 |
 Previous Article | Next Article 
The Journal of Neuroscience, April 15, 2003, 23(8):3538
Stabilization of Bursting in Respiratory Pacemaker Neurons
Andrew K.
Tryba,
Fernando
Peña, and
Jan-Marino
Ramirez
The University of Chicago, Department of Organismal Biology and
Anatomy, Chicago, Illinois 60637
 |
ABSTRACT |
Synaptic and endogenous pacemaker properties have been
hypothesized as principal cellular mechanisms for respiratory rhythm generation. This rhythmic activity is thought to originate in the
pre-Bötzinger complex, an area that can generate fictive respiration when isolated in brainstem slice preparations of mice. In
slice preparations, external potassium concentration
([K+]o) is typically elevated
from 3 to 8 mM to induce rhythmic population activity.
However, elevated [K+]o may not simply
depolarize respiratory neurons but also change rhythm-generating
mechanisms by inducing or altering pacemaker properties. To test this,
we examined the membrane potential
(Vm) of nonpacemaker neurons and
endogenous bursting properties of pacemaker neurons before and after
blockade of excitatory and inhibitory synaptic input in 3 mM [K+]o artificial CSF
(aCSF). Most pacemaker neurons (82%) ceased to burst in 3 mM [K+]o aCSF after
blockade of glutamatergic transmission. In all of these, endogenous
bursting was restored on additional blockade of glycinergic and
GABAergic inhibition. Thus, bursting properties are suppressed by
endogenous synaptic inhibition, the level of which may determine
whether network rhythmicity is generated in 3 mM
(n = 12) or 8 mM (n = 40) [K+]o aCSF. In 3 mM
[K+]o aCSF, synaptically isolated
pacemaker neurons (n = 22) continued to burst over
a wide range of imposed Vm. Furthermore, the
Vm of synaptically isolated pacemaker
neurons was not significantly affected (p = 0.1; n = 10) when
[K+]o was changed from 8 to 3 mM, whereas isolated nonpacemakers hyperpolarized
(p < 0.001; n = 14). We
conclude that respiratory pacemaker neurons possess membrane properties
that stabilize their bursting against changes in
[K+]o and imposed changes in
Vm.
Key words:
respiration; pacemaker properties; pattern
generation; pre-Bötzinger complex; rhythm generation; potassium
concentration
| |
Introduction |
Throughout the brain, intense
neuronal activity can raise the extracellular potassium concentration
([K+]o) from 3 mM (resting) to up to 10-12 mM
[K+]o, and this
may alter rhythmogenesis for a variety of networks (Xiong and Stringer,
2000 ). Changes in
[K+]o can have
severe and even fatal consequences unless network or pacemaking
mechanisms can compensate (Cohen et al., 1975; Johnson et al., 2001).
Stabilization of this vital activity requires adjusting the
excitability of neurons despite changes in
[K+]o during
sensory stimulation (Singer and Lux, 1975; Poolos et al., 1987),
bursting during normoxia (Haller et al., 2001; Somjen, 2002), hypoxia
(Hansen, 1985; Müller and Somjen, 2000), and epileptiform activity (Orkand, 1980; Jensen et al., 1994). The respiratory center
within the brainstem must also face these challenges and indeed
continues to be rhythmic over a range of
[K+]o (Newstead et
al., 1990; Peterson et al., 1992; Johnson et al., 2001). However, the
mechanisms that allow the respiratory network to operate over a wide
range of [K+]o are
unknown. Here, we begin to examine this issue.
Increasing evidence suggests that the respiratory network is localized
within the pre-Bötzinger complex (PBC). Lesioning of the PBC
abolishes breathing in vivo (Ramirez et al., 1998; Gray et
al., 2001), and isolated in a medullary brainstem slice, the PBC still
generates respiratory rhythmic activity in vitro (Smith et
al., 1991). However, experiments using this slice preparation are
typically performed with
[K+]o raised from
3 to 8 mM to induce rhythmic network activity at the population level within the PBC (Smith et al., 1991; Lieske et al.,
2000). Elevating
[K+]o may recruit
neurons that are not endogenous pacemakers into a voltage range in
which they express pacemaking properties (Richter and Spyer, 2001)
similar to hyperkalemic induction of ectopic pacemakers in the heart
(Cohen et al., 1975), granule cell bursting in the dentate gyrus (Pan
and Stringer, 1997), and in hippocampal pyramidal neurons (Jensen et
al., 1994). Indeed, computational models of inspiratory neurons suggest
that they do not express pacemaking properties at physiological
[K+]o (Rybak et
al., 2001). This theoretical consideration has led to the hypothesis
that the induction of pacemaker properties at nonphysiological
[K+]o may
significantly alter rhythm-generating mechanisms in the in
vitro respiratory network (Rybak et al., 2001). If
rhythm-generating mechanisms in vitro are fundamentally
different from those in vivo, the usefulness of in
vitro preparations for understanding the neuronal control of
breathing becomes questionable. However, to date the effect of changing
[K+]o on
respiratory pacemaker neurons was only considered in modeling studies
(Del Negro et al., 2001; Rybak et al., 2001); no experiments have
tested whether pacemaker neurons are inactive at physiological [K+]o. It is also
unknown how changes in
[K+]o affect
pacemaker activity. Here we show that pacemaker properties are present
at physiological
[K+]o, and these
properties are surprisingly unaffected by changes in
[K+]o, suggesting
that respiratory pacemaker neurons may possess membrane properties that
stabilize pacemaker activity. Such membrane properties may not only
exist in respiratory neurons but may be a property of pacemaker neurons
in general.
| |
Materials and Methods |
All experiments conformed to the guiding principles for the care
and use of animals approved by the National Institutes of Health and
the Animal Care and Use Committee at the University of Chicago. All
efforts were made to minimize both the number of animals used and their suffering.
Medullary brain slice preparation. All experiments used the
transverse, rhythmic medullary brain-slice preparation (Funk et al., 1994; Ramirez et al., 1996) (see Fig.
