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The Journal of Neuroscience, December 15, 2002, 22(24):10898-10905
Rhythmicity without Synchrony in the Electrically Uncoupled
Inferior Olive
Michael A.
Long1,
Michael R.
Deans2,
David L.
Paul2, and
Barry W.
Connors1
1 Department of Neuroscience, Division of Biology and
Medicine, Brown University, Providence, Rhode Island 02912, and
2 Department of Neurobiology, Harvard Medical School,
Boston, Massachusetts 02115
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ABSTRACT |
Neurons of the inferior olivary nucleus (IO) form the climbing
fibers that excite Purkinje cells of the cerebellar cortex. IO neurons
are electrically coupled through gap junctions, and they generate
synchronous, subthreshold oscillations of membrane potential at
~5-10 Hz. Experimental and theoretical studies have suggested that
both the rhythmicity and synchrony of IO neurons require electrical
coupling. We recorded from pairs of IO neurons in slices of mouse
brainstem in vitro. Most pairs of neurons from wild-type
(WT) mice were electrically coupled, but coupling was rare and weak
between neurons of knock-out (KO) mice for connexin36, a neuronal gap
junction protein. IO cells in both WT and KO mice generated rhythmic
membrane fluctuations of similar frequency and amplitude. Oscillations
in neighboring pairs of WT neurons were strongly synchronized, whereas
the oscillations of KO pairs were uncorrelated. Spontaneous
oscillations in KO neurons were not blocked by tetrodotoxin.
Spontaneously oscillating neurons of both WT and KO mice generated
occasional action potentials in phase with their membrane rhythms, but
only the action potentials of WT neuron pairs were synchronous.
Harmaline, a  -carboline derivative thought to induce tremor by
facilitating rhythmogenesis in the IO, was injected systemically into
WT and KO mice. Harmaline-induced tremors were robust and
indistinguishable in the two genotypes, suggesting that gap
junction-mediated synchrony does not play a role in harmaline-induced
tremor. We conclude that electrical coupling is not necessary for the
generation of spontaneous subthreshold oscillations in single IO
neurons, but that coupling can serve to synchronize rhythmic activity
among IO neurons.
Key words:
inferior olive; electrical coupling; connexin36; gap
junction; harmaline; rhythms; synchrony
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INTRODUCTION |
Many neurons in the CNS generate
rhythmic, synchronized activity, using mechanisms that are poorly
understood. One of the most dramatically rhythmic brain structures is
the inferior olive (IO). Its neurons are the origin of the climbing
fibers, which provide strong synaptic excitation to the Purkinje cells
of the cerebellum; every action potential in a climbing fiber evokes a
complex spike in all of its postsynaptic Purkinje cells (Eccles et al.,
1966 , 1967). IO neurons have several distinctive physiological characteristics (Crill, 1970; Llinás and Yarom, 1981a,b),
including a strong tendency to generate spontaneous subthreshold
oscillations of their membrane potential (Benardo and Foster, 1986;
Llinás and Yarom, 1986). IO cells fire action potentials at
frequencies from 1 to 10 Hz (Armstrong et al., 1968). The subthreshold
membrane oscillations of IO cells determine the precise timing of IO
action potentials and thus also the timing of the complex spikes of
Purkinje cells (Llinás, 1991; Lampl and Yarom, 1993). The firing
of complex spikes in multiple Purkinje cells, and by inference the
spiking of multiple IO neurons, often occurs with a significant degree of synchrony that may play an important role in the coordination and
timing of motor control (Bell and Kawasaki, 1972; Sasaki et al., 1989;
Llinás, 1991; Welsh et al., 1995).
A variety of mechanisms have been proposed to explain the rhythmicity
and synchrony of IO neurons. Subthreshold membrane oscillations seem to
involve the interaction of several types of voltage-dependent ion
channels in IO cell membranes, most notably low-threshold calcium
channels, hyperpolarization-activated cation channels, and perhaps the
NMDA subtype of glutamate-gated channels (Llinás and Yarom,
1981a,b, 1986; Benardo and Foster, 1986; Yarom and Llinás, 1987;
Bal and McCormick, 1997; Placantonakis and Welsh, 2001). Synchronous
firing is presumed to require gap junctions, which interconnect IO
neurons and mediate direct electrical coupling (Llinás et al.,
1974; Sotelo et al., 1974; Llinás and Yarom, 1981b; Benardo and
Foster, 1986). However, several lines of evidence have inspired the
hypothesis that electrical coupling not only mediates synchrony but
also is essential for generating the subthreshold oscillations
themselves (Llinás, 1991; Yarom, 1991; Sherman and Rinzel, 1992;
Lampl and Yarom, 1997; Manor et al., 2000). However, this hypothesis
has never been directly tested.
