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The Journal of Neuroscience, February 15, 2000, 20(4):1435-1445
Intercellular Communication in Spinal Cord Astrocytes: Fine
Tuning between Gap Junctions and P2 Nucleotide Receptors in Calcium
Wave Propagation
Eliana
Scemes1,
Sylvia
O.
Suadicani1, 2, and
David C.
Spray1
1 Department of Neuroscience, Albert Einstein
College of Medicine, Bronx, New York 10461, and
2 University Sao Judas Tadeu, Sao Paulo, SP,
Brazil
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ABSTRACT |
Electrophysiological properties of gap junction channels and
mechanisms involved in the propagation of intercellular calcium waves
were studied in cultured spinal cord astrocytes from sibling wild-type
(WT) and connexin43 (Cx43) knock-out (KO) mice. Comparison of the
strength of coupling between pairs of WT and Cx43 KO spinal cord
astrocytes indicates that two-thirds of total coupling is attributable
to channels formed by Cx43, with other connexins contributing the
remaining one-third of junctional conductance. Although such a
difference in junctional conductance was expected to result in the
reduced diffusion of signaling molecules through the Cx43 KO spinal
cord syncytium, intercellular calcium waves were found to propagate
with the same velocity and amplitude and to the same number of cells as
between WT astrocytes. Measurements of calcium wave propagation in the
presence of purinoceptor blockers indicate that calcium waves in Cx43
KO spinal cord astrocytes are mediated primarily by
extracellular diffusion of ATP; measurements of responses to
purinoceptor agonists revealed that the functional P2Y receptor subtype
is shifted in the Cx43 KO astrocytes, with a markedly potentiated
response to ATP and UTP. Thus, the reduction in gap junctional
communication in Cx43 KO astrocytes leads to an increase in autocrine
communication, which is a consequence of a functional switch in the P2Y
nucleotide receptor subtype. Intercellular communication via calcium
waves therefore is sustained in Cx43 null mice by a finely tuned
interaction between gap junction-dependent and independent mechanisms.
Key words:
glia; connexin; purinoceptor; calcium waves; spinal cord; connexin43; knock-out mice
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INTRODUCTION |
Intercellular propagation of
Ca2+ waves has been described in a wide
variety of cell types and is considered one mechanism by which
cooperative cell activity is coordinated (see Sanderson et al., 1994 ).
In the CNS such waves occur among and between neurons and glial cells
both under normal and pathological conditions (Cornell-Bell et al.,
1990; Charles et al., 1991, 1996; Cornell-Bell and Finkbeiner, 1991;
Cornell-Bell and Williamson, 1993; Attwell, 1994; Kandler and Katz,
1995, 1998; Nedergaard et al., 1995; Takeda et al., 1995; Yuste et al.,
1995).
Propagation of Ca2+ waves between cells
can be mediated by the intracellular and extracellular diffusion of
messenger molecules. Intercellular calcium wave propagation directly
from the cytosol of one cell to another requires the presence of gap
junction channels, which allow signaling molecules
(Mr < 1000 Da), such as inositol triphosphate (IP3),
Ca2+, and cyclic ADP ribose (Saez et al.,
1989; Christ et al., 1992; Churchill and Louis, 1998), to cross
boundaries between adjacent cells and thus sustain their propagation.
The alternative pathway for communication of the calcium signals
involves the diffusion of signaling molecules such as ATP through the
extracellular space, activating P2 nucleotide receptors in neighboring
cells that may or may not be in contact (Osipchuk and Cahalan, 1992;
Hassinger et al., 1996; Guthrie et al., 1999).
The relative contribution of intercellular gap junction-mediated and
extracellular gap junction-independent pathways in the propagation of
calcium waves among astrocytes remains controversial. Some reports
indicate that the calcium wave spread between astrocytes relies
entirely on the gap junction-mediated route (Charles et al., 1992;
Finkbeiner, 1992; Nedergaard, 1994; Venance et al., 1995, 1997),
whereas others support a pathway involving primarily extracellular ATP
diffusion (Hassinger et al., 1996; Guan et al., 1997; Zanotti and
Charles, 1997; Cotrina et al., 1998).
Such divergent views regarding the mechanism underlying calcium wave
propagation may be related in part to the heterogeneous distribution of
gap junctions and P2 receptors in the CNS. Astrocytes from different
CNS regions display different degrees of gap junction coupling (Batter
et al., 1992; Lee et al., 1994) and express different subtypes of P2
receptors (Pearce and Langley, 1994; Ho et al., 1995; King et al.,
1996).
Astrocytes are coupled to each other by gap junction channels formed
mainly by connexin43 (Cx43). In the brain, Cx43 channels contribute
~95% of total junctional conductance between astrocytes, with the
other connexins (Cx30, Cx40, Cx45, and Cx46) supporting the remaining
junctional communication (Dermietzel, 1996; Spray, 1996; Spray et al.,
1998; Dermietzel et al., 2000; Kunzelmann et al., 1999).
In the spinal cord, although Cx43 expression has been described between
astrocytes (Ochalski et al., 1997; Theriault et al., 1997; Rash and
Yasumura, 1999), the relative contribution of various connexins to the
coupling is unknown. Because differences in connexin expression and in
the strength of coupling determine the function and regulation of CNS
communication compartments, the present study was undertaken to
characterize the gap junction channels and to evaluate the relative
contribution of gap junction-dependent and independent mechanisms in
the propagation of intercellular calcium waves between spinal cord
astrocytes. It is shown here that communication within the spinal cord
astrocytic syncytium is sustained by a finely tuned interaction between
gap junction-dependent and independent mechanisms, so that a reduction
of gap junction-mediated intercellular communication in Cx43 null mice
is compensated by an increased autocrine communication. Enhanced
intercellular Ca2+ wave signaling in
spinal cord astrocytes occurs as a consequence of a functional switch
in the P2 receptor subtype, implying that gap junction and P2 receptor
expression are functionally interconnected.
