 |
 Previous Article | Next Article 
The Journal of Neuroscience, January 15, 2000, 20(2):529-541
A Molecular Link between Inward Rectification and Calcium
Permeability of Neuronal Nicotinic Acetylcholine  3 4 and 42
Receptors
Ali Pejmun
Haghighi and
Ellis
Cooper
Department of Physiology, McGill University, Montréal,
Québec, Canada H3G 1Y6
 |
ABSTRACT |
Many nicotinic acetylcholine receptors (nAChRs) expressed by
central neurons are located at presynaptic nerve terminals. These receptors have high calcium permeability and exhibit strong inward rectification, two important physiological features that enable them to
facilitate transmitter release. Previously, we showed that
intracellular polyamines act as gating molecules to block neuronal
nAChRs in a voltage-dependent manner, leading to inward rectification.
Our goal is to identify the structural determinants that underlie the
block by intracellular polyamines and govern calcium permeability of
neuronal nAChRs. We hypothesize that two ring-like collections of
negatively charged amino acids (cytoplasmic and intermediate rings)
near the intracellular mouth of the pore mediate the interaction with
intracellular polyamines and also influence calcium permeability. Using
site-directed mutagenesis and electrophysiology on
 4 2 and 34
receptors expressed in Xenopus oocytes, we observed that
removing the five negative charges of the cytoplasmic ring had little
effect on either inward rectification or calcium permeability. However,
partial removal of negative charges of the intermediate ring diminished
the high-affinity, voltage-dependent interaction between intracellular
polyamines and the receptor, abolishing inward rectification. In
addition, these nonrectifying mutant receptors showed a drastic
reduction in calcium permeability. Our results indicate that the
negatively charged glutamic acid residues at the intermediate ring form
both a high-affinity binding site for intracellular polyamines and a
selectivity filter for inflowing calcium ions; that is, a common site
links inward rectification and calcium permeability of neuronal nAChRs.
Physiologically, this molecular mechanism provides insight into how
presynaptic nAChRs act to influence transmitter release.
Key words:
nicotinic acetylcholine receptor; presynaptic receptors; transmitter release; ion permeation; gating particles
| |
INTRODUCTION |
A number of studies implicate
cholinergic nicotinic receptors in a wide variety of cognitive
functions, including visual and auditory processing, nociception, and
attention and memory mechanisms (Piciotto et al., 1995 ; Bannon et al.,
1998; Xiang et al., 1998; Marubio et al., 1999; Vetter et al., 1999).
Many neurons express nicotinic acetylcholine receptors (nAChRs) at
synapses; at some, nAChRs are located postsynaptically and mediate fast
excitatory synaptic transmission, whereas at many others, nAChRs are
located presynaptically and facilitate neurotransmitter release
(Clarke, 1993; MacDermott et al., 1999). Functionally, neuronal nAChRs have two properties that make them suitable to influence transmitter release: they have high calcium permeability (McGehee and Role, 1995),
and they inwardly rectify, that is, they conduct inward currents at
negative potentials but do not conduct outward currents at positive
potentials (Mathie et al., 1990; Sands and Barish, 1992; Ifune and
Steinbach, 1993). Inward rectification provides an important mechanism
to ensure that the receptors do not short circuit the action potential
in the nerve terminal and reduce transmitter release.
That muscle nAChRs have relatively low permeability to calcium (Lewis,
1979; Adams et al., 1980) and do not show inward rectification suggests
that calcium permeability and inward rectification go hand in hand for
nAChRs. Interestingly, this relationship also holds for subtypes of
glutamate receptors: AMPA/kainate receptors that have low calcium
permeability show little inward rectification, whereas those that have
high calcium permeability show strong inward rectification (Hume et
al., 1991; Verdoorn et al., 1991; Dingledine et al., 1999). It is not
fortuitous that these two properties correlate for AMPA/kainate
receptors because the same structural determinant affects both
properties. The purpose of this study is to determine the structural
element or elements of neuronal nAChRs that influence calcium
permeability and inward rectification.
Nicotinic AChRs have three ring-like collections of charged residues on
either side of the pore (extracellular, cytoplasmic, and intermediate
rings) that influence ion conduction; the intermediate ring is located
at the narrowest region, or gate, of the pore and affects ion
selectivity (Imoto et al., 1988; Cooper et al., 1991; Konno et al.,
1991; Galzi et al., 1992; Bertrand et al., 1993; Wilson and Karlin,
1998). Previously, we demonstrated that inward rectification of
neuronal nAChRs, like glutamate receptors, results from a
voltage-dependent block of the receptor pore by intracellular
polyamines (Haghighi and Cooper, 1998a). Our hypothesis is that the
cytoplasmic and intermediate rings form the site of interaction for
intracellular polyamines.
To test this hypothesis, we use a combined approach of site-directed
mutagenesis of neuronal nAChR subunit cDNAs and two-electrode voltage-clamp and patch-clamp techniques on recombinant receptors expressed in Xenopus oocytes. Our results indicate that the
negatively charged residues at the intermediate ring are essential for
the interaction of polyamines with 42 and 34 neuronal
nAChRs. Furthermore, we show that these negatively charged residues
influence the calcium selectivity of the pore, indicating that a common structural element governs both inward rectification and calcium permeability of neuronal nAChRs.