1A,B). Mice (0- to 9-d-old
CD-1 outbred mice; Charles River Laboratories,
Wilmington, MA) were deeply anesthetized with ether (delivered
by inhalation) and quickly decapitated at the C3/C4 spinal level
(Ramirez et al., 1996). The brainstem was dissected in ice-cold
artificial CSF (aCSF) that was equilibrated with carbogen (95%
O2 and 5% CO2), pH 7.4. Rhythmic 650-µm-thick slices containing the PBC (Ramirez et al.,
1996) were obtained by slicing the medulla using a microslicer
(VT1000S; Leica, Nussloch, Germany). Slices were submerged
in a recording chamber (6 ml) under circulating aCSF (30°C; flow
rate, 17 ml/min; total volume, 200 ml) containing the following (in
mM): 118 NaCl, 3 KCl, 1.5 CaCl2, 1 MgCl2 × 6 H2O, 25 NaHCO3, 1 NaH2PO4, and 30 D-glucose, equilibrated with carbogen (95%
O2 and 5% CO2), pH 7.4. KCl was elevated from 3 to 8 mM over a span of 30 min before commencing recordings. All aCSF chemicals were obtained from
Sigma (St. Louis, MO). Bath temperature was monitored and
automatically adjusted to 30 ± 0.7°C of the set temperature
using a Warner Instruments (Hamden, CT) TC-344B
temperature regulator with an in-line solution heater (SH-27B); bath
temperature at various locations within the bath was routinely uniform.
Electrophysiological recordings: integrated PBC population
activity and current clamp recordings. Extracellular recordings were obtained with glass suction electrodes positioned on the slice
surface in the PBC (see Fig. 1A). The signal
collected was amplified and filtered (low-pass, 1.5 kHz; high-pass 250 Hz), rectified, and integrated using an electronic filter (time
constant, 60 msec) (Ramirez et al., 1996) (see Fig.
1B). The population activity is predominated by
inspiratory neurons such that integrated PBC activity is in phase with
integrated XII activity (Telgkamp and Ramirez, 1999) and PBC
population bursts thus serve as a marker of fictive inspiration (see
Fig. 1A,B).
Intracellular patch-clamp recordings were obtained from PBC neurons
using the blind-patch technique (see Fig. 1Ci). Patch electrodes were manufactured from filamented borosilicate glass tubes
(Clark G150F-4; Warner Instruments) and filled with a
solution containing the following (in mM): 140 K-gluconic acid, 1 CaCl2 × 6 H2O, 10 EGTA, 2 MgCl2 × 6 H2O, 4 Na2ATP, and 10 HEPES. Only inspiratory neurons active in phase with population activity were considered in this study. The discharge pattern of each cell type was
first identified in the cell-attached mode (in 8 mM
[K+]o aCSF).
Experiments were then performed in whole-cell patch-clamp mode. The
membrane-potential values were corrected for liquid junction potentials
as described by Neher (1992). In current-clamp, to isolate neurons
from chemical synaptic input, we added glutamatergic, GABAergic,
or glycinergic antagonists either individually or as a mixture. These
drugs were bath applied at the following final concentrations (in
µM): 40 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; Tocris Cookson, Ballwin, MO), 10 µM
(RS)-3-(2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid
(CPP; Tocris Cookson), 1 µM
strychnine (Sigma), and 20 µM bicuculline free-base (Sigma). Note that unlike
bicuculline methiodide, the bicuculline free-base derivative is a
specific GABA receptor antagonist and is not known to block
apamin-sensitive Ca2+-activated
K+ currents (Johnson and Seutin, 1997;
Debarbieux et al., 1998).
Data analysis. All recordings were transferred to a personal
computer using a Digidata (Axon Instruments, Foster City,
CA) analog-to-digital conversion board. Data were stored using Axotape (version 2.0; Axon Instruments) and analyzed off-line.
Only signals with good signal-to-noise ratios were quantitatively
analyzed with software programs written using Igor Pro version 3.11 (WaveMetrics, Lake Oswego, OR). To make membrane
potential (Vm) measurements (Table
1) under various experimental conditions
(e.g., 3 vs 8 mM
[K+]o aCSF), the
Vm was averaged over a 100 sec period
of time, and the resultant value was compared with similar data
collected under a different condition from the same cell using a paired
Student's t test. Because in certain situations (e.g., 8 mM
[K+]o aCSF)
neurons were firing action potentials and/or bursting, we eliminated
Vm deflections attributable to
spikes, bursts, and their afterhyperpolarizations from our averaged
Vm measurements using code written
with Igor Pro so that the average accurately reflected the baseline
Vm.
View this table:
[in this window]
[in a new window]
|
Table 1.
Effect of changing aCSF [K+]o
from 8 to 3 mM on Vm of
synaptically isolated (in CNQX, CPP, bicuculline, and strychnine)
pacemakers and nonpacemakers
|
|
| |
Results |
Population activity in 3 mM
[K+]o
The population activity recorded with
[K+]o elevated to
8 mM (Fig.
1B,Ci,Di,
top traces) can be used to identify intracellularly recorded neuronal
activity (Fig. 1Ci,Di, bottom traces). The
neurons with activity that is in phase with the population bursts are termed inspiratory neurons (Fig. 1Ci,Di). After
lowering the aCSF [K+]o from 8 to 3 mM, the majority (40 of 52) of slices ceased to generate population bursts (Fig. 1Cii). However, in some
cases (12 of 52), rhythmic activity persisted in 3 mM
[K+]o at the
cellular and population levels (Fig. 1Dii); this has not been published previously. We next examined whether cessation of
rhythmicity in most preparations was caused by effects of lower [K+]o on
pacemakers and/or nonpacemakers by comparing their activity before and
after isolation from chemical synaptic transmission.
View larger version (41K):
[in this window]
[in a new window]
|
Figure 1.
Mouse medullary slice preparation containing the
respiratory network. A, Extracellular suction electrodes
are placed on the surface of the brain slice preparation to record
population activity from the PBC. The hypoglossal motor nucleus
is labeled (XII). B, PBC population activity (PBC trace)
is integrated ( PBC) and used as a marker for fictive eupneic
inspiratory activity. Ci, Record of PBC (top trace)
and simultaneous intracellular recording from an inspiratory neuron in
aCSF having 8 mM [K+]o.
