesfatigue very readily. Landmesser and Pilar (1972) also reportedrapid fatigue in the embryonic chick ciliary ganglion. In addition,the slow signals were reduced or blocked in Ca²⁺-free Ringer's solution (Fig. 5) and blocked by Cd²⁺ and Mn²⁺. From these interventions, we conclude that the slow opticalsignals are related to postsynaptic potentials.

The fast spike-like optical signals accompanying the slow signal were classified as either type IIIa or type IIIb. As mentionedin Results, type IIIa signal was classified further into typeIIIa(1) and type IIIa(2). Considering that the signal relatedto the postsynaptic potential is evoked within the nucleus ofthe tractus solitarius, we suppose (1) that type IIIa(1) signalis composed of type I signal and the slow signal together withthe postsynaptic firing signal; (2) that type IIIa(2) signal iscomposed of type I signal and the slow signal; and (3) that typeIIIb signal is composed of type I signal, type II signal, andthe slow signal, as illustrated schematically in Figure 16.

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Figure 16. Schematic representation of plausible origins of the different components of type IIIa(1), type IIIa(2), and type IIIb signalsevoked by vagal stimulation. The dashed lines indicate the observedsignals; the solid lines show type I, type II, and slow signals.See Discussion for additional details.

Because the slow signal is very slow (~1 sec duration) compared with intracellular EPSP electrode recordings by others inadult, juvenile, older embryos and cultured neuron preparations,there may be some concerns that the slow signal contains additionalcomponents, such as polysynaptic EPSPs. In a few experiments weincreased the microscope magnification, and we could not discernsignificant differences in the duration of the slow signals. Therefore,in the range of the microscope magnifications used in the presentexperiment, the possibility of detecting the variable delays inthe signals among the multiple neurons within the receptive fieldby one detector appears not to have been considered. Thus, weinterpret the long duration of the slow signal as attributableto slow synaptic transmission in the embryonic preparation. Onthe other hand, the slow optical signal resembles the glial signalthat was recorded from skate cerebellar slices (Konnerth et al.,1987). However, the slow signal was detected from a preparationstained with an oxonol dye (RH 482), which is relatively insensitiveto glial cell membrane potential changes (Konnerth et al., 1987).Therefore, the possibility was ruled out that the slow signalwas glial in origin.

In the E15 and E16 preparations, it seems likely that the slow signals were concentrated in the overlapping zone of areasI (corresponding to the nucleus of the tractus solitarius) andII (corresponding to the dorsal motor nucleus of the vagus nerve).In the lateral part of area I, the slow signals were not significantlyidentified. A possible explanation for this result is that thesynaptic function has not yet been completed at the lateral zoneof the nucleus tractus solitarius in these developmental stages.

The result that the slow signals were first detected in the E15 preparations suggests that the synaptic function is organizedin the nucleus of the tractus solitarius of the embryonic ratinitially around the 15-d-old embryonic stage; this may be regardedas the embryogenetic expression (origin) of synaptic transmission.

As in the case observed in embryonic chick brainstems, the slow optical signals were inhibited by APV and CNQX. We thereforeinterpret the slow optical signal as reflecting the glutamate-mediated(glutamatergic) excitatory postsynaptic potential. Furthermore,it is likely that NMDA and non-NMDA receptors emerged functionallyat the 15-d-old embryonic nucleus of the tractus solitarius.

Mg²⁺ block is a key characteristic of NMDA receptors, as shown by Nowak et al. (1984). From the observation that, in the E14preparation, the slow signal, which was not detectable in normalRinger's solution, was evoked in Mg²⁺-free Ringer's solution, we suggest that postsynaptic functionrelated to NMDA receptors emerges, in latent form, within thenucleus of the tractus solitarius at the 14-d-old embryonic stage.In addition, this experiment suggests that glutamate releasingactivity in the terminals of the sensory nerves has already beeninitiated within the nucleus of the tractus solitarius at thisembryonic stage. In other embryonic preparations, it has alsobeen reported that NMDA-mediated synaptic function is present1-2 d before the formation of non-NMDA-mediated synaptic connections(Lee et al., 1988; Ziskind-Conhaim, 1990).

With morphogenesis studies, Altman and Bayer (1982) have reported that the neurons of the nucleus of the tractus solitariusare produced between days E12 and E15 with a peak on day E13,and that the neurons of the nucleus ambiguus are produced relativelylate, with a peak on day E15. Also, Altman and Bayer (1982) haveshown that the neurons of the dorsal motor nucleus of the vagusnerve are produced with a peak on day E12. In Figure 17, the sequenceof embryonic expressions of neural responses within the vagal-relatednuclei is summarized, compared with the morphogenesis.

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Figure 17. Summary of sequence of event in the initial embryonic emergence of the neural responses in the rat vagus-related nuclei. Thefunctional events are compared with morphogenesis of the nuclei(Altman and Bayer, 1982). See Discussion for additional details.

Finally, considering the common evidence between the rat and the chick, the basic profiles in the embryogenetic expressionof functional organization of the vagal nuclei are summarizedas follows: (1) the neurons that constitute the vagal nuclei arefunctionally arranged in a hierarchical pattern; the activityis largest in the central part of the vagal nuclei; (2) althoughthe central parts of the motor and sensory nuclei are separatedspatially, the nuclei are overlapped; this evidence is one illustrationof failure in a morphological and anatomical context; (3) in thenucleus of the tractus solitarius, the synaptic function is latentlygenerated 1 d before the expression of the glutamate-mediatedEPSPs, and the onset of synaptic function is regulated by extracellularMg²⁺; and (4) in the nucleus of the tractus solitarius, the ontogeneticexpression of the EPSPs includes NMDA and non-NMDA-receptor functions.Furthermore, as shown typically in the nucleus ambiguus, the embryonicorganization of morphology and physiology/function is not necessarilytemporally coincident.

  FOOTNOTES

Received Sept. 15, 1997; revised Nov. 20, 1997; accepted Nov. 20, 1997.

This work was supported in part by grants from the Ministry of Education, Science and Culture, Japan, and Funds from the UeharaMemorial Life Science Foundation, the Research Aid of the InoueFoundation for Science, and the Esso Research Grants for Woman-Scientists(to Y.M.-S.). We thank Larry Cohen and Brian Salzberg for theirthoughtful reading of this manuscript and for helpful comments.We are grateful to Narishige Scientific Instrument Laboratoryfor construction of several special apparatuses for the equipmentand Emi Bandai for her assistance in preparing this manuscript.
Correspondence should be addressed to Kohtaro Kamino, Department of Physiology, Tokyo Medical and Dental University Schoolof Medicine, 1-5-45 Yushima, Bunkyo-ku, Tokyo 113, Japan.

Dr. Hirota's Present address: Department of Physiology, Shimane Medical University, Izumo-shi, Shimane 693, Japan.

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Results
Discussion
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