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The Journal of Neuroscience, March 15, 2001, 21(6):1939-1948
Domain Interactions Regulating AMPA Receptor Desensitization
Kathryn M.
Partin
Department of Anatomy and Neurobiology, Colorado State University,
Fort Collins, Colorado 80523-1670
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ABSTRACT |
Desensitization is a common property of glutamate and other
ligand-gated ion channels, yet its molecular mechanism is unknown. For
glutamate receptors, agonist binding involves interactions with
identified amino acids from two lobes and may result in stabilizing the
lobes in a closed "clamshell" conformation. The present studies demonstrate that two structures,  -strands 7 and 8 and  -helices J
and K, functionally interact with each other and likely form hinges
between the two lobes, influencing the coupling between agonist binding
and desensitization. Two amino acids identified within these regions
form a solvent-exposed interface with a third amino acid, a mutation of
which was shown previously to block receptor desensitization
(L507 in glutamate receptor 3). This interface may regulate
a concerted conformational shift of the AMPA subtype of glutamate
receptor subunits to the desensitized state.
Key words:
AMPA receptors; glutamate receptors; cyclothiazide; desensitization; electrophysiology; ion channels; mutagenesis
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INTRODUCTION |
Glutamate receptors mediate rapid
excitatory synaptic transmission in the CNS. This signaling
occurs via activation, deactivation, and desensitization gating
transitions, which control ion permeation on a millisecond time scale
(Edmonds et al., 1995 ; Trussell and Otis, 1996). Although the molecular
events underlying coupling between the agonist-binding site and the
control of ion permeation are unclear, a 38 amino acid "flip/flop"
domain that lies between transmembrane segments M3 and M4 of all
AMPA receptors is involved (Sommer et al., 1990). A single
residue within flip/flop [S750 in flip or
N750 in flop; amino acids are numbered according
to the mature protein (Bettler et al., 1992)] determines differential sensitivity to allosteric modulators (Partin et al., 1996).
The agonist-binding domain of the glutamate receptor 2 (GluR2) subunit
of AMPA receptors is formed by two globular lobes (domains 1 and 2)
consisting of highly ordered -helices and -sheets that are
connected by two polypeptide strands (crossovers 1 and 2) (Armstrong et
al., 1999). Domain 1 is made up of residues mostly from the "S1"
region upstream of membrane segment 1 (M1), whereas domain 2 is made up
mostly of residues from the "S2" region between M2 and M3
(Stern-Bach et al., 1994). Glutamate receptors share structural
homology with the prokaryotic amino acid-binding proteins, lysine/arginine/ornithine-binding protein (LAOBP) (Oh et al., 1993),
and glutamine-binding protein (QBP) (Nakanishi et al., 1990; O'Hara et
al., 1993; Hsiao et al., 1996). For LAOBP, bound ligand stabilizes a
protein conformation consisting of a rotation of one lobe with respect
to the other, in what has been described as a closed "Venus
fly-trap" or "clamshell" conformation. The closed conformation
results in a large shift in the torsion angle of the N-C peptide
bond ( ) of one amino acid (A90) and smaller shifts of  or for four other amino acids within the two
connecting strands (Oh et al., 1993). For glutamate receptors it is
assumed that the same type of conformational shift occurs (Mano et al., 1996; Sutcliffe et al., 1996; Swanson et al., 1997; Paas, 1998). However, although amino acid-binding proteins contain sequences homologous to the N-terminal portion of flip/flop in glutamate receptors, the receptors contain additional C-terminal sequences that
continue through and beyond this region of homology. The additional
residues contain a cysteine that forms a disulfide bond with a cysteine
in domain 2, allowing flip/flop (overlapping -helices J and K;
see Fig. 1) to serve as a third connecting strand between the
two lobes.
The goal of the present study was to determine whether residues within
the S1/S2 structure interact with flip/flop to control desensitization
and its modulation by drugs, by the use of chimeric receptors. A better
understanding of the molecular details of allosteric modulation may
provide a rational basis for the development of new drugs to
downregulate receptor activity during episodes of hyperexcitability
(Rogawski, 1993) or to upregulate glutamate receptor activity,
enhancing learning and memory after loss of glutamatergic neurons after
stroke or brain injury (Yamada, 1998).
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MATERIALS AND METHODS |
Recombinant DNA. Plasmids encoding the cDNA for the
rat flip variant of wild-type GluRA (GluR1), as well as the
cDNAs for green fluorescent protein (GFP) and GluR6, were a gift of Dr. Peter Seeburg (MPI Medical Research, Heidelberg, Germany). The wild-type glutamate receptor cDNAs were subcloned into pBlueScript II
(Stratagene, La Jolla, CA). Point mutations in GluR1 were constructed by the use of QuikChange (Stratagene), whereas GluR6/GluR1
chimeras were made by using overlapping PCR. All mutations were
confirmed by sequencing (Macromolecular Resources Facility, Colorado
State University, Fort Collins, CO). Purified plasmid DNA was
restricted with EcoRI and was then used as a template for
in vitro transcription by T7 polymerase (Ambion, Austin,
TX). Mutations were numbered according to the mature (truncated) GluR1
or GluR6 protein (Bettler et al., 1992).