Some of our results have been presented previously (Haghighi and
Cooper, 1998b).
| |
MATERIALS AND METHODS |
Site-directed mutagenesis
We designed two complementary oligonucleotide primers containing
the substituted nucleotide or nucleotides corresponding to amino acids
at the cytoplasmic or intermediate ring of 3, 4, and 4 nAChR
subunits, and used the Quick-Change Site-Directed Mutagenesis kit
(Stratagene, La Jolla, CA) to mutate each subunit. Rat 3 and 4
cDNAs were cloned into the pCDNA1 expression vector (Invitrogen, San
Diego, CA), and chick 4 and 2 (gifts from Dr. M. Ballivet,
University of Geneva) were cloned into derivatives of pSV2.cat
expression vectors (Cooper et al., 1991). For each reaction, we mixed
5-50 ng of the wild-type plasmid and 125 ng of each of the two primers
in a solution containing 5 µl of 10× reaction buffer (Stratagene), 1 µl of dNTP mix (Stratagene), and 1 µl of pfu DNA polymerase (2.5 U/ml; Stratagene), diluted with double-distilled water to a final
volume of 50 µl. The reaction mixture was then cycled in a PCR
apparatus (PTC-100; MJ Research) according to the following protocol: 1 cycle at 95°C for 30 sec followed by 12-18 cycles at 95°C for 30 sec, 55°C for 1 min, and 68°C for 2 min. The following amino acids
were mutated: 3: aspartic acid (D) at position 237 to alanine (A)
(3D237A), glutamic acid (E) at position 240 to
alanine (3E240A), glutamine (Q)
(3E240Q) or aspartic acid (D)
(3E240D); 4: glutamic acid (E) at position 242 to alanine (4E242A) and glutamic acid at
position 245 to alanine (4E245A); 4:
aspartic acid at position 236 to alanine (4D236A) and glutamic acid at position 239 to
alanine (4E239A). All mutations were verified
by sequencing.
Expression of nAChR subunit cDNAs in oocytes
Xenopus oocytes were defolliculated and prepared as
described by Bertrand et al. (1991). We injected 1-3 ng of pairwise
combinations of cDNAs coding for neuronal nAChR subunits or 3-6 ng of
pairwise mutant 4 and 2 or 3 and 4 into the nucleus of
oocytes. This difference in the amount of cDNA injection was to achieve
sufficient levels of expression for the mutant receptors. Oocytes were
incubated at 19°C for 2-7 d before recording. For single-channel
experiments, the vitelline membrane surrounding the oocytes was removed.
Injection of BAPTA and spermine into the oocytes
To avoid the activation of the endogenous
Ca2+-activated
Cl currents in the presence of
extracellular Ca2+, we injected oocytes
2-10 min before recording with BAPTA. The injection solution contained
100 mM BAPTA with 85 mM
Na+, 2.5 mM
K+, and 10 mM HEPES adjusted
to pH 7.4 with NaOH. We injected between 30 and 60 nl of this solution
into oocytes, which corresponds to a concentration of ~5-7
mM in the oocytes.
To examine the effect of the increase in the intracellular
concentration of spermine on the wild-type and mutant neuronal nAChRs,
we injected oocytes with 60 nl of a solution containing (in mM):
100 spermine, 100 BAPTA, 85 Na+, 2.5 K+, and 10 HEPES adjusted to pH 7.4. In
some recordings a third electrode was used to inject spermine into the
oocytes while under two-electrode clamp. In all spermine injection
experiments, removal of Ca-activated Cl
currents was used as an indication of successful injection.
Neuronal and myotube cultures
Superior cervical ganglia (SCGs) were dissected from
neonatal Sprague Dawley rats (Charles River) and dissociated
mechanically and enzymatically as previously described (McFarlane and
Cooper, 1992). Briefly, the ganglia were dissected under sterile
conditions from animals killed by cervical dislocation. The
ganglia were dissociated at 37°C in collagenase (1 mg/ml, type I;
Sigma, St. Louis, MO) for 15 min followed by dispase (2.4 mg/ml, grade
II; Boehringer Mannheim, Indianapolis, IN) for 2-3 hr. Dissociated neurons were washed with L-15 medium supplemented with 10% horse serum
and plated onto laminin-coated (40 µg/ml, overnight at 4°C; gift of
Dr. S. Carbonetto, McGill University) Aclar coverslips (Allied
Chemicals, Clifton, NJ) in modified Petri dishes. The neurons were
incubated in 1.5 ml of L-15 medium supplemented with 5% rat serum,
vitamins, cofactors, penicillin, streptomycin, and sodium bicarbonate
as described previously (Hawrot and Patterson, 1979). The media was
supplemented with nerve growth factor.
We used a similar method to isolate neonatal rat myoblasts. Briefly, we
dissected strips of pectoral muscles from neonatal rats and dissociated
them in collagenase (1 mg/ml) for 15 min at 37°C. Myoblasts were
incubated in 1.5 ml of L-15 medium supplemented with 10% fetal calf
serum. Myoblasts fused to form multinucleated myotubes 2-4 d after
plating. All cultures were maintained at 37°C in a humidified
incubator with an atmosphere of 5% CO2 and 95% air.
Electrophysiology
Whole-cell recordings from oocytes. To measure the
macroscopic ACh-evoked currents in oocytes, we used the two-electrode
voltage-clamp technique (Bertrand et al., 1991). These experiments were
performed at room temperature (22-24°C) using a standard
voltage-clamp amplifier (built by Mr. A. Sherman, McGill University).
During the recordings, oocytes were superfused with control perfusion
solution or agonist solutions at 10-20 ml/min; switching from one
solution to another was done manually. Recording electrodes had tip
diameters of 10-15 µm and were filled with 3 M KCl. All
mutant receptors, 3D237A4, 34D236A,
3D237A4D236A,
3E240A4,
3E240Q4,
3E240D4,
34E239A, 4E242A2 and
4E245A2, produced ACh-evoked currents when
expressed in Xenopus oocytes. For equimolar injections of
cDNAs, inward currents at  90 mV were on average 8-12 times smaller
for the intermediate mutant receptors or 2-3 times smaller for the
cytoplasmic mutant receptors compared to those for the wild-type
receptors. The half-maximal concentration (EC50)
for ACh was not significantly different among the mutant and wild-type receptors.