Cii, Both population (PBC, top trace) and neuron
bursts cease in aCSF with 3 mM
[K+]o. Di, Record from
a different preparation than in Ci and
Cii shows fictive inspiratory bursts (PBC, top trace)
and synchronized inspiratory neuron activity in aCSF having 8 mM [K+]o.
Dii, Note that both the population and inspiratory
neuron bursts persist in aCSF with 3 mM
[K+]o. Calibration:
(Cii) Ci-Dii, 15 mV, 10 sec.
|
|
Synaptically isolated inspiratory pacemaker neuron activity in
elevated (8 mM) and physiological
[K+]o
All of the pacemakers used for analysis met several criteria
before being classified as inspiratory pacemaker neurons
(n = 22). First, after isolation of the neuron from
chemical synaptic input with bath applied CNQX, CPP, strychnine, and
bicuculline, pacemaker neurons continued to burst in the absence of
inspiratory population bursts (Fig.
2A,B).
Second, isolated pacemakers exhibited voltage-dependent
bursting properties. That is, either brief depolarizing current
injection could trigger a burst (data not shown), or hyperpolarizing current could terminate an ongoing burst; either of these reset the
ongoing rhythm (Fig. 2B). Finally, current injection
changed the bursting frequency of the neuron; depolarization increased (Fig. 2C, top trace) and hyperpolarization reduced (Fig.
2C, bottom trace) the bursting frequency.
View larger version (24K):
[in this window]
[in a new window]
|
Figure 2.
Criteria for identifying pacemakers.
A, In 8 mM
[K+]o aCSF, inspiratory pacemaker
bursts are in phase with PBC bursts. B, Bath
application of CNQX, CPP, bicuculline, and strychnine eliminates PBC
bursts while pacemaker neurons continue bursting. Brief current
injection reset the ongoing rhythm, the timing of which is demarcated
by black bars above the neuron recording. C, Injecting
depolarizing current into synaptically isolated pacemakers increased
the bursting frequency (top neural trace), whereas hyperpolarizing
current terminated bursting during current injection (bottom trace).
The y-axis scale in A applies to
B and C.
|
|
To examine the activity of pacemaker neurons at physiological potassium
concentrations, the aCSF containing 8 mM
[K+]o was replaced
with aCSF having 3 mM
[K+]o (Fig.
3A-C). Rhythmic bursting of
most (n = 18 of 22) of the pacemakers in aCSF with 8 mM
[K+]o was replaced
with tonic activity on lowering the
[K+]o to 3 mM
[K+]o (Fig.
3C) and remained tonic after blockade of glutamatergic synaptic transmission with CNQX and CPP (Fig. 3D). Blockade
of inhibition restored endogenous bursting in all of the pacemakers that were not bursting after isolation from glutamatergic synaptic input in 3 mM
[K+]o (Fig.
3D,E). Because synaptic inhibition
appeared to suppress pacemaker bursting in 3 mM
[K+]o, we also
tested whether (before blocking synaptic transmission) injecting
depolarizing DC could bring them into a voltage range in which they
burst. All examined inspiratory pacemakers that were tonic in 3 mM
[K+]o (Fig.
4A,B)
burst on depolarizing constant current injection (n = 5) (Fig. 4C). These neurons generated rhythmic bursts
without current injection after synaptic isolation (Fig.
4D).
View larger version (32K):
[in this window]
[in a new window]
|
Figure 3.
Synaptic inhibition can suppress pacemaker
bursting. A, Population bursts (PBC) and some
pacemakers cease bursting when 8 mM
[K+]o aCSF is exchanged with 3 mM [K+]o aCSF (arrow
indicates onset of exchange). B, Expanded record of
neuron bursting in 8 mM
[K+]o aCSF. C,
Relatively tonic spiking in 3 mM
[K+]o aCSF. D, The
neuron continues to spike tonically in 3 mM
[K+]o aCSF after blockade of
glutamatergic transmission with CNQX and CPP. E,
Endogenous bursting is restored after subsequent blockade of synaptic
inhibition with strychnine and bicuculline. y-Axis scale
in B applies to A-E.
x-Axis scale in B applies to
C-E.
|
|
View larger version (24K):
[in this window]
[in a new window]
|
Figure 4.
Pacemaker activity in 3 mM
[K+]o aCSF is restored during
depolarizing current injection. A, Under control
conditions (8 mM
[K+]o), pacemaker bursts are in
phase with those of the population (PBC). B, The
pacemaker is tonically active on lowering the aCSF
[K+]o to 3 mM.
C, Constant depolarizing current injection depolarized
the neuron into a Vm in which bursting was
restored. D, The pacemaker burst endogenously (i.e.,
without current injection) after synaptic isolation of the pacemaker in
3 mM [K+]o with
bath-applied CNQX, CPP, bicuculline, and strychnine.
y-Axis in A applies to
A-D.
|
|
Some of the pacemakers (n = 4 of 22) continued to
generate endogenous bursting when aCSF
[K+]o was lowered
from 8 to 3 mM before blocking chemical synaptic transmission but in the absence of population activity (Fig.
5A-C). These neurons
continued bursting in 3 mM
[K+]o after
blockade of synaptic input with CNQX, CPP, bicuculline, and strychnine
(Fig. 5D,E).
View larger version (64K):
[in this window]
[in a new window]
|
Figure 5.
