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The Journal of Neuroscience, March 15, 1998, 18(6):2212-2225
Neuromodulatory Inputs Maintain Expression of a Lobster Motor
Pattern-Generating Network in a Modulation-Dependent State: Evidence
from Long-Term Decentralization In Vitro
Muriel
Thoby-Brisson and
John
Simmers
Laboratoire de Neurobiologie des Réseaux, Université de
Bordeaux I and Centre National de la Recherche Scientifique, 33120 Arcachon, France
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ABSTRACT |
Neuromodulatory inputs play a critical role in governing the
expression of rhythmic motor output by the pyloric network in the
crustacean stomatogastric ganglion (STG). When these inputs are removed
by cutting the primarily afferent stomatogastric nerve (stn) to the
STG, pyloric neurons rapidly lose their ability to burst spontaneously,
and the network falls silent. By using extracellular motor nerve
recordings from long-term organotypic preparations of the
stomatogastric nervous system of the lobster Jasus
lalandii, we are investigating whether modulatory inputs exert
long-term regulatory influences on the pyloric network operation in
addition to relatively short-term neuromodulation. When decentralized
(stn cut), quiescent STGs are maintained in organ culture, pyloric rhythmicity gradually returns within 3-5 d and is similar to, albeit
slower than, the triphasic motor pattern expressed when the stn is
intact. This recovery of network activity still occurred after
photoinactivation of axotomized input terminals in the isolated STG
after migration of Lucifer yellow. The recovery does not depend on
action potential generation, because it also occurred in STGs maintained in TTX-containing saline after decentralization. Resumption of rhythmicity was also not activity-dependent, because recovery still
occurred in STGs that were chronically depolarized with elevated
K+ saline or were maintained continuously active
with the muscarinic agonist oxotremorine after decentralization. We
conclude that the prolonged absence of extraganglionic modulatory
inputs to the pyloric network allows expression of an inherent
rhythmogenic capability that is normally maintained in a strictly
conditional state when these extrinsic influences are present.
Key words:
pyloric motor network; neuromodulation; stomatogastric
nervous system; spiny lobster; organ culture; long-term
decentralization; functional recovery
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INTRODUCTION |
A major issue in neuroscience has
been to determine the control exerted by a presynaptic neuron on its
postsynaptic targets. To date, most work has focused on
"conventional" synaptic influences involving transient opening of
ligand-gated ion channels. In addition to this rapid-acting,
short-lasting regulation, synaptic inputs also exert persistent
long-term influences that play a major role in establishing and
maintaining the properties of their postsynaptic targets (Thoenen and
Edgar, 1982 ). Such long-term influences include regulation of
transmitter phenotype (Hyatt-Sachs et al., 1993) and synthesis (Black
and Green, 1973), receptor and gene expression (Le Moine et al., 1990;
Weiser et al., 1994), and membrane excitability (Traynor et al., 1992;
see below).
Demonstration of trans-synaptic influences has relied essentially on
two approaches, either observing innervation-dependent changes during
development or suppressing a source of synaptic input to a specified
target region in the mature nervous system. The best-studied of the
second of these approaches is denervation of the adult neuromuscular
junction. After suppression of motor innervation, pre-existing muscle
fiber ion channels proliferate and alter their distribution and
kinetics (Fambrough, 1979; Beam et al., 1985; Angelides, 1986), and new
channel types may appear (Lehouelleur et al., 1983; Lupa et al., 1995).
In contrast to muscle cells, trans-synaptic regulation of the
bioelectrical properties of central neurons, attributable in large part
to the inaccessability and complexity of the networks in which they are
embedded, is still poorly understood. Thus, when a neuronal assemblage
is deprived of a source of innervation, any modifications in cellular
properties and remaining synaptic connections are difficult to
assess.
A system amenable to such investigation is the pyloric network of the
crustacean stomatogastric nervous system (STNS). All 14 neurons of this
network lie within the stomatogastric ganglion (STG), and it is one of
the best-studied neuronal networks in which all of the constituent
neurons have been identified; much about their cellular properties and
synaptic interactions is known (Selverston and Moulins, 1987;
Harris-Warrick et al., 1992). When the STNS is placed in
vitro, the pyloric network continues to generate a rhythmic motor
pattern similar to that seen in vivo (Rezer and Moulins,
1983). Although network rhythmicity arises from an interplay between
synaptic connectivity and bursting properties intrinsic to the pyloric
neurons (Harris-Warrick et al., 1992), the expression of these
properties strictly depends on an ensemble of neuromodulatory
influences arising outside the network (Moulins and Cournil, 1982; Bal
et al., 1988). Thus, when STG inputs are blocked, pyloric neurons no
longer burst, and the network falls silent.
The aim of the present study was to assess whether central modulatory
inputs exert a long-term influence on the pyloric network in addition
to their short-term "permissive" action on rhythmogenesis. We used
extracellular motor nerve recordings from long-term organ cultures of
the STNS of the Cape lobster Jasus lalandii to compare spontaneous pyloric network activity in short- and long-term
decentralized STG and nondecentralized controls. We found that 3-5 d
after deprivation of all neuromodulatory input, the network acquires a
spontaneous rhythmogenic capability, suggesting a persistent functional
recovery from elimination of some of the central nervous inputs on
which network operation normally depends. This transition from
"conditional" to "nonconditional" states is not related to
levels of network activity, nor does it depend on the generation of
intraganglionic action potentials.