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MATERIALS AND METHODS |
Astrocyte cultures
Spinal cord astrocytes derived from wild-type (WT) and Cx43
knock-out (KO) neonatal mice (GJA1M1 strain; heterozygotes obtained from Jackson Laboratory, Bar Harbor, ME) were used in this study. After
painless death the cervical to lumbar vertebrae were dissected, and
spinal cord segments were evicted from the vertebrae with fine forceps.
Each spinal cord was cut into small pieces after the removal of
meninges and digested in 0.25% collagenase (Sigma, St. Louis, MO) in
PBS, pH 7.4, for 10-20 min at 37°C. Cells were collected by
centrifugation at 1000 rpm for 2 min at room temperature. The final
pellet was suspended in DMEM (Life Technologies,
Gaithersburg, MD) containing 5% fetal bovine serum and 1%
antibiotics, and the cells were seeded on tissue culture dishes. The
medium was changed 48 hr later and then every 2 d thereafter.
Astrocytes from the brains of WT and Cx43 KO mice also were used for
some experiments. To obtain those cells, we dissected whole
brain tissue from neonatal mice after removal of meninges and then
minced and incubated them with 0.1% trypsin at 37°C. Cells were
dissociated from minced tissue by trituration with a small-bore
pipette, spun at 1000 rpm for 2 min, and resuspended in culture medium
(DMEM) complemented with 5% fetal bovine serum and 1% antibiotics and
maintained as described above for spinal cord astrocyte cultures.
Astrocytes in culture were identified by immunostaining with anti-glial
fibrillary acidic protein (GFAP). Approximately 80-90% of the cells
were immunopositive for GFAP. Studies described here were performed on
spinal cord and brain astrocytes maintained for 2-3 weeks in culture.
Genotypes were determined from PCR of tail samples obtained at
the time of cell isolation, as described previously (Dermietzel et al.,
2000).
Electrophysiology
Electrical coupling. Junctional conductance in WT and
Cx43 KO spinal cord astrocytes was characterized by using the dual
whole-cell voltage-clamp technique. Freshly dissociated pairs of
astrocytes were voltage-clamped at holding potentials of 0 mV, and
8-10 sec duration command steps ( V) in 20 mV
increments from  110 to +110 mV or from 100 to +100 mV were
presented to one cell with pClamp 6 software (Axon Instruments, Foster
City, CA). Junctional currents (Ij)
were recorded in the unstepped cell; junctional conductance (Gj) was calculated as
Ij/V (Spray et al.,
1981). Patch pipettes were filled with (in mM)
140 CsCl, 10 EGTA, and 5 Mg2ATP, pH 7.25. Cells
were bathed in solution containing (in mM) 140 NaCl, 2 KCl, 2 CaCl2, 1 BaCl2, 2 CsCl, 1 MgCl2, and
5 HEPES, pH 7.2.
Characterization of gap junction channels. Biophysical
properties of junctional channels present between pairs of spinal cord astrocytes were characterized by an analysis of their voltage sensitivity and single-channel conductances. Voltage sensitivity of
Gj was assessed by plotting the ratio
of Gj at the end of the pulse
(steady-state Gj) to that measured at
the beginning of the pulse (instantaneous
Gj) for each voltage. Unitary
junctional conductances were measured in cell pairs in which only a few
channels were active by dividing peaks in all-point histograms of
junctional currents by the transjunctional voltage
(Vj).
Confocal microscopy
Intracellular calcium measurements. Confluent
cultures of spinal cord astrocytes plated on glass-bottomed microwells
were loaded with Indo-1 AM (10 µM; Molecular Probes,
Eugene, OR) at 37°C for 45 min, after which they were rinsed with PBS
and used for confocal microscopy. Intracellular
Ca2+ was measured in loaded astrocytes
bathed in PBS, pH 7.4, at room temperature. The ratio of Indo-1
fluorescence intensity emitted at two wavelengths (390-440 nm and
>440 nm) was imaged by using UV laser excitation at 351 nm. Ratio
images were acquired continuously at 1 Hz after background and shading
correction by using a Nikon real time confocal microscope (RCM 8000)
with UV large pinhole and Nikon 40× water immersion objective
(numerical aperture, 1.15; working distance, 0.2 mm). Indo-1
fluorescence ratio images were acquired continuously before and 1-2
min after the induction of intercellular calcium waves (see below). The
ratiometric images were saved on an optical disk recorder as the
average of 32 frames and then played back for measurements of changes
in calcium level with Polygon-Star software (Nikon, Tokyo, Japan). The
gray levels (number of pixels per area) within the regions of interest
(circular spots with radii of 6.4 µm, containing ~200 pixels) were
averaged and then used for analysis.
Velocity, amplitude, and efficacy of calcium wave spread.
Calcium waves in Indo-1 AM-loaded spinal cord astrocytes were
evoked by mechanical stimulation of one cell in the confocal field
(171 × 128 µm; 21,888 µm2) by a
glass pipette with a 1-2 µm outer diameter, as previously described
(Scemes et al., 1998). The velocity of calcium waves was calculated as
the distance (µm) between the stimulated and the nonstimulated cells
divided by the time interval (sec) between the half-maximal calcium
increases within the stimulated and responding cells. Half-maximal
calcium increases were obtained from sigmoidal curves fit to the
ascending phase of each Indo-1 fluorescence ratio increase, using
Origin 3.01 software.
Amplitudes of calcium wave were considered to be the maximal increments
in intracellular calcium observed in responding cells, calculated for
each cell as the value of the Indo-1 fluorescence ratio rise at the
peak of the response divided by the basal fluorescence ratio value
acquired before the induction of the calcium waves.