Pacemakers can burst in aCSF with 3 and 8 mM [K+]o without blocking
synaptic transmission. A, Lowering the aCSF
[K+]o from 8 to 3 mM
(starting at downward arrow) typically results in a cessation of PBC
bursts (top trace), but some inspiratory neurons continue to burst
rhythmically (Neuron). B, C, Expanded
record of population (PBC) and cell (Neuron) in 8 mM
[K+]o (B) and
when aCSF [K+]o is lowered to 3 mM (C). Note that the neuron continues
to burst rhythmically in 3 mM
[K+]o, despite cessation of
PBC bursts. D, For pacemakers, raising aCSF
[K+]o from 3 to 8 mM while
chemical synaptic transmission is blocked does not result in a marked
shift in the baseline Vm (solutions
exchanged starting at downward arrow). E,
F, Expanded record of synaptically isolated pacemaker
activity in 3 mM [K+]o
aCSF (E) and when the
[K+]o is increased to 8 mM
(F). y-Axis in B
applies to B, C, and F.
x-Axis in B and E applies
to F.
|
|
Intrinsic membrane properties of pacemaker neurons anchor
Vm
As indicated in Table 1, the baseline
Vm of synaptically isolated pacemaker
neurons did not significantly change on lowering the aCSF
[K+]o from 8 to 3 mM (n = 10). Bursting in
synaptically isolated pacemakers also continued with little apparent
change in baseline Vm when
[K+]o was
increased from 3 to 8 mM (n = 3 tested) (Fig. 5D-F). To examine the bursting
properties of synaptically isolated pacemakers over a range of imposed
Vm, we injected hyperpolarizing
current pulses of several seconds in duration (n = 22).
Stepping to various hyperpolarized Vm
with 10 sec current injections revealed typical voltage-dependent
bursting properties (Fig.
6A-C). That is, the frequency of bursting decreased at hyperpolarized levels, and endogenous bursting could be suppressed by strongly hyperpolarizing current injections (n = 22) (Fig.
6A-C). However, the hyperpolarization evoked a slow
depolarization in pacemaker neurons whereby the neuron depolarized
throughout the constant current injection (n = 22)
(Figs. 2C, 6C). In 13 of these pacemakers, we
injected hyperpolarizing currents of varying intensity for >10 sec,
and in each case, the Vm depolarized
to a range in which endogenous bursting resumed (Fig.
6D). The maximum hyperpolarization resulting from a
current injection was plotted versus
Vm just before the first burst that occurred while the current injection was maintained. This plot revealed
that pacemaker neurons have intrinsic membrane properties that
depolarize them during the hyperpolarization (n = 13)
(Fig. 7A). In four cases,
pacemakers were hyperpolarized with constant current injected for the
same duration (3.7 min). Measurement of their
Vm at the onset of the current
injection ( 77.8 mV ± 1.9 SD) and just before terminating the
hyperpolarizing pulse (68.9 mV ± 2.3 SD) revealed that
pacemakers depolarized during the course of hyperpolarizing current
injection (p = 0.01; paired t test;
n = 4) (Fig. 6D). The bursting
frequency also increased throughout the maintained hyperpolarization
(p < 0.001; one-way ANOVA), but the bursting
frequency during the last 30 sec of current injection (0.21 ± 0.08, mean ± SD) did not reach control frequency (30 sec before
current application; 0.36 ± 0.18 SD; p = 0.014; one sample t test) (Fig. 7B). Bursting frequency
over the 30 sec after termination of current injection (0.37 ± 0.22 SD) was similar to baseline frequency measured 30 sec before
hyperpolarizing current injection (p = 0.841;
one-sample t test) (Fig. 7B).
View larger version (38K):
[in this window]
[in a new window]
|
Figure 6.
Hyperpolarizing current injections into
synaptically isolated pacemaker in 3 mM
[K+]o aCSF. Endogenous bursting
frequency is reduced or bursting is terminated during hyperpolarization
to 65 mV with a 10 sec 0.06 nA current injection
(A), 70 mV with a 10 sec 0.09 nA current
injection (B), and 75 mV with a 10 sec 0.13
nA current injection (C).
D, Hyperpolarization to 80 mV using a 0.15 nA
constant current injection for a longer (3.7 min) duration does not
terminate bursting. Calibration: (in A)
A-D, 10 mV.
|
|
View larger version (25K):
[in this window]
[in a new window]
|
Figure 7.
Pacemaker neurons depolarize during
hyperpolarization. A, Vm of
synaptically isolated pacemakers (in 3 mM
[K+]o aCSF containing CNQX plus CPP,
bicuculline, and strychnine) measured immediately after onset of
current injection (x-axis) and immediately before the
first burst (y-axis). Each square represents one
current injection, and data are pooled from n = 13 neurons. B, Mean burst frequency histogram (10 sec bins:
n = 4 mean ± SD) before, during, and after
hyperpolarizing current injection for 3.7 min. The pacemakers in 3 mM [K+]o aCSF were
synaptically isolated in CNQX, CPP, bicuculline, and strychnine. Onset
and offset of current injection are indicated by arrows.
|
|
Nonpacemaker inspiratory neuron activity in 3 and 8 mM [K+]o
Are intrinsic membrane properties that anchor
Vm against changes in
[K+]o or
hyperpolarization also present in inspiratory nonpacemakers? When the
aCSF [K+]o is
lowered from 8 to 3 mM, activity in nonpacemaker
neurons behaved much like the population activity (Fig.
8A) and hyperpolarized (Table 1). Synaptically driven rhythmic bursting that was present in 8 mM
[K+]o ceased at 3 mM
[K+]o aCSF (Fig.
8A,B). The nonpacemaker neurons
became inactive and did not generate spontaneous action potentials when
the [K+]o was at 3 mM (Fig. 8A) or when they were
isolated from glutamatergic synaptic input with CNQX and CPP
(n = 25) (Fig. 8C). With glutamatergic input
blocked, we also examined the effects of blocking inhibition in 10 nonpacemakers. These nonpacemaker neurons were either tonically active
(n = 7) or silent (n = 3) (Fig.
9A-C) after additional blockade of synaptic inhibition with bicuculline and strychnine. Unlike
pacemakers (Fig. 4C), nonpacemaker inspiratory neurons (Fig.
9A) generated tonic activity in response to depolarizing current injection in 3 mM
[K+]o aCSF before
(Fig. 9B) and after (Fig. 9C) isolation from
chemical synaptic transmission (n = 5). In
addition, these neurons did not burst when the
[K+]o was raised
from 3 to 8 mM (n = 5) (Fig.
9D). The Vm of
nonpacemakers did not change during prolonged (3.7 min) hyperpolarizing
current injection to 81.3 mV ± 2.3 SD. The membrane potential
just before terminating the current injection was 80.8 mV ± 2.9 SD (n = 5; p = 0.328; paired
t test) (Fig. 9E).
View larger version (26K):
[in this window]
[in a new window]
|
Figure 8.