Oocyte electrophysiology. Oocytes were harvested from
Xenopus laevis as described previously (Cotton
and Partin, 2000). Animal care and surgical procedures conformed to the
institutional animal care and use committee standards and practices.
Forty-six nanoliters of cRNA at 0.5-1.0 µg/µl were injected into
each oocyte cytoplasm. Experiments on oocytes were performed under
two-electrode voltage clamp with an Axoclamp 2A (Axon Instruments,
Foster City, CA) at a holding potential of  60 mV, in a continuously
perfused chamber of ~5 µl volume. The extracellular solution
contained modified Barth's solution [88 mM
NaCl, 1 mM KCl, 2.4 mM
NaHCO3, 0.3 mM Ba(NO3)2, 0.41 mM BaCl2, 0.82 mM MgSO4, and 15 mM HEPES, pH 7.6], to which was added glutamate
or kainate along with cyclothiazide (20 mM stock
solution dissolved in DMSO). Salts and drugs, including kainate and
cyclothiazide, were purchased from Sigma (St. Louis, MO). DMSO was
added so that all solutions contained equivalent amounts of vehicle.
Solution exchange was controlled via an electronic BPS-8 valve
control system (ALA Scientific, Westbury, NY) and electronic valves
(The Lee Company, Westbrook, CT). Electrodes of 0.1-3 M resistance
were filled with 1 M CsCl and 5 mM EGTA. Current responses were filtered at 100 Hz (Cygnus Technology, Delaware Water Gap, PA) and acquired by a Power
Macintosh 7600/132 computer with an Instrutech ITC-16 interface
(Great Neck, NY) that was controlled by the program Synapse
(Synergistic Research Systems, Silver Springs, MD).
Whole-cell electrophysiology. Human embryonic kidney
fibroblasts (HEK293 cells; CRL 1573) from American Type Culture
Collection (Rockville, MD) were cultured as described previously
(Partin et al., 1996). Cells were transiently transfected by the use of FuGene reagent (Boehringer Mannheim, Indianapolis, IN) with a combination of 90% glutamate receptor cDNA and 10% GFP cDNA (Chalfie et al., 1994), driven by the same cytomegalovirus promoter. Currents were recorded 24-72 hr after transfection on whole cells. Cells were
voltage-clamped at 60 mV by the use of an Axopatch 200B (Axon
Instruments). Thin-walled borosilicilate glass micropipets (catalog
#TW150F; World Precision Instruments, Sarasota, FL) with a resistance
of 2-5 M were filled with (in mM): 135 CsCl, 10 CsF, 10 HEPES, 5 Cs-BAPTA, 1 MgCl2, and 0.5 CaCl2, pH7.2. After going into voltage clamp,
each cell was lifted to a flow pipe constructed from  tubing
(catalog #BT150-10; Sutter Instrument Company, Novato, CA) and placed
in the control solution stream close to the interface between
continuously flowing control and drug-containing solutions.
Extracellular solution contained (in mM): 145 NaCl, 5.4 KCl, 5 HEPES, 1 MgCl2, 1.8 CaCl2, and 0.1 mg/ml phenol red, pH 7.3. Solution
flow was driven by a syringe pump (KD Scientific, New Hope, PA)
at a rate of 0.2-0.6 ml/min. Cells were rapidly jumped into
drug-containing solution for 10-500 msec with a 70 µm step
controlled by a piezoelectric device (Burleigh Instruments, Fishers,
NY). Responses were filtered at 5 kHz with a low-pass Bessel filter
(Warner Instruments, Hamden, CT), digitized at 0.25-10 msec/point, and
stored on a PowerMac computer, using an ITC-16 interface (Instrutech).
Data acquisition and analysis were done using Synapse (Synergistic
Research Systems).
Data analysis. The kinetics of desensitization was
analyzed as described previously (Partin et al., 1996). Statistical
ANOVAs were performed using Microsoft Excel software. Current
traces were plotted using KaleidaGraph 3.5 (Synergy Software, Reading, PA). Visualization of three-dimensional protein structure was done on
the GluR2 Protein Data Bank coordinates (Armstrong et al.,
1999), using RasMac version 2.5-UCB (Berkley, CA) and MacLook version 2.1 (Molecular Applications Group, Palo Alto, CA).