The efficacy of calcium spread between glial cells is reported here as
the proportion of cells responding with an intracellular calcium
increase during the propagation of the wave in relation to the total
number of cells within the field of view.
To describe the overall properties of calcium waves under different
conditions, we here define a factor (E.V.A.) as being the
product of the relative values (test/control) obtained for the
Efficacy, Velocity, and Amplitude of
the calcium waves.
Contribution of extracellular signaling and gap junction-mediated
intercellular communication to the propagation of calcium waves.
The contribution of ATP-mediated calcium waves between cultured
astrocytes was evaluated by exposing sibling cultures of WT and Cx43 KO
spinal cord astrocytes to 100 µM of suramin [8-(3-benzamido-4methylbenzamido)-naphtalene-1,3,5-trisulfonic acid;
Sigma] or PPADS (pyridoxal phosphate-6-azophenyl-2'4'-disulfonic acid;
Sigma), two P2 receptor antagonists (see King et al., 1996; Bolego et
al., 1997; Ralevic and Burnstock, 1998), and comparing the velocities,
amplitudes, efficacies, and E.V.A. factors of calcium spread
with those of untreated cultures.
Heptanol, a potent gap junction channel blocker in astrocytes
(Dermietzel et al., 1991), was bath-applied (3 mM final
concentration) to astrocytes cultured from both WT and Cx43 KO siblings
to measure the effects of gap junction blockade on the calcium wave
spread between these glial cells.
Measurements of P2 agonist and antagonist effects
Intracellular calcium levels. Changes in cytosolic
calcium levels induced by P2 receptor agonists were measured in WT and Cx43 KO spinal cord and brain astrocytes loaded with fura-2 AM. Cells
plated on glass-bottomed microwells were loaded with fura-2 AM (10 µM; Molecular Probes) at 37°C for 45 min, after which
they were rinsed with PBS and viewed on a Zeiss (Oberkochen, Germany) epifluorescence microscope. Intracellular
Ca2+ was measured in loaded astrocytes
bathed in PBS, pH 7.4. The ratio of fura-2 fluorescence emitted at two
excitation wavelengths (340 and 380 nm) was obtained by using a
combined system of an optical filter wheel (Sutter Instruments,
Burlingame, CA) and a shutter (Uniblitz, Rochester, NY) driven by an
OEI computer (Universal Imaging, Media, PA). The images were acquired
with an intensified CCD camera (Quantex) and analyzed with Metafluor Imaging System software (Universal Imaging). Fura-2 fluorescence ratio
images were acquired continuously at a rate of 0.3 Hz before and after
the addition of purine and pyrimidine receptor agonists. Intracellular
calcium levels were obtained by measuring the ratio of fura-2 intensity
during excitation at 340 and 380 nm from regions of interest after
using the calibration equation:
[Ca2+]i = KD {(R Rmin)/(Rmax R)}
(F380min/F380max),
where [Ca2+]i is
the calculated intracellular calcium concentration,
KD is the dissociation constant of the
ion of interest with the dye (in this case
KD = 224 nM;
Grynkiewicz et al., 1985), R is the ratio intensity,
Rmin is the ratio of the intensity
obtained at zero calcium, Rmax is the
ratio of the intensity at saturated calcium,
F380min is the
fluorescence intensity measured at zero calcium at 380 nm (nonsensitive
to calcium), and
F380max is the
fluorescence intensity measured with saturated calcium at 380 nm.
Pharmacology of P2 receptors. Noncumulative dose-response
curves were obtained for a series of P2 receptor agonists on fura-2 AM-loaded astrocytes from brains and spinal cords of WT and Cx43 KO
mice. An interval of 5 min after several washes was maintained between
the addition of increasing doses (final concentration, 10 nM-1 mM) of the same agonist, and a 10 min
interval was maintained between two successive curves. After each
application the cells were washed three times with 1 ml of PBS. When
the effects of P2 antagonists on agonist response were investigated,
the antagonists were diluted in PBS and kept in contact with the cells
for a period of 15 min before and throughout the dose-response curve
acquisition. The EC50 values (effective
concentration that induced half-maximal increase in intracellular
Ca2+ levels) for each agonist were
calculated from the sigmoidal fittings of the dose-response curves
with Origin 3.01 software. The characterization of the P2 receptor
subtypes involved in the changes in intracellular Ca2+ levels observed in brain and spinal
cord WT and Cx43 KO astrocytes was performed by ranking the
EC50 values of the different agonists and
comparing the order of potencies with those determined by Ralevic and
Burnstock (1998) for each known P2 receptor subtype. The P2 receptor
agonists used were ATP, UTP (uridine 5'-triphosphate), 2-Me-S-ATP (2-methylthioadenosine 5'-triphosphate), and
ADP- -S [adenosine 5'-O-(2-thiodiphosphate];
the P2 receptor antagonists used were suramin and PPADS.
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RESULTS |
Electrical coupling between WT and Cx43 KO spinal
cord astrocytes
Dual whole-cell recordings revealed that junctional conductance
between pairs of wild-type spinal cord astrocytes was low (3.34 ± 0.94 nS; n = 43 cell pairs; Fig.
1). However, junctional conductance
obtained for pairs of Cx43 KO astrocytes was even lower (0.94 ± 0.42 nS; n = 50 cell pairs; Fig. 1). These values are
statistically different (p < 0.05; Student's
t test), indicating both that Cx43 contributes a major
component of junctional conductance and that other connexins also
provide gap junctional channels in these cells. Consistent with this
finding, voltage sensitivity of Gj in
WT and Cx43 KO spinal cord astrocytes differed markedly. In WT
astrocytes the relaxation of junctional currents was observed only in
response to 50 mV < Vj < 50 mV, whereas in
Cx43 KO astrocytes the currents decayed substantially at lower voltages
(compare Fig.