Nonpacemaker inspiratory neuron bursting ceases in
3 mM [K+]o aCSF.
A, PBC (top trace) and inspiratory neuron activity
during replacement of 8 mM
[K+]o aCSF with aCSF having 3 mM [K+]o (arrow indicates
onset of aCSF exchange). Note that the neuron hyperpolarizes in 3 mM [K+]o aCSF.
B, Expanded record of inspiratory neuron activity in 8 mM [K+]o.
C, Both population and neuron activity remain silent in
3 mM [K+]o aCSF with
blockade of glutamatergic input with CNQX and CPP. Calibration:
(B) B, C, 10 mV, 1 sec.
|
|
View larger version (19K):
[in this window]
[in a new window]
|
Figure 9.
Nonpacemaker neurons are tonic in 3 mM
aCSF on super-rheobase current injection. A, PBC (top
trace) and nonpacemaker inspiratory neuron activity in 8 mM
[K+]o (bottom trace).
B, In 3 mM aCSF, PBC population bursts
and nonpacemaker activity cease and depolarizing current injection
evokes tonic activity (current). C, After blockade of
chemical transmission with CNQX, CPP, bicuculline, and strychnine,
PBC population activity and nonpacemakers remain silent. The cell
discharges tonically on depolarization in 3 mM
[K+]o aCSF. D,
Synaptically isolated nonpacemaker remains silent when aCSF
[K+]o is raised from 3 to 8 mM. Calibration: (B)
C-E, 25 mV, 1 sec. Nonpacemakers do not depolarize
during prolonged hyperpolarizing current injection.
|
|
| |
Discussion |
The results of this study indicate that in the brainstem slice
preparation, the respiratory network (PBC) and pacemaker neurons can
produce fictive respiratory activity at physiological extracellular potassium concentrations
([K+]o). Thus,
pacemakers may play a key role in respiratory rhythmogenesis under
physiological conditions. Data obtained by Johnson et al. (2001)
revealed that in vitro the presence of endogenous synaptic inhibition can suppress PBC population bursts, and we add here that
endogenous bursting properties of pacemakers can also be suppressed by
synaptic inhibition in aCSF with 3 mM
[K+]o. Intrinsic
membrane properties of pacemakers, but not nonpacemaker neurons, can
anchor their membrane potential within a range in which they burst
endogenously, despite imposed hyperpolarization or changes in
[K+]o.
A central issue to understanding breathing in mammals is to identify
the neural mechanisms underlying rhythm generation for a variety of
breathing patterns (e.g., eupnea, sighs, and gasps). Respiratory
pacemakers have been hypothesized to play a key role in rhythmogenesis,
but those isolated in various in vitro preparations have
been described in aCSF containing elevated
[K+]o
(Thoby-Brisson and Ramirez, 2000; for review, see Richter and Spyer,
2001). This paradigm has fostered controversy over whether endogenous
pacemakers contribute to the respiratory rhythm, because in other
systems, neurons that do not express pacemaking properties at 3 mM
[K+]o burst
endogenously when
[K+]o is raised
(Jensen et al., 1994; Jensen and Yaari, 1997; Su et al., 2001).
Furthermore, modeling of respiratory neurons predicted, on the basis of
theoretical considerations, that potassium concentrations must be >6
mM for endogenous bursting to occur and suggested
that endogenous pacemakers cannot be responsible for, or even
contribute to, respiratory rhythmogenesis at physiological potassium
concentrations (Rybak et al., 2001). For these reasons, several authors
have proposed that respiratory rhythmogenesis is an emergent network property that depends on synaptic interactions (for review, see Richter
and Spyer, 2001). However, the results presented here argue against
excluding pacemakers as playing a role in rhythmogenesis, because both
the population and endogenous pacemakers can generate respiratory
activity in 3 mM
[K+]o aCSF (Figs.
1Dii, 5A).
The possibility that pacemaker neurons are essential for respiratory
rhythm generation has been questioned recently on the basis of
pharmacological experiments (Del Negro et al., 2002). Although
strain and species differences are possible, these studies have
demonstrated that riluzole, a blocker of the persistent sodium current
that is found in some respiratory pacemakers, did not abolish
respiratory rhythm generation in either mice or rats. This conclusion
is based on the assumption that all pacemaker neurons have similar
bursting properties and are sensitive to riluzole. However, this is not
the case. The respiratory network not only contains the pacemaker
neurons whose bursting depends on the persistent sodium current but
also pacemaker neurons with bursting properties that depend on calcium
currents (Thoby-Brisson and Ramirez, 2001). The majority of neurons in
the study by Del Negro et al. (2002) were examined in zero
extracellular calcium concentrations that abolish bursting in the
Ca2+-dependent pacemaker population. Thus,
the riluzole sensitivity of these pacemaker neurons remains unexamined.
Indeed, our studies suggest that not all pacemaker neurons are riluzole
sensitive, and some of these continue to burst after blockade of
voltage-dependent Ca2+ channels with
cadmium (Parkis et al., 2002). Although it remains unclear whether
pacemaker neurons are essential for respiratory rhythm generation, this
study demonstrates that pacemaker neurons could contribute to
respiratory rhythm generation, not only at high but also physiological
[K+]o. Clearly,
many properties of the respiratory network are consistent with the
concept that pacemaker neurons contribute to respiratory rhythm
generation. The frequency of pacemaker bursts mimics the biphasic
hypoxic response (Thoby-Brisson and Ramirez, 2000), and modeling
studies demonstrate that many characteristics of the respiratory
network can be explained by the activation and inactivation properties
of endogenously bursting neurons (Butera et al., 1999a,b).
Our study also contributed to a better understanding of the role of
synaptic inhibition in the respiratory network. Previous studies have
demonstrated that synaptic inhibition plays a critical role in the
generation of the respiratory pattern that underlies eupneic activity
(Lieske et al., 2000; Büsselberg et al., 2001). However,
rhythmogenesis persists after the blockade of synaptic inhibition
(Figs. 2B, 3E, 4D,
5D, 6A) (Smith et al., 1991, 2000; Ramirez
et al., 1997; Shao and Feldman, 1997; Brockhaus and Ballanyi, 1998;
Rekling and Feldman, 1998; Butera et al., 1999; Koshiya and
Smith, 1999). Here, we demonstrate that inhibition plays a critical
role in modulating pacemaker activity, as occurs in other systems. For
instance, inhibition regulates endogenous bursting in the
stomatogastric system of crustacea (Cazalets et al., 1987), the spinal
cord (Su, 2001), and the substantia nigra (Silva and Bunney, 1988).