To measure the current voltage (I-V) relationships,
we used a voltage ramp protocol applied within 2-4 sec after the
inward current had reached its maximum amplitude; the speed of the ramp was 333 mV/sec. Voltage ramps were applied for 360-600 msec
(corresponding to 120-200 mV), during which time no significant
desensitization was observed. I-V curves were also obtained
by measuring the ACh-evoked currents at different membrane potentials
(steady-state I-V curves). Both current and voltage traces
were monitored and stored for analysis. Currents were sampled at
100-350 Hz on-line with a Pentium personal computer (PC) (running at
60 MHz and an analog-to-digital card; Omega, Stamford, CT). The
program PATCHKIT (Alembic Software, Montreal, Québec, Canada) was
used for stimulation and data acquisition.
External perfusion solution contained (in mM): 96 NaCl, 2 KCl, 1 Na2H2PO4,
1 BaCl2, and 10 HEPES, and 1 µM
atropine; pH was adjusted with NaOH to 7.4-7.5. For
Ca2+ permeability measurements, we used a
control solution containing 1 mM
CaCl2 instead of BaCl2 and
compared the reversal potential change when we switched to a solution
of either (in mM) 100 CaCl2; 10 CaCl2 and 90 NaCl; 25 CaCl2
and 75 NaCl; or 50 CaCl2 and 50 NaCl. All
solutions were buffered by 10 mM HEPES and NaOH to a pH of
7.4-7.5 and contained 1 µM atropine. Spermine (Sigma)
was added to the control solution containing 1 mM
BaCl2 where indicated. Spermine was dissolved in
sterile water, and aliquots were kept frozen at 20°C.
Single-channel recordings from oocytes. Only oocytes that
gave rise to large inward currents (>1 µA in response to 1 µM ACh for 42 expressing oocytes or in response 10 µM ACh for 34 expressing oocytes when
voltage-clamped at 40 mV) were used for single-channel recordings.
Outside-out recordings were performed using a List EPC-7 amplifier at
room temperature (22-24°C) (Hamill et al., 1981). Pipette resistance
ranged from 5 to 10 M for outside-out recordings, and electrodes
were coated with Sylgard (Dow Corning). Recordings were obtained in the
continuous presence of ACh (0.1-0.2 µM for 42
receptors and 1-10 µM for 34) in the recording
bath. ACh-evoked single-channel activity gradually diminished after excision of the patch (in 2-5 min). Signals were digitized with a
pulse code modulation (501; Sony, Tokyo, Japan) and stored on videocassette recorder tapes. For off-line analysis, stored signals were filtered at 1.5-2 kHz with an 8-pole Bessel filter (Frequency Devices) and sampled at 10 kHz using a Pentium-60 PC. The program PATCHKIT was used for stimulation and data acquisition.
External solution contained (in mM): 100 KCl, 1 CaCl2, and 10 HEPES, and 1 µM
atropine, and pH was 7.4 adjusted with KOH. Recording electrodes
contained (in mM): 80 KF, 20 potassium acetate, 10 HEPES,
and 10 EGTA, and pH was adjusted to 7.4 with KOH. Spermine was added to
the intracellular solution where indicated.
Whole-cell recordings from rat SCG neurons and cultured
myotubes. Whole-cell patch-clamp recordings were performed at room temperature (22-24°C) using a List EPC-7 amplifier (Hamill et al.,
1981). Throughout the recordings, cells were perfused with the external
solution at a rate of 1 ml/min. ACh was applied by pressure ejection
from pipettes with tip diameters of 20-30 µm (Mandelzys et al.,
1995). The resistance of patch pipettes ranged from 2 to 6 M, and
50-80% of the series resistance was compensated. For experiments with
muscle nAChRs, we chose small multinucleated myotubes that had grown
for 2-4 d in culture.
Both steady-state and ramp I-V curves were obtained for
ACh-evoked macroscopic currents recorded from myotubes and SCG neurons. The speed of the voltage ramp protocol was 200-1000 mV/sec; voltage ramps were applied 600 msec after the application of ACh and lasted for
120-600 msec, during which time no significant desensitization was
observed. Both current and voltage were monitored during the recordings
and stored for analysis. Currents were filtered at 1.5 kHz with an
8-pole Bessel filter, sampled at 2.5-5 kHz, displayed and stored
on-line with a Pentium-60 PC. The program PATCHKIT was used for
stimulation and data acquisition.
External perfusion solution contained (in mM): 140 NaCl,
5.4 KCl, 0.33 NaH2PO4, 0.44 KH2PO4, 2.8 CaCl2, 10 HEPES, 5.6 glucose, and 2 glutamine,
and 0.5-1 µM TTX (Sigma) and 1 µM
atropine; pH was adjusted to 7.4. Acetylcholine iodide (Ach; Sigma) was
dissolved in the same external perfusion solution (100 µM
for SCG neurons and 20 µM for myotubes). Recording
electrodes were filled with intracellular solution containing (in
mM): 70 KF, 65 potassium acetate, 5 NaCl, 1 MgCl2, 10 EGTA, and 10 HEPES; pH was 7.4, adjusted with KOH.