Here we describe studies of IO neurons in a mouse with a null mutation
for the gene encoding connexin36 (Cx36), the protein most
prevalent in neuronal gap junctions of the mammalian brain (Condorelli
et al., 2000; Rash et al., 2000). Previous work on Cx36
knock-out (KO) mice showed that electrical coupling is almost entirely
absent between certain inhibitory neurons of the neocortex (Deans et
al., 2001), the hippocampus (Hormuzdi et al., 2001), and the reticular
nucleus of the thalamus (Landisman et al., 2002), all of which are
frequently coupled in wild-type (WT) animals. We show here that both
the incidence and strength of electrical coupling between IO neurons
are also greatly reduced in the Cx36 KO mouse compared with
WT controls. The uncoupled IO network in the KO mice continues to
generate subthreshold membrane oscillations, but they are asynchronous.
Surprisingly, a type of drug-induced tremor that is thought to depend
on synchronized discharges in the olivocerebellar system was just as
vigorous in the KO mice as in the WT mice.
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MATERIALS AND METHODS |
Longitudinal (parasagittal) slices (300 µm thick) were
prepared as described previously (Llinás and Yarom, 1981b; Gibson et al., 1999) from Cx36 WT or KO littermate mice [postnatal
day 14 (P14) to P17]. The construction of the mice and
-galactosidase histochemistry have been described in detail
previously (Deans et al., 2001). Briefly, mice were intracardially
perfused with 5-10 ml of an ice-cold solution containing (in
mM): 124 sucrose, 3 KCl, 1.25 NaH2PO4, 2 MgSO4, 26 NaHCO3, 10 dextrose, and 2 CaCl2. The brain was then rapidly
removed, and slices were made with a vibratome (Campden Instruments,
Lafayette, IN). Slices were incubated for 45 min at 32°C and
then kept at room temperature in a holding chamber until they were
transferred to a submersion-style recording chamber held at 32°C. The
incubation solution contained (in mM): 126 NaCl,
3 KCl, 1.25 NaH2PO4, 2 MgSO4, 26 NaHCO3, 10 dextrose, and 2 CaCl2, saturated with 95%
O2/5% CO2; the recording solution was the same, except for reduced divalent ion levels (1 MgSO4 and 1 CaCl2) and a
slight increase in potassium (3.5 KCl). Micropipettes were filled with
(in mM): 135 potassium gluconate, 4 KCl, 2 NaCl,
10 HEPES, 0.2 EGTA, 4 ATP-Mg, 0.3 GTP-Tris, and 7 phosphocreatine-Tris,
pH 7.25 (280 mOsm). All recordings were made in current-clamp mode
using matched amplifiers (Axoprobe; Axon Instruments, Foster City, CA),
and cells were visualized under IR-differential interference contrast
(DIC) optics using a Zeiss (Thornwood, NY) Axioskop and a Hamamatsu
(Bridgewater, NJ) CCD camera.
Data were digitized, collected, and analyzed with auto- and
cross-correlograms and power spectra using Labview (National
Instruments, Austin, TX) routines written by Jay R. Gibson (University
of Texas Southwestern Medical Center, Dallas, TX), as described
previously (Beierlein et al., 2000). Subthreshold membrane potentials
were band-pass filtered (1-70 Hz) before analysis. The correlograms were first averaged and then normalized by the product of the SD of the
signal in each recording: Normalized correlation (t) = [Average(A[t'] × B[t'  t])]/[SD(A[t']) × SD(B[t'])], where A[t'] and B[t']
represent the two voltage records, t' is the time variable
for the actual traces, and t is the time variable for the
correlation. For each neuron pair, we report the average
cross-correlation derived from five 10 sec epochs of activity. Shuffled
controls were obtained by phase-shifting spontaneous oscillations from 10 WT cell pairs by regular intervals, multiple times, and then calculating the cross-correlation at time 0 for each shuffled epoch.
The correlations from all phase-shifted samples were averaged (mean,
0.03), and the 95% confidence interval was estimated from the
variance. Action potential correlations were calculated as described
previously (Beierlein et al., 2000).
For the tremor experiments, age-matched (P14-P31) groups of WT and KO
mice were tested with the experimenter blind as to genotype. Each mouse
was injected intraperitoneally with harmaline (10-15 mg/kg).