Parts of this study have been published previously (Thoby and Simmers,
1997).
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MATERIALS AND METHODS |
All experiments (n = 48) were performed on adult
male and female Cape lobster, Jasus lalandii, purchased from
commercial suppliers (Cap Langouste, Nice, France) and kept in aquaria
with fresh running seawater until used. Before dissection, lobsters
were cold-anesthetized by placing them in ice for 30-45 min. Standard
dissection techniques (Selverston and Moulins, 1987) were used; the
isolated STNS consisted of the STG with its motor nerves, the paired
commissural ganglia (CoG), the esophageal ganglion (OG), and their
interconnecting nerves including the stomatogastric nerve (stn), which
connects the STG to the OG and CoG (see Fig. 1). The STNS was pinned
out on a silicone elastomer (Sylgard 184; Dow Corning)-lined Petri dish
under sterile-filtered oxygenated lobster saline [composition in
mM: NaCl, 480; KCl, 12.75; MgSO4, 3.9;
CaCl2-2H2O, 13.7; and HEPES, 5; pH 7.45 (all
from Sigma, St. Louis, MO)] containing glucose (1 gm/l), penicillin
(35 µg/ml), and streptomycin (50 µg/ml). The preparations were
maintained at 15°C throughout the experiment with a
laboratory-constructed cooling system, and the bathing saline,
including antibiotics, was renewed daily. Under such conditions, organ
cultures remained viable for 2 weeks or more.
To isolate the STG from extraganglionic inputs, we cut the stn or, in
some cases, reversibly blocked descending axonal impulses by placing
10 7 M TTX (Sigma) in a Vaseline well
built around a desheathed portion of the stn. To ensure the absence of
impulses arising in axotomized stn fibers, we built, in several
experiments, a Vaseline well around the transected stn stump and filled
the well with a Lucifer yellow solution (Sigma; 10% in distilled
water) that was allowed to migrate (>12 hr) into the ganglionic
terminals of cut stn axons before their ablation by illumination with
intense blue light (450-490 nm; Miller and Selverston, 1979).
Extracellular motor nerve recordings were made with Vaseline-isolated
platinum wire electrodes connected to laboratory-constructed extracellular amplifiers. In most recordings, individual motoneurons could be identified by the timing of their rhythmic bursting and/or the
presence of their action potentials in known motor nerve terminal branches. Data were recorded on a Gould ES 1000 electrostatic chart
recorder and simultaneously digitized (Neurocorder DR 886) and stored
on magnetic tape (VHS, JVC).
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RESULTS |
Pyloric rhythmicity depends on modulatory
extraganglionic inputs
When the STNS is placed in vitro, the pyloric network
continues to generate a rhythmic motor program (Fig.
1A) similar to that
recorded in the intact animal (Rezer and Moulins, 1983). This pattern
consists of sequential bursts of activity in the pyloric dilator (PD),
lateral pyloric (LP), and pyloric (PY) motoneurons (Selverston and
Moulins, 1987; Harris-Warrick et al., 1992). A fundamental feature of
the Jasus pyloric network is that it is spontaneously active
in vitro only if the STG is attached to the OG and CoG (Fig.
1A). When inputs from these ganglia to the STG are
eliminated by cutting the stn or by blocking stn axonal conduction with
tetrodotoxin (TTX) (Fig. 1B), pyloric rhythmicity
ceases within 10 min (seven of seven preparations tested). When the STG is functionally reconnected to the anterior ganglia by rinsing the TTX
from the stn, the pyloric network again expresses its typical triphasic
motor pattern (Fig. 1C). These results agree with previous
reports (Moulins and Cournil, 1982; Nagy and Miller, 1987) that pyloric
rhythmicity depends on unpatterned permissive inputs from the rostral
centers that enable oscillatory burst-generating properties in
individual pyloric neurons (Bal et al., 1988).
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Figure 1.
Expression of lobster pyloric network activity
depends on descending modulatory inputs. A, Pyloric
neural output from a combined STNS preparation (schema
at left) consisting of the STG connected via the stn to the CoG and
OG. Motor nerves recorded are the lp-py nerve
(lp-pyn), which carries LP and
PY motoneuron axons, and the pd nerve
(pdn), which contains PD neuron
axons. B, Complete absence of spontaneous rhythmic
activity in the same preparation 30 min after axonal conduction in the
stn was blocked with tetrodotoxin (107 M) placed in a Vaseline well
around the stn (schema at
left). C, Spontaneous rhythmic activity
reappearing minutes after the STG is functionally reconnected to the
rostral ganglia by rinsing the toxin from the stn
(schema at left).