2A,C
with 2B,D). In addition, asymmetry was common in Cx43 KO astrocyte cell pairs (see triangles in Fig.
2B), and junctional conductance measured at high
voltages (Gmin or residual
conductance; see Spray et al., 1981) was lower for the Cx43 KO than for
WT spinal cord astrocytes.
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Figure 1.
Strength of electrical coupling between cultured
wild-type (WT) and Cx43 knock-out (KO) spinal cord astrocytes as
determined by dual whole-cell recordings. Measurements of junctional
conductance showed that pairs of WT spinal cord astrocytes
(black bars) are weakly coupled (3.34 ± 0.94 nS;
n = 43 cell pairs) and that electrical coupling is
significantly lower (0.94 ± 0.42 nS; n = 50 cell pairs) in Cx43 KO astrocytes (white bars).
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Figure 2.
Voltage sensitivity of junctional conductance
(Gj) between pairs of spinal cord
astrocytes from WT (A, C) and from Cx43 KO (B,
D) mice. In pairs of WT spinal cord astrocytes,
Gj was insensitive to transjunctional
voltages below 50 mV (V0 = ± 60 mV),
and a substantial voltage-insensitive conductance was present even at
80 mV (A, C), indicating that Cx43 is the dominant
protein forming junctional channels. The steeper voltage dependence of
the junctional conductance between pairs of Cx43 KO astrocytes
(B) indicates that other connexins (most likely
Cx40 and Cx45) contribute to junctional conductance. Different
symbols in the graphs represent data points obtained
from different cell pairs.
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Electrophysiological characterization of gap junction channels
expressed in spinal cord astrocytes
Single-channel recordings obtained from pairs of spinal cord
astrocytes revealed differences between WT and Cx43 KO mice. In WT
astrocytes, most common junctional channels were 70-90 pS (with a 30 pS substate observed at high Vj; Fig.
3A), similar to properties of
Cx43 channels in other systems (Moreno et al., 1994a,b); however, both
larger and smaller channels also were detected occasionally (Fig.
3A,B). In 10 cell pairs in which unitary conductances were
resolvable, all pairs exhibited 70-90 pS channels, two showed channels
with unitary conductances >150 pS, and two pairs showed 40-50 pS
channels. In Cx43 KO spinal cord astrocytes, 30-50 pS channels (Fig.
3C) and larger, >150 pS channels (Fig. 3D) were
predominant. In 10 pairs of Cx43 KO astrocytes, 30-50 pS channels were
found in all pairs, and channels with conductances >150 pS were
present in two recordings.
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Figure 3.
Characteristics of junctional channels between WT
(A, B) and Cx43 KO (C, D) spinal cord
astrocytes. The channels most frequently observed between pairs of WT
astrocytes displayed unitary conductance of ~70-90 pS
(A) and showed a 30 pS substate, although 150 pS
channels also were seen in 20% of the recordings
(B). In pairs of Cx43 KO astrocytes the most
common current fluctuations had sizes corresponding to 30-50 pS
(C) without displaying measurable substates; as
in WT, large conductance channels (>150 pS) also were observed in
~20% of the cell pairs (D).
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Properties of calcium wave spread between WT and Cx43 KO spinal
cord astrocytes
As a further test for differences in intercellular communication
between wild-type and Cx43 knock-out spinal cord astrocytes, mechanically evoked calcium wave spread was evaluated in these cultures
(Figs. 4A,B,
5A,D). In response to a brief touch of one astrocyte
(indicated in representative examples in Fig. 4A,B), intracellular Ca2+ levels increased in a
progressively larger area of the field. For both WT and Cx43 KO spinal
cord astrocytes the spread was rapid and extensive (Figs.
4A1-A4;
4B1-B4;
5A,D) Measurements of velocity, amplitude, and efficacy of
Ca2+ wave propagation are presented in
Table 1 and show no significant differences (p > 0.05; Student's t
test) in any of the parameters; furthermore, the products of these
parameters (E.V.A. factor) were very similar, with a ratio
near unity.
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Figure 4.
Intercellular calcium wave propagation in
confluent cultures of WT (A) and Cx43 KO
(B) spinal cord astrocytes. Cells were loaded
with 10 µM Indo-1 AM and excited at 352 nm while being
imaged simultaneously at emission wavelengths of 380 and 410 nm, using
a Nikon real time confocal microscope. The pseudocolor display shows a
range of ratiometrically determined changes in intracellular calcium
levels from resting (yellow-green) to high levels
(bright red). Images
A1-A4 and
B1-B4 were acquired at 1 sec
intervals after a single cell (marked by a white cross)
was stimulated mechanically during the ratiometric confocal imaging.
The pseudocolor scale for Indo-1 fluorescence ratio (from 0.5 to 3.0)
is displayed at the right side of the figure.
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These data are strikingly different from those previously obtained by
our laboratory by using cortical astrocytes (Scemes et al., 1998), in
which calcium wave propagation between Cx43 KO cortical astrocytes was
shown to be attenuated when compared with that of WT siblings. [For
brain astrocytes the ratio of the calculated E.V.A. factors
(KO/WT) is 0.46, indicating that deletion of Cx43 reduces this overall
index of calcium wave propagation by one-half.] To account for such a
difference in calcium wave propagation between Cx43 KO spinal cord
astrocytes and between Cx43 KO brain astrocytes, we considered three
possibilities: (1) that the remaining gap junction channels expressed
in Cx43 KO spinal cord astrocytes might be sufficient to allow
diffusion of second messengers throughout the syncytium, thereby fully
supporting wave propagation in the absence of Cx43; (2) that the
propagation of calcium waves between WT and Cx43 KO spinal cord
astrocytes might be an entirely gap junction-independent mechanism,
supported by the diffusion of purines and pyrimidines liberated by the
stimulated cells and activating P2 receptors of the surrounding cells;
or (3) that both gap junction-dependent and independent mechanisms might be involved, but that the extracellular component of the calcium
wave propagation between Cx43 KO spinal cord astrocytes might be
modified in such a way that even small amounts of ATP released from the
mechanically stimulated cells would be sufficient to stimulate most
cells in the field.