Immediately after injection, mice were placed in a small ventilated
chamber suspended from a transducer that measured vertical force.
Harmaline-induced tremor patterns were continuously monitored, recorded
on a computer, and quantified offline. Power spectra for each mouse
were calculated from the average of three robust, representative 5 sec
epochs of tremor obtained while animals were not locomoting.
Data are reported as mean ± SD unless specified otherwise.
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RESULTS |
Electrical coupling requires Cx36
-galactosidase histochemistry of Cx36 KO tissue showed cellular
staining distributed throughout the IO (Fig.
1A). The intensity of
staining varied widely across neurons, and some were not stained at
all; the absence of stain might indicate lack of gene expression, or it
could reflect a technical problem, such as poor reagent penetrance.
Regardless, the -galactosidase staining is consistent with previous
evidence that Cx36 is widely expressed in the neurons of the IO
(Condorelli et al., 2000; Rash et al., 2000).
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Figure 1.
IO neurons from KO mice. A,
-Galactosidase histochemistry of a parasagittal section from a
Cx36 KO mouse shows many strongly stained cells in the IO
nucleus. B, IR-DIC image of two very closely spaced
neurons during paired whole-cell recordings from the IO of a KO mouse.
Despite their proximity, these cells were not electrically coupled to
each other.
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We recorded from neurons along the full rostrocaudal extent of the
inferior olive. Most cells generate spontaneous subthreshold oscillations of membrane potential (Fig.
2A) (see below). The intrinsic spiking properties of IO cells (Table
1) were similar to those described
previously (Llinás and Yarom, 1981b). Each action potential
displayed a rapid, overshooting spike of ~100 mV, followed by a
smaller (~50 mV) but prolonged plateau phase (Fig.
2A,B,D) that had several voltage "ripples" across
it (see Fig. 6A-C, spikes). The action
potentials of IO neurons from WT and Cx36 KO mice did not differ in
amplitude, duration, spontaneous frequency, or the number of plateau
ripples (Table 1). Input resistances, measured with 100 pA
hyperpolarizing steps, were ~30% higher in KO neurons than in WT
neurons. Resting membrane potentials (defined as the mean membrane
potential in spontaneously oscillating cells in the absence of holding
current) did not differ between WT and KO cells.
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Figure 2.
Electrical coupling is greatly diminished in the
Cx36 KO mouse. A, Paired whole-cell
recordings from coupled WT cells show synchronized subthreshold
oscillations, occasional action potentials in cell 1, and correlated
electrical coupling potentials in cell 2. Note that the gain for cell 2 is higher than that from cell 1. B, Expanded view of a
spontaneous action potential in cell 1 and its associated
electrotonically propagated spikelet in cell 2 (same recordings shown
in A). Dashed lines show where traces in
A are expanded in B. C, Electrical
coupling in a pair of WT neurons. A hyperpolarizing current step (1
nA) injected into cell 1 induced an electrotonically propagated
hyperpolarization in cell 2. D, E, Electrical coupling
was absent in a representative pair of IO cells from a Cx36
KO mouse. To remove the effects of spontaneous membrane oscillations,
voltage traces in C-E are the averages of 10 trials,
with the exception of the representative action potential in the KO
cell shown in D.
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Electrical coupling is common between IO neurons (Llinás et al.,
1974). To assay coupling prevalence and strength, we recorded simultaneously from closely spaced neuron pairs (<25 µm between somata; for the majority, spacing was <5 µm) (Fig.
1B). To quantify the strength of coupling, 10-50
strong (1 nA) hyperpolarizing current steps (600 msec) were applied
to each IO cell in turn (Fig. 2C,E). The voltage responses
to the current steps in the injected and neighboring cells were each
averaged. Values for the coupling coefficient (defined as
 Vneighboring
cell/Vinjected cell) were estimated for both directions of current flow. Coupling
coefficients did not depend significantly on direction, and reported
values are the averages of estimates from both directions. Cell pairs were considered electrically coupled if they had an average coupling coefficient of >0.008, which was just above our detection limit. In
the WT mice, 79% of sampled IO neuron pairs were electrically coupled,
with a mean coupling coefficient of 0.038 (Table 1). In contrast, only
9% of pairs from KO mice were coupled (p < 0.001; Fisher's exact test). The electrical coupling between pairs
from the WT was, on average, approximately four times stronger than that between the few coupled pairs observed in KO slices (Table 1)
(p < 0.001; t test). Thus,
considering both prevalence and strength, KO neurons had only ~3% of
the electrical coupling observed in WT neurons. In most coupled pairs
of WT neurons (14 of 17), action potentials in one neuron evoked
prominent spikelets (electrotonically conducted action potentials) in
the neuron coupled to it (Fig. 2B) (mean spikelet
amplitude, 1.51 ± 1.23 mV; range, 0.47-4.7 mV). Each spikelet
was followed by relatively strong, prolonged hyperpolarization (Fig.