Our data show that inhibition can suppress endogenous bursting of some
(Fig. 3E) but not all (Fig. 5C) pacemakers
in vitro, which could explain why respiratory network
activity ceases at physiological potassium concentrations (Fig.
1Cii) (Johnson et al., 2001). Although this finding may
suggest that network and inspiratory pacemaker activity
primarily depends on modulation of inhibition (i.e., conditional
pacemaking), the same level of inhibition may not be present in
vivo. Along these lines, whereas elevating
[K+]o raised
excitability of nonpacemaker neurons (Table 1), it may also suppress
chloride-mediated GABAergic inhibition (Traynelis and Dingledine, 1989;
Jensen et al., 1994; Pan and Stringer, 1997); both of these factors may
enhance the likelihood of evoking population activity in
vitro. That said, inhibition does not interfere with the mechanism
of pacemaker bursting, because depolarizing pacemakers that are
tonically firing in 3 mM
[K+]o can bring
them into a Vm range in which bursting
occurs (Fig. 4C).
Another important finding of our study was that lowering the
[K+]o from 8 to 3 mM did not significantly change the
Vm of synaptically isolated pacemaker
neurons (Table 1). Thus, future neural models of the respiratory
network should consider that the excitability of pacemaker neurons is
not primarily determined by
EK+ (Del Negro et al.,
2001). More importantly, unlike nonpacemaker neurons, intrinsic
membrane properties of pacemakers seem to anchor their
Vm in a range in which they express
pacemaking properties. After hyperpolarizing current injection,
pacemaker neurons had intrinsic membrane properties that depolarized
them into a Vm in which they express
pacemaker bursting. This may serve to enhance the stability of
rhythmogenesis during variations in
[K+]o, as occurs
for bursting activity during normoxia (Haller et al., 2001; Somjen,
2002) and hypoxic conditions (Hansen, 1985; Müller and Somjen,
2000). Future studies will be necessary to determine the type of ion
channel that is responsible for this depolarization. One obvious
candidate is Ih current. However, this
ionic current is only expressed in some, but not all, respiratory pacemaker neurons (Thoby-Brisson et al., 2000). Furthermore, the putative ion channel appears to have a much slower time constant, because the depolarization developed in tens of seconds (Figs. 6D, 7B) rather than within 1.5 sec, as is
typical for the Ih current (Thoby-Brisson et al., 2000). Whatever the underlying mechanism, intrinsic pacemaker properties could contribute to stabilization of the Vm of pacemakers to promote
bursting despite changes in [K+]o (Table 1,
Fig. 6D) (Kramer and Zucker, 1985; Andrew,
1987). These intrinsic mechanisms may be widely responsible for
stabilizing rhythmic bursting of pacemakers in a variety of systems
including Aplysia (Kramer and Zucker, 1985), supraoptic
magnocellular neurons (Andrew, 1987), and nucleus principalis
trigeminal neurons (Sandler et al., 1998).
The results support the hypothesis that PBC pacemakers may contribute
to respiratory rhythmogenesis. These data suggest that it is not
necessary to assume that the rhythm relies on network properties. In
addition, it would be useful to integrate these findings into new
models of respiratory rhythm generation, so the models more accurately
reflect results from experimental manipulation. Finally, the degree of
synaptic inhibition may permit flexibility in terms of control of
pacemakers so that the respiratory pattern can be adjusted to meet the
respiratory needs of the animal.
| |
FOOTNOTES |
Received Sept. 12, 2002; revised Feb. 5, 2003; accepted Feb. 5, 2003.
This work was supported by National Institutes of Health (NIH) Grant
1F32HL67659 (A.K.T.), a Pew Charitable Trust Fellowship (F.P.), and NIH
Grant RO1-HL 60120 (J.M.R.). We thank Drs. Steve P. Lieske for
technical support in data analysis and editing and Marjorie Parkis for
editorial comments.
Correspondence should be addressed to Dr. Andrew K. Tryba, The
University of Chicago, Department of Organismal Biology and Anatomy,
1027 East 57th Street, Chicago, IL 60637-1508. E-mail: Tech10s{at}techsan.org.
| |
References |
-
Andrew RD
(1987)
Endogenous bursting by rat suproptic neuroendocrine cells is calcium dependent.
J Physiol (Lond)
384:451-465[Abstract/Free Full Text].
-
Brockhaus J,
Ballanyi K
(1998)
Synaptic inhibition in the respiratory network of neonatal rats.
Eur J Neurosci
10:3823-3839[Web of Science][Medline].
-
Busselberg D,
Bischoff AM,
Paton JF,
Richter DW
(2001)
Reorganization of respiratory network activity after loss of glycinergic inhibition.
Pflügers Arch
441:444-449[Web of Science][Medline].
-
Butera Jr RJ,
Rinzel J,
Smith JC
(1999a)
Models of respiratory rhythm generation in the pre-Botzinger complex. I. Bursting pacemaker neurons.
J Neurophysiol
81:382-397.
-
Butera Jr RJ,
Rinzel J,
Smith JC
(1999b)
Models of respiratory rhythm generation in the pre-Botzinger complex. II. Populations of coupled pacemaker neurons.
J Neurophysiol
81:398-415.
-
Cazalets JR,
Cournil I,
Geffard M,
Moulins M
(1987)
Suppression of oscillatory activity in crustacean pyloric neurons: implication of GABAergic inputs.
J Neurosci
7:2884-2893[Abstract].
-
Cohen HC,
Rosen KM,
Pick A
(1975)
Disorders of impulse conduction and impulse formation caused by hyperkalemia in man.
Am Heart J
89:501-509[Web of Science][Medline].