To evaluate the extent to which calcium wave propagation between spinal
cord astrocytes from WT and Cx43 KO mice involved gap
junction-dependent and independent pathways, we analyzed the properties
of calcium wave spread after treating the cells with the gap junction
channel blocker heptanol and with two P2 receptor antagonists, suramin
and PPADS. Representative examples of each type of experiment are
illustrated in Figure 5, and values from all experiments are presented in Table 1.
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Figure 5.
Propagation of calcium waves between cultured WT
(A-C) and Cx43 KO (D-F)
spinal cord astrocytes under control conditions (A, D)
and in the presence of heptanol (B, E) and PPADS
(C, F). Changes in the Indo-1 fluorescence ratio
recorded in the mechanically stimulated cell (open
squares) and in three other cells (located no further than 60 µm from the stimulated cell; closed symbols) are
plotted as a function of time. Note that heptanol greatly attenuated
the propagation of calcium waves between WT spinal cord astrocytes
(B) and that PPADS blocked the spread of calcium
signaling between Cx43 KO spinal cord astrocytes
(F). Arrows indicate the time at
which a cell was stimulated mechanically; the time interval between the
responses of the stimulated cell and other cells was used to calculate
the velocity of calcium wave propagation (see Materials and
Methods).
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In both WT and Cx43 KO spinal cord astrocytes bathed in 3 mM heptanol, the velocity, amplitude, and efficacy of
calcium wave propagation were reduced (Fig. 5B,E, and
WTh/WTc and
KOh/KOc values in Table 1).
However, the reduction was more severe in the WT than in the Cx43 KO
spinal cord astrocytes, as reflected by the ratio of E.V.A.
factor obtained for each group
(KOh/WTh = 5.7; Table 1).
This result indicates that calcium wave propagation in WT spinal cord
astrocytes is more vulnerable to inhibition by the gap junction channel
blocker than in KO astrocytes.
The contribution of the extracellular calcium signaling pathway was
evaluated by the use of two P2 nucleotide receptor antagonists, suramin
and PPADS. In the presence of suramin (100 µM) the
E.V.A. factor for WT and Cx43 KO spinal cord astrocytes was
reduced to 61 and 50%
(WTs/WTc;
KOs/KOc; bottom part of
Table 1), which was primarily attributable to decreased velocity
of the waves (p < 0.001; Dunn's Method). As a
consequence, the ratio of the E.V.A. factor for WT and
Cx43 KO spinal cord astrocytes was close to unity
(KOs/WTs = 1.02; top part
of Table 1).
By contrast, in the presence of the P2 receptor antagonist PPADS (100 µM) the calcium waves propagated between Cx43 KO
astrocytes with an E.V.A.
(KOp/WTp) factor that was
0.19 of that measured between WT cells in the same condition (Table 1;
see also Fig. 5C,F). Noteworthy, the action of this
P2 antagonist on the propagation of calcium waves between WT astrocytes
was minor [E.V.A.
(WTp/WTc) = 0.86; see
bottom part of Table 1] when compared with the marked attenuation
imposed by this agent to the propagation of waves in KO astrocytes
[E.V.A.
(KOp/KOc) = 0.16; bottom part of Table 1]. This low E.V.A. factor in
Cx43 KO spinal cord astrocytes was attributable both to reduction in
velocity and also to a reduced number of cells participating in
the response (p < 0.001; Dunn's Method; Table
1).
Taken together, these results indicate that both gap junction-dependent
and independent mechanisms participate in the propagation of calcium
waves between WT and Cx43 KO spinal cord astrocytes. However, the
relative contribution of the extracellular pathway to the propagation
of intercellular calcium waves differs in these two types of cells;
calcium wave spread between WT spinal cord astrocytes is supported
mainly by a gap junction-dependent mechanism, whereas waves propagating
between Cx43 KO spinal cord astrocytes are supported mainly by the
extracellular component involving diffusion of an agent activating P2
receptors, presumably ATP. Furthermore, because PPADS differently
affected wave propagation between WT and KO astrocytes, it was
hypothesized that Cx43 KO astrocytes might express a different P2
receptor subtype that was more sensitive to PPADS blockade than that of
the WT cells.
Because it has been shown that anandamide and oleomide abolish dye and
electrical coupling without affecting the calcium wave propagation
(Guan et al., 1997), whereas 18-glycyrrhetinic acid and heptanol
block both gap junction coupling and calcium wave propagation, it was
proposed that heptanol and 18-glycyrrhetinic acid might block the
extracellular component of the calcium waves (Guan et al., 1997). To
determine the extent to which heptanol affected the extracellular
component of calcium wave propagation in our studies, we incubated
astrocytes with 3 mM heptanol, and ATP (5 µM;
near the EC50 value determined from
dose-response experiments shown below) was applied to the cells. As
shown in Figure 6, heptanol neither
prevented nor attenuated intracellular calcium rise in response to 5 µM ATP (Fig. 6B), whereas the P2
antagonist suramin (100 µM) totally abolished
the response to this same concentration of ATP (Fig. 6C).
ATP sensitivity was fully restored by rinsing the cells for 5 min in
PBS (Fig. 6D).