2B, cell 2) that reflects the electrotonically conducted afterhyperpolarization of the presynaptic cell (coupling potentials in fast-spiking interneurons of neocortex) (Galarreta and
Hestrin, 1999; Gibson et al., 1999) and perhaps also some contribution
generated by spontaneous oscillations in neighboring coupled cells. KO
pairs never generated electrically coupled spikelets (Fig.
2D).
In a recent report, Devor and Yarom (2002b) demonstrated that
electrical coupling between IO neurons depends strongly on cell spacing. To be sure we were maximizing the detectability of coupling, we recorded a subset of neuronal pairs in which somata were <5 µm
apart (many were nominally touching, as in Fig. 1B).
Among this subset, all six WT pairs were coupled (coupling coefficient, 0.03 ± 0.008), whereas only one of 11 KO pairs was coupled, very weakly (coupling coefficient, ~0.008).
Spontaneous subthreshold oscillations do not require
electrical coupling
Many IO neurons generate spontaneous subthreshold oscillations of
their membrane potentials when recorded under control conditions (Fig.
2A) (Benardo and Foster, 1986; Llinás and
Yarom, 1986). Experimental data and theoretical analyses have suggested
that these oscillations may be an emergent property of the electrically coupled network of IO neurons, and that coupling is required for the
maintenance of rhythms (Manor et al., 2000; Loewenstein et al., 2001).
We found, however, that spontaneous rhythms occurred in ~80% of IO
neurons from both WT and Cx36 KO mice (Fig.
3A,B). They ranged in
amplitude from 2 to 30 mV peak-to-peak and had frequencies of ~1-8
Hz (Table 1). The prevalence and frequency of subthreshold rhythms in
WT and KO cells were not different, and those from KO neurons were
slightly but significantly larger than those from WT neurons. To
eliminate the possibility that subthreshold rhythms of KO neurons were
being driven by afferents from an extrinsic source, we bathed the
slices in TTX to block action potentials. Nine of 10 KO cells bathed in
TTX were spontaneously rhythmic, with amplitudes and frequencies
indistinguishable from cells recorded without TTX. These results
suggest that electrical coupling is not important for subthreshold
rhythmogenesis in the IO.
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Figure 3.
The frequency of spontaneous subthreshold
oscillations in WT cells is determined by the electrically coupled
network. Membrane potentials were altered by injecting steady currents,
either hyperpolarizing or depolarizing, into WT
(A) and KO (B) cells.
C, Amplitudes of subthreshold oscillations were a strong
function of membrane potential in both WT and KO neurons: summary of
data from nine WT and nine KO cells. Mean amplitudes at various
membrane potentials were scaled to largest responses and summed across
5-mV-wide bins, along with SE bars. The only significant difference was
at the most hyperpolarized level (66 to 70 mV), where the WT
response was greater than the KO response (p < 0.05; t test). D, Oscillation
frequency was a strong function of membrane polarization in neurons
from the KO but was invariant with membrane potential in WT neurons.
The graph shows data obtained from cells illustrated in
A (WT) and B (KO). E, To
summarize the voltage dependence of oscillation frequency, the best-fit
line was calculated for each set of data points (as in
D) (9 WT and 9 KO cells). The graph in E
plots the slopes of the linear fits, in Hertz per millivolts.
Dashed line shows slope of zero.
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The frequency of subthreshold rhythms in a single IO neuron tends to be
independent of its mean membrane potential, which suggests that the
activity of each neuron is strongly influenced by input from the
electrically coupled local network (Benardo and Foster, 1986; Lampl and
Yarom, 1997). We confirmed this in neurons from WT mice (Fig.
3A) (n = 9). When steady currents were injected into spontaneously rhythmic cells, the amplitudes of subthreshold oscillations were largest near resting potential or
slightly negative to it and greatly decreased at potentials 10-15 mV
more hyperpolarized or depolarized (Fig. 3A,C); the
fundamental oscillation frequency, however, did not change with
polarization in the WT (Fig. 3D). Current injections into KO
neurons also strongly modulated the amplitude of subthreshold
oscillations, with a voltage dependence similar to that of WT cells
(Fig. 3B,C) (n = 9). The oscillation
frequency of KO cells, however, increased to almost twice its baseline
level as membrane potential was depolarized by 10-15 mV (Fig.