Three-dimensional images were constructed using Molscript version 2.0 (Kraulis, 1991) and Raster3D version 2.0 (Merritt and Bacon, 1997) on a Silicon Graphics Octane Workstation.
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RESULTS |
Rationale for the design of receptor chimeras
Previous studies had demonstrated that cyclothiazide is a
selective, positive modulator of AMPA versus kainate non-NMDA receptors and, in fact, has an inhibitory effect on kainate receptors. GluR6 is a
kainate receptor that is expressed robustly in both the
Xenopus oocyte and mammalian fibroblast heterologous
systems. Therefore, to identify residues in AMPA receptors that
contribute to drug modulation, small domains of GluR1 were swapped into
GluR6 and analyzed for gain of function. Amino acids were investigated
on the basis of their proximity to flip/flop as predicted from tertiary structure (Stern-Bach et al., 1994; Armstrong et al., 1999) (Fig. 1). Initially, chimeras were screened for
function and drug sensitivity in oocytes under slow solution perfusion.
Because the kinetics of desensitization is poorly resolved under these
circumstances, the ability of cyclothiazide to modulate desensitization
was assayed by measuring the amplitude of the peak current in the
absence or presence of cyclothiazide. Subsequently, desensitization
kinetics of interesting chimeras was characterized by the use of rapid perfusion in transiently transfected HEK293 cells. Previous studies had
shown that insertion into GluR6 of either the entire flip/flop domain
of GluR1 (GluR6-Flip) (Partin and Mayer, 1996) or a single residue
within flip/flop (GluR6-Q755S) (Partin et al.,
1995) could confer a modest sensitivity to cyclothiazide.
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Figure 1.
Sequence and structure of GluR6 chimeras.
a, The molecular structure of GluR2 S1/S2 (Armstrong et
al., 1999), with BETA 7,8 shown in red and the flip/flop
region shown in green, is in accordance with the
color scheme shown for the primary sequence below.
b, GluR1 amino acids swapped into GluR6 are indicated
with red and green lines for the
following chimeras (GluR1 residue numbers are indicated in parentheses
in the following and refer to the mature GluR1 protein):
GluR6-BETA 7,8 (489-502), -Flip
(722-781), -Helix J (742-752), -Helix K
(750-763), and -FlipC17 (764-780).
Structural elements of the GluR2 agonist-binding domain (Armstrong et
al., 1999) are indicated in gray; horizontal
bars represent -helices, and arrows represent
-strands. Other symbols indicate residues known to be
important in desensitization: the filled diamond
indicates the amino acid that, when mutated, completely blocks
desensitization [L507 in GluR3 (Stern-Bach et al.,
1998)]; the filled triangle marks a site of
glycosylation that is important for modulation by Concanavalin A of
GluR6 desensitization (Everts et al., 1999); the filled
square represents a residue thought to form an important
exposed patch within a hydrophobic domain (Chen et al., 1999); and
filled circles indicate residues that differ as a result
of alternative splicing within the flip/flop domain of GluR1 (Sommer et
al., 1990). Residues in bold represent amino acids
that are divergent between GluR1 and GluR6. c, Spatial
relationship between GluR2 amino acids homologous to GluR1 residues
S493 (within BETA 7,8), N750 (S750
within GluR1 flip), and L479 [L507 of GluR3
(Stern-Bach et al., 1998)] is shown. This view of the molecule is
rotated, with respect to a, to show better the side
chains of residues used in this study. d, An identical
view of the molecule is shown in a space-filling representation. The
BETA 7,8 domain is shown in red, the flip/flop domain is
shown in green, and the three critical residues are
shown in pink. BETA 7,8, -Strands 7 and 8; C, C terminal; N, N
terminal.
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Conferring increased cyclothiazide sensitivity on GluR6
As shown previously, cyclothiazide is a modulator causing a
dramatic decrease in the desensitization of GluR1 (Fig.
2b1) but not
that of GluR6 (Fig. 2b2). Also in
agreement with previous results, a point mutation in GluR6 that
converts a glutamine residue to the serine as found at position 750 in
GluR1(flip) results in a modest degree of cyclothiazide sensitivity
(Fig. 2b3). Among the several GluR6/GluR1
chimeras that were designed and screened, only one was identified that
further enhanced sensitivity to cyclothiazide, GluR6-BETA 7,8 + Q755S (Fig. 2b4).