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Figure 6.
Changes in intracellular calcium levels in fura-2
AM-loaded WT astrocytes exposed to 5 µM ATP before
(A) and after (B) exposure
to the gap junction channel blocker heptanol and to the P2 receptor
antagonist suramin (C). Note that heptanol (3 mM) did not attenuate the effect of ATP (compare
A and B), whereas suramin (100 µM) greatly diminished the response
(C), which was reestablished 5 min after washout
(D). n = 60 cells from two
independent experiments. Arrows indicate times of ATP
addition.
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Pharmacological characterization of P2 receptors in WT and
Cx43 KO spinal cord astrocytes
To determine whether Cx43 KO spinal cord astrocytes express a
different P2 receptor subtype from those of their WT sibling cells, we
examined the order of potency of P2 receptor agonists by measuring the
changes in intracellular calcium levels in fura-2 AM-loaded WT and Cx43
KO astrocytes.
The application of increasing concentrations of different P2 receptor
agonists to cultured WT and Cx43 KO spinal cord astrocytes induced
dose-dependent increases in intracellular calcium concentration (Figs.
7, 8A, Table
2). Figure 7 shows representative results obtained for WT spinal cord astrocytes exposed to different
concentrations of ATP, with minimal effective ATP concentrations
estimated to be in the range of 1.0 µM and
maximal responses being induced by 100 µM ATP.
The dose-response curves and respective EC50
values obtained for the P2 receptor agonists in WT spinal cord
astrocytes are shown in Figure
8A. Based on the
EC50 values, the responses of WT spinal cord
astrocytes to the P2 agonists could be ranked in the following order of
potency: 2-Me-S-ATP > ATP > UTP  ADP--S. Similar to what was described previously for rat
spinal cord astrocytes (Salter and Hicks, 1994, 1995), the order of
potency obtained here for WT mouse spinal cord astrocytes suggests a
predominant participation of the P2Y1 receptor subtype in eliciting
rises in intracellular calcium. The possible involvement of the P2X receptor subtype, which is sensitive to 2-Me-S-ATP, was
ruled out in experiments in which application of the specific P2X
agonist,  ,-Me-S-ATP (0.1 µM-1.0 mM), did not
induce any change in the intracellular calcium levels of these cells
(n = 20; data not shown).
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Figure 7.
Intracellular calcium levels measured in WT
astrocytes loaded with fura-2 AM in response to increasing ATP
concentrations. n = 20 cells in each
panel.
|
|
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Figure 8.
Dose-response curves obtained for P2 agonists
(A, B) and for ATP in the presence of two P2 antagonists
(C, D), suramin and PPADS, measured in fura-2 AM-loaded
WT (A, C) and Cx43 KO (B, D) spinal cord
astrocytes. The order of agonist potency
(2-Me-S-ATP > ATP > UTP ADP--S) measured by the EC50 values
indicates that WT spinal cord astrocytes express a P2Y1 receptor
subtype (A); the order of potency ATP = UTP
 2-Me-S-ATP ADP--S
indicates that Cx43 KO spinal cord astrocytes express a P2Y2 receptor
subtype (B). Note that in WT astrocytes suramin
and PPADS (100 µM) did not affect the EC50
value obtained for ATP (C), whereas in Cx43 KO
astrocytes the dose-response curve to ATP was shifted to the right
(D). Each point in the graphs
corresponds to the relative increment in intracellular calcium (from
basal levels to maximal responses; see also Table 2) induced by
increased concentrations of agonists. The results are from 60-80 cells
in at least three independent experiments.
|
|
A dramatically different response to P2 receptor agonists was obtained
for Cx43 KO spinal cord astrocytes (Fig. 8B, Table 2). Whereas EC50 values were similar for
ADP--S in WT and Cx43 KO spinal cord astrocytes, the
KO astrocytes were markedly more sensitive to ATP and UTP and markedly
less sensitive to 2-Me-S-ATP (Fig. 8A,B,
Table 2). This resulted in a shift in the order of potency of P2
receptor agonists (ATP = UTP ADP--S 2-Me-S-ATP) obtained for Cx43 KO spinal cord astrocytes,
suggesting that these cells express the P2Y2 type as the dominant P2 receptor.
These results thus indicate that in spinal cord astrocytes lacking Cx43
there is a change in P2 receptor subtype from a P2Y1 to a P2Y2 subtype.
It is noteworthy that, besides the change in the order of potency, the
concentration of ATP and UTP necessary to induce a half-maximal calcium
rise was decreased by one and two orders of magnitude, respectively, in
Cx43 KO spinal cord astrocytes (EC50 = 0.5 µM for both ATP and UTP) as compared with WT siblings
(EC50 = 4.0 µM for ATP;
EC50 = 32.0 µM for UTP). These data
indicate that, in contrast to their WT siblings, Cx43 KO spinal cord
astrocytes are substantially more sensitive to these two endogenous
nucleotides (Table 2).
Effects of suramin and PPADS on the ATP responses of WT and Cx43 KO
spinal cord astrocytes
Exposure of WT and Cx43 KO spinal cord astrocytes to either
suramin (100 µM) or PPADS (100 µM) greatly
reduced the responses induced by ATP (Table 2). However, the antagonism
imposed by these two P2 receptor blockers to ATP action was more
pronounced in Cx43 KO spinal cord astrocytes than in WT cells (Fig.
8C,D, Table 2). This difference was particularly marked for
PPADS, which at 100 µM was eightfold more
potent in blocking ATP responses of Cx43 KO spinal cord astrocytes
(Table 2). Such a difference presumably accounts for the greater
inhibition of Ca2+ wave propagation by
PPADS than by suramin in Cx43 KO spinal cord astrocytes (see Table
1).