3B,D). In general, the oscillation frequency of WT cells was
invariant with membrane potential (Fig. 3E) (mean slope,
0 ± 0.08 Hz/mV), whereas the frequency of most KO cells increased
as the membrane was depolarized (mean slope, 0.22 ± 0.11 Hz/mV)
(WT and KO means were different; p < 0.0005;
t test).
Paired recordings from neighboring IO neurons were used to measure the
synchrony of their subthreshold and spiking activities. Figure
4 shows representative recordings from a
WT pair and a KO pair. Subthreshold oscillations of neighboring WT
neurons were usually well correlated (Fig. 4A,
left), whereas IO pairs from the KO were almost always
uncorrelated (Fig. 4A, right). These differences were evident from plots of the membrane potential of one
cell against another (Fig. 4B) and from
cross-correlograms (Fig. 4C). When the mean frequencies of
subthreshold oscillations in simultaneously recorded WT neurons were
compared, they were indistinguishable from each other (Fig.
4D, left) (mean difference in peak
frequencies between paired cells was 0.14 ± 0.28 Hz;
n = 20 pairs). However, the frequencies of paired KO
neurons were always at least slightly different from each other (Fig.
4D, right) (mean difference in frequency
between paired cells was 0.8 ± 0.8 Hz; n = 19 pairs). The disparity between frequencies of recorded pairs was
significantly greater in the KO than in the WT
(p < 0.005; t test). Almost all
sampled WT pairs showed significantly correlated rhythms, whereas
correlations in the KO pairs were all very weak (Fig.
5), and the two groups were significantly different (p < 0.000005; Student's
t test). In the IO of WT mice, two pairs that were not
measurably coupled to one another nevertheless had well correlated
subthreshold oscillations (Fig. 5).
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Figure 4.
Electrical synapses are required for synchrony of
spontaneous rhythms. Left, Data derived from one WT
pair; right, data derived from one KO pair.
A, Rhythms recorded simultaneously from two closely
spaced WT (left) and KO (right) neurons
appear similar in amplitude and frequency, although the phase of the
two KO recordings obviously varies. B, Data from the
same cell pairs are shown in Lissajous figures, which plot the membrane
potential of IO1 versus IO2. Recordings from
the WT neurons are nearly identical (left), but those
from KO neurons show no correlation (right).
C, Cross-correlograms (Cross Corr) of
both pairs derived from >60 sec of data quantify the high degree of
rhythmic correlation between WT cells (left) and the
absence of correlation between KO cells (right).
Dashed lines mark zero time. D, Power
spectra calculated from the same data show that the frequencies
(Freq) of paired WT neurons were identical, whereas KO
cell frequencies differed.
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Figure 5.
Rhythms of electrically uncoupled IO neurons are
asynchronous. The graph plots the peak correlations obtained from
cross-correlograms of 12 WT and KO neuron pairs, obtained as described
in Figure 3C. Filled triangles are from
cell pairs that were measurably, electrically coupled; open
triangles are from pairs that were not coupled.
Horizontal lines are mean values. The shaded
area shows the 95% confidence interval, derived from shuffled
data of 10 WT neurons.
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Synchronous spiking requires electrical coupling
The action potentials of IO neurons are usually triggered near the
peaks of their subthreshold oscillations (Lampl and Yarom, 1993).
Because the oscillations are temporally correlated in normal animals,
action potentials should also tend to be correlated. Many of the WT and
KO cells generated occasional spikes approximately once every 5-15
subthreshold cycles, when their membranes were spontaneously
oscillating (Fig.
6A,B). These action
potentials arose from the depolarizing crest of the subthreshold
oscillations. When pairs of WT neurons were recorded, action potentials
were indeed temporally correlated (Fig. 6A,C,D).
Pairs of KO neurons, however, generated similar frequencies of action
potentials but were uncorrelated (n = 4 pairs each from
WT and KO) (Fig. 6B). Cross-correlograms generated
from 200 sec epochs of spontaneous spiking (5 msec bin widths) of WT
pairs showed a strong central peak near 0 msec, but correlograms from
KO pairs were inevitably flat (Fig. 6D).
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Figure 6.