Glutamate responses of GluR6-BETA 7,8 + Q755S
were potentiated 24.5 (± 9.5)-fold by cyclothiazide, compared with 2.2 (± 0.9)-fold for GluR6-Q755S; kainate responses of GluR6-BETA 7,8 + Q755S were potentiated
158.5 (± 82)-fold, versus 1.9 (± 0.5)-fold for
GluR6-Q755S (Fig. 2c). The double chimera consisting of GluR6 containing both BETA 7,8 and the entire flip/flop domain of GluR1 was nonfunctional (data not shown). BETA 7,8 lies within the previously defined S1 domain (Stern-Bach et al., 1994)
and coincides with a region that has structural homology with one of
the connecting strands (crossover 1) between the two agonist-binding
lobes of LAOBP (Figs. 1, 2a) (Oh et al., 1993; Armstrong et
al., 1999). The data in Figure 2 suggest that Q755S and residues within BETA 7,8 act together
to play an important role in cyclothiazide sensitivity.
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Figure 2.
Identification of a domain within S1 that enhances
modulation by cyclothiazide. a, Schematic representation
of the structure of the agonist-binding domain, focusing on -strands
7 and 8 and -helices J and K, also shown in Figure 1.
b, Electrophysiological responses
(bottom) of chimeric receptors expressed in
Xenopus oocytes, with schematic representations
(top) of the chimeric constructs (GluR1 sequences shown
in black; GluR6 sequences shown in gray).
Control glutamate and kainate responses (hairline) are
superimposed on responses in the presence of cyclothiazide
(CTZ; bold). Closed arrows
point to the peak current in the control; open arrows
point to the peak current in the presence of cyclothiazide. Wild-type
(wt) GluR1 currents were potentiated by cyclothiazide
(b1), whereas wt GluR6 currents were
consistently inhibited by cyclothiazide
(b2). GluR6-Q755S currents
were somewhat potentiated by cyclothiazide (Partin et al., 1995)
(b3), but the double chimera
GluR6-BETA 7,8 + Q755S was strongly potentiated by
cyclothiazide (b4). Insets
(b4), A higher magnification of control
currents for GluR6-BETA 7,8 + Q755S. These experiments were
done in the absence of Concanavalin A, a modulator of kainate receptor
desensitization, and therefore the responses to agonists desensitized
within 1-2 sec in oocytes. c, The mean potentiation by
100 µM CTZ of peak currents
(IAGONIST+CTZ/IAGONIST)
plotted for 300 µM glutamate (stippled
bars) or 300 µM kainate
(filled bars). Error bars represent SEM; the
number of oocytes studied under each condition ranges from 5 to
10.
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Identification of residues in the BETA 7,8 domain of GluR1 critical
for cyclothiazide modulation
If the BETA 7,8 region is indeed involved with allosteric
modulation of AMPA receptors by cyclothiazide, then mutation of individual residues within this domain in GluR1 that are divergent from
GluR6 should produce a loss of modulation by cyclothiazide. GluR1
receptors with point mutations in BETA 7,8 (Fig.
3a) were studied in HEK293
cells exposed to agonist by rapid perfusion. Thus, modulation of
desensitization by cyclothiazide is reflected in the slowing of current
decay in the continued presence of 10 mM
glutamate, rather than as an increase in peak current amplitude. There
was no effect on modulation by cyclothiazide compared with that of wt
GluR1 when residues
M499-K501 within BETA 7,8 were mutated to the residues found at the homologous positions in GluR6 (Fig. 3b,c). However, the mutation of
S493T resulted in a dramatic reduction in the
efficacy of cyclothiazide. Interestingly, a loss of modulation by
cyclothiazide did not occur when S493 was mutated to alanine (Fig. 3b), which has a less bulky side chain than
threonine. Testing the effect of increasing the size of the side chain
by mutating it to glutamine or cysteine was not possible because these
substitutions grossly impaired current amplitudes and prevented further
quantitation, although qualitatively the effects of cyclothiazide appeared to be greatly diminished (data not shown). Inspection of the
atomic coordinates of GluR2 indicated that of the four divergent
residues in BETA 7,8, the S493 side chain is
nearest to N750 of GluR2(flop) [7.79 Å, or 8.41 Å if that residue were the S750 found in
GluR1(flip)]. That the size and/or shape of the side chain at position
493 is so critical for modulation (threonine adds an asymmetric
C-atom) suggests some type of an interaction between these
residues. A functional interaction may be caused by a state-dependent,
physical interaction between BETA 7,8 and flip/flop, a direct
interaction between these residues and cyclothiazide, or the
participation by these residues in the regulation of desensitization, thereby affecting modulation of desensitization in an allosteric manner. The GluR1 point mutations provide independent confirmation of
the conclusions drawn from the GluR6-BETA 7,8 + Q755S chimera and implicate
S493 in regulating GluR1 sensitivity to
cyclothiazide. In addition to impacting cyclothiazide modulation, point
mutations in BETA 7,8 affected control desensitization kinetics, which
reached significance for I500Y
(p = 0.00058; Fig. 3d) but not for
S493T, which is consistent with the GluR6
"C1a" mutant described by Stern-Bach et al. (1998). The role of
BETA 7,8 and the flip/flop region in control desensitization is
addressed in further detail by the experiments described below.