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Long-term STNS organ culture
Because our purpose was to assess the response of the pyloric
network to long-term removal of extrinsic modulatory inputs, we
initially established experimental conditions under which the STNS
remained viable for at least 3-5 d in vitro. This period corresponds to the time scale over which sustained changes may occur in
the intrinsic properties of central neurons (Hyatt-Sachs et al., 1993;
Evinger et al., 1994), including stomatogastric neurons (Panchin et
al., 1993; Turrigiano et al., 1995), when deprived of synaptic
influences and/or completely isolated in primary cell culture. Figure
2 shows extracellular pyloric nerve recordings from an intact STNS on the 1st, 4th, and 7th day in vitro. Robust pyloric rhythmicity continued throughout the 7 d period, with the only noticeable change being a gradual decrease in
cycle frequency from 1.2 Hz on day 1 to 0.5 Hz on day 7. Similar observations were made from all five intact STNS preparations tested,
with maximum survival periods (i.e., uninterrupted expressions of
pyloric rhythmicity) of ~20 d. As seen in the pooled data of Figure
3A, over this period, cycle
frequency decreased significantly (p < 0.001, paired Student's t test) from a mean (±SE) of
1.08 ± 0.05 Hz on day 1 to 0.62 ± 0.14 and 0.51 ± 0.16 Hz on days 5 and 7, respectively. This decline stabilized over
subsequent days (data not shown) and probably reflected the general
rundown of nervous systems operating in isolation from their normal
humoral and metabolic environment.
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Figure 2.
Spontaneous pyloric output from an intact STNS
during long-term organ culture in vitro.
A, Day 1. Rhythmic pyloric network activity recorded
extracellularly from the lateral ventricular nerve (lvn;
top trace) and the pdn (bottom
trace) of an intact isolated STNS (schema).
B, Day 4. Same preparation and nerve recordings after
4 d in vitro. C, Day 7. Same
preparation and nerve recordings after 7 d in
vitro. Although the rhythm has slowed, the pyloric network is
still spontaneously active.
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Figure 3.
Evolution of pyloric cycle frequency and phasing
of motor bursts in long-term STNS preparations in which the STG
remained connected to the rostral ganglia. A, Mean cycle
frequency (±SE) of spontaneous pyloric rhythmicity in five combined
STNS preparations at days 1, 5, and 7 in organ culture. The
preparations were continuously active throughout the experiment,
although cycle frequency gradually decreased. Each histogram was
derived from at least 50 consecutive cycles per preparation.
B, Phase relationships of the pyloric motoneurons on day
1 (clear boxes) and day 5 (shaded boxes)
in vitro. The beginning and end of each
box represent the mean (±SE) onset and offset phases of
the burst of the indicated neuron; one cycle is shown. Results are from
the same preparations used in A. Pyloric network phase
relationships did not change significantly (paired Student's
t test) in organ culture.
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In contrast, analysis of pyloric phase relationships revealed little
quantitative changes in the pyloric pattern during long-term maintenance in organ culture. As is seen in Figure 3B, which
was obtained from the same preparations used in Figure 3A,
the duty cycle (mean fraction of the cycle occupied by a burst of a
motoneuron) and the phase of activity of the PD, LP, and PY neurons
were not significantly different on days 5 and 1 of organotypic
survival.
A crucial feature of these combined in vitro STNS
preparations is that expression of pyloric network rhythmicity remains
strictly dependent on extrinsic modulatory inputs. This dependence,
which was seen in five of five preparations, is illustrated in Figure 4 in which an isolated combined STNS
produced uninterrupted pyloric rhythmicity during a 7 d period in
culture (Fig. 4A). However, as seen for freshly
dissected STNS (see Fig. 1), this preparation immediately (Fig.
4B) and reversibly (Fig. 4C) fell silent
when decentralized by blocking stn impulse traffic with TTX. This
experiment also argues against a significant contribution to
rhythmogenesis from axotomy-induced changes in the bioelectrical
behavior of pyloric motoneurons, as found in other motor systems
(Goodman and Heitler, 1979; Kuwada and Wine, 1981), or from a
nonspecific action of the antibiotics in the bathing saline. For
example, penicillin induces epileptogenic oscillations and burst firing in central neurons (Meyer and Prince, 1973) and motoneurons (Veskov et
al., 1989). Replacing penicillin with an alternative antibiotic, gentamycin (50 µg/ml), had no effect on the ability of combined STNS
preparations to remain continuously active in vitro.
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Figure 4.
Pyloric network activity of a combined STNS
remains conditional on functional stn inputs throughout long-term organ
culture. A, Spontaneous rhythmic activity
(right) was recorded extracellularly from pyloric motor
nerves of an isolated STNS (left) in which the STG
remained attached to the three rostral ganglia after 7 d in organ
culture. B, Pyloric activity ceases
(right) soon after disconnection of the STG from the
three rostral ganglia by the application of 107
M TTX to the stn (left). C,
Pyloric activity returns (right) after the blockade of
stn axonal conduction was removed (left).
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Recovery of pyloric rhythmicity in long-term
isolated STG
To follow the response of the pyloric network to
prolonged removal of central modulatory inputs, we placed combined STNS
preparations in culture and then cut the stn to eliminate immediately
input from the rostral ganglia. One such experiment is illustrated in Figure 5, in which the same pyloric
nerves were monitored before (Fig. 5A) and on a daily basis
for 4 d after (Fig. 5B) stn transection. As seen
previously (Fig. 1) and consistent with its dependence on extrinsic
modulatory inputs, the network fell silent soon after STG
decentralization (Fig. 5Bi). In some experiments
(n = 8), transection was performed on stn in which
impulses were blocked previously with locally applied TTX. This
procedure, which was used to avoid stn axon injury discharge (and hence
transmitter release by stn fiber terminals in the STG), decreased the
time it took for the pyloric network to fall quiescent but did not otherwise alter the initial inability of the network to operate without
intact rostral inputs.