Action potentials are synchronized by electrical
coupling. A, Spontaneous spiking from two WT neurons
during a 4-sec-long epoch of spontaneous subthreshold rhythms shows
simultaneous spiking. The traces below show magnified
views of an action potential in the top cell, a
subthreshold spikelet in the bottom cell
(left), and two nearly simultaneous spikes
(right). Dashed lines show where
top traces are expanded in bottom traces.
B, A similar 4 sec epoch of rhythmic activity in two KO
neurons shows only asynchronous spiking. C, When 22 spiking epochs from the WT pair are aligned on the spikes of one cell,
it is evident that spikes in the second cell most often occur with a
brief lag or lead. Dashed line is aligned with peaks of
spikes in cell 1. D, Spike cross-correlogram (5 msec bin
width) taken from 200 sec of spontaneous spiking from the pairs
illustrated above. WT cells show a strong peak at 0 msec, whereas spikes from KO cells were uncorrelated. E,
When the same WT spiking data were cross-correlated with finer temporal
resolution (0.5 msec bin width), it is clear that the periods of
highest spiking probability occurred before and after spikes in the
reference neuron.
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To characterize the behavior of WT neurons at finer temporal
resolution, correlograms of spiking activity were calculated with 0.5 msec bin widths. These revealed that the probability of spiking peaked
on either side of the zero time point, at approximately +2 msec and 2
msec, with almost no correlated spikes in precise synchrony (Fig.
6C,E). All four tested pairs of spiking WT neurons had peaks
offset from zero time. The most straightforward explanation of this
result is that each relatively rare spike in one neuron tends to
enhance the probability of spiking in its neighboring neuron, with an
average lag of ~2 msec. The mechanism of this triggering is very
likely to be the electrical synapse that interconnects the two cells. A
broad IO action potential in one neuron generates a relatively
prolonged electrotonic spikelet in the coupled neuron (Fig.
6A,C), and that spikelet often triggers an action
potential with a lag determined by the kinetics of the coupling
transform. The symmetry of the correlogram peaks in Figure
6E suggests that each neuron of this pair was
approximately equally capable of triggering a spike in the other.
Harmaline-induced tremor does not require IO synchrony
Harmaline, a -carboline derivative, causes 8-14 Hz tremor in
mice (Fowler et al., 2001). Harmaline-induced tremor requires an
inferior olivary nucleus in other species (Llinás and Volkind, 1973), and the drug is assumed to act by modulating the
rhythm-generating ionic currents of IO cells (Llinás and Yarom,
1986; Llinás, 1991). To test the functional impact of electrical
coupling and the IO synchrony that it mediates, we measured
harmaline-induced tremor in both WT and KO mice. Prominent
harmaline-induced tremors with a peak frequency of ~13-14 Hz
typically began 5-10 min after systemic administration of the drug
(Fig. 7A,C). Tremor was
indistinguishable in WT and KO animals. No genotype-related differences
were seen in the frequency (Fig. 7B,D), peak amplitude,
average onset time, or integrated power of the tremors (Table
2), nor were any differences detected
across genotypes when juvenile (P14-P17) and young adult (P31) mice
were compared separately.
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Figure 7.
Harmaline-induced tremor does not require
electrical coupling in IO. A, Force transducer output
from representative spontaneous tremor in a WT mouse before
(thick line) and after (thin line)
harmaline administration. Transducer output units are arbitrary but
fixed across all measurements. B, Power spectra from
force measurements in control (thick) and harmaline
(thin) states; harmaline tremor is evident as a sharp,
strong peak at ~14 Hz. C, Similar force measurements
in a representative KO mouse before and after harmaline (same scale as
in A). D, The power spectrum from the KO
mouse tremor is similar to that of the WT mouse.
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DISCUSSION |
Our results demonstrate that IO neurons are electrically coupled
by Cx36-dependent gap junctions. This is consistent with in
situ hybridization results (Condorelli et al., 2000) and
ultrastructural labeling studies (Rash et al., 2000), which show an
abundance of Cx36 mRNA and protein in the IO. IO coupling is
similar in strength, prevalence, and Cx36 dependence to the coupling
between inhibitory neurons in the neocortex (Galarreta and Hestrin,
1999; Gibson et al., 1999; Deans et al., 2001), hippocampus (Hormuzdi et al., 2001), and thalamic reticular nucleus (Landisman et al., 2002). Cx36 may not be the only connexin subtype that is functional in
IO neurons, because we did observe a small amount of residual coupling
in KO tissue, but Cx36 does seem to be required for the large majority
of the coupling. Interestingly, KO mice do not compensate for the loss
of Cx36 by expressing large amounts of some other type of connexin in
neurons of the neocortex (Deans et al., 2001), thalamic reticular
nucleus (Landisman et al., 2002), or inferior olive (this study).