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Figure 3.
Effect of point mutations within the BETA 7,8 domain of GluR1 on modulation by cyclothiazide. a, An
alignment of GluR1 and GluR6 sequences within the BETA 7,8 domain
showing that there are 10 identical (dashes) and 4 nonidentical residues. Each of the divergent residues was mutated in
GluR1 to the side chain found in GluR6 and analyzed for function and
sensitivity to cyclothiazide. b, Individual, whole-cell
responses in transiently transfected HEK293 cells rapidly perfused with
100 msec pulses of 10 mM glutamate in control conditions
(hairline) or in the presence of 100 µM
CTZ (bold line). The time constant for
desensitization of control responses is indicated with each
trace. Calibration bars for current are shown for the
control responses; responses in the presence of cyclothiazide were
scaled to the peak amplitude of the control response. The mutation
S493T dramatically altered the ability of cyclothiazide to
block desensitization, without altering control kinetics.
c, Analysis of potentiation by cyclothiazide of point
mutations, showing mean decay
(ISTEADY-STATE/IPEAK)
after 100 msec in the presence of 100 µM cyclothiazide
and 10 mM glutamate. Cyclothiazide failed to block
desensitization only for GluR1-S493T. Error bars represent
SEM, and the number of cells studied is indicated in
parentheses above each
column. d, Mean time constants for
desensitization of control responses for each point mutant.
GluR1-I500Y desensitization kinetics was significantly
faster than that of wt GluR1 (*p = 0.00058).
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Functional interactions controlling desensitization kinetics
In agreement with our previous results (Partin et al., 1995), the
Q755S point mutation in GluR6 not only introduced
sensitivity to cyclothiazide but also slowed the kinetics of control
desensitization in response to glutamate from
 desensitization = 3.8 ± 0.4 msec (n = 6) to desensitization = 16.4 ± 1.4 msec (n = 12; Fig.
4a1,a2,b). Because Q755 and BETA 7,8 residues appeared to be
important for cyclothiazide modulation of desensitization of
GluR6-based chimeras (Fig. 2), it was important to determine whether
mutation of these residues affected control desensitization kinetics.
Control desensitization kinetics of GluR6/GluR1 chimeras was tested by
fast perfusion. Introduction of the BETA 7,8 domain of GluR1 into
GluR6-Q755S reversed the desensitization-slowing
effect of the point mutation, restoring a time constant for
desensitization similar to that of wt GluR6 (Fig.
4a3). Introducing the BETA 7,8 domain
alone into GluR6 caused a modest, but significant, increase in the rate of desensitization (desensitization = 2.6 ± 0.3 msec; n = 13; Fig. 4b). GluR1-BETA
7,8 contains a serine at position 493, which when mutated to threonine
(the homologous residue is at position 504 of GluR6) abolished
modulation by cyclothiazide (Fig. 3b). Thus, it
was important to determine whether
GluR6-T504S + Q755S had
control desensitization kinetics like that of GluR6-BETA 7,8. The double-point mutant receptor demonstrated desensitization kinetics
(desensitization = 5.5 ± 0.3 msec;
n = 18) similar to that of wt GluR6 (Fig.
4a4), indicating that
T504 in BETA 7,8 is sufficient to correct the
slowing of desensitization caused by introduction of GluR1-BETA 7,8 into GluR6. These data support the hypothesis that one residue in BETA
7,8 and one residue in flip/flop interact functionally to regulate
desensitization. However, the data do not exclude an indirect,
allosteric mechanism.
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Figure 4.
Amino acids regulating desensitization kinetics.
a1-a4, Fast
perfusion experiments performed in the whole-cell configuration on wt
and chimeric GluR6 receptors transiently expressed in HEK293 cells,
comparing control (hairline) and
CTZ-modulated (bold) responses to 10 mM glutamate. Time constants for control
desensitization for each trace are indicated. The
structure of each chimera is shown above each
trace (sequences derived from GluR1 are shown in
black; those derived from GluR6 are shown in
gray). b, Summary of the mean control
kinetics, showing that desensitization of GluR6-Q755S was
significantly slower than that of wt GluR6 (**p < 0.0001), whereas desensitization of GluR6-BETA 7,8 is significantly
faster than that of wt GluR6 (**p = 0.0001).
However, the double chimera GluR6-BETA 7,8 + Q755S does
not significantly differ from wt GluR6; thus, the
presence of GluR1 sequence in both regions compensated for the defects
induced by the presence of GluR1 sequence in only one of the two
regions. c, Summary of the mean kinetics of
desensitization in the presence of 100 µM
cyclothiazide, showing that the actions of cyclothiazide were greatest
on any chimera that contains the Q755S mutation
(independent of the presence of the BETA 7,8 domain).