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Figure 5.
Functional recovery of pyloric network activity
during long-term organ culture of a decentralized STG.
A, Pyloric rhythmicity in a freshly dissected, intact
STNS (schema at left). Motor nerves recorded are the lp-pyn and the pdn.
B, Same preparation and recordings made at daily
intervals after cutting the stn (schema at
left). There is a complete absence of pyloric network
activity on the 1st (i) and 2nd
(ii) day after suppressing STG inputs. By the 3rd day
(iii) after stn transection, a slow spontaneous rhythm emerges. By the 4th day after stn section (iv), the
decentralized pyloric network expresses a more robust rhythm that,
although still slower than the control pattern (compare
A), consists of strongly coordinated bursting in the
three pyloric motoneuron classes (LP, PY,
and PD).
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In contrast to the total silence of the pyloric network during the
first 2 d after stn transection (Fig.
5Bi,ii), pyloric activity gradually reappears
from the 2nd or 3rd day. This restoration initially consists of tonic
firing or slow irregular motoneuron bursting (Fig. 5Biii),
but by the 4th or 5th day (Fig. 5Biv), the spontaneous
rhythm is similar to, albeit slower than (but see below), the pattern
seen originally when the stn was intact (compare Fig. 5A).
To follow more precisely the time course of this reacquisition of
pyloric rhythmicity in decentralized STGs, we recorded from five
preparations on successive days after placement in culture and stn
transection. Pooled measurements of mean pyloric cycle frequency (±SE)
from days 1 to 7 are shown in Figure
6A. After 1-2 d in
culture, little or no spontaneous activity was expressed by all
preparations. On day 3, slow pyloric activity appeared, and on day 5, the frequency of this activity abruptly and significantly
(p < 0.001, paired Student's t
test) increased (mean frequency, 0.07 ± 0.02 Hz on day 4 and
0.37 ± 0.19 Hz on day 5), after which cycle frequency stabilized
(0.43 ± 0.15 Hz on day 7). Note that although the cycle
frequencies of these recovered pyloric rhythms were some 60% less than
were those on day 1 before decentralization (compare Fig.
3A, Day 1), these values were comparable with the
cycle frequencies of 5 and 7 d in vitro preparations with intact stns (compare Fig. 3A, Day 5,
Day 7). Resumption of pyloric rhythmicity was
observed in 84% of 15 isolated STG preparations, and in each case in
which it occurred, rhythmicity was expressed for the remaining
preparation survival time (maximum 15 d).
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Figure 6.
Evolution of pyloric cycle frequency and phasing
in long-term decentralized STGs in vitro.
A, Mean pyloric cycle frequency (±SE) of five STGs
during the 7 d after decentralization. Each point
was derived from at least 50 consecutive cycles (when rhythmicity was
expressed) per preparation. B, Phase relationships of
the same neurons on day 1 before decentralization (clear
boxes) and in recovered rhythms 4 d after decentralization
(black boxes). Data are from the same preparations used
in A. Onset and offset phases before and after
decentralization were compared using a paired Student's
t test (*p < 0.05;
**p < 0.01).
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Phase relationships of the three main classes of pyloric motoneuron
after rhythm recovery (on day 5) are shown in Figure
6B (data are pooled from the same preparations used
in Fig. 6A). For comparison, the phase and duty cycle
of the neurons before decentralization (on day 1) are also illustrated.
For the PD and LP neurons, the duty cycle differed little in the two
experimental situations, although the LP neuron-burst onset and offset
occurred relatively earlier in each cycle of the recovered rhythm. For the PY neurons, the duty cycle increased significantly (by 15-20%) as
a result of their bursts beginning earlier in the cycle. As a
consequence, the overlap between LP neuron-burst termination and PY
neurons-burst onset remained constant.
In summary to this point, therefore, after several days in
vitro, the pyloric network is capable of functional recovery from the loss of central inputs on which its activity normally depends. Although the re-established rhythm is slower and somewhat different in
terms of the timing and relative contribution of individual neuron
bursts to each cycle, basic features of the normal triphasic pyloric
motor pattern are strictly maintained.
Recovery is not caused by continued activity in
axotomized afferent terminals
Because regeneration of severed stn axons was not
possible in our in vitro experiments, re-establishment of
normal interganglionic pathways (Cohen et al., 1986) cannot be
responsible for the reacquisition of pyloric rhythmicity in long-term
isolated STG. In contrast, similar to crustacean axons in general
(Bittner, 1988), axotomized fiber terminals in the stn stump are slow
to degenerate (Royer, 1987). Thus, the possibility arises that these
residual input processes begin to generate action potentials and to
liberate transmitter and so to contribute to the restoration of pyloric rhythmicity. However, this hypothesis can be rejected for the following
reasons. First, whereas blockade of stn impulses with focally applied
isotonic sucrose or TTX always caused cessation of pyloric activity
(n = 7) in control combined preparations, similar
treatment of the stn stump of recovered long-term (>3 d) isolated STGs
(n = 8) never interrupted ongoing rhythmicity (data not
shown). It is also noteworthy that sucrose or TTX applied to a
desheathed portion of the primarily efferent nerve leading to the lvns
similarly failed (n = 3) to disturb recovered pyloric rhythmicity. In a complementary experiment (n = 2), a
TTX block placed on this nerve throughout the entire 3 d after STG
decentralization also did not affect reacquisition of the pyloric
rhythm. Together these observations suggest that activity occurring in
STG afferent fibers in this nerve (Katz and Harris-Warrick, 1989) is
also not participating in rhythm recovery.