By comparing our results from WT and KO neurons, it is clear that
electrical coupling can synchronize the activity of IO neurons and that
it is not necessary for the generation of spontaneous subthreshold
oscillations in IO. Surprisingly, the harmaline-induced tremor was
unaffected by a strong reduction of coupling between IO neurons. These
results are consistent with some long-standing hypotheses about the
cellular mechanisms of inferior olivary function, but they contradict
certain others.
Each action potential in an IO neuron triggers powerful climbing fiber
synapses that evoke complex spikes in cerebellar Purkinje cells (Eccles
et al., 1966). Synchrony in this system is evident from both the
correlated complex spikes of Purkinje cells (Lang et al., 1999) and the
synchronized rhythms of IO neurons (Leznik et al., 2002). One
compelling view is that synchrony in the olivocerebellar system is
critical to its role in motor control (Llinás et al., 1975;
Llinás, 1991). Synchrony of IO neurons has long been attributed to the fact that they are electrically coupled by gap junctions (Llinás et al., 1974; Sotelo et al., 1974; Llinás and
Yarom, 1981b), although the dependence of synchrony on coupling had not been demonstrated directly. In our study of the Cx36 KO
mouse, we found that electrical coupling between IO cells, synchrony of
spontaneous subthreshold oscillations, and correlations between spikes
are nearly abolished. These results strongly support the classical view
that electrical coupling can synchronize the activity of IO neurons and
thereby coordinate the firing of ensembles of Purkinje cells.
IO neurons are also intrinsically rhythmic, and this rhythmicity
has a strong effect on the timing of their action potentials (Lampl and
Yarom, 1993). The mechanism of subthreshold oscillations clearly
involves particular ionic currents in IO membranes (Llinás and
Yarom, 1981a,b; Benardo and Foster, 1986; Bal and McCormick, 1997).
However, a variety of indirect experimental results (Llinás and
Yarom, 1986; Yarom, 1991; Bleasel and Pettigrew, 1992; Lampl and Yarom,
1997) and theoretical studies (Manor et al., 1997; Loewenstein et al.,
2001) have inspired the hypothesis that single IO neurons cannot
generate spontaneous, ongoing oscillations, but that rhythmicity occurs
as an emergent property of the electrically coupled network of IO
neurons. Our data challenge this idea. IO neurons of the
Cx36 KO were electrically uncoupled, yet just as strongly
rhythmic as IO neurons of WT mice. The two most probable explanations
for this result are that: (1) single IO neurons of normal mice are
indeed intrinsically rhythmic, because of their voltage- and
time-dependent ion channels, or (2) IO neurons of the
Cx36-null mutant express a different complement of ion
channels compared with their WT siblings. Although it cannot be ruled
out, the latter possibility seems less likely. Most of the intrinsic membrane properties of the KO cells, including resting potentials, action potential mechanisms, and subthreshold oscillation frequency, were similar to those of the WT cells (Table 1). An exception was input
resistance, which was somewhat higher in KO neurons. However, higher
input resistance in the uncoupled KO cells is predicted if gap
junctional conductance is a significant fraction of the input
conductance of each WT neuron (Deans et al., 2001). In coupled networks
of neocortical interneurons, for example, calculations suggest each
cell is coupled to tens of other cells, and approximately half of the
input conductance of each cell is attributable to summed gap junctional
conductances (Amitai et al., 2002). The higher input resistance of KO
neurons may account for the modestly larger amplitude of their
oscillations compared with WT cells. These results suggest that a
substantial change in olivary ion channel types or density is not part
of the Cx36 KO phenotype, although it is possible that small
compensatory changes occur. It is also unlikely that the weak residual
coupling we observed in KO neurons caused their spontaneous
oscillations; theories predicting a rhythmogenic role for coupling also
predict synchrony among the oscillating cells (Manor et al., 1997;
Loewenstein et al., 2001), and our paired KO recordings did not reveal
any synchrony. We suggest that single IO neurons are intrinsically capable of generating spontaneous subthreshold oscillations. This is
not to say that electrical coupling has no effect on subthreshold oscillations. The different voltage dependencies of WT and KO oscillations (Fig. 3C) suggest that the electrically coupled
network of WT neurons sustains oscillations of single IO cells over a range of membrane potentials that tends to inactivate the conductances that generate the oscillations of uncoupled KO cells.