In WT spinal cord astrocytes suramin and PPADS significantly reduced
the maximal response induced by ATP (from 4.1 to 0.4 µM
Ca2+; Table 2) without affecting the
EC50 values (Fig. 7C), providing evidence that the antagonism is noncompetitive. For Cx43 KO spinal cord
astrocytes, however, PPADS was more potent than suramin in reducing the
maximal response to ATP (from 1.9 to 0.1 µM
Ca2+ and to 0.3 µM
Ca2+ for PPADS and suramin, respectively;
Table 2) and in shifting the EC50 value (from 1.5 to 44.4 µM and to 132 µM, for suramin and PPADS, respectively; Fig.
8D).
These results showing that the blockade of P2 receptors by PPADS and
suramin is different in WT and in Cx43 KO astrocytes further support
the data described above indicating that WT and Cx43 KO spinal cord
astrocytes express different P2 receptor subtypes. Furthermore, they
indicate that the differential sensitivity of the two P2 receptor
subtypes to ATP may account for the changes in calcium wave properties
observed between WT and Cx43 KO spinal cord astrocytes.
Purinoceptors also are altered in Cx43 KO astrocytes from
the brain
Because the data described above indicated that deletion of the
Cx43 gene resulted in a change in P2 receptor subtype expression in
spinal cord astrocytes, we evaluated whether such alteration also
occurred in astrocytes from the brain by analyzing the order of P2
agonist potency in these cells.
In contrast to WT spinal cord astrocytes, WT brain astrocytes exhibited
an order of agonist potency (ATP = UTP > 2-Me-S-ATP = ADP--S) suggesting that
these cells express P2Y2 receptors (Fig.
9A). Although the
EC50 values differed somewhat, this order of
agonist potency for WT brain astrocytes was the same as that obtained
for Cx43 KO spinal cord astrocytes (compare Figs. 8B, 9A and values in Table 2). For Cx43 KO brain astrocytes the
order of agonist potency obtained (ADP--S > UTP
>ATP 2-Me-S-ATP; Fig. 9B) resembled that
described for the P2Y3 purinoceptors in chick brain (Webb et al.,
1996).
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Figure 9.
Dose-response curves obtained for P2 receptor
agonists measured in fura-2 AM-loaded WT (A) and
Cx43 KO (B) brain astrocytes. Based on the
EC50 values obtained for ATP, UTP,
2-Me-S-ATP, and ADP--S, the order of
agonist potency indicates that WT brain astrocytes express P2Y2,
whereas Cx43 KO brain astrocytes express the P2Y3 receptor subtype.
Each point in the graphs corresponds to the relative
increment in intracellular calcium (from basal levels to maximal
responses) induced by increased concentrations of agonists. The results
were obtained from 60-80 cells in at least three independent
experiments.
|
|
Although the order of P2 agonist potency was different in brain
astrocytes cultured from WT and Cx43 KO mice, the
EC50 values obtained for ATP and UTP were very
similar (EC50 = 3-5 µM in WT and
EC50 = 3-12 µM in Cx43 KO
astrocytes; Fig. 9A,B). Thus, in terms of the propagation of
intercellular calcium waves through the extracellular space, it seems
likely that expression of either of these two P2Y receptors would
affect wave propagation in a similar way.
| |
DISCUSSION |
It is shown here that spinal cord astrocytes form a weakly coupled
syncytium, with functional gap junction channels formed by Cx43 and
other connexins. The strength of coupling, measured as the junctional
conductance between cell pairs (3 nS), is four to six times lower than
that described for cortical astrocytes [in rats, 13 nS, Dermietzel et
al. (1991); in mouse, 17 nS, Spray et al. (1998)]; this difference is
expected to reflect on the functionality of the astrocytic syncytium,
specifically in the dissipation of ionic gradients, neurotransmitters,
and metabolites. Furthermore, based on the values of junctional
conductance (~1 nS) obtained here for pairs of Cx43 KO spinal cord
astrocytes (compared with 3 nS obtained for WT spinal cord astrocytes;
see Fig. 1), it is estimated that approximately two-thirds of the total
coupling is attributable to Cx43 and that the other connexins contribute the remaining one-third of coupling. This is strikingly different from the 5% contribution calculated for connexins other than
Cx43 in cortical astrocytes (Spray et al., 1998), signifying that the
contribution of other connexins to astrocytic syncytial properties is
more significant and important in the spinal cord than in the brain.
The voltage sensitivities and single-channel properties of gap
junctions between Cx43 KO spinal cord astrocytes are similar to those
for Cx26, Cx30, Cx40, and Cx45 (Bukauskas et al., 1995a,b; Moreno et
al., 1995; Hellmann et al., 1996; Valiunas et al., 1999), and the
presence of these connexins has been confirmed in spinal cord
astrocytes via RT-PCR, Northern blots, and immunocytochemistry (E. Scemes, unpublished observations). Because Cx43 forms nonselective channels whereas Cx26, Cx40, and Cx45 are more permissive to the transfer of cations than anions (Veenstra et al., 1994; Beblo et al.,
1995; Beblo and Veenstra, 1997; Wang and Veenstra, 1997) (see also
Spray, 1996), it is expected that the spinal cord astrocytic syncytium
in Cx43 knock-outs will favor the exchange of positively charged
molecules in comparison to what occurs in cortical astrocytes from
these animals. Thus, it could be speculated that even weak coupling
through cation-favoring channels will facilitate the dissipation of
K+ ions throughout the spinal cord
astrocytic syncytium, whereas the limited diffusion of anionic
signaling molecules, such as IP3, may compromise
coordination of the network via gap junction-mediated propagation of
calcium waves.