Second and most compellingly, experimental ablation of axotomized
fibers in the stn stump did not prevent the reacquisition of pyloric
rhythmicity. One of eight such preparations is shown in Figure
7. For this experiment, a control
combined STNS was set up and recorded (Fig. 7A), then the
stn was cut, and a 10% aqueous solution of Lucifer yellow was placed
in a Vaseline well built around the transected stn stump (Fig.
7B). After orthograde migration of the dye in the severed
stn axons during the subsequent 18 hr, the staining of afferent
projections within the ganglionic neuropile was verified directly under
a fluorescence microscope, and then the dye-filled terminals were
photoinactivated by exposure for 10-15 min to intense blue light
(Miller and Selverston, 1979).
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Figure 7.
Recovery of pyloric network rhythm after
photoinactivation of stn input terminals. A, Spontaneous
pyloric output from a freshly dissected combined STNS is shown.
Extracellular recordings are from the lvn and from distal branches
carrying the PY and PD neuron axons (schema).
B, Pyloric rhythm ceases after cutting the stn. A
Vaseline well filled with Lucifer yellow was placed around the cut stn
stump (schema) to dye-fill axons into the STG.
C, After 18 hr of dye migration, STG illumination with
blue light (schema) transiently activates the pyloric
network during photoinactivation of dye-filled terminals.
Di, The absence of any activity in the same preparation
2 hr after photoinactivation of stn inputs (schema) is
shown. Dii-Div, Recordings from the same nerves shown
in A-Di, at days 2 (Dii), 3 (Diii), and 4 (Div) after the original
decentralization, show gradual recovery of spontaneous triphasic
pyloric rhythmicity.
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Two criteria for successful ablation of STG input terminals were used:
(1) an intense activation of pyloric neurons during STG illumination
(Fig. 7C), indicating depolarization-induced transmitter
release from dying input axon terminals, and (2), after the network
fell silent after photoinactivation (Fig. 7Di), insensitivity to electrical stimulation applied to the stn stump (see
below). It should be noted that backfilling the stn unavoidably stains
a small number of neurons that have cell bodies located in the STG and
that send their axons away from the ganglion in the stn. Because one of
these cells is the unique interneuron of the pyloric network, the
anterior burster (AB) interneuron, this cell was necessarily deleted
from the network. [Direct intrasomatic recordings to be reported in a
subsequent paper confirmed that the AB neuron was killed by this
procedure (M. Thoby-Brisson and J. Simmers, unpublished
observations).] Despite these conditions, however, reacquisition of
pyloric rhythmicity still occurred with approximately the same time
course as before, attaining full recovery 5 d after stn transection
(Fig. 7D). As seen previously (Figs. 5,
6A), the process again followed a gradual transition
from complete silence (Fig. 7Di), via tonic (Fig.
7Dii) and weakly rhythmic (Fig. 7Diii) activity,
to a robust triphasic pattern on the 3rd day after photoinactivation
(Fig. 7Div). Functional recovery of a long-term
decentralized pyloric network therefore does not require an intact
network, nor evidently does it depend on the survival of axotomized
input terminals.
A major concern in these ablation experiments is the extent to which
stn input axons, especially the finer fibers, were successfully labeled
by the dye and killed by the photoinactivation procedure. Although we
cannot verify that all afferent axons were eliminated, in three control
experiments, extracellular stn stimulation before and after
photoinactivation strongly suggested that a significantly large
proportion of the modulatory terminals were effectively removed. One
such experiment is shown in Figure 8, in
which a 1 sec electrical stimulation of the stn elicited pyloric
rhythmicity from an otherwise silent decentralized STG soon after stn
transection (Fig. 8A) and, similarly, after washout
with normal saline after 18 hr of Lucifer yellow migration into the
input nerve stump (Fig. 8Bi). In contrast to this
continued activation after the backfill, repeating the stimulation ~3
hr after STG illumination now failed completely to elicit the pyloric
rhythm (Fig. 8Bii). This lack of responsiveness to
stn stump stimulation, which was sustained for the longevity of the
preparation, persisted with increasing strengths of stimulation, after
placing the electrode closer to the ganglion and even after recutting
the nerve at its point of entry to the ganglion (data not shown). Thus
although survival of some axotomized terminals remains possible, it is
difficult to see how these projections alone could be responsible for
the subsequent recovery of network activity in long-term STG
culture.
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Figure 8.
Test for photoinactivation of stn input terminals
in the STG. A, Extracellular electrical stimulation (10 Hz for 1 sec at arrow) of the stn stump evokes pyloric
activity in an otherwise quiescent STG, 2 hr after cutting the stn.
B, Same preparation  18 hr after stn labeling with
Lucifer yellow is shown. Stimulation (arrows) of the
stained input nerve (now bathed in normal saline) again elicits pyloric
rhythmicity (i) but has no effect  3 hr after
illuminating the ganglion (ii). Increasing the stimulus intensity or resectioning the stn stump similarly had no effect.