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In the presence of cyclothiazide, desensitization kinetics was similar
for GluR6-Q755S and GluR6-BETA 7,8 + Q755S (Fig. 4c). However, the ratio of
the time constant of desensitization in the presence of cyclothiazide
to the time constant of desensitization in control was much greater for
GluR6-BETA 7,8 + Q755S (11.4-fold) than for
GluR6-Q755S (2.3-fold) or GluR6-BETA 7,8 (0.9-fold), because of faster kinetics of control desensitization for
the latter constructs. These data offer an explanation of the large effect that cyclothiazide had on potentiation of peak currents when
tested in the oocyte system (Fig. 2).
Differential contributions of -helices J and K to the modulation
of GluR1 by cyclothiazide
The results presented thus far suggest that residues within
BETA 7,8 and flip/flop affect both modulation by cyclothiazide and
control desensitization kinetics and identify two residues (S493 and S750) that
mediate these effects. Two prominent structural components within
flip/flop are -helices J and K (Fig. 1). Although it was clear from
previous studies that the differential drug modulation of
desensitization in flip versus flop isoforms of AMPA receptors was
controlled by the S/N/Q site (i.e., at the position of
Q755 of GluR6 or S750 of
GluR1), the contribution of other residues within flip/flop had not
been defined. Thus, in the present study GluR6/GluR1 chimeras of
smaller domains within flip/flop were constructed and tested for
sensitivity to cyclothiazide. Introduction of the entire flip/flop
domain into GluR6 conferred cyclothiazide slowing of desensitization
(Fig. 5a1)
in agreement with previous studies in oocytes (Partin and Mayer, 1996).
Cyclothiazide slowed desensitization for GluR6-Flip ~38-fold, to
193 ± 17.5 msec (Fig. 5b), but not to the extend that
occurred for wt GluR1. This effect was not seen when only the
C-terminal 17 amino acids of flip/flop were inserted
(GluR6-FlipC17
desensitization = 3.4 ± 0.4 msec;
n = 8; Fig. 5a2).
Cyclothiazide also had little effect when -helix K from GluR1 and
Q755S were inserted into GluR6, with only a
twofold slowing of desensitization
(desensitization = 19.3 ± 1.9 msec;
n = 9; Fig. 5a3). By
contrast, for a chimera that included all of helix J, cyclothiazide
slowed desensitization 18-fold
(desensitization = 179.4 ± 12.7 msec;
n = 5; Fig. 5a4), suggesting a dominant role for -helix J in regulating drug
modulation of GluR1. Both the GluR6-Helix J and GluR6-Helix K chimeras
had slower kinetics of desensitization than either wt GluR1 or GluR6 had (Fig. 5c).
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Figure 5.
Dominance of -helix J in determining
cyclothiazide modulation of GluR1.
a1-a4,
Whole-cell responses of GluR6 chimeras transiently expressed in HEK293
cells show that inclusion of -helix J
(a4) appeared to be necessary and
sufficient to match the efficacy of modulation by cyclothiazide seen
with GluR6-Flip (a1).
b, Quantitation of the efficacy of modulation of
flip/flop domain chimeras as measured by comparing the mean time
constants of desensitization in the presence of cyclothiazide is shown.
c, The control kinetics of desensitization was
significantly slower than that of wt GluR1 for both helix-swapping
chimeras (*p < 0.001), whereas those of the
GluR6-Flip and GluR6-FlipC17 chimeras were similar to those
of wt GluR1. ND, Nondesensitizing.
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The contributions of a residue homologous to one affecting
desensitization of GluR3
Previously, Stern-Bach et al. (1998) identified a residue in
GluR3 (L507) that, when mutated to the tyrosine
found at the homologous position in GluR6
(L507Y), blocks desensitization. Their data
suggest that this residue, together with sequences between M1 and M4,
may participate in allosteric modulation by cyclothiazide. To probe
this hypothesis further, a GluR6 chimera that includes helix J from
GluR1, in conjunction with a mutation (Y490L in
GluR6) that effectively inverts the mutation of Stern-Bach et al.
(1998), was tested for allosteric modulation by cyclothiazide (Fig.
6). The ability of cyclothiazide to block
desensitization at the end of either a 100 or 500 msec application of
glutamate was used to assess the contributions of these residues to
allosteric modulation. Some desensitization was present at the end of
the 500 msec pulse of agonist for all three chimeras. In particular, there was substantial desensitization (75-80%) by the end of the 500 msec pulse for the chimera replacing just helix J (as seen in Fig. 5)
and the construct replacing helix J in conjunction with the
Y490L mutation (Fig. 6b). However,
when the T504S substitution was included
(GluR6-Helix J + Y490L + T504S), desensitization was significantly reduced
(p = 0.006) to ~40% by the end of the pulse.