Analysis
Whole-cell ACh-evoked I-V curves were obtained by
subtracting the current in response to a ramp voltage change in the
absence of agonist from that in the presence of agonist (Haghighi and Cooper, 1998a). The G-V curves were obtained by plotting
the cord conductance against voltage. The cord conductance was
calculated according to the following equation:
|
(1)
|
where G is the cord conductance corresponding to each
membrane potential (Vm), I
is the ACh-evoked current at the corresponding Vm, and
Erev is the reversal potential.
To measure the amplitude of single-channel currents, we used either
all-points histograms of open and closed distributions or measured the
amplitude of the channel openings individually using PATCHKIT.
Histograms were fit by Gaussian curves using Origin 4.1 graphics
software (Microcal Software).
To quantify the voltage-dependent block by intracellular spermine, we
fit the single-channel G-V relationships to a derivation of
the Woodhull (1973) equation (Johnson and Ascher, 1990; Haghighi and
Cooper, 1998a):
![G/G<SUB><UP>max</UP></SUB>=1/{1+[S]/K<SUB><UP>d</UP></SUB>},](/content/vol20/issue2/fulltext/529/img002.gif)
|
(2)
|
where
and G is the conductance in the presence of spermine
at any given Vm,
Gmax is the maximum unblocked
conductance, [S] is the internal concentration of spermine for
outside-out patches or is the equivalent free intracellular polyamine
concentration needed to produce macroscopic rectification,
Kd is the dissociation constant at a
given Vm,
Kd(0) is the dissociation constant at
0 mV, z is the valence of spermine,  is the
fraction of the membrane electric field sensed by spermine, and
F, R, and T have their usual meanings. To estimate the intracellular concentration of spermine, we fit the
macroscopic G-V curves to Equation 2 using the
Kd(0) and measured from the
single-channel experiments.
To measure the effect of increasing intracellular spermine, we fit the
macroscopic G-V curves to the Boltzmann equation:
|
(3)
|
where V1/2 is the membrane
potential at which conductance (G) has reduced to
half of the maximum conductance (Gmax)
and k is a slope factor corresponding to the amount of
depolarization needed to change the conductance e-fold.
Dose-response curves for the effect of extracellular spermine were fit
to a derivation of the logistic equation:
![I/I<SUB><UP>max</UP></SUB>=1/{1+(<UP>IC</UP><SUB>50</SUB>/[S])},](/content/vol20/issue2/fulltext/529/img005.gif)
|
(4)
|
where IC50 is the half-maximal
inhibition dose, and [S] is the external concentration of spermine.
To calculate PCa/PNa, we
measured the reversal potential of the I-V curves in
external solutions containing different amounts of
Ca2+ and used these values in a derivation
of the Goldman, Hodgkin, and Katz (GHK) constant field voltage
equation as presented by Lewis (1979):
![E<SUB><UP>rev</UP>(<UP>Ca</UP>)</SUB>−E<SUB><UP>rev</UP>(<UP>Na</UP>)</SUB>=RT/F <UP>ln</UP>{([Na]<SUB><UP>o</UP></SUB>+P<SUB><UP>K</UP></SUB>/P<SUB><UP>Na</UP></SUB>[K]<SUB><UP>o</UP></SUB>+4P′<SUB><UP>Ca</UP></SUB>/P<SUB><UP>Na</UP></SUB>[Ca]<SUB><UP>o</UP></SUB>)/](/content/vol20/issue2/fulltext/529/img006.gif)
|
(5)
|
where
and PX is the permeability
coefficient of ion X,
[X]o is the extracellular
concentration of ionic specie X, and R,
T and F have their usual meanings. Concentration
of each ion was multiplied by its corresponding activity coefficient
(Robinson and Stokes, 1960; Butler, 1968), and
PK/PNa
was 1.2 (our unpublished observations). I-V curves were fit
to a ninth order polynomial function, and reversal potentials were
measured by eye. We compensated for junction potentials caused by
switching between different solutions.
The best fit to the data were achieved by minimizing
 2 using a routine from Origin 4.1 graphics software that is based on a Levenberg-Marquardt
algorithm. All data points are presented as mean ± SEM.
Statistical significance between values was examined using a paired
Student's t test.
| |
RESULTS |
Figure 1 highlights the difference
in inward rectification among nAChR subtypes. Figure
1A shows the ACh-evoked whole-cell current-voltage
(I-V) relationship for native nAChRs expressed by
neonatal rat sympathetic neurons from the SCG; these receptors showed
strong inward rectification. Figure 1B shows the
corresponding ACh-evoked I-V curve for native nAChRs
expressed by neonatal rat myotubes. In contrast to nAChRs on SCG
neurons, these muscle nAChRs showed little inward rectification.
View larger version (21K):
[in this window]
[in a new window]
|
Figure 1.
Inward rectification of neuronal nAChRs.
A shows the ACh-evoked macroscopic current-voltage
relationship (I-V curve) recorded from a neonatal rat
SCG neuron. Whole-cell currents were recorded while the membrane
potential was ramped from 80 to +60 mV (333 mV/sec). The
I-V curve was obtained by subtracting the control
current from the current evoked by 100 µM ACh. The
I-V curve is fitted to a ninth order polynomial
function and shows strong inward rectification. B shows
the ACh-evoked macroscopic I-V curve recorded from a
rat myotube (Ach, 20 µM). In contrast to
A, this I-V curve shows no inward
rectification. C shows a macroscopic ACh-evoked
I-V curve for 42 neuronal nAChR, and
D shows a macroscopic ACh-evoked I-V
curve for 34 neuronal nAChR expressed in Xenopus
oocytes. Similar to native nAChRs on SCG neurons, these recombinant
receptors exhibit strong inward rectification. E and
F show single-channel records obtained from outside-out
patches expressing 42 or 34 receptors, respectively. In
control patches, inward rectification of these receptors is lost.