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Recovery of rhythmicity in a silent STG
Because residual extrinsic inputs to the pyloric network
do not seem to underlie the resumption of rhythmicity, we examined whether this process required impulse-driven signaling within the
network itself. To test this possibility, we incubated long-term decentralized STGs in TTX-containing saline to block fast sodium channels and hence prevent generation of action potentials. One such
experiment is illustrated in Figure 9, in
which the spontaneous pyloric rhythm in a freshly dissected combined
STNS was first recorded (Fig. 9A), then the stn was cut, and
the preparation was rendered completely silent by adding
107 M TTX to the bathing saline (Fig.
9B). (Intracellular recordings also verified that individual
pyloric neurons did not continue to oscillate without spikes and
interact via graded synaptic transmission.) After 4 d under such
conditions (with the TTX replenished daily along with antibiotic), the
toxin-containing saline was rinsed (requiring at least 6 hr) from the
ganglion until action potentials were again expressed. In 10 out of 12 such experiments, the termination of long-term TTX exposure was
accompanied by the expression of a strongly active pyloric rhythm (Fig.
9C) that again displayed all the main features of the
pattern seen before decentralization (compare Fig. 9A with
C). These observations therefore support the earlier
conclusion that functional recovery of the decentralized pyloric
network is not caused by continued discharge in axotomized input
terminals and also indicate that the recovery process does not require
electrical activity within the ganglion itself.
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Figure 9.
Recovery of pyloric rhythmicity in a
decentralized, long-term silent STG. A, Spontaneous
pyloric pattern (right) recorded from the
lp-pyn and the pdn of a freshly
dissected combined STNS preparation (left) under normal
saline. B, Total absence of activity in the same nerves
(right) after the stn was cut in the presence of TTX
(107 M) in the bathing saline
(left). The decentralized, silent preparation was
maintained under these conditions during the following 4 d. C, Pyloric motor pattern (right)
expressed on day 5, 6 hr after rinsing the toxin from the decentralized
STG (left).
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Recovery of rhythmicity in an active STG
Finally, we wished to assess whether rhythm recovery was because
of a direct, intrinsic response of pyloric network neurons whereby they
compensated for their diminished levels of activity after
decentralization to become rhythmically bursting (LeMasson et al.,
1993; Turrigiano et al., 1994). If this was the case, then a network
that was forced to remain active after isolation from extrinsic inputs
would be expected to display a diminished capacity for subsequent
functional recovery. In a first step to test this possibility, we
increased pyloric neuron activity after decentralization by elevating
the extracellular potassium ion concentration (Franklin et al., 1992;
Berdan et al., 1993). Specifically, isolated ganglia (n = 4) were incubated for 3 d after decentralization in saline
containing twice (25 mM) the normal K+
concentration. [A [K+] increase of this
order causes pyloric lobster stomatogastric neurons to depolarize 5-10
mV (M. Thoby-Brisson and J. Simmers, unpublished observations).] As is
shown in Figure 10, exposure of a newly
decentralized, silent STG (Fig. 10A) to high
K+ saline caused a pyloric pattern to reappear (Fig.
10Bi) within minutes of the onset of superfusion.
Presumably this rhythm, which was slower and less regular than normal,
was triggered by nonspecific stimulation of the STG via the potassium
depolarization. After 4 d further exposure to these conditions
(Fig. 10Bii), the still-active decentralized ganglion
was returned to normal (12 mM) K+
saline, and the pyloric motor nerves were again recorded some 1-2 hr
later. The robust and regular activity seen in Figure 10C, which was observed in all four isolated ganglia up to 24 hr after return to control saline, suggests that prolonged potassium
depolarization does not significantly impair the capacity of the
pyloric network to recover rhythmicity.
View larger version (26K):
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[in a new window]
|
Figure 10.
Recovery of pyloric rhythmicity in a
decentralized, chronically depolarized STG. A, Absence
of rhythm (right) in a freshly dissected STNS after
cutting the stn in normal saline (left). Recordings are
from the lp-pyn and the pdn.
B, Activation of the rhythm (right) by
superfusion of elevated (25 mM) K+
saline (i, left), which was replenished
daily over the following 4 d. Recordings are from the same nerves
used in A on days 1 (i) and 5 (ii) of high K+ exposure.
C, Robust spontaneous pyloric rhythm on day 5 (right), 1-2 hr after rinsing the preparation with
normal (12 mM) K+ saline
(left).
|
|
In a parallel set of experiments, we used specific pharmacological
stimulation with oxotremorine (105 M),
a muscarinic agonist known to induce pyloric rhythmicity in the
isolated lobster STG (Bal et al., 1994), to sustain pyloric network
activity throughout the 4 d period after decentralization. The
results of one such experiment are shown in Figure
11. Again, the pyloric rhythm in a
combined STNS disappeared after cutting the stn (Fig.
11A) but was immediately and powerfully restored (Fig. 11B) by superfusing the STG with oxotremorine
(105 M). During the ensuing 3 d,
the bath saline containing the oxotremorine was renewed daily, and the
preparation was monitored to verify uninterrupted pyloric activity
(data not shown). The STG was then rinsed with normal saline for 24 hr
and again recorded, now 5 d after the initial dissection (Fig.