Thus, the contributions of GluR1 S493 to
allosteric modulation are evident even in a chimera that has a
substitution at the nondesensitizing site. These data further support
the hypothesis that S493 in GluR1 plays an
important role in drug modulation.
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Figure 6.
Contributions of the nondesensitizing mutation to
allosteric modulation. a, Whole-cell responses in
transfected HEK293 cells to rapid applications of glutamate for 500 msec, in the presence of 100 µM cyclothiazide, are shown
for wt GluR1 and three GluR6/GluR1 chimeras. None of these
chimeras permitted the complete block of desensitization that is seen
with wt GluR1. However, the GluR6 chimera containing the
T504S mutation was more efficacious than were the two
chimeras lacking T504S. b, Quantitation of
the steady-state-to-peak ratio at the end of either a 100 msec
(gray bars) or a 500 msec (black
bars) application of glutamate is shown. Inclusion of
T504S significantly (p = 0.006)
increases the steady-state-to-peak ratio at the end of a 500 msec
application compared with that seen with GluR6-Helix J + Y490L. pk, Peak; ss,
steady-state.
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Identification of residues in -helices J and K critical for
modulation by cyclothiazide
To finely map the role of amino acids in -helices J and K,
individual residues in GluR1 were mutated to alanine (or glycine in the
case of A745), and the mutant receptors were
assayed for sensitivity to cyclothiazide. Because of the large number
of receptors studied, function was assayed in oocytes, where the
ability of cyclothiazide to block desensitization was measured by
determining the ratio of peak to steady-state current during a 60 sec
application of glutamate. The effect of the mutations showed a
periodicity (Fig. 7a), which
may be the result of the tertiary structure in this region.
Specifically, modulation by cyclothiazide was markedly impaired at two
positions, V746
(Iss/Ipk = 0.33 ± 0.06) and L755 (Iss/Ipk = 0.40 ± 0.06) (Fig. 7b), compared with that of wt GluR1. A magnified
portion of the GluR2(flop) crystal structure is shown in Figure
7c, indicating the spatial relationship of four residues (S493, N750,
V746, and L755) that are
critical for allosteric modulation by cyclothiazide. A nearest-neighbor
analysis (MacLook version 2.1) indicated that each of these four
side chains is the nearest neighbor ( 5 Å) either of each other or of
residues within BETA 7,8. Taken together, these data indicate that BETA 7, 8 and flip/flop form at least part of a functional domain, regulating sensitivity to cyclothiazide and affecting desensitization kinetics.
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Figure 7.
Effect of alanine substitution within flip/flop on
modulation by cyclothiazide of GluR1. a, Individual
residues within flip/flop were mutated, and modulation by cyclothiazide
was characterized in Xenopus oocytes. A summary of the
mean modulation by cyclothiazide [IGlu+CTZ
(ss)/IGlu+CTZ (pk)] for all point mutants is shown. Ratios
were normalized to that of wt GluR1 (WT). Each
residue was mutated to alanine, except A745 that was
mutated to glycine. Error bars represent SEM; the number of oocytes
studied for each mutant is shown in parentheses
above each column. b,
Responses of wt GluR1 and two point mutations, V746A and
L755A, show control responses (hairline) and
responses in the presence of 100 µM CTZ
(bold line). Both point mutations demonstrated less
effective modulation by cyclothiazide. The asterisk
represents calibration for wt GluR1. c, Molecular
representation, using the atomic coordinates of GluR2 (Armstrong et
al., 1999), shows the proximity of side chains that, when mutated,
alter the efficacy of cyclothiazide, including S493,
V746, L755, and
N750.
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DISCUSSION |
The results reported here newly identify a residue within BETA 7,8 of the AMPA receptor GluR1 as functionally interacting with the
-helical J and K region (within the alternatively spliced flip/flop
domain) to regulate desensitization and its modulation by
cyclothiazide. In particular, introduction of BETA 7,8 of GluR1 into
GluR6 with a point mutation in -helix J
(GluR6-Q755S) conferred greater sensitivity to
cyclothiazide than did wt GluR6 or GluR6-Q755S. Moreover, a point mutation in -sheet 7 of GluR1
(S493) affected cyclothiazide sensitivity in a
manner that depended on the size of the side chain, in that increasing
side chain size diminished the effects of cyclothiazide but decreasing
the size had no effect. These findings are supportive of a functional
interaction between -helices J and K and -sheets 7 and 8. Such an
interpretation is further supported by the analysis of a GluR6
-helical J and K point mutation that caused a defect in control
desensitization kinetics, which could be compensated for by concomitant
mutation at position T504 in BETA 7,8. Another
indication of a functionally important domain-domain interaction was
provided by scanning alanine mutagenesis across -helices J and K,
which identified the two additional residues
(V746 and L755) as being
important for modulation by cyclothiazide.