Addition of spermine (20 µM for 42 and 50 µM for 34) to the patch electrode blocks outward
currents at positive potentials and reduces the amplitude of inward
currents.
|
|
To further investigate the inward rectification of neuronal nAChRs, we
studied recombinant receptors in Xenopus oocytes. Figure 1,
C and D, shows I-V curves for two
neuronal nAChR subtypes: 42 receptors (Fig. 1C), made
up of two subunits widely expressed in the CNS (Wada et al., 1989;
Sargent, 1993; McGehee and Role, 1995), and 34 receptors (Fig.
1D), made up of two subunits highly expressed in
peripheral autonomic neurons (Boyd et al., 1988; Couturier et al.,
1990; Mandelzys et al., 1994). Similar to nAChRs on SCG neurons, the
ACh-evoked I-V curves for both 42 and 34 receptor exhibited strong inward rectification.
Previously, we demonstrated that the strong inward rectification of
42 receptors results from a voltage-dependent block of the
receptor pore by intracellular polyamines (Haghighi and Cooper, 1998a).
A similar mechanism holds true for 34 receptors. Figure 1,
E and F, show examples from single-channel
experiments on 42 and 34 measured in outside-out patches;
at positive potentials (Vm), spermine
blocked the outward current from both these receptors when applied from
the intracellular side. To determine the affinity of 34 receptors
for polyamines, we repeated these single-channel experiments with four
different spermine concentrations ranging from 0.1 to 100 µM on at least three different patches for each
concentration and used a Woodhull (1973) model (see Materials and
Methods and Haghighi and Cooper, 1998a) to analyze this
voltage-dependent block (data not shown). From these experiments, we
determined that the affinity of 34 receptors for spermine at 0 mV
(K d(0)) was 6.7 ± 0.5 µM, approximately twofold higher than
Kd(0) for 42 receptors (3.6 µM) (Haghighi and Cooper, 1998a); however, the
proportion of the membrane field sensed by spermine (, 50-55%) was
the same for both receptor types.
We were interested to determine the site of interaction between
intracellular polyamines and neuronal nAChRs. Because polyamines are
highly positively charged, a likely site for the interaction between
neuronal nAChRs and intracellular polyamines is the negatively charged
region at the cytoplasmic side of the channel pore between M1 and M2.
Figure 2 shows an amino acid alignment of
this region for the four neuronal nAChR subunits: 3, 4, 2, and
4. The region between M1 and M2 contains five amino acids, two of
which are negatively charged and are in homologous positions for each subunit. The location of the five glutamic acids (E),
corresponding to position 240 for 3, has been referred to as the
intermediate ring, and the site of the negatively charged aspartic acid
residues (D) (3, 2, and 4) or E
(4) closer to M1 has been referred to as the cytoplasmic ring (Imoto
et al., 1988; Galzi et al., 1991; Karlin and Akabas, 1995). We
hypothesized that these negatively charged residues form the site of
interaction for the positively charged polyamines. To test this, we
mutated these residues to neutral amino acids, using site-directed
mutagenesis, and examined the functional properties of these mutant
receptors expressed in Xenopus oocytes.
View larger version (14K):
[in this window]
[in a new window]
|
Figure 2.
Charged amino acids flanking the pore region are
conserved in neuronal nAChRs subunits. This figure shows the amino acid
sequence alignment of neuronal nAChR subunits 3, 4, 2, and
4 for the cytoplasmic end of M1, M1-M2 loop, M2 segment, and part
of the M2-M3 loop. This alignment shows the presence of three
ring-like accumulations of charged residues flanking M2: the
cytoplasmic ring (corresponding to 3D237), the intermediate ring
(corresponding to 3D240), and the extracellular ring (corresponding
to 3E261).
|
|
Cytoplasmic ring mutations have little effect on
inward rectification
First, we investigated the role of the cytoplasmic ring on the
rectification of 34 receptors by mutating the D at this site to
alanine (A) for both 3 and 4 subunits; we refer
to these mutant subunits as 3D237A and
4D236A, respectively. We coexpressed pairwise
combinations of mutant and wild-type 3 and 4 cDNAs in
Xenopus oocytes to produce three different receptors:
3D237A4, 34D236A, and
3D237A4D236A.
For each receptor, we obtained the macroscopic ACh-evoked
I-V curve. To quantify the rectification, we measured the
relative conductance at four membrane potentials, 40 mV, +20 mV, +40
mV, and +80 mV to that at 90 mV. For
3D237A4 or
34D236A receptors, we observed no
significant difference in rectification compared to that for wild-type
34 receptors (Fig. 3A,
Table 1). The I-V curves for
3D237A4D236A
receptors also showed strong inward rectification up to +20 mV (Fig.
3B); however, at Vm greater
than +25 mV, we observed significantly more outward current compared to
wild-type 34 receptors. The conductance at +40 mV and that at +80
mV for 3D237A4D236A
receptors were approximately 12 times greater than those for wild-type
34 receptors at these potentials.
View larger version (20K):
[in this window]
[in a new window]
|
Figure 3.
Substitution of negatively charged residues of the
intermediate ring abolishes inward-rectification of neuronal nAChRs.
A shows an ACh-evoked macroscopic I-V
curve obtained from an oocyte expressing the cytoplasmic ring mutant
receptor 34D236A. This mutant receptor exhibits
inward rectification similar to the wild type 34 receptor.
B shows an ACh-evoked macroscopic I-V
curve obtained from an oocyte expressing the cytoplasmic ring mutant
receptor 3D237A4D236A.