11C). Here again, because robust rhythmicity was still
expressed after removal of the agonist, the simplest interpretation is
that, in our organ cultures, rhythm recovery is not deriving solely
from an activity-dependent, homeostatic adjustment of excitability by
individual pyloric neurons. Results similar to those shown in Figure 11
were obtained from all five oxotremorine-treated STGs tested.
View larger version (22K):
[in this window]
[in a new window]
|
Figure 11.
Recovery of pyloric rhythmicity in a continuously
active decentralized STG. A, Absence of rhythm
(right) in a freshly dissected STNS after stn
transection (left). Recordings are from the
lp-pyn and the pdn. B,
Activation of the rhythm (right) by superfusion of
105 M oxotremorine
(oxo; left), which was replenished daily
over the following 3 d. C, Spontaneous pyloric
rhythm on day 5 (right), 24 hr after rinsing the
muscarinic agonist from the preparation (left).
|
|
| |
DISCUSSION |
In this paper we have shown that, whereas short-term suppression
of modulatory inputs to the stomatogastric ganglion causes immediate
cessation of pyloric network activity, after 3-5 d in organ culture
the decentralized network reacquires the ability to generate a
spontaneous motor pattern similar to that expressed when the input stn
was intact. This indicates that prolonged absence of a population of,
as yet unidentified, modulatory inputs to the pyloric network allows
the expression of an intrinsic rhythmogenic capability that is normally
maintained in a strictly conditional (modulation-dependent) state by
these same extrinsic influences.
What is the stimulus for this alteration in chemosensitivity of the
isolated network? When the STG is placed in organ culture, the pyloric
network neurons are not only decentralized but also are themselves
axotomized as well as exposed to a chemical environment totally
different from that experienced in vivo. The importance of
changes in humoral environment is difficult to assess. For example,
certain downregulatory factors, such as specific circulating hormones,
that may sustain network chemodependence in vivo are undoubtedly missing in our in vitro conditions.
Alternatively, stimulatory factors, such as the unavoidable use of
antibiotic in the organ culture medium, could play a nonspecific role
in rhythm recovery (Meyer and Prince, 1973; Veskov et al., 1989), although our finding that long-term stn intact in vitro
preparations immediately fell silent with subsequent stn blockade
argues against this possibility.
Axotomy is well known to evoke a variety of changes in the intrinsic
character of neurons, such as increasing somatic excitability (Goodman
and Heitler, 1979; Kuwada and Wine, 1981) and altering the expression
of neurotransmitters (Hyatt-Sachs et al., 1993) and receptors (Jacob
and Berg, 1987). Here again, however, the inability of the isolated
STNS to sustain pyloric rhythmicity after STG decentralization after
several days in vitro suggests that pyloric motoneuron
axotomy does not make a substantial contribution to rhythm recovery. A
further argument that axotomy-induced plasticity is insufficient to
account for pyloric rhythm recovery in organ culture derives from
experiments in which the STG was decentralized (with its efferent
nerves left intact) in vivo (J. Simmers and E. Rezer,
unpublished observations; see also Rezer and Moulins, 1992). In all
cases in which the stn had been cut in situ (from 1 week to
12 months), robust pyloric rhythmicity continued to be expressed by the
decentralized STG when freshly dissected from the animal. Importantly,
moreover, these ex vivo experiments confirm that the
recovery of rhythmicity occurring in our organ culture experiments
represents a long-lasting phenomenon that extends beyond the temporal
and experimental constraints of the Petri dish.
Initially, we were concerned that the stn terminals might be continuing
to release modulatory substances after axotomy and that, in combination
with the development of a type of postsynaptic "denervation
supersensitivity" (Fambrough, 1979; but see Dunn and Marshall, 1985),
might lead to the reactivation of the pyloric network. Moreover, the
STG terminals themselves may be postsynaptic to the network neurons
they influence (Nusbaum et al., 1992). Thus, at least in theory, local
circuit interactions between nondegenerated, axotomized modulatory
terminals and their pyloric targets could eventually promote and
sustain network rhythmicity. However, our experiments with TTX-treated
preparations indicated that if such processes were occurring, they did
not rely on spike generation or spike-mediated synaptic activity.
Furthermore, a stronger argument against any direct contribution of
surviving input terminals is that re-establishment of pyloric
rhythmicity after decentralization still occurred after their
photoablation. Stn photoinactivation also unavoidably kills the AB
interneuron, the sole nonmotor member of the pyloric network, the axon
of which projects in the stn. Resumption of rhythmicity therefore does
not require an intact network or the participation of the neuron
considered to possess the strongest rhythmogenic properties in the
network (Bal et al., 1988).
Given that the recovery process is a direct consequence of network
decentralization, in principle either or both of two signaling mechanisms could be involved. One possibility is that in the absence of
a permissive modulatory drive, pyloric neurons adjust their intrinsic
properties as a direct consequence of their lack of rhythmic activity.
Alternatively, functional recovery could arise from the loss of
extrinsic inputs that otherwise continuously downregulate network
excitability via a trans-synaptic process.