-
Debarbieux F,
Brunton J,
Charpak S
(1998)
Effect of bicuculline on thalamic activity: a direct blockade of IAHP in reticularis neurons.
J Neurophysiol
79:2911-2918[Abstract/Free Full Text].
-
Del Negro CA,
Johnson SM,
Buter RJ,
Smith JC
(2001)
Models of respiratory rhythm generation in the pre-Botzinger complex. III. Experimental tests of model predictions.
J Neurophysiol
86:59-74[Abstract/Free Full Text].
-
Del Negro CA,
Koshiya N,
Butera Jr RJ,
Smith JC
(2002)
Persistent sodium current, membrane properties and bursting behavior of pre- Bötzinger complex inspiratory neurons in vitro.
J Neurophysiol
88:2242-2250[Abstract/Free Full Text].
-
Funk G,
Smith JC,
Feldman JL
(1994)
Development of thyrotropin-releasing hormone and norepinephrine potentiation of inspiratory-related hypoglossal motorneuron discharge in neonatal and juvenile mice in vitro.
J Neurophysiol
72:2538-2541[Abstract/Free Full Text].
-
Gray PA,
Janczewski WA,
Mellen N,
McCrimmon DR,
Feldman JL
(2001)
Normal breathing requires preBotzinger complex neurokinin-1 receptor-expressing neurons.
Nat Neurosci
4:927-930[Web of Science][Medline].
-
Haller M,
Mironov SL,
Karschin A,
Richter DW
(2001)
Dynamic activation of Katp channels in rhythmically active neurons.
J Physiol (Lond)
537:69-81[Abstract/Free Full Text].
-
Hansen AJ
(1985)
Effects of anoxia on ion distribution in the brain.
Physiol Rev
65:101-148[Free Full Text].
-
Jensen MS,
Yaari Y
(1997)
Role of intrinsic burst firing, potassium accumulation, and electrical coupling in the elevated potassium model of hippocampal epilepsy.
J Neurophysiol
77:1224-1233[Abstract/Free Full Text].
-
Jensen MS,
Azouz Y,
Yaari Y
(1994)
Variant firing patterns in rate hippocampal pyramidal cells modulated by extracellular potassium.
J Neurophysiol
71:831-839[Abstract/Free Full Text].
-
Johnson SM,
Koshiya N,
Smith JC
(2001)
Isolation of the kernel for respiratory rhythm generation in a novel preparation: the pre-Bötzinger complex "island."
J Neurophysiol
85:1772-1776[Abstract/Free Full Text].
-
Johnson SW,
Seutin V
(1997)
Bicuculline methiodide potentiates NMDA-dependent burst firing in rat dopamine neurons by blocking apamin-sensitive Ca2+-activated K+ currents.
Neurosci Lett
231:13-16[Web of Science][Medline].
-
Koshiya N,
Smith JC
(1999)
Neuronal pacemaker for breathing visualized in vitro.
Nature
400:360-363[Medline].
-
Kramer RH,
Zucker RS
(1985)
Calcium-induced inactivation of calcium current causes inter-burst hyperpolarization of Aplysia bursting neurons.
J Physiol (Lond)
362:131-160[Abstract/Free Full Text].
-
Lieske SP,
Thoby-Brisson M,
Telgkamp P,
Ramirez JM
(2000)
Reconfiguration of the neural network controlling multiple breathing patterns: eupnea, sighs and gasps.
Nat Neurosci
3:600-607[Web of Science][Medline].
-
Müller M,
Somjen GG
(2000)
Na+ and K+ concentrations, extra- and intracellular voltages and the effect of TTX in hypoxic rat hippocampal slices.
J Neurophysiol
83:735-745[Abstract/Free Full Text].
-
Neher E
(1992)
Correction for liquid junction potentials in patch clamp experiments.
Methods Enzymol
207:123-131[Web of Science][Medline].
-
Newstead CG,
Donaldson GC,
Sneyd JR
(1990)
Potassium as a respiratory signal in humans.
J Appl Physiol
69:1799-1803[Abstract/Free Full Text].
-
Orkand RK
(1980)
Extracellular potassium accumulation in the nervous system.
FASEB J
39:1515-1518.
-
Pan E,
Stringer JL
(1997)
Role of calcium and potassium in generation of cellular bursts in the dentate gyrus.
J Neurophysiol
77:2293-2299[Abstract/Free Full Text].
-
Parkis MA,
Peña F,
Ramirez JM
(2002)
The roles of pacemaker neurons in the generation of different respiratory rhythms.
Soc Neurosci Abstr
28:362.5.
-
Paterson DJ,
Dorrington KL,
Bergel DH,
Kerr G,
Miall RC,
Stein JF,
Nye PC
(1992)
Effect of potassium on ventilation in the rhesus monkey.
Exp Physiol
77:217-220[Abstract].
-
Poolos NP,
Mauk MD,
Kocsis JD
(1987)
Activity-evoked increases in extracellular potassium modulate presynaptic excitability in the CA1 region of the hippocampus.
J Neurophysiol
58:404-416[Abstract/Free Full Text].
-
Ramirez JM,
Schwarzacher SW,
Pierrefiche O,
Olivera BM,
Richter DW
(1996)
Selective lesioning of the cat pre-Bötzinger complex in vivo eliminates breathing but not gasping.
J Physiol (Lond)
507:895-907.
-
Ramirez JM,
Telgkamp P,
Elsen FP,
Quellmalz UJA,
Richter DW
(1997)
Respiratory rhythm generation in mammals: synaptic and membrane properties.
Respir Physiol
110:71-85[Web of Science][Medline].
-
Ramirez JM,
Quellmalz UJA,
Wilken B,
Richter DW
(1998)
The hypoxic response of neurons within the in vitro mammalian respiratory network.
J Physiol (Lond)
507:571-582[Abstract/Free Full Text].
-
Rekling JC,
Feldman JL
(1998)
PreBotzinger complex and pacemaker neurons: hypothesized site and kernel for respiratory rhythm generation.
Annu Rev Physiol
60:385-405[Web of Science][Medline].
-
Richter DW,
Spyer KM
(2001)
Studying rhythmogenesis of breathing: comparison of in vivo and in vitro models.