C-F show ACh-evoked macroscopic I-V
curves obtained from oocytes expressing intermediate ring mutant
receptors 34E239A, 3E240A4,
3E240Q4, or 4E245A2. All four
mutant receptors show a nearly linear ACh-evoked I-V
relationship from 90 to +80 mV. Insets in each figure
show ACh-evoked currents in response to a voltage ramp and demonstrate
that the ACh-evoked currents do not show any significant
desensitization. For all insets the length of the trace
is 6 sec.
|
|
View this table:
[in this window]
[in a new window]
|
Table 1.
The effect of mutations in the cytoplasmic and the
intermediate ring on the macroscopic inward rectification and
Ca2+ permeability of 42 and 34 nAChRs
|
|
In addition to 34 receptors, we investigated the role of the
cytoplasmic ring on the rectification of 42 receptors. We mutated
the E at 240 to A for 4 (4E242A) and
coexpressed 4E242A with wild-type 2 in
Xenopus oocytes. We observed no significant difference in
the ACh-evoked I-V curves for
4E242A2 receptor compared to that for
wild-type 42 receptors (Table 1).
Removal of negative charges at the intermediate ring abolishes
inward rectification
Next, we investigated the role of the intermediate ring on the
rectification of 34 receptors by mutating the E to A for both
3 and 4 subunits; we refer to these mutant subunits as 3E240A and 4E239A,
respectively. We coexpressed these mutant subunits with wild-type 3
and 4 in Xenopus oocytes to produce either
34E239A or
3E240A4 receptors.
These mutations in the intermediate ring had a dramatic effect on
inward rectification. Figure 3C shows a result from an
oocyte expressing 34E239A receptors. In
contrast to wild-type 34 receptors, the ACh-evoked
I-V curve for 34E239A receptors
was virtually linear (Fig. 3C); the ACh-evoked current
reversed at approximately 10 mV (Fig. 3C), and our ion
substitution experiments indicated that this current was carried
exclusively by cations (data not shown). We obtained similar results
from >30 oocytes expressing 34E239A
receptors. We measured the relative conductance at 40 mV, +20 mV, +40
mV, and +80 mV to that at 90 mV (Table 1); we observed no significant
difference in conductance at each potential (Table 1). The conductance
at +40 mV was 93% of that at 90 mV, ~100 times greater than that
of wild-type 34 receptors.
Our results with 34E239A receptors indicate
that removal of the negative charge in the intermediate ring of 4
abolishes the strong inward rectification of 34 receptors. To
determine the effect of a similar mutation in the 3 subunit, we
examined the rectification properties of
3E240A4 receptors. The ACh-evoked I-V curve for 3E240A4 receptors
was almost linear, and the current reversed at approximately 10 mV
(Fig. 3D). The conductance at +40 mV was 79% of that at
90 mV, ~85 times greater than that of wild-type 34 receptors
(Table 1). These results indicate that removal of the negative charge
in the intermediate ring of the subunit is sufficient to abolish
the strong inward rectification of 34 receptors.
To test the effect of different amino acid side chains at the
intermediate ring on rectification, we mutated E at 240 to glutamine (Q) or aspartic acid (D) in 3 and coexpressed it with wild-type 4. The ACh-evoked I-V curves recorded from
3E240Q4 receptors were essentially linear
and not significantly different from those of
3E240A4 receptors (Fig. 3E;
Table 1). This demonstrates that neutral amino acid substitution at the
intermediate ring abolishes inward rectification regardless of the
side-chain size. On the other hand, 3E240D4
receptors inwardly rectified, although not as strong as wild-type
34 receptors (Table 1), indicating that the size of the
negatively charged side chain influences the degree of rectification.
In addition, to test whether this effect on the rectification was
specific to 34 receptors, we mutated E at the intermediate ring
to A in the 4 subunit and coexpressed it with wild-type 2 in
Xenopus oocytes. As shown in Figure 3F, these
4E245A2 receptors had almost linear
I-V curves reversing at approximately 10 mV. The
conductance at +40 mV was 79% of that at 90 mV, and ~90 times
greater than that of wild-type 42 receptors (Table 1). These
results demonstrate that, like 34 receptors, partial removal of
negatively charged residues in the intermediate ring abolishes strong
inward rectification of 42 receptors.
Elevated intracellular spermine increased inward rectification of
42 and 34 receptors, but had no effect on nonrectifying
4E245A2 and 3E240A4 receptors
Our results on intermediate ring mutations suggest that a decrease
in the net negative charge of the intermediate ring abolishes the
interaction of intracellular polyamines with neuronal nAChRs. To
further investigate this possibility, we examined the effects of
increasing the intracellular spermine concentration in
Xenopus oocytes expressing either 42, 34,
4E245A2, or
3E240A4 receptors. For most experiments,
first we recorded the ACh-evoked I-V curve, then we
injected the oocytes with spermine and repeated the I-V
measurements at 2-3 min intervals. To verify that our injections
worked, we included BAPTA along with spermine; in all injected oocytes,
BAPTA abolished calcium-activated chloride currents when we recorded
the ACh-evoked current with 1 mM
Ca2+ as the only divalent cation in the
extracellular solution (see Materials and Methods). Alone, BAPTA had no
effect on inward rectification of wild-type or mutant receptors.
For ACh-evoked currents from Xenopus oocytes expressing
wild-type 42 or 34 receptors, we observed that
intracellular injections of spermine caused a progressive increase in
rectification, producing its maximal effect in ~10 min. Figure
4 shows example I-V curves from 42 (Fig. 4A) and 34 (Fig.
4D) receptors before and after spermine injection.