Examination of the crystal structure of the agonist-binding
portion of GluR2(flop) reveals that -helices J and K and BETA 7,8 both lie between the two lobes that form the agonist-binding site and
are therefore in a position to play a role in the stabilization of lobe
closure. The BETA 7,8 domain shares structural homology with one of the
connecting strands (crossover 1) between the two lobes of the
periplasmic amino acid-binding proteins LAOBP and QBP (Oh et al., 1993;
Armstrong et al., 1999). Thus, BETA 7,8 might perform the same function
for glutamate receptors, with specific residues undergoing large
changes in torsion angles after ligand binding to stabilize the closed
clamshell conformation. Glutamate receptors diverge from amino
acid-binding proteins because of novel sequences C-terminal to helices
J and K (homologous to helices VII and VIII of QBP) that permit the
formation of a disulfide bond, allowing flip/flop to become a third
connecting strand between the two lobes. It has been postulated that
variable degrees of lobe closure reflect the different states of
receptor activity: open, closed, and desensitized (Armstrong et al.,
1999). That -helices J and K and BETA 7,8 form connecting strands
between the two lobes suggests that these two regions may act in
concert to regulate the transition between open and closed clamshell
conformations, thereby coupling agonist binding and channel gating.
Examination of the crystal structure also reveals that each of the two
critical residues, S750 of -helix J and
S493 of BETA 7,8, is exposed on the surface of
the protein, as illustrated in Figure 1, c and d.
In a recent study, Stern-Bach et al. (1998) identified a residue in
AMPA receptors (L507 of GluR3, homologous to
L479 of GluR1) that, when mutated, completely
blocks the onset of desensitization. As noted by Stern-Bach et al.
(1998), this residue is also present on the surface of the protein, and
the spatial relationship between it and the two residues identified here, S493 and S750, is
notable (Fig. 1). It is clear that all three residues have a functional
role in regulating desensitization, all lie within domain 1 (the large
domain), and together they form a plane on the same exposed face of the
protein. However, the residues appear to be too far apart to
participate in a direct three-way interaction;
L479 lies ~15 Å from
S493 and ~20 Å from S750. In contrast, S493 and
S750 are ~8 Å from each other in this crystal
structure, which probably represents the open, nondesensitized state of
the intact receptor (Armstrong et al., 1999). The data presented here
suggest that in the transition to the desensitized state,
S493 and S750 either
interact directly or allosterically.
The functional properties and spatial positioning of these three
residues (L479, S493, and
S750) suggest that together they form an
interface that may be the site of a specific subunit-subunit interaction. Such an interface would thus contain one amino acid within
-helix D (directly involved with agonist binding, Fig. 1), one amino
acid within a hinge region, and one amino acid within the alternatively
spliced regulatory domain of flip/flop. Glutamate receptors are formed
from four [or five (Premkumar and Auerbach, 1997)] individual
subunits that assemble to make a receptor complex (Rosenmund et al.,
1998). Each subunit can bind (at least) one molecule of agonist
(Clements and Westbrook, 1991). There is evidence that binding of
glutamate to a single subunit is sufficient for channel opening,
although opening to larger conductance states requires the binding of
agonist to more than one subunit (Rosenmund et al., 1998). Can a single
subunit also undergo desensitization after opening? It has been widely
postulated that desensitization occurs via an allosteric mechanism,
whereby agonist binding induces a change in the conformation of one
subunit that is extended to the subunit-subunit interface, allowing
the entire protein to undergo a concerted shift in conformation to the
desensitized state. Such a postulate predicts the existence of multiple
interdomain contacts between subunits that regulate desensitization.
The data shown here are consistent with L479,
S493, and S750 serving just such a function but do not exclude the possibility that these residues
participate in domain-domain interactions within a single subunit.
Further structural and functional analyses will be required to resolve
these issues.
| |
FOOTNOTES |
Received Sept. 25, 2000; revised Dec. 13, 2000; accepted Dec. 22, 2000.
This work was supported by American Heart Association Scientist
Development Grant 0030100N. I thank Dr. Mark L. Mayer, in whose lab
this project was initiated, Drs. Kurt Beam and Mike Tamkun for
scientific discussions and critical reading of this manuscript, and
Galen Pickard for his technical assistance.
Correspondence should be addressed to Dr. Kathryn M. Partin at the
above address. E-mail: kpartin{at}lamar.colostate.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