Evidence of activity-dependent regulation has derived from both
dissociated cell culture (Turrigiano et al., 1994, 1995) and modeling
experiments (LeMasson et al., 1993) on STG neurons. In this scheme,
silent dissociated pyloric neurons are proposed to sense the lack of
rhythmic drive from other pyloric neurons and to modify their membrane
conductances so as to resume firing and eventually endogenous rhythmic
bursting (Marder et al., 1996). An important prediction from this
interpretation is that stimulating a cultured neuron that is already
rhythmically active should reverse the process, inducing the cell to
downregulate its conductances to produce a tonic mode of firing. Both
experimental (Turrigiano et al., 1994) and theoretical (LeMasson et
al., 1993) evidence from the responses of bursting pyloric neurons in
culture to short-lasting (~1 hr) rhythmic stimulation indicate that
this is indeed the case. However, the short time scale for this change
suggests a different underlying process from the plasticity revealed in
the present study.
Interestingly, solitary pyloric neurons in culture spontaneously
develop an intrinsic burst-generating capability over a time scale
(2-3 d) similar to that for the recovery of rhythmicity in our
long-term decentralized organ cultures (see also Marder et al., 1996).
However, there are a number of indications that signals in addition to
the level of neuronal activity are involved. For example, using
elevated extracellular potassium concentrations in the bathing saline
to produce sustained depolarization of pyloric neurons did not diminish
the capacity of the decentralized network to recover rhythmicity. This
was somewhat surprising, because chronic depolarization in culture
causes neuronal calcium currents to decrease gradually (Delorme and
McGee, 1986; Franklin et al., 1992; Berdan et al., 1993), whereas an
increase in Ca2+ channels seems to underlie the
enhanced excitability necessary for the transition to burst firing in
dissociated stomatogastric neurons (Turrigiano et al., 1995). In a
similar vein, continuous exposure (over 3-4 d) to oxotremorine, a
muscarinic agonist known to induce bursting in decentralized lobster
pyloric neurons (Bal et al., 1988, 1994), failed to prevent or prolong
network recovery. Neither of these observations are consistent with
pyloric neuron activity-dependent type mechanisms underlying the
recovery described here. Thus, the second possibility that the
decentralized network is responding to the removal of extrinsic inputs
that normally exert a sustained downregulatory influence on network
excitability in addition to short-term neuromodulatory control arises.
Whether such a long-term influence from modulatory inputs involves a
trophic or growth factor remains to be seen, although such factors are known to play an important role in conventional cell-cell
interactions, including the regulation of receptor/transmitter
expression and levels of target cell excitability (Martinou and Merlie,
1991; Reist et al., 1992; Traynor et al., 1992). Moreover, precedent exists for negative regulation of adult neuronal properties by central
nervous inputs (also revealed by ganglionic decentralization), such as
the continual repression of neuropeptide biosynthesis in rat
sympathetic neurons (Kessler and Black, 1982; Zigmond et al., 1992;
Hyatt-Sachs et al., 1993). Indeed the intriguing possibility exists
that pyloric network neurons themselves also produce novel neuroactive
substances that are not normally expressed with intact central
inputs.
How can this interpretation from our organ culture experiments be
reconciled with earlier dissociated neuron data (Turrigiano et al.,
1994, 1995; Marder et al., 1996)? Perhaps massively traumatized, rapidly outgrowing stomatogastric neurons in culture react differently than do neurons that remain relatively undisturbed within an entire decentralized ganglion. The molecular and cellular responses of central
neurons differ according to direct and indirect injury (Weiser et al.,
1994), and the time course and magnitude of a somatic response of a
neuron to axotomy is closely related to lesion distance (Berdan et al.,
1993). Explanted stomatogastric neurons generally have only a very
short (<200 µm) primary neurite (Graf and Cooke, 1990; Turrigiano
and Marder, 1993), whereas in organ explants the nerve tracts
containing pyloric motor axons are severed as far as 30-40 mm from the
STG. An attractive possibility, therefore, is that the different
in vitro preparations reveal separate extrinsic and
intrinsic regulatory mechanisms that are not mutually exclusive but
that normally operate conjointly in vivo;
innervation-dependent, trans-synaptic influences could serve to
establish overall levels of (conditional) excitability in pyloric network neurons, whereas activity-dependent processes could be responsible for their individual tuning and adjustment. Multiple strategies involving intrinsic and extrinsic processes are used in the
short-term modulation of adult motor networks (Harris-Warrick et al.,
1992; Katz, 1995); it is similarly not unreasonable to expect similar
diversity in the origin and nature of their long-term control.
Moreover, that modulatory inputs help maintain pyloric network
rhythmogenesis in a dependent, rather than autoactive, state would
render the network far more susceptible to short-lasting modulatory
control.
| |
FOOTNOTES |
Received Sept. 22, 1997; revised Dec. 18, 1997; accepted Dec. 22, 1997.
This work was partly supported by the Human Frontier Science Program
and a doctoral studentship from the Ministère de l'Enseignement Supérieur et de la Recherche to M.T.-B. We also thank Dr. Pierre Meyrand for helpful discussions and comments on this manuscript.
Much of the impetus for this work came from Professor Maurice Moulins,
who died in December 1995. We dedicate this article to his memory.
Correspondence should be addressed to Dr. J. Simmers, Laboratoire de
Neurobiologie des Réseaux, Université de Bordeaux I and
Centre National de la Recherche Scientifique, Place du Dr Peyneau,
33120 Arcachon, France.
| |
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Top
Abstract
Introduction