Perhaps the most surprising result of our study is that KO mice,
which have a profound deficit in electrical coupling and spontaneous
spike synchrony in their IO, nevertheless have normal harmaline-induced
tremors. There is extensive evidence implicating the IO in the origins
of harmaline tremors (Llinás and Volkind, 1973; de Montigny and
Lamarre, 1973). It seems natural to assume that the electrical coupling
of IO neurons plays a role in coordinating strong volleys of afferent
excitation to the cerebellum, which in turn lead to synchronous
tremor-inducing output to motor structures (Loewenstein, 2002). Indeed,
that is what we expected. However, the robust tremor of the KO animals
and its close similarity to that of WT animals demands another explanation.
If the IO is indeed an essential component of the pacemaker for
harmaline-induced tremors, then there must be some gap
junction-independent mechanism that allows IO neurons to synchronize at
~14 Hz in vivo. There are several possibilities. Within
the IO, complex synaptic clusters called glomeruli contain closely
apposed, gap junction-coupled dendrites; these dendrites are also
postsynaptic to numerous GABAergic inhibitory synapses (Sotelo et al.,
1974; De Zeeuw et al., 1990). Blocking IO inhibition in rats apparently
enhances the synchrony of its climbing fiber output (Llinás and
Sasaki, 1989; Lang et al., 1996), but it is possible that the IO
inhibitory circuits also serve as the substrate for synchrony in the
absence of electrical coupling. The IO has a system of recurrent
inhibition (Armstrong et al., 1968; Crill, 1970; Llinás et al.,
1974), although there is little evidence for inhibitory interneurons
within the IO (De Zeeuw et al., 1998). It is possible that when
intrinsic rhythmicity is enhanced by harmaline, spike discharges by IO
neurons could be synchronized by a divergent set of inhibitory feedback
connections. Such inhibitory feedback could come from internuclear
connections. Olivocerebellar axons excite the cerebellar nuclei, and
the nuclear cells return a GABAergic feedback projection to the IO
(Sotelo et al., 1986; De Zeeuw et al., 1997). This reciprocal
excitatory-inhibitory circuit could in principle generate a high
degree of synchronous, rhythmic activity under the proper conditions.
Cerebellar nuclear neurons have many of the same intrinsic membrane
currents prominent in IO cells, including low-threshold calcium
currents (Llinás and Mühlethaler, 1988; Aizenman and
Linden, 1999). Harmaline may facilitate the rhythmicity of nuclear
cells just as it does IO cells (Llinás and Yarom, 1986).
Collaterals of the nuclear cells would then deliver this synchronized,
rhythmic inhibition to downstream motor circuits.
Our data suggest that gap junction-mediated synchrony does not play a
major role in pathological forms of tremors, such as essential tremor,
which the effects of harmaline may mimic. This does not necessarily
imply, however, that electrical coupling in IO is irrelevant to
olivocerebellar function. More sensitive tests of tremor patterns
across time and body segments may yet reveal differences between the WT
and KO phenotype. Recent work using voltage-sensitive dyes to image
activity in IO slices revealed spatially distinct domains, consisting
of hundreds of neurons, that generate highly synchronized rhythms
(Devor and Yarom, 2002a; Leznik et al., 2002). Modeling results suggest
that the size of the rhythmic domains may be determined by the strength
of electrical coupling (Leznik et al., 2002). Clusters of synchronized
IO neurons drive synchronized complex spiking in spatially discrete
groups of Purkinje cells (Welsh et al., 1995; Lang et al., 1999). Our results lead to the prediction that the Cx36 KO mouse should have disruptions in the spatiotemporal patterns of complex spiking in the
cerebellar cortex. If such patterns are indeed important for the
control of movement, then the KO animals should also exhibit specific
deficits of motor control.
| |
FOOTNOTES |
Received Aug. 19, 2002; revised Sept. 23, 2002; accepted Oct. 3, 2002.
This work was supported by National Institutes of Health Grants NS25983
(B.W.C.), DA12500 (B.W.C.), and GM37751 (D.L.P.). We thank Saundy
Patrick for outstanding technical help, Jay Gibson for software
development, and Michael Beierlein and Scott Cruikshank for helpful
comments on this manuscript.
Correspondence should be addressed to Barry W. Connors, Department of
Neuroscience, Box 1953, 190 Thayer Street, Brown University, Providence, RI 02912. E-mail: BWC{at}brown.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