Increasing intracellular spermine caused a significant leftward shift
in the ACh-evoked I-V and G-V curves, without
affecting the ACh-evoked current amplitude at 90 mV or the reversal
potential (Fig. 4). To quantify the effect of increasing intracellular
spermine, we fit the G-V curves to a Boltzmann equation (Eq. 3, see Materials and Methods) and determined
V1/2, the
Vm where G was reduced to
50% of Gmax, and k, the
amount of depolarization needed to change the conductance e-fold. For
42, V1/2 was shifted to left by
16 ± 1.3 mV after spermine injection and for 34, V1/2 was shifted to the left by
19 ± 2.4 mV; k decreased from 14.5 ± 1.2 to
12 ± 1.5 mV for both 42 and 34.
View larger version (26K):
[in this window]
[in a new window]
|
Figure 4.
Effect of increasing intracellular spermine.
A shows macroscopic ACh-evoked I-V
curves obtained from 42 receptors expressed in
Xenopus oocytes. I-V curves were
obtained before and 3 and 10 min after injecting 60 nl of a solution
containing 100 mM spermine into the oocytes.
B shows the G-V curves corresponding to
the I-V curves in A. The solid
lines are fits to the G-V curves using the
Woodhull equation. The leftward shift in the G-V curve
corresponds to an ~10-fold increase in intracellular spermine
concentration. C shows macroscopic ACh-evoked
I-V curves before and after injection of spermine
recorded from an oocyte expressing 4E245A2 receptors.
There was no significant difference between the I-V
curves before and after injection of spermine. D and
E show the I-V and G-V
curves from an oocyte expressing 34 receptors before and after
injection with 60 nl of a solution containing 100 mM
spermine. The solid lines are fits to the
G-V curves using the Woodhull equation. The leftward
shift in the G-V curve corresponds to an ~15-fold
increase in intracellular spermine concentration. F
shows the I-V curves for 3E240A4
receptors before and after spermine injection. Similar to
4E245A2 receptors, there was no significant
difference between the I-V curves before and after
injection of spermine.
|
|
To estimate the concentration of free spermine in oocytes after
injection, we used the Woodhull equation (Eq. 2, see Materials and
Methods). Using values for kd(0) and
for 42 (Haghighi and Cooper, 1998a) and 34 (Fig. 1), we
solved the Woodhull equation to estimate the equivalent free
intracellular polyamine concentration (see Materials and Methods) [S]
that best described the macroscopic G-V curves. The solid
lines in Figure 4, B and E, represents the best
fits to the Woodhull equation. Before spermine injections, [S] ranged
from 70 to 80 µM in different oocytes
(75.6 ± 1.6 µM; n = 37).
For the oocyte expressing 42 receptors shown in Figure 4B, injecting spermine increased [S] ~10-fold;
for the oocyte expressing of 34 receptors shown in Figure
4E, spermine injection increased [S] by ~15-fold.
On average, spermine injection increased [S] by 10.1 ± 1.7-fold
(n = 19). These results indicate that raising free
intracellular spermine levels leads to stronger inward rectification of
42 and 34 receptors, providing further evidence that inward rectification of neuronal nAChRs results from a voltage-dependent block
by intracellular spermine (Haghighi and Cooper, 1998a).
Next, we investigated whether increased intracellular free spermine
would be sufficient to confer inward rectification to ACh-evoked
currents for the intermediate ring mutant receptors. Figure 4 shows
example I-V curves for 4E245A2
(Fig. 4C) and 3E240A4 (Fig.
4F) receptors before and after spermine injection. Increasing intracellular spermine caused no significant shift in the
ACh-evoked I-V or G-V curves for either
receptor. Furthermore, increasing intracellular spermine had no effect
on the ACh-evoked current amplitudes or the reversal potential (Fig.
4C,F). We observed similar results from 26 of 26 oocytes. These results suggest that the reduction in the net negative
charge at the intermediate ring dramatically decreases the affinity of
intracellular polyamines for the receptor.
Extracellular spermine blocks nonrectifying
mutant receptors
To determine whether the intermediate ring mutations
affected polyamine permeability, we performed ion substitution
experiments. We expressed 4E245A2 receptors
in Xenopus oocytes and then measured ACh-evoked currents in
the extracellular solution containing different concentrations of
spermine. With spermine as the only conducting ion in the extracellular
solution, this mutant receptor failed to produce detectable ACh-evoked
currents, even at 120 mV holding potential (data not shown). With an
extracellular solution containing 90 mM
Na+ and 10 mM
spermine, we found that spermine blocked >95% of the ACh-evoked
current without affecting the reversal potential. We found that the
block by extracellular spermine had little voltage dependence and
reversed relatively slowly (~80% in 3-5 min). These results suggest
that spermine has negligible permeability through 4E245A2 receptors. To examine the block by
extracellular spermine, we measured ACh-evoked currents at 3 min
intervals after coapplication of 1 µM ACh with
increasing concentrations of spermine. Figure 5A shows the spermine
inhibition curves for 42 and 4E245A2 receptors; by first approximation, these curves can be described by a logistic equation (Eq. 4). From the spermine inhibition curves, we
obtained the IC50 for mutant
4E245A2 receptors (62.3 ± 13.3 µM; n = 6) and wild-type
42 receptors (42.8 ± 5.7 µM;
n = 8), which were not significantly different
(p > 0.05).
View larger version (14K):
[in this window]
[in a new window]
|
Figure 5.
Extracellular spermine blocks nonrectifying mutant
receptors. A shows the dose inhibition curves for the
effect of extracellular spermine on 42 and
4E245A2, and B shows the dose
inhibition curves for 34 and 3E240A4. Data
points were fitted to a logistic equation (see Materials and Methods).