However, although the spinal cord astrocytic syncytium is less well
coupled than that of the brain, the velocity, amplitude, and efficacy
of calcium wave propagation between WT spinal cord astrocytes do not
differ from that previously described for cortical astrocytes (Scemes
et al., 1998). This suggests either that (1) the degree of coupling in
spinal cord astrocytes is sufficient to allow the diffusion of second
messengers to support wave propagation or (2) the extracellular pathway
plays an important role in calcium wave propagation within the
astrocytic syncytium. The first possibility is supported by the results
obtained here showing that heptanol prevented calcium wave propagation
between WT spinal cord astrocytes (see Table 1) and that this gap
junction channel blocker does not affect the extracellular component of
the wave, as seen by the responses of astrocytes to ATP when in the
presence of heptanol (see Fig. 6). Taken together, these data support
previous studies indicating that gap junction channels are the main,
although not the exclusive, route for calcium wave propagation between
astrocytes (Charles et al., 1992; Enkvist and McCarthy, 1992; Venance
et al., 1995; Naus et al., 1997; Scemes et al., 1998).
The most surprising finding obtained in this study is that astrocytes
from Cx43 null mice displayed altered functional expression of P2Y
receptor subtypes. For intercellular communication within the spinal
cord the shift in P2Y receptor subtype from P2Y1 to P2Y2 observed in
Cx43 KO cells renders the extracellular component of calcium waves the
main route by which calcium signaling is achieved. Because the P2Y2
receptor subtype expressed in Cx43 KO spinal cord astrocytes is one to
two orders of magnitude more sensitive to ATP and UTP than the P2Y1
receptor expressed in the WT sibling cells (see
EC50 values in Table 2 and Fig. 8), it is
proposed that the same amount of ATP released from the stimulated cells
would be sufficient to activate receptors in cells located much farther
from the point of stimulation than would occur in WT cells expressing
the less-sensitive P2Y1 receptor subtype. Such supposition is supported
by the present results showing that the properties of calcium wave
propagation between Cx43 KO spinal cord astrocytes are similar to those
of WT sibling cells and that waves in Cx43 cells are greatly reduced by
PPADS, a P2 receptor antagonist. For calcium waves traveling between
brain astrocytes, however, the change in P2 receptor subtype from P2Y2
to P2Y3 is unlikely to have such an effect, because they display the
same EC50 values for ATP and UTP (see Fig. 9).
Thus, the extent of diffusion of ATP or UTP through the extracellular
space is not expected to exceed the distance of second messenger
diffusion through gap junctions. Indeed, attenuation of calcium wave
propagation between Cx43 KO cortical astrocytes was reported previously
(Scemes et al., 1998).
Although gap junctions may provide the main route by which astrocytes
communicate with one another, it is clear that the extent to which
junctional channels contribute to the propagation of intercellular
calcium waves may vary in different CNS regions and under certain
pathological conditions. For instance, the extent to which calcium
waves propagate between cultured astrocytes derived from hypothalamus
is one-half of that obtained for hippocampal astrocytes, although their
strength of coupling appears to be similar (Blomstrand et al., 1999).
Under pathological conditions, such as inflammation and
neurodegenerative disorders of the CNS, the relative contribution of
gap junction-dependent and independent mechanisms to the propagation of
intercellular calcium waves may be altered; treatment of human fetal
astrocytes with interleukin-1 shifts the mode of intercellular
calcium wave propagation from a gap junction-dependent to a gap
junction-independent mechanism that is paralleled by a decrease in Cx43
expression and an increase in mRNA encoding the UTP-sensitive P2Y2
receptor (John et al., 1999).
Such an interplay between gap junctions and paracrine/autocrine
signaling provides a high degree of plasticity for intercellular communication between astrocytes. Although we interpret our results to
suggest that this interplay may reflect the influence of gap junctional
communication on expression patterns of other genes, the mechanism by
which Cx43 and P2 receptor expression is linked is unknown. One
possible way by which this might occur would involve the different
selective diffusion of signaling molecules through gap junction
channels formed of different connexins. Such a mechanism recently was
proposed for osteoblastic cell lines in which transcriptional activities of osteoblast-specific promoters were modulated in opposite
directions by overexpressing either Cx43 or Cx45 (Lecanda et al.,
1998). Alternatively, the expression of Cx43 might recruit a specific
type of P2 receptor to the membrane preferentially (as occurs via the
direct binding of ZO-1; Giepmans and Moolenaar, 1998; Toyofuku et al.,
1998) or selectively might affect P2 receptor gene expression directly
or via a binding protein.
The different P2 receptor subtypes functionally expressed in brain and
spinal cord astrocytes and the different P2 receptor subtypes exhibited
when Cx43 is absent provide further evidence that the physiological
properties of astrocytes in these CNS regions are not identical. In
terms of intercellular communication through calcium waves, such
differences between brain and spinal cord astrocytes are likely to
affect the extent to which the coordination of cooperative cell
activity is achieved under normal and pathological conditions.
| |
FOOTNOTES |
Received Oct. 4, 1999; revised Nov. 30, 1999; accepted Dec. 1, 1999.
This research was supported primarily by the American Paralysis
Association, Grant APA SB1-9802-2 (to E.S.), with additional support
from the Kirby Foundation (to E.S. and D.C.S.), Fundacao de Amparo a
Pesquisa do Estado de Sao Paulo FAPESP 1997/2379-2 (to S.O.S.), and
National Institutes of Health 5PO1-NS-07512 and NS-34931 (to E.S.,
S.O.S., and D.C.S.).
Correspondence should be addressed to Dr. Eliana Scemes, Department of
Neuroscience, Room 712, Kennedy Center, Albert Einstein College of
Medicine, Yeshiva University, 1410 Pelham Parkway South, Bronx, NY
10461. E-mail: scemes{at}aecom.yu.edu.
| |
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