Trends Neurosci
24:464-472[Web of Science][Medline].
-
Rybak IA,
St John WM,
Paton JF
(2001)
Models of neuronal bursting behavior: implications for in-vivo versus in-vitro respiratory rhythmogenesis.
Adv Exp Med Biol
499:159-164[Medline].
-
Sandler VM,
Puil E,
Schwarz DWF
(1998)
Intrinsic response properties of bursting neurons in the nucleus principalis trigemini of the gerbil.
Neuroscience
83:891-904[Web of Science][Medline].
-
Shao YM,
Feldman JL
(1997)
Respiratory rhythm generation and synaptic inhibition of expiratory neurons in pre-Botzinger complex: differential roles of glycinergic and GABAergic neural transmission.
J Neurophysiol
77:1853-1860[Abstract/Free Full Text].
-
Silva NL,
Bunney BS
(1988)
Intracellular studies of dopamine neurons in vitro: pacemakers modulated by dopamine.
Eur J Pharmacol
149:307-315[Web of Science][Medline].
-
Singer W,
Lux HD
(1975)
Extracellular potassium gradients and visual receptive fields in the cat striate cortex.
Brain Res
96:378-383[Web of Science][Medline].
-
Smith JC,
Ellenberger HH,
Ballanyi K,
Richter DW,
Feldman JL
(1991)
Pre-Bötzinger complex: a brainstem region that may generate respiratory rhythm in mammals.
Science
254:726-729[Abstract/Free Full Text].
-
Smith JC,
Butera RJ,
Koshiya N,
Del Negro C,
Wilson CG,
Johnson SM
(2000)
Respiratory rhythm generation in neonatal and adult mammals: the hybrid pacemaker-network model.
Respir Physiol
122:131-147[Web of Science][Medline].
-
Somjen GG
(2002)
Ion regulation in the brain: implications for pathophysiology.
The Neuroscientist
8:254-267.
-
Su CK
(2001)
Intraspinal amino acid neurotransmitter activities are involved in the generation of rhythmic sympathetic nerve discharge in newborn rat spinal cord.
Brain Res
904:112-125[Web of Science][Medline].
-
Su H,
Alroy G,
Kirson ED,
Yaari Y
(2001)
Extracellular calcium modulates persistent sodium current-dependent burst-firing in hippocampal pyramidal neurons
J Neurosci
21:4173-4182[Abstract/Free Full Text].
-
Telgkamp P,
Ramirez JM
(1999)
Differential response of respiratory nuclei to anoxia in rhythmic brainstem slices of mice.
J Neurophysiol
82:2163-2170[Abstract/Free Full Text].
-
Thoby-Brisson M,
Ramirez J-M
(2000)
Role of inspiratory pacemaker neurons in mediating the hypoxic response of the respiratory network in vitro.
J Neurosci
20:5858-5866[Abstract/Free Full Text].
-
Thoby-Brisson M,
Ramirez J-M
(2001)
Identification of two types of inspiratory pacemaker neurons in the isolated respiratory neural network of mice.
J Neurophysiol
86:104-112[Abstract/Free Full Text].
-
Traynelis SF,
Dingledine R
(1989)
Role of extracellular space in hyperosmotic suppression of potassium-induced electrographic seizures.
J Neurophysiol
61:927-938[Abstract/Free Full Text].
-
Xiong ZQ,
Stringer JL
(2000)
Sodium pump activity, not glial spatial buffering, clears potassium after epileptiform activity induced in the dentate gyrus.
J Neurophysiol
83:1443-1451[Abstract/Free Full Text].
Copyright © 2003 Society for Neuroscience 0270-6474/03/2383538-09$05.00/0
This article has been cited by other articles:
|
|
|
|
 
L. Ziskind-Conhaim, L. Wu, and E. P. Wiesner
Persistent Sodium Current Contributes to Induced Voltage Oscillations in Locomotor-Related Hb9 Interneurons in the Mouse Spinal Cord
J Neurophysiol,
October 1, 2008;
100(4):
2254 - 2264.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. K. Tryba, F. Pena, S. P. Lieske, J.-C. Viemari, M. Thoby-Brisson, and J.-M. Ramirez
Differential Modulation of Neural Network and Pacemaker Activity Underlying Eupnea and Sigh-Breathing Activities
J Neurophysiol,
May 1, 2008;
99(5):
2114 - 2125.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Ruangkittisakul, S. W. Schwarzacher, L. Secchia, Y. Ma, N. Bobocea, B. Y. Poon, G. D. Funk, and K. Ballanyi
Generation of Eupnea and Sighs by a Spatiochemically Organized Inspiratory Network
J. Neurosci.,
March 5, 2008;
28(10):
2447 - 2458.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Rebuttal from Ramirez
J Appl Physiol,
August 1, 2007;
103(2):
721 - 722.
[Full Text]
[PDF]
|
|
|
|
|
|
|
J.-M. Ramirez and A. Garcia III
Point:Counterpoint: Medullary pacemaker neurons are essential for both eupnea and gasping in mammals vs. medullary pacemaker neurons are essential for gasping, but not eupnea, in mammals
J Appl Physiol,
August 1, 2007;
103(2):
717 - 718.
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. K. Purvis, J. C. Smith, H. Koizumi, and R. J. Butera
Intrinsic Bursters Increase the Robustness of Rhythm Generation in an Excitatory Network
J Neurophysiol,
February 1, 2007;
97(2):
1515 - 1526.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J.-C. Viemari and J.-M. Ramirez
Norepinephrine Differentially Modulates Different Types of Respiratory Pacemaker and Nonpacemaker Neurons
J Neurophysiol,
April 1, 2006;
95(4):
2070 - 2082.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. K. Tryba, F. Pena, and J.-M. Ramirez
Gasping activity in vitro: a rhythm dependent on 5-HT2A receptors.
J. Neurosci.,
March 8, 2006;
26(10):
2623 - 2634.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. K. Tryba and J.-M. Ramirez
Hyperthermia Modulates Respiratory Pacemaker Bursting Properties
J Neurophysiol,
November 1, 2004;
92(5):
2844 - 2852.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
TOP
ABSTRACT
Introduction