There is no significant difference in the block by extracellular
spermine for all four receptors.
|
|
We repeated these measurements on wild-type 34 receptors and
mutant 3E240A4 (Fig. 5B). We
observed no significant difference in the spermine inhibition curves
between wild-type 34 (IC50 = 45.1 ± 7.2 µM; n = 5) and mutant
3E240A4 receptors
(IC50 = 65.4 ± 12.3 µM; n = 5) (Fig.
5B). We observed similar block by extracellular spermine for
3E240Q4 and
34E239A (data not shown). The
cytoplasmic ring mutant,
3D237A4D236A, was
also blocked by extracellular spermine in a similar manner
(IC50 = 43.8 ± 4.9 µM; n = 5; data not shown).
These results indicate that mutations in the intermediate ring that
abolish inward rectification have little effect on the block by
extracellular spermine.
Relative calcium permeability
The Ca2+ to
Na+ permeability ratios
(PCa/PNa) for neuronal
nAChRs have been reported to range from 0.7 to 10 depending on the subunit composition of the receptors (Sands and Barish, 1991; Adams and
Nutter, 1992; Trouslard et al., 1993; Bertrand et al., 1993). Because
the intermediate ring has been shown to influence permeability of
cations (Konno et al., 1991; Galzi et al., 1992; Corringer et al.,
1999), we compared PCa/PNa
among wild-type and mutant 42 and 34 receptors expressed in
Xenopus oocytes. To avoid contaminating ACh-evoked currents
with the endogenous Ca2+-activated
chloride currents in these cells (Miledi and Parker, 1984), we injected
oocytes with BAPTA before our electrophysiological measurements (see
Materials and Methods). In Figure
6A, we recorded the
ACh-evoked I-V curve from 34 receptors in control
external solution (98 mM
Na+, 2 mM
K+, and 1 mM
Ca2+) and repeated the measurement in a
solution containing equimolar Ca2+. In 100 mM Ca2+, we observed
a rightward shift in the reversal potential of 3.6 mV. From the
modified GHK equation (Eq. 5; Lewis, 1979; see Materials and Methods),
we obtained an average
PCa/PNa of 0.78 ± 0.02 for 34 receptors (n = 8) (Table 1). We
repeated these experiments with external solutions of either 10 mM Ca2+ and 90 mM Na+, 25 mM Ca2+ and 75 mM Na+, or 50 mM Ca2+ and 50 mM Na+. We found
that PCa/PNa for 34
in all three solutions (n = 4 at each concentration)
was not significantly different from that when we made equimolar
substitutions of Na+ and
K+ with Ca2+.
We observed a significant reduction of ACh-evoked currents when Ca2+ in the external solutions was >25
mM (Fig. 6A); this observation is consistent with the decrease in single-channel conductance for
neuronal nAChRs when Ca2+ is the main
charge carrier (Adams and Nutter, 1992; Mulle et al., 1992; Vernino et
al., 1992).
View larger version (20K):
[in this window]
[in a new window]
|
Figure 6.
Substitution of the negatively charged residues of
the intermediate ring with neutral amino acids drastically reduces
Ca2+ permeability of 42 and 34
receptors. A and B show
I-V curves for 34 and 42 receptors
expressed in Xenopus oocytes, respectively. Switching
from the control solution to one containing 100 mM
Ca2+ causes a rightward shift of the reversal
potential for both receptors. C shows ACh-evoked
I-V curves for the mutant
3D237A4D236A receptor in the presence of
the control solution and one containing 100 mM
Ca2+. Switching to 100 mM
Ca2+ causes a rightward shift of the reversal
potential, similar to that observed for 34 wild-type receptor.
D-F shows I-V curves for
4E245A2, 3E240Q4, and
34E239A, respectively. Switching to 100 mM Ca2+ causes a significant leftward
shift in the reversal potential for all three receptors, indicating low
relative Ca2+ permeability for these
receptors.
|
|
We also measured PCa/PNa
for 42 receptors (Fig. 6B). After switching the
control external solution to 100 mM
Ca2+, we observed an average rightward
shift in the reversal potential of 15.5 ± 0.28 mV
(n = 8); from the GHK equation we calculated an average
PCa/PNa of 1.65 ± 0.15 for 42 receptors (n = 8), approximately
twice that for 34 receptors (Table 1). We repeated these
experiments with an external solution of 10 mM
Ca2+ and 90 mM
Na+ and found similar values for
PCa/PNa (n = 6). Consistent with the higher value for 42, we found that we
needed to pre-inject greater amounts of BAPTA to ensure that we did not
activate Ca2+-activated chloride currents.
Next, we investigated whether mutations of negatively charged residues
at the cytoplasmic and intermediate ring alter the relative calcium
permeability of 42 and 34 receptors. After switching the
control external solution to 100 mM
Ca2+, we observed a rightward shift in the
reversal potential for 3D237A4D236A
receptors similar to that for 34 (Fig. 6C, Table 1).
We obtained similar results in six of six oocytes expressing 3D237A4D236A
receptors (Table 1). These results indicate that the negatively charged
residues of the cytoplasmic ring have little influence on calcium permeability.
We tested whether mutations of charged residues at the intermediate
ring alter calcium permeability by measuring
PCa/PNa for mutant
3E240A4,
3E240Q4,
34E239A, and
|
TOP
ABSTRACT
INTRODUCTION
![([Na]<SUB><UP>i</UP></SUB>+P<SUB><UP>K</UP></SUB>/P<SUB><UP>Na</UP></SUB>[K]<SUB><UP>i</UP></SUB>+4P′<SUB><UP>Ca</UP></SUB>/P<SUB><UP>Na</UP></SUB>[Ca]<SUB><UP>i</UP></SUB>)},](/content/vol20/issue2/fulltext/529/img007.gif)